Spot-Scanning Confocal Photon Beams for Hypofractionated Brain Radiosurgery.

IF 2.8 4区医学 Q3 ONCOLOGY

Technology in Cancer Research & Treatment Pub Date : 2025-01-01 Epub Date: 2025-05-21 DOI:10.1177/15330338251342873

Lijun Ma, Shuang Luan, Nguyen Phuong Dang, Benjamin Ziemer, Steve Braunstein, Michael McDermott, Cheng Yu, Gabriel Zada, Eric L Chang

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引用次数: 0

Abstract

IntroductionStereotactic radiosurgery (SRS) has been broadly used to treat brain tumors. In this study, a dose kernel-based spot scanning (DKSC) treatment delivery has been developed for hypofractionated brain SRS.MethodsDKSC treatments employs hundreds of confocal photon dose kernels. For such a delivery, a single continuous scanning path was first mapped within a 3D target volume, and then a series of dose kernels of variable sizes, shapes and beam weights were placed and then optimized along the path to produce highly conformal dose distributions. For implementation of DKSC delivery in a clinical setting, we specifically employed the Leksell Gamma Knife (LGK) system, where it is considered as the gold standard of modern SRS treatments.ResultsDKSC was successfully implemented for a patient treatment for the first time. General methodology as well as specific workflow and treatment planning caveats of implementing DKSC for the LGK is reported. To highlight the novelty of DKSC, we also compared DKSC against the conventional LGK-SRS treatment including its latest treatment planning optimization software.ConclusionDKSC has been demonstrated to be technically feasible, clinically implementable, and uniquely advantageous for hypofractionated brain SRS. Further studies are warranted toward testing DKSC for variable SRS modalities, different disease sites including extra-cranial lesions.

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点扫描共聚焦光子束用于低分割脑放射外科。

立体定向放射外科（SRS）已广泛应用于脑肿瘤的治疗。在本研究中，一种基于剂量核的点扫描（DKSC）治疗方法被开发用于低分割的脑SRS。方法sdksc治疗采用数百个共聚焦光子剂量核。对于这种递送，首先在三维目标体积内绘制单个连续扫描路径，然后放置一系列可变大小，形状和光束重量的剂量核，然后沿着路径进行优化，以产生高度适形的剂量分布。为了在临床环境中实施DKSC交付，我们特别采用了Leksell伽玛刀（LGK）系统，它被认为是现代SRS治疗的金标准。结果dksc首次成功应用于患者治疗。报告了对LGK实施DKSC的一般方法以及具体工作流程和治疗计划注意事项。为了突出DKSC的新颖性，我们还将DKSC与传统的LGK-SRS处理进行了比较，包括其最新的处理计划优化软件。结论dksc在技术上是可行的，在临床上是可实施的，在减少分割的脑SRS中具有独特的优势。需要进一步的研究来测试DKSC对可变SRS模式、不同疾病部位（包括颅外病变）的检测。

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

Technology in Cancer Research & Treatment 医学-肿瘤学

CiteScore

4.40

自引率

0.00%

发文量

202

审稿时长

2 months

期刊介绍： Technology in Cancer Research & Treatment (TCRT) is a JCR-ranked, broad-spectrum, open access, peer-reviewed publication whose aim is to provide researchers and clinicians with a platform to share and discuss developments in the prevention, diagnosis, treatment, and monitoring of cancer.