UNITED STATES

SECURITIES AND EXCHANGE COMMISSION

Washington, D.C. 20549

FORM 10-K

☒ ANNUAL REPORT UNDER SECTION 13 OR 15(d) OF THE SECURITIES EXCHANGE ACT OF 1934

For the fiscal year ended: December 31, 2020

☐ TRANSITION REPORT UNDER SECTION 13 OR 15(d) OF THE SECURITIES EXCHANGE ACT OF 1934

For the transition period from ____________ to ____________

Commission file number: 001-38793

INMUNE BIO INC.

(Exact name of registrant as specified in its charter)

INMUNE BIO INC.

David Moss

1200 Prospect Street, Suite 525

La Jolla, CA 92037

Phone: (858) 964 3720

(Address of principal executive offices)(Zip Code)

(858) 964 3720

(Registrant’s telephone number, including area code)

Securities registered pursuant to Section 12(b) of the Act: None

Securities registered pursuant to Section 12(g) of the Act:

Indicate by check mark if the registrant is a well-known seasoned issuer, as defined in Rule 405 of the Securities Act. Yes ☐ No ☒

Indicate by check mark if the registrant is not required to file reports pursuant to Section 13 or Section 15(d) of the Act. Yes ☐ No ☒

Indicate by checkmark whether the registrant (1) has filed all reports required to be filed by Section 13 or 15(d) of the Securities Exchange Act of 1934 during the preceding 12 months (or for such shorter period that the registrant was required to file such reports), and (2) has been subject to such filing requirements for the past 90 days. Yes ☒ No ☐

Indicate by check mark whether the registrant has submitted electronically every Interactive Data File required to be submitted pursuant to Rule 405 of Regulation S-T (§ 232.405 of this chapter) during the preceding 12 months (or for such shorter period that the registrant was required to submit and post such files). Yes ☒ No ☐

Indicate by check mark whether the registrant is a large accelerated filer, an accelerated filer, a non-accelerated filer, smaller reporting company, or an emerging growth company. See the definitions of “large accelerated filer,” “accelerated filer,” “smaller reporting company,” and “emerging growth company” in Rule 12b-2 of the Exchange Act.

If an emerging growth company, indicate by check mark if the registrant has elected not to use the extended transition period for complying with any new or revised financial accounting standards provided pursuant to Section 13(a) of the Exchange Act. ☐

Indicate by check mark whether the registrant is a shell company (as defined in Rule 12b-2 of the Exchange Act). Yes ☐ No ☒

The aggregate market value of the registrant’s common stock held by non-affiliates of the registrant was approximately $21.2 million as of the last business day of the registrant’s most recently completed second fiscal quarter (June 30, 2020), based upon the closing sale price for the registrant’s common stock on that day as reported by the NASDAQ Capital Market. Shares of common stock held by each officer and director of the registrant on June 30, 2020 have been excluded in that such persons may be deemed to be affiliates.

As of March 4, 2021, there are 14,932,638 shares of common stock, $0.001 par value per share outstanding.

FORM 10-K

FOR THE YEAR ENDED DECEMBER 31, 2020

TABLE OF CONTENTS

PART I

All brand names or trademarks appearing in this report are the property of their respective holders. Unless the context requires otherwise, references in this report to “INmune Bio” the “Company,” “we,” “us,” and “our” refer to INmune Bio, Inc., a Nevada corporation.

FORWARD-LOOKING STATEMENTS

This Annual Report on Form 10-K (this “Annual Report”) contains “forward-looking statements” Forward-looking statements reflect our current view about future events. When used in this Report, the words “anticipate,” “believe,” “estimate,” “expect,” “future,” “intend,” “plan,” or the negative of these terms and similar expressions, as they relate to us or our management, identify forward-looking statements. Such statements include, but are not limited to, statements contained in this Report relating to our business strategy, our future operating results and liquidity and capital resources outlook. Forward-looking statements are based on our current expectations and assumptions regarding our business, the economy and other future conditions. Because forward–looking statements relate to the future, they are subject to inherent uncertainties, risks and changes in circumstances that are difficult to predict. Our actual results may differ materially from those contemplated by the forward-looking statements. They are neither statements of historical fact nor guarantees of assurance of future performance. We caution you therefore against relying on any of these forward-looking statements. Important factors that could cause actual results to differ materially from those in the forward-looking statements include, without limitation, our ability to raise capital to fund continuing operations; our ability to protect our intellectual property rights; the impact of any infringement actions or other litigation brought against us; competition from other providers and products; our ability to develop and commercialize products and services; changes in government regulation; our ability to complete capital raising transactions; and other factors (including the risks contained in the section of this Annual Report entitled “Risk Factors”) relating to our industry, our operations and results of operations. Actual results may differ significantly from those anticipated, believed, estimated, expected, intended or planned.

Factors or events that could cause our actual results to differ may emerge from time to time, and it is not possible for us to predict all of them. We cannot guarantee future results, levels of activity, performance or achievements. Except as required by applicable law, including the securities laws of the United States, we do not intend to update any of the forward-looking statements to conform these statements to actual results.

PART I

Item 1. Business

Our Strategy

Our objective is to develop and commercialize our product candidates to treat diseases where the innate immune system is not functioning normally and contributing to the patient’s disease. This can be in cancer where Natural Killer (“NK”) cells are inactive and contribute to a tumor’s evasion of the immune system and/or disease progression while expression of MUC4 and cells of the tumor microenvironment such as Myeloid Derived Suppressor Cells (“MDSC”) proliferate to protect the tumor from attack by the patient’s immune system or this can be other diseases such as neurologic and metabolic diseases where chronic inflammation results in innate immune system dysfunction and disease progression or infectious disease where cytokine storm causes a hypermetabolic state that causes the need to seek medical attention. Our initial focus will be the treatment of cancer, treatment of Alzheimer’s Disease (“AD”), treatment of Treatment Resistant Depression (“TRD”), treatment of immune mediated complications due to COVID-19 and non-alcoholic steatohepatitis (“NASH”). In cancer, we plan to pursue two parallel development programs: (1) with INKmune we will initially focus on treating resistant disease women with relapse refractory ovarian carcinoma and patients with high-risk myelodysplastic syndrome (high risk MDS); (2) with INB03, we will treat patients with advanced cancers with elevated biomarkers of inflammation in their blood and evidence of disease that is resistant to immunotherapy including women with MUC4 expressing HER2+ breast cancer. Our third drug candidate XPro1595, targets Alzheimer’s Disease and TRD. XPro1595 for AD is progressing through Phase I trials and is being prepared for Phase II trials. XPro1595 for TRD is being prepared for Phase II trials. Our fourth drug candidate, LIVNate, will be used to treat patients with NASH. Our final drug, Quellor is in Phase II trials for the treatment of pulmonary complications due to COVID-19 infection. The principal components of our strategy to achieve this objective are to:

Pursue development and regulatory approval pathways. We believe Quellor, INKmune, INB03 and XPro1595 may be approvable under pathways that are potentially shorter than those typically available for drug products based on novel active ingredients, including as an orphan drug under the Orphan Drug Act and approval under the Food and Drug Administration (the “FDA”) Accelerated Approval Program (see “Government Regulation”). We have not yet had a discussion with the Medicines and Healthcare Products Regulatory Agency (“MHRA”) and/or FDA regarding such designation, but plan to do so in the future. We believe both our INB03 HER2+ metastatic breast cancer program, high risk MDS and ovarian carcinoma treatment programs and our program Quellor to treat respiratory complications due to COVID19 infection fit the criteria used by the FDA to grant these regulatory designations. We believe that it would take a minimum of six months to receive Orphan Drug status once we submit an application and a minimum of 12 months to receive a designation once we submit an application. We might never have these discussions, submit applications under the Orphan Drug Act as the FDA Accelerated Approval Program or have these applications approved if we do.

Adopt a two-pronged patent strategy. We are pursuing a two-pronged product development strategy that will seek to solidify our existing IP to prevent competition and expand our IP suite into related therapeutic areas. We are confident that our core in-licensed IP (see “Intellectual Property”) will allow us both freedom-to-operate and provide robust protection from outside competition. We will continue to invest in expanding our patent suite. We will also seek to further to strengthen our IP position by looking to in-license IP related to our focus on the innate immune system.

Provide clear value propositions to third-party payors to merit reimbursement for our product candidates. We are designing our clinical development programs to demonstrate compelling, competitive advantages to patients and prescribers, and to demonstrate value propositions to third-party payors. We believe the use of INKmune and/or INB03 in patients with a high risk of tumor progression and death from tumor should prolong survival, improve the patient’s quality of life and decrease the total cost of care for patients with these lethal malignancies. For example, ovarian cancer patients relapse frequently. Each relapse requires an expensive, hospital-based treatment regimen that has decreasing benefits. Treatment with INKmune as an out-patient may provide a more durable remission and limit the need for treatment-associated hospitalizations. At the patient level, we believe INKmune and INB03 therapy, once approved, should improve survival and quality of life. At the payor level, we believe INKmune, once approved, should provide more predictable costs and outcomes. Therapies for Alzheimer’s disease are needed for medical, social and economic reasons. The cost of Alzheimer’s disease to the government is large and growing. The cost to families and care givers is real and burdensome. We believe treatment of patients with dementia, including Alzheimer’s disease, may provide a strategy to alter the costly dynamic of this disease in society today. NASH, a silent epidemic in the US due to the high incidence of obesity, is expected to be the most common cause of liver transplant 2030. There are no approved therapies for the NASH at this time. We believe treatment of patients requiring hospitalization due to medical complications of COVID-19 infection may alter the arc of the pandemic. If effective, Quellor should allow patients to be discharged from the hospital more quickly and decrease the risk of respiratory failure requiring mechanical ventilation.

Collaborate to maximize the value of our technology. We believe there are two reasons for us to enter collaborations with other companies. The first is the further development of INKmune, INB03, Quellor, LIVNate and XPro1595 by either providing additional innovations to the product, including combination therapy strategies, and/or providing resources to improve the speed and breadth of the development process. The second is to optimize the commercialization of our products either globally or regionally. The ideal partner will benefit us in both ways.

We continue to look for ways to utilize our unique capabilities to optimize clinical application of cell therapies. We believe that we have identified a way to manufacture human mesenchymal stem cells for the medical research and biotech community that offers large volumes of high-quality, low passage human umbilical cord mesenchymal stem cells with minimal batch-to-batch variability. We believe this may solve the problem associated with supplying an adequate supply of human mesenchymal stem cells for clinical applications. The process to produce pooled, human umbilical cord mesenchymal stem cells was developed at University College London. We have established a reliable supply of human umbilical cords based on our agreement with the Anthony Nolan Cord Blood Bank in the United Kingdom. We have developed a validated manufacturing process that reliably produces contract manufacturer of the clinical grade (“cGMP”) quality mesenchymal stem cells. The manufacturing process can be performed at a contract manufacturing site under the direction of Mark Lowdell, the Company’s CSO. We have negotiated an exclusive 10-year license to the manufacturing process from University College London Business, the licensing organization of University College London. We will seek academic laboratories and biopharma companies who need a reliable source of high quality pooled human umbilical cord mesenchymal stem cells for research of and development of clinical products. Once identified, we plan to act as a cGMP for the development of therapeutic products by utilizing contract manufacturers. Because the production of the product is not continuous, we do not expect to engage a contract manufacturer until we have a customer identified. We have identified several contract manufacturers in the UK that have the capability to produce cGMP stem cells. We expect the commercial arrangement with academic laboratories or biopharma companies to be a combination of fee-for-service and licensing that does not require additional investment by us. We will be opportunistic in pursuing therapeutic opportunities for our own portfolio with this platform in the future if resources become available. The regulatory path for therapeutic applications of the mesenchymal stem cell products is well established and similar to the regulatory approval process for other cell therapies. We will only be responsible for regulatory compliance related to manufacturing of the mesenchymal stem cells when the product is being developed by a third party. When developing a therapeutic product for the Company’s commercial portfolio, the Company will be responsible for all aspects of the regulatory process.

Overview of Immunotherapy for Cancer

The immune system has two parts, innate and adaptive. The innate immune system is the body’s first line of defense against an infection, providing immediate, non-specific responses to eliminate harmful cells in the body. Components of the innate immune system include cytokines, chemokines, macrophages, neutrophils and NK cells, among others.

The adaptive immune system is often initially triggered by the innate immune system, mounts a delayed response against diseased cells and plays a role protecting against re-infection. An adaptive immune response is highly specific to a pathogen or antigen and is developed or learned from prior exposure. Key components of the adaptive immune system include antibodies which bind to antigens and mark them for destruction by other immune cells, B-cells which produce these antibodies upon exposure to antigens, and T-cells which attack and eliminate the diseased cells.

The biopharmaceutical industry has made significant advances in harnessing specific components of innate and adaptive immune systems for therapeutic use. Some of these approaches are summarized below.

Cytokines. One of the early applications of immunotherapy is the use of cytokines, including interferons and interleukin-2 (“IL-2”). Interferons are molecules that inhibit the growth and replication of diseased cells and stimulate innate immune cells to attack them. They have been used as standard of care for hepatitis B and C and multiple sclerosis, and to a lesser extent, as treatment for certain cancers, including chronic myeloid leukemia, cutaneous T-cell lymphoma, myeloma and non-Hodgkin’s lymphoma. However, the use of interferons has generally decreased over the years due to serious adverse events (e.g., flu-like symptoms and dramatic weight loss) and introduction of new therapies with higher efficacy, better safety profiles and more convenient administration although Alpha-interferon remains the treatment of choice for some hematological conditions such as polycythemia. IL-2 activates T-cells and NK cells to attack diseased cells. IL-2 has been used to treat select cancers, but due to its relatively poor safety profile, physicians often only resort to this therapy for the most advanced settings. Tumor Necrosis Factor alpha (“TNF”) is the focus of INB03. TNF biology has four elements that include two cytokines, soluble TNF and trans-membrane TNF (“sTNF” and “tmTNF,” respectively), and two receptors, TNF Receptor 1 and 2 (“TNFR1” and “TNFR2”). The biology of TNF ligation of TNFR varies dramatically based on what elements of the TNF system that are used. sTNF binding to TNFR1 is responsible for inflammation and cell death while sTNF binding to TNFR2 promotes proliferation of regulatory T cells (“Treg”). In patients with advanced cancers, increased sTNF is not favorable to long-term survival because it promotes epithelial-mesenchymal transformation and metastasis while making the tumor microenvironment more immunosuppressive promoting resistance to therapy. In the CNS, sTNF promotes neuronal cell death, demyelination and synaptic pruning while tmTNF promotes nerve cell survival, improves synaptic function and stimulates remyelination. In brief, sTNF is the “bad” TNF and tmTNF is the “good” TNF. In patients with cancer, infection or neurologic disease, blockade of tmTNF function has negative consequences such as immunosuppression, increased infection, synaptic dysfunction and demyelination.

Antibody therapy. Antibodies exist in three formats: monoclonals (“mAbs”), oligo/polyclonal and antibody-drug conjugates. mAbs represent an effective therapeutic modality and are important to the treatment paradigm of various diseases. Drug manufacturers have leveraged mAbs’ ability to induce an antibody-dependent cell-mediated cytotoxicity, or ADCC effect to develop better treatments that prolong survival and quality of life of patients. In addition, mAbs designed to inhibit specific checkpoints in the immune system have overcome in vivo immune suppression and the resulting immune responses have led to profound therapeutic benefit in some patients. However, the degree of efficacy of these therapies is heavily reliant on the immune system of patients, many of whom are severely immuno-compromised. For example, despite over $1.0 billion of sales generated by recently launched PD-1 and PDL1 checkpoint inhibitors, they are reported to be generally only effective in approximately 10% to 25% of the addressable patient population. In addition, mAbs are manufactured through a complex process that requires purification of cell products created from a cell line. Polyspecific antibodies, for example bi-specific antibodies, are able to target more than one antigen. These are often used to bring and effector T cell in contact with a target cell. Antibody drug conjugates are mAbs attached to a toxin, chemotherapy or radio therapy that delivers the cancer killing payload directly to the cancer.

Dendritic Cell Therapies. This approach is designed to indirectly stimulate a patient’s T-cells by leveraging the role of dendritic cells in presenting antigens to T-cells. Cancer vaccines are the most common application of dendritic cells. The only FDA-approved dendritic cell therapy is PROVENGE, which entails collecting monocytes from the patient, maturing them into dendritic cells, “loading” ex vivo with the patient’s cancer antigens, and then re-infusing in the patient. Currently, this process is cumbersome and expensive, and again, relies on an intact and effective immune system of the patient. There are additional ongoing preclinical studies and clinical trials being conducted by our competitors aimed at addressing certain of the limitations associated with this approach. To date, current clinical results of dendritic cell therapies have been mixed.

CAR-T and TCR Therapies. T-cells recognize diseased cells by receptors engaging with antigens that are present on or inside the diseased cells. CAR-T therapy entails genetically engineering T-cells to express synthetic CARs that direct T-cells to antigens on the surface of cancer cells. TCR therapy modifies T-cells to express high-affinity tumor specific TCRs that recognize intra-cellular antigens that must be presented on the surface of target cells. In early clinical trials, CAR-T and TCR therapies have demonstrated impressive anti-tumor activity in a narrow spectrum of hematologic cancers and garnered significant attention by research institutions and biopharmaceutical companies. We believe a key limitation of adaptive autologous immunotherapy is the need to retrieve non-compromised immune cells from a cancer patient which requires a complex and costly manufacturing process to develop the therapy. The complexity of this personalized process is reflected in the price of the two approved therapies. CAR-T therapies - tisagenlecleucel and axicabtagene ciloleucel for advanced leukemia and lymphoma respectively. The cost of a single therapy is many hundreds of thousands of dollars. As a consequence of this need to harvest active T-cells, current Phase I clinical trials for autologous CAR-T cell therapy in large part enroll patients from highly selected, often relatively early-stage disease in a narrow spectrum of cancers, including bulky hematological cancers. In addition, Phase I clinical trials of CAR-T cell immunotherapy have reported severe adverse toxicities of cytokine release syndrome and neurotoxicity, requiring hospitalization, pre-conditioning and, in some instances, intensive care unit admission following side effects associated with cytokine release syndrome. As a result, though our competitors continue to develop their CAR-T and TCR product candidates with the goal of addressing certain of the limitations associated with these approaches, we believe these serious challenges may limit their potential and use in a variety of indications, including solid tumors.

Checkpoint Inhibitors. Immune cells express proteins that are immune checkpoints that control and down-regulate the immune response. These are best defined in T lymphocytes and include PD-1, CTLA-4, TIM-3 and LAG3. Tumor cells express the ligands to these receptors. When T cells bind the ligand to these proteins on the tumor cells, the T cell is turned off and does not attempt to attack the tumor cell. Thus, checkpoint inhibitors (“CPI”) are part of the complex strategy used by the tumor to evade the patient’s immune system and are responsible for resistance to immunotherapy. Biopharmaceutical companies have successfully developed CPI that block the receptor/ligand interaction to promote the adaptive immune response to the tumor. Six CPI are currently approved, pembrolizumab, nivolumab, atezolizumab, avelumab, durvalumab, and ipilimumab for a wide variety of solid tumors including melanoma, lung, bladder, gastric cancers and others. More CPI are in development and more tumor types will be added to the list of sensitive tumors over the next years. CPI have become the backbone of cancer therapy and are expected to be the best -selling class of drugs by 2027.

NK Cells. NK cells typically represent approximately 2% to 13% of circulating lymphocytes and are a critical component of the immune system responsible for innate immunity. Unlike adaptive immune cells, they are ever present and ready to attack, having the inherent ability to detect and eliminate diseased cells without the need for antigen presentation, which is why they are called “natural killers.”

NK cells bind to stress ligands expressed by the diseased cells and directly eliminate them. This binding induces NK cells to release cytokines, including, interferons and GM-CSF, which are integral in recruiting additional innate and adaptive immune responses by the host. NK cells also represent a critical effector cell for ADCC, whereby target cells bound with human antibodies, whether made by the patient’s body or administered, are selectively destroyed by the NK cells.

MDSC Cells: MDSC are present in very low quantities in healthy patients. MDSC develop and proliferate in patients with chronic infection and with cancer. In cancer, MDSC are a unique and well-defined cell population that home to the cancer and secrete immunosuppressive cytokines that provide a protective, immunosuppressive shield to the tumor. This protective immunosuppressive shield prevents the patient’s immune system from attacking the tumor. The presence of MDSC in the tumor microenvironment and/or circulating in the patient’s blood predict for more advanced disease, resistance to immunotherapy and a worse patient survival.

Our Innate Immune Dominant-Negative TNF product candidate

We renamed XPro1595, which we license from Xencor, to INB03 when it is used for cancer related indications. We will continue to call the drug XPro1595 when used for treatment of neuropsychiatric diseases, including Alzheimer’s disease and TRD discussed below. We call the drug Quellor and LIVNate respectively for treatment of pulmonary complications of COVID-19 and NASH respectively. Quellor, LIVNate, INB03 and XPro1595 are the same drug with different names for marketing purposes. INB03 is a novel innate immune system check-point inhibitor that we believe decreases expression of MUC4 by the tumor, an important resistance mechanism to immunotherapy, decreases proliferation of MDSC and decreases the secretion of immunosuppressive cytokines that protect the tumor from the patient’s immunologic attack and help make the tumor resistant to immunotherapy. INB03, by inhibiting soluble TNF without inhibiting trans-membrane TNF or TNF receptors (“tmTNF” and “TNFR” respectively), decreases expression of MUC4, alters the immunoregulatory cell and cytokine profile of the tumor microenvironment to decrease the population of MDSC, decrease immunosuppressive cytokines and increase immunoregulatory cytokines that changes the patient’s immune response to their tumor with improved NK/DC crosstalk that causes expansion of the immune response including recruitment of the adaptive immune system with an increase in effector and cytotoxic T cells that attack the cancer allowing for decreased resistance to immunotherapy including immune checkpoint inhibitors (CPR), anti-HER2 immunotherapy such as Herceptin and kinase inhibitors such as lapatinib. By using INB03 as part of combination therapy for cancer, we believe the patient’s dysregulated immune response, a hallmark of cancer progression and resistance to therapy, to be converted to a coordinated immune response that can overcome resistance mechanisms to immunotherapy. These immune responses have been studied in two animal models. In a murine model of an inflammatory cancer, where 3-methylcholanthrese is given to mice in a subcutaneous injection that causes the development of multiple cutaneous fibrosarcoma. This model was developed by Y Akamatsu in 1967 while working at the National Cancer Institute of the NIH. In research published by Professor Nikola Vujanovic in Cancer Immunology Research in 2016, treatment with INB03 resulted in smaller and fewer cancers with increased survival. INB03 is an engineered PEGylated protein that neutralizes human soluble TNF, a human inflammatory cytokine that is increased in patients with advanced cancer. By specifically neutralizing the cytokine, there is decreased phosphorylation of STAT3, an essential step required for the proliferation of the MDSC population, and secretion of the immunosuppressive cytokines. The combination of decreased MDSC proliferation and decreased immunosuppressive cytokines allows the immune system to respond to the tumor. This data was published in an article entitled Inhibition of Soluble Tumor Necrosis Factor Prevents Chemically Induced Carcinogenesis in Mice in Cancer Immunology Research in Cancer Immunology Research 2016. In summary, INB03 functions as an innate immune system checkpoint inhibitor by eliminating the population of MDSC that provides an immunosuppressive shield protecting the tumor, the patient’s immune system is able to function normally to the benefit of the patient – it can attack the tumor. TNF plays an important role in breast cancer (Schillaci R, Front. Oncol., 22 April 2020 | https://doi.org/10.3389/fonc.2020.00584). In a murine model of trastuzumab resistant breast cancer using JMIT-1 cells, a human cell line of HER2 positive breast cancer resistant to trastuzumab placed into immunocompromised mice, INB03 downregulates MUC4 from the surface of the JMIT-1 HER2+ breast cancer cells to allow the trastuzumab resistant cells to become trastuzumab sensitive (Figure A from Bruni, NYAS 2020) to decrease tumor growth (from Schillaci SABCS 2018, Figure B). JMIT-1 cells are also resistant to lapatinib, a TKI inhibitor used as a second line therapy in women with trastuzumab resistant HER2+ breast cancer. The addition of INB03 to lapatinib in the animal model reverses lapatinib resistance in part by decreasing expression of MUC4 (from Bruni NYAS 2020, Figure C). In addition to decreasing resistance to trastuzumab by decreasing MUC4 expression, INB03 decreases the immunosuppressive tumor microenvironment (Schillaci SABCS 2018, Bruni NYAS 2020). These data are relevant to all tumors that express HER2 and MUC4 including upper gastrointestinal malignancies such as gastric and pancreatic cancer.

Because INB03 targets the patient’s immune system and not the tumor, we believe INB03 is an immunotherapy that can be used to treat many types of hematologic malignancies and solid tumors as part of combination therapy. The decision to use INB03 in a patient will be based on biomarkers that should predict that a patient will benefit from treatment with the drug. MDSC rarely exist in patients without cancer or chronic inflammation. Because MDSC can be measured in the tumor and/or blood of patients with immune dysregulation and chronic inflammation caused by their cancer, MDSC blood levels i) have prognostic value predicting cancer stage and risk of dying from cancer; ii) may be used as a biomarker to target patients who will benefit from INB03 therapy and iii) should be biomarkers demonstrating a pharmacodynamic effect of INB03. Other biomarkers of inflammation may be useful in predicting if a patient will benefit from therapy with INB03 such as Our Phase I clinical trial focused on using INB03 as monotherapy. This is a typical Phase I clinical trial design for first-in-man trials in cancer. We expect to use INB03 as part of combination therapy with approved cancer therapies as part of Phase II development. We do not expect to need to modify INB03 therapy to treat each different type of cancer, because INB03 therapy targets the immune system, not the cancer. We do expect to develop the INB03 beyond Phase II to target a specific type of cancer to meet the current system of regulatory approval. For instance, INB03 may be approved to treat patients with elevated MDSC who have lung cancer. To get subsequent approval for the treatment of patients with renal cell cancer who have increased MDSC, we will need to perform a pivotal trial in patients with renal cancer. Likewise, if we want to get approval of treatment of women with HER2 positive breast cancer who express MUC4, we will need to perform a trial in those patients and the results of that trial may be independent of MDSC levels. After the first regulatory approval, if and when achieved, we believe the difficulty and cost of achieving these labels extensions will decline with each successive approval. At this time, we cannot predict if patients without biomarkers of inflammation, elevated MDSC or cytokines, or increased expression of MUC4 will benefit from treatment with INB03. Those studies may be performed in the future, but they are not a priority.

