Design-optimization and material selection for a femoral-fracture fixation-plate implant

The problem of size/thickness optimization of a distal femoral-fracture fixation-plate is addressed computationally using a combined finite-element/design-optimization procedure. To obtain realistic physiological loading conditions associated with normal living activities (cycling, in the present case), a musculoskeletal multi-body inverse-dynamics analysis is carried out of a human riding the bicycle. While optimizing the design of the femoral-fracture locking-plate, realistic functional requirements pertaining to attain the required level of fracture-femur fixation and longevity/lifecycle were used. It is argued that these types of analysis should be used to complement pre-clinical implant-evaluation tests, the tests which normally include a limited number of physiological loading conditions and single pass/fail outcomes/decisions with respect to a set of lower-bound implant–performance criteria.

[1]  John Rasmussen,et al.  Design Optimization of Airline Seats , 2008 .

[2]  J. Cegoñino,et al.  A Comparative Analysis of Different Treatments for Distal Femur Fractures using the Finite Element Method , 2004, Computer methods in biomechanics and biomedical engineering.

[3]  R. Ganz,et al.  The Evolution of Femoral Shaft Plating Technique , 1998, Clinical orthopaedics and related research.

[4]  J. G. Bledsoe,et al.  Biomechanical Comparison of Polyaxial-Type Locking Plates and a Fixed-Angle Locking Plate for Internal Fixation of Distal Femur Fractures , 2009, Journal of orthopaedic trauma.

[5]  Uwe Schramm Multi-disciplinary optimization for NVH and crashworthiness , 2001 .

[6]  P. de Jong Multi-body modelling of recumbent cycling , 2006 .

[7]  Mark de Zee,et al.  Computational analysis of the influence of seat pan inclination and friction on muscle activity and spinal joint forces. , 2009 .

[8]  R. Haftka,et al.  Structural shape optimization - A survey , 1985 .

[9]  Michael Damsgaard,et al.  Analysis of musculoskeletal systems in the AnyBody Modeling System , 2006, Simul. Model. Pract. Theory.

[10]  L. Claes,et al.  Intradiscal pressure together with anthropometric data--a data set for the validation of models. , 2001, Clinical biomechanics.

[11]  M Stigant,et al.  Development of a fibre optic goniometer system to measure lumbar and hip movement to detect activities and their lumbar postures , 2007, Journal of medical engineering & technology.

[12]  John Rasmussen,et al.  A generic detailed rigid-body lumbar spine model. , 2007, Journal of biomechanics.

[13]  M. Matsuichi,et al.  Fatigue of metals subjected to varying stress , 1968 .

[14]  Imtiaz Haque,et al.  Reliability-Based Design Optimization for Durability of Ground Vehicle Suspension System Components , 2010 .

[15]  M. Bendsøe,et al.  Generating optimal topologies in structural design using a homogenization method , 1988 .

[16]  A. Lystrup,et al.  Composite materials for wind power turbine blades , 2005 .

[17]  F.C.T. van der Helm,et al.  A finite element musculoskeletal model of the shoulder mechanism. , 1994 .

[18]  R. Zickel Fractures of the adult femur excluding the femoral head and neck: a review and evaluation of current therapy. , 1980, Clinical orthopaedics and related research.

[19]  A. J. Lee,et al.  Controlled plastic deformation for the fastening mechanism of an internal fixation device. The new Mennen 3 PeriPro plate , 2007, Computer methods in biomechanics and biomedical engineering.

[20]  Panos Y. Papalambros,et al.  Principles of Optimal Design: Modeling and Computation , 1988 .

[21]  K N An,et al.  Determination of muscle and joint forces: a new technique to solve the indeterminate problem. , 1984, Journal of biomechanical engineering.

[22]  L. Joskowicz,et al.  A CT-based high-order finite element analysis of the human proximal femur compared to in-vitro experiments. , 2007, Journal of biomechanical engineering.