PixelPrint4D:为呼吸运动应用制造患者特异性可变形 CT 模型的 3D 打印方法。

Jessica Y Im, Neghemi Micah, Amy E Perkins, Kai Mei, Michael Geagan, Peter B Noël
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引用次数: 0

摘要

所有活体医学成像都会受到病人运动的影响,尤其是呼吸运动,这对诊断成像和放射治疗的临床工作流程有重大影响。目前已开发出许多技术,如运动伪影减少和肿瘤跟踪算法,以补偿成像过程中的呼吸运动。为了评估这些技术,需要呼吸运动模型(RMP)作为临床前测试环境,例如在计算机断层扫描(CT)中。然而,目前的 RMP 高度简化,无法展示真实的组织结构或变形模式。随着更复杂的运动补偿技术(如基于深度学习的算法)的兴起,需要更逼真的 RMP。这项工作介绍了 PixelPrint4D,这是一种三维打印方法,旨在为 CT 成像制作逼真的、患者特异的可变形肺部模型。该模型准确复制了患者的肺部结构、纹理和衰减曲线。此外,它还表现出精确的非刚性变形、体积变化和压缩下的衰减变化。PixelPrint4D 能够制作高度逼真的 RMP,超越现有模型,为各种新型 CT 技术提供更强大的测试环境。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
PixelPrint4D: A 3D printing method of fabricating patient-specific deformable CT phantoms for respiratory motion applications.
All in-vivo medical imaging is impacted by patient motion, especially respiratory motion, which has a significant influence on clinical workflows in diagnostic imaging and radiation therapy. Many technologies such as motion artifact reduction and tumor tracking algorithms have been developed to compensate for respiratory motion during imaging. To assess these technologies, respiratory motion phantoms (RMPs) are required as preclinical testing environments, for instance, in computed tomography (CT). However, current RMPs are highly simplified and do not exhibit realistic tissue structures or deformation patterns. With the rise of more complex motion compensation technologies such as deep learning-based algorithms, there is a need for more realistic RMPs. This work introduces PixelPrint4D, a 3D printing method designed to fabricate lifelike, patient-specific deformable lung phantoms for CT imaging. The phantom demonstrated accurate replication of patient lung structures, textures, and attenuation profiles. Furthermore, it exhibited accurate nonrigid deformations, volume changes, and attenuation changes under compression. PixelPrint4D enables the production of highly realistic RMPs, surpassing existing models to offer more robust testing environments for a diverse array of novel CT technologies.
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