XPro1595 neutralizes soluble TNF in the brain in exactly the same way INB03 neutralizes soluble TNF in the tumor microenvironment but the effects of soluble TNF neutralization in the brain are different. The cause of the destructive neuroinflammation in the brain are microglial and astroglial cells. The glial cell are two of four cells in the neural unit that also includes oligodentrocytes and nerve cells. Activated microglial cells are considered the resident macrophages of the brain. The primary role of microglial cells is to protect the neural unit from infection. When innate immune dysfunction causes chronic inflammation, activated microglial cells produce soluble TNF that activates astrocytes. Activated glial cells cause nerve cell and oligodrocyte dysfunction that results in synaptic pruning, nerve cell death and demyelination of neurons. These pathologies contribute, in part, to neurodegenerative diseases such as AD, Parkinson’s disease, ALS, MS, Huntington’s disease, glaucoma and TBI (traumatic brain injury) may contribute to neuropsychiatric diseases such as depression, bi-polar disease, sleep disorders, autism, schizophrenia and PTSD. In the setting of AD, microglial activation causes dendritic pruning, synaptic dysfunction and nerve cell death that contributes to cognitive decline and the behavioral manifestations of AD including depression, aggressiveness, sleep disorders, hallucinations and anhedonia. Elimination of microglial activation should reverse these symptoms. Because soluble TNF is the apex cytokine in the inflammatory cytokine cascade, neutralization of soluble TNF with XPro1595 should prevent glial activation and normalizes function of the neural unit.

The Company has an on-going Phase I trial using XPro1595 to reverse neuroinflammation in patients with Alzheimer’s disease. The trial is being performed in Australia and is partially funded by a $1M USD Part-the-Cloud Award from the Alzheimer’s Association. The clinical trial is the first in the Company’s development program for the treatment of dementia. The open label, dose escalation trial in patients with Alzheimer’s disease with biomarkers of peripheral inflammation (one of CRP>1.5mg/L, HgbA1c>6.0, ESR>10sec or have ApoE4) treats the patients with XPro1595 as a once-a-week subcutaneous injection for 3 months. Patients have multiple biomarkers of neuroinflammation tested before and during therapy including soluble biomarkers in blood and cerebral spinal fluid, volatile biomarkers in breath, behavioral biomarkers (neuropsychiatric symptoms of AD) and neuroimaging biomarkers using MRI. The primary goal of this short, open label study is to demonstrate that treatment with XPro1595 decreases neuroinflammation safely and to define the dose of XPro1595 to use in the Phase II trial. Studies of cognitive function are performed on the patients but are not expected to show significant change because of the short duration of the trial and the wide range of disability in patients enrolled in the clinical trial (MMSE range: 24-12). The goal of the planned Phase II trial will be to demonstrate the prolonged control of neuroinflammation in patients with dementia will help control cognitive decline. Although the trial has not been designed, we expect the trial be of a longer duration than the Phase I trial.

The trial continues to enroll patients. More than half of the expected 18 patients have been enrolled. Preliminary data was presented in a webinar on 13 July 2020. Neuroimaging data from six patients were presented in the figure below. In summary, treatment with XPro1595 at either 0.3 or 1.0mg/kg once-a-week as a subcutaneous injection (low and high dose respectively) decreased white matter free water (WMFW) as measured by MRI. WMFW is a validated biomarker of neuroinflammation. Although the number of patients is low, there was a dose response with a greater decrease in WMFW in the high dose compared to the low dose group. An analysis of inflammation in white matter tracts demonstrated a significant decrease in WMFW (40%; range 20-52%) in the arcute fasciculus, a white matter tract important in the control of language and short-term memory (Figure D). These data suggest XPro1595 is decreasing neuroinflammation in patients with Alzheimer’s disease who have biomarkers of peripheral inflammation.

Additional data was presented on January 21, 2021. The goal of the January 21 data release was to show a correlation between the white matter free water, a novel biomarker of inflammation with cerebral spinal fluid (“CSF”) cytokines and chemokine levels, a traditional measure neuroinflammation. CSF cytokine/chemokines were measure in 9 patients before and after 12 weeks of weekly therapy with XPro1595 using a panel from OLINK Target 48 Cytokine (https://www.olink.com/products/olink-target-48-cytokine/), that measures 45 (Figure AD1).

In the 6 patients in the 1mg/kg per week dose, only one cytokine and chemokine, interferon gamma (INFg) did not change in the CSF of patients, the remainder all decreased on average of 15%. Using data from all patients treated for 12 weeks (3 low dose, 6 high dose), a high correlation (R²=.7561) between the white matter free water safe mase and the inflammation composite score is shown in figure AD2. The data analyzed provides evidence that XPro1595 decreases neuroinflammation in patients with Alzheimer’s disease.

We believe these data support the use of XPro1595 to treat other diseases where neuroinflammation is a part of the pathophysiology of the disease. The company studied the consequences of decreasing neuroinflammation in the 6 patients from high dose group (XPro1595 1mg/kg for 12 weeks) be looking at the CSF proteome using technology for Proteome Sciences using their TMT Calibrator™ platform (https://www.proteomics.com/services/tmtcalibrator-workflow). A large data set of proteins were identified. Early analysis of the data focusing on 26 AD related proteins demonstrated changes in inflammation, neuronal and synaptic proteins caused by decreasing neuroinflammation after treatment with XPro1595 (Figure AD3). The proteome also demonstrated a clear dose response with a greater number of proteins being affected by the high dose compared to low dose XPro1595 therapy (0.3 vs 1.0 mg/kg/week for 12 weeks) (Figure AD4). The CSF proteome data is only partially analyzed. Additional data may result from these ongoing analytics. In summary, these data allow the Company to commit to initiating a blinded randomized Phase II trial in Alzheimer’s disease patients with peripheral biomarkers of inflammation in the second half of 2021. The design of the trial has not been finalized nor has the Company had discussions with the FDA. Hence the precise start date depends on gaining regulatory approval for trial initiation by the FDA and resolution of the COVID19 pandemic.

COVID-19 infection causes a cytokine storm in many patients. The cytokine storm includes elevated levels of TNF, IL6, IL1 and other pro-inflammatory cytokines in the patient’s blood. The cytokine storm correlates with symptoms of COVID19 of one or more organ systems - neurologic, gastrointestinal, pulmonary, cardiovascular and renal. In 20% of patients, the cytokine storm causes severe enough symptoms to require hospitalization. Targeting soluble TNF may have benefit in hospitalized patients with cytokine storm for two reasons. TNF may be the “master cytokine”. Up-regulation of TNF is required for expression of IL6 and IL1, the two other prominent cytokines of the cytokine storm. TNF activates endothelial cells to upregulate Tissue Factor that cause the formation of blood clots. Aberant blood clots contribute to the pathology in patients with COVID-19 infection.

The Company initiated a blinded randomized trial using Quellor to treat hospitalized patients with respiratory symptoms due to a COVID-19 infection. The 366-patient trial is being perform under an FDA IND#151,834 in multiple centers in the US. The trial includes a Go/NoGo decision by the Data Safety Monitoring Board (“DSMB”) after the first 100 patients. No data will be released by the DSMB other than the trial should continue or be closed. The trial enrolls patients admitted to the hospital who are considered high risk for developing the need for mechanical respiratory support. Patients are randomized to receive a single dose of Quellor, 1mg/kg as a subcutaneous injection or placebo. If patients remain in the hospital for one week, they may get a second dose of the investigational product. The primary end-point is the need for mechanical ventilation or death by 28 days. The final safety visit is at or about day 40. Quellor is identical to XPro1595, INB03 and LIVNate. The trial is listed on www.clinicaltrials.gov.

Effective therapy for TRD is a large unmet need. Twenty percent of patients with a Major Depressive Disorder have TRD. Once third of TRD patients have peripheral biomarkers to inflammation (elevated CRP). This is a large patient population. The role of TNF and anti-TNF therapeutics was explored in a small open label clinical trial by Prof. Andrew Miller, MD of Emory University demonstrated the patients have elevated TNF levels and treatment with infliximab treated their depression (Miller, 2011).

The Company received a $2.9M USD award from the National Institute of Mental Health (“NIMH”) to treat TRD with XPro1595. The blinded, randomized Phase II trial will use a biomarkers of peripheral inflammation to select patients with TRD for enrollment. Patients will be treated for 6 weeks. Primary end-points include both clinical and neuroimaging measures. The final trial design is ongoing and discussions with the FDA are not complete. The Company anticipates receiving authorization to initiate the clinical trial in the second half of 2021.

LIVNate neutralizes soluble TNF in the treatment of NASH the same way that INB03 and XPro1595 neutralize soluble TNF for the treatment of cancer and neurodegenerative diseases respectively. NASH is a complex disease with inflammatory, metabolic and fibrotic components that contribute to disease progression. The effects of LIVNate on NASH are diverse. Based on murine data, we believe there are 3 major pathologic cycles that contribute to NASH. The peripheral pathologic cycle is metabolic with obesity and insulin resistance contributing to the inflammatory and metabolic process that drives NASH. The regional pathologic cycle includes intestinal inflammation with resulting leaky gut that drives the development mesenteric fat. All three elements contribute to a highly inflammatory mileau delivered directly to the liver via the portal vein. The local pathologic loop includes lipotoxicity and innate immune dysfunction caused by activated hepatic stellate cell, natural killer cells and hepatocytes. These pathologic cycles cause hepatocyte death, inflammation and fibrosis – the pathologic hallmarks of NASH. In murine models of NASH, LIVNate has effects on each pathologic cycle decreasing insulin resistance, intestinal inflammation and leak, hepatic inflammation, hepatocyte death and fibrosis. These results must be confirmed in humans.

INB03, XPro1595, Quellor and LIVNate, are delivered as a subcutaneous injection, similar to an insulin treatment, given one to three times per week. Because this is a simple subcutaneous injection similar to an insulin injection (the therapy patients give themselves for treatment of Type 1 diabetes mellitus), we expect patients to administer the therapy to themselves and not require expensive or logistically challenging clinic visits to receive the therapy.

Three step process to preparation for INB03, XPro1595, Quellor and LIVNate for human clinical trials:

Release of INB03, XPro1595, Quellor and LIVNate drug supply

GMP DN-TNF product (INB03, XPro1595, Quellor and LIVNate) are available for clinical development after completion of release testing. The annual process for release testing was completed in February 2018, January 2019, December 2019 and November 2020. The supply of DN-TNF product is limited, but enough to complete the planned Phase I study in Alzheimer’s disease and Phase II studies in hospitalized patients with COVID-19. The re-release dossier has been submitted to the regulatory authorities in Australia and the US (the FDA). We received notification on May 2018 that the INB03 can be used for oncology clinical trials and in May 2019 that XPro1595 can be used in Alzheimer’s disease clinical trials in AUS and in August 2020 that Quellor can be used for the COVID-19 clinical trial in the US. For future trials, new batches of INB03, XPro1595, Quellor and LIVNate will need to be produced. We plan to use a two-step approach to production of the new drug supply. We hope to improve the yield of the drug product using the existing E.coli based system. Once the new process is validated and functional, we will perform a manufacturing campaign drug for future clinical trials. This process has started at our manufacturing vendor KBI. The company expects the first batches of new drug to be available 4Q21 assuming that manufacturing materials remain available and are not consumed by COVID-19 vaccine manufacturers. We expect the existing drug supply to support clinical development program until mid-2021. New drug supply may not be available before the existing drug supply has been exhausted.

Interaction with Regulatory Authorities Regarding INB03, XPro1595 and LIVNate Development

We have completed a Phase I trial with INB03 in oncology. We are enrolling patients in a Phase I trial with XPro1595 in patients with Alzheimer’s disease and a Phase II trial with Quellor to treat hospitalized patients with respiratory complications from COVID-19. The Phase II program with Alzheimer’s disease will start after completion of the on-going Phase I program. The Phase I trial with XPro1595 in patients with Alzheimer’s disease is performed in Australia under the regulatory authority of the TGA using the Clinical Trials Exemption (“CTX”) scheme. Our first interaction with the regulatory body occurred in March 2018. The Company received approval to initiate the Phase I trial with INB03 in patients with advanced solid tumors on May 21, 2018. The second interaction with the regulatory body occurred in March 2019. The Company received approval to initiate the Phase I trial with XPro1595 in patients with Alzheimer’s disease in May 2019. Our first interaction with the FDA occurred in July 2020. We received authorization to begin enrolling patients in the COVID19 trial late August 2020. We plan to discuss the Phase II Alzheimer’s disease and Phase II TRD clinical trials with the FDA during the first half of 2021.

INB03 Product Development Path: Proposed Phase II Studies in patients with cancer

Phase I open label study in patients with advance solid tumors has been completed. All future studies cancer will use INB03 as part of combination therapy. Based on the results of the Phase I study and work performed and reported by Prof. Roxana Schillaci, we are planning a study of INB03 in combination with currently approved second line therapy for treatment of tumors that express MUC4. This may include a study in women with trastuzumab resistant HER2+ metastatic breast cancer where primary or secondary resistance to trastuzumab is common and may include women with brain metastasis. Alternatively, a combination therapy trial in MUC4 expressing tumors of the upper gastrointestinal tract such as gastric or pancreatic cancer may be performed. These trials will not be initiated until the COVID-19 pandemic has run its course. We do not expect to treat patients in a Phase II trial with INB03 before 2022.

INB03 Registration Studies and/or Partnering

We plan to pursue an efficient registration strategy using INB03 to improve the lives of patients with cancer and biomarkers of inflammation. We believe that this strategy has use across many types of solid tumors including patients who have failed CPI, tyrosine kinase inhibitors (“TKI”) and anti-cancer antibody therapy We have an active partnering position as it relates to INB03 development in cancer, although no partnering discussion are underway at this time. We do not expect partnering discussions to begin until Phase II data demonstrating efficacy of INB03 as part of combination therapy for cancer are available.

Our INB03 platform can be used in cancer patients in many ways. The Phase I trial suggests the drug should not be used alone to treat cancer but used in combination with, but not limited to, other cancer therapies including cytotoxic chemotherapy, immunotherapy, radiation and surgery. We believe that INB03 can also be used to treat many types of hematologic and epithelial cancers.

INB03, XPro1595, Quellor and LIVNate Regulatory Strategy

Drugs from the DN-TNF platform will be developed using adequately powered, well designed studies with the goal to demonstrate a meaningful clinical benefit to patients. In general, these will be blinded, randomized clinical trials using validated end-points that have been authorized by a regulatory authority – the FDA, TGA, MHRA, EMA, etc. Currently, all planned studies will be performed in North America, AUS and/or the UK. Studies will be expanded to Europe and beyond as resources permit and development needs expand. Because there are no therapies similar to INB03, XPro1595, Quellor or LIVNate approved in any market and no therapies approved for the treatment of the diseases we are pursuing, we plan to take advantage of the regulatory opportunities afforded to therapies that treat markets with a high unmet need. In the U.S., this includes Orphan Drug Designation and expedited programs for approval including Accelerated Approval, Breakthrough Therapy Designation, Fast Track Designation, and priority review (see “Government Regulation”), and in the setting of COVID-19, Emergency Use Authorization. We cannot predict which, if any, of these programs we will benefit from without further discussions with the FDA. Similar programs exist in the EU with the EMA. We will engage the EMA once we have initiated Phase II trials in the United States and Australia.

Immunotherapy for Treatment of Alzheimer’s Disease

XPro1595 is being developed for the treatment of Alzheimer’s disease. XPro1595 is identical to INB03, Quellor and LIVNate in every way but name. The name XPro1595 will be used as the drug name in the Alzheimer’s disease development program. Microglial activation and neuroinflammation are important causes of the synaptic dysfunction and nerve cell death that causes cognitive decline in patient with dementia and Alzheimer’s disease. The relationship between β amyloid plaques and tau neurofibrillary tangles, the traditional targets in AD drug development and neuroinflammation is complex. We believe targeting plaques and tangles is not an effective treatment strategy, but that targeting neuroinflammation, the final common pathway of synaptic dysfunction and nerve cell death is. Substantial direct pre-clinical data supports the use of XPro1595 in murine models of AD. Substantial indirect data supports use of XPro1595 in humans including a decreased risk of AD in patients treated with non-selective TNF inhibitors for rheumatoid arthritis and treatment using direct injection into paraspinous venous plexus. Because of different mechanism of action of XPro1595 compared to the non-selective TNF inhibitors, we expect a lower risk of immunosuppression and demyelinating diseases such as MS. The Company reported preliminary data on July 13, 2020 and January 21, 2021 supporting the use of XPro1595 to decrease neuroinflammation in patients with Alzheimer’s disease and biomarkers of peripheral inflammation (see above)

We continue to enroll patients into an open label, biomarker directed, Phase I clinical trial in AUS that approaches AD as an immunologic disease. Patients with dementia who have the diagnosis of AD with biomarkers of chronic inflammation that includes at least one of a hs-CRP>1.5 mg/L, a ESR>10 mm/h, a HbgA1C>6.0% or are ApoE4 positive will be treated with XPro1595 for 12 weeks. Three dosing cohorts were planned – 0.3, 1.0 and 3 mg per week as a subcutaneous injection. Patients will have 5 groups of inflammatory biomarkers test before therapy, at 6 weeks and at 12 weeks. Biomarkers will be tested in blood and cerebral spinal fluid, white matter free water will be determined by MRI and a “breath test” measuring exhaled volatile organ compounds will be used to determine a signature of inflammation in AD patients. Finally, behavioral biomarkers of fatigue, depression aggression, anhedonia and sleep disorders, behaviors that are very sensitive to neuroinflammation, will be cataloged using validated scales to determine if these behaviors improve as neuroinflammation is brought under control. The first patient was enrolled in the low dose 0.3mg/kg/week cohort in the last week of November 2019. The Safety Review Committee met by teleconference on January 7, 2020 to review the course of the patients in the first cohort and voted to open the second cohort, 1.0mg/kg/week, to enrollment. The first patients were enrolled in the cohort the second week of February 2020. Based on preliminary data released on July 13, 2020 and January 21, 2021, we are confident that the clinical trial will be closed after completion of a 0.6mg/kg treatment group. We have canceled plans to treat patients with 3.0mg/kg. If safety is confirmed, the data from the Phase I trial will allow the Company to choose a dose to bring forward into the Phase II trial and select biomarkers for that trial. We plan to meet with the FDA to present our plans for the Phase II study in patients with AD in the first half of 2021. If those meetings and subsequent regulatory filings are successful, we plan to start treating patients in the Phase II trial in the second half of 2021.

XPro1595 Registration Studies and/or Partnering

We plan to aggressively pursue an efficient registration strategy using XPro1595 to improve the lives of patients with AD with biomarkers of inflammation. We believe AD is not the only indication for XPro1595 in neurodegenerative and neuropsychiatric diseases. We plan to pursue other indications in neurodegenerative diseases as resources become available. We have received NIMH funding to support a Phase II TRD program that hopes to start patient enrollment in the second half of 2021. We have an active partnering position as it relates to XPro1595 development in neurodegenerative and neuropshyciatric diseases, although no partnering discussion are underway at this time. There are two partnering opportunities with this novel immunotherapy for the treatment of neurologic and psychiatric diseases. The first is a traditional partnership focused on the developing the drug for all neurodegenerative and neuropsychiatric applications. The second is a more focused partnership developing XPro1595 as part of a combination therapy for a company’s existing therapy. After completion of proof-of-concept Phase II studies, we will decide what the most efficient registration strategy is available to the company with XPro1595. We may to have biopharma partners participate in this decision making. We may also seek to be acquired at this stage.

Immunotherapy for the treatment of NASH

LIVNate is being developed for the treatment of NASH. LIVNate is identical to INB03, Quellor and XPro1595 in every way but name. The name LIVNate will be used as the drug name in the NASH development program. NASH is a pleiotropic disease with elements of metabolic, immunologic and fibrotic pathophysiology contributing to disease development and progression. The Company believes targeting the metabolic and immunologic pathology is the best way to treat NASH. Furthermore, we believe there are three pathologic drivers of NASH, two which originate beyond the liver (refer to Figure 7 below). The peripheral pathologic loop includes obesity and insulin resistance. The regional pathologic loop includes intestinal inflammation, intestinal leak and mesenteric fat, a source of inflammatory factors that are concentrated in portal blood. Finally, the local pathologic loop is caused by lipotoxicity and innate immune activation in the liver that results in hepatocyte death, hepatitis and fibrosis, the hallmarks of NASH. In murine studies of NASH, LIVNate reverses insulin resistance, intestinal inflammation and decreases the NAS (“NAFLD Activity Score”) and Fibrosis score suggesting that LIVNate may be an effective therapy for the treatment of NASH.

We are planning an open label Phase II study of patients with NASH. The study is planned as a proof-of-concept study in patients with F3/F3 disease defined by non-invasive laboratory and imaging studies. Patients will be treated with LIVNate for 6 months by once a week subcutaneous injection. We do not plan to perform liver biopsies as any part of the study. If the study is positive, further development of LIVNate in NASH will be considered. Further development may include additional clinical trials alone or with a partner or divesting the program. This clinical trial has been delayed due to the COVID-19 pandemic. We do not expect to enroll patients into a NASH Phase II clinical trial until 2022 at the earliest.

LIVNate Registration Studies and/or Partnering Programs

Because NASH is an exceptionally dynamic area of drug development, the Company will decide on a development and/or partnering program after the completion of the Phase II study. At this time, it is impossible to predict the development and commercial landscape or to know if LIVNate can be used to treat NASH as a stand-alone drug or as part of combination therapy. Finally, the market for treatments of metabolic and inflammatory liver diseases may expand to include non-alcoholic fatty liver disease (“NAFLD”) in the near future. This market expansion may impact the Company’s development plans for LIVNate.

INKmune: Our NK cell Directed Product Candidate

INKmune is our lead product candidate that converts resting NK cells into primed NK cells, an essential step in them becoming activated cancer-killing NK cells. We have shown this works ex vivo in human tissue cell cultures, and we believe that this will work in vivo which is the purpose of our planned clinical trials.

Three step process to preparation for INKmune human clinical trials:

INKmune GMP scale-up for Phase I/II clinical material

The working cell banks and individual INKmune product to be used in the patients for the clinical trial have been produced at the Royal Free Hospital in the CCGTT to full cGMP (MHRA MIA(IMP)11149). All manufacturing has been under the direction of Professor Mark Lowdell. The Company can produce enough INKmune to complete both Phase I clinical trials in women with ovarian cancer and in patients with high-risk MDS. We have validated storage of INKmune for up to 12 months in vapor phase nitrogen and have a fully scalable, closed system manufacturing process which can produce up to 6 patient doses per week during phase I and II trials. At intermediate scale we can manufacture 40 doses per week in a single 80 liter bioreactor. Importantly, we have validated the storage of INKmune at -80oC for up to three months which greatly facilitates the delivery and local storage of the drug for clinical trials and post commercialization. In contrast, as far as we know all other NK cell therapies and T cell therapies require complex shipping of drug products in vapor phase nitrogen below -150^oC and specialized arrangements for ongoing storage at the clinical sites. We may need additional INKmune for future clinical trials.

INKmune Biomarker Development Program

We have discovered two biomarker strategies that we believe can be used to demonstrate: i) who should receive INKmune therapy; ii) if the INKmune therapy is working; and iii) when INKmune therapy should be repeated. For the initial Phase I/II trials in patients with ovarian cancer and high-risk MDS, we expect the biomarker testing will be performed in a single laboratory under our direction. In the near future, we will develop assay systems with standard operating procedures to ensure uniform testing of the biomarker across clinical sites. This will facilitate expansion of the clinical programs to multiple sites. We anticipate that, in the future, the biomarker program may be a surrogate marker for both clinical effectiveness and marketing purposes.

Interaction with Regulatory Authorities Regarding INKmune Development

The INKmune Phase I studies in high-risk MDS and ovarian cancer will be performed in the UK. We met with the Medicines and Healthcare Products Regulatory Agency (“MHRA”), the UK version of the FDA as part of a Scientific Advice Meetings in preparation for submitting the CTA for each program. The purpose of the meeting was to explain to the MHRA our manufacturing process and clinical plan for the development of INKmune in a Phase I relapse/refractory ovarian cancer and high risk MDS respectively.

INKmune Product Development Path Proposed Phase I Study in patients with ovarian cancer

Pending the evolution of the COVID-19 pandemic in 2021, we plan to initiate an open label Phase I cancer study in patients with ovarian carcinoma. Patients will be enrolled who have a low burden of relapse refractory disease and have peripheral blood or ascites NK cells which can respond to INKmune in a laboratory test on NK function. The study design agreed upon after discussion with the MHRA on September 12, 2017 was for a two-step Phase I/II study but this has been modified to an classic Phase I study followed by a randomized phase II. At present we anticipate the Phase I to be performed under the modified CTA at a single UK site, Sheffield University Hospital. We expect to initiate trial by the third quarter of 2021. In the Phase I trial, women with relapse refractory ovarian cancer will be treated with INKmune, given as an intra-peritoneal infusion through an indwelling peritoneal catheter in a traditional open label study to demonstrate safety and determine the dose of INKmune to be carried into the larger Phase II portion of the study. Based on pre-clinical studies that indicate that women with relapsed/refractory ovarian cancer have NK cells in their peritoneal cavity that response to INKmune to kill SKOV3, an NK-resistant ovarian cell line, we believe intra-peritoneal delivery of INKmune will be therapeutically effective. Three clinical trials support this observation. Two clinical trials have been performed using the first generation haplo-identical TpNK product in patients with AML. Both of those studies have been published (PLoS One. 2015 Jun 10;10(6):e0123416. doi: 10.1371/journal.pone.0123416. eCollection 2015) and (Biol Blood Marrow Transplant. 2018 Mar 26. pii: S1083-8791(18)30132-0. doi: 10.1016/j.bbmt.2018.03.019.). In summary, the studies showed that TpNK therapy, when delivered by intravenous infusion after conditioning therapy, was effective in providing prolong remissions with a toxicity profile that was manageable. TpNK therapy has not been delivered via intraperitoneal infusion, but a similar treatment strategy is used for the delivery of TALL-104 cells. TALL-104 is a replication incompetent human MHC non-restricted cytotoxic T-cell leukemic cell line that has been extensively studied and used to treat a number of cancers. Currently, Galileo Research, an Italian biotech company, has used TALL-104 in a Phase II clinical trial to treat women with ovarian cancer (http://www.galileoresearch.it/en/pipeline/TALL-104.html). In that study, TALL-104 is delivered via intraperitoneal infusion. Although the efficacy of the therapy is not yet known, the therapy is well tolerated with toxicities mainly related to the infusion catheter, not related to the TALL-104 infusion. The primary end points of the INKmune Phase I trial are safety and determining the dose of INKmune to take into the Phase II portion of the clinical trial. The key secondary efficacy end-points to be studied are i) increased NK cell priming as determined by multicolor flow cytometry of NK cells from the patient; ii) increased NK cell killing of SKOV3 tumor in a bioassay as shown in Figure 2 below; and iii) a decrease in tumor burden as measured by CA125 levels in the blood. Once safety and the optimal INKmune dose have been determined, a randomized study of women treated with INKmune will be compared to a group of control patients who receive only standard of care. We expect to treat six patients in the Phase I portion of the trial, but this number can increase by as many as 18.

