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Project 1: Optimizing Treatment of GBM by FLASH

项目1：GBM FLASH优化治疗

基本信息

批准号：
10415034
负责人：
Charles Limoli
金额：
$ 35.82万
依托单位：
UNIVERSITY OF CALIFORNIA-IRVINE
依托单位国家：
美国
项目类别：
财政年份：
2020
资助国家：
美国
起止时间：
2020-06-01 至 2025-05-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10415034
关键词：
Address Aftercare Anatomy Behavioral Biology Blood Vessels Brain Brain Injuries Brain Neoplasms Canis familiaris Cause of Death Cessation of life Chemotherapy and/or radiation Clinic Clinical Clinical Management Clinical Trials Cognition Cognitive Collaborations Complement Complex Coupled Cranial Irradiation Data Data Set Development Dose Dose-Rate Electron Beam Electrons Fractionation Glioblastoma Goals Human Resources Immunologics Indiana Individual Inflammation Inflammatory Infrastructure Institution International Laboratories Medical Modality Modeling Molecular Mus Neurocognition Neurocognitive Neurologic Neurons Normal tissue morphology Oncologist Outcome Oxidation-Reduction Oxygen Patients Physics Program Research Project Grants Radiation Radiation Injuries Radiation Oncology Radiation therapy Radiation-Induced Change Radiobiology Radiotherapy Research Regimen Research Research Design Roentgen Rays Science Series Structure Symptoms Techniques Technology Testing Therapeutic Index Time Toxic effect Translating Translations Tumor Tissue Universities University Hospitals Vascular Morphologic Change Work base brain tissue cancer cell cancer therapy chemotherapy clinical practice clinical translation clinically relevant cognitive function design dosimetry experimental study immunoregulation indexing inflammatory marker innovation insight irradiation mouse model multidisciplinary neurobehavioral neurobiological mechanism neuronal tumor neurotoxicity novel novel strategies pre-clinical preclinical imaging preclinical study programs response success temozolomide therapy design treatment optimization tumor tumor progression

项目摘要

PROJECT SUMMARY/ABSTRACT – Project 1: Optimizing Treatment of GBM by FLASH We are proposing the creation of a research program entitled, “Increasing the therapeutic index of brain tumor treatment through innovative FLASH radiotherapy (FLASH-RT),” focused on translating a novel irradiation modality rapidly into the clinic. The overall hypothesis to be tested is that radiation delivered at ultra-high dose rates (compared to the much lower dose rates used in current clinical practice) can significantly ameliorate normal tissue complications while maintaining acceptable if not improved tumor control. To test this hypothesis, the program will deploy a comprehensive series of preclinical studies that will critically evaluate tumor control, neurocognitive outcomes and resultant radiation injury to the brain following FLASH-RT and conventional dose rate irradiation. Collectively, these studies will generate the requisite data sets required for the rapid translation of the novel FLASH irradiation platform to the clinical setting. Preclinical studies in mice assessing orthotopic tumor control, cognition, neuronal and vascular structure, immunomodulation, and oxygen-dependent mechanisms of radiation injury are coupled with a clinical trial in GBM dog patients to inform the oncologists of the potential benefits of this potentially paradigm shifting approach. The objectives of this program project will be facilitated by the activities conducted by the Dosimetry/Physics/Modeling core and the Neurobehavioral core. Project 1 will focus on the assessing the therapeutic index, comprising tumor control and normal brain injury, of FLASH-RT compared to conventional dose rate irradiation. Orthotopic tumor-bearing mice will be treated with FLASH and conventional RT under clinically relevant scenarios: single fraction and fractionated, with and without concurrent chemotherapy, using electron and MV x-ray beams. The experiments will be conducted across our institutions (CHUV, Stanford, and Indiana University) using our novel FLASH irradiation platforms, supported by Cores 2 and 3. We will evaluate cellular and molecular mechanisms underlying the differential effects of FLASH by assessing neuronal and tumor structure, and markers of inflammation/immunomodulation. The success of this innovative program project grant is bolstered by the unparalleled breadth and depth of our multi-disciplinary investigative team at UC Irvine, Stanford University, SLAC National Accelerator Laboratory, CHUV/Lausanne University Hospital, and Indiana University that has pioneered the development of the initial experimental infrastructure for conducting FLASH-RT research and produced strong preclinical evidence of increased therapeutic index, comprising expertise in radiation oncology, radiobiology, medical physics, and preclinical imaging and accelerator science. In summary, Project 1 will pave the way for near-term clinical translation of FLASH-RT by systematically testing FLASH and conventional dose-rate irradiation under clinically relevant regimens, and will complement studies in Projects 2-4 focused on longer-term neurotoxicity, expanding to other species preclinically, and physico-chemical mechanisms of FLASH-RT.

项目概要/摘要-项目1：通过FLASH优化GBM治疗我们建议创建一个研究项目，题为“提高脑肿瘤的治疗指数通过创新的FLASH放射治疗（FLASH-RT），“专注于将一种新的放射疗法快速进入临床。有待检验的总体假设是，超高剂量的辐射剂量率（与当前临床实践中使用的低得多的剂量率相比）可以显著改善正常的组织并发症，同时保持可接受的，如果没有改善的肿瘤控制。为了验证这个假设，该计划将部署一系列全面的临床前研究，将严格评估肿瘤控制， FLASH-RT和常规剂量后的神经认知结局和由此产生的脑辐射损伤速率辐照总的来说，这些研究将产生快速翻译所需的必要数据集。新型FLASH照射平台的临床应用。小鼠临床前研究，评估原位肿瘤控制、认知、神经元和血管结构、免疫调节和氧依赖性辐射损伤的机制与GBM狗患者的临床试验相结合，以告知肿瘤学家这种潜在的范式转变方法的潜在好处。该项目的目标将由剂量测定/物理学/建模核心和神经行为核心进行的活动促进。项目1将侧重于评估治疗指标，包括肿瘤控制和正常脑损伤， FLASH-RT与常规剂量率照射的比较。原位荷瘤小鼠将用临床相关场景下的FLASH和常规RT：单次分割和分割，有和无同步化疗，使用电子和MV X射线束。实验将在我们的这些机构（CHUV、斯坦福大学和印第安纳州大学）使用我们的新型FLASH辐照平台，核心2和3。我们将评估FLASH差异效应的细胞和分子机制通过评估神经元和肿瘤结构以及炎症/免疫调节的标志物。这项创新计划项目赠款的成功得到了无与伦比的广度和深度的支持，我们在加州大学欧文分校、斯坦福大学、SLAC国家加速器的多学科调查团队实验室，CHUV/洛桑大学医院和印第安纳州大学，开创了开发了进行FLASH-RT研究的初始实验基础设施，并产生了强大的增加治疗指数的临床前证据，包括放射肿瘤学，放射生物学，医学物理学、临床前成像和加速器科学。总之，项目1将通过系统测试为FLASH-RT的近期临床转化铺平道路 FLASH和常规剂量率照射的临床相关方案，并将补充研究项目2-4侧重于长期的神经毒性，扩展到其他物种的临床前和物理化学 FLASH-RT机制。