Finite element analysis of the multiple drilling technique for early osteonecrosis of the femoral head

doi:10.3877/cma.j.issn.1673-9450.2017.01.007

Abstract

Abstract:

Objective

To explore the influencing factors in traditional single large channel core decompression and multiple drilling technique in the treatment of early osteonecrosis of the femoral head with the methods of finite element analysis.

Methods

The right femur of healthy adults were choosen as the research object, and CT scanning was conducted to get the images of cross sections.The images were then inputted into computer to get contour of femur and rebuild 3D model.Distal end of femur was completely fixed, and 570N pressure on the femoral head was applied according to the three-dimensional space distribution of femur force under physiological state. Three-dimensional finite element models were founded with the necrotic range of 15% and 30%, then the stress distributions of cancellous bone and cortical bone of femoral head were obtained through the models.

Results

Different methods of decompression and different numbers of channel cores would lead to a different stress value: stress concentration would appear on femoral head after core decompression. Multiple drilling technique would get a more stress concentration comparing to traditional single large channel core decompression, the stress value was summit of cortical bone and cancellous bone would both less than their yield strength and tensile strength of femoral hard.

Conclusions

Multiple drilling technique is more effective and feasible in the treatment of early osteonecrosis of the femoral head comparing to traditional single large channel core decompression.

Key words: Core decompression, Multiple channels, Osteonecrosis of the femoral head, Finite element method

Binbin Yang, Yaosheng Liu, Shubin Liu, Xiuyun Su, Peidong Sun, Shiguo Zhou. Finite element analysis of the multiple drilling technique for early osteonecrosis of the femoral head[J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2017, 12(01): 39-45.

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Figures/Tables 10

References 29

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组织	弹性模量(MPa)	泊松比
骨皮质	15 100.0	0.30
骨松质	445.0	0.22
坏死骨	332.9	0.30

组织	弹性模量(MPa)	泊松比
骨皮质	15 100.0	0.30
骨松质	445.0	0.22
坏死骨	332.9	0.30

模拟减压手术类型	股骨头承力点(MPa)		股骨颈区(MPa)		股骨大转子下(MPa)
模拟减压手术类型	皮质骨	松质骨	皮质骨	松质骨	皮质骨	松质骨
单纯坏死模型	13.10	0.19	7.20	0.12	3.80	0.05
大直径减压模型	16.30	0.23	8.10	0.19	4.90	0.07
6孔道减压模型	15.50	0.22	7.80	0.17	4.50	0.06
12孔道减压模型	16.30	0.27	8.30	0.21	5.10	0.08
大直径＋6孔道减压模型	17.10	0.33	9.30	0.23	5.60	0.11

模拟减压手术类型	股骨头承力点(MPa)		股骨颈区(MPa)		股骨大转子下(MPa)
模拟减压手术类型	皮质骨	松质骨	皮质骨	松质骨	皮质骨	松质骨
单纯坏死模型	13.10	0.19	7.20	0.12	3.80	0.05
大直径减压模型	16.30	0.23	8.10	0.19	4.90	0.07
6孔道减压模型	15.50	0.22	7.80	0.17	4.50	0.06
12孔道减压模型	16.30	0.27	8.30	0.21	5.10	0.08
大直径＋6孔道减压模型	17.10	0.33	9.30	0.23	5.60	0.11

模拟减压手术类型	股骨头承力点(MPa)		股骨颈区(MPa)		股骨大转子下(MPa)
模拟减压手术类型	皮质骨	松质骨	皮质骨	松质骨	皮质骨	松质骨
单纯坏死模型	14.20	0.25	7.50	0.12	4.10	0.06
大直径减压模型	17.30	0.29	8.30	0.23	5.00	0.09
6孔道减压模型	16.80	0.25	8.30	0.19	4.90	0.07
12孔道减压模型	17.10	0.31	8.50	0.24	5.30	0.09
大直径＋6孔道减压模型	17.60	0.37	9.80	0.27	6.70	0.12

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