- 作者:Shinji Inoue ; MDa ; Masao Akagi ; MD ; PhDa ; ; Shigeki Asada ; MDa ; Shigeshi Mori ; MDa ; Hironori Zaima ; PhDb ; Masahiko Hashida ; PhDb
- 关键词:unicompartmental ; arthroplasty ; fracture ; tibia ; finite element method
- 刊名:The Journal of Arthroplasty
- 出版年:2016
- 出版时间:September 2016
- 年:2016
- 卷:31
- 期:9
- 页码:2025-2030
- 全文大小:1983 K
Methods
We constructed a 3-dimensional finite elemental method model of the tibia with a medial component and assessed stress concentrations by changing the inclination from 6° varus to 6° valgus. Subsequently, we repeated the same procedure adding extended sagittal bone cuts of 2° and 10° in the posterior tibial cortex. Furthermore, we calculated the bone volume that supported the tibial component, which is considered to affect stress distribution in the medial tibial condyle.
Results
Stress concentrations were observed on the medial tibial metaphyseal cortices and on the anterior and posterior tibial cortices in the corner of cut surfaces in all models; moreover, the maximum principal stresses on the posterior cortex were larger than those on the anterior cortex. The extended sagittal bone cuts in the posterior tibial cortex increased the stresses further at these 3 sites. In the models with a 10° extended sagittal bone cut, the maximum principal stress on the posterior cortex increased as the tibial inclination changed from 6° varus to 6° valgus. The bone volume decreased as the inclination changed from varus to valgus.
Conclusion
In this finite element method, the risk of MTCFs increases with increasing valgus inclination of the tibial component and with increased extension of the sagittal cut in the posterior tibial cortex.