ITEM 1. Business

 

Overview

 

Unless otherwise provided in this Annual Report, references to the “Company,” “we,” “us,” and “our” and similar references refer to Celcuity Inc., a Delaware corporation. We own various unregistered trademarks and service marks, including our corporate logo. Solely for convenience, the trademarks, trade names and service marks in this Annual Report, including those owned by third parties, may be referred to without the ®,TM or SM symbols, but such references should not be construed as any indicator that the owner of such trademarks, trade names and service marks will not assert, to the fullest extent under applicable law, their rights thereto. We do not intend the use or display of other companies’ trademarks, trade names and service marks to imply an endorsement or sponsorship of us by any other companies.

 

We are developing companion diagnostic tests designed to expand the eligible patient populations for targeted therapies by discovering new cancer sub-types molecular-based approaches cannot detect. Our proprietary CELsignia (previously known as “CELx”) diagnostic platform is the only commercially ready technology we are aware of that uses a patient’s living tumor cells to identify the specific abnormal cellular process driving a patient’s cancer and the targeted therapy that best treats it. We believe our CELsignia platform provides two important improvements over traditional molecular diagnostics. First, molecular diagnostics can only provide a snapshot of the genetic mutations present in a patient’s tumor because they analyze fixed (i.e., dead) cells. Using fixed cells prevents molecular diagnostics from analyzing the dynamic cellular activities, known as cell signaling, that regulate cell proliferation or survival. Cancer can develop when certain cell signaling activity becomes abnormal, or dysregulated. Since genetic mutations are often only weakly correlated to the dysregulated cell signaling activity driving a patient’s cancer, a molecular diagnostic is prone to providing an incomplete diagnosis. CELsignia tests overcome this limitation by measuring dynamic cell signaling activity in a cancer patient’s living tumor cells. When a CELsignia test detects abnormal signaling activity, a more accurate diagnosis of the patient’s cancer driver is obtained. Second, molecular diagnostics can only estimate the probability of a patient’s potential drug response based on a statistical analysis of the drug’s clinical trial results. Instead of this indirect estimate of drug response, CELsignia tests confirm that a targeted therapeutic matches the patient’s cancer driver, which significantly increases the likelihood of a positive clinical outcome.

 

Our first analytically validated and commercially ready test using our CELsignia platform is our CELsignia HER2 Signaling Function Test, or CELsignia HSF Test. Our CELsignia HSF Test diagnoses two new sub-types of HER2-negative breast cancer that traditional molecular diagnostics cannot detect. Our internal studies show that approximately 15%-20% of HER2-negative breast cancer patients have abnormal HER2 signaling activity similar to levels found in HER2+ breast cancer cells. As a result, these HER2-negative patients have undiagnosed HER2-driven breast cancer and would be likely to respond to the same anti-HER2 targeted therapies only HER2+ patients receive today. Our CELsignia HSF Test is targeting HER2-negative breast cancer patients receiving drug treatment.

 

Our second CELsignia test for breast cancer evaluates independent c-Met signaling activity and its involvement with HER family signaling in HER2-negative breast cancer tumor cells. Our internal studies have found that approximately 20%-25% of HER2-negative breast cancer patients have abnormal c-Met signaling activity that is co-activated with abnormal HER family signaling. These studies suggest that this sub-group of HER2-negative breast cancer patients may best respond to treatment with a combination of HER family and c-Met inhibitors.

 

We completed development of our third CELsignia test for breast cancer during the fourth quarter of 2019. This new test evaluates PI3K signaling in HER2-negative breast cancer tumor cells. Our internal studies demonstrate how measurement of PI3K-involved signaling may provide a more sensitive and specific method of identifying patients most likely to benefit from PI3K inhibitors than current genetic tests that measure PI3K mutations.

 

We intend to combine these three tests to create the CELsignia Multi-Pathway Signaling Function Test, or CELsignia MP Test. With this next generation CELsignia test, we plan to provide an analysis of HER1, HER2, HER3, c-MET, and PI3K-node involved signaling activity for each patient tumor specimen received.

