Corrosion of Modular Titanium Alloy Stems in Cementless Hip Replacement

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Volume 2, Issue 10 (November 2005)

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ISSN: 1546-962X
Page Count: 10

Corrosion of Modular Titanium Alloy Stems in Cementless Hip Replacement
Urban, RM
Assistant Professor and Director, Implant Pathology Laboratory, Professor and Director Section of Biomaterials Research, and Director, Metal Ion Laboratory, Rush University Medical Center, IL

Gilbert, JL
Professor and Associate Dean, Syracuse University, NY

Jacobs, JJ

Abstract

Severe, localized corrosion of titanium-alloy femoral stems has been reported for specific designs of hip prostheses intended for fixation using acrylic cement. The purpose of the present study was to examine the possibility that corrosion might also occur when titanium-alloy stems are inserted without cement, but the body of the stem is modular in design. Fourteen (7 primary and 7 revision) cementless, modular-body, titanium-6% aluminum-4% vanadium alloy femoral stems of similar design were removed at revision surgery after 2 to 108 months in situ. The reason for removal was unexplained pain (4), femoral or acetabular loosening (4), infection (3), recurrent dislocation (2), or component malposition (1). The devices and, in selected cases, tissue from the joint psuedocapsule were studied with the use of light and scanning electron microscopy. Fretting corrosion products were characterized using energy dispersive x-ray analysis, selected area diffraction, and micro-Raman spectroscopy. Damage at the modular body connections was absent in 3 stems, mild in 6, moderate in 4, and severe in 1. The surface damage was characterized predominately by fretting scars and by pitting and etching. Thick deposits of mixed titanium oxides were found adherent to the stem at the sites of corrosion and as 0.01 to 200 micrometer particles within histiocytes and multinucleated giant cells in the joint pseudocapsule. Fretting corrosion at the modular-body junctions of titanium-alloy femoral stems can generate solid degradation products, adding to the particulate burden of the periprosthetic tissues and potentially accelerating bearing-surface wear by a third-body mechanism. Both of these features can potentiate the development and progression of osteolysis. In addition, fretting corrosion can increase the potential for structural failure of the device. These findings stress the importance of the design of modular junctions to minimize corrosion and the generation of corrosion products.

Keywords:
titanium, corrosion, fretting, modularity, particulate debris, metal ions

Paper ID: JAI12810
DOI: 10.1520/JAI12810
ASTM International is a member of CrossRef.

Author Title Corrosion of Modular Titanium Alloy Stems in Cementless Hip Replacement Symposium Titanium, Niobium, Zirconium, and Tantalum for Medical and Surgical Applications, 2004-11-10 Committee F04

		Home Journals STPs Manuals Topics Subscriptions/Pricing Digital Library / Journals / Journal of ASTM International (JAI) / Citation Page Volume 2, Issue 10 (November 2005) Click here to download this paper now for $25 PDF (2.5M) View License Agreement ISSN: 1546-962X Page Count: 10 Corrosion of Modular Titanium Alloy Stems in Cementless Hip Replacement Urban, RM Assistant Professor and Director, Implant Pathology Laboratory, Professor and Director Section of Biomaterials Research, and Director, Metal Ion Laboratory, Rush University Medical Center, IL Gilbert, JL Professor and Associate Dean, Syracuse University, NY Jacobs, JJ Abstract Severe, localized corrosion of titanium-alloy femoral stems has been reported for specific designs of hip prostheses intended for fixation using acrylic cement. The purpose of the present study was to examine the possibility that corrosion might also occur when titanium-alloy stems are inserted without cement, but the body of the stem is modular in design. Fourteen (7 primary and 7 revision) cementless, modular-body, titanium-6% aluminum-4% vanadium alloy femoral stems of similar design were removed at revision surgery after 2 to 108 months in situ. The reason for removal was unexplained pain (4), femoral or acetabular loosening (4), infection (3), recurrent dislocation (2), or component malposition (1). The devices and, in selected cases, tissue from the joint psuedocapsule were studied with the use of light and scanning electron microscopy. Fretting corrosion products were characterized using energy dispersive x-ray analysis, selected area diffraction, and micro-Raman spectroscopy. Damage at the modular body connections was absent in 3 stems, mild in 6, moderate in 4, and severe in 1. The surface damage was characterized predominately by fretting scars and by pitting and etching. Thick deposits of mixed titanium oxides were found adherent to the stem at the sites of corrosion and as 0.01 to 200 micrometer particles within histiocytes and multinucleated giant cells in the joint pseudocapsule. Fretting corrosion at the modular-body junctions of titanium-alloy femoral stems can generate solid degradation products, adding to the particulate burden of the periprosthetic tissues and potentially accelerating bearing-surface wear by a third-body mechanism. Both of these features can potentiate the development and progression of osteolysis. In addition, fretting corrosion can increase the potential for structural failure of the device. These findings stress the importance of the design of modular junctions to minimize corrosion and the generation of corrosion products. Keywords: titanium, corrosion, fretting, modularity, particulate debris, metal ions Paper ID: JAI12810 DOI: 10.1520/JAI12810 ASTM International is a member of CrossRef. Author Title Corrosion of Modular Titanium Alloy Stems in Cementless Hip Replacement Symposium Titanium, Niobium, Zirconium, and Tantalum for Medical and Surgical Applications, 2004-11-10 Committee F04