Simone Giovanni Gugliandolo, Shabarish Purushothaman Pillai, Shankar Rajendran, Maria Giulia Vincini, Matteo Pepa, Floriana Pansini, Mattia Zaffaroni, Giulia Marvaso, Daniela Alterio, Andrea Vavassori, Stefano Durante, Stefania Volpe, Federica Cattani, Barbara Alicja Jereczek-Fossa, Davide Moscatelli, Bianca Maria Colosimo
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引用次数: 0
Abstract
The work investigates the implementation of personalized radiotherapy boluses by means of additive manufacturing technologies. Boluses materials that are currently used need an excessive amount of human intervention which leads to reduced repeatability in terms of dosimetry. Additive manufacturing can solve this problem by eliminating the human factor in the process of fabrication. Planar boluses with fixed geometry and personalized boluses printed starting from a computed tomography scan of a radiotherapy phantom were produced. First, a dosimetric characterization study on planar bolus designs to quantify the effects of print parameters such as infill density and geometry on the radiation beam was made. Secondly, a volumetric quantification of air gap between the bolus and the skin of the patient as well as dosimetric analyses were performed. The optimization process according to the obtained dosimetric and airgap results allowed us to find a combination of parameters to have the 3D-printed bolus performing similarly to that in conventional use. These preliminary results confirm those in the relevant literature, with 3D-printed boluses showing a dosimetric performance similar to conventional boluses with the additional advantage of being perfectly conformed to the patient geometry.
这项工作研究通过增材制造技术实现个性化放疗栓。目前使用的栓剂材料需要过多的人工干预,导致剂量测定的可重复性降低。增材制造技术可以消除制造过程中的人为因素,从而解决这一问题。根据放疗模型的计算机断层扫描结果,我们制作了具有固定几何形状的平面注射器和个性化注射器。首先,对平面栓剂设计进行了剂量测定研究,以量化打印参数(如填充密度和几何形状)对辐射束的影响。其次,还对栓剂与患者皮肤之间的空气间隙进行了体积量化,并进行了剂量分析。根据获得的剂量测定和气隙结果进行优化后,我们找到了一个参数组合,使 3D 打印栓剂的性能与传统使用的栓剂类似。这些初步结果证实了相关文献中的观点,三维打印栓剂显示出与传统栓剂相似的剂量学性能,而且还具有与患者几何形状完全吻合的额外优势。
期刊介绍:
The purpose of the journal Radiological Physics and Technology is to provide a forum for sharing new knowledge related to research and development in radiological science and technology, including medical physics and radiological technology in diagnostic radiology, nuclear medicine, and radiation therapy among many other radiological disciplines, as well as to contribute to progress and improvement in medical practice and patient health care.