Bioprinting Plant Virus Nanoparticles for Immunotherapy and Relapse Prevention of Ovarian Cancer

生物打印植物病毒纳米颗粒用于卵巢癌的免疫治疗和复发预防

• 批准号: 10414977
• 负责人: SHAOCHEN CHEN
• 金额: $ 56.27万
• 依托单位: UNIVERSITY OF CALIFORNIA, SAN DIEGO
• 依托单位国家: 美国
• 财政年份: 2020
• 资助国家: 美国
• 起止时间: 2020-07-01 至 2025-06-30
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10414977
• 关键词: 3-Dimensional; 3D Print; Adjuvant; Antigens; Antitumor Response; Biocompatible Materials; Biological Testing; Biopolymers; C57BL/6 Mouse; Cancer Vaccines; Cells; Cessation of life; Clinical Trials; Complex; Data; Development; Devices; Disease; Disease remission; Dose; Formulation; Future; Geometry; Hour; Image; Immune; Immunity; Immunologics; Immunosuppression; Immunotherapy; Implant; Investigation; Irradiated tumor; Left; Location; Lytic; Malignant neoplasm of ovary; Mechanics; Medicine; Memory; Methods; Modeling; Modification; Nature; Oncogenic Viruses; Oncology; Operative Surgical Procedures; Optics; Patients; Pattern recognition receptor; Peptides; Plant Viruses; Plants; Printing; Process; Prognosis; Proteins; Publishing; Quality Control; Recurrence; Relapse; Reproducibility; Resolution; Scanning Electron Microscopy; Serous; Source; Stimulus; Surrogate Markers; System; Techniques; Testing; Therapeutic; Treatment Efficacy; Tumor Antigens; Tumor Debulking; Tumor Immunity; Vaccines; Virus-like particle; Woman; Work; X ray spectroscopy; adaptive immune response; base; bioprinting; cancer cell; cancer immunotherapy; chemotherapy; clinically significant; design; disorder later incidence prevention; efficacy evaluation; electron energy; engineering design; immune activation; in situ vaccination; innovation; insight; intraperitoneal; mouse model; nano; nanoparticle; neoantigens; neoplastic cell; novel; ovarian cancer prevention; photopolymerization; prevent; prophylactic; recruit; scaffold; subcutaneous; translational approach; tumor; tumor microenvironment; vaccination schedule

Summary Bioprinting plant virus nanoparticles for immunotherapy and relapse prevention of ovarian cancer High grade serous ovarian cancer (HGSOC) is the most common and severe form of ovarian cancer and women with HGSOC have a poor prognosis. Immunotherapy approaches that induce systemic antitumor immunity, in particular those that prevent relapse, are urgently needed for HGSOC. We propose to employ plant virus-like nanoparticles (VLPs) combined with slow release antigen depots as a cancer vaccine approach to launch sys- temic antitumor immunity during remission to block relapse. Our data indicate that intraperitoneal (IP) admin- istration of plant VLPs in a mouse model of ovarian cancer modulates the tumor microenvironment to relieve immunosuppression and generate adaptive anti-tumor immunity and memory against tumor antigens. The VLPs are non-infectious, non-cytotoxic, and non-cytolytic, but the highly repetitive nature of the proteinaceous VLPs triggers innate immune activation and associated adaptive immune response. Building on this, we will develop a VLP biopolymer formulation to enable effective immunotherapy following surgical debulking in HGSOC. We will incorporate irradiated tumor cells as source for patient specific tumor antigens; the cells will be delivered together with the VLPs which act as adjuvant to launch long-lasting anti-tumor immunity. The proposed immu- notherapy implant will be produced through an innovative 3D bioprinting technique; specifically, rapid, microscale continuous optical bioprinting (µCOB). This platform offers control over both the topographical complexity and the cellular and material composition of the scaffold at micron-level resolution. Our rapid 3D bioprinting process allows for photopolymerization of multiple biocompatible materials, and facilitates incorporation of VLPs and/or cells. The engineering design space and tunability of this approach is impeccable; in particular the implant will be designed so that therapeutic doses are released in programmed intervals (prime/boost) vs. continuous slow release. We will fulfill three specific aims: 1) Bioprint VLP biopolymer implants and test various configurations to optimize slow, continuous release vs. staged, e.g. weekly release of the therapeutic VLPs. The implants will undergo rigorous quality control and reproducibility testing and released VLPs will undergo structural analysis and biological testing. 2) Evaluate efficacy of the immunotherapy implants vs. soluble VLPs will be evaluated using mouse model of ovarian cancer (ID8vegf/defb29). Immunological investigation will provide insights into the mechanism of the immunotherapy. 3) To further explore vaccine parameters and model very low endogenous patient antigen loads during remission, we will bioprint biopolymer implants to deliver VLPs and antigen (from irradiated cells) prior to challenge with ID8vegf/defb29 cells. For future translational approaches, patient tumor from surgical debulking and/or patient neoantigen peptides would be used. The clinical significance is high: we envision a simple modification to the current treatment work-flow, where small degradable vaccine implants are left in the intraperitoneal (IP) cavity during surgery or administered subcutaneously (SC) post-surgery, or both.

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