INKmune Product Development Path Proposed Phase I Study in patients with high-risk MDS

During 2021, we plan to initiate an open label Phase I cancer study in patients with high-risk myelodysplastic syndrome (“MDS”). Patients will be enrolled who have a low burden of disease after completion of conventional therapy and have peripheral blood NK cells which can respond to INKmune in a laboratory test of NK function. At present we anticipate the Phase I to be performed at a single UK site, University Hospital Southampton. A UK contract research organization has been appointed and we expect to initiate trial by the third quarter of 2021. In the Phase I trial, patients with detectable residual disease in bone marrow and/or peripheral blood (<15% blasts by conventional tests) will be treated with intravenous infusions of INKmune and monitored for changes in peripheral blood NK activation, NK function and changes in residual blast counts in blood and bone marrow. We and others have previously shown that MDS patients with inadequate NK function have statistically significantly poorer prognosis than matched patients with normal levels of NK function (Tsirogianni et al 2019) and we have shown in laboratory experiments that the functional activity of NK cells from MDS patients can be enhanced by exposure to INKmune. Moreover, INKmune-primed NK cells are not inhibited by the hypoxic conditions of the diseased bone marrow microenvironment. Because both INKmune programs are being run in the UK, delays due to the COVID-19 pandemic may delay initiation of the clinical trial.

INKmune Registration Studies and/or Partnering

After completion of proof-of-concept Phase II studies with INKmune, we will decide whether to continue to develop INKmune as a treatment for ovarian carcinoma indication and/or high risk MDS. Other solid cancers are of interest including nasopharyngeal cancer (“NPC”) which is a known target for NK cells and an important unmet clinical need in emerging markets such as mainland China. We expect to have biopharma partners participate in this decision. We may also seek to be acquired at this stage or partner INKmune. Although our development strategy is focused on North America and Europe, we believe INKmune will also be attractive for markets on the Pacific Rim, South Asia and South America, but will wait for partners to help with the development in those regions, however, at this time, we are not negotiating with any potential partners.

Importantly, we have published data demonstrating INKmune efficacy at priming allogeneic NK cells ex-vivo (described above) and this includes priming of NK cells differentiated from cord-blood derived hematopoietic stem cells (Domogala et al Cytotherapy 2017: 19:710-720). Numerous companies are developing therapeutic strategies using cord blood derived NK cell products and one or more may wish to partner with us to potentiate their product by co-incubation or co-administration with INKmune.

INKmune Regulatory Strategy

INKmune is a new therapy for the treatment of cancer that will need to be proven safe and effective by well-designed clinical trials that show a meaningful clinical benefit to patients. We believe that registration trials will need to be designed as randomized trials in patients with cancer where one group of patients received INKmune and another receive best available care. We received advice from the MHRA on September 12, 2017 on the design clinical trial for ovarian cancer. And have used that advice to plan both current phase I trials. We plan to perform the Phase I trials with INKmune in the United Kingdom under two clinical trials authorizations (“CTA”) – one for each indication. If either phase I elicits “positive” data we plan to open one or more Phase II programs to additional sites in the United Kingdom and the US. We will meet with the FDA once we have data from the Phase I trials. Because there are no therapies similar to INKmune approved in any market, we plan to take advantage of the regulatory opportunities afforded to therapies that treat small markets with a high unmet need. In the U.S., this includes Orphan Drug Designation and expedited programs for approval including Accelerated Approval, Breakthrough Therapy Designation, Fast Track Designation, and priority review (see “Government Regulation”). We cannot predict which of these programs we will benefit from, if any at all, without further discussions with the FDA. Similar programs exist in the EU with the European Medicines Agencies (“EMA”).

Emerging Market Opportunity

The cancer therapy market is large, diverse and competitive. Although the concept of immunotherapy with monoclonal antibodies has been around for more than 20 years, the concept that patient derived immunosuppressive factors was a barrier to effective cancer treatment was recently recognized and had its first therapy approved just four years ago (ipilimumab, Yervoy, BMS, March 2011). Since then, five additional “check point” inhibitors have been approved, but the market is in its infancy. Most of the focus on strategies for modulating tumor-based immunosuppression focus is on the adaptive immune system (“T-cells”). The role of, and the importance of manipulating the innate immune system has more recently become a target of therapeutic development. NK cells are part of the innate immune system and are critical in both tumor surveillance (prevention) and treatment (killing). MDSCs are part of the innate immune system that only appear once the patient has chronic inflammation, a common occurrence in patients with cancer. The main role of the MDSC is to protect the tumor from attack by the patient’s immune system. Because T-cell focused strategies do not have an effect on the innate immune system, patient’s receiving such treatments may fail to recruit half of the patient’s immune system, the innate immune system, to attack the patient’s cancer. Clinicians increasingly recognize that durable responses to cancer require a coordinated attack by the patient’s adaptive and innate immune system. Normalizing the response of the innate immune system requires eliminating the dysregulated innate immune response that decreases the patient’s ability to see and attack the cancer as well as mechanisms the protect the cancer from immunologic attack (effector and protector function respectively). INKmune primes NK cells to enable them to attack the tumor. INB03, by decreasing the proliferation and function of MDSC, will lessen the immunosuppressive shield that protects the tumor from immunologic attack and, through NK/DC crosstalk, recruit the adaptive immune system to the fight.

Challenges in the Market for Our Product Candidates

The market for new oncology therapies is busy, complicated, and rapidly evolving. We will be competing with companies that are older, larger, better financed and have greater experience. There are two types of drug companies – development companies and commercial companies. Development companies take the risk of developing new products to proof-of-concept. Once proof-of-concept has been achieved, if the drug provides clinical benefit, the product is usually acquired by a commercial company, which completes the drug’s clinical development and markets the product. We are a development company which will seek to develop products such as INKmune from the bench to the bedside to demonstrate proof-of-concept. The goal for us is to successfully develop such products to the point where they are attractive targets for potential partners/acquirers.

According to a recent Markets and Markets report, the immunotherapy market is growing rapidly at an annual rate of over 13%. Recently, the market is biased towards T cell-based immunotherapies including bi-specific antibody therapies, checkpoint inhibitors and CAR-T cell-based therapies. There are substantial numbers of clinical trials that are focused on the adaptive immune system versus clinical trials that are focused on the innate immune system for the treatment of cancer. Our challenge will be to educate partners on the value of NK cell-based therapeutic strategies. The need to educate people of the importance of INB03 is equally challenging. At the academic level, there is recognition that therapies targeting MDSC are needed to improve the results of immunotherapies. Investors and potential partners are only now learning about MDSC. We will be responsible for educating them on the importance of MDSC and why INB03 may be an important addition to the oncologist’s armamentarium. We believe educating investors and partners about new therapeutic opportunities is an easier task than trying to differentiate our company from the many other cancer immunotherapy companies. We plan to use a combination of publication, presentation and investor relations to promote INKmune and INB03 and to educate the clinical, biopharma and investor community on the value of these novel therapeutic approaches.

DN-TNF Competition

To our knowledge, there are no other innate immune system check-point inhibitors in development that combine the characteristics of neutralizing soluble TNF, decreasing the population and function of MDSC while promoting NK/DC crosstalk that expands, decreases expression of MUC4 and recruits the adaptive immune response to attack the patient’s tumor. Lilly is developing LY3022855, a human IgG1 monoclonal antibody designed to target the CSF1R that should inhibit MDSC from receiving CSF1 signals, decreasing their survival and relieving the effect of MDSC in the tumor. Daiichi Sankyo Inc., in collaboration with Bristol Myers Squibb, is testing DS-8273a, a TRIAL-R2 agonistic antibody in combination with a PDL1 inhibitor to decrease the number of MDSC in patients with colorectal cancer. Rgenix Inc., is developing RGX-104, an orally bioavailable small molecule immunotherapy that targets LXR (liver X Receptor). RGX-104 reportedly depletes MDSC. Syntrix Biosystems is developing SX-682. SX-682 is a small-molecule dual-inhibitor of CXCR1 and CXCR2, the chemokine receptors pivotal to tumor metastasis, therapy-resistance, and myeloid cell suppression of cancer surveillance by the adaptive immune system. By blocking the CXCR1/2 pathway, SX-682 may prevent recruitment of MDSC to the tumor microenvironment. The University of Minnesota has a trivalent antibody program aimed at treating patients with advanced hematologic malignancies. This CD16/IL-15/CD33 (161533) Tri-Specific Killer Engagers (TriKes) product may target CD33+ MDSC. Siamab Therapeutics is developing an anti-sialyl-Tn monoclonal antibody that targets MDSC in some tumor types. Clathera Biosciences, in collaboration with Incyte, a US based biotech, is developing CB-1158 (INCB01158), an arginase inhibitor to decreases MDSC. A Phase II clinical trial is open that combines CB-1158 with nivolumab, an anti-PD1 CPI marketed by Bristol Myers Squib. Reata Pharmaceuticals is testing omaveloxolone (RTA 408) in the phase Ib/II REVEAL trial in combination with either ipilimumab (Yervoy) or nivolumab (Opdivoo) in patients with advanced unresectable or metastatic melanoma. Currently approved non-selective TNF inhibitors, infliximab, etanercept, adalimumab and others, are not considered direct competitors of INB03 in the treatment of cancer because of their mechanism of action and safety side effects. Non- selective TNF inhibitors block the function of both sTNF and tmTNF. Blockade of tmTNF is immunosuppressive increasing the risk of infection and cancer in patients. This is shown in Figure 3 below where maintaining function to tmTNF by genetic or pharmacologic means results in an immunocompetent animal that can protect itself against infection. Blockade or knock-out of both sTNF and tmTNF results in death from infection.

INKmune Competition

Our industry is highly competitive and subject to rapid and significant technological change. Our potential competitors include large pharmaceutical and biotechnology companies, specialty pharmaceutical and generic drug companies, academic institutions, government agencies and research institutions. We believe that key competitive factors that will affect the development and commercial success of our product candidates are efficacy, safety, tolerability, reliability, price, and reimbursement level. Many of our potential competitors, including many of the organizations named below, have substantially greater financial, technical, and human resources than we do and significantly greater experience in the discovery and development of product candidates, obtaining FDA and other regulatory approvals of products and the commercialization of those products. Accordingly, our competitors may be more successful than us in obtaining FDA approval for and achieving widespread market acceptance of their drugs. Our competitors’ drugs may be more effective, or more effectively marketed and sold, than any drug we may commercialize and may render our product candidates obsolete or non-competitive before we can recover the expenses of developing and commercializing any of our product candidates. We anticipate that we will face intense and increasing competition as new drugs enter the market and advanced technologies become available. Further, the development of new treatment methods for the conditions we are targeting could render our drugs non-competitive or obsolete.

INKmune is an immunotherapy that harnesses the biology of NK cells for the treatment of cancer. There is a long list of immunotherapy strategies for the treatment of cancer and the immunotherapy for cancer market is growing rapidly. There are at least three ways to classify immunotherapy for cancer. The list below classifies immunotherapy strategies beginning with those that are most closely related to INKmune:

We are not aware of any approved treatments that are classified as NK cell therapies. We are aware of public companies in the NK cell therapy business such as NantKwest, Nkarta, Fate Therapeutics and Glycostem. These companies are developing products that involve replacing or supplementing NK cells of the patient for the treatment cancer. Their product requires extensive ex-vivo cell manipulations which, with respect to NantKwest and Fate Therapeutics, may include gene therapy. The next larger group of companies are in the personalized immuno-oncology business with products focused on T cell activation strategies. The most popular are the CAR-T cell therapies which are a patient specific ex-vivo gene therapy approach to a single disease (for example: pediatric ALL). CAR-T therapy has become wildly popular of late and includes many private companies, newer public companies such as Bluebird, Juno Therapeutics and Mustang Bio as well as established companies such as Novartis and Gilead. For many of the companies, CAR-T cell therapies is their only business. For the latter two, CAR-T cell therapies is a newly in-licensed program with marketing authorization in the US. Finally, the precision immune-oncology category also includes companies with anti-cancer antibody products and the newer “check-point” inhibitors. Antibody therapies are all about “illuminating” the cancer to the innate immune system (NK cells). Monoclonal antibodies were the original immunotherapy that drove the growth of well-known biopharma companies including Genentech/Roche, Amgen, Merck and others. Each of these products is disease specific (ie: treat only HER2+ breast cancer). Modern therapeutic antibodies are much more complicated bi-specific and tri-specific antibodies that attempt to connect the cancer with activated T-cells of the adaptive immune system. Check-point inhibitors are currently the most rapidly expanding product category in immuno-oncology. These CTLA-4 (ipilimumab) and PD-1 inhibitors (pembrolizumab and nivolumab) specifically block a mechanism that shields cancers from T-cell killing. The two companies in this business are Merck (pembrolizumab) and GSK (ipilimumab and nivolumab). There are many others trying to join this promising therapeutic area including large companies such as BMS and Roche.

There are several FDA approved drugs that improve the ability of the innate immune system (NK-cells) to treat cancer including mono-clonal antibody therapies (for example: Rituximab®; Avastin® and Herceptin® marketed by Roche/Genentech); and “check-point” inhibitors (Yervoy® and Opdivo®, BMS, Keytruda®, Merck and others). There is a large amount of development activity in the immune checkpoint inhibitor field from both pharmaceutical giants including AstraZeneca, Merck & Co, Pfizer, Merck KGaA, Roche, GSK, Novartis and Amgen and many start-ups, small companies and university spin-offs which have emerged in the past two years. Examples (in alphabetical order) include Agenus, Alligator Bioscience, Ambrx, AnaptysBio, argenx, Bioceros, BioNovion, Cellerant Therapeutics, Checkpoint Therapeutics, Compugen, CureTech, Enumeral, Five Prime Therapeutics, Genmab, GITR, ImmuNext, IOmet Pharma, iTeos Therapeutics, Jounce Therapeutics, KAHR Medical, Multimeric Biotherapeutics, Nativis, Orega Biotech, Pelican Therapeutics, Pieris Pharmaceuticals, Prima BioMed, Redx Pharma, Sorrento Therapeutics, Tesaro, TG Therapeutics, Theravectys and ToleroTech active in the field. The list of companies with poly-specific antibodies that attempt to link the cancer with a cytotoxic T cell is long, includes both private and public companies (Amgen, Xencor, F-Star, Merus and many others). Finally, two CAR-T cell therapies were just approved for the treatment of ALL – Kymriah™ (Novartis) and Yescarta™ (Gilead). We expect additional drugs to gain marketing authorization in the immune-oncology space.

To our knowledge, there are no innate immune check-point inhibitors in development that have the unique characteristics of INB03 that neutralize sTNF to: i) decreases the proliferation of MDSC; ii) decreasing local and systemic immunosuppression caused by MDSC by stopping production of immunosuppressive cytokines and; iii) improving NK/DC cross-talk to recruit the adaptive immune system to fight the cancer.

Intellectual Property

We seek to protect our therapeutic programs by continuously developing patent properties covering novel compositions, formulations, purpose-limited compositions, combination treatments, methods of medical treatment, and other inventions in the United States Patent & Trademark Office (the “USPTO”), the World Intellectual Property Organization (“WIPO”) under the Patent Cooperation Treaty (“PCT”), and in patent offices for various foreign jurisdictions. While each invention is unique and territories for protection are decided on a case by case basis, we generally pursue patents in Australia, Canada, Europe, Japan, and the United States, and sometimes in Brazil, China and/or Korea. The following sections and corresponding tables summarize, for each of our current therapeutic programs, our pending and granted patent positions, to the extent publicly available, as of the time of preparing this document:

DN-TNF Platform Technology (Cancer, Neurologic Diseases, Metabolic Diseases, COVID-19)

The DN-TNF Platform Technology covers a variety of dominant negative tumor necrosis factor (“DN-TNF”) variant proteins, including the pegylated DN-TNF protein variants known as XPro1595, INB03, LIVNate, and Quellor. These DN-TNF protein variants can be considered a platform technology for treating the underlying immune dysfunction associated with many disease manifestations. The following table summarizes current IP covering our DN-TNF Platform Technology:

XPro1595 (Neurologic Diseases)

The patent suite for XPro1595 includes the DN-TNF patents (above) and other patents and patent applications directed to methods of treatment of disease. This patent suite continues to expand with active prosecution on use of XPro1595 (a DN-TNF variant) in neurologic diseases. The following table summarizes current IP expanding our DN-TNF Platform Technology for CNS-related methods of treatment:

INB03 (Oncology)

The patent suite for INB03 includes the DN-TNF patents (above) and other patents and patent applications directed to methods of treatment of disease. This patent suite continues to expand with active prosecution on use of INB03 (a DN-TNF variant) in oncology. The following table summarizes current IP expanding our DN-TNF Platform Technology for oncology-related methods of treatment:

LIVNate (Metabolic Diseases)

The patent suite for LIVNate includes the DN-TNF patents (above) and other patents and patent applications directed to methods of treatment of disease. This patent suite continues to expand with active prosecution on use of LIVNate (a DN-TNF variant) for treating metabolic diseases. The following table summarizes current IP expanding our DN-TNF Platform Technology for metabolic disease -related methods of treatment:

Quellor (CRS and COVID-19)

The patent suite for Quellor includes the DN-TNF patents (above) and other patents and patent applications directed to methods of treatment of disease. This patent suite continues to expand with active prosecution on use of Quellor (a DN-TNF variant) for treating cytokine release syndrome (CRS) and complications of COVID-19. We have two patent properties pending as of the date of this document.

INKmune (Oncology)

The INKmune program is directed to compositions and methods of treating cancer. INKmune comprises cells and/or membrane portions of cells derived from a cancer cell line expressing a unique biological signature (that is often downregulated in many cancers), which cells/membrane portions are inactivated to prevent proliferation, and which are administered to a patient. Once administered, the inactivated cells/membranes (INKmune) are presented in vivo to the patient’s own resting NK cells, thereby providing the unique biological signature, and resulting in what we call “NK cell priming,” that is, the change of a resting NK cell to a non-naturally occurring state, or “primed NK cell,” wherein the primed NK cell has received the signals often downregulated by cancer cells. Now having the often-downregulated signals, a primed NK cell can subsequently contact, adhere and commence killing of the patient’s cancer cells. The following table summarizes current IP covering INKmune:

Our commercial success depends in part on obtaining and maintaining patent protection and trade secret protection of our current and future product candidates and the methods used to manufacture them, as well as successfully defending these patents against third-party challenges. Our ability to stop third parties from making, using, selling, offering to sell or importing our products depends on the extent to which we have rights under valid and enforceable patents or trade secrets that cover these activities. We cannot assure you that our pending patent applications will result in issued patents.

International PCT patent applications cover all 152 nations which are signatories of the PCT. However, our IP strategy generally recognizes the United States, United Kingdom, European Union, Canada, Japan, Australia and China as targets for extending patent protection under the PCT. Decisions regarding which countries to extend patent coverage under the PCT is taken on a case by case basis, subject to normal business considerations such as value and return on investment.

Each of the above-identified patents and patent applications is subject to change based on strategic patent portfolio building decisions, which may include refiling and reissue, certain abandonments, including those in favor of continuing patent applications, maturations from provisional to non-provisional filings, and other regular patent prosecution activities.

Trademarks

The following table summarizes trademark applications and registrations used or intended for use in connection with products in our pipeline:

Each of the above-identified trademark applications is subject to change as the trademark portfolio develops and we begin to perfect these registrations with actual use after receiving marketing authorization.

Immune Ventures, LLC License Agreement

On October 29, 2015, the Company entered into an exclusive license agreement (the “INKmune License Agreement”) with Immune Ventures, LLC (“Immune Ventures”). Pursuant to the INKmune License Agreement, we were granted exclusive worldwide, sub-licensable, royalty-bearing licenses (collectively “Patent Rights”) as well as all applications (the “Field”) of the Patent Rights, including rights to incorporate any improvements or additions to the patents that may be developed in the future to the following patents and patent applications:

Patent Applications: 

Patents:

In consideration for the Patent Rights, we agreed to the following milestone payments (of which none have been incurred as of December 31, 2020):

In addition, we agreed to pay the licensor a royalty of 1% of net sales during the life of each patent granted to us. The Licensor is owned by Raymond J. Tesi, our President and a member of our Board of Directors, David Moss, our Chief Financial Officer and Treasurer and Mark Lowdell, our Chief Scientific Officer. In countries where a claim of an issued and unexpired patent or a pending claim in a pending patent application within the Patent Rights exists a royalty of nine percent of net sales of each of each licensed product shall be paid for the remaining life of each patent on a country by country basis.

The term of the agreement began on October 29, 2015 and, if not terminated sooner pursuant to the agreement, ends on a country-by-country basis on the date of the expiration of the last to expire patent rights where patent rights exists. Upon the termination of the agreement we shall have a fully paid up, perpetual, royalty-free license without further obligation to Immune Ventures. The agreement can be terminated by Immune Ventures if, after 60 days from the Company’s receipt of notice that the Company has not made a payment under the agreement, and the Company still does not make this payment. On July 20, 2018, the parties amended the agreement under which the Company was required achieve milestones pursuant to the agreement. On October 30, 2020, the parties executed an additional amendment to the agreement under which the Company is required to achieve the following milestones:

Initiation of Phase 1 clinical or equivalent trials by October 29, 2021

Initiation of Phase II clinical trials or equivalent by October 29, 2023

Initiation of Phase III clinical trials or equivalent by October 29, 2025

Filing of NDA or equivalent by October 29, 2026 or equivalent

If the Company doesn’t achieve the above milestones, it is required to negotiate in good faith with Immune Ventures to determine how it can either remedy the failure or achieve an alternate development. If the Company fails to make any required efforts, or if the efforts do not remedy the situation within 60 days of written notice by Immune Ventures, then Immune Ventures may provide notice to terminate the license or convert it to a non-exclusive license.

University of Pittsburg License Agreement

On October 3, 2017, the Company entered into an Assignment and Assumption Agreement with Immune Ventures related to intellectual property licensed from the University of Pittsburgh. Pursuant to the Assignment and Assumption Agreement (the “Assignment Agreement”), Immune Ventures assigned all of its rights, obligations and liabilities under an Exclusive License Agreement between the University of Pittsburgh – Of the Commonwealth System of Higher Education (“Licensor”) and Immune Ventures to INmune Bio (“Licensee”), (the “PITT Agreement”).

Consideration under the PITT Agreement includes: (i) annual maintenance fees, (ii) royalty payments based on the sale of products making use of the licensed technology, and (iii) milestone payments.

Annual maintenance fees under the PITT Agreement include: $5,000 due June 26 of each year 2020-2022; $10,000 due on June 26 of each year 2023-2024; and $25,000 due on June 26 of each year 2025 and annually thereafter until first commercial sale. As of December 31, 2020, the Company has no amounts owed pursuant to the PITT Agreement. The Company is current on its annual maintenance fees pursuant to the PITT Agreement.

Upon first commercial sale of a product making use of the licensed technology under the PITT Agreement, the Licensee is required to pay royalties equal to 2.5% of Net Sales each calendar quarter.

Moreover, under the PITT Agreement the Licensee is required to make milestone payments as follows:

The Company made a $50,000 milestone payment to the University of Pittsburgh in March 2019 as a result of the initiation of a Phase I clinical trial. The PITT Agreement expires upon the earlier of: (i) expiration of the last claim of the Patent Rights forming the subject matter of the PITT Agreement; or (ii) the date that is 20 years from the effective date of the agreement (June 26, 2037).

The Company may terminate the PITT Agreement upon 3 months prior written notice provided all payments under the license are current. Licensor may terminate the PITT Agreement upon written notice if: (i) the Company defaults as to performance of material obligations which have not been cured within 60 days after receiving written notice; or (ii) the Company ceases to carry out its business, becomes bankrupt or insolvent, applies for or consents to the appointment of a trustee, receiver or liquidator of its assets or seeks relief under any law for the aid of debtors.

Xencor License Agreement

On October 3, 2017, the Company entered into a license agreement with Xencor, Inc. (“Xencor”), which has discovered and developed a proprietary biological molecule that inhibits soluble tumor necrosis factor (the “Xencor Agreement”). Pursuant to the Xencor Agreement, Xencor granted the Company an exclusive worldwide, royalty-bearing license in licensed patent rights, licensed know-how and licensed materials (as defined in the Xencor Agreement) to make, develop, use, sell and import any pharmaceutical product that comprises, contains, or incorporates Xencor’s proprietary protein known as “XPro1595” that inhibits soluble tumor necrosis factor (or all modifications, formulations and variants of the licensed protein that specifically bind soluble tumor necrosis factor) alone or in combination with one or more active ingredients, in any dosage or formulation. In connection with the Xencor Agreement, we paid Xencor a one-time non-creditable and non-refundable fee of $100,000 and agreed to issue Xencor 1,585,000 shares of our common stock. We also issued warrants to Xencor which are discussed below.

