Design and development of additivemanufactured multi-channel brachytherapy applicators for cancer treatment

Journal of Micromanufacturing Pub Date : 2024-02-06 DOI:10.1177/25165984231215888

Shahi Nabhan A. K., Kritik Saxena, Niyas Puzhakkal, Dinesh Makuny, Jose Mathew, D. Lawrence K.

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Abstract

Additive manufacturing (AM) is emerging as an effective manufacturing technology that benefits the medical field with its ease of quickly realizing complex designs. Brachytherapy is a process to cure cancer patients through a high dose rate of gamma radiation. This work aimed at AM-based development of multi-channel vaginal and penile brachytherapy applicators for selectively treating cancer cells in a direction sideways to the applicator rather than the uniform radiation dose possible around the conventional applicator used in cancer treatment. An analytical model was proposed to predict the maximum surface temperature on applicators during Ir-192 source radiation. Also, the predicted values of multi-physics-based finite element method simulation were experimentally validated using a thermal imaging camera. Thermal imaging is a non-contact measurement that is found superior to the brachytherapy scale to position radioactive sources inside the applicator. Experimentally examined multi-channel applicator shows dosimetry advantage in effective radiation control and shows promise of curing cancerous cells with minimal effects on normal cells.

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设计和开发用于癌症治疗的增材制造多通道近距离放射治疗器

快速成型制造（AM）正在成为一种有效的制造技术，它可以轻松快速地实现复杂的设计，从而造福于医疗领域。近距离放射治疗是一种通过高剂量率伽马射线治疗癌症患者的方法。这项工作旨在基于 AM 技术开发多通道阴道和阴茎近距离放射治疗涂抹器，以选择性地治疗涂抹器侧向的癌细胞，而不是在用于癌症治疗的传统涂抹器周围进行均匀的放射剂量。研究人员提出了一个分析模型，用于预测 Ir-192 放射源辐射时涂药器表面的最高温度。此外，还使用热成像摄像机对基于多物理场的有限元法模拟的预测值进行了实验验证。热成像是一种非接触式测量方法，与近距离放射疗法标尺相比，它在定位放射源在涂抹器内部的位置方面更具优势。经过实验检验的多通道涂抹器在有效控制辐射方面显示出剂量学优势，并有望在治愈癌细胞的同时将对正常细胞的影响降至最低。

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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Journal of Micromanufacturing

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