Non-discriminating cancer therapies, including chemotherapy and radiation, marginally differentiate between tumour and healthy cells. However, these therapies have defined the paradigm of cancer therapy for the last 50 years. Current forms of cancer therapies manifest serious side effects including edema, hair loss, nausea, internal bleeding, vomiting, fatigue, muscle/joint pain and others. Antibody drug conjugates (ADCs) are a class of therapeutics that harness the antigen-selectivity of antibodies to deliver highly potent cytotoxic drugs to antigen-expressing tumour cells. New effective and less-invasive technology are needed: with approximately 14 million new cases and 8.2 million cancer related deaths in 2012 worldwide, there is an increasing urgency to find more cures for more patients. Solutions are needed to improve life quality for patients undergoing treatment and also eliminating cancer, while decreasing rates of recurrence and relapse. OncoLinx has developed an ADC platform that will create the next generation of ADC therapies with Azonafide payloads specifically targeting cancer cells, while sparing healthy cells—resulting in superior treatment and manageable, milder side effects. Oncolinx’s platform is composed of the payload (Azonafide) and a chemical linker sequence, whose technical features make this drug complex when coupled to any antibody and therefore targeting any possible cancer type. The Azonafide platform has the unique ability to both induce cancer cell death and activate the immune system. Furthermore the highly efficient linker technology allows for an easy synthesis and conjugation enabling the commercialization of a cost-effective chemotherapeutic product. No other oncologic drug, currently marketed, is able to address therapy effectiveness, reduction of side effects, and healthcare cost-savings at the same time with an unique product. During the feasibility investigations, OncoLinx established that in order to achieve the target product profile features and the commercialization capacity (license deal) the technology must be optimized and its safe profile extensively proved in in vivo validation studies. A strategic plan will minimize R&D costs by collaborating with strong partners – like Abzena -, and perform the preclinical development in order for the Azonafide-ADC to be approved for the first-in-human clinical studies and other clinical studies.
Overall objectives: To further advance the technology, OncoLinx will require to produce the High Potency Active Pharmaceutical Ingredient (HPAPI) molecule and to perform preclinical testing in rodents and non-human primates. These assays will be integral in bridging the gap between in vitro and in vivo work. The ultimate goal of the ADC development plan, described below, will be to better understand the compound(s) metabolite‐mediated toxicity and safety profile to make a concrete decision for the purpose of enabling the clinical trial application, which is a crucial part of the drug approval process. A Clinical Trial Application (CTA) package will be based on the Investigational Medicinal Product Dossier (IMPD) that contains previous data from literature and quality/non-clinical data from the following studies: bioanalytical method validation in one rodent and one non‐rodent specie; single and multiple‐dose toxicity and pharmacokinetic in one rodent and one non‐rodent specie; and in vitro CYP inhibition/induction in human liver microsomes. Assessment of the degree of binding of the drug candidate to plasma proteins, and of its metabolism during incubation in vitro with hepatic microsomes or hepatocytes from nonclinical species and human, are expected for non-biological drugs prior to the initial clinical study . The pivotal toxicology studies will be conducted in rat/monkeys as relevant species (predictive for humans) to evaluate potential on-and off-target safety risks. The target profile of this ADC drug candidate will be later stage patients with a specific breast cancer subtype such as HER2- positive, with the pre-clinical plan aiming to assess the safety of the conjugate antibody/drug in order to support first-in-human clinical trials.