We also agreed to pay Xencor a royalty of 5% on net sales of all Licensed Products in a given calendar year, which are payable on a country-by- country and licensed product by licensed product basis until the date that is the later of (a) the expiration of the last to expire valid claim covering any pharmaceutical product that contains, comprises, or incorporates Xencor’s proprietary protein known as XPro1595 alone or in combination with one or more active ingredients, in any dosage or formulation. (“Licensed Product”) in such country or (b) ten years following the first sale to a third party of the licensed product in such country. Net Sales with respect to any Licensed Product is the gross amounts invoiced by us for sales of the Licensed Products less deductions actually incurred.

Under the Xencor Agreement, we also agreed to pay Xencor a percentage of any sublicensing revenue that it receives equal to (i) 60% of sublicensing revenue received in respect of any sublicense granted prior to initiation of a Phase 1 Clinical Trial of a Licensed Product in the applications for the treatment of disease in humans (the “Field”); (ii) 30% of Sublicensing Revenue received in respect of any sublicense granted on or after initiation of a Phase 1 Clinical Trial of a Licensed Product in the Field and prior to initiation of a Phase 2 Clinical Trial of a Licensed Product in the Field; (iii) 15% of Sublicensing Revenue received in respect of any sublicense granted on or after initiation of a Phase 2 Clinical Trial of a Licensed Product in the Field and prior to initiation of a Phase 3 Clinical Trial of a Licensed Product in the Field; (iv) 10% of Sublicensing Revenue received in respect of any sublicense granted on or after initiation of a Phase 3 Clinical Trial of a Licensed Product in the Field and prior filing of the first NDA application for any Licensed Product in the Field; and (v) 5% of Sublicensing Revenue received in respect of any sublicense granted on or after the approval of the first NDA application for any Licensed Product in the Field. For clarity, initiation of a clinical trial shall mean dosing of a first patient in said clinical trial.

A valid claim is an issued, unexpired or pending claim with the patent rights that Xencor controls as of October 3, 2017 which patent rights are necessary to make, develop, use, sell, have sold, offer for sale and import a Licensed Product in the Field (the Field means all applications for the treatment of diseases in humans) or the Product Patent Rights, which claim has not lapsed, been abandoned, been revoked or been held to be unpatentable, invalid or unenforceable by a final judgment of a court or other governmental agency or competent jurisdiction from which no appeal can be or is taken within the time allowed for appeal and which has not been admitted to be invalid or unenforceable through reissue, re-examination, disclaimer or otherwise. Product Patent Rights shall mean any and all our patent rights that are necessary to make, develop, use, sell, have sold, offer for sale and import a Licensed Product in the Field, including any improvements or patent rights directed to the Licensed Product. Either party may terminate the Xencor Agreement upon 60 days’ (10 days for any payment default) prior written notice to the other party after the breach of any material provision of the agreement by the other party if the breaching party has not cured the breach within the 60-day period (10-day period for any payment default) following written notice of termination by the non-breaching party. We can terminate the Xencor Agreement upon 180 days prior written notice to Xencor. Xencor may terminate the Xencor Agreement in its entirety or with respect to any specific Licensed Product upon written notice in the event that we contest, oppose or challenge or assist any party in contesting, opposing or challenging, Xencor’s ownership of, or the enforceability or validity of the Patent Rights that Xencor controls as of October 3, 2017 which Patent Rights are necessary to make develop, use, sell, have sold, offered for sale and import a Licensed Product in the Field. Either party may terminate the Xencor Agreement upon written notice to the other party upon or after the insolvency, bankruptcy, dissolution or winding up of such other party or the making or seeking to make or arrange an assignment for the benefit of creditors of such other party or the initiation of proceedings in voluntary or involuntary bankruptcy which proceeding or action remains undismissed or unstayed for a period of more than 60 days.

In connection with the Xencor Agreement, we entered into a stock issuance agreement with Xencor pursuant to which it agreed to issue Xencor 1,585,000 shares of its common stock and fully vested warrants to purchase an additional number of shares of common stock equal to 10% our the fully diluted company shares immediately following such purchase. In August 2018, we entered into a First Amendment to Stock Issuance Agreement. Pursuant to the amendment, the purchase price for the additional shares may only be paid by cash.

University College London License Agreement – MSC

On July 19, 2019, the Company entered into license agreement with UCL Business PLC (“UCLB”) with a ten-year term. Pursuant to the license agreement, the Company acquired an exclusive license (and a right to sub-license) to the technology and know-how relating to an isolation and commercial scale expansion methodology of GMP grade human umbilical cord mesenchymal stem/stromal cells (“MSC”).

In exchange for the license agreement, the Company paid UCLB an initial license fee of approximately $10,000 and shall pay annual licensing fees of approximately $13,000 per year for the remaining term of the agreement beginning in July 2020. The Company will pay UCLB a royalty of 3-3.5% of the net sales value (as defined in the agreement) of all licensed products sold or used by the Company. As of December 31, 2020, no amounts are owed to UCLB pursuant to this license agreement. In the event the Company sub-licenses the technology and know-how, the Company will pay UCLB a royalty of 12 percent of the consideration (cash or non-cash) received by the Company in relation to the development or sub-licensing of any of the technology and know-how.

INKmune Research and Development

We expect to use third parties to conduct our preclinical and clinical trials under the direct supervision of management.

INKmune Manufacturing

We intend to contract with third parties for the manufacture of our compounds for investigational purposes, for preclinical and clinical testing and for any FDA approved products for commercial sale. Pre-clinical and clinical material for the early clinical trials with INKmune has been manufactured under the direction of Mark Lowdell at a licensed Good Manufacturing Practice (“GMP”) facility. The master cell bank, working cell bank and individual product doses were completed in July 2018. This clinical material is planned for use in the Phase I/II clinical trials in ovarian cancer. If we raise adequate capital to initiate the high-risk MDS Phase I/II trials, additional working cell banks and therapeutic product will be produced from the existing master cell bank. This process takes approximately 6 months and is not anticipated to delay the initiation of the high-risk MDS Phase I/II trials. We may transfer the manufacturing to a different commercial contract manufacturing organization after completion of these Phase II studies.

Human Mesenchymal Stem Cells

In November 2017, we entered into a Material Transfer and License Agreement with the Anthony Nolan Cord Blood Bank (“AN”), the oldest and largest non-directed cord blood bank in the United Kingdom for the supply the starting material for the mesenchymal stem cells - umbilical cords not used after cord blood harvest. Mark Lowdell’s research group developed and validated a methodology for producing large numbers of clinical-grade pooled human umbilical cord derived mesenchymal stem cells (“HucMSC”). We believe the reproducible and reliable supply of large quantities of high-quality a may solve one of the major problems associated with the development of mesenchymal stem cell therapies for medicine. Under this agreement we were granted a license to produce and sell these cells for medical research, including clinical trials. The agreement provides that Immune Bio Internal shall pay to AN £200 plus VAT (if applicable) for each umbilical cord tissue sample (and any intellectual property, developed, or conceived by Immune Bio International in exercising its rights under the agreement (“Licensed Product”)) Immune Bio International receives pursuant to the agreement. Additionally, during the entire term of the agreement, Immune Bio International shall pay AN a royalty of 2% of the net sales of the Licensed Product. We believe we are well positioned to become a preferred manufacturing partner for companies who need MSC for clinical programs. Manufacture of HucMSC is performed under the direction of Mark Lowdell in a licensed GMP facility that is contracted to the Company as part of existing research and development agreements. The starting material for the HucMSC product is provided by the AN. The HucMSC product produced in this facility are fully qualified to be used for either research or clinical trials. Currently, we plan to supply HucMSC to third parties for their research use and in clinical trials as part of the development process for commercial pro/ducts. We may decide to expand this agreement in the future if the commercial and/or development opportunities warrant such expansion. At the current time, we expect this program to be funded by revenues from commercial sales. The agreement with AN terminates on November 29, 2027. AN may terminate the license on written notice to us, if a donor withdraws consent to the continued use of umbilical cord tissue samples that were obtained by AN. Additionally, either party may terminate the agreement on 30 days prior written notice to the other if that other party materially breach any term of the agreement and such breaches (to the extent it is remediable) is not remedied within 30 days of the written request to the other party to do so.

Challenges in the Market for Immunotherapy Products

Government Regulation

The FDA and other federal, state, local and foreign regulatory agencies impose substantial requirements upon the clinical development, approval, labeling, manufacture, marketing, and distribution of drug products. These agencies regulate, among other things, research and development activities and the testing, approval, manufacture, quality control, safety, effectiveness, labeling, storage, record keeping, advertising and promotion of our product candidates. The regulatory approval process is generally lengthy and expensive, with no guarantee of a positive result. Moreover, failure to comply with applicable FDA or other requirements may result in civil or criminal penalties, recall or seizure of products, injunctive relief including partial or total suspension of production, or withdrawal of a product from the market.

Various regulatory authorities regulate, among other things, the research, manufacture, promotion, and distribution of drugs in the United States under the FDA and other statutes and implementing regulations. The process required by the FDA before prescription drug product candidates may be marketed in the United States generally involves the following:

The testing and approval process requires substantial time, effort and financial resources, and we cannot be certain that any approvals for our product candidates will be granted on a timely basis, if at all.

Preclinical tests include laboratory evaluations of product chemistry, formulation and stability, as well as studies to evaluate toxicity in animals and other animal studies. The results of preclinical tests, together with manufacturing information and analytical data, are submitted as part of an IND to the FDA. Some preclinical testing may continue even after an IND is submitted. The IND also includes one or more protocols for the initial clinical trial or trials and an investigator’s brochure. An IND automatically becomes effective 30 days after receipt by the FDA, unless the FDA, within the 30-day time period, raises concerns or questions relating to the proposed clinical trials as outlined in the IND and places the clinical trial on a clinical hold. In such cases, the IND sponsor and the FDA must resolve any outstanding concerns or questions before any clinical trials can begin. Clinical trial holds also may be imposed at any time before or during studies due to safety concerns or non-compliance with regulatory requirements. An independent institutional review board, or IRB, at each of the clinical centers proposing to conduct the clinical trial must review and approve the plan for any clinical trial before it commences at that center. An IRB considers, among other things, whether the risks to individuals participating in the trials are minimized and are reasonable in relation to anticipated benefits. The IRB also approves the consent form signed by the trial participants and must monitor the study until completed.

The FDA offers several regulatory mechanisms that provide expedited or accelerated approval procedures for selected drugs in the indications on which we are focusing our efforts. These include accelerated approval under Subpart H of the agency’s NDA approval regulations, fast track drug development procedures and priority review.

We plan to seek orphan drug designation for INKmune for the treatment of ovarian carcinoma. The United States, European Union and other jurisdictions may grant orphan drug designation to drugs intended to treat a “rare disease or condition,” which, in the United States, is generally a disease or condition that affects no more than 200,000 individuals. In the European Union, orphan drug designation can be granted if: the disease is life threatening or chronically debilitating and affects no more than 50 in 100,000 persons in the European Union; without incentive it is unlikely that the drug would generate sufficient return to justify the necessary investment; and no satisfactory method of treatment for the condition exists or, if it does, the new drug will provide a significant benefit to those affected by the condition. If a product that has an orphan drug designation subsequently receives the first regulatory approval for the indication for which it has such designation, the product is entitled to orphan exclusivity, meaning that the applicable regulatory authority may not approve any other applications to market the same drug for the same indication, except in limited circumstances, for a period of seven years in the United States and 10 years in the European Union Orphan drug designation does not prevent competitors from developing or marketing different drugs for the same indication or the same drug for different indications. Orphan drug designation must be requested before submitting an NDA. After orphan drug designation is granted, the identity of the therapeutic agent and its potential orphan use are publicly disclosed. Orphan drug designation does not convey an advantage in, or shorten the duration of, the review and approval process. However, this designation provides an exemption from marketing and authorization (NDA) fees. We plan to follow a similar path with INB03, although the precise indication cannot be determined until we are farther along in the development process.

Clinical Trials

Phase 1 clinical trials typically involve the initial introduction of the product candidate into healthy human volunteers. In Phase 1 clinical trials, the product candidate is typically tested for safety, dosage tolerance, absorption, metabolism, distribution, excretion and pharmacodynamics.

Phase 2 clinical trials are conducted in a limited patient population to gather evidence about the efficacy of the product candidate for specific, targeted indications; to determine dosage tolerance and optimal dosage; and to identify possible adverse effects and safety risks.

Phase 3 clinical trials are undertaken to evaluate clinical efficacy and to test for safety in an expanded patient population at geographically dispersed clinical trial sites. The size of Phase 3 clinical trials depends upon clinical and statistical considerations for the product candidate and disease, but sometimes can include several thousand patients. Phase 3 clinical trials are intended to establish the overall risk-benefit ratio of the product candidate and provide an adequate basis for product labeling.

Clinical trials involve the administration of the product candidate to human subjects under the supervision of qualified medical investigators according to approved protocols that detail the objectives of the study, dosing procedures, subject selection and exclusion criteria, and the parameters to be used to monitor participant safety. Regulatory procedures differ in each country we will be working in., For example, in the US, each protocol is submitted, to the FDA as part of the IND for their review and consent before enrolling patients in the clinical trial. The US is not the only place to perform clinical trials. Most countries have systems in place to allow academics and companies to sponsor clinical trials of novel therapies in patients. For financial and technical reasons, the Company will perform the Phase I clinical trials of our programs in the United Kingdom and Australia. The US will be included in the Phase II programs. Other venues such as Europe, Canada, Japan and other Pacific Rim countries may be included in the development program in the future. The first clinical trial with INKmune will be initiated in the United Kingdom. In the United Kingdom, the regulatory submission is made to the MHRA for a clinical trials authorization (“CTA”). This is a multistep process. The Company had a Scientific Advice meeting with the MHRA in September 2017 to discuss the INKmune Phase I/II trial in women with relapse/refractory ovarian cancer including trial design, manufacturing processes and clinical trial execution. The MHRA gave recommendations on trial design, manufacturing controls and the regulatory procedures needed to initiate the clinical trial. We received CTA approval from the MHRA for an INKmune trial in ovarian cancer on December 18, 2018. The approval allows for the execution of the Phase I/II INKmune clinical trial in the United Kingdom. We plan to have two cancer clinics referring the 6 patients needed for the Phase I portion of the trial. The patients will be treated at the Phase I unit a university hospital. We expect all of the Phase I sites to be in London, United Kingdom. If the Phase I trial proceeds as planned, we expect to open the Phase II portion of the trial in early 2020. The Phase II trial will include at least 3 other clinical sites in the United Kingdom and may include clinical sites in the US. Because 30 patients will be required to complete the Phase II portion of the trial, we expect to need sites in both the US and United Kingdom. The additional clinical sites in the United Kingdom or US have not been identified at this time. No additional regulatory procedures will be needed to add sites in the United Kingdom. To add sites in the US, we will need to file an IND with the FDA. Once the FDA approves the IND, clinical sites can be opened. We have chosen relapsed/refractory ovarian cancer as the anticipated Phase 1 study for INKmune for a number of reasons. Relapsed refractory is a disease with poor treatment options. Our pre-clinical data suggests INKmune may have advantages over other immunotherapies in the treatment of ovarian cancer. Ovarian cancer has a sensitive and validated biomarker to measure disease burden – CA125. This allows the Company to accurately select patients for the clinical trial and determine if INKmune therapy is effective. We believe that intraperitoneal delivery of INKmune is a low-risk delivery strategy for a phase 1 study. The patients we plan to enroll in the trial have their disease concentrated in the peritoneal cavity further supporting the use of intra-peritoneal delivery. Finally, relapsed refractory ovarian cancer is an Orphan indication in the US. This provides regulatory advantages for registration of INKmune. INB03 will follow a similar development strategy, but will use Australia for the Phase I programs. In Australia, clinical trials for INB03 are performed under the clinical trials notification (“CTN”) scheme authorized by the Therapeutic Good Administration (“TGA”). The TGA is the equivalent agency to the FDA in the US and the MHRA in the United Kingdom. We filed an Australian Clinical Trial Notification, or CTN, for INB03 and XPro1595 during the second quarter of 2018 and 2019 respectively. Applications were accepted in May 2018 and 2019 to allow us to initiate the Phase I trials in cancer and Alzheimer’s disease respectively. We have completed the oncology Phase 1 open label dose escalation trial in patients with advanced solid tumors and biomarkers of inflammation in their blood.

The Phase I trial has been completed and provided evidence of safety and a pharmacodynamic drug affect, decrease of inflammatory biomarkers, needed to move the program to a Phase II clinical trial in cancer. The Phase II clinical trial that will combine INB03 with approved second line therapy in patients with brain metastasis in women with Her2+ breast cancer. This is a combination trial where the addition of INB03 to approved second line therapy may provide a therapeutic alternative in a disease without any drugs approved. The Company has not lost interest in combining INB03 with CPI, but competition for patients is fierce in this arena. Our plan is to pursue treatment of tumors that express MUC4 as our lead indication. Tumors that express MUC4 are resistant to all forms of immunotherapy due to a combination of increased MDSC in the tumor, decreased inflammation in the tumor (a “cold” tumor) and direct effects of MUC4 and soluble TNF on HER2 function. If combination therapy with INB03 decreases MUC4 expression and changes the TME to make the “cold” tumor “hot”, then addition of a CPI will be warranted. Checkpoint inhibitors are immunotherapy drugs that target proteins in the tumor and immune cells to improve the adaptive immune response to the tumor by reversing immunologic strategies the cancer uses to evade the immune system. These drugs target PD1, PDL-1 or CTLA-4. As of April 2018, there are six checkpoint inhibitors approved in the US (Ipilimumab, Atezolizumab, Avelumab, Durvalumab, Pembrolizumab, and Nivolumab). Additional checkpoint inhibitors to new and existing targets are in development and will be approved in the coming years. Checkpoint inhibitors are having a significant impact on the treatment of cancer and are expected to be the largest selling class of cancer therapies by 2027. INB03 can impact the cancer market for CPI in two ways; i) increase the number of patients eligible for CPI by making “cold” tumors “hot” and ii) reverse resistance to CPI due to immunologic factors in the TME such as increased MDSC. Currently, only 25-30% of patients treated with currently approved checkpoint inhibitors respond to therapy and many of these become refractory after a period of treatment. This means at least 70% of patients are resistant to, or refractory to, checkpoint inhibitors. Experts agree that combination therapy is needed and necessary to improve the response to checkpoint inhibitor therapy in resistant and refractory patients. To that end, companies with approved checkpoint inhibitors are looking for companion drugs improve patient response and expand market opportunities. The INB03 development program in cancer is designed to take advantage of our pre-clinical data and the needs to the cancer community to improve the safety and efficacy of checkpoint inhibitors. At this time, the combination trial to treat trastuzumab resistant HER2+ expressing cancer is our lead registration strategy for INB03. Current therapies for trastuzumab resistant cancers are used on a trial by error approach. Using MUC4 expression as a biomarker for to predict trastuzumab resistance brings a precision medicine approach to this difficult clinical scenario. Addition of INB03 to the treatment regimen for treating HER2+ cancers may convert “cold” tumors to “hot” tumors making the eligible for treatment with CPI. Finally, the clinical development landscape for CPI combination therapies to treat CPI resistant therapies is chaotic. The design and successful completion of a Phase II trial is not guarantee of clinical relevance or commercial viability. There are multiple therapies on the market or in development for the treatment of trastuzumab resistant breast cancer. The most prominent of antibody conjugates including ado-trastuzumab emtansine (Kadycycla/T-DM1, Genentech/Roche) and trastuzumab deruxtecan (Enhertu, Daiichi Sankyo). To our knowledge, there are no drugs approved for the treatment of patients with HER2+ brain metastasis. CPI are not active in HER2+ cancers but there is considerable interest in attempting to modify the TME to allow effective use of CPI in patients with advanced disease. Checkpoint inhibitor companies announced large partnering deal with companies producing checkpoint inhibitor potentiators – BMS/Nektar; BMS/IFM and Merck/Incyte. Experts agree that partnering in this arena will continue. The registration and development strategy for INB03 is multinational. The Phase II program may enroll patients in other countries, including the United States after submitting an Investigational New Drug application, or IND, to the U.S. Food and Drug Administration, or FDA. If partnering is successful at any stage of INB03 development, we expect the partner to influence the development and regulatory decisions needed with moving the drug to commercialization. Finally, combination therapy to treat patients resistant to trastuzumab or CPI are not the only oncology application for INB03. INB03 can be combined with other immune-oncology therapy to improve efficacy, safety or both. INB03 can be used as part of combination therapy with immuno-oncology drugs, paired with tradition therapies such as cytotoxic chemotherapy, kinase inhibitors, cell therapies or radiation therapy. The company is pursuing pre-clinical data in some of these areas. When and if positive developments occur, we will communicate them to our shareholders. There are other regulatory venues that will be important for both our products – the largest and most important is Europe. In Europe, the European Medicines Agencies (“EMA”) is responsible for authorization of clinical trials in member states. In EU, there may be a requirement to get individual country authorization at the same time as EMA authorization. The initial development of INB03. XPro1595 and LIVNate will occur in AUS followed by trials in the US. The development of INKmune will occur primarily in the United Kingdom followed by trials in the US. XPro1595 is being developed for the treatment of Alzheimer’s disease under a Part-the-Cloud Award received Feb 2019. The biomarker directed Phase I trial is being performed in AUS using a regulatory strategy identical to that used for INB03 in cancer. Regulatory approval to initiate the trial was received on February 8, 2019. XPro1595 treats microglial activation and innate immune dysregulation may be the cause with Alzheimer’s disease in some patients. To our knowledge, there are few companies using an anti-inflammatory strategy for the treatment of Alzheimer’s disease. Those companies include Denali Therapeutics (NASDAQ: DNLI); developing DNL747 that targets critical signaling proteins in the TNF pathway that regulate inflammation and cell death. Alector (NASDAQ: ALEC) in partnership with Abbvie is developing AL002 that targets TREM2 on microglial cells. Gliacure is targeting microglial cells in Alzheimer’s disease with a small molecule candidate GC021109. LIVNate is being developed for the treatment of NASH. The Phase II trial will occur in AUS and NZ, is expected to require fewer than 5 clinical sites to complete enrollment. LIVNate offers a unique therapeutic strategy for the treatment of NASH by targeting peripheral, regional and local cycles of pathology that contribute to the development and progression of the disease. There are many drugs in development for NASH classified in three groups – anti-fibrotic, metabolic and anti-inflammatory therapies. Drug development for the treatment of NASH has been difficult. In 2019, several programs failed in late stage development including seldapar (CYMABAY) and selonsertib (GILEAD). Currently, ocaliva by Intercept is expected to be the first drug to receive FDA approval for the treatment of NASH with by elafibranor by GENFIT is expected to be second. The list of companies with NASH therapies in earlier stages of development is long, including cenicriviroc by ALLERGAN, MGL-3196 by MADRIGAL, VK2809 by VIKING Therapeutics and belapectin by GALECTIN. To our knowledge, the only true anti-inflammatory strategy in development is an anti-IL11 being developed by Boheringer Ingelheim most likely as part of combination therapy.

Clinical testing must satisfy extensive FDA regulations. Reports detailing the results of the clinical trials must be submitted at least annually to the FDA and safety reports must be submitted for serious and unexpected adverse events. Success in early stage clinical trials does not assure success in later stage clinical trials. The FDA, an IRB or we may suspend a clinical trial at any time on various grounds, including a finding that the research subjects or patients are being exposed to an unacceptable health risk.

New Drug Applications

Assuming successful completion of the required clinical trials, the results of product development, preclinical studies and clinical trials are submitted to the FDA as part of an NDA. An NDA also must contain extensive manufacturing information, as well as proposed labeling for the finished product. An NDA applicant must develop information about the chemistry and physical characteristics of the drug and finalize a process for manufacturing the product in accordance with cGMP. The manufacturing process must be capable of consistently producing quality product within specifications approved by the FDA. The manufacturer must develop methods for testing the quality, purity and potency of the final product. In addition, appropriate packaging must be selected and tested and stability studies must be conducted to demonstrate that the product does not undergo unacceptable deterioration over its shelf life. Prior to approval, the FDA will conduct an inspection of the manufacturing facilities to assess compliance with cGMP.

The FDA reviews all NDAs submitted before it accepts them for filing. The FDA may request additional information rather than accept an NDA for filing. In this event, the NDA must be resubmitted with the additional information and is subject to review before the FDA accepts it for filing. After an application is filed, the FDA may refer the NDA to an advisory committee for review, evaluation and recommendation as to whether the application should be approved and under what conditions. The FDA is not bound by the recommendation of an advisory committee, but it considers them carefully when making decisions. The FDA may deny approval of an NDA if the applicable regulatory criteria are not satisfied. Data obtained from clinical trials are not always conclusive and the FDA may interpret data differently than we interpret the same data. The FDA may issue a complete response letter, which may require additional clinical or other data or impose other conditions that must be met in order to secure final approval of the NDA. If a product receives regulatory approval, the approval may be significantly limited to specific diseases and dosages or the indications for use may otherwise be limited, which could restrict the commercial value of the product. In addition, the FDA may require us to conduct Phase 4 testing which involves clinical trials designed to further assess a drug’s safety and effectiveness after NDA approval, and may require surveillance programs to monitor the safety of approved products which have been commercialized. Once issued, the FDA may withdraw product approval if ongoing regulatory requirements are not met or if safety or efficacy questions are raised after the product reaches the market.

Post-Approval Requirements

Any products manufactured or distributed by us pursuant to FDA approvals are subject to pervasive and continuing regulation by the FDA, including, among other things, requirements relating to record-keeping, reporting of adverse experiences, periodic reporting, distribution, and advertising and promotion of the product. After approval, most changes to the approved product, such as adding new indications or other labeling claims, are subject to prior FDA review and approval. There also are continuing, annual user fee requirements for any marketed products and the establishments at which such products are manufactured, as well as new application fees for supplemental applications with clinical data. Pharmaceutical manufacturers and their subcontractors are required to register their establishments with the FDA and certain state agencies, and are subject to periodic unannounced inspections by the FDA and certain state agencies for compliance with GMP, which impose certain procedural and documentation requirements upon us and our third-party manufacturers. Changes to the manufacturing process are strictly regulated, and, depending on the significance of the change, may require prior FDA approval before being implemented. FDA regulations also require investigation and correction of any deviations from cGMP and impose reporting requirements upon us and any third-party manufacturers that we may decide to use. Accordingly, manufacturers must continue to expend time, money and effort in the area of production and quality control to maintain compliance with cGMP and other aspects of regulatory compliance. If our future suppliers are not able to comply with these requirements, the FDA may, among other things, halt our clinical trials, require us to recall a product from distribution, or withdraw approval of the product.

