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使用CAx和增材制造(AM)系统制造具有更高精度的解剖结构聚合物模型以用于骨科手术规划

Manufacturing Polymer Model of Anatomical Structures with Increased Accuracy Using CAx and AM Systems for Planning Orthopedic Procedures.

作者信息

Turek Paweł, Filip Damian, Przeszłowski Łukasz, Łazorko Artur, Budzik Grzegorz, Snela Sławomir, Oleksy Mariusz, Jabłoński Jarosław, Sęp Jarosław, Bulanda Katarzyna, Wolski Sławomir, Paszkiewicz Andrzej

机构信息

Faculty of Mechanical Engineering and Aeronautics, Rzeszów University of Technology, 35-959 Rzeszów, Poland.

Institute of Medical Science, University of Rzeszów, 35-959 Rzeszów, Poland.

出版信息

Polymers (Basel). 2022 May 31;14(11):2236. doi: 10.3390/polym14112236.

DOI:10.3390/polym14112236
PMID:35683908
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9182597/
Abstract

Currently, medicine uses typical industrial structure techniques, including reverse engineering, data processing, 3D-CAD modeling, 3D printing, and coordinate measurement techniques. Taking this into account, one can notice the applications of procedures used in the aviation or automotive industries based on the structure of Industry 4.0 in the planning of operations and the production of medical models with high geometric accuracy. The procedure presented in the publication shortens the processing time of tomographic data and increases the reconstruction accuracy within the hip and knee joints. The procedure allows for the partial removal of metallic artifacts from the diagnostic image. Additionally, numerical models of anatomical structures, implants, and bone cement were developed in more detail by averaging the values of local segmentation thresholds. Before the model manufacturing process, additional tests of the PLA material were conducted in terms of its strength and thermal properties. Their goal was to select the appropriate type of PLA material for manufacturing models of anatomical structures. The numerical models were divided into parts before being manufactured using the Fused Filament Fabrication technique. The use of the modifier made it possible to change the density, type of filling, number of counters, and the type of supporting structure. These treatments allowed us to reduce costs and production time and increase the accuracy of the printout. The accuracy of the manufactured model geometry was verified using the MCA-II measuring arm with the MMDx100 laser head and surface roughness using a 3D Talyscan 150 profilometer. Using the procedure, a decrease in geometric deviations and amplitude parameters of the surface roughness were noticed. The models based on the presented approach allowed for detailed and meticulous treatment planning.

摘要

目前,医学采用典型的工业结构技术,包括逆向工程、数据处理、3D-CAD建模、3D打印和坐标测量技术。考虑到这一点,人们可以注意到基于工业4.0结构的航空或汽车行业所使用的程序在手术规划和高几何精度医学模型生产中的应用。该出版物中介绍的程序缩短了断层扫描数据的处理时间,并提高了髋关节和膝关节内的重建精度。该程序允许从诊断图像中部分去除金属伪影。此外,通过对局部分割阈值的值进行平均,更详细地开发了解剖结构、植入物和骨水泥的数值模型。在模型制造过程之前,对聚乳酸材料的强度和热性能进行了额外测试。其目的是选择合适类型的聚乳酸材料来制造解剖结构模型。在使用熔丝制造技术制造之前,将数值模型分成几个部分。使用改性剂可以改变密度、填充类型、计数器数量和支撑结构类型。这些处理使我们能够降低成本和生产时间,并提高打印精度。使用带有MMDx100激光头的MCA-II测量臂验证了制造模型几何形状的精度,并使用3D Talyscan 150轮廓仪测量了表面粗糙度。使用该程序后,表面粗糙度的几何偏差和幅度参数有所降低。基于所提出方法的模型允许进行详细而细致的治疗规划。

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