 

In addition to the five new breast cancer sub-types our CELsignia MP Test diagnoses, we discovered 11 new potential cancer sub-types in breast, lung, colon, ovarian, kidney, and bladder cancers. Approved or investigational drugs are currently available to treat each of these new potential cancer sub-types. CELsignia tests for these additional cancer sub-types are in various stages of development, and we expect them to become commercially ready on a staggered basis over the next few years. The development process for these additional CELsignia tests includes completion of internal animal, verification, training set, and validation studies. As new CELsignia tests become commercially ready, we expect to initiate collaborations with pharmaceutical companies to help them obtain new drug indications for the new cancer sub-types our tests identify. In addition, we will continue our research to identify additional new cancer sub-types and to develop the corresponding CELsignia tests to diagnose them.

 

 

Our overall commercialization strategy is to develop companion diagnostics that identify new cancer sub-types and to seek collaborations with pharmaceutical companies, which can vary in scope. We have two collaborations underway that rely on the CELsignia HSF Test to select breast cancer patients for treatment with HER2 targeted therapies. For the first one of these collaborations, we are fielding a prospective clinical trial with Genentech, Inc. (“Genentech”) and NSABP Foundation, Inc. (“NSABP”) to evaluate the efficacy of Genentech’s HER2 targeted therapies in patients with these newly identified cancer sub-types. We expect interim results from this trial in early-to-mid-2021 and final results approximately nine months later. For the second of these collaborations, we are fielding a prospective clinical trial with Puma Biotechnology, Inc. (“Puma”) and West Cancer Center to evaluate the efficacy and safety of Puma’s drug, Nerlynx, and chemotherapy in breast cancer patients selected with our CELsignia HSF Test. We expect to obtain interim results in mid-2021and final results approximately 9-12 months later.

 

For a third collaboration, we were selected by NSABP and Puma to evaluate tissue samples from a Phase II study evaluating Puma’s pan-HER inhibitor, Nerlynx, Genentech’s HER2 antibody, Herceptin, and Bristol-Myers Squibb’s EGFR inhibitor, Erbitux, in metastatic colorectal cancer patients. This 35-patient study is expected to be completed in late 2021. Unlike the trial with NSABP and Genentech, our CELsignia test will be used solely to evaluate tissue samples after they have been enrolled in this trial. We will not receive payment for the testing we perform. We expect our CELsignia test will provide critical insight after the trial is completed about the patient characteristics most correlative to drug response.

 

In conjunction with the development of the CELsignia MP Test, we will seek collaborations with pharmaceutical companies to field clinical trials that evaluate the efficacy of combining HER family inhibitors and c-Met inhibitors in breast cancer patients who have abnormal c-Met and abnormal HER-family pathway activity. The FDA has approved two c-Met inhibitors and six HER-family inhibitors for cancer treatment. Additional c-Met and HER-family inhibitors are being evaluated in on-going clinical trials. Several pharmaceutical companies possess both a c-Met and a HER family inhibitor. We will also seek collaborations with pharmaceutical companies to field clinical trials that evaluate the efficacy of PI3K inhibitors in breast cancer patients who have abnormal PI3K-node involved signaling activity. The FDA has approved several PI3K inhibitors for cancer treatment and additional PI3K inhibitors are being evaluated in on-going clinical trials.

 

While molecular tests identify increasing numbers of genetic variants in tumor tissue, determining the dysfunction driving most patient’s cancer using molecular tests remains elusive. Less than 20% of Americans who died of cancer in 2018 were eligible for a molecular targeted therapy because they lacked what are currently considered actionable genetic or proteomic mutations. This reflects the limitations of using static measurements of proteins or genetic mutations in fixed cells to characterize the dynamic and complex cell signaling activity that may be driving a patient’s cancer.