The FDA may withdraw approval if compliance with regulatory requirements and standards is not maintained or if problems occur after the product reaches the market. Later discovery of previously unknown problems with a product, including adverse events of unanticipated severity or frequency, or with manufacturing processes, or failure to comply with regulatory requirements, may result in revisions to the approved labeling to add new safety information; imposition of post-market studies or clinical studies to assess new safety risks; or imposition of distribution restrictions or other restrictions under a REMS program.

The FDA closely regulates the marketing, labeling, advertising and promotion of pharmaceutical products. A company can make only those claims relating to safety and efficacy, purity and potency that are approved by the FDA and in accordance with the provisions of the approved label. The FDA and other agencies actively enforce the laws and regulations prohibiting the promotion of off-label uses. Failure to comply with these requirements can result in, among other things, adverse publicity, warning letters, corrective advertising and potential civil and criminal penalties. Physicians may prescribe legally available products for uses that are not described in the product’s labeling and that differ from those tested by us and approved by the FDA. Such off-label uses are common across medical specialties. Physicians may believe that such off-label uses are the best treatment for many patients in varied circumstances. The FDA does not regulate the behavior of physicians in their choice of treatments. The FDA does, however, restrict manufacturer’s communications on the subject of off-label use of their products.

Other Healthcare Laws and Compliance Requirements

Our sales, promotion, medical education, clinical research and other activities following product approval will be subject to regulation by numerous regulatory and law enforcement authorities in the United States in addition to FDA, including potentially the Federal Trade Commission, the Department of Justice, the Centers for Medicare and Medicaid Services, or CMS, other divisions of the U.S. Department of Health and Human Services and state and local governments. Our promotional and scientific/educational programs must comply with the federal Anti-Kickback Statute, the civil False Claims Act, physician payment transparency laws, privacy laws, security laws, and additional federal and state laws similar to the foregoing.

The federal Anti-Kickback Statute prohibits, among other things, the knowing and willing, direct or indirect offer, receipt, solicitation or payment of remuneration in exchange for or to induce the referral of patients, including the purchase, order or lease of any good, facility, item or service that would be paid for in whole or part by Medicare, Medicaid or other federal health care programs. Remuneration has been broadly defined to include anything of value, including cash, improper discounts, and free or reduced price items and services. The federal Anti-Kickback Statute has been interpreted to apply to arrangements between pharmaceutical manufacturers on one hand and prescribers, purchasers, formulary managers, and beneficiaries on the other. Although there are a number of statutory exceptions and regulatory safe harbors protecting some common activities from prosecution, the exceptions and safe harbors are drawn narrowly. Practices that involve remuneration that may be alleged to be intended to induce prescribing, purchases or recommendations may be subject to scrutiny if they do not qualify for an exception or safe harbor. Failure to meet all of the requirements of a particular applicable statutory exception or regulatory safe harbor does not make the conduct per se illegal under the federal Anti-Kickback Statute. Instead, the legality of the arrangement will be evaluated on a case-by-case basis based on a cumulative review of all its facts and circumstances. Several courts have interpreted the statute’s intent requirement to mean that if any one purpose of an arrangement involving remuneration is to induce referrals of federal healthcare covered business, the federal Anti-Kickback Statute has been violated. The government has enforced the federal Anti-Kickback Statute to reach large settlements with healthcare companies based on sham research or consulting and other financial arrangements with physicians. Further, a person or entity does not need to have actual knowledge of the statute or specific intent to violate it to have committed a violation. In addition, the government may assert that a claim including items or services resulting from a violation of the federal Anti-Kickback Statute constitutes a false or fraudulent claim for purposes of the False Claims Act. Many states have similar laws that apply to their state health care programs as well as private payors.

Federal false claims and false statement laws, including the federal civil False Claims Act, or FCA, imposes liability on persons or entities that, among other things, knowingly present or cause to be presented claims that are false or fraudulent or not provided as claimed for payment or approval by a federal health care program. The FCA has been used to prosecute persons or entities that “cause” the submission of claims for payment that are inaccurate or fraudulent, by, for example, providing inaccurate billing or coding information to customers, promoting a product off-label, submitting claims for services not provided as claimed, or submitting claims for services that were provided but not medically necessary. Actions under the FCA may be brought by the Attorney General or as a qui tam action by a private individual in the name of the government. Violations of the FCA can result in significant monetary penalties and treble damages. The federal government is using the FCA, and the accompanying threat of significant liability, in its investigation and prosecution of pharmaceutical and biotechnology companies throughout the country, for example, in connection with the promotion of products for unapproved uses and other illegal sales and marketing practices. The government has obtained multi-million and multibillion dollar settlements under the FCA in addition to individual criminal convictions under applicable criminal statutes. In addition, certain companies that were found to be in violation of the FCA have been forced to implement extensive corrective action plans, and have often become subject to consent decrees or corporate integrity agreements, restricting the manner in which they conduct their business.

The federal Health Insurance Portability and Accountability Act of 1996, or HIPAA, created additional federal criminal statutes that prohibit, among other things, knowingly and willfully executing, or attempting to execute, a scheme to defraud any healthcare benefit program, including private third-party payors; knowingly and willfully falsifying, concealing or covering up a material fact or making any materially false, fictitious or fraudulent statement in connection with the delivery of or payment for healthcare benefits, items or services; and willfully obstructing a criminal investigation of a healthcare offense. Like the federal Anti-Kickback Statute, the Affordable Care Act amended the intent standard for certain healthcare fraud statutes under HIPAA such that a person or entity no longer needs to have actual knowledge of the statute or specific intent to violate it in order to have committed a violation.

Given the significant size of actual and potential settlements, we expect that the government will continue to devote substantial resources to investigating healthcare providers’ and manufacturers’ compliance with applicable fraud and abuse laws. Also, many states have similar fraud and abuse statutes or regulations that may be broader in scope and may apply regardless of payor, in addition to items and services reimbursed under Medicaid and other state programs. Additionally, to the extent that our products, once commercialized, are sold in a foreign country, we may be subject to similar foreign laws.

In addition, there has been a recent trend of increased federal and state regulation of payments made to physicians and other healthcare providers. The Patient Protection and Affordable Care Act, as amended by the Health Care and Education Reconciliation Act, or collectively, the Affordable Care Act, among other things, imposed new reporting requirements on certain manufacturers of drugs, devices, biologics and medical supplies for which payment is available under Medicare, Medicaid or the Children’s Health Insurance Program, with specific exceptions, for payments or other transfers of value made by them to physicians and teaching hospitals, as well as ownership and investment interests held by physicians and their immediate family members. Covered manufacturers are required to collect and report detailed payment data and submit legal attestation to the accuracy of such data to the government each year. Failure to submit required information may result in civil monetary penalties of up to an aggregate of $150,000 per year (or up to an aggregate of $1 million per year for “knowing failures”), for all payments, transfers of value or ownership or investment interests that are not timely, accurately and completely reported in an annual submission. Additionally, entities that do not comply with mandatory reporting requirements may be subject to a corporate integrity agreement. Certain states also mandate implementation of commercial compliance programs, impose restrictions on covered manufacturers’ marketing practices and/or require the tracking and reporting of gifts, compensation and other remuneration to physicians and other healthcare professionals.

We may also be subject to data privacy and security regulation by both the federal government and the states in which we conduct our business. HIPAA, as amended by the Health Information Technology and Clinical Health Act, or HITECH, and their respective implementing regulations, imposes specified requirements on certain health care providers, plans and clearinghouses (collectively, “covered entities”) and their “business associates,” relating to the privacy, security and transmission of individually identifiable health information. Among other things, HITECH makes HIPAA’s security standards directly applicable to “business associates,” defined as independent contractors or agents of covered entities that create, receive, maintain or transmit protected health information in connection with providing a service for or on behalf of a covered entity. HITECH also increased the civil and criminal penalties that may be imposed against covered entities, business associates and possibly other persons, and gave state attorneys general new authority to file civil actions for damages or injunctions in federal courts to enforce HIPAA and seek attorney’s fees and costs associated with pursuing federal civil actions. In addition, certain states have their own laws that govern the privacy and security of health information in certain circumstances, many of which differ from each other and/or HIPAA in significant ways and may not have the same effect, thus complicating compliance efforts.

Coverage and Reimbursement

Sales of pharmaceutical products depend significantly on the extent to which coverage and adequate reimbursement are provided by third-party payors. Third-party payors include state and federal government health care programs, managed care providers, private health insurers and other organizations. Although we currently believe that third-party payors will provide coverage and reimbursement for our product candidates, if approved, we cannot be certain of this. Third-party payors are increasingly challenging the price, examining the cost-effectiveness, and reducing reimbursement for medical products and services. In addition, significant uncertainty exists as to the reimbursement status of newly approved healthcare products. The U.S. government, state legislatures and foreign governments have continued implementing cost containment programs, including price controls, restrictions on coverage and reimbursement and requirements for substitution of generic products. Adoption of price controls and cost containment measures, and adoption of more restrictive policies in jurisdictions with existing controls and measures, could further limit our net revenue and results. We may need to conduct expensive clinical studies to demonstrate the comparative cost-effectiveness of our products. The product candidates that we develop may not be considered cost-effective and thus may not be covered or sufficiently reimbursed. It is time consuming and expensive for us to seek coverage and reimbursement from third-party payors, as each payor will make its own determination as to whether to cover a product and at what level of reimbursement. Thus, one payor’s decision to provide coverage and adequate reimbursement for a product does not assure that another payor will provide coverage or that the reimbursement levels will be adequate. Moreover, a payor’s decision to provide coverage for a drug product does not imply that an adequate reimbursement rate will be approved. Reimbursement may not be available or sufficient to allow us to sell our products on a competitive and profitable basis.

Healthcare Reform

The United States and some foreign jurisdictions are considering or have enacted a number of legislative and regulatory proposals to change the healthcare system in ways that could affect our ability to sell our products profitably. Among policy makers and payors in the United States and elsewhere, there is significant interest in promoting changes in healthcare systems with the stated goals of containing healthcare costs, improving quality and/or expanding access. In the United States, the pharmaceutical industry has been a particular focus of these efforts and has been significantly affected by major legislative initiatives.

By way of example, in March 2010, the Affordable Care Act was signed into law, intended to broaden access to health insurance, reduce or constrain the growth of healthcare spending, enhance remedies against fraud and abuse, add new transparency requirements for the healthcare and health insurance industries, impose new taxes and fees on the health industry and impose additional health policy reforms. Among the provisions of the Affordable Care Act of importance to our potential drug candidates are:

In addition, other legislative changes have been proposed and adopted since the Affordable Care Act was enacted. These changes include, among others, the Budget Control Act of 2011, which mandates aggregate reductions to Medicare payments to providers of up to 2% per fiscal year effective April 1, 2013, and, due to subsequent legislative amendments, will remain in effect through 2024 unless additional Congressional action is taken. In January 2013, President Obama signed into law the American Taxpayer Relief Act of 2012, which, among other things, further reduced Medicare payments to several providers, including hospitals and cancer treatment centers, increased the statute of limitations period for the government to recover overpayments to providers from three to five years. These new laws may result in additional reductions in Medicare and other healthcare funding, which could have a material adverse effect on customers for our product candidates, if approved, and, accordingly, our financial operations.

We expect that the Affordable Care Act, as well as other healthcare reform measures that may be adopted in the future, may result in more rigorous coverage criteria and lower reimbursement, and in additional downward pressure on the price that we receive for any approved product. Any reduction in reimbursement from Medicare or other government-funded programs may result in a similar reduction in payments from private payors. The implementation of cost containment measures or other healthcare reforms may prevent us from being able to generate revenue, attain profitability or commercialize our drugs.

Human Capital Resources

As of December 31, 2020, we had 5 full-time employees. We consider the intellectual capital of our employees to be an important driver of our business and key to our future prospects. Since the Company’s inception the Company has experienced no employee turnover. We monitor our compensation programs closely and provide what we consider to be a very competitive mix of compensation and insurance benefits for all our employees, as well as participation in our equity programs. None of our employees is subject to a collective bargaining agreement or represented by a trade or labor union. We consider our relations with our employees to be good.

Corporate Information

We were incorporated under the laws of the State of Nevada on September 25, 2015. Our principal executive office is located at 1200 Prospect Street, Suite 525, La Jolla, CA 92037 and our telephone number is (858) 964-3720.

Item 1a. Risk Factors

Summary of Risk Factors

Below is a summary of the principal factors that make an investment in our common stock speculative or risky. This summary does not address all of the risks that we face. Additional discussion of the risks summarized in this risk factor summary, and other risks that we face, can be found below under the heading “Risk Factors” and should be carefully considered, together with other information in this Form 10-K and our other filings with the SEC, before making an investment decision regarding our common stock.

You should carefully consider the risks described below as well as other information provided to you in this document, including information in the section of this document entitled “Information Regarding Forward Looking Statements.” If any of the following risks actually occur, the Company’s business, financial condition or results of operations could be materially adversely affected, the value of the Company’s Common Stock could decline, and you may lose all or part of your investment.

RISKS RELATED TO OUR BUSINESS

We will need additional capital. If additional capital is not available or is available at unattractive terms, we may be forced to delay, reduce the scope of or eliminate our research and development programs, reduce our commercialization efforts or curtail our operations.

In order to develop and bring our product candidates to market, we must commit substantial resources to costly and time-consuming research, preclinical and clinical trials and marketing activities. We anticipate that our existing cash and cash equivalents will enable us to maintain our current operations for at least the next twelve months. We anticipate using our cash and cash equivalents to fund further research and development with respect to our lead product candidates. We may, however, need to raise additional funding sooner if our business or operations change in a manner that consumes available resources more rapidly than we anticipate. Our requirements for additional capital will depend on many factors, including:

To the extent we raise additional capital through the sale of equity securities, the issuance of those securities could result in dilution to our shareholders. In addition, if we obtain debt financing, a substantial portion of our operating cash flow may be dedicated to the payment of principal and interest on such indebtedness, thus limiting funds available for our business activities. If adequate funds are not available, we may be required to delay, reduce the scope of or eliminate our research and development programs, reduce our commercialization efforts or curtail our operations. In addition, we may be required to obtain funds through arrangements with collaborative partners or others that may require us to relinquish rights to technologies, product candidates or products that we would otherwise seek to develop or commercialize ourselves or license rights to technologies, product candidates or products on terms that are less favorable to us than might otherwise be available.

The Company will require substantial additional funds to support its research and development activities, and the anticipated costs of preclinical studies and clinical trials, regulatory approvals and eventual commercialization. Such additional sources of financing may not be available on favorable terms, if at all. If we do not succeed in raising additional funds on acceptable terms, we may be unable to initiate clinical trials or obtain approval of any product candidates from the FDA and other regulatory authorities. In addition, we could be forced to discontinue product development, forego sales and marketing efforts and forego attractive business opportunities. Any additional sources of financing will likely involve the issuance of our equity securities, which will have a dilutive effect on our stockholders.

We face intense competition in the markets targeted by our lead product candidates. Many of our competitors have substantially greater resources than we do, and we expect that all of our product candidates under development will face intense competition from existing or future drugs.

We expect that all of our product candidates under development, if approved, will face intense competition from existing and future drugs marketed by large companies. These competitors may successfully market products that compete with our products, successfully identify drug candidates or develop products earlier than we do, or develop products that are more effective, have fewer side effects or cost less than our products, if any.

Additionally, if a competitor receives FDA approval before we do for a drug that is similar to one of our product candidates, FDA approval for our product candidate may be precluded or delayed due to periods of non-patent exclusivity and/or the listing with the FDA by the competitor of patents covering its newly-approved drug product. Periods of non-patent exclusivity for new versions of existing drugs such as our current product candidates can extend up to three and one-half years. See “Business — Government Regulation.”

These competitive factors could require us to conduct substantial new research and development activities to establish new product targets, which would be costly and time consuming. These activities would adversely affect our ability to commercialize products and achieve revenue and profits.

Competition and technological change may make our product candidates and technologies less attractive or obsolete.

We compete with established pharmaceutical and biotechnology companies that are pursuing other forms of treatment for the same indications we are pursuing and that have greater financial and other resources. Other companies may succeed in developing products earlier than us, obtaining FDA approval for products more rapidly, or developing products that are more effective than our product candidates. Research and development by others may render our technology or product candidates obsolete or noncompetitive, or result in treatments or cures superior to any therapy we develop. We face competition from companies that internally develop competing technology or acquire competing technology from universities and other research institutions. As these companies develop their technologies, they may develop competitive positions that may prevent, make futile, or limit our product commercialization efforts, which would result in a decrease in the revenue we would be able to derive from the sale of any products.

There can be no assurance that any of our product candidates will be accepted by the marketplace as readily as these or other competing treatments. Furthermore, if our competitors’ products are approved before ours, it could be more difficult for us to obtain approval from the FDA. Even if our products are successfully developed and approved for use by all governing regulatory bodies, there can be no assurance that physicians and patients will accept our product(s) as a treatment of choice.

Furthermore, the pharmaceutical research industry is diverse, complex, and rapidly changing. By its nature, the business risks associated therewith are numerous and significant. The effects of competition, intellectual property disputes, market acceptance, and FDA regulations preclude us from forecasting revenues or income with certainty or even confidence.

If we fail to protect our intellectual property rights, our ability to pursue the development of our technologies and products would be negatively affected.

Our success will depend, in part, on our ability to obtain patents and maintain adequate protection of our technologies and products. If we do not adequately protect our intellectual property, competitors may be able to use our technologies to produce and market drugs in direct competition with us and erode our competitive advantage. Some foreign countries lack rules and methods for defending intellectual property rights and do not protect proprietary rights to the same extent as the United States. Many companies have had difficulty protecting their proprietary rights in these foreign countries. We may not be able to prevent misappropriation of our proprietary rights.

We have received, and are currently seeking, patent protection for numerous compounds and methods of treating diseases. However, the patent process is subject to numerous risks and uncertainties, and there can be no assurance that we will be successful in protecting our products by obtaining and defending patents. These risks and uncertainties include the following: patents that may be issued or licensed may be challenged, invalidated, or circumvented, or otherwise may not provide any competitive advantage; our competitors, many of which have substantially greater resources than us and many of which have made significant investments in competing technologies, may seek, or may already have obtained, patents that will limit, interfere with, or eliminate our ability to make, use, and sell our potential products either in the United States or in international markets; there may be significant pressure on the United States government and other international governmental bodies to limit the scope of patent protection both inside and outside the United States for treatments that prove successful as a matter of public policy regarding worldwide health concerns; countries other than the United States may have less restrictive patent laws than those upheld by United States courts, allowing foreign competitors the ability to exploit these laws to create, develop, and market competing products.

Moreover, any patents issued to us may not provide us with meaningful protection, or others may challenge, circumvent or narrow our patents. Third parties may also independently develop products similar to our products, duplicate our unpatented products or design around any patents on products we develop. Additionally, extensive time is required for development, testing and regulatory review of a potential product. While extensions of patent term due to regulatory delays may be available, it is possible that, before any of our product candidates can be commercialized, any related patent, even with an extension, may expire or remain in force for only a short period following commercialization, thereby reducing any advantages of the patent.

In addition, the United States Patent and Trademark Office (the “USPTO”) and patent offices in other jurisdictions have often required that patent applications concerning pharmaceutical and/or biotechnology-related inventions be limited or narrowed substantially to cover only the specific innovations exemplified in the patent application, thereby limiting the scope of protection against competitive challenges. Thus, even if we or our licensors are able to obtain patents, the patents may be substantially narrower than anticipated.

Our success depends on patent applications that are licensed exclusively to us and other patents to which we may obtain assignment or licenses. We may not be aware, however, of all patents, published applications or published literature that may affect our business either by blocking our ability to commercialize our product candidates, by preventing the patentability of our product candidates to us or our licensors, or by covering the same or similar technologies that may invalidate our patents, limit the scope of our future patent claims or adversely affect our ability to market our product candidates.

In addition to patents, we rely on a combination of trade secrets, confidentiality, nondisclosure and other contractual provisions, and security measures to protect our confidential and proprietary information. These measures may not adequately protect our trade secrets or other proprietary information. If they do not adequately protect our rights, third parties could use our technology, and we could lose any competitive advantage we may have. In addition, others may independently develop similar proprietary information or techniques or otherwise gain access to our trade secrets, which could impair any competitive advantage we may have.

Patent protection and other intellectual property protection is crucial to the success of our business and prospects, and there is a substantial risk that such protections will prove inadequate.

We license our patents from third party owners. If such owners do not properly maintain or enforce the intellectual property underlying such licenses, our competitive position and business prospects could be harmed. Our licensors may also seek to terminate our license.

We are a party to a number of licenses that give us rights to third-party intellectual property that is necessary or useful to our business. To this end, we are dependent on our licenses with Xencor, Inc., Immune Ventures, LLC the University of Pittsburgh and University College London. Our success will depend in part on the ability of our licensors to obtain, maintain and enforce our licensed intellectual property. Our licensors may not successfully prosecute any applications for or maintain intellectual property to which we have licenses, may determine not to pursue litigation against other companies that are infringing such intellectual property, or may pursue such litigation less aggressively than we would. Without protection for the intellectual property we license, other companies might be able to offer similar products for sale, which could adversely affect our competitive business position and harm our business prospects. If we lose any of our right to use third-party intellectual property, it could adversely affect our ability to commercialize our technologies, products or services, as well as harm our competitive business position and our business prospects.

We are dependent on our licensing agreement with Xencor and the termination of this agreement could a have an adverse effect on our business.

On October 3, 2017, the Company entered into a license agreement with Xencor, Inc., which has discovered and developed a proprietary biological molecule that inhibits soluble tumor necrosis factor. Pursuant to the license agreement, Xencor granted the Company an exclusive worldwide, royalty-bearing license in licensed patent rights, licensed know-how and licensed materials to make, develop, use, sell and import any pharmaceutical product that comprises, contains, or incorporates Xencor’s proprietary protein known as “XPro1595” that inhibits soluble tumor necrosis factor (or all modifications, formulations and variants of the licensed protein that specifically bind soluble tumor necrosis factor) alone or in combination with one or more active ingredients, in any dosage or formulation. If we breach this Agreement Xencor may be able to terminate it and as a result of this terminate our business could be negatively impacted.

Our officers and Directors own the company that we license our INKmune patent from.

On October 29, 2015, we entered into an exclusive license agreement with Immune Ventures, LLC (Immune Ventures). The license agreement relates to our natural killer program, INKmune. Immune Ventures is owned by our President and a member of our Board of Directors, David Moss, our Chief Financial Officer and Treasurer and Mark Lowdell, our Chief Scientific Officer. Because our officers and directors also own Immune Ventures there may be an inherent conflict of interest which could result in unanticipated actions that adversely affect us.

We have a limited operating history, and expect to incur significant additional operating losses.

We are an early-stage company formed in September 2015 and have only a limited operating history. Therefore, there is limited historical financial information upon which to base an evaluation of our performance. Our prospects must be considered in light of the uncertainties, risks, expenses, and difficulties frequently encountered by companies in their early stages of operations. We expect to incur substantial additional operating expenses over the next several years as our research, development, and commercial activities increase. The amount of future losses and when, if ever, we will achieve profitability are uncertain. Our ability to generate revenue and achieve profitability will depend on, among other things, successful completion of the preclinical and clinical development of our product candidate; obtaining necessary regulatory approvals from the FDA and international regulatory agencies; implementing successful manufacturing, sales, and marketing arrangements; and raising sufficient funds to finance our activities. If we are unsuccessful at some or all of these undertakings, our business, prospects, and results of operations may be materially adversely affected.

INKmune represents a novel approach to cancer treatment that creates significant challenges for us.

We believe INKmune represents a novel approach to cancer treatment. Advancing this novel therapy creates significant challenges for us, including:

Even if we are able to commercialize any product candidate that we develop, the product may become subject to unfavorable pricing regulations, third-party payor reimbursement practices or healthcare reform initiatives that could harm our business.

The commercial success of our product candidates will depend substantially, both domestically and abroad, on the extent to which the costs of our product candidates will be paid by health maintenance, managed care, pharmacy benefit and similar healthcare management organizations, or reimbursed by government health administration authorities (such as Medicare and Medicaid), private health coverage insurers and other third-party payors. If reimbursement is not available, or is available only to limited levels, we may not be able to successfully commercialize our product candidates. Even if coverage is provided, the approved reimbursement amount may not be high enough to allow us to establish and maintain pricing sufficient to realize a meaningful return on our investment.

There is significant uncertainty related to third-party payor coverage and reimbursement of newly approved drugs. Marketing approvals, pricing and reimbursement for new drug products vary widely from country to country. Some countries require approval of the sale price of a drug before it can be marketed. In many countries, the pricing review period begins after marketing or product licensing approval is granted. In some non-U.S. markets, prescription pharmaceutical pricing remains subject to continuing governmental control even after initial approval is granted. As a result, we might obtain marketing approval for a product in a particular country, but then be subject to price regulations that delay commercial launch of the product, possibly for lengthy time periods, which may negatively impact the revenues we are able to generate from the sale of the product in that country. Adverse pricing limitations may hinder our ability to recoup our investment in one or more product candidates, even if our product candidates obtain marketing approval.

We depend on obtaining certain patents and protecting our proprietary rights.

Our success will depend, in part, on our ability to obtain patents, maintain trade secret protection and operate without infringing on the proprietary rights of third parties or having third parties circumvent our rights. We have filed and are actively pursuing a patent application for our product candidates. The patent positions of biotechnology, biopharmaceutical and pharmaceutical companies can be highly uncertain and involve complex legal and factual questions. Thus, there can be no assurance that our patent application will result in the issuance of a patent, that we will develop additional proprietary products that are patentable, that any patents issued to us will provide us with any competitive advantages or will not be challenged by any third parties, that the patents of others will not impede our ability to do business or that third parties will not be able to circumvent our patents. Furthermore, there can be no assurance that others will not independently develop similar products, duplicate any of our products not under patent protection, or, if patents are issued to us, design around the patented products we developed or will develop.

