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Active NON-SBIR/STTR RPGS NIH (US)

Molecular Imaging Guidance for Potentiating Chemoimmunotherapy in Pancreatic Cancer using Photodynamic Priming

$6.4M USD

Funder NATIONAL INSTITUTE OF BIOMEDICAL IMAGING AND BIOENGINEERING
Recipient Organization University of Texas Dallas
Country United States
Start Date Jul 01, 2024
End Date Apr 30, 2028
Duration 1,399 days
Number of Grantees 1
Roles Principal Investigator
Data Source NIH (US)
Grant ID 10804024
Grant Description

ABSTRACT Pancreatic ductal adenocarcinoma (PDA) is the 3rd most deadly cancers with a 5-year survival rate of only 3% in patients with metastases. Current efforts to improve outcomes in PDA have yet to significantly extend patient survival. This is in part due to the fact that 80-90% of PDA cases are not surgically resectable and exhibit local

or distant metastases upon diagnosis, thereby significantly shortening survival. The most aggressive and toxic chemotherapy cocktail regimen, FOLFIRINOX, fails to extend median survival beyond 11.1 months. While combinations of chemotherapy with immunotherapy (chemo-immunotherapy) have been paradigm-shifting for

several primary and metastatic cancers, they still fail to significantly extend PDA patient survival. For example, chemo-immunotherapy using gemcitabine, nab-Paclitaxel and Pembrolizumab extended overall survival in PDA patients to only 15 months. As such, there remains a critical need for transformative modalities that

improve response rates to chemo-immunotherapy in PDA patients. Chemo-immunotherapy is largely limited in PDA by desmoplasia which contributes to 1) poor drug delivery, and 2) an immunosuppressive tumor microenvironment that neutralizes the action of immunotherapies. This project capitalizes on a non-toxic light-

activated modality known as photodynamic priming (PDP), which we have shown to directly remediate desmoplasia. In doing so, PDP augments the delivery of small molecular weight therapeutics, monoclonal antibodies, and nanomedicines, and also mechanistically sensitize tumors to both chemotherapy and immunotherapy. Furthermore, we and others have shown that PDP induces T cell mediated anti-tumor

responses, thereby synergizing with immune-checkpoint blockade. In this proposal, we will use optical molecular imaging to direct the engineering of a single PD-L1 targeted liposome that delivers PDP and chemo-immunotherapy in a spatiotemporal, synchronized fashion. We will use syngeneic models representing T cell inflamed and non-T cell inflamed PDA tumors, Genetically

Engineered Mouse Models, and orthotopic patient-derived PDA xenograft models in order to: 1) promote a homogenous tumor deposition of chemotherapy and immunotherapy agents, 2) mechanistically sensitize tumors to chemotherapy, 3) induce immunogenic cell death, and 4) provoke a T cell mediated anti-tumor

attack. By first remediating desmoplasia, we propose that a single targeted liposome integrating PDP and chemo-immunotherapy will improve PDA responsiveness at considerably lower chemotherapy doses, thereby prolonging patient survival, while mitigating dose-limiting toxicities and improving patient quality of life.

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University of Texas Dallas

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