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Development and validation of a computational model of the knee joint for the evaluation of surgical treatments for osteoarthritis

Rajshree Mootanah, Carl W. Imhauser, F. Reisse, Diagarajen Carpanen, Robert Walker, Matthew F. Koff, Mark Lenhoff, S. Robert Rozbruch, Austin T. Fragomen, Z. Dewan, Yatin Kirane, K. Cheah, JK Dowell, Howard J. Hillstrom

Year
2014
Citations
109
Access
Open access

Abstract

A three-dimensional (3D) knee joint computational model was developed and validated to predict knee joint contact forces and pressures for different degrees of malalignment. A 3D computational knee model was created from high-resolution radiological images to emulate passive sagittal rotation (full-extension to 65°-flexion) and weight acceptance. A cadaveric knee mounted on a six-degree-of-freedom robot was subjected to matching boundary and loading conditions. A ligament-tuning process minimised kinematic differences between the robotically loaded cadaver specimen and the finite element (FE) model. The model was validated by measured intra-articular force and pressure measurements. Percent full scale error between FE-predicted and in vitro-measured values in the medial and lateral compartments were 6.67% and 5.94%, respectively, for normalised peak pressure values, and 7.56% and 4.48%, respectively, for normalised force values. The knee model can accurately predict normalised intra-articular pressure and forces for different loading conditions and could be further developed for subject-specific surgical planning.

Keywords

Cadaveric spasmKinematicsKnee JointSagittal planeCadaverOsteoarthritisJoint (building)BiomechanicsBiomedical engineeringFinite element method

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