 

Directly measuring dynamic cell signaling activity is an alternative diagnostic approach to identify the cancer driver in patient tumors lacking actionable genomic or proteomic mutations. This approach requires the use of living patient tumor cells as well as technology to quantify signaling activity levels. Efforts to obtain patient tumor cells have previously been limited by the lack of reliable methods to extract and culture cancer cells from patient tumors. Lack of access to living patient tumor cells, in turn, hampered development of technology to analyze dynamic signaling activity.

 

Our CELsignia platform addresses the need for better cancer diagnostic tests using two complementary technologies that represent a significant departure from molecular-based analyses. Unlike molecular tests that use fixed or lysed (i.e., dead) cells and can only measure the static composition of a cell, our CELsignia platform measures real-time signaling activity in a patient’s live tumor cells. This enables us to (1) identify the cellular signaling dysfunction driving a patient’s cancer; and (2) identify the targeted therapy that matches the dysfunction in the patient’s cells. Our CELsignia tests are performed in our laboratory in Minneapolis, Minnesota that is certified under the Clinical Laboratory Improvement Amendments of 1988, or CLIA, and accredited by the College of American Pathologies, or CAP.

 

Our platform, comprised of our internally developed cell microenvironment and cell signaling quantification technologies, allows for more accurate diagnoses and the discovery of new cancer sub-types. We believe our CELsignia platform will fundamentally change the standard-of-care many cancer patients receive. Patients with the newly identified cancer sub-types we have discovered have oncogenic pathways that are signaling abnormally, and, we believe, may respond positively to a matching targeted therapy. By identifying patients with a new cancer sub-type, each CELsignia test will create, in effect, a proprietary patient population that molecular diagnostics cannot identify.

 

Our initial commercial strategy is to partner with pharmaceutical companies to provide companion diagnostics for the pharmaceutical partners’ existing or investigational targeted therapies. We expect such partnerships to involve collaboration on clinical trials, regulatory submissions, and commercialization activities. We will initiate activities to pursue partnerships as our CELsignia tests become commercially ready and can be matched with a potential partner’s targeted therapies. Our commercial-related efforts to date have focused on seeking partnerships for our CELsignia HSF and CELsignia MP tests, which became commercially ready as a laboratory developed test (“LDT”) in 2016 and 2018, respectively. We expect to seek pharmaceutical partnerships for a variety of different targeted therapies in other solid tumor types as we are conducting our initial clinical trials with Genentech’s and Puma’s targeted therapies.

 

We believe our CELsignia tests will expand the matching drug’s market size because they can facilitate approval of new drug indications that a pharmaceutical company would not otherwise be able to obtain. We expect that successful pharmaceutical company partnerships will generate significant revenue from the sale of tests to identify patients eligible for clinical trials, from milestone payments, and, potentially, from royalties on the incremental drug revenues our tests enable. A key requirement for success of these partnerships will be clinical trial results that demonstrate the advantages of using a CELsignia test as a companion diagnostic. Once a new drug indication is received that requires use of the CELsignia test to identify eligible patients, we will offer our tests directly to treating physicians and coordinate go-to-market strategies with our partner. This coordination of commercialization strategies will allow us to significantly leverage the sales, marketing and reimbursement resources of our pharmaceutical partner, unlike traditional molecular diagnostic companies.

 

 

Our Value Proposition

 

We believe we offer a clear and compelling value proposition to the key healthcare stakeholders:

 

 

 

 

Our Competitive Strengths

 

We have a number of key strengths that enhance our ability to achieve our mission and build a successful company:

 

 

 

 

 

 

 

Our Platform Advantages

 

Our unique and proprietary CELsignia functional cellular analysis technology represents a major shift from the diagnostic industry’s reliance on molecular profiling to characterize a patient’s cancer sub-type. Our goal is to leverage our technology to build a durable competitive advantage that enables us to improve outcomes for a significant percentage of cancer patients.

