Historically, intratumoral therapy was limited by the physical difficulty of reaching tumors. The rise of a new discipline, Interventional Oncology, has largely solved this access problem. The critical bottleneck is now the lack of drugs specifically designed and optimized for local delivery and sustained retention within the tumor.
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The company's platform creates drug microparticles large enough for tumor retention but with a massive surface area for sustained drug release. This is counterintuitive to typical engineering, where surface area is increased by making particles smaller, and it forms the basis of their intellectual property.
By delivering a high, sustained local drug concentration, Nenology's platform shifts cancer cell death from a passive process (apoptosis) to immunogenic cell death. This releases antigens that actively prime the immune system, creating a secondary anti-tumor effect and potentially boosting the efficacy of other immunotherapies.
Pathways like integrins have long been of interest but lacked effective therapeutic approaches. The advent of new technologies, such as antibody-drug conjugates and checkpoint inhibitors, has created opportunities to re-explore these older targets with potent, modern drugs, breathing new life into decades-old research.
A key trend in 2025's drug approvals is that "best-in-class" therapies are distinguished not just by efficacy, but by innovations in formulation and delivery that improve the patient experience. Examples include subcutaneous versions of IV drugs and new delivery methods that expand patient access.
The future of medicine isn't about finding a single 'best' modality like CAR-T or gene therapy. Instead, it's about strategic convergence, choosing the right tool—be it a bispecific, ADC, or another biologic—based on the patient's specific disease stage and urgency of treatment.
Accession's second product is a bispecific antibody that binds to all cancer cells. While this would be dangerously toxic if delivered systemically, their targeted virus delivery system ensures it is only produced inside the tumor. This strategy makes previously "undruggable" therapeutic concepts viable.
For years, major pharmaceutical companies dismissed intratumoral therapy as "off strategy." This sentiment is now changing due to better tumor access and the urgent need for less toxic combination therapies. This market shift is creating new partnering interest in Nenology's platform after years of facing strategic objections.
Actuate’s drug was designed to be highly lipophilic (fat-soluble) to cross the blood-brain barrier for CNS treatment. This same property proved crucial for its success in oncology, as it allows the drug to easily penetrate cancer cell membranes and reach the nucleus.
Unlike older antibody-drug conjugates (ADCs), newer agents are designed so their chemotherapy payload can diffuse out of the target cell and kill nearby tumor cells that may not even express the target antigen. This "bystander effect" significantly enhances their anti-tumor activity.
Instead of just killing cancer cells, the primary mechanism is to insert a gene that forces the infected cell to produce and secrete a potent drug, like an anti-PD-L1 antibody. This creates a hyper-concentrated therapeutic effect directly in the tumor microenvironment, a concept termed "molecular surgery."