Evaluating the potential for maximized T cell redistribution entropy to improve abscopal responses to radiotherapy.

Convergent science physical oncology Pub Date : 2017-09-01 Epub Date: 2017-06-15 DOI:10.1088/2057-1739/aa7269

Rachel Walker, Jonathan D Schoenfeld, Shari Pilon-Thomas, Jan Poleszczuk, Heiko Enderling

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引用次数: 5

Abstract

The potential for local radiation therapy to elicit systemic (abscopal) anti-tumor immune responses has been receiving a significant amount of attention over the last decade. We recently developed a mathematical framework designed to simulate the systemic dissemination of activated T cells among multiple metastatic sites. This framework allowed the identification of non-intuitive patterns of T cell redistribution after localized therapy, and offered suggestions as to the optimal site to irradiate in order to increase the magnitude of an immune-mediated abscopal response. Here, we evaluate the potential for such a framework to provide clinical decision making support to radiation oncologists. Several challenges such as efficient segmentation and delineation of multiple tumor sites on PET/CT scans, validation of model prediction performance, and effective clinical trial design remain to be addressed prior to the incorporation of such a tool in the clinical setting.

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评估最大化T细胞再分配熵的潜力，以改善放射治疗的体外反应。

在过去的十年里，局部放射治疗引发全身(体外)抗肿瘤免疫反应的潜力已经得到了大量的关注。我们最近开发了一个数学框架，旨在模拟活化T细胞在多个转移部位的全身传播。该框架允许识别局部治疗后T细胞重新分配的非直观模式，并提供关于最佳照射部位的建议，以增加免疫介导的体外反应的大小。在这里，我们评估这种框架为放射肿瘤学家提供临床决策支持的潜力。一些挑战，如PET/CT扫描中多个肿瘤部位的有效分割和描绘，模型预测性能的验证，以及有效的临床试验设计，在将这种工具纳入临床环境之前，仍有待解决。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Convergent science physical oncology

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