 

Our CELsignia platform advantages include:

 

 

 

 

 

 

 

Our Industry

 

According to the Centers for Disease Control and Prevention, cancer was the second-leading cause of death in the United States in 2018, responsible for nearly one of every four deaths. There are many types of cancer treatment options, including surgery, radiation therapy, chemotherapy, immunotherapy, hormone therapy, stem cell transplant, and targeted therapy. Targeted therapies are drugs or other substances that block the growth and spread of cancer by interfering with specific molecular targets involved in the progression of cancer. Targeted therapies differ from standard chemotherapy drugs in that they are often cytostatic (block tumor cell proliferation) rather than cytotoxic (kill tumor cells). According to the National Cancer Institute, there are currently more than 90 approved targeted oncology therapies, some of which cost more than $100,000 per treatment course.

 

Diagnostic tests to detect single biomarkers are now widely used by pathologists to determine the molecular sub-type of a cancer. When a molecular biomarker test is used to support the choice of therapy to prescribe, it is often referred to as a “companion diagnostic.” Increasing numbers of targeted therapeutics are prescribed based on the results from a companion diagnostic test to detect the presence of a molecular biomarker. Only patients testing positive for the biomarker are eligible to receive the associated therapy.

 

Companion diagnostics are becoming increasingly important to the pharmaceutical industry. The use of companion diagnostics to better match patients to effective treatments positively impacts clinical outcomes and lowers expenditures on drugs that do not benefit patients. Stratifying the eligible patient population to include only likely responders is particularly important when the percentage of likely responders is only a fraction of the total cancer population. In these circumstances, narrowing the eligible patient population is often necessary to meet the clinical endpoint targets required to receive FDA drug approval.

 

 

Our Market Opportunities

 

Companion Diagnostic Development Opportunities

 

We believe there at least 50 different potential opportunities for our company to collaborate on companion diagnostic programs with pharmaceutical companies. Our ability to develop partnering relationships with these pharmaceutical companies will be predicated on a number of factors, including the size of the patient population our CELsignia test identifies, the remaining patent life of the matching targeted therapy, as well as the success or failure of clinical trials we have conducted with other pharmaceutical companies. Completing clinical trials requires, among other things, successful enrollment of patients, meeting trial endpoint goals, and completing the trial in a timely manner. The time to complete a clinical trial can vary widely depending on a number of factors, many of which will be specific to any particular clinical trial.

 

We believe the revenue opportunity per companion diagnostic program will be consistent with other development programs pharmaceutical companies support. In addition, the revenue for an individual companion diagnostic program would represent only a small fraction of the potential value the new drug indication our companion diagnostic could create for our pharmaceutical company partner. For some drugs, our tests could double the number of patients eligible for a targeted therapy.

 

CELsignia Testing Opportunities

 

We expect to generate recurring companion diagnostic testing revenues once a CELsignia companion diagnostic-linked drug therapy is approved for patient use. On average, we believe that the lifetime value of providing the companion diagnostic test will significantly exceed the revenue generated from the companion diagnostic development program. We expect to offer each CELsignia test to patients at prices ranging from $4,000–$7,000, depending on the number of pathways evaluated. No tests directly comparable to the CELsignia tests are available today to offer reference points for pricing purposes. Pricing for several proprietary complex genomic tests, however, fall within this range and we believe this provides guidance on the amount insurance companies are willing to pay for highly informative tests that guide patient care.

 

CELsignia Technology Background

 

The Role of Cellular Signaling Pathways in Cancer

 

Cancer is a class of exceedingly complex and diverse diseases characterized by the development of abnormal cells that divide uncontrollably and can infiltrate and destroy normal body tissue and disrupt normal organ function. In normal cells, a series of biochemical activities, known as signal transduction, transmit biochemical signals through an interconnected network of signaling pathways to control cell proliferation and survival. Cancer arises when alterations occur in one or more of these signaling pathways and normal cell processes are disrupted, resulting in uncontrolled cell proliferation. These alterations are driven by a variety of cellular aberrations, including genetic mutations and dysregulated signaling pathway mechanisms. Identifying the alteration driving an individual’s cancer is complicated by the immense complexity of these signal transduction processes and the practically unquantifiable number of pathway variables.

