PHSOR09 Presentation Time: 9:40 AM

IF 1.7 4区医学 Q4 ONCOLOGY

Brachytherapy Pub Date : 2024-10-25 DOI:10.1016/j.brachy.2024.08.083

Brian Hrycushko Ph.D., Aurelie Garant MD, Zohaib Iqbal PhD, Yesenia Gonzalez PhD, Tiylar Cotton BS, David Sher MD, MPH, Kevin Albuquerque MD, Tsuicheng Chiu PhD

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引用次数: 0

Abstract

Purpose

Plesio-brachytherapy offers a favorable option for treating skin cancer or keloids post-surgical excision, particularly on curved body surfaces. By closely conforming body contours, plesio-brachytherapy can provide a more uniform surface dose compared to suboptimal external beam techniques. Current HDR flap-based brachytherapy methods, although flexible in design, can be a challenge to shape to irregular surfaces where maintaining a consistent distance for the radioactive sources is paramount to treatment goals. To address these issues, this work proposes a customized flexible silicone applicator to achieve a better fit to the patient's body with minimal air gaps.

Materials and Methods

Our plesiotherapy workflow begins with thin-cut (1mm slice) CT simulation of the treatment area for patient setup and applicator fabrication. Depending on the site, immobilization methods may be used for patient comfort and position reproducibility. A 10 mm thick bolus structure is created from the simulation image set in treatment planning system software. Applicator channel paths are designed in Autodesk Inventor (Autodesk, Inc. San Francisco, CA). Two molds are then 3D printed for surface applicator casting: an external mold is printed with PLA on an Ultimaker S7 printer (Utrecht, Netherlands) to maintain the applicator shape; and internal molds are printed with regular resin using a FormLab Form 3 printer (Somerville, MA) to house the applicator channels. Once assembled, silicone (ECO-Flex 00-30, Smooth-on) was cast into the molds. After curing, single leader flexible implant tubes are inserted into the channels and fixed in place with standard plastic buttons. The patient undergoes a second CT simulation scan for treatment planning, during which the applicator location is marked on the patient for reproducibility on treatment days. Figure 1 illustrates a 3D rendering of a silicone applicator for a vulvar and perineal surface region treatment.

Results

HDR plesiotherapy using a patient-specific flexible applicator has been successfully implemented clinically. Several patient-specific applicators have been made to treat sites (e.g. vulvar, face, buttock) with surface contours that would be difficult to treat with external beam or standard flap-based HDR brachytherapy.

Conclusions

This approach demonstrates the feasibility and effectiveness of using a silicone surface applicator in delivering targeted radiation therapy for skin cancer treatment, offering a promising option for patients with lesions in challenging anatomical locations. Future work will evaluate the use of surface-guided imaging technologies to reduce the number of CT simulations. Also, optimization strategies for catheter trajectories will also be investigated.

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PHSOR09 演讲时间：上午 9:40

目的 plesio近距离放射治疗为治疗皮肤癌或手术切除后的瘢痕疙瘩提供了一个有利的选择，尤其是在弯曲的体表。与不理想的体外射束技术相比，plesio 近距离放射治疗能紧密贴合身体轮廓，提供更均匀的表面剂量。目前基于皮瓣的 HDR 近距离放射治疗方法虽然设计灵活，但要在不规则的体表进行塑形是一项挑战，而在这种情况下，放射源保持一致的距离是实现治疗目标的关键。为了解决这些问题，这项研究提出了一种定制的柔性硅胶涂抹器，可以更好地贴合患者的身体，将气隙减到最小。材料与方法我们的近距离放射治疗工作流程首先是对治疗区域进行薄切割（1 毫米切片）CT 模拟，以进行患者设置和涂抹器制作。根据治疗部位的不同，可能会采用固定方法，以保证患者的舒适度和位置的可重复性。根据治疗计划系统软件中的模拟图像集创建 10 毫米厚的栓剂结构。在 Autodesk Inventor（加州旧金山 Autodesk 公司）中设计涂抹器通道路径。然后三维打印出两个模具，用于表面涂抹器的铸造：外部模具用 Ultimaker S7 打印机（荷兰乌得勒支）上的聚乳酸打印，以保持涂抹器的形状；内部模具用 FormLab Form 3 打印机（马萨诸塞州萨默维尔）上的普通树脂打印，以容纳涂抹器通道。组装完成后，将硅胶（ECO-Flex 00-30，Smooth-on）浇注到模具中。固化后，将单头柔性植入管插入通道，并用标准塑料按钮固定到位。患者接受第二次 CT 模拟扫描以制定治疗计划，扫描期间在患者身上标记涂抹器的位置，以确保治疗日的可重复性。图 1 展示了用于外阴和会阴表面区域治疗的硅胶涂抹器的三维效果图。结论这种方法证明了使用硅胶表面涂抹器为皮肤癌治疗提供靶向放射治疗的可行性和有效性，为在具有挑战性的解剖位置出现病变的患者提供了一种很有前景的选择。未来的工作将评估表面引导成像技术的使用情况，以减少 CT 模拟的次数。此外，还将研究导管轨迹的优化策略。

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

Brachytherapy 医学-核医学

CiteScore

3.40

自引率

21.10%

发文量

119

审稿时长

9.1 weeks

期刊介绍： Brachytherapy is an international and multidisciplinary journal that publishes original peer-reviewed articles and selected reviews on the techniques and clinical applications of interstitial and intracavitary radiation in the management of cancers. Laboratory and experimental research relevant to clinical practice is also included. Related disciplines include medical physics, medical oncology, and radiation oncology and radiology. Brachytherapy publishes technical advances, original articles, reviews, and point/counterpoint on controversial issues. Original articles that address any aspect of brachytherapy are invited. Letters to the Editor-in-Chief are encouraged.