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《中国医学物理学杂志》[ISSN:1005-202X/CN:44-1351/R]

卷:

37

期数:

2020年第2期

页码:

243-248

栏目:

生物材料与力学

出版日期:

2020-02-25

文章信息/Info

Title:

Biomechanical changes of avascular necrosis of the femoral head treated by core decompression and allogeneic bone grafting: a finite element analysis

文章编号:

1005-202X（2020）02-0243-06

作者:

胡元斌1; 周岳来2; 李永顺3; 刘冬3

1.东南大学附属中大医院骨科， 江苏 南京 210009； 2.江苏省苏北人民医院创伤骨科， 江苏 扬州 225000； 3.东南大学附属中大医院江北院区骨科， 江苏 南京 210044

Author(s):

HU Yuanbin1;  ZHOU Yuelai2;  LI Yongshun3;  LIU Dong3

1. Department of Orthopaedics, Zhongda Hospital, Southeast University, Nanjing 210009, China; 2. Department of Orthopedic Trauma, Jiangsu Subei People’s Hospital, Yangzhou 225000, China; 3. Department of Orthopedics, Jiangbei District Hospital of Zhongda Hospital, Southeast University, Nanjing 210044, China

关键词:

股骨头; 缺血性坏死; 有限元分析; 髓芯减压; 同种异体植骨; 生物力学

Keywords:

Keywords: femoral head;  avascular necrosis;  finite element analysis;  core decompression;  allogeneic bone grafting;  biomechanics

分类号:

R318.01

DOI:

DOI:10.3969/j.issn.1005-202X.2020.02.019

文献标志码:

A

摘要:

目的：分析髓芯减压并同种异体植骨治疗早期股骨头缺血性坏死的临床应用。方法：选取收治的1例早期股骨头缺血坏死男性患者，入院后术前对患侧股骨头行多层螺旋CT扫描，然后将CT扫描的图片资料导入专业的有限元分析软件，建立股骨头缺血坏死的有限元模型，在有限元模型上模拟进行髓芯钻孔减压术，隧道植入骨块到软骨下骨约0~6 mm处，自体松质骨夯实。双足站立位为股骨头的模拟受力体位，髋关节的负荷条件为：外展肌合力M、髂胫束力T以及髋关节接触力J分别为1 060、1 721、1 621 N，选取90°、120°以及150°的坏死角度，分别计算未处理过的股骨头坏死模型的塌陷值、行单纯髓芯减压以及行髓芯减压加植骨时的塌陷值。结果：股骨头的正常骨质杨氏模量高于坏死骨的杨氏模量，正常骨质的横向变形系数低于坏死骨。行股骨头髓芯钻孔减压术后，股骨头的塌陷值显著增加，而减压隧道植入同种异体骨后，其塌陷值显著减低，但高于正常的股骨头。同时，由于股骨头坏死角度的增加，其塌陷值也明显增加。结论：髓芯钻孔减压并同种异体植骨术能有效增进坏死区的骨质修复，加强减压通道所致股骨头支撑结构的改变，防止股骨头关节面的塌陷。

Abstract:

Abstract: Objective To analyze the clinical application of core decompression combined with allogeneic bone grafting in the treatment of early avascular necrosis of the femoral head. Methods A patients with early avascular necrosis of the femoral head was enrolled. Multi-slice spiral CT scan was performed on the affected femoral head before operation, and the obtained CT image was then imported into a professional finite element analysis software for establishing a finite element model of avascular necrosis of the femoral head. The simulation of core decompression was conducted on the finite element model. The allogeneic bone was grafted to the subchondral bone at about 0-6 mm through compression channel, and the autologous cancellous bone was compacted. Biped standing position was adopted as the simulated force position of the femoral head. The load-bearing conditions of the hip joint were as follow: the abductor muscle force M, iliotibial tract tendon force T and hip joint contact force J were 1 060, 1 721 and 1 621 N, respectively. The necrosis angles of 90°, 120° and 150° were used to calculate the collapse value of the untreated femoral head necrosis model and the collapse values after treatments with core decompression only or core decompression combined with bone grafting. Results The Young’s modulus of the normal bone of the femoral head was higher than that of the necrotic bone, while the lateral deformation coefficient of the normal bone was lower than that of the necrotic bone. After the femoral head core decompression, the collapse value of the femoral head was obviously increased, and after that the allogeneic bone was grafted in the decompression channel, the collapse value was remarkably reduced, but still higher than that of the normal femoral head. Meanwhile, due to the increase in the necrosis angles of the femoral head, its collapse value was also significantly increased. Conclusion Core decompression combined with allogeneic bone grafting can effectively improve the bone repair in the necrotic area, strengthen the deformation of the femoral head support structure caused by the decompression channel, and prevent the collapse of the femoral head joint surface.

备注/Memo

备注/Memo:

【收稿日期】2019-10-11 【基金项目】南京市医学科技发展项目（YKK17271） 【作者简介】胡元斌，博士，副主任医师，研究方向：骨科创伤、关节外科，E-mail: nanjhuyb168@163.com

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更新日期/Last Update: 2020-03-03