 

As recently as 20 years ago, most cancers were classified and subsequently treated solely on the basis of the anatomical location of the tumor in the body. Chemotherapies that kill rapidly dividing cells were widely used, but they had only limited efficacy for many patients and caused a wide range of dangerous side effects due to lack of discrimination for tumor tissue. As tools to identify molecular mutations became available, scientists began to uncover correlations between certain molecular mutations, cancer tissue type, and a patient’s prognosis. This fostered the development of molecularly targeted therapeutics that were designed to disrupt the specific cellular function of the drug target, typically abnormal signaling pathway activity, associated with the molecular mutation. These targeted therapies greatly improved outcomes for some cancer patients and are a testament to the efficacy of targeted therapies when effectively prescribed. According to information published by the Journal of Clinical Oncology in July 2015, targeted therapies are oftentimes 10 to 20 times more expensive than chemotherapies.

 

In conjunction with the advent of targeted therapies, new molecular diagnostics were developed to help physicians refine the classification of a patient’s cancer into sub-types based on the presence of specific molecular anomalies, such as genetic mutations or over-expressed proteins. Such mutations or over-expressed proteins are commonly referred to as “biomarkers” when they are used to diagnose a disease and evaluate treatment options. For instance, breast cancer diagnostic tests are performed to determine whether two protein biomarkers, human epidermal growth factor receptor 2 (HER2) or estrogen receptors (ER), are overexpressed in the cancer cells. The results of these tests are used to classify the patient’s cancer molecular sub-type and to guide selection of a corresponding targeted drug therapy.

 

The launch and on-going development of many new targeted therapies and the increasing use of companion molecular diagnostics to guide selection of the most appropriate therapy for each patient ushered in the era of so-called “precision medicine” in oncology. Advances in genomic and proteomic techniques and drug discovery enabled researchers to identify new drug targets, new molecular diagnostics, and drugs that would specifically bind to the target.

 

While the increased usage of targeted therapies has improved patient outcomes, there is increasing recognition that the promise of molecularly guided diagnoses and targeted treatment has fallen far short of expectations. This is generally due to the heterogeneous nature of these diseases from patient to patient and the challenge of identifying the specific cellular dysfunction driving a cancer patient’s tumor growth. No matter how sophisticated or detailed, a point-in-time molecular profile can only provide a snapshot of a tumor. As a result, the genetic mutations many current tests identify are often only weakly correlated to the abnormal signaling driving a patient’s cancer. This is because protein and gene profiling provide an incomplete assessment of the biochemical activity promoting cancer tumor growth. In fact, when dysregulated, the activity of signaling pathway networks are, we believe, not possible to assess using current genetic analyses, despite the impressive investments in mapping the human genome and advancements in techniques to identify molecular mutations.

 

 

 

Our CELsignia Platform

 

We have made significant investments in research and development to build the first commercially-ready cancer diagnostic platform that we are aware of that measures the signaling pathway activity in a patient’s living tumor cells. To measure dynamic cellular activity, we internally developed two distinct but complementary technologies, which now comprise our CELsignia platform:

 

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Cell microenvironment. Previous research has shown that cancer cells extracted from a patient’s tumor share the molecular features of the primary cancers from which they were derived and could provide an ex vivo (outside the patient) model of a patient’s tumor. The technology around tumor cell extraction from individual patients and culturing techniques, however, has largely remained undeveloped. For instance, we are not aware of any competing diagnostic tests that use live patient tumor cells to measure dynamic cell signaling activity. Studies on the topic have historically highlighted the challenges of deriving a viable patient tumor cell sample from an individual patient tumor specimen.

