Optimal use of limited proton resources for liver cancer patients in combined proton-photon treatments.

IF 3.3 3区 医学 Q2 ENGINEERING, BIOMEDICAL
Louise Marc, Jan Unkelbach
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Abstract

Objective: Liver cancer patients may benefit from proton therapy through increase of the tumor control probability (TCP). However, proton therapy is a limited resource and may not be available for all patients. We consider combined proton-photon liver SBRT treatments (CPPT) where only some fractions are delivered with protons. It is investigated how limited proton fractions can be used best for individual patients and optimally allocated within a patient group. Approach: Photon and proton treatment plans were created for five liver cancer patients. In CPPT, limited proton fractions may be optimally exploited by increasing the fraction dose compared to photon fraction dose. To determine a patient's optimal proton and photon fraction dose, we maximize the target BED while constraining the mean normal liver BED, which leads to an up- or downscaling of the proton and photon plan, respectively. The resulting CPPT balances the benefits of fractionation in the normal liver versus exploiting the superior proton dose distributions. After converting the target BED to TCP, the optimal number of proton fractions per patient is determined by maximizing the overall TCP of the patient group. Main results: For the individual patient, a CPPT treatment that delivers a higher fraction dose with protons than photons allows for dose escalation in the target compared to delivering the same proton and photon fraction dose. On the level of a patient group, CPPT may allow to distribute limited proton slots over several patients. Through an optimal use and allocation of proton fractions, CPPT may increase the average patient group TCP compared to a proton patient selection strategy where patients receive single-modality proton or photon treatments. Significance: Limited proton resources can be optimally exploited via CPPT by increasing the target dose in proton fractions and allocating available proton slots to patients with the highest TCP increase. .

在质子-光子联合治疗中优化利用肝癌患者的有限质子资源。
目的:肝癌患者可通过提高肿瘤控制概率(TCP)从质子治疗中获益。然而,质子治疗的资源有限,并非所有患者都能接受质子治疗。我们考虑了质子-光子联合肝脏 SBRT 治疗(CPPT),在这种治疗中,只有某些部分使用质子。我们研究了如何将有限的质子部分最好地用于个别患者,以及如何在患者群体中进行最佳分配:为五名肝癌患者制定了光子和质子治疗计划。在 CPPT 中,与光子分量剂量相比,通过增加分量剂量,可以最佳利用有限的质子分量。为了确定患者的最佳质子和光子分数剂量,我们在最大化目标 BED 的同时,对平均正常肝脏 BED 进行了限制,这导致质子和光子计划分别向上或向下缩放。由此产生的 CPPT 平衡了正常肝脏分馏与利用质子剂量分布优势之间的优势。将目标 BED 转换为 TCP 后,通过最大化患者组的总体 TCP 来确定每位患者的最佳质子分段数:对单个患者而言,与提供相同的质子和光子分量剂量相比,质子分量剂量高于光子分量剂量的 CPPT 治疗可使靶区的剂量升级。就患者群体而言,CPPT 可以将有限的质子名额分配给多名患者。与质子患者选择策略(患者接受单一模式质子或光子治疗)相比,通过优化质子分数的使用和分配,CPPT 可以提高患者组的平均 TCP 值:通过 CPPT,可以提高质子分段的目标剂量,并将可用的质子时段分配给 TCP 增幅最高的患者,从而优化利用有限的质子资源。
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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来源期刊
Physics in medicine and biology
Physics in medicine and biology 医学-工程:生物医学
CiteScore
6.50
自引率
14.30%
发文量
409
审稿时长
2 months
期刊介绍: The development and application of theoretical, computational and experimental physics to medicine, physiology and biology. Topics covered are: therapy physics (including ionizing and non-ionizing radiation); biomedical imaging (e.g. x-ray, magnetic resonance, ultrasound, optical and nuclear imaging); image-guided interventions; image reconstruction and analysis (including kinetic modelling); artificial intelligence in biomedical physics and analysis; nanoparticles in imaging and therapy; radiobiology; radiation protection and patient dose monitoring; radiation dosimetry
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