Your search keyword '"Goreham-Voss CM"' showing total 6 results

1. Cartilage-on-cartilage versus metal-on-cartilage impact characteristics and responses.

Author

Heiner AD, Smith AD, Goetz JE, Goreham-Voss CM, Judd KT, McKinley TO, and Martin JA

Subjects

Animals, Cattle, Chondrocytes physiology, Copper, Stress, Mechanical, Zinc, Cartilage, Articular injuries, Osteoarthritis etiology

Abstract

A common in vitro model for studying acute mechanical damage in cartilage is to impact an isolated osteochondral or cartilage specimen with a metallic impactor. The mechanics of a cartilage-on-cartilage (COC) impact, as encountered in vivo, are likely different than those of a metal-on-cartilage (MOC) impact. The hypothesis of this study was that impacted in vitro COC and MOC specimens would differ in their impact behavior, mechanical properties, chondrocyte viability, cell metabolism, and histologic structural damage. Osteochondral specimens were impacted with either an osteochondral plug or a metallic cylinder at the same delivered impact energy per unit area, and processed after 14 days in culture. The COC impacts resulted in about half of the impact maximum stress and a quarter of the impact maximum stress rate of change, as compared to the MOC impacts. The impacted COC specimens had smaller changes in mechanical properties, smaller decreases in chondrocyte viability, higher total proteoglycan content, and less histologic structural damage, as compared to the impacted MOC specimens. If MOC impact conditions are to be used for modeling of articular injuries and post-traumatic osteoarthritis, the differences between COC and MOC impacts must be kept in mind., (Copyright © 2013 Orthopaedic Research Society.)

Published

2013

2. Preferential superior surface motion in wear simulations of the Charité total disc replacement.

Author

Goreham-Voss CM, Vicars R, Hall RM, and Brown TD

Subjects

Biomechanical Phenomena physiology, Equipment Failure Analysis instrumentation, Friction physiology, Humans, Intervertebral Disc physiology, Intervertebral Disc surgery, Lumbar Vertebrae physiology, Prosthesis Design methods, Range of Motion, Articular physiology, Surface Properties, Total Disc Replacement instrumentation, Weight-Bearing physiology, Equipment Failure Analysis methods, Finite Element Analysis, Lumbar Vertebrae surgery, Models, Biological, Total Disc Replacement methods

Abstract

Laboratory wear simulations of the dual-bearing surface Charité total disc replacement (TDR) are complicated by the non-specificity of the device's center of rotation (CoR). Previous studies have suggested that articulation of the Charité preferentially occurs at the superior-bearing surface, although it is not clear how sensitive this phenomenon is to lubrication conditions or CoR location. In this study, a computational wear model is used to study the articulation kinematics and wear of the Charité TDR. Implant wear was found to be insensitive to the CoR location, although seemingly non-physiologic endplate motion can result. Articulation and wear were biased significantly to the superior-bearing surface, even in the presence of significant perturbations of loading and friction. The computational wear model provides novel insight into the mechanics and wear of the Charité TDR, allowing for better interpretation of in vivo results, and giving useful insight for designing future laboratory physical tests.

Published

2012

3. Apparent transverse compressive material properties of the digital flexor tendons and the median nerve in the carpal tunnel.

Author

Main EK, Goetz JE, Rudert MJ, Goreham-Voss CM, and Brown TD

Subjects

Adult, Aged, Biomechanical Phenomena, Elasticity, Female, Finite Element Analysis, Humans, Male, Materials Testing, Middle Aged, Neurons pathology, Pressure, Stress, Mechanical, Tendons pathology, Wrist pathology, Carpal Tunnel Syndrome pathology, Compressive Strength, Median Nerve pathology

Abstract

Carpal tunnel syndrome is a frequently encountered peripheral nerve disorder caused by mechanical insult to the median nerve, which may in part be a result of impingement by the adjacent digital flexor tendons. Realistic finite element (FE) analysis to determine contact stresses between the flexor tendons and median nerve depends upon the use of physiologically accurate material properties. To assess the transverse compressive properties of the digital flexor tendons and median nerve, these tissues from ten cadaveric forearm specimens were compressed transversely while under axial load. The experimental compression data were used in conjunction with an FE-based optimization routine to determine apparent hyperelastic coefficients (μ and α) for a first-order Ogden material property definition. The mean coefficient pairs were μ=35.3 kPa, α=8.5 for the superficial tendons, μ=39.4 kPa, α=9.2 for the deep tendons, μ=24.9 kPa, α=10.9 for the flexor pollicis longus (FPL) tendon, and μ=12.9 kPa, α=6.5 for the median nerve. These mean Ogden coefficients indicate that the FPL tendon was more compliant at low strains than either the deep or superficial flexor tendons, and that there was no significant difference between superficial and deep flexor tendon compressive behavior. The median nerve was significantly more compliant than any of the flexor tendons. The material properties determined in this study can be used to better understand the functional mechanics of the carpal tunnel soft tissues and possible mechanisms of median nerve compressive insult, which may lead to the onset of carpal tunnel syndrome., (Copyright © 2010 Elsevier Ltd. All rights reserved.)