 

We have developed a cell microenvironment to extract and expand viable tumor cells from fresh human tumor tissue, which meets the three critical clinical parameters a patient-derived tumor cell sample would need to satisfy in order to meet the regulatory and clinical requirements for a diagnostic test measuring signaling activity:

 

 

Dynamic patient cell signaling quantification. The second component of our CELsignia platform involves methods to quantify specific dynamic signal transduction events in patient derived tumor cells. The complexity of signal transduction processes is immense, and the permutations of the pathway variables are practically unquantifiable. Current analytical methods to assess these variables use fixed or lysed (i.e., dead) cells. Point-in-time measurements are limited to assessment of the compositional status (e.g., mutation), concentration level (e.g., protein amount), or activation status (e.g., phosphorylation) of a finite number of signaling pathway components. A key insight underlying our technology was our observation that, no matter how sophisticated or detailed, a point-in-time molecular profile would only provide a snapshot. These methods could not provide a complete, dynamic assessment of the signaling activity driving a patient’s cancer. These point-in-time molecular analyses would, in many cases, only provide a weak correlation to the presence of the signaling pathway dysfunction driving a patient’s cancer. Instead, we concluded that a complete diagnosis of cancer and an assessment of a patient’s response to treating their disease requires measurement of the underlying activity of signaling pathways in live patient tumor cells.

 

 

To measure live real-time dynamic cell signaling activity, we utilize an impedance biosensor instrument. An impedance biosensor is an analytical platform that converts changes in cellular activity to a measurable electrical signal. When cells are stimulated and change their function, the accompanying changes alter the electrical signal that is measured. The output value is quantified over time and used to determine a Signaling Function Score. To determine the activity of a specific signaling pathway, an activating agent specific to a pathway receptor is used to turn on the pathway and a corresponding inhibitory agent specific to the pathway receptor is used to turn signaling off. When signaling pathways are stimulated in this manner, a change in the electrical signal occurs and Signaling Function Score recorded. By relying on the principle of detecting signaling pathway activity, we believe we can develop tests for a range of disease types and targeted therapies that affect various cellular pathways. 

 

We believe our pioneering efforts have substantially advanced the technology of culturing primary tumor cells and analyzing cell signaling activity to guide therapy selection. We have two issued U.S. patents, one issued international patent, six pending U.S. patent applications, 27 pending non-U.S. patent applications, and one pending international PCT patent application, as well as significant proprietary know-how and trade secrets for the various cell sample preparation and cellular analysis methods we have developed.

 

New Product Development

 

We are leveraging our CELsignia technology to discover new cancer sub-types that a genomic test cannot detect. These new sub-types are characterized by the hyperactive signaling pathway our test identifies. These sub-types cannot be detected by genomic tests because they lack a corresponding molecular biomarker to identify it. We will translate our discoveries into companion diagnostic tests.

 

We have already discovered several new breast cancer sub-types: HER2-negative breast cancers that are ER-positive or ER-negative with either (i) abnormal HER2 signaling, (ii) abnormal HER-family signaling coincident with abnormal c-Met signaling, and (iii) abnormal PI3K signaling.

 

We are currently conducting research to identify additional cancer sub-types in five solid tumor types. Our research studies to date have identified 11 potentially new breast, lung, ovarian, kidney, and bladder cancer sub-types that involve dysregulated oncogenic signaling pathways. Multiple dysregulated pathways were active in each of these tumor types. These studies confirm that the CELsignia platform can be a cancer sub-type discovery engine and that we can create a multi-pathway test to identify the specific driver in a patient’s tumor. We expect to eventually expand the tumor types we evaluate to include colon, head and neck, leukemia, esophageal, and gastric cancers.

 

We will seek to identify individual signaling pathways that may be driving at least 5% to 10% of the total cancers in each tissue area. Once we have characterized the prevalence of the different sub-types of signaling dysfunction in each tumor type and validated the tests for the different pathways, our plan will be to launch a corresponding CELsignia test. Eventually, each CELsignia test will analyze multiple pathways in a patient’s tumor to identify the specific pathway dysfunction driving a patient’s cancer. Testing multiple pathways will thus provide a system view of the patient’s cancer using dynamic functional analysis. We believe this will result in more accurate diagnosis of a patient compared to molecular diagnostics that are using next generation sequencing to assess the status of multiple static biomarkers.

