Abstract

Abstract Purpose: Radiation is the most common modality for lung cancer treatment method. Radiationinduces apoptosis, causing cancer cells to be fragmented and expose the cancer-associatedantigens to the tumor microenvironment. These can be recognized by antigen-presenting cells(APC) to induce the antineoplastic effect by activating cytotoxic T cells. Our prior studies showadding immunoadjuvant like AntiCD40 with radiation can further activate the APCs in its anti-tumor (M1) format. Recent studies have shown that flavonoids like Hesperetin, an ACE2receptor agonist also can induce apoptosis in cancer cells whereas ACE2 receptors are abundant in lung cancer cells.This project aims to develop a novel treatment for non-small cell lung cancer (NSCLC) using nanotechnology for inhalation drug delivery Hesperetin, a flavonoid with antioxidant and pro-apoptotic activity; bound to PLGA-coated nanoparticles (Hesperetin Nanoparticles, HNPs) andAntiCD40 aiming for localized targeted dosing to reduce the treatment-related systemic toxicity.We plan to test the efficacy and safety of this aerosol spray. Methods: In-vitro studies were performed in human A549 (ATCC) and murine LLC1 (ATCC)lung cancer cell lines for growth (MTT) and clonogenic survival assays to demonstrate the anti-cancer cell activity of Hesperetin (Sigma). Next, HNP was prepared using NanoFabTx™ nano-formulation reagent kits (Millipore-Sigma). A syngeneic orthotopic murine model of Lungadenoma was generated in wild (+/+) C57/BL6 background mice with similar background LLC1cell lines. We developed syngeneic orthotopic murine lung tumors with luciferase genetransfected LL/2-Luc2 (ATCC) Lewis Lung Cancer cell line in wild-type C57BL/6 mice(Techonic). Lung tumor-bearing mice were treated with HNP, antiCD40, or both with aerosolspray with a control group treated with the solvent (dH2O) only. To assess the drug delivery withaerosol treatment ex-vivo lung tissue was analyzed for Fluorescence tagged antiCD40 andnanoparticle uptakes. A survival assay was performed to analyze the efficacy of aerosoltreatment of HNPs with or without AntiCD40. All cohorts were also analyzed for body score, body weight, and liver and kidney functions. Results: We were able to successfully develop an aerosol drug delivery model to administer bothAnti-CD40 and HNP in a murine lung cancer model. In our analysis of an orthotopic murinelung cancer model, we demonstrate a high intake of the HNP and AntiCD40 by the cancer cellssparing the normal lung tissue. Moreover, the highest percentage of survival rate was observed with the combination aerosol treatment with HNP+AntiCD40 (p<0.001), compared to CD40alone (p<0.01) or HNP (p<0.01) alone. Comments: This treatment model will allow us to make the lung cancer treatment method easilyavailable for the mass population without having hazardous radiation treatment in the lungcancer model. Citation Format: Sayeda Yasmin-Karim, Geraud Richard, Amanda Fam, Alina-Marissa Ogurek, G. Mike Makrigiorgos. Aerosol delivery of immunotherapy and hesperetin nanoparticles in murine lung cancer model [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 491.

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