Journal ArticleDOI
Migration of corrosion products from modular hip prostheses. Particle microanalysis and histopathological findings.
TLDR
Solid corrosion product was present at the junction of the modular head and neck and as particles within the periprosthetic tissues as early as eight months postoperatively and in several hips, it was also present on the polyethylene bearing surface.Abstract:
Migration of solid corrosion products from the modular head-neck junction of fifteen total hip replacements to the periprosthetic tissues was studied. The devices and tissues were recovered at the time of a revision procedure or at autopsy after a mean of sixty-four months (range, eight to ninety-seven months). The prostheses had a cobalt-chromium-alloy head coupled with a cobalt-chromium-alloy or a titanium-alloy stem. The solid corrosion product was identified by electron microprobe analysis and Fourier transform infrared microprobe spectroscopy as a chromium orthophosphate hydrate-rich material. The product was present at the junction of the modular head and neck and as particles within the periprosthetic tissues as early as eight months postoperatively. In several hips, it was also present on the polyethylene bearing surface. The particles in the tissues ranged in size from less than one to 500 micrometers. They were present within histiocytes or were surrounded by foreign-body giant cells in the pseudocapsule of the hip joint; in the membranes of the femoral bone-implant interface; and at sites of femoral endosteal erosions, with and without loosening of the femoral component.read more
Citations
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Journal ArticleDOI
Corrosion of metal orthopaedic implants.
TL;DR: This review focuses on electrochemical corrosion phenomena in alloys used for orthopaedic implants, evidenced by particulate corrosion and wear products in tissue surrounding the implant, which may ultimately result in a cascade of events leading to periprosthetic bone loss.
Journal ArticleDOI
Dissemination of wear particles to the liver, spleen, and abdominal lymph nodes of patients with hip or knee replacement.
Robert M. Urban,Joshua J. Jacobs,Michael J. Tomlinson,John Gavrilovic,Jonathan Black,Michel Peoc'h +5 more
TL;DR: Systemic distribution of metallic and polyethylene wear particles was a common finding, both in patients with a previously failed implant and in those with a primary total joint prosthesis.
Journal ArticleDOI
Biomedical Implants: Corrosion and its Prevention - A Review~!2009-12-22~!2010-01-20~!2010-05-25~!
TL;DR: In this article, the authors discuss various issues associated with biological corrosion of different kinds of implants used as cardio stents, orthopedic and dental implants, which is considered to be the best solution to combat corrosion and to enhance the life span of the implants and longevity of the human beings.
Journal ArticleDOI
Metal release in patients who have had a primary total hip arthroplasty. A prospective, controlled, longitudinal study.
Joshua J. Jacobs,Anastasia K. Skipor,Leslie M. Patterson,Nadim J. Hallab,Wayne G. Paprosky,Jonathan Black,Jorge O. Galante +6 more
TL;DR: It is suggested that fretting corrosion at the head-neck coupling is an important source of metal release that can lead to increased concentrations of chromium in the serum and urine after total hip replacement.
Journal ArticleDOI
Corrosion at the Head-Neck Taper as a Cause for Adverse Local Tissue Reactions After Total Hip Arthroplasty
H. John Cooper,Craig J. Della Valle,Richard A. Berger,Matthew W. Tetreault,Wayne G. Paprosky,Scott M. Sporer,Joshua J. Jacobs +6 more
TL;DR: Adverse local tissue reactions can occur in patients with a metal-on-polyethylene bearing secondary to corrosion at the modular femoral head-neck taper, and their presentation is similar to the adverseLocal tissue reactions seen in Patients with aMetal- on-metal bearing.
References
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Journal ArticleDOI
In vivo corrosion of modular hip prosthesis components in mixed and similar metal combinations. The effect of crevice, stress, motion, and alloy coupling
TL;DR: It is hypothesized that the restricted crevice environment, coupled with high cyclic stresses which cause repeated fracture of the passive oxide films in the taper, result in an unstable electrochemical environment within the crevice for both the cobalt alloy and Ti-alloy passive films.
Journal ArticleDOI
Macrophage/particle interactions: Effect of size, composition and surface area
Arun S. Shanbhag,Joshua J. Jacobs,Jonathan Black,Jonathan Black,Jorge O. Galante,Tibor T. Glant,Tibor T. Glant +6 more
TL;DR: Macrophage response to particulate debris appears to be dependent on particle size, composition, and dose as given by surface area ratio, and inhibition of macrophage DNA synthesis at higher surface area ratios suggests cell damage or death.
Journal ArticleDOI
Composition and morphology of wear debris in failed uncemented total hip replacement
TL;DR: Interfacial membranes collected at revision from 11 failed uncemented Ti-alloy total hip replacements were examined and polyethylene particles were found, similar to the particles seen in the base resin used in the manufacture of the acetabular implants.
Journal ArticleDOI
The pathology of the joint tissues and its clinical relevance in prosthesis failure.
TL;DR: It was found that in the amounts normally shed into joints, debris particles do not appear to stimulate a polymorphonuclear response, and frozen section may aid the surgeon in determining the methods and timing of revision operations.
Journal ArticleDOI
Bone resorption activity of particulate-stimulated macrophages.
Tibor T. Glant,Tibor T. Glant,Joshua J. Jacobs,Gyöngyi Molnár,Arun S. Shanbhag,Arun S. Shanbhag,Márta Valyon,Jorge O. Galante +7 more
TL;DR: Comparison of the effect of particulate size, concentration, and composition on the secretion of IL‐1 and PGE2 by peritoneal macrophages and on the bone‐resorbing activity of conditioned medium harvested from particulate‐challenged Macrophages indicates that, in a macrophage‐bone coculture system, factors other than P GE2 and IL-1 also may regulate particulates‐induced bone resorption.