NIR-activatable Prodrugs for Treating Peritoneally Metastasized Ovarian Cancers
You, Youngjae   
University of Oklahoma Health Sciences Center, Oklahoma City, OK, United States

Ovarian cancer (estimated 21,980 new cases and 14,270 deaths in 2014) is the most lethal gynecologic malignancy, and is often discovered in advanced stages when the cancer has metastasized to the peritoneal cavity. Effective eradication of remaining cancers, after optimal debulking surgery, is the key to successful treatment of peritoneally metastasized ovarian cancers. However, current standard treatment (chemotherapy following the surgery) has failed to greatly improve overall survival rates and still causes systemic side effects. Thus, a more effective and safe treatment regimen is urgently needed. This proposal addresses these issues with a unique multifunctional prodrug strategy. Our long-term goal is to develop a platform multifunctional prodrug strategy to achieve synergistic combination of site-specific chemotherapy and photodynamic therapy (PDT, an FDA-approved photochemistry-based regime), which maximizes therapeutic efficacy and minimizes side effects. It is also applicable to a wide range of metastatic tumors. Each prodrug is comprised of an anticancer drug, singlet oxygen (SO)-labile linker, a fluorescent photosensitizer, and cancer- targeting group. Once illuminated by visible-NIR light, the prodrug generates SO that directly damages cancer cells and tumor vasculature (PDT effects). It also releases active drugs only in tumors. PDT is mechanistically distinct from chemotherapeutic drugs and also effectively kills chemo-resistant cancer cells. Thus, the combination of PDT and chemotherapy will provide maximum efficacy. Side effects are avoided by site-specifically releasing drugs only in tumors following specific delivery of inactive prodrugs to tumors. To actively and externally control the release of drug by visible-NIR, we use our novel SO-labile linker. We also employ physiological synergistic effects to minimize the diffusion of the site-specifically released drugs to the systemic circulation. Both vascular damage by PDT and tight binding of drugs to their targets limit the diffusion of the drugs from tumor to blood circulation, avoiding systemic side effects of the drugs. The goals will be realized with 3 specific aims: (1) Synthesize, optimize, and evaluate targeted prodrugs of chemotherapeutic agents, (2) Validate the physiologically-based pharmacokinetic (PK) model and mechanisms of tumor damage, (3) Determine tumor-detection efficiency and antitumor effects for peritoneal ovarian tumors. Major deliverables of this proposal will be (i) targeted prodrugs optimized for ovarian cancers, (ii) physiology-based PK models of prodrugs, which can be a foundation for models of future prodrugs, and (iii) validation of applicability of our prodrugs for optical detection and treatment for orthotopic mouse models with metastasized peritoneal ovarian cancers. The findings of this proposal will significant impact outcomes for patients with metastasized resistant and advanced (stages II-IV) ovarian cancers. The strategy of this proposal will also be adaptable to a wide array of metastatic tumors. The platform prodrugs will also impact scientific research by providing novel and effective prodrug strategy for spatio-temporal drug delivery tools.

Public Health Relevance

Ovarian cancer remains one of the most deadly forms of cancer because it is typically diagnosed after it has advanced to a late stage: current treatments cause significant side effects and have limited long-term success. Our research takes advantage of a unique synergistic combination of photodynamic therapy and local chemotherapy, and focuses on developing multifunctional prodrugs that are more effective and safer than current treatments. This strategy will be applicable for treating a wide range of diseases including ovarian cancer.