3D 打印个性化晶格植入物作为一种重建承重骨地理缺陷的创新策略。

3D-Printed Personalized Lattice Implant as an Innovative Strategy to Reconstruct Geographic Defects in Load-Bearing Bones.

机构信息

Department of Orthopedics, Orthopedic Research Institute, West China Hospital, Sichuan University, Chengdu, China.

Model Worker and Craftsman Talent Innovation Workshop of Sichuan Province, Chengdu, China.

出版信息

Orthop Surg. 2024 Apr;16(4):821-829. doi: 10.1111/os.14003. Epub 2024 Jan 31.

DOI:10.1111/os.14003

PMID:38296795

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10984818/

Abstract

OBJECTIVE

Geographic defect reconstruction in load-bearing bones presents formidable challenges for orthopaedic surgeon. The use of 3D-printed personalized implants presents a compelling opportunity to address this issue. This study aims to design, manufacture, and evaluate 3D-printed personalized implants with irregular lattice porous structures for geographic defect reconstruction in load-bearing bones, focusing on feasibility, osseointegration, and patient outcomes.

METHODS

This retrospective study involved seven patients who received 3D-printed personalized lattice implants for the reconstruction of geographic defects in load-bearing bones. Personalized implants were customized for each patient. Randomized dodecahedron unit cells were incorporated within the implants to create the porous structure. The pore size and porosity were analyzed. Patient outcomes were assessed through a combination of clinical and radiological evaluations. Tomosynthesis-Shimadzu metal artifact reduction technology (T-SMART) was utilized to evaluate osseointegration. Functional outcomes were assessed according to the Musculoskeletal Tumor Society (MSTS) 93 score.

RESULTS

Multiple pore sizes were observed in porous structures of the implant, with a wide distribution range (approximately 300-900 um). The porosity analysis results showed that the average porosity of irregular porous structures was around 75.03%. The average follow-up time was 38.4 months, ranging from 25 to 50 months. Postoperative X-rays showed that the implants matched the geographic bone defect well. Osseointegration assessments according to T-SMART images indicated a high degree of bone-to-implant contact, along with favorable bone density around the implants. Patient outcomes assessments revealed significant improvements in functional outcomes, with the average MSTS score of 27.3 (range, 26-29). There was no implant-related complication, such as aseptic loosening or structure failure.

CONCLUSION

3D-printed personalized lattice implants offer an innovative and promising strategy for geographic defect reconstruction in load-bearing bones. This approach has the potential to match the unique contours and geometry of the geographic bone defect and facilitate osteointegration.

摘要

目的

在承重骨中进行地理缺陷重建对矫形外科医生来说是一个艰巨的挑战。使用 3D 打印的个性化植入物为解决这个问题提供了一个极具吸引力的机会。本研究旨在设计、制造和评估用于承重骨地理缺陷重建的具有不规则格子多孔结构的 3D 打印个性化植入物，重点关注可行性、骨整合和患者结果。

方法

本回顾性研究纳入了 7 名接受 3D 打印个性化格子植入物治疗承重骨地理缺陷的患者。为每位患者定制个性化植入物。在植入物中纳入随机十二面体单元以创建多孔结构。分析了孔径和孔隙率。通过临床和影像学评估相结合评估患者的结果。使用托马森断层摄影 Shimadzu 金属伪影减少技术（T-SMART）评估骨整合。根据肌肉骨骼肿瘤学会（MSTS）93 评分评估功能结果。

结果

在植入物的多孔结构中观察到多个孔径，分布范围较广（约 300-900μm）。孔隙率分析结果表明，不规则多孔结构的平均孔隙率约为 75.03%。平均随访时间为 38.4 个月，范围为 25 至 50 个月。术后 X 射线显示植入物与地理骨缺陷匹配良好。根据 T-SMART 图像进行的骨整合评估表明，骨与植入物的接触程度很高，并且植入物周围的骨密度良好。患者结果评估显示功能结果显著改善，平均 MSTS 评分为 27.3（范围 26-29）。没有与植入物相关的并发症，如无菌性松动或结构失败。

结论

3D 打印个性化格子植入物为承重骨地理缺陷重建提供了一种创新且有前途的策略。这种方法有可能匹配地理骨缺陷的独特轮廓和几何形状，并促进骨整合。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6db6/10984818/d3e5b7c9d0b0/OS-16-821-g005.jpg

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3D 打印个性化晶格植入物作为一种重建承重骨地理缺陷的创新策略。

3D-Printed Personalized Lattice Implant as an Innovative Strategy to Reconstruct Geographic Defects in Load-Bearing Bones.

机构信息

出版信息

OBJECTIVE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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