Does Increased Topside Conformity in Modular Total Knee Arthroplasty Lead to Increased Backside Wear?

Schwarzkopf, Ran; Scott, Richard D.; Carlson, Evan M.; Currier, John H.

doi:10.1007/s11999-014-3648-0

Cited by 20 publications

(9 citation statements)

References 13 publications

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“…This correlation is corroborated in multiple other retrieval studies [1,3,4,18]. There also are varying degrees of evidence that backside wear is increased by other implant factors such as polyethylene sterilization in noninert gas [2,5,6,9,25,40], polyethylene manufacturing [16,27], tibial baseplate composition [3,4,7], conformity of the polyethylene articular surface [36], and polyethylene thickness [13,44]. In some studies, patient factors such as longer time in vivo of the polyethylene [17,21,31], increased patient weight [8], male sex, and younger patient age [16] have been shown to increase backside wear.…”

Section: Introductionsupporting

confidence: 54%

Current Total Knee Designs: Does Baseplate Roughness or Locking Mechanism Design Affect Polyethylene Backside Wear?

Sisko

Teeter

Lanting

et al. 2017

Clinical Orthopaedics &Amp; Related Research

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Our study showed that in the complex interplay between baseplate surface finish and locking mechanism design, a polished baseplate with a robust locking mechanism had the lowest backside damage and linear wear. However, improvements in locking mechanism design in nonpolished baseplates potentially may offset some advantages of a polished baseplate. Further retrieval analyses need to be done to confirm such findings, especially analyzing current crosslinked polyethylene. Additionally, we need mid- and long-term studies comparing TKA revisions attributable to wear and osteolysis among implants before understanding if such design differences are clinically relevant.

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Section: Introductionsupporting

confidence: 54%

Current Total Knee Designs: Does Baseplate Roughness or Locking Mechanism Design Affect Polyethylene Backside Wear?

Sisko

Teeter

Lanting

et al. 2017

Clinical Orthopaedics &Amp; Related Research

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“…This study was subject to several limitations. First, we used a pin‐on‐disk test method, so the shapes of the pin‐and‐disk specimens were different from those of the joint replacements, whereas Schwarzkopf et al reported that the conformity of the bearing surface affected the backside damage of PE . However, the roughness of the bearing surface of the pin‐and‐disk specimens was similar to that of the artificial joint products.…”

Section: Discussionmentioning

confidence: 86%

The effects of presence of a backside screw hole on biotribological behavior of phospholipid polymer‐grafted crosslinked polyethylene

et al. 2017

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One of the important factors in determining the success of joint replacement is the wear performance of polyethylene. Although highly crosslinked polyethylene (CLPE) is presently used, it is still not adequate. We have developed a surface modification technology using poly(2-methacryloyloxyethyl phosphorylcholine) (PMPC) in an attempt to improve wear performance. In this study, we evaluated the wear and creep deformation resistances of 3-mm and 6-mm thick PMPC-grafted CLPE disks, set on a metal back-plate, with and without a sham screw hole. The gravimetric wear and volumetric change of the disks were examined using a multidirectional pin-on-disk tester. PMPC grafting decreased the gravimetric wear of CLPE regardless of the presence of a screw hole, and did not affect the volumetric change. The volumetric change in the bearing and backside surfaces of the 3-mm thick disk with a screw hole was much larger than that of those without a screw hole or those of the 6-mm thick disk, which was caused by creep deformation. PMPC grafting on the bearing surface can be a material engineering approach to reduce the wear without changing the creep deformation resistance, and is a promising surface modification technology that can be used to increase the longevity of various artificial joints. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 106B: 610-618, 2018.

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“…The polyethylene is often secured to the tray by one of a variety of proprietary locking mechanisms, comprising a fixed‐bearing device. A frequently cited reason for failure of these knee replacements is wear of articular and/or backside (non‐articular) surface of this polyethylene tibial insert …”

mentioning

confidence: 99%

“…For knee replacement patients, the sub‐micron polyethylene debris produced by wear of the tibial insert can cause a number of negative outcomes including synovitis, aseptic loosening, and osteolysis . Although in fixed‐bearing tibial constructs the polyethylene is captured by the metal tray, previous studies have indicated that the backside surface of the tibial insert can move relative to the tray, and this micro‐motion is a potential source of significant debris .…”

mentioning

confidence: 99%

Contribution of micro‐motion to backside wear in a fixed bearing total knee arthroplasty

Levine

Lewicki

Currier

et al. 2016

Journal Orthopaedic Research

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This study seeks to identify important factors related to backside wear of tibial inserts in vivo and determine an appropriate wear model for backside wear. An IRB approved database was queried for tibial inserts of a single design from one manufacturer that exhibited evidence of rotatory motion on the backside of the polyethylene. These devices were measured for volumetric wear using a previously established protocol. Features including the change in locking lip width and measurement of micro-motion marks were used to describe the motion pattern. Volumetric wear and implant characteristics were compared using linear regressions by modeling wear theories suggested by Archard and Wang to determine the most appropriate model for backside wear. The Wang model showed that duration, adjusted sliding distance, and cross-shear index accounted for approximately 58% of the volumetric wear variation while adjusted sliding distance and duration in vivo accounted for approximately 35% of the volumetric wear variation in the Archard model. Patient weight (p = 0.750), patient BMI (p = 0.680), and backside area (p = 0.784) of the tibial insert were all found to be non-significant in the Wang model. Similarly, patient weight (p = 0.233), patient BMI (p = 0.162), and backside area (p = 0.796) were found to be non-significant in the Archard model. Multidirectional micro-motion appears to contribute significantly to the wear of these components, supporting the Wang theory of cross-shear for polyethylene wear. Cross-shear of polymers on an unpolished titanium tray can lead to an increase in wear debris in the body. Care should be taken when designing locking mechanisms and tray designs. © 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 34:1933-1940, 2016.

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Does Increased Topside Conformity in Modular Total Knee Arthroplasty Lead to Increased Backside Wear?

Cited by 20 publications

References 13 publications

Current Total Knee Designs: Does Baseplate Roughness or Locking Mechanism Design Affect Polyethylene Backside Wear?

Current Total Knee Designs: Does Baseplate Roughness or Locking Mechanism Design Affect Polyethylene Backside Wear?

The effects of presence of a backside screw hole on biotribological behavior of phospholipid polymer‐grafted crosslinked polyethylene

Contribution of micro‐motion to backside wear in a fixed bearing total knee arthroplasty

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