Abstract 299: Self-assembling nanoparticles: A novel approach for targeted cancer treatment using tumor treating fields

Abstract

Abstract Tumor Treating Fields (TTFields) are used in cancer treatment as they offer increased efficacy, safety, and low adverse effects. They have shown significant potential in pancreatic cancer (PC) clinical trials when combined with chemotherapy. It is pertinent to know that although TTFields-chemotherapy combination definitely enhances the treatment efficacy, it also results in chemotherapy induced severe adverse effects. To resolve this, we earlier reported development of Gemcitabine loaded self-assembling cationic-anionic polymer nanoparticles (S-CAP NPs) capable of achieving TTFields-triggered targeted drug release at the PC tumor site. Initially, four S-CAP NPs [C4 and C7 from chitosan- bovine serum albumin (Chitosan-BSA) S-CAP NPs; P5 and P8 from polyethylenimine- bovine serum albumin (PEI-BSA) S-CAP NPs] were shortlisted [Table 1 - particle size: ~ 200 nm; % encapsulation efficiency (EE): 55-65%]. For proof-of-concept studies, effect of TTFields on the % EE and % cumulative drug release of the S-CAP-NPs was investigated. The studies revealed (Table 1) significant reduction (p value < 0.05) in the % EE of S-CAP NPs within 48h TTFields treatment, confirming that the TTFields destabilize the NPs triggering targeted drug release. Similarly, In vitro drug release studies showed significant increase (p< 0.01) in rate of drug release from S-Cap NPs in presence of TTFields. The cell inhibition assay confirmed the synergism in cell apoptosis wherein PEI-BSA S-CAP NPs showed higher efficacy compared to chitosan-BSA S-CAP NPs. Further, additional stability studies continued over a period of 18 months confirmed stable formulations. In vivo acute and chronic toxicity studies are underway to identify the most optimum dose of S-CAP NPs for further in vivo efficacy studies. To summarize, S-CAP-NPs present a promising avenue to achieve targeted chemotherapy in conjunction with TTFields. This work is supported by AACR-Novocure tumor treating fields research fellowship. Table 1. Effect of TTFields on % encapsulation efficiency (n=3). Data represented as Mean ± SD. Batch Particle size (nm) Encapsulation efficiency (%) - 0h Encapsulation efficiency (%) - 24h - 150 KHZ Encapsulation efficiency (%) - 48h - 150 KHZ Chitosan-BSA S-CAP NPs C4 210.54 ± 38.96 61.26 ± 5.11 36.21 ± 3.53 24.86 ± 3.19 C7 215.67 ± 32.55 65.31 ± 5.84 32.19 ± 2.68 21.86 ± 4.64 PEI-BSA S-CAP NPs P5 198.29 ± 41.05 58.83 ± 3.33 27.66 ± 3.31 18.96 ± 3.96 P8 209.92 ± 31.33 64.31 ± 5.13 24.83 ± 4.29 19.42 ± 2.73 Citation Format: Preshita Prafulla Desai, Sunil Prabhu. Self-assembling nanoparticles: A novel approach for targeted cancer treatment using tumor treating fields [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 299.