CD137+ tumor infiltrating lymphocytes predicts ovarian cancer survival

Preclinical Evaluation and Pilot Clinical Study of CD137 PET Radiotracer for Noninvasive Monitoring Early Responses of Immunotherapy

Given the variability in the effectiveness of immune checkpoint blocking therapy among patients and tumor types, development of noninvasive methods for longitudinal assessment of immune cell function and early tumor response is crucial for precision immunotherapy. CD137 (4-1BB), a marker of activated T cells, plays a significant role in immunotherapy. However, its potential as an imaging biomarker for activated T cells in the tumor microenvironment has not been explored. This study introduces a bicyclic peptide-based probe that targets CD137 for noninvasive PET imaging of tumor-infiltrating activated T cells. Methods: A bicyclic peptide-based probe, [18F]AlF-NOTA-BCP137, was first designed and synthesized for quantitative and longitudinal whole-body visualization of CD137 dynamics. Initially, [18F]AlF-NOTA-BCP137 was assessed in mouse models with varying CD137 expression levels. Next, [18F]AlF-NOTA-BCP137 was used for longitudinal monitoring of systemic CD137 changes in a humanized tumor-bearing mouse model. Lastly, the probe was further evaluated in a small group of patients with hepatocellular carcinoma undergoing immunotherapy or combination immunotherapy. Results: [18F]AlF-NOTA-BCP137 PET accurately characterized CD137 expression in homologous transplanted mouse models and tumor patients. The findings from animal studies indicated that uptake of [18F]AlF-NOTA-BCP137 was predictive of the early therapeutic response to combination immunotherapies and was positively associated with the increased survival rates of mice with tumors. A preliminary clinical study involving small patient cohorts demonstrated that [18F]AlF-NOTA-BCP137 imaging effectively predicted early patient responses to immunotherapeutic interventions. Conclusion: [18F]AlF-NOTA-BCP137 PET imaging of CD137 is a promising and reliable method for evaluating the efficacy of multiple combination immunotherapies and merits further validation in larger-scale clinical trials. This approach has the potential for early noninvasive visualization of individual patient responses in combination cancer immunotherapy and will aid in tailoring personalized strategies for patients.

Adoptive T cell therapy for ovarian cancer

Although ovarian cancer patients typically respond to standard of care therapies, including chemotherapy and DNA repair inhibitors, the majority of tumors recur highlighting the need for alternative therapies. Ovarian cancer is an immunogenic cancer in which the accumulation of tumor infiltrating lymphocytes (TILs), particularly T cells, is associated with better patient outcome. Thus, harnessing the immune system through passive administration of T cells, a process called adoptive cell therapy (ACT), is a promising therapeutic option for the treatment of ovarian cancer. There are multiple routes by which tumor-specific T cell products can be generated. Dendritic cell cancer vaccines can be administered to the patients to induce or bolster T cell responses against tumor antigens or be utilized ex vivo to prime T cells against tumor antigens; these T cells can then be prepared for infusion. ACT protocols can also utilize naturally-occurring tumor-reactive T cells isolated from a patient tumor, known as TILs, as these cells often are heterogeneous in composition and antigen specificity with patient-specific cancer recognition. Alternatively, T cells may be sourced from the peripheral blood, including those that are genetically modified to express a tumor antigen-specific T cell receptor (TCR) or chimeric antigen receptor (CAR) to redirect their specificity and promote their activity against tumor cells expressing the target tumor antigen. Here, we review current ACT strategies for ovarian cancer and provide insights into advancing ACT therapy strategies for the treatment of ovarian cancer.