 

Clinical Trial Approach

 

A major component of our development and commercial activities is providing clinical data from interventional clinical trials using our CELsignia tests. Our clinical trial strategy is predicated on proving the correlation between our CELsignia Signaling Function Score and a patient’s clinical results. Once our first trial demonstrates that our CELsignia test identifies patients responsive to targeted therapies, we expect pharmaceutical companies to partner with us to fund trials to evaluate new potential indications for their drugs with patients identified by one of our CELsignia tests. The trials will be designed to confirm that patients with abnormal pathway signaling obtain a superior clinical response to a therapy targeting that pathway than to the standard-of-care therapy they currently receive.

 

For trials involving patients not currently eligible for a cancer drug that targets a certain pathway, we would first obtain a tissue specimen from each subject and perform the CELsignia test to identify subjects who have abnormal signaling. These patients would then be randomly assigned to either an arm that receives the current standard-of-care therapy or one that includes the current standard-of-care therapy plus the targeted therapy. All patients would be monitored until their disease progresses or until the end of the treatment regimen.

 

 

CELsignia Multi-Pathway Signaling Function Test

 

Our CELsignia MP Test is a qualitative LDT that measures HER2, c-Met, and PI3K signaling activity in tumor cells obtained from patients previously diagnosed with HER2-negative breast cancer that is either ER-positive or ER-negative to determine whether or not the patients have one of the following cancer sub-types:

 

 

 

 

Abnormal HER2 Signaling Driven Cancer

 

Approximately 15% of breast cancer patients are diagnosed with HER2+ breast cancer when their tumor cells are found to have overexpressed or amplified levels of HER2. These patients are treated with anti-HER2 targeted therapies in combination with chemotherapies. Results from a number of clinical trial results for HER2 drugs reveal that only about 40% of HER2-positive patients respond to them. In addition, findings from several clinical trials have shown that a sub-set of HER2-negative patients benefit from therapies that target HER2. These results highlight the relatively weak correlation between HER2 receptor or gene amplification status and drug response.

 

Despite the widely recognized role that a dysregulated HER2-related signaling network plays in promoting breast cancer, only tests measuring a single reactant, HER2 protein, are performed in the clinic to diagnose it; we believe no diagnostic tests are available today that measure HER2 signaling activity within a patient’s breast tumor epithelial cells. This focus on measuring HER2 expression-levels reflects the widely-held view that measuring a patient’s HER2 status is sufficient to diagnose HER2-driven breast cancers. When only HER2 expression is measured, though, patients classified as HER2-negative but whose tumor cells have abnormal HER2 signaling are diagnosed as not having HER2-driven breast cancer, when, in fact, they do.

 

Since current genomic methods cannot identify HER2-negative breast cancer patients who have the HER2-driven cancer, a new method was required. Such a method would need to analyze the HER2-signaling pathways (MAPK and PI3K) associated with HER2 cancers in a patient’s tumor cells. Our CELsignia MP Test identifies patients whose HER2 status as determined by conventional techniques does not represent the correct diagnosis of their breast cancer at a functional level.

 

For the sub-group of HER2-negative breast cancer patients diagnosed with abnormal HER2-signaling, it would be intended that they receive treatment with HER2 therapies.

 

Abnormal c-Met Signaling coincident with Abnormal HER2 signaling

 

Signaling through c-Met is necessary for normal cell development. Numerous studies have established the significant role of the c-Met pathway in tumor growth and metastasis. Cross-talk between c-Met and HER family receptors is also suspected of playing a role in tumor progression and resistance to HER targeted therapies. Numerous clinical trials have evaluated dual inhibition of c-Met and HER pathways in a variety of tumor types, but they have produced mostly negative results. Since subjects enrolled in these trials were primarily ones with c-Met protein overexpression or gene amplification, other biological factors, such as c-Met and HER signaling activity, are likely more important to measure when identifying patients eligible for c-Met therapies.