We may be required to obtain licenses from third parties to avoid infringing patents or other proprietary rights. No assurance can be given that any licenses required under any such patents or proprietary rights would be made available, if at all, on terms we find acceptable. If we do not obtain such licenses, we could encounter delays in the introduction of products or could find that the development, manufacture or sale of products requiring such licenses could be prohibited.

A number of pharmaceutical, biopharmaceutical and biotechnology companies and research and academic institutions have developed technologies, filed patent applications or received patents on various technologies that may be related to or affect our business. Some of these technologies, applications or patents may conflict with our technologies or patent applications. Such conflict could limit the scope of the patents, if any, that we may be able to obtain or result in the denial of our patent applications. In addition, if patents that cover our activities are issued to other companies, there can be no assurance that we would be able to obtain licenses to these patents at a reasonable cost or be able to develop or obtain alternative technology. If we do not obtain such licenses, we could encounter delays in the introduction of products, or could find that the development, manufacture or sale of products requiring such licenses could be prohibited. In addition, we could incur substantial costs in defending ourselves in suits brought against us on patents it might infringe or in filing suits against others to have such patents declared invalid.

Much of our know-how and technology may not be patentable. To protect our rights, we plan to require employees, consultants, advisors and collaborators to enter into confidentiality agreements. There can be no assurance, however, that these agreements will provide meaningful protection for our trade secrets, know-how or other proprietary information in the event of any unauthorized use or disclosure. Further, our business may be adversely affected by competitors who independently develop competing technologies, especially if we obtain no, or only narrow, patent protection.

We are subject to various government regulations.

The manufacture and sale of human therapeutic products in the U.S. and foreign jurisdictions are governed by a variety of statutes and regulations. These laws require approval of manufacturing facilities, controlled research and testing of products and government review and approval of a submission containing manufacturing, preclinical and clinical data in order to obtain marketing approval based on establishing the safety and efficacy of the product for each use sought, including adherence to current cGMP during production and storage, and control of marketing activities, including advertising and labeling.

The products we are currently developing will require significant development, preclinical and clinical testing and investment of substantial funds prior to its commercialization. The process of obtaining required approvals can be costly and time-consuming, and there can be no assurance that we develop successfully this product or any future products, or that this product or any future products we develop will prove to be safe and effective in clinical trials or receive applicable regulatory approvals. Potential investors and shareholders should be aware of the risks, problems, delays, expenses and difficulties which we may encounter in view of the extensive regulatory environment which controls our business.

If we are unable to keep up with rapid technological changes in our field or compete effectively, we will be unable to operate profitably.

We are engaged in a rapidly changing field. Other products and therapies that will compete directly with the product that we are seeking to develop and market currently exist or are being developed. Competition from fully integrated pharmaceutical companies and more established biotechnology companies is intense and is expected to increase. Most of these companies have significantly greater financial resources and expertise in discovery and development, manufacturing, preclinical and clinical testing, obtaining regulatory approvals and marketing than us. Smaller companies may also prove to be significant competitors, particularly through collaborative arrangements with large pharmaceutical and established biopharmaceutical or biotechnology companies. Many of these competitors have significant products that have been approved or are in development and operate large, well-funded discovery and development programs. Academic institutions, governmental agencies and other public and private research organizations also conduct research, seek patent protection and establish collaborative arrangements for therapeutic products and clinical development and marketing. These companies and institutions compete with us in recruiting and retaining highly qualified scientific and management personnel. In addition to the above factors, we will face competition based on product efficacy and safety, the timing and scope of regulatory approvals, availability of supply, marketing and sales capability, reimbursement coverage, price and patent position. There is no assurance that our competitors will not develop more effective or more affordable products, or achieve earlier patent protection or product commercialization, than our own.

Other companies may succeed in developing products earlier than ourselves, obtaining FDA and European Medicines Agency (“EMA”) approvals for such products more rapidly than we will, or in developing products that are more effective than products we propose to develop. While we will seek to expand our technological capabilities in order to remain competitive, there can be no assurance that research and development by others will not render our technology or products obsolete or non-competitive or result in treatments or cures superior to any therapy we develop, or that any therapy we develop will be preferred to any existing or newly developed technologies.

We may request priority review for our product candidate in the future. The FDA may not grant priority review for our product candidate. Moreover, even if the FDA designates such product for priority review, that designation may not lead to a faster regulatory review or approval process and, in any event, would not assure FDA approval.

We may be eligible for priority review designation for our product candidate if the FDA determines such product candidate offers major advances in treatment or provides a treatment where no adequate therapy exists. A priority review designation means that the goal for the FDA to review an application in six months, rather than the standard review period of ten months. The FDA has broad discretion with respect to whether or not to grant priority review status to a product candidate, so even if we believe a particular product candidate is eligible for such designation or status, the FDA may decide not to grant it. Thus, while the FDA has granted priority review to other oncology disease products, our product candidate, should we determine to seek priority review, may not receive similar designation. Moreover, even if our product candidate is designated for priority review, such a designation does not necessarily mean a faster regulatory review process or necessarily confer any advantage with respect to approval compared to conventional FDA procedures. Receiving priority review from the FDA does not guarantee approval within an accelerated timeline or thereafter.

We believe we may in some instances be able to secure approval from the FDA or comparable non-U.S. regulatory authorities to use accelerated development pathways. If we are unable to obtain such approval, we may be required to conduct additional preclinical studies or clinical trials beyond those that we contemplate, which could increase the expense of obtaining, and delay the receipt of, necessary marketing approvals.

We anticipate that we may seek an accelerated approval pathway for our product candidates. Under the accelerated approval provisions in the Federal Food, Drug, and Cosmetic Act, or FDCA, and the FDA’s implementing regulations, the FDA may grant accelerated approval to a product designed to treat a serious or life-threatening condition that provides meaningful therapeutic benefit over available therapies upon a determination that the product has an effect on a surrogate endpoint or intermediate clinical endpoint that is reasonably likely to predict clinical benefit. The FDA considers a clinical benefit to be a positive therapeutic effect that is clinically meaningful in the context of a given disease, such as irreversible morbidity or mortality. For the purposes of accelerated approval, a surrogate endpoint is a marker, such as a laboratory measurement, radiographic image, physical sign, or other measure that is thought to predict clinical benefit, but is not itself a measure of clinical benefit. An intermediate clinical endpoint is a clinical endpoint that can be measured earlier than an effect on irreversible morbidity or mortality that is reasonably likely to predict an effect on irreversible morbidity or mortality or other clinical benefit. The accelerated approval pathway may be used in cases in which the advantage of a new drug over available therapy may not be a direct therapeutic advantage, but is a clinically important improvement from a patient and public health perspective. If granted, accelerated approval is usually contingent on the sponsor’s agreement to conduct, in a diligent manner, additional post-approval confirmatory studies to verify and describe the drug’s clinical benefit. If such post-approval studies fail to confirm the drug’s clinical benefit, the FDA may withdraw its approval of the drug.

Prior to seeking such accelerated approval, we will seek feedback from the FDA and will otherwise evaluate our ability to seek and receive such accelerated approval. There can be no assurance that after our evaluation of the feedback and other factors we will decide to pursue or submit a New Drug Application, or NDA, for accelerated approval or any other form of expedited development, review or approval. Similarly, there can be no assurance that after subsequent FDA feedback we will continue to pursue or apply for accelerated approval or any other form of expedited development, review or approval, even if we initially decide to do so. Furthermore, if we decide to submit an application for accelerated approval or under another expedited regulatory designation (e.g., breakthrough therapy designation), there can be no assurance that such submission or application will be accepted or that any expedited development, review or approval will be granted on a timely basis, or at all. The FDA or other non-U.S. authorities could also require us to conduct further studies prior to considering our application or granting approval of any type. A failure to obtain accelerated approval or any other form of expedited development, review or approval for our product candidate would result in a longer time period to commercialization of such product candidate, could increase the cost of development of such product candidate and could harm our competitive position in the marketplace.

Clinical drug development involves a lengthy and expensive process with an uncertain outcome. We may incur additional costs or experience delays in completing, or ultimately be unable to complete the development and commercialization of our product candidate.

Our product candidates are either in early clinical development or have not entered into clinical trials and are in development stage. Therefore, the risk of failure of our product candidates is high. It is impossible to predict when or if our product candidates will prove effective or safe in humans or will receive regulatory approval. Before obtaining marketing approval from regulatory authorities for the sale of any product candidate, we must complete preclinical development and then conduct extensive clinical trials to demonstrate the safety and efficacy of our product candidate in humans. Clinical testing is expensive, difficult to design and implement, can take many years to complete and is uncertain as to outcome. A failure of one or more clinical trials can occur at any stage of testing. The clinical development of our product candidates is susceptible to the risk of failure inherent at any stage of drug development, including failure to demonstrate efficacy in a clinical trial or across a broad population of patients, the occurrence of severe or medically or commercially unacceptable adverse events, failure to comply with protocols or applicable regulatory requirements and determination by the FDA or any comparable non-U.S. regulatory authority that a drug product is not safe or effective for its intended uses. It is possible that even if our product candidate has a beneficial effect, that effect will not be detected during clinical evaluation as a result of one or more of a variety of factors, including the size, duration, design, measurements, conduct or analysis of our clinical trials. Conversely, as a result of the same factors, our clinical trials may indicate an apparent positive effect of a product candidate that is greater than the actual positive effect, if any. Similarly, in our clinical trials we may fail to detect toxicity of or intolerability caused by our product candidates, or mistakenly believe that our product candidates are toxic or not well tolerated when that is not in fact the case.

The outcome of preclinical studies and early clinical trials may not be predictive of the success of later clinical trials, and interim results of a clinical trial do not necessarily predict final results. Many companies in the pharmaceutical and biotechnology industries have suffered significant setbacks in late-stage clinical trials after achieving positive results in earlier development, and we cannot be certain that we will not face additional setbacks.

The design of a clinical trial can determine whether its results will support approval of a product; however, flaws in the design of a clinical trial may not become apparent until the clinical trial is well advanced or completed. In addition, preclinical and clinical data are often susceptible to varying interpretations and analyses. Many companies that believed their product candidates performed satisfactorily in preclinical studies and clinical trials have nonetheless failed to obtain marketing approval for the product candidates. Even if we believe that the results of clinical trials for our product candidate warrant marketing approval, the FDA or comparable non-U.S. regulatory authorities may disagree and may not grant marketing approval of our product candidate.

In some instances, there can be significant variability in safety or efficacy results between different clinical trials of the same product candidate due to numerous factors, including changes in trial procedures set forth in protocols, differences in the size and type of the patient populations, changes in and adherence to the clinical trial protocols and the rate of dropout among clinical trial participants. Any clinical trials that we may conduct may not demonstrate the efficacy and safety necessary to obtain regulatory approval to market our product candidate.

If clinical trials of our product candidates fail to demonstrate safety and efficacy to the satisfaction of the FDA and comparable non-U.S. regulators, we may incur additional costs or experience delays in completing, or ultimately be unable to complete, the development and commercialization of our product candidates.

We are not permitted to commercialize, market, promote or sell any product candidate in the United States without obtaining marketing approval from the FDA. Comparable non-U.S. regulatory authorities, such as the EMA, impose similar restrictions. We may never receive such approvals. We must complete extensive preclinical development and clinical trials to demonstrate the safety and efficacy of our product candidate in humans before we will be able to obtain these approvals.

Clinical testing is expensive, difficult to design and implement, can take many years to complete and is inherently uncertain as to outcome. We have not previously submitted an NDA to the FDA or similar drug approval filings to comparable non-U.S. regulatory authorities for any product candidate.

Any inability to successfully complete preclinical and clinical development could result in additional costs to us and impair our ability to generate revenues from product sales, regulatory and commercialization milestones and royalties. In addition, if (1) we are required to conduct additional clinical trials or other testing of our product candidate beyond the trials and testing than we contemplate, (2) we are unable to successfully complete clinical trials of our product candidate or other testing, (3) the results of these trials or tests are unfavorable, uncertain or are only modestly favorable, or (4) there are unacceptable safety concerns associated with our product candidate, we, in addition to incurring additional costs, may:

If we experience any of a number of possible unforeseen events in connection with clinical trials of any of our product candidates, potential marketing approval or commercialization of that product candidate could be delayed or prevented.

We may experience numerous unforeseen events during, or as a result of, clinical trials that could delay or prevent marketing approval of any of our product candidates, including:

Product development costs for us will increase if we experience delays in testing or pursuing marketing approvals and we may be required to obtain additional funds to complete clinical trials and prepare for possible commercialization of our product candidates. We do not know whether any preclinical tests or clinical trials will begin as planned, will need to be restructured or will be completed on schedule, or at all. Significant preclinical or clinical trial delays also could shorten any periods during which we may have the exclusive right to commercialize our product candidates or allow our competitors to bring products to market before we do and impair our ability to successfully commercialize our product candidates and may harm our business and results of operations. In addition, many of the factors that cause, or lead to, clinical trial delays may ultimately lead to the denial of marketing approval of our product candidates.

If we experience delays or difficulties in the enrollment of patients in clinical trials, we may not achieve our clinical development on our anticipated timeline, or at all, and our receipt of necessary regulatory approvals could be delayed or prevented.

We may not be able to initiate or continue clinical trials for INKmune our DN-TNF product platform or any other product candidate if we are unable to locate and enroll a sufficient number of eligible patients to participate in clinical trials. Patient enrollment is a significant factor in the timing of clinical trials, and is affected by many factors, including:

Our inability to enroll a sufficient number of patients for our clinical trials could result in significant delays or may require us to abandon one or more clinical trials altogether. Enrollment delays in our clinical trials may result in increased development costs for our product candidates, delay or halt the development of and approval processes for our product candidates and jeopardize our ability to achieve our clinical development timeline and goals, including the dates by which we will commence, complete and receive results from clinical trials. Enrollment delays may also delay or jeopardize our ability to commence sales and generate revenues from our product candidates. Any of the foregoing could cause the value of the Company to decline and limit our ability to obtain additional financing, if needed.

We will need to obtain FDA approval of any proposed product brand names, and any failure or delay associated with such approval may adversely impact our business.

A pharmaceutical product cannot be marketed in the U.S. or other countries until we have completed rigorous and extensive regulatory review processes, including approval of a brand name. Any brand names we intend to use for our product candidates will require approval from the FDA regardless of whether we have secured a formal trademark registration from the U.S. Patent and Trademark Office, or the USPTO. The FDA typically conducts a review of proposed product brand names, including an evaluation of potential for confusion with other product names. The FDA may also object to a product brand name if it believes the name inappropriately implies medical claims. If the FDA objects to any of our proposed product brand names, we may be required to adopt an alternative brand name for our product candidates. If we adopt an alternative brand name, we would lose the benefit of our existing trademark applications for such product candidate and may be required to expend significant additional resources in an effort to identify a suitable product brand name that would qualify under applicable trademark laws, not infringe the existing rights of third parties and be acceptable to the FDA. We may be unable to build a successful brand identity for a new trademark in a timely manner or at all, which would limit our ability to commercialize our product candidates.

We may rely on orphan drug status to develop and commercialize our product candidates, but orphan drug designation, if obtained, may not confer marketing exclusivity or other expected commercial benefits as anticipated.

Market exclusivity afforded by orphan drug designation is generally offered as an incentive to drug developers to invest in developing and commercializing products for unique diseases that impact a limited number of patients. The FDA may grant orphan drug designation to drugs intended to treat a rare disease or condition, which is generally a disease or condition that affects fewer than 200,000 individuals in the United States. Qualification to maintain orphan drug status is generally monitored by the regulatory authorities during the orphan drug exclusivity period, currently seven years from the date of approval in the United States.

We intend to seek orphan drug designation in the United States for our product candidate for the treatment of AML and ovarian cancer and we expect to rely on orphan drug exclusivity for our product candidate. Even if granted, orphan drug designation, and related market exclusivity, in the United States could be lost. Further, even if we are granted orphan drug status, the FDA can still approve different drugs for use in treating the same indication or disease, which would create a more competitive market for us and our revenues will be diminished.

Further, for our product candidate, it is possible that another company also holding orphan drug designation for the same product candidate will receive marketing approval for the same indication before we do. If that were to happen, our applications for that indication may not be approved until the competing company’s period of exclusivity expires. Even if we are the first to obtain marketing authorization for an orphan drug indication, there are circumstances under which a competing product may be approved for the same indication during the seven-year period of marketing exclusivity, such as if the later product is shown to be clinically superior to the orphan product, or if the later product is deemed a different product than ours. Further, the seven-year marketing exclusivity would not prevent competitors from obtaining approval of the same product candidate as ours for indications other than those in which we have been granted orphan drug designation, or for the use of other types of products in the same indications as our orphan product.

If the market opportunities for our product candidates are smaller than we believe they are, our revenues may be adversely affected and our business may suffer. Because the target patient populations of our product candidates are small, we must be able to successfully identify patients and capture a significant market share to achieve and maintain profitability.

We focus our research and product development on treatments for certain cancer indications. Our projections of both the number of people who have failed other therapies or have limited medical options for such indications, are based on estimates. These estimates may prove to be incorrect and new studies may change the estimated incidence or prevalence. The number of patients with such diseases in the United States, Europe and elsewhere may turn out to be lower than expected or may not be otherwise amenable to treatment with our products, or new patients may become increasingly difficult to identify or gain access to, all of which would adversely affect our results of operations and our business. Additionally, because our target patient populations are small, we will be required to capture a significant market share to achieve and maintain profitability.

We may fail to comply with regulatory requirements.

Our success will be dependent upon our ability, and our collaborative partners’ abilities, to maintain compliance with regulatory requirements, including cGMP, and safety reporting obligations. The failure to comply with applicable regulatory requirements can result in, among other things, fines, injunctions, civil penalties, total or partial suspension of regulatory approvals, refusal to approve pending applications, recalls or seizures of products, operating and production restrictions and criminal prosecutions.

Even if our product candidates receive marketing approval, they may fail to achieve the degree of market acceptance by physicians, patients, third-party payors and others in the medical community necessary for commercial success and the market opportunity for the product candidates may be smaller than we estimate.

We have never commercialized a product. Even if INKmune, our DN-TNF product platform (INB03, XPro1595, Quellor, LIVNate), or any other product candidate we develop is approved by the appropriate regulatory authorities for marketing and sale, it may nonetheless fail to gain sufficient market acceptance by physicians, patients, third-party payors and others in the medical community. For example, physicians are often reluctant to switch their patients from existing therapies even when new and potentially more effective or convenient treatments enter the market. Further, patients often acclimate to the therapy that they are currently taking and do not want to switch unless their physicians recommend switching products or they are required to switch therapies due to lack of reimbursement for existing therapies.

Efforts to educate the medical community and third-party payors on the benefits of our product candidate may require significant resources and may not be successful. If our product candidate is approved but does not achieve an adequate level of market acceptance, we may not generate significant revenues and we may not become profitable. The degree of market acceptance of INmune or any other product candidate we develop, if approved for commercial sale, will depend on a number of factors, including:

The potential market opportunities for our product candidate are difficult to estimate precisely. Our estimates of the potential market opportunities are predicated on many assumptions, including industry knowledge and publications, third-party research reports and other surveys. While we believe that our internal assumptions are reasonable, these assumptions involve the exercise of significant judgment on the part of our management, are inherently uncertain and the reasonableness of these assumptions has not been assessed by an independent source. If any of the assumptions proves to be inaccurate, the actual markets for our product candidate could be smaller than our estimates of the potential market opportunities.

Even if we obtain regulatory approvals for INKmune and/or any product from our DN-TNF platform (INB03, XPro1595, Quellor, LIVNate) those approvals and ongoing regulation of our products may limit how we manufacture and market our products, which could prevent us from realizing the full benefit of our efforts.

If we obtain regulatory approvals, INKmune and/or the DN-TNF product platform, and the manufacturing facilities used for its production will be subject to continual review, including periodic inspections, by the FDA and other United States and foreign regulatory authorities. In addition, regulatory authorities may impose significant restrictions on the indicated uses or marketing of INKmune or other products that we may develop. These and other factors may significantly restrict our ability to successfully commercialize INKmune.

We and many of our vendors and suppliers will be required to comply with current Good Manufacturing Practices, or GMP, which include requirements relating to quality control and quality assurance as well as to the corresponding maintenance of records and documentation. Furthermore, any manufacturing facilities will need to be approved by regulatory agencies before these facilities can be used to manufacture INKmune, and they will also be subject to additional regulatory inspections. Any material changes we may make to our manufacturing process may require approval by the FDA and state or foreign regulatory authorities. Failure to comply with FDA or other applicable regulatory requirements may result in criminal prosecution, civil penalties, recall or seizure of products, partial or total suspension of production or withdrawal of a product from the market.

We must also report adverse events that occur when our products are used. The discovery of previously unknown problems with INKmune, the DN-TNF product platform or manufacturing facilities used to manufacture INKmune or the DN-TNF product platform may result in restrictions or sanctions on our products or manufacturing facilities, including withdrawal of our products from the market. Regulatory agencies may also require us to reformulate our products, conduct additional clinical trials, make changes in the labeling of our product or obtain re-approvals. This may cause our reputation in the market place to suffer or subject us to lawsuits, including class action suits.

If our product candidates receive marketing approval and we, or others, later discover that the drug is less effective than previously believed or causes undesirable side effects that were not previously identified, our ability to market the drugs could be compromised.

Clinical trials of our product candidates will be conducted in carefully defined subsets of patients who have agreed to enter into clinical trials. Consequently, it is possible that our clinical trials may indicate an apparent positive effect of a product candidate that is greater than the actual positive effect, if any, or alternatively fail to identify undesirable side effects. If, following approval of our product candidate, we, or others, discover that the drug is less effective than previously believed or causes undesirable side effects that were not previously identified, any of the following adverse events could occur:

Any of these events could have a material and adverse effect on our operations and business.

Any product candidate for which we obtain marketing approval, along with the manufacturing processes, qualification testing, post-approval clinical data, labeling and promotional activities for such product, will be subject to continual and additional requirements of the FDA and other regulatory authorities.

These requirements include submissions of safety and other post-marketing information, reports, registration and listing requirements, good manufacturing practices, or GMP requirements relating to quality control, quality assurance and corresponding maintenance of records and documents, and recordkeeping. Even if marketing approval of our product candidate is granted, the approval may be subject to limitations on the indicated uses for which the product may be marketed or to conditions of approval, or contain requirements for costly post-marketing testing and surveillance to monitor the safety or efficacy of the product. The FDA closely regulates the post-approval marketing and promotion of pharmaceutical products to ensure such products are marketed only for the approved indications and in accordance with the provisions of the approved labeling.

In addition, later discovery of previously unknown problems with our products, manufacturing processes, or failure to comply with regulatory requirements, may lead to various adverse results, including:

We currently have no marketing and sales organization and have no experience in marketing products. If we are unable to establish marketing and sales capabilities or enter into agreements with third parties to market and sell our product candidates, we may not be able to generate product revenue.

We currently have no sales, marketing or distribution capabilities and have no experience as a company in marketing products. If we develop internal sales, marketing and distribution organization, this would require significant capital expenditures, management resources and time, and we would have to compete with other pharmaceutical and biotechnology companies to recruit, hire, train and retain marketing and sales personnel.

If we are unable or decide not to establish internal sales, marketing and distribution capabilities, we expect to pursue collaborative arrangements regarding the sales, marketing and distribution of our products. However, we may not be able to establish or maintain such collaborative arrangements, or if we are able to do so, their sales forces may not be successful in marketing our products. Any revenue we receive would depend upon the efforts of such third parties, which may not be successful. We may have little or no control over the sales, marketing and distribution efforts of such third parties and our revenue from product sales may be lower than if we had commercialized our product candidates ourselves. We also face competition in our search for third parties to assist us with the sales, marketing and distribution efforts of our product candidates. There can be no assurance that we will be able to develop internal sales, marketing distribution capabilities or establish or maintain relationships with third-party collaborators to commercialize any product in the United States or overseas.

We face substantial competition from other pharmaceutical and biotechnology companies and our operating results may suffer if we fail to compete effectively.

The development and commercialization of new drug products is highly competitive. We expect that we will face significant competition from major pharmaceutical companies, specialty pharmaceutical companies and biotechnology companies worldwide with respect to INKmune, our DN-TNF product platform, and any other of our product candidates that we may seek to develop or commercialize in the future. Specifically, due to the large unmet medical need, global demographics and relatively attractive reimbursement dynamics, the oncology market is fiercely competitive and there are a number of large pharmaceutical and biotechnology companies that currently market and sell products or are pursuing the development of product candidates for the treatment of cancer. Our competitors may succeed in developing, acquiring or licensing technologies and drug products that are more effective, have fewer or more tolerable side effects or are less costly than any product candidates that we are currently developing or that we may develop, which could render our product candidates obsolete and noncompetitive.

We rely on key personnel and, if we are unable to retain or motivate key personnel or hire qualified personnel, we may not be able to grow effectively.

We are dependent on certain members of our management, the loss of services of one or more of whom could materially adversely affect us. In particular, our success depends to a significant extent upon the continued services of Dr. Raymond J. Tesi, our President and CEO. Dr. Tesi has overseen INmune Bio since inception and provides leadership for our growth and operations strategy as well as being an inventor of our patents. Although we have entered into an employment agreement with Dr. Tesi, if he were to nevertheless terminate his employment with us, the loss of the services of Dr. Tesi, would have a material adverse effect on our growth, revenues, and prospective business. We are also highly dependent on the other principal members of our management and scientific team. We are not aware of any present intention of any of our key personnel to leave our company or to retire. The loss of any of our key personnel, or the inability to attract and retain qualified personnel, may significantly delay or prevent the achievement of our research, development or business objectives and could materially adversely affect our business, financial condition and results of operations.

Our ability to manage growth effectively will require us to continue to implement and improve our management systems and to recruit and train new employees. There can be no assurance that we will be able to successfully attract and retain skilled and experienced personnel.

