Optimizing Nozzle Travel Time in Proton Therapy

2022 IEEE 35th International Symposium on Computer-Based Medical Systems (CBMS) Pub Date : 2022-07-01 DOI:10.1109/CBMS55023.2022.00085

M. Spezialetti, Renata Di Filippo, Ramon Gimenez De Lorenzo, G. Gravina, G. Placidi, Guido Proietti, F. Rossi, S. Smriglio, J. M. R. Tavares, F. Vittorini, F. Mignosi

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引用次数: 1

Abstract

Proton therapy is a cancer therapy that is more expensive than classical radiotherapy but that is considered the gold standard in several situations. Since there is also a limited amount of delivering facilities for this techniques, it is fundamental to increase the number of treated patients over time. The objective of this work is to offer an insight on the problem of the optimization of the part of the delivery time of a treatment plan that relates to the movements of the system. We denote it as the Nozzle Travel Time Problem (NTTP), in analogy with the Leaf Travel Time Problem (LTTP) in classical radiotherapy. In particular this work: (i) describes a mathematical model for the delivery system and formalize the optimization problem for finding the optimal sequence of movements of the system (nozzle and bed) that satisfies the covering of the prescribed irradiation directions; (ii) provides an optimization pipeline that solves the problem for instances with an amount of irradiation directions much greater than those usually employed in the clinical practice; (iii) reports preliminary results about the effects of employing two different resolution strategies within the aforementioned pipeline, that rely on an exact Traveling Salesman Problem (TSP) solver, Concorde, and an efficient Vehicle Routing Problem (VRP) heuristic, VROOM.

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质子治疗中喷嘴行程时间优化

质子治疗是一种比传统放射治疗更昂贵的癌症治疗方法，但在一些情况下被认为是金标准。由于这种技术的输送设施数量有限，因此随着时间的推移，增加接受治疗的患者数量至关重要。这项工作的目的是提供一个洞察的问题，优化部分交付时间的治疗计划，涉及到系统的运动。我们将其称为喷嘴旅行时间问题(NTTP)，类似于经典放射治疗中的叶子旅行时间问题(LTTP)。特别是这项工作:(i)描述了输送系统的数学模型，并形式化了寻找满足规定照射方向覆盖的系统(喷嘴和床)的最佳运动序列的优化问题;(ii)提供了一个优化管道，解决了辐射方向数量远大于临床实践中通常使用的情况下的问题;(iii)报告了在上述管道中采用两种不同解决策略的效果的初步结果，这两种策略依赖于精确的旅行推销员问题(TSP)求解器Concorde和高效的车辆路线问题(VRP)启发式算法VROOM。

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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2022 IEEE 35th International Symposium on Computer-Based Medical Systems (CBMS)

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