朝着使用多材料、颗粒喂料的增材制造平台制造新型成像幻影的方向发展。

Franck Lacan, Richard Johnston, Rhys Carrington, Emiliano Spezi, Peter Theobald
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引用次数: 0

摘要

增材制造(AM)提供的设计自由度现在被用于多种应用,包括个性化医疗成像领域的许多应用。本研究利用颗粒式多材料AM机器作为制造新成像模型的途径,用于开发和改进用于检测细微软组织异常的算法。传统上包括均质材料,高分辨率扫描现在允许异质,多材料的幻影。研究了聚乳酸(PLA)、热塑性聚氨酯(TPU)和热塑性弹性体(TPE)作为潜在材料。相对于数字设计文件评估了制造精度和精度,同时通过微计算机断层扫描量化填充密度来评估实现结构非均质性的潜力。Hounsfield单位(HU)也通过临床扫描仪捕获。PLA的建造始终太小,差0.2 - 0.3%。相反,TPE零件始终比数字文件大,尽管只大0.1%。相对于指定的尺寸,TPU组件的差异可以忽略不计。材料填充的准确性和精度较差,PLA在3次构建中相对于数字文件表现出更高和更低的密度。TPU和TPE产生的填充物都过于致密。PLA材料产生可重复的HU值,在TPU和TPE上精度较差。随着充填密度的增加,所有的HU值都趋向于甚至超过水的参考值(0 HU)。这些数据表明,颗粒式增材制造可以生产出准确而精确的结构,并有可能包括多种材料,为更现实和先进的幻影设计提供机会。在这样做的过程中,这将使临床科学家能够开发出更灵敏的应用程序,旨在检测组织中更细微的变化,并确信他们的校准模型反映了他们的预期设计。
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Towards using a multi-material, pellet-fed additive manufacturing platform to fabricate novel imaging phantoms.

The design freedom afforded by additive manufacturing (AM) is now being leveraged across multiple applications, including many in the fields of imaging for personalised medicine. This study utilises a pellet-fed, multi-material AM machine as a route to fabricating new imaging phantoms, used for developing and refining algorithms for the detection of subtle soft tissue anomalies. Traditionally comprising homogeneous materials, higher-resolution scanning now allows for heterogeneous, multi-material phantoms. Polylactic acid (PLA), a thermoplastic urethane (TPU) and a thermoplastic elastomer (TPE) were investigated as potential materials. Manufacturing accuracy and precision were assessed relative to the digital design file, whilst the potential to achieve structural heterogeneity was evaluated by quantifying infill density via micro-computed tomography. Hounsfield units (HU) were also captured via a clinical scanner. The PLA builds were consistently too small, by 0.2 - 0.3%. Conversely, TPE parts were consistently larger than the digital file, though by only 0.1%. The TPU components had negligible differences relative to the specified sizes. The accuracy and precision of material infill were inferior, with PLA exhibiting greater and lower densities relative to the digital file, across the 3 builds. Both TPU and TPE produced infills that were too dense. The PLA material produced repeatable HU values, with poorer precision across TPU and TPE. All HU values tended towards, and some exceeded, the reference value for water (0 HU) with increasing infill density. These data have demonstrated that pellet-fed AM can produce accurate and precise structures, with the potential to include multiple materials providing an opportunity for more realistic and advanced phantom designs. In doing so, this will enable clinical scientists to develop more sensitive applications aimed at detecting ever more subtle variations in tissue, confident that their calibration models reflect their intended designs.

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来源期刊
Journal of Medical Engineering and Technology
Journal of Medical Engineering and Technology Engineering-Biomedical Engineering
CiteScore
4.60
自引率
0.00%
发文量
77
期刊介绍: The Journal of Medical Engineering & Technology is an international, independent, multidisciplinary, bimonthly journal promoting an understanding of the physiological processes underlying disease processes and the appropriate application of technology. Features include authoritative review papers, the reporting of original research, and evaluation reports on new and existing techniques and devices. Each issue of the journal contains a comprehensive information service which provides news relevant to the world of medical technology, details of new products, book reviews, and selected contents of related journals.
期刊最新文献
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