 

Our recent studies found that a subset of HER2-negative breast cancer patients has abnormal c-Met signaling coincident with abnormal HER2 signaling. The c-Met expression level of each patient studied was normal. Strong evidence was found that c-Met and HER2 signaling is co-involved and may explain why a c-Met tyrosine kinase inhibitor is not an effective antagonistic when c-Met is hyperactive for this patient sub-set. Additionally, evidence was found that simultaneous inhibition of HER1, HER2, and HER3 signaling, in addition to inhibition of c-Met signaling, was necessary to inhibit HER2 and c-Met signaling activity most effectively.

 

For the sub-group of HER2-negative breast cancer patients diagnosed with abnormal c-Met and HER2-signaling, it would be intended that they receive treatment with a combination of pan-HER and c-Met inhibitors.

 

Abnormal PI3K Signaling Tumors

 

The PI3K signaling pathway is a key regulator of normal cellular processes involved in cell growth, proliferation, metabolism, motility, survival, and apoptosis. Aberrant activation of the PI3K pathway promotes the survival and proliferation of tumor cells in many human cancers. In breast cancer, only patients with certain PI3K mutations are eligible for treatment with a PI3K inhibitor. However, recent clinical trial results suggest that factors other than the mutational status of PI3K may be important to measure when identifying patients eligible for PI3K inhibitors. Less than 20% of PI3K mutated late stage breast cancer patients achieved an objective response in a Phase III clinical trial with alpelisib, a recently approved PI3K inhibitor.

 

Our studies found hyperactive PI3K involved signaling in a sub-set of HER2-negative breast cancer patients. Strong evidence was found that pan-PI3K inhibitors, rather than inhibitors targeting PI3K-a, may provide the most effective attenuation of dysregulated signaling involving the PI3K-node. Our studies also found that the signaling activity involving PI3K-a is likely more important to measure than the mutational status of PI3K-a when selecting patients for treatment with a PI3K-a inhibitor like alpelisib.

 

 

Interventional Clinical Trials in Process using a CELsignia Test to Select Patients for Treatment

 

FACT 1 Clinical Trial to Evaluate Efficacy of Genentech’s HER2 Drugs

 

In July 2018, we activated a clinical trial with NSABP to evaluate the efficacy and safety of Genentech’s drugs, Herceptin (trastuzumab) and Perjeta (pertuzumab), and chemotherapy, in breast cancer patients selected with our CELsignia test. NSABP serves as the sponsor and principal investigator of the trial and is responsible for, among other things, setting up clinical sites, enrolling patients, and managing clinical data. NSABP contracted separately with Genentech to provide Herceptin and Perjeta for the study at no cost. We are performing the CELsignia HSF Test to select patients for the trial and are providing the funding for the trial’s patient-related costs. Completing this trial will require, among other things, successful enrollment of patients, meeting trial endpoint goals, and completing the trial in a timely manner. As of February 2020, there were 27 activated sites participating in the FACT 1 trial. The enrollment rate of patients has fallen short of the expectations NSABP originally provided. Based on NSABP’s updated estimates of patient enrollment rates, we expect to obtain interim results in early-to-mid 2021 and final results approximately nine months later.

 

NSABP is one of the country’s premier clinical research cooperatives. Its members include many of the country’s leading medical centers and their investigators are amongst the most-respected in the breast cancer field. Genentech is one of the largest biopharmaceutical companies in the world and was the first company to launch a HER2 targeted therapy; their anti-HER2 targeted therapies have roughly 95% market share.

 

We submitted an Investigational Device Exemption, or IDE, application to the FDA to obtain approval to use our CELsignia HSF Test in a clinical trial setting. The IDE submission included validation test protocols and study reports, manufacturing process summaries, and relevant publications. The FDA approved our IDE in early 2017.

 

The goal is to demonstrate that patients who have an abnormal HER2 signaling pathway, as identified by our CELsignia test, respond to treatment with a matching targeted therapy. A synopsis of the trial protocol is provided below.