Clinical application research on the titanium metal metatarsal prosthesis designed through FEA and manufactured by 3D printing.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-10-10 DOI:10.1038/s41598-025-19302-1

Chao Wu, Danwei Shen, Binwei Qin, Jiayan Deng, Haigang Hu, Xiangyu Wang, Lian Xu, Hong Li, Taicong Yang

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引用次数: 0

Abstract

exploring the therapeutic efficacy of a 3D-printed multiple microporous titanium metatarsal and polyethylene sesamoid prosthesis based on finite element analysis. A patient with defect in the first metatarsal was enrolled. A digital model of the first metatarsal and medial cuneus prosthesis was designed from the contralateral images and the relevant anatomical parameters measured in the preoperative period (Model A). Model B was obtained by finite element analysis and iterative optimization of Model A. Model A and Model B designed with a microporous, an insertion structure for bone ingrowth and fusion, and a polyethylene sesamoid for limb weight-bearing. The object A and object B, made from titanium, were generated by 3D printing. The polyethylene sesamoid was manufactured by computerized numerical control technology. The prosthesis consist of object B and polyethylene sesamoid was implanted into the patient. The clinical parameters were evaluated. The maximum displacements of Model A and Model B were 0.031 mm and 0.019 mm. the deviation of the stress results was controlled within 5% between Model A and Model B. The object A with 63% weighed object B. There is significant difference for pressure in M1 and M5 area between bilateral foot. The AOFAS score was 48 before surgery and 88 after 15 months of surgery. The VAS score of before surgery, after 15 months of surgery and after 27 months of surgery was 7, 2 and 1, respectively. The lightweight and microporous design based on finite element analysis for metatarsal prosthesis, and manufactured by titanium and polyethylene can Reconstruct the arch.

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有限元设计3D打印制造钛金属跖骨假体的临床应用研究。

基于有限元分析，探索3d打印多微孔钛跖骨聚乙烯籽骨假体的治疗效果。我们招募了一名第一跖骨缺损患者。根据对侧图像和术前测量的相关解剖参数设计第一跖骨内侧楔假体数字模型（模型A）。通过对模型A进行有限元分析和迭代优化得到模型B。模型A和模型B设计了微孔结构、用于骨长入融合的插入结构和用于肢体承重的聚乙烯籽状结构。物体A和物体B由钛制成，是通过3D打印生成的。采用计算机数控技术制备聚乙烯芝麻籽。假体由B体和聚乙烯籽骨组成，植入患者体内。评估临床参数。模型A和模型B的最大位移分别为0.031 mm和0.019 mm，模型A和模型B的应力结果偏差控制在5%以内，物体A占物体B重量的63%，双足M1和M5区域的压力差异显著。术前AOFAS评分48分，术后15个月AOFAS评分88分。术前、术后15个月、术后27个月VAS评分分别为7分、2分、1分。基于有限元分析的轻量化和微孔设计，采用钛和聚乙烯材料制作的跖骨假体可以重建足弓。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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