Immunotherapies (ITx) for melanoma have led to marked improvements in clinical outcomes. However, objective response rates remain quite low (10-30%) because T-cells fail to infiltrate metastases in many patients. Thus, the translation of adjunct approaches that enhance T-cell infiltration and/or lift the immunosuppressive tumor microenvironment could vastly expand the population of melanoma patients exhibiting durable responses to immunotherapy. Toward this goal, we hypothesize that perturbation of the melanoma microenvironment with focused ultrasound (FUS), applied in energy regimens designed to elicit thermal ablation (T-FUS) and/or microbubble cavitation (M-FUS), can stimulate immunologic responses that are both intrinsically therapeutic and synergistic with translatable immunotherapies. Indeed, our pilot studies indicate that, even when applied to only a small fraction of tumor volume, both T-FUS and M-FUS cooperate with the immune system to control melanoma. This proposal is comprised of 3 specific aims that will serve to define differences in the innate and adaptive immune responses that are elicited by applying different FUS energy regimes to tumors, identify barriers to tumor immunity, and ascertain treatment protocols that more effectively combine FUS energy regimes with adjunct immunotherapies for treating metastatic melanoma.
Specific Aim 1 will first characterize thermal and mechanical energy deposition generated during the application of T-FUS and M-FUS to B16F10 melanoma. Then, using bilateral melanoma tumor models, we will identify T-FUS and M-FUS ?ablation fractions? that, when combined with first line ?PD1 immunotherapy for melanoma, yield most efficacious immunological control of a distant tumor. These ablation fractions will be carried forward through the rest of the proposal.
Specific Aim 2 will entail determining the impact of the selected FUS energy regimes with ?PD1 on discrete factors that influence the sequential steps involved in the activation, expansion, and recruitment of T cells to the microenvironments of FUS-treated and distant tumors. In turn, this will help us define optimized protocols for immune cell activation and understand aspects of FUS modalities that are beneficial or detrimental to T cell-mediated tumor control. Additional studies under Aim 2 will assess the mechanisms of adaptive resistance elicited by application of FUS in these selected energy regimes. This will allow us to understand the diversity and intensity of compensatory anti-inflammatory responses to FUS, which will be a critical aspect in optimizing the combination of FUS with anti-tumor immunotherapy. Finally, Specific Aim 3 will both ascertain the ability of FUS to promote antibody entrance to tumor and utilize information from previous aims to identify and test combinations of selected FUS energy regimens and immunotherapeutic drugs in treatments that we hypothesize will yield most effective control of disseminated tumors. We believe the highly systematic and directed approach proposed here is more likely to lead to successful clinical therapies for melanoma patients with limited T cell infiltration.
Immunotherapies for metastatic melanoma are effective only in a small fraction of patients, generally those who have high immune cell infiltration. We have previously shown that applying focused ultrasound energy into tumors can stimulate immune cell recruitment. In this proposal, we will comprehensively examine how applying focused ultrasound with different energy modes affects anti-tumor immunity and then, based on this information, identify and test combinations of focused ultrasound and immunotherapeutic drugs that we propose will be most efficacious for treating melanoma.
