Above-knee prosthesis design based on fatigue life using finite element method and design of experiment.

The main objective of this work is to improve the standard of the existing design of knee prosthesis developed by Thailand's Prostheses Foundation of Her Royal Highness The Princess Mother. The experimental structural tests, based on the ISO 10328, of the existing design showed that a few components failed due to fatigue under normal cyclic loading below the required number of cycles. The finite element (FE) simulations of structural tests on the knee prosthesis were carried out. Fatigue life predictions of knee component materials were modeled based on the Morrow's approach. The fatigue life prediction based on the FE model result was validated with the corresponding structural test and the results agreed well. The new designs of the failed components were studied using the design of experimental approach and finite element analysis of the ISO 10328 structural test of knee prostheses under two separated loading cases. Under ultimate loading, knee prosthesis peak von Mises stress must be less than the yield strength of knee component's material and the total knee deflection must be lower than 2.5mm. The fatigue life prediction of all knee components must be higher than 3,000,000 cycles under normal cyclic loading. The design parameters are the thickness of joint bars, the diameter of lower connector and the thickness of absorber-stopper. The optimized knee prosthesis design meeting all the requirements was recommended. Experimental ISO 10328 structural test of the fabricated knee prosthesis based on the optimized design confirmed the finite element prediction.

[1]  R. A. Fisher,et al.  Design of Experiments , 1936 .

[2]  Oleksandr Poliakov,et al.  Multicriteria Synthesis of a Polycentric Knee Prosthesis For Transfemoral Amputees , 2012 .

[3]  Clare K Fitzpatrick,et al.  Dynamic finite element knee simulation for evaluation of knee replacement mechanics. , 2012, Journal of biomechanics.

[4]  Yoshiharu Mutoh,et al.  Fatigue Life Prediction of SUS 630 (H900) Steel under High Cycle Loading , 2013 .

[5]  Shuhei Takeuchi,et al.  A study of the mechanical properties of an Al–Si–Cu alloy (ADC12) produced by various casting processes , 2012 .

[6]  Luis Héctor Hernández-Gómez,et al.  Optimization of the Design of a Four Bar Mechanism for a Lower Limb Prosthesis Using the Taboo Search Algorithm , 2013 .

[7]  P. Blume,et al.  Let them walk! Current prosthesis options for leg and foot amputees. , 2008, Journal of the American College of Surgeons.

[8]  Ming Zhang,et al.  Design of monolimb using finite element modelling and statistics-based Taguchi method. , 2005, Clinical biomechanics.

[9]  H. C. Lee,et al.  High cycle fatigue life prediction of cold forging tools based on workpiece material property , 2007 .

[10]  Nian-Zhong Chen,et al.  A numerical approach to evaluate the fatigue life of monolimb. , 2006, Medical engineering & physics.

[11]  Hobson Da,et al.  Computer optimization of polycentric prosthetic knee mechanisms. , 1975 .

[12]  Ica Manas-Zloczower,et al.  Enhancement of fatigue life of polyurethane composites containing carbon nanotubes , 2013 .

[13]  M. A. El Baradie,et al.  Prediction of tool life in end milling by response surface methodology , 1997 .

[14]  William L. Cleghorn,et al.  Topology Optimization of an Injection Moldable Prosthetic Knee Joint , 2010 .

[15]  J. Simões,et al.  Relationship of design features of stemmed tibial knee prosthesis with stress shielding and end-of-stem pain , 2009 .

[16]  C W Radcliffe Four-bar linkage prosthetic knee mechanisms: Kinematics, alignment and prescription criteria , 1994, Prosthetics and orthotics international.