Radiation-Induced Acute Lung Pneumonitis After Pencil-Beam Scanning Proton Treatment for Breast Cancer: Correlation With Dose-Volume Parameters and Optimization Objectives to Reduce Lung Toxicities.

IF 3.5 3区医学 Q2 ONCOLOGY

Practical Radiation Oncology Pub Date : 2025-08-19 DOI:10.1016/j.prro.2025.07.005

Jiyeon Park, Julie A Bradley, Nancy P Mendenhall, Raymond B Mailhot Vega, Teena Burchianti, Yawei Zhang, Hardev Grewal, Mohammad Saki, Twyla Willoughby, Perry B Johnson, Mark Artz

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Abstract

Proton treatment using pencil-beam scanning (PBS) for patients with breast cancer offers advantages in achieving a conformal dose distribution while also reducing the cardiac dose. However, when employing 2 anterior fields to mitigate the effects of respiratory motion on dose delivery, managing the ipsilateral lung doses becomes critical due to the high linear-energy transfer (LET) at the distal end of the beams. Although the incidence of radiation pneumonitis (RP) after breast radiation therapy is relatively low, it is essential to address the cases that develop RP following proton treatment to minimize lung toxicity. We conducted a retrospective case study analyzing follow-up computed tomography images taken at 1 week, 1.5 months, and 4.5 months after the onset of the patient's pneumonitis symptoms to correlate them with proton doses. The patient's PBS treatment was prescribed at a dose of 50 Gy with an additional 10 Gy boost, using a relative biological effectiveness (RBE) of 1.1, delivered in 2 Gy daily fractions. Our histogram analysis revealed noticeable increases in Hounsfield units at a dose of 40 Gy (RBE = 1.1), underscoring a potential dose-volume parameter that could help minimize the occurrence of RP. Furthermore, the lung volume associated with the RP was encompassed with an iso-LET level greater than 5.0 keV/μm, with a proton dose exceeding 40 Gy (RBE = 1.1). In examining the LET-dependent RBE-weighted dose using the McNamara model in the original treatment plan, we found the volumes receiving more than 50 Gy (V_50Gy) and 40 Gy (V_40Gy) were 110 cc and 267 cc, respectively. By incorporating dose objectives of V_50Gy and V_40Gy to limit the ipsilateral lung volume into PBS plans, the volumes were successfully reduced to 0 cc and 3 cc, while maintaining target dose coverage and robustness. Optimizing a breast PBS plan (RBE = 1.1) using objectives that addressed both the V_50Gy and V_40Gy to minimize lung exposure was shown to be clinically feasible and should be considered as a strategy to reduce lung toxicity when treating breast cancer with PBS proton therapy.

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乳腺癌PBS质子治疗后放射性引起的急性肺肺炎：与剂量-体积参数的相关性和降低肺毒性的优化目标

使用铅笔束扫描（PBS）对乳腺癌患者进行质子治疗在获得适形剂量分布的同时也减少了心脏剂量方面具有优势。然而，当采用两个前场来减轻呼吸运动对剂量传递的影响时，由于光束远端的高线性能量转移（LET），管理同侧肺剂量变得至关重要。虽然乳房放射治疗后放射性肺炎（RP）的发生率相对较低，但必须解决质子治疗后发生RP的病例，以尽量减少肺毒性。我们进行了一项回顾性病例研究，分析了患者肺炎症状出现后1周、1.5个月和4.5个月的随访计算机断层扫描图像，以将其与质子剂量联系起来。患者的PBS治疗剂量为50戈瑞，外加10戈瑞，使用1.1的相对生物有效性（RBE），以每天2戈瑞的剂量给药。我们的直方图分析显示，在40 Gy的剂量下，Hounsfield单位显著增加（RBE = 1.1），强调潜在的剂量-体积参数可以帮助减少RP的发生。此外，与RP相关的肺体积被大于5.0 keV/μm的iso-LET水平包围，质子剂量超过40 Gy （RBE = 1.1）。在原始治疗方案中使用麦克纳马拉模型检查let依赖性rbe加权剂量时，我们发现接受超过50Gy （V50Gy）和40Gy （V40Gy）的体积分别为110 cc和267 cc。通过将V50Gy和V40Gy的剂量靶限制同侧肺体积纳入PBS计划，成功地将体积减少到0 cc和3 cc，同时保持靶剂量覆盖和稳健性。优化乳房PBS计划（RBE = 1.1），同时考虑V50Gy和V40Gy的目标，以最大限度地减少肺暴露，这在临床上是可行的，在使用PBS质子治疗乳腺癌时，应将其视为降低肺毒性的策略。

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

Practical Radiation Oncology Medicine-Radiology, Nuclear Medicine and Imaging

CiteScore

5.20

自引率

6.10%

发文量

177

审稿时长

34 days

期刊介绍： The overarching mission of Practical Radiation Oncology is to improve the quality of radiation oncology practice. PRO''s purpose is to document the state of current practice, providing background for those in training and continuing education for practitioners, through discussion and illustration of new techniques, evaluation of current practices, and publication of case reports. PRO strives to provide its readers content that emphasizes knowledge "with a purpose." The content of PRO includes: Original articles focusing on patient safety, quality measurement, or quality improvement initiatives Original articles focusing on imaging, contouring, target delineation, simulation, treatment planning, immobilization, organ motion, and other practical issues ASTRO guidelines, position papers, and consensus statements Essays that highlight enriching personal experiences in caring for cancer patients and their families.