Published

2011

4. Cross-shear implementation in sliding-distance-coupled finite element analysis of wear in metal-on-polyethylene total joint arthroplasty: intervertebral total disc replacement as an illustrative application.

Author

Goreham-Voss CM, Hyde PJ, Hall RM, Fisher J, and Brown TD

Subjects

Elastic Modulus, Equipment Failure Analysis, Finite Element Analysis, Friction, Humans, Materials Testing, Prosthesis Design, Shear Strength, Surface Properties, Computer-Aided Design, Intervertebral Disc Displacement surgery, Joint Prosthesis, Metals chemistry, Polyethylene chemistry

Abstract

Computational simulations of wear of orthopaedic total joint replacement implants have proven to valuably complement laboratory physical simulators, for pre-clinical estimation of abrasive/adhesive wear propensity. This class of numerical formulations has primarily involved implementation of the Archard/Lancaster relationship, with local wear computed as the product of (finite element) contact stress, sliding speed, and a bearing-couple-dependent wear factor. The present study introduces an augmentation, whereby the influence of interface cross-shearing motion transverse to the prevailing molecular orientation of the polyethylene articular surface is taken into account in assigning the instantaneous local wear factor. The formulation augment is implemented within a widely utilized commercial finite element software environment (ABAQUS). Using a contemporary metal-on-polyethylene total disc replacement (ProDisc-L) as an illustrative implant, physically validated computational results are presented to document the role of cross-shearing effects in alternative laboratory consensus testing protocols. Going forward, this formulation permits systematically accounting for cross-shear effects in parametric computational wear studies of metal-on-polyethylene joint replacements, heretofore a substantial limitation of such analyses., (Copyright (c) 2010 Elsevier Ltd. All rights reserved.)

Published

2010

5. Compliance-dependent load allocation between sensing versus non-sensing portions of a sheet-array contact stress sensor.

Author

Hartmann JM, Rudert MJ, Pedersen DR, Baer TE, Goreham-Voss CM, and Brown TD

Subjects

Biomechanical Phenomena, Cartilage, Articular, Humans, Models, Biological, Sensitivity and Specificity, Tensile Strength, Weight-Bearing, Finite Element Analysis, Joint Prosthesis standards, Materials Testing methods

Abstract

Piezoresistive array pressure sensors are widely used in orthopaedic research to determine contact stress distributions across articular joint surfaces. Experience with such sensors has shown there can be inaccuracies in how the sensor perceives applied load, depending on the material stiffnesses between which it is compressed experimentally, versus in calibration. A study was undertaken to quantify the relationship between load perception of one such sensor design (Tekscan) and the stiffness of the materials between which it is compressed. A three-dimensional finite element model of a 3x3 sensel portion of the sensing matrix was formulated, along with a layer of compression test material on each side of the sensor. The elastic modulus of the test material was varied across the range representative of cartilage (12 MPa) to hard plastic (10 GPa). Using the computed contact pressure results between contacting surfaces of the sensor layers, the percentage of load passing through the active conductor intersections was determined. The results revealed that with increase of the elastic modulus of the material between which the sensor was compressed, the percentage of load on the active conductor intersections increased monotonically. The highest sensitivity of perceived loading to test material modulus (0.1%/MPa) was seen at the low end of the modulus range. The more compliant the test material, the more the sensor layers conformed around each other's geometric incongruities, the larger the true contact areas, and the higher the fraction of the total load that passed through the intermediate (non-sensing) regions between the conductors.

Published

2009

6. A finite element exploration of cartilage stress near an articular incongruity during unstable motion.

Author

Goreham-Voss CM, McKinley TO, and Brown TD

Subjects

Finite Element Analysis, Humans, Stress, Mechanical, Weight-Bearing, Cartilage, Articular physiology, Motion

Abstract

Both instability and residual articular incongruity are implicated in the development of post-traumatic osteoarthritis (OA) following intra-articular fracture, but currently no information exists regarding cartilage stresses for unstable residual incongruities. In this study, a transversely isotropic poroelastic cartilage finite element model was implemented and validated within physiologically relevant loading ranges. This material model was then used to simulate the loading of cartilage during stable and unstable motion accompanying a step-off incongruity residual from intra-articular fracture, using load data from previous cadaver tests of ankle instability. Peak solid-phase stresses and fluid pressure were found to increase markedly in the presence of instability. Solid-phase transients of normal stress increased from 2.00 to 13.8 MPa/s for stable compared to unstable motion, and tangential stress transients increased from 17.1 to 118.1 MPa/s. Corresponding fluid pressure transients increased from 15.1 to 117.9 MPa/s for unstable motion. In the most rapidly loaded sections of cartilage, the fluid was found to carry nearly all of the normal load, with the pressurization of the fluid resulting in high solid matrix tangential stresses.

Published

2007