Product liability lawsuits against us could divert our resources, cause us to incur substantial liabilities and limit commercialization of any products that we may develop.

We face an inherent risk of product liability claims as a result of the clinical testing of our product candidate despite obtaining appropriate informed consents from our clinical trial participants. We will face an even greater risk if we commercially sell any product that we may develop. For example, we may be sued if any product we develop allegedly causes injury or is found to be otherwise unsuitable during clinical testing, manufacturing, marketing or sale. Any such product liability claims may include allegations of defects in manufacturing, defects in design, a failure to warn of dangers inherent in the product, negligence, strict liability or a breach of warranties. Claims could also be asserted under state consumer protection acts. If we cannot successfully defend ourselves against product liability claims, we may incur substantial liabilities or be required to limit commercialization of our product candidate. Regardless of the merits or eventual outcome, liability claims may result in:

Although we plan to maintain general liability insurance, this insurance may not fully cover potential liabilities that we may incur. The cost of any product liability litigation or other proceeding, even if resolved in our favor, could be substantial. In addition, insurance coverage is becoming increasingly expensive. If we are unable to obtain or maintain sufficient insurance coverage at an acceptable cost or to otherwise protect against potential product liability claims, it could prevent or inhibit the development and commercial production and sale of our product candidate, which could adversely affect our business, financial condition, results of operations and prospects.

We will need to grow the size and capabilities of our organization, and we may experience difficulties in managing this growth.

To execute our business plan, we will need to rapidly add other management, accounting, regulatory, manufacturing and scientific staff. We currently have 5 full time employees and retain the services of additional personnel on an independent contractor basis. We will need to attract, retain and motivate a significant number of new additional managerial, operational, sales, marketing, financial, and other personnel, as well as highly skilled scientific and medical personnel, and to expand our capabilities to successfully pursue our research, development, manufacturing and commercialization efforts and secure collaborations to market and distribute our products. This growth may strain our existing managerial, operational, financial and other resources. We also intend to add personnel in our research and development and manufacturing departments as we expand our clinical trial and research capabilities. Any inability to attract and retain qualified employees to enable our planned growth and establish additional capabilities or our failure to manage our growth effectively could delay or curtail our product development and commercialization efforts and harm our business.

If we or any of our third-party manufacturers do not maintain high standards of manufacturing, our ability to develop and commercialize our product candidate could be delayed or curtailed.

We and any third parties that we may use in the future to manufacture our products must continuously adhere to cGMP regulations rigorously enforced by the FDA through its facilities inspection program. If our facilities or the facilities of third parties who produce our products do not pass a pre-approval inspection, the FDA will not grant market approval for our product candidates. In complying with cGMP, we and any third-party manufacturers will need to expend significant time, money and effort in production, record-keeping and quality control to assure that each component of our product candidates meets applicable specifications and other requirements. We or any of these third-party manufacturers may also be subject to comparable or more stringent regulations of foreign regulatory authorities. If we or any of our third-party manufacturers fail to comply with these requirements, we may be subject to regulatory action, which could delay or curtail our ability to develop, obtain regulatory approval of, and commercialize our product candidates. If our component part manufacturers and suppliers fail to provide components of sufficient quality, and that meet our required specifications, our clinical trials or commercialization of our product candidates could be delayed or halted, and we could face product liability claims. There can be no assurance we can manufacture a scalable quantity of our product for clinical trials or commercialization.

If we or our third-party manufacturers use hazardous and biological materials in a manner that causes injury or violates applicable law, we may be liable for damages.

Our research and development activities involve the controlled use of potentially hazardous substances, including chemical and biological materials, by us and any third-party manufacturers. We and such manufacturers will be subject to federal, state and local laws and regulations in the United States governing the use, manufacture, storage, handling and disposal of medical and hazardous materials. Although we will seek to ensure that our procedures for using, storing and disposing of these materials comply with legally prescribed standards, we cannot completely eliminate the risk of contamination or injury resulting from medical or hazardous materials. As a result of any such contamination or injury, we may incur liability or local, city, state or federal authorities may curtail the use of these materials and interrupt our business operations. In the event of an accident, we could be held liable for damages or penalized with fines, and the liability could exceed our resources. We do not have any insurance for liabilities arising from medical or hazardous materials. Compliance with applicable environmental laws and regulations is expensive, and current or future environmental regulations may impair our research, development and production efforts, which could harm our business, prospects, financial condition or results of operations.

We plan to rely on third parties to conduct clinical trials for our product candidates. Any failure by a third party to meet its obligations with respect to the clinical development of our product candidate may delay or impair our ability to obtain regulatory approval for our product candidates.

We plan to rely on academic institutions and private oncology centers to conduct clinical trials relating to our product candidates. Our reliance on third parties to conduct clinical trials could, depending on the actions of such third parties, jeopardize the validity of the clinical data generated and adversely affect our ability to obtain marketing approval from the FDA or other applicable regulatory authorities.

Such clinical trial arrangements will provide us with information rights with respect to the clinical data, including access to and the ability to use and reference the data, including for our own regulatory filings, resulting from the clinical trials. If investigators or institutions breach their obligations with respect to the clinical trials of our product candidate, or if the data proves to be inadequate, then our ability to design and conduct any future clinical trials may be adversely affected.

Our reliance on these third parties for research and development activities will reduce our control over these activities but will not relieve us of our responsibilities. For example, we will design our clinical trials and will remain responsible for ensuring that each of our clinical trials is conducted in accordance with the general investigational plan and protocols for the trial. Moreover, the FDA requires us to comply with standards, commonly referred to as good clinical practices, or GCPs, for conducting, recording and reporting the results of clinical trials to assure that data and reported results are credible and accurate and that the rights, integrity and confidentiality of trial participants are protected. Our reliance on third parties that we do not control will not relieve us of these responsibilities and requirements. We also are required to register ongoing clinical trials and post the results of completed clinical trials on a government-sponsored database, ClinicalTrials.gov, within specified timeframes. Failure to do so can result in fines, adverse publicity and civil and criminal sanctions.

Furthermore, these third parties may also have relationships with other entities, some of which may be our competitors. If these third parties do not successfully carry out their contractual duties, meet expected deadlines or conduct our clinical trials in accordance with regulatory requirements or our stated protocols, we will not be able to obtain, or may be delayed in obtaining, marketing approvals for our product candidate and will not be able to, or may be delayed in our efforts to, successfully commercialize our product candidate.

We also expect to rely on other third parties to store and distribute drug supplies for our clinical trials. Any performance failure on the part of our distributors could delay clinical development or marketing approval of our product candidate or commercialization of our products, producing additional losses and depriving us of potential product revenue.

Recent legislative and regulatory activity may exert downward pressure on potential pricing and reimbursement for our products, if approved, could materially affect our opportunity to commercialize such products.

The United States and several other jurisdictions are considering, or have already enacted, a number of legislative and regulatory proposals to change the healthcare system in ways that could affect our ability to sell any of our products profitably, if approved. Among policy-makers and payors in the United States and elsewhere, there is significant interest in promoting changes in healthcare systems with the stated goals of containing healthcare costs, improving quality and/or expanding access to healthcare. In the United States, the pharmaceutical industry has been a particular focus of these efforts and has been significantly affected by major legislative initiatives. There have been, and likely will continue to be, legislative and regulatory proposals at the federal and state levels directed at broadening the availability of healthcare and containing or lowering the cost of healthcare. We cannot predict the initiatives that may be adopted in the future. The continuing efforts of the government, insurance companies, managed care organizations and other payors of healthcare services to contain or reduce costs of healthcare may adversely affect:

In March 2010, the Affordable Care Act, or the ACA, became law in the United States (see “Business — Government Regulation”). The goal of ACA is to reduce the cost of healthcare, broaden access to health insurance, constrain healthcare spending, enhance remedies against fraud and abuse, add transparency requirements for the healthcare and health insurance industries, impose taxes and fees on the health industry, impose additional health policy reforms, and substantially change the way healthcare is financed by both governmental and private insurers. While we cannot predict what impact on federal reimbursement policies this legislation will have in general or on our business specifically, ACA may result in downward pressure on pharmaceutical reimbursement, which could negatively affect market acceptance of any of our products, if they are approved.

We cannot predict what healthcare reform initiatives may be adopted in the future. Further federal, state and foreign legislative and regulatory developments are likely, and we expect ongoing initiatives to increase pressure on drug pricing. Such reforms could have an adverse effect on anticipated revenues from product candidates that we may successfully develop and for which we may obtain regulatory approval and may affect our overall financial condition and ability to develop product candidates.

Changes in U.S. patent law could diminish the value of patents in general, thereby impairing our ability to protect our products.

As is the case with other pharmaceutical companies, our success is heavily dependent on intellectual property, particularly on obtaining and enforcing patents. Obtaining and enforcing patents in the pharmaceutical industry involves both technological and legal complexity, and therefore, is costly, time-consuming and inherently uncertain. In addition, the United States has recently enacted and is currently implementing wide-ranging patent reform legislation. Further, recent U.S. Supreme Court rulings have either narrowed the scope of patent protection available in certain circumstances or weakened the rights of patent owners in certain situations. In addition to increasing uncertainty with regard to our ability to obtain patents in the future, this combination of events has created uncertainty with respect to the value of patents, once obtained.

In September 2011, the Leahy-Smith America Invents Act, or the American Invents Act, or AIA, was signed into law. The AIA includes a number of significant changes to U.S. patent law, including provisions that affect the way patent applications will be prosecuted and may also affect patent litigation. The USPTO is currently developing regulations and procedures to govern administration of the AIA, and many of the substantive changes to patent law associated with the AIA. It is not clear what other, if any, impact the AIA will have on the operation of our business. Moreover, the AIA and its implementation could increase the uncertainties and costs surrounding the prosecution of our patent application, which could have a material adverse effect on our business and financial condition.

An important change introduced by the AIA is that, as of March 16, 2013, the United States transitioned to a “first-to-file” system for deciding which party should be granted a patent when two or more patent applications are filed by different parties claiming the same invention. A third party that files a patent application in the USPTO after that date but before us could therefore be awarded a patent covering an invention of ours even if we had made the invention before it was made by the third party. This will require us to be cognizant going forward of the time from invention to filing of a patent application. Furthermore, our ability to obtain and maintain valid and enforceable patents depends on whether the differences between our technology and the prior art allow our technology to be patentable over the prior art. Since patent applications in the United States and most other countries are confidential for a period of time after filing, we cannot be certain that we were the first to either (1) file any patent application related to our product candidates or (2) invent any of the inventions claimed in our patents or patent applications.

Among some of the other changes introduced by the AIA are changes that limit where a patentee may file a patent infringement suit and providing opportunities for third parties to challenge any issued patent in the USPTO. This applies to all of our U.S. patents, even those issued before March 16, 2013. Because of a lower evidentiary standard in USPTO proceedings compared to the evidentiary standard in United States federal court necessary to invalidate a patent claim, a third party could potentially provide evidence in a USPTO proceeding sufficient for the USPTO to hold a claim invalid even though the same evidence would be insufficient to invalidate the claim if first presented in a district court action. Accordingly, a third party may attempt to use the USPTO procedures to invalidate our patent claims that would not have been invalidated if first challenged by the third party as a defendant in a district court action.

Business or economic disruptions or global health concerns could seriously harm our development efforts and increase our costs and expenses.

Broad-based business or economic disruptions could adversely affect our ongoing or planned research and development activities. For example, in December 2019 an outbreak of a novel strain of coronavirus originated in Wuhan, China, and has since spread to a number of other countries, including the United States. To date, this outbreak has already resulted in extended shutdowns of certain businesses in the Wuhan region and has had ripple effects to businesses around the world. Global health concerns, such as coronavirus, could also result in social, economic, and labor instability in the countries in which we or the third parties with whom we engage operate. We cannot presently predict the scope and severity of any potential business shutdowns or disruptions, but if we or any of the third parties with whom we engage, including the suppliers, clinical trial sites, regulators and other third parties with whom we conduct business, were to experience shutdowns or other business disruptions, our ability to conduct our business in the manner and on the timelines presently planned could be materially and negatively impacted. It is also possible that global health concerns such as this one could disproportionately impact the clinical sites in which we conduct any of our clinical trials, which could have a material adverse effect on our business and our results of operation and financial condition. The Company has not yet experienced any known business disruptions as a result of the coronavirus.

We may face business disruption and related risks resulting from President Biden’s invocation of the Defense Production Act, which could have a material adverse effect on our business.

In response to the COVID-19 pandemic, President Biden invoked the Defense Production Act (the “Defense Production Act”). Pursuant to the Defense Production Act, the federal government may, among other things, require domestic industries to provide essential goods and services needed for the national defense. While we have not experienced any impact on our business as a result of such actions, we continue to assess the potential impact that the invocation of the Defense Production Act may have on our ability to effectively conduct our business operations as planned, either as a result of becoming directly subject to the requirements of the Defense Production Act, our suppliers becoming so subject and diverting deliveries of raw materials elsewhere, or otherwise. There can be no assurance that we will not be impacted by any action taken by the federal government under the Defense Production Act, and any resulting disruption on our ability to conduct business could have a material adverse effect on our financial condition and results or operations.

A cybersecurity incident and other technology disruptions could negatively affect our business and our relationships with customers.

We use technology in substantially all aspects of our business operations. The widespread use of technology, including mobile devices, cloud computing, and the internet, give rise to cybersecurity risks, including security breach, espionage, system disruption, theft and inadvertent release of information. Our business involves the storage and transmission of numerous classes of sensitive and/or confidential information and intellectual property, including information relating to suppliers, private information about employees, and financial and strategic information about us and our business partners. If we fail to effectively assess and identify cybersecurity risks associated with the use of technology in our business operations, we may become increasingly vulnerable to such risks. Additionally, while we have implemented measures to prevent security breaches and cyber incidents, our preventative measures and incident response efforts may not be entirely effective. The theft, destruction, loss, misappropriation, or release of sensitive and/or confidential information or intellectual property, or interference with our information technology systems or the technology systems of third parties on which we rely, could result in business disruption, negative publicity, brand damage, violation of privacy laws, loss of customers, potential liability and competitive disadvantage.

Risks Related to our Common Stock

We do not intend to pay dividends for the foreseeable future.

We have paid no dividends on our common stock to date, and we do not anticipate paying any dividends to holders of our common stock in the foreseeable future. While our future dividend policy will be based on the operating results and capital needs of the business, we anticipate that we will retain any earnings to finance our future expansion and for the implementation of our business plan. As an investor, you should take note of the fact that a lack of a dividend can further affect the market value of our common stock, and could significantly affect the value of any investment in our Company.

We are subject to the reporting requirements of federal securities laws, which can be expensive and may divert resources from other projects, thus impairing our ability grow.

We are a public reporting company and, accordingly, subject to the information and reporting requirements of the Exchange Act and other federal securities laws, including compliance with the Sarbanes-Oxley Act of 2002 (the “Sarbanes-Oxley Act”). The costs of preparing and filing annual and quarterly reports, proxy statements and other information with the SEC and furnishing audited reports to stockholders would cause our expenses to be higher than they would be if we remained privately held.

It may be time consuming, difficult and costly for us to develop and implement the internal controls and reporting procedures required by the Sarbanes-Oxley Act. We may need to hire additional financial reporting, internal controls and other finance personnel in order to develop and implement appropriate internal controls and reporting procedures.

We are an “emerging growth company” within the meaning of the Securities Act of 1933, as amended, or the Securities Act, and if we decide to take advantage of certain exemptions from various reporting requirements applicable to emerging growth companies, our common stock could be less attractive to investors.

We will remain an emerging growth company until the earliest of (1) the last day of the fiscal year during which we have total annual gross revenues of $1.07 billion or more, (2) December 31, 2024 (the last day of the fiscal year following the fifth anniversary of the completion of our initial public offering), (3) the date on which we have, during the previous three-year period, issued more than $1.0 billion in non-convertible debt, and (4) the date on which we are deemed to be a “large accelerated filer” under the Securities Exchange Act of 1934, as amended, or the Exchange Act (i.e., the first day of the fiscal year after we have (a) more than $700.0 million in outstanding common equity held by our non-affiliates, measured each year on the last day of our second fiscal quarter, and (b) been public for at least 12 months).

Even after we no longer qualify as an emerging growth company, we may still qualify as a “smaller reporting company,” which would allow us to take advantage of many of the same exemptions from disclosure requirements including exemption from compliance with the auditor attestation requirements of Section 404 of the Sarbanes-Oxley Act and reduced disclosure obligations regarding executive compensation in our periodic reports and proxy statements. We cannot predict if investors will find our common stock less attractive because we may rely on these exemptions. If some investors find our common stock less attractive as a result, there may be a less active trading market for our common stock and our stock price may be more volatile.

Our stock price may be volatile.

The market price of our common stock is likely to be highly volatile and could fluctuate widely in price in response to various factors, many of which are beyond our control, including the following:

In addition, the securities markets have from time to time experienced significant price and volume fluctuations that are unrelated to the operating performance of particular companies. These market fluctuations may also materially and adversely affect the market price of our Common Stock.

You may have difficulty trading and obtaining quotations for our common stock.

Our securities are not actively traded, and the bid and asked prices for our common stock may fluctuate widely. As a result, investors may find it difficult to dispose of, or to obtain accurate quotations of the price of, our securities. This severely limits the liquidity of the common stock and would likely reduce the market price of our common stock and hamper our ability to raise additional capital. There is a limited market for our securities. Accordingly, investors may therefore bear the economic risk of an investment in the Securities thereof, for an indefinite period of time.

Additional stock offerings in the future may dilute your percentage ownership of our company.

Given our plans and expectations that we may need additional capital and personnel, we may need to issue additional shares of common stock or securities convertible or exercisable for shares of common stock, including convertible preferred stock, convertible notes, stock options or warrants. The issuance of additional securities in the future will dilute the percentage ownership of then current stockholders.

Anti-takeover provisions in our stockholder rights plan could make a third-party acquisition of us difficult.

We have a stockholder rights plan that may have the effect of discouraging unsolicited takeover proposals. Specifically, the rights issued under the stockholder rights plan could cause significant dilution to a person or group that attempts to acquire us on terms not approved in advance by our board of directors. The rights plan is not intended to prevent a takeover, and we believe it will enable all our stockholders to realize the full potential value of their investment in the Company and protect the Company and its stockholders from efforts to obtain control of the Company that are inconsistent with the best interests of the Company and its stockholders. The rights under the plan will expire on December 30, 2021, subject to a possible earlier expiration to the extent provided in the stockholder rights plan, unless extended.

ITEM 1B. UNRESOLVED STAFF COMMENTS

Not applicable.

ITEM 2. PROPERTIES

The Company subleases approximately 1,000 square feet of office space in La Jolla, California from a related party, which serves as the headquarters of the Company. We pay approximately $4,000 per month for this sublease which expires in July 2024. We believe our current facilities are suitable and adequate to meet our current needs.

ITEM 3. LEGAL PROCEEDINGS

We currently are not a party to any material litigation or other material legal proceedings. We may, from time to time, be subject to legal proceedings and claims arising in the normal course of business.

ITEM 4. MINE SAFETY DISCLOSURES

Not applicable.

PART II

ITEM 5. MARKET FOR REGISTRANT’S COMMON EQUITY, RELATED STOCKHOLDER MATTERS AND ISSUER PURCHASES OF EQUITY SECURITIES

Common Stock

Our common stock trades under the symbol “INMB” on the Nasdaq and has been publicly traded since February 4, 2019. Prior to this time, there was no public market for our common stock.

As of December 31, 2020, there were 35 holders of record of our common stock. Because shares of our common stock are held by depositories, brokers and other nominees, the number of beneficial holders of our shares is substantially larger than the number of record holders.

Purchases of Equity Securities by the Issuer

During January 2020, the Company purchased and cancelled 220,000 shares of its common stock from a shareholder in exchange for $1,012,000 of cash. Immediately following the purchase, the investor owned less than 10% of the outstanding common stock of the Company.

Dividend Policy

We have not declared any cash dividends on our common stock since inception and do not anticipate paying such dividends in the foreseeable future. We plan to retain any future earnings for use in our business operations. Any decisions as to future payment of cash dividends will depend on our earnings and financial position and such other factors as the Board of Directors deems relevant.

Item 6. Selected Financial Data

As a smaller reporting company, as defined in Rule 12b-2 promulgated under the Exchange Act, and in Item 10(f)91) of Regulation S-K, we are electing scaled disclosure reporting obligations and therefore are not required to provide the information required by this item.

PART II

ITEM 7. MANAGEMENT’S DISCUSSION AND ANALYSIS OF FINANCIAL CONDITION AND RESULTS OF OPERATIONS

You should read the following discussion and analysis of our financial condition and results of operations in conjunction with our financial statements and notes thereto appearing elsewhere in this Annual Report. In addition to historical financial information, the following discussion and analysis contains forward-looking statements that involve risks, uncertainties, and assumptions. Our actual results could differ materially from those anticipated by these forward-looking statements as a result of many factors. We discuss factors that we believe could cause or contribute to these differences below and elsewhere in this Form 10-K, including those set forth under “Risk Factors” and “Forward-Looking Statements.”

Overview

We are a clinical-stage immunotherapy company focused on developing drugs that may reprogram the patient’s innate immune system to treat disease. We believe this may be done by targeting cells of the innate immune system that cause acute and chronic inflammation and are involved in the immune dysfunction associated with chronic diseases such as cancer, neurodegenerative, metabolic and infectious diseases. The Company has two therapeutic platforms – dominant-negative TNF platform (“DN-TNF”) and the Natural Killer (“NK”) platform. The DN-TNF platform neutralizes soluble TNF (“sTNF”) without affecting trans-membrane TNF (“tmTNF”) or the receptors TNFR1 and TNFR2. This unique biologic mechanism differentiates the DN-TNF drugs from currently approved non-selective TNF inhibitors that inhibit the function of both sTNF and tmTNF. Protecting the function of tmTNF while neutralizing the function of sTNF is a potent anti-inflammatory drug that does not cause immunosuppression or demyelination. Currently approved non-selective TNF inhibitors are approved to treat autoimmune disease, however they are contraindicated in patients with infection, cancer and neurologic diseases because they increase the risk of infection, cancer and demyelinating neurologic diseases, respectively, because of off-target effects on inhibiting tmTNF. The NK platform targets the dysfunctional natural killer cells (“NK cells”) in patients with cancer. NK cells are part of the normal immunologic response to cancer with important roles in immunosurveillance to prevent cancer and in preventing relapse by clearing residual disease. Residual disease is the cancer left behind, often undetected, that can grow and cause relapse. The NK cells of cancer patients have the ability to kill cancer cells but are not effective because cancer cells mutate to evade NK cell immune surveillance. INKmune provides the missing signals needed to prime NK cells to overcome the immune evasion mutation to allow NK cells to kill the cancer cell. We believe INKmune is best used to eliminate residual disease after the patient has completed other cancer therapies. Both the DN-TNF platform and the INKmune platform can be used to treat multiple diseases. The DN-TNF platform will be used as an immunotherapy for the treatment of cancer, neurodegenerative, metabolic and infectious diseases. INKmune is being developed to treat NK sensitive hematologic malignancies and solid tumors.

We believe our DN-TNF platform can be used to reverse resistance in immunotherapy, to target glial activation to prevent progression of Alzheimer’s disease (“AD”), to target neuroinflammation in treatment resistant depression (“TRD”), to target intestinal leak and inflammation to treat non-alcoholic steatohepatitis (“NASH”) and to treat complications of the cytokine storm associated with COVID-19 infection. The drug is named differently for each indication; INB03, XPro1595, LIVNate and Quellor, respectively, but it is the same drug product. In each case, we believe neutralizing sTNF is a cornerstone to the treatment of each of these diseases. As an immunotherapy for cancer, we are using INB03 to neutralize sTNF produced by HER2+ trastuzumab resistant breast cancers to reverse resistance to therapy. sTNF causes an up-regulation of MUC4 expression that causes steric hindrance of trastuzumab binding to the HER2/Neu receptor on HER2+ breast cancer cells. Without binding, trastuzumab is not effective. In addition, INB03 changes the immunobiology of the tumor microenvironment by decreasing the number of immunosuppressive myeloid cells, both myeloid derived suppressor cells and tumor active macrophages, and increasing the number of cytotoxic lymphocytes in the TME. The Company has completed an open label dose escalation trial in cancer patients with metastatic solid tumors that have failed multiple lines of therapy. The trial informs the design of the Phase II trial by demonstrating that INB03 was safe and well tolerated, defined the dose of INB03 to carry into Phase II trials, and demonstrated a pharmacodynamic end-point. A Phase II trial is planned in women with advanced HER2+ breast cancer with metastasis.

Likewise, we believe the DN-TNF platform can be used to treat selected neurodegenerative diseases. XPro1595 is being used to treat patients with Alzheimer’s disease in a Phase I trial partially funded by a Part-the-Clouds Award from the Alzheimer’s Association. XPro1595 targets activated microglia and astrocytes of the brain that produce sTNF that promotes nerve cell loss and synaptic dysfunction, key elements in the development of dementia. In animal models, elimination of sTNF prevents nerve cell dysfunction and reverses synaptic pruning. The Phase I trial in patients with biomarkers of inflammation with AD is enrolling patients. The open label, dose escalation trial is designed to demonstrate that XPro1595 decreases neuroinflammation in patients with AD. This end-points of the trial are measures of neuroinflammation and neurodegeneration in blood and cerebral spinal fluid, measures of neuroinflammation by MRI by measuring white matter free water and breath by measuring volatile organic compounds in exhaled breath and by monitoring neuropsychiatric symptoms known to be associated with neuroinflammation including depression, apathy, aggression, hallucinations and sleep disorders.

In addition, we believe the DN-TNF platform can be used to treat selected metabolic diseases. LIVNate is being developed to treat NASH. NASH is a pleiotropic disease caused by a complex mix of metabolic, inflammatory and fibrotic pathophysiology. We believe targeting inflammation caused by intestinal leak, mesenteric and peripheral fat will prevent lipotoxicity, hepatic stellate cell activation and hepatocyte death that causes fibrosis and liver dysfunction associated with advanced disease. sTNF is elevated in obesity and is believed to cause intestinal leak. Intestinal leak combined with cytokines coming from mesenteric fat may dramatically increase the concentration of inflammatory cytokines in portal blood destined for the liver. The cytokine load contributes to the development of non-alcoholic fatty liver disease (“NAFLD”) and progression to NASH. LIVNate, by neutralizing sTNF improves insulin sensitivity, decreases the inflammation in peripheral and mesenteric fat and may also seal the intestinal leak. This combination prevents development of NAFLD or NASH in animal models. The Company is planning a Phase II open label randomized study using non-invasive measures to enroll patients with NASH in a study using a fixed dose of LIVNate delivered as a once a week sub-cutaneous injection.

