Effect of Elastic Modulus on Biomechanical Properties of Lumbar Interbody Fusion Cage
Effect of Elastic Modulus on Biomechanical Properties of Lumbar Interbody Fusion Cage
摘要
This work focuses on the influence of elastic modulus on biomechanical properties of lumbar interbody fusion cages by selecting two titanium alloys with different elastic modulus. They were made by a new β type alloy with chemical composition of Ti-24Nb-4Zr-7.6Sn having low Young's modulus -50 GPa and by a conventional biomedical alloy Ti-6Al-4V having Young's modulus -110 GPa. The results showed that the designed cages with low modulus (LMC) and high modulus (HMC) can keep identical compression load -9.8 kN and endure fatigue cycles higher than 5× 10^6 without functional or mechanical failure under 2.0 kN axial compression. The anti-subsidence ability of both group cages were examined by axial compression of thoracic spine specimens (T9-T10) dissected freshly from the calf with averaged age of 6 months. The results showed that the LMC has better anti-subsidence ability than the HMC (p〈0.05). The above results suggest that the cage with low elastic modulus has great potential for clinical applications.
This work focuses on the influence of elastic modulus on biomechanical properties of lumbar interbody fusion cages by selecting two titanium alloys with different elastic modulus. They were made by a new β type alloy with chemical composition of Ti-24Nb-4Zr-7.6Sn having low Young's modulus -50 GPa and by a conventional biomedical alloy Ti-6Al-4V having Young's modulus -110 GPa. The results showed that the designed cages with low modulus (LMC) and high modulus (HMC) can keep identical compression load -9.8 kN and endure fatigue cycles higher than 5× 10^6 without functional or mechanical failure under 2.0 kN axial compression. The anti-subsidence ability of both group cages were examined by axial compression of thoracic spine specimens (T9-T10) dissected freshly from the calf with averaged age of 6 months. The results showed that the LMC has better anti-subsidence ability than the HMC (p〈0.05). The above results suggest that the cage with low elastic modulus has great potential for clinical applications.
参考文献20
-
1Y. Arai, M. Takahashi and H. Kurosawa: J. Orthop. Sur., 2002, 10(1), 1.
-
2P.C. McAfee , J.G. DeVine,C.D. Chaput,B.G. Prybis,I.L. Fedder, B.W. Cunningham, D.J. Farrell, S.J. Hess and F.E. Vigna: Spine, 2005, 30(6 Suppl), S60.
-
3T.A. Zdeblick and F.M. Phillips: Spine, 2003, 28(15 Suppl), S2.
-
4N. Desogus, F. Ennas, R. Leuze and A. Maleci: J. Neurosurg Sci., 2005, 49(4), 137.
-
5P.C. McAfee: J. Bone Joint Surg (Am), 1999, 81,859.
-
6T. Steffen, A. Tsantrizos, I. Fruth and M. Aebi: J. Eur. Spine, 2000, 9(Suppl 1),, $89.
-
7J. Beddoes and K. Bucci: J. Mater. Sci., Mater. Med., 1999, 10, 389.
-
8S.H. Lee, F.R. Brennan, J.J. Jacob, R.M. Urban, D.R. Ragasa and T.T.Glant: J. Orthop. Res., 1997, 15, 40.
-
9K. Merritt and S.A. Brown: Clin. Orthop. Relat. Res., 1996, 329, 233.
-
10T.H. Smit, R.Muller, D.M. Van and P.I. Wuisman: Spine, 2003, 28(16), 1802.
-
1李宗坤,滕彦磊,赵通阳.塑性混凝土防渗墙应力变形分析[J].人民黄河,2011,33(1):129-130. 被引量:3
-
2刘志平,杜素梅,呼英俊,潘存海.低弹性模量Ti/W多孔复合材料的组织和力学性能[J].热加工工艺,2010,39(4):69-71.
-
3庞建平,董丽,丁建林.上西山水库除险加固工程大坝混凝土防渗墙配比试验研究[J].水利建设与管理,2013,33(5):41-44. 被引量:1
-
4尤明庆.岩石试样的杨氏模量与围压的关系[J].岩石力学与工程学报,2003,22(1):53-60. 被引量:97
-
5祝小靓,丁建彤,蔡跃波,白银.胶凝砂砾石强度和弹性模量试验研究[J].人民黄河,2016,38(3):126-128. 被引量:8
-
6赵宏霞.羟基磷灰石微结构调控的研究进展[J].功能材料,2017,48(1):1047-1055. 被引量:4
-
7车维斌,宋庆杰,刘登贵.长河坝水电站大坝防渗墙高强低弹混凝土配合比设计与应用[J].四川水力发电,2015,34(3):43-47.
-
8郭立新,林天亮,李春雷.关节损伤对脊椎频率特性的影响分析[J].东北大学学报(自然科学版),2006,27(6):623-626.
-
9邓云,吴颖,李云飞.果蔬在贮运过程中的生物力学特性及质地检测[J].农业工程学报,2005,21(4):1-6. 被引量:31
-
10薛平,贾明印,丁筠.环保减排的塑木新材料[J].新材料产业,2008(1):50-53. 被引量:2
