个体化三维打印多孔增材在猪模型中重建髋臼骨缺损。

Reconstruction of the Acetabular Bone Defect by the Individualized Three-Dimensional Printed Porous Augment in a Swine Model.

机构信息

Department of Orthopaedics, The First Medical Centre, Chinese PLA General Hospital, Beijing 100853, China.

Department of Orthopaedics, The Logistics Support Forces of Chinese PLA 985 Hospital, Taiyuan, Shanxi 030001, China.

出版信息

Biomed Res Int. 2020 Nov 30;2020:4542302. doi: 10.1155/2020/4542302. eCollection 2020.

DOI:10.1155/2020/4542302

PMID:33335923

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7723487/

Abstract

METHODS

As an acetabular bone defect model created in Bama miniswine, an augment individually fabricated by 3D print technique with Ti6Al4V powders was implanted to repair the defect. Nine swine were divided into three groups, including the immediate biomechanics group, 12-week biomechanics group, and 12-week histological group. The inner structural parameters of the 3D printed porous augment were measured by scanning electron microscopy (SEM), including porosity, pore size, and trabecular diameter. The matching degree between the postoperative augment and the designed augment was assessed by CT scanning and 3D reconstruction. In addition, biomechanical properties, such as stiffness, compressive strength, and the elastic modulus of the 3D printed porous augment, were measured by means of a mechanical testing machine. Moreover, bone ingrowth and implant osseointegration were histomorphometrically assessed.

RESULTS

In terms of the inner structural parameters of the 3D printed porous augment, the porosity was 55.48 ± 0.61%, pore size 319.23 ± 25.05 m, and trabecular diameter 240.10 ± 23.50 m. Biomechanically, the stiffness was 21464.60 ± 1091.69 N/mm, compressive strength 231.10 ± 11.77 MPa, and elastic modulus 5.35 ± 0.23 GPa, respectively. Furthermore, the matching extent between the postoperative augment and the designed one was up to 91.40 ± 2.83%. Besides, the maximal shear strength of the 3D printed augment was 929.46 ± 295.99 N immediately after implantation, whereas the strength was 1521.93 ± 98.38 N 12 weeks after surgery ( = 0.0302). The bone mineral apposition rate (m per day) 12 weeks post operation was 3.77 ± 0.93 m/d. The percentage bone volume of new bone was 22.30 ± 4.51% 12 weeks after surgery.

CONCLUSION

The 3D printed porous Ti6Al4V augment designed in this study was well biocompatible with bone tissue, possessed proper biomechanical features, and was anatomically well matched with the defect bone. Therefore, the 3D printed porous Ti6Al4V augment possesses great potential as an alternative for individualized treatment of severe acetabular bone defects.

摘要

方法

在巴马小型猪中建立髋臼骨缺损模型，采用 3D 打印技术个体化制造的钛合金增材（Ti6Al4V 粉末）被植入以修复缺损。将 9 头猪分为三组，包括即刻生物力学组、12 周生物力学组和 12 周组织学组。通过扫描电子显微镜（SEM）测量 3D 打印多孔增材的内部结构参数，包括孔隙率、孔径和小梁直径。通过 CT 扫描和 3D 重建评估术后增材与设计增材的匹配程度。此外，通过机械试验机测量 3D 打印多孔增材的生物力学性能，如刚度、抗压强度和弹性模量。此外，还通过组织形态计量学评估了骨长入和植入物骨整合情况。

结果

3D 打印多孔增材的内部结构参数方面，孔隙率为 55.48±0.61%，孔径为 319.23±25.05μm，小梁直径为 240.10±23.50μm。生物力学方面，刚度为 21464.60±1091.69N/mm，抗压强度为 231.10±11.77MPa，弹性模量为 5.35±0.23GPa。此外，术后增材与设计增材的匹配程度高达 91.40±2.83%。此外，3D 打印增材植入后即刻的最大抗剪强度为 929.46±295.99N，术后 12 周时为 1521.93±98.38N（=0.0302）。术后 12 周时，骨矿物质沉积率（m/d）为 3.77±0.93m/d。术后 12 周时，新骨的骨体积百分比为 22.30±4.51%。

结论

本研究设计的 3D 打印多孔 Ti6Al4V 增材与骨组织具有良好的生物相容性，具有适当的生物力学特性，与缺损骨在解剖学上匹配良好。因此，3D 打印多孔 Ti6Al4V 增材作为严重髋臼骨缺损个体化治疗的替代方法具有很大的潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ada6/7723487/1b8f859d2c78/BMRI2020-4542302.001.jpg

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个体化三维打印多孔增材在猪模型中重建髋臼骨缺损。

Reconstruction of the Acetabular Bone Defect by the Individualized Three-Dimensional Printed Porous Augment in a Swine Model.

机构信息

出版信息

METHODS

RESULTS

CONCLUSION

方法

结果

结论

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