We also believe the DN-TNF platform may be used to treat the complications associated with the cytokine storm caused by coronavirus disease 2019 (“COVID-19”). Three inflammatory cytokines make up the cytokine storm associated with COVID19 infection – sTNF, IL-6 and IL-1β. Targeting sTNF with Quellor may have advantages because IL-6 and IL-1 expression occur after sTNF expression; sTNF promotes endothelial activation causing expression of proteins that promote trafficking of immune cells from the blood vessel to the tissue and expression of Tissue Factor that stimulates the coagulopathy that is a prominent pathology of COVID-19 infection. The Company plans a Phase II trial in patients with symptomatic COVID-19 infection and hypoxia. The goal of the study is to prevent the catastrophic complications of advanced COVID-19 infection including one or more of the need for mechanical ventilation, new onset of cardiovascular, neurologic or thromboembolic disease, admission to an intensive care unit or death. The randomized trial will treat patients requiring hospitalization because of their disease.

Effective therapy for treatment resistant depression (TRD) is a large unmet need. Twenty percent of patients with a Major Depressive Disorder have TRD. Once third of TRD patients have peripheral biomarkers to inflammation (elevated CRP). This is a large patient population. The role of TNF and anti-TNF therapeutics was explored in a small open label clinical trial by Prof. Andrew Miller, MD of Emory University demonstrated the patients have elevated TNF levels and treatment with infliximab treated their depression (Miller, 2011). The Company received a $2.9M USD award from the National Institute of Mental Health (NIMH) to treat TRD with XPro1595. The blinded, randomized Phase II trial will use a biomarkers of peripheral inflammation to select patients with TRD for enrollment. Patients will be treated for 6 weeks. Primary end-points include both clinical and neuroimaging measures. The final trial design has is ongoing and discussions with the FDA are not complete. The Company anticipates receiving authorization to initiate the clinical trial in the second half of 2021.

We believe that INKmune improves the ability of the patient’s own NK cells to attack their tumor. INKmune interacts with the patient’s NK cells to convert them from inert resting NK cells that ignores the cancer into primed NK cells that kill the cancer cell. INKmune is a replication incompetent proprietary cell line we have named INB16 that is given to the patient after determining that i) the patient has adequate NK cells in their circulation and ii) those NK cells are functional when exposed to INKmune in vitro. INKmune is designed to be given to patients after their immune system has recovered after cytotoxic chemotherapy to target the residual disease the remains after treatment with cytotoxic therapy. INKmune can be used to treat numerous hematologic malignancies and solid tumors including leukemia, multiple myeloma, lymphoma, lung, ovary, breast, renal and prostate cancer. The Company plans Phase I trials using INKmune to treat patients with high risk MDS, a form of leukemia and women with relapsed refractory ovarian.

As a company with less than $1.07 billion in revenue during our last fiscal year, we qualify as an “emerging growth company” under the JOBS Act. As an emerging growth company, we may take advantage of specified reduced disclosure and other requirements that are otherwise applicable generally to public companies. These provisions include:

We have elected to take advantage of the above-referenced exemptions and we may take advantage of these exemptions for up to five years or such earlier time that we are no longer an emerging growth company. We would cease to be an emerging growth company if we have more than $1.07 billion in annual revenues, we have more than $700 million in market value of our stock held by non-affiliates, or we issue more than $1 billion of non-convertible debt over a three-year period. We may choose to take advantage of some but not all of these reduced burdens.

Components of Operating Results

Operating Expenses

Research and Development

Research and development expense consists of expenses incurred while performing research and development activities to discover and develop our product candidates. This includes conducting preclinical studies and clinical trials, manufacturing development efforts and activities related to regulatory filings for product candidates. We recognize research and development expenses as they are incurred. Our research and development expense primarily consist of:

We typically use our employee, consultant and infrastructure resources across our development programs. We track outsourced development costs by product candidate or development program, but we do not allocate personnel costs, other internal costs or external consultant costs to specific product candidates or development programs.

We participate, through our wholly-owned subsidiary in Australia, in the Australian research and development tax incentive program, such that a percentage of our qualifying research and development expenditures are reimbursed by the Australian government, and such incentives are reflected as a reduction of research and development expense. The Australian research and development tax incentive is recognized when there is reasonable assurance that the incentive will be received, the relevant expenditure has been incurred and the amount of the consideration can be reliably measured.

We participate, through our wholly-owned subsidiary in the United Kingdom, in the research and development program provided by the United Kingdom tax relief program, such that a percentage of our qualifying research and development expenditures are reimbursed by the United Kingdom government, and such incentives are reflected as a reduction of research and development expense. The United Kingdom research and development tax incentive is recognized when there is reasonable assurance that the incentive will be received, the relevant expenditure has been incurred and the amount of the consideration can be reliably measured.

Substantially all of our research and development expenses to date have been incurred in connection with our current and future product candidates. We expect our research and development expenses to increase significantly for the foreseeable future as we advance an increased number of our product candidates through clinical development, including the conduct of our planned clinical trials and manufacturing drug to be used in those clinical trials. The process of conducting clinical trials necessary to obtain regulatory approval is costly and time consuming. The successful development of product candidates is highly uncertain. At this time, we cannot reasonably estimate the nature, timing or costs required to complete the remaining development of any product candidates. This is due to the numerous risks and uncertainties associated with the development of product candidates.

The costs of clinical trials may vary significantly over the life of a project owing to, but not limited to, the following:

We do not expect any of our product candidates to be commercially available for at least the next several years, if ever. We expect to continue to incur significant expenses and increasing operating losses for the foreseeable future, which may fluctuate significantly from quarter-to-quarter and year-to-year. We anticipate that our expenses will increase substantially as we:

General and Administrative Expenses

General and administrative expenses consist principally of payroll and personnel expenses, including stock-based compensation; professional fees for legal, consulting, accounting and tax services; overhead, including rent and utilities; and other general operating expenses not otherwise classified as research and development expenses.

Waiver of Common Stock Issuable

Waiver of common stock issuable consists of a reversal of stock-based compensation for a consultant that permanently waived the Company issuing 200,000 shares owed to the consultant which were expensed in a prior period.

Other income

Other income primarily consists of income from a settlement in 2020. In addition, other income includes interest income on money market accounts during 2020 and 2019.

Critical Accounting Policies and Significant Judgments and Estimates

This management’s discussion and analysis of our financial condition and results of operations is based on our financial statements, which we have prepared in accordance with accounting principles generally accepted in the United States. The preparation of our financial statements requires us to make estimates and assumptions that affect the reported amounts of assets and liabilities and the disclosure of contingent assets and liabilities at the date of our financial statements, as well as the reported revenues and expenses during the reported periods. We evaluate these estimates and judgments on an ongoing basis. We base our estimates on historical experience and on various other factors that we believe are reasonable under the circumstances, the results of which form the basis for making judgments about the carrying value of assets and liabilities that are not readily apparent from other sources. Actual results may differ from these estimates under different assumptions or conditions.

In-Process Research and Development

The Company evaluates the carrying value of indefinite-lived intangible assets, which consists of in-process research and development (“IPR&D”), on an annual basis or more frequently when indicators of impairment exist. An impairment of indefinite-lived intangible assets would occur if the fair value of the intangible asset is less than the carrying value. Intangible assets with finite lives are tested for impairment when events or changes in circumstances indicate that the carrying amount of such assets may not be recoverable. If these facts and circumstances exist, the Company assesses for recovery by comparing the carrying values of the assets with their future undiscounted net cash flows. Significant management judgment is required in the forecast of future operating results that are used in the preparation of expected undiscounted cash flows.

IPR&D assets are considered to be indefinite-lived until the completion or abandonment of the associated research and development projects. During the period the assets are considered indefinite-lived, they are tested for impairment. If the related project is terminated or abandoned, the Company may have a full or partial impairment related to the IPR&D assets, calculated as the excess of their carrying value over fair value. The valuation process is very complex and requires significant input and judgment using internal and external sources with respect to the Company’s future revenue and expense growth rates, changes in working capital use, the selection of an appropriate discount rate, and other assumptions and estimates.

Research and Development (“R&D”)

R&D expenses consist primarily of costs related to clinical studies and outside services, personnel expenses, and other R&D expenses. Clinical studies and outside services costs relate primarily to services performed by clinical research organizations and related clinical or development manufacturing costs, materials and supplies, filing fees, regulatory support, and other third-party fees. Personnel expenses relate primarily to salaries, benefits and share-based compensation. R&D expenditures are charged to operations as incurred.

We recognize R&D tax credits receivable from the United Kingdom and Australian government for spending on R&D as an offset of R&D expenses.

Stock-Based Compensation

We measure and recognize compensation expense for all stock-based awards granted to service providers. employees, and directors based on the estimated fair value of the award on the grant date. We calculate the estimated fair value of stock options on the date of grant using the Black-Scholes option-pricing model, which is impacted by the fair value of our common stock, as well as changes in assumptions regarding a number of highly complex and subjective variables. These variables include, but are not limited to, the market value of common stock on the grant date, the expected dividend yield, the expected term of the awards, the risk-free interest rates and the expected common stock price volatility over the term of the option awards. The expected volatility is based on the historical volatility of a few unrelated public companies within our industry over the most recent period commensurate with the estimated expected term of our stock options as we have insufficient historical information regarding the volatility of the share price of our common stock. The risk-free interest rate for periods within the contractual life of the option is based on the U.S. Treasury yield in effect at the time of grant. We have never declared or paid dividends and have no plans to do so in the foreseeable future.

We recognize the fair value of stock options on a straight-line basis over the period during which a service provider is required to provide services in exchange for the award (generally the vesting period). We account for forfeitures as they occur.

Off-Balance Sheet Arrangements

During the periods presented, we did not have any off-balance sheet arrangements as defined under SEC rules.

Licensing and Collaboration Agreements

We anticipate that in-licensing, out-licensing and strategic collaborations will become an integral part of our operations, providing the company with opportunities to leverage our partners’ expertise and capabilities to further expand the potential of our technologies, product candidates and revenue streams.

Xencor

In October 2017, we licensed INB03 (also known as XPro1595, Quellor, and LIVNate) from Xencor. This exclusive, global, unrestricted license came with considerable know-how, intellectual property, pre-clinical data, regulatory documentation and product stocks. Currently, we are focused on the immune-oncology uses of this unique asset. In the future, we may develop the asset in a wide variety of therapeutic areas, with a variety of delivery techniques by ourselves or in conjunction with partners.

Results of Operations

Comparison of the Years Ended December 31, 2020 and December 31, 2019

Revenues

During 2020, the Company sold MSC’s to one third-party and recognized $10,916 of revenues. There were no sales during 2019.

General and Administrative

General and administrative expenses were $6.3 million for the year ended December 31, 2020, compared to $6.0 million for the year ended December 31, 2019. The increase was primarily attributable to higher stock-compensation ($0.2 million higher in 2020), higher insurance expense ($0.2 million higher in 2020) and higher wages and benefits ($0.2 million higher in 2020) partially offset by lower professional fees ($0.4 million lower in 2020).

Research and Development

Research and development expenses increased to $5.9 million for the year ended December 31, 2020 from $3.3 million for the year ended December 31, 2019. During the years ended December 31, 2020 and 2019, the Company recorded stock-based compensation of $0.6 million and $1.8 million, respectively, within research and development expenses. The increase in research and development expenses during the year ending December 31, 2020 compared to December 31, 2019 is due to additional amounts incurred for the advancement of our drug platform and due to the Company incurring manufacturing costs in connection with producing its DN-TNF product.

Waiver of Common Stock Issuable

During the year ended December 31, 2019, the Company reversed $1.5 million of expense as a result of a consultant permanently waiving the Company’s obligation to issue 200,000 shares owed to the consultant which were expensed in a prior period. No similar transaction occurred during the year ended December 31, 2020.

Other Income

Other income increased during the year ended December 31, 2020 compared to 2019 as a result of the Company receiving a refund from a third-party vendor pursuant to a release and settlement agreement of approximately $0.1 million for services provided in a previous year, partially offset by earning lower interest in 2020 compared to 2019.

Liquidity and Capital Resources

Liquidity is the ability of a company to generate funds to support its current and future operations, satisfy its obligations and otherwise operate on an ongoing basis.

We incurred a net loss of $12,099,159 and $7,678,313 for the years ended December 31, 2020 and 2019, respectively. Net cash used in operating activities was $8,943,646 and $5,384,656 for the years ended December 31, 2020 and 2019, respectively. Since inception, we have funded our operations primarily with proceeds from the sales of our common stock and from the receipts of grants. As of December 31, 2020, we had cash and cash equivalents of $22.0 million. We anticipate that operating losses and net cash used in operating activities will increase over the next few years as we advance our products under development.

Our primary uses of capital are, and we expect will continue to be, third-party clinical and preclinical research and development services, costs incurred to manufacture our drugs under development, compensation and related expenses, legal, patent and other regulatory expenses and general overhead costs. We believe our use of CROs provides us with flexibility in managing our spending.

The Company incurs the majority of its research and development expenses in Australia and the United Kingdom. Fluctuations in the rate of exchange between the United States dollar and the pound sterling as well as the Australian dollar could adversely affect our financial results, including our expenses as well as assets and liabilities. We currently do not hedge foreign currencies but will continue to assess whether that strategy is appropriate. As of December 31, 2020, the cash balance held by our foreign subsidiaries with currencies other than the United States dollar was approximately $0.6 million. We do not have any material financial exposure to one customer or one country that would significantly hinder our liquidity.

As of December 31, 2020, the Company had an accumulated deficit of $33,375,340 and working capital of $22,209,460. Losses have principally occurred as a result of stock-based compensation expense as well as the substantial resources required for research and development of the Company’s products which included the general and administrative expenses associated with its organization and product development, as well as the lack of sources of material revenues until such time as the Company’s products are commercialized. As of December 31, 2020, we had cash and cash equivalents of $22.0 million. In addition, during January and February 2021, we raised an additional $29.0 million in gross proceeds through sales of common stock under the ATM program. As such, we believe our cash and cash equivalents, including the proceeds received in January and February 2021, will be sufficient to fund our operations for at least the next 12 months following the filing date of this Annual Report on Form 10-K.

Initial Public Offering

During the year ended December 31, 2019, the Company completed its initial public offering in which the Company sold 1,020,820 shares of its common stock for gross proceeds of $8.2 million (net proceeds of $7.3 million).

April and May sale of common stock

During April and May 2019, the Company sold 522,212 shares of its common stock to certain investors for cash proceeds of $4.7 million, of which the Company’s CEO purchased 11,100 shares for $0.1 million of cash and the Company’s CFO purchased 5,000 shares for $0.1 million of cash.

The Lincoln Park Transaction

On May 15, 2019, the Company entered into the Lincoln Park Purchase Agreement pursuant to which Lincoln Park has agreed to purchase from us up to an aggregate of $20.0 million of the Company’s common stock (subject to certain limitations) from time to time over the 24-month term of the agreement. The Company also entered into a registration rights agreement with Lincoln Park pursuant to which the Company filed with the Securities and Exchange Commission (the “SEC”) the registration statement to register for resale under the Securities Act of 1933, as amended, or the Securities Act, the shares of common stock that have been or may be issued to Lincoln Park under the Purchase Agreement. The registration statement was effective as of July 2, 2019.

As a result, on May 15, 2019, 70,000 newly issued shares of the Company’s common stock were issued to Lincoln Park as consideration for Lincoln Park’s commitment to purchase shares of the Company’s common stock under the agreement, and 30,000 newly issued shares of common stock, valued at $10.00 per share, were sold to Lincoln Park in an initial purchase for an aggregate gross purchase price of $0.3 million ($0.2 million net of offering costs). During the year ended December 31, 2020, the Company issued 196,000 shares of the Company’s common stock to Lincoln Park for gross proceeds of $1,002,644.

Under the terms and subject to the conditions of the Lincoln Park Purchase Agreement, the Company has the right, but not the obligation, to sell to Lincoln Park, and Lincoln Park is obligated to purchase up to, an additional $18.7 million worth of shares of the Company’s common stock. Such future sales of common stock by the Company, if any, will be subject to certain limitations, and may occur from time to time, at the Company’s option, over the 24-month term of the agreement.

As contemplated by the Lincoln Park Purchase Agreement, and so long as the closing price of the Company’s common stock exceeds $3.50 per share, then the Company may direct Lincoln Park, at its sole discretion to purchase up to 20,000 shares of its common stock on any business day. The price per share for such purchases will be equal to the lower of: (i) the lowest sale price on the applicable purchase date and (ii) the arithmetic average of the three (3) lowest closing sale prices for the Company’s common stock during the twelve (12) consecutive business days ending on the business day immediately preceding such purchase date (in each case, to be appropriately adjusted for any reorganization, recapitalization, non-cash dividend, stock split or other similar transaction that occurs on or after the date of the purchase agreement). The maximum amount of shares subject to any single regular purchase increases as the Company’s share price increases, subject to a maximum of $1.0 million.

In addition to regular purchases, the Company may also direct Lincoln Park to purchase other amounts as accelerated purchases or as additional purchases if the closing sale price of the common stock exceeds certain threshold prices as set forth in the purchase agreement. There are no trading volume requirements or restrictions under the purchase agreement nor any upper limits on the price per share that Lincoln Park must pay for shares of common stock.

The Lincoln Park Purchase Agreement and the registration rights agreement contain customary representations, warranties, agreements and conditions to completing future sale transactions, indemnification rights and obligations of the parties. The Company has the right to terminate the purchase agreement at any time, at no cost or penalty. During any “event of default” under the purchase agreement, all of which are outside of Lincoln Park’s control, Lincoln Park does not have the right to terminate the purchase agreement; however, the Company may not initiate any regular or other purchase of shares by Lincoln Park, until such event of default is cured. In addition, in the event of bankruptcy proceedings by or against the Company, the purchase agreement will automatically terminate.

Actual sales of shares of common stock to Lincoln Park under the purchase agreement will depend on a variety of factors to be determined by the Company from time to time, including, among others, market conditions, the trading price of the common stock and determinations by the Company as to the appropriate sources of funding for the Company and its operations. Lincoln Park has no right to require any sales by the Company, but is obligated to make purchases from the Company as it directs in accordance with the purchase agreement. Lincoln Park has covenanted not to cause or engage in any manner whatsoever, any direct or indirect short selling or hedging of the Company’s shares.

ATM Sales Agreement

On April 16, 2020, we entered into a sales agreement with BTIG, as sales agent, to establish an ATM offering program. We were required to pay BTIG a commission of 3% of the gross proceeds from the sale of shares. During the year ended December 31, 2020, we issued and sold 178,600 shares of common stock at an average price of $5.45 per share under the ATM program. The aggregate net proceeds were approximately $0.8 million after BTIG’s commission and other offering expenses.

During January and February 2021, we issued and sold 1,439,480 shares of common stock at an average price of $20.17 per share under the ATM program. The aggregate net proceeds were approximately $28.4 million after offering expenses.

Public Offering

During July 2020, the Company completed an underwritten public offering in which it sold 2,500,000 shares of common stock at a public offering price of $10.00 per share. The 2,500,000 shares sold included the full exercise of the underwriters’ option to purchase 326,086 shares at a price of $10.00 per share. Aggregate net proceeds from the underwritten public offering were approximately $23.1 million, net of approximately $1.9 million in underwriting discounts and commissions and offering expenses.

Grants

During 2019, the Company was awarded a $1.0 million grant from the Alzheimer’s Association to advance XPro1595, a novel therapy targeting neuroinflammation as a cause of Alzheimer’s disease. The endowment was awarded under the Part the Cloud to RESCUE grant. During the years ended December 31, 2020 and 2019, the Company received $0.1 million and $0.9 million, respectively, related to the grant, which the Company recorded as a reduction of research and development expense. As of December 31, 2020, the Company has received $1.0 million of cash proceeds from the Alzheimer’s Association and no additional amounts are available to the Company pursuant to this grant.

During the year ended December 31, 2020, the Company was awarded a $0.5 million grant from the Amyotrophic Lateral Sclerosis (“ALS”) Association to fund a study of the efficacy of XPro1595 to reverse ALS in vitro and to fund a study of the efficacy of XPro1595 to protect against ALS model phenotypes in vivo. During the year ended December 31, 2020, the Company received $0.3 million of cash proceeds pursuant to this grant which the Company recorded as deferred liabilities. During the year ended December 31, 2020, the Company recorded $0.2 million as a reduction of research and development expense related to the ALS grant. As of December 31, 2020, the Company recorded $0.1 million as deferred liabilities in the consolidated balance sheet related to the ALS grant.

During September 2020, the Company was awarded a grant of up to $2.9 million from the National Institutes of Health (“NIH”). As of December 31, 2020, the Company has not received any proceeds pursuant to this grant. 

Cash Flows

The following table provides information regarding our cash flows for the years ended December 31, 2020 and 2019:

Net Cash Used in Operating Activities

Our cash used in operating activities was primarily driven by our net loss.

Operating activities used $8.9 million of cash for the year ended December 31, 2020, primarily resulting from our net loss of $12.1 million, partially offset by non-cash stock-based compensation charges of $3.1 million.

Operating activities used $5.4 million of cash for the year ended December 31, 2019, primarily resulting from our net loss of $7.7 million, a net cash outflow of $0.3 million for changes in our net operating assets and liabilities, offset by non-cash stock-based compensation charges of $4.1 million, partially offset by a waiver of common stock issuable of $1.5 million. The change in our net operating assets and liabilities was primarily due to a decrease in accounts payable and accrued liabilities of $0.2 million and a $0.1 million increase in prepaid expenses.

Net Cash Provided by Financing Activities

During July 2020, the Company completed an underwritten public offering in which it sold 2,500,000 shares of common stock at a public offering price of $10.00 per share. Aggregate net proceeds from the underwritten public offering were approximately $23.1 million, net of approximately $1.9 million in underwriting discounts and commissions and offering expenses.

During the year ended December 31, 2020, the Company purchased 220,000 shares from an investor for approximately $1.0 million. In addition, the Company sold 196,000 shares of its common stock to Lincoln Park for cash proceeds of approximately $1.0 million.

During the year ended December 31, 2020, the Company issued and sold 178,600 shares of common stock at an average price of $5.45 per share under the ATM program for net cash proceeds of approximately $0.8 million.

During February 2019, the Company completed its initial public offering in which the Company sold 1,020,820 shares of its common stock for gross proceeds of approximately $8.2 million (net proceeds of approximately $7.3 million).

During April and May 2019, the Company sold 522,212 shares of its common stock to certain investors for cash proceeds of approximately $4.7 million of which the Company’s CEO purchased 11,100 shares for $119,325 of cash and the Company’s CFO purchased 5,000 shares for $53,550 of cash.

On May 15, 2019, the Company sold 30,000 shares of its common stock to Lincoln Park for $300,000 in gross cash proceeds (net cash proceeds of $230,000) and issued 70,000 shares of its common stock to Lincoln Park pursuant to the terms of the purchase agreement as consideration for its commitment to purchase shares under the purchase agreement.

Item 7A. Quantitative and Qualitative Disclosures about Market Risk

We are exposed to market risk from changes in foreign currency rates.

Item 8. Financial Statements and Supplementary Data

INDEX TO CONSOLIDATED FINANCIAL STATEMENTS

REPORT OF INDEPENDENT REGISTERED PUBLIC ACCOUNTING FIRM

To the Stockholders and the Board of Directors of

INmune Bio, Inc.

La Jolla, California

Opinion on the Financial Statements

We have audited the accompanying consolidated balance sheets of INmune Bio, Inc. (the “Company”) as of December 31, 2020 and 2019, the related consolidated statements of operations and comprehensive loss, stockholders’ equity and cash flows for the years ended December 31, 2020 and 2019, and the related notes (collectively referred to as the “financial statements”). In our opinion, the financial statements present fairly, in all material respects, the financial position of the Company as of December 31, 2020 and 2019, and the results of its operations and its cash flows for the years ended December 31, 2020 and 2019, in conformity with accounting principles generally accepted in the United States of America.

Basis for Opinion

These financial statements are the responsibility of the Company’s management. Our responsibility is to express an opinion on the Company’s financial statements based on our audits. We are a public accounting firm registered with the Public Company Accounting Oversight Board (United States) (“PCAOB”) and are required to be independent with respect to the Company in accordance with the U.S. federal securities laws and the applicable rules and regulations of the Securities and Exchange Commission and the PCAOB.

We conducted our audits in accordance with the standards of the PCAOB. Those standards require that we plan and perform the audits to obtain reasonable assurance about whether the financial statements are free of material misstatement, whether due to error or fraud. The Company is not required to have, nor were we engaged to perform, an audit of its internal control over financial reporting. As part of our audits we are required to obtain an understanding of internal control over financial reporting but not for the purpose of expressing an opinion on the effectiveness of the Company’s internal control over financial reporting. Accordingly, we express no such opinion.

Our audits included performing procedures to assess the risks of material misstatement of the financial statements, whether due to error or fraud, and performing procedures that respond to those risks. Such procedures included examining, on a test basis, evidence regarding the amounts and disclosures in the financial statements. Our audits also included evaluating the accounting principles used and significant estimates made by management, as well as evaluating the overall presentation of the financial statements. We believe that our audits provide a reasonable basis for our opinion.

/s/ Marcum LLP

Marcum LLP

We have served as the Company’s auditor since 2017.

Houston, Texas

March 4, 2021

INMUNE BIO, INC.

CONSOLIDATED BALANCE SHEETS

See accompanying notes to these consolidated financial statements.

INMUNE BIO, INC.

CONSOLIDATED STATEMENTS OF OPERATIONS AND COMPREHENSIVE LOSS

FOR THE YEARS ENDED DECEMBER 31, 2020 AND 2019