Effect of cementing technique and cement type on thermal necrosis in hip resurfacing arthroplasty—a numerical study

Janssen, Dennis; Scheerlinck, Thierry

doi:10.1002/jor.21512

Cited by 24 publications

(23 citation statements)

References 38 publications

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“…With increased thickness of the cement mantle at the proximal humerus adjacent to the tuberosities, temperatures may reach levels high enough to produce thermal bone necrosis. 17,23 The exothermic effects of polymethyl methacrylate were recently studied in a cadaver model that compared the cortical bone temperatures of a full cementation technique with an impaction grafting technique similar to the black and tan technique used in this study. 31 The temperature observed at the surgical neck adjacent to the location of the tuberosity decreased 23% in the impaction grafting technique, dropping the maximum recorded temperature from 52.4 AE 8.1 C to 40.4 AE 4.8 C, below the 47 C threshold thought to create thermal bone necrosis.…”

Section: Discussionmentioning

confidence: 99%

Tuberosity healing after reverse shoulder arthroplasty for acute proximal humerus fractures: the “black and tan” technique

Formaini

Everding

Levy

et al. 2015

Journal of Shoulder and Elbow Surgery

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Section: Discussionmentioning

confidence: 99%

Tuberosity healing after reverse shoulder arthroplasty for acute proximal humerus fractures: the “black and tan” technique

Formaini

Everding

Levy

et al. 2015

Journal of Shoulder and Elbow Surgery

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“…However, there is a concern that this technique might have long-term detrimental effects related to stress shielding [24,29] or thermal necrosis associated with the increase in overall cement needed for component fixation [15,18,20]. Our study compared survivorship, hip scores, and other radiographic findings between hips resurfaced with a cemented metaphyseal stem and hips resurfaced with a press-fit metaphyseal stem.…”

Section: Discussionmentioning

confidence: 99%

“…All currently available hip resurfacing prostheses feature a metaphyseal stem, typically left uncemented, which helps to facilitate proper alignment for insertion of the femoral component. Cementing this metaphyseal stem increases the area for fixation between the bone and the prosthesis, but this increases the total amount of bone cement needed for fixation, and several studies suggest that the heat generated from the cementing process could lead to thermal necrosis of the surrounding cancellous bone [15,18,20], which could in turn cause femoral neck fracture or femoral loosening. Additionally, cementing the stem may alter the load transfer between the femoral component and the femoral neck, leading to adverse modifications of the proximal femur [24,29].…”

Section: Introductionmentioning

confidence: 99%

Are There Long-term Benefits to Cementing the Metaphyseal Stem in Hip Resurfacing?

Amstutz

Duff

Bhaurla

2015

Clin Orthop Relat Res

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Background Cementing the metaphyseal stem during hip resurfacing surgery improves the initial fixation of the femoral component. However, there may be long-term detrimental effects such as stress shielding or an increased risk of thermal necrosis associated with this technique. Questions/purposes We compared (1) long-term survivorship free from radiographic femoral failure, (2) validated pain scores, and (3) radiographic evidence of component fixation between hips resurfaced with a cemented metaphyseal stem and hips resurfaced with the metaphyseal stem left uncemented. Methods We retrospectively selected all the patients who had undergone bilateral hip resurfacing with an uncemented metaphyseal stem on one side, a cemented metaphyseal stem on the other side, and had both surgeries performed between July 1998 and February 2005. Fortythree patients matched these inclusion criteria. During that period, the indications for cementing the stem evolved in the practice of the senior author (HCA), passing through four phases; initially, only hips with large femoral defects had a cemented stem, then all stems were cemented, then all stems were left uncemented. Finally, stems were cemented for patients receiving small femoral components (\48 mm) or having large femoral defects (or both). Of the 43 cemented stems, two, 13, 0, and 28 came from each of those four periods. All 43 patients had complete followup at a minimum of 9 years (mean, 143 ± 21 months for the uncemented stems; and 135 ± 22 months for the cemented stems; p = 0.088). Survivorship analyses were performed with Kaplan-Meier and Cox proportional hazards ratios using radiographic failure of the femoral component as the endpoint. Pain was assessed with University of California Los Angeles (UCLA) pain scores, and radiographic femoral failure was defined as complete radiolucency around the metaphyseal stem or gross migration of the femoral component. Results There were four failures of the femoral component in the press-fit stem group while the cemented stem group had no femoral failures (p = 0.0471). With the numbers available, we found no differences between the two groups regarding pain relief or radiographic appearance other than in patients whose components developed loosening. Conclusions Cementing the metaphyseal stem improves long-term implant survival and does not alter long-term pain relief or the radiographic appearance of the proximal femur as had been a concern based on the results of finite element studies. We believe that patients with small component sizes and large femoral head defects have more to gain from the use of this technique which adds surface area for fixation, and there is no clinical downside to cementing the stem in patients with large component sizes.

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“…The modeling method of prescribed temperature decrease used in the current study is limited because the actual maximal temperature varies depending on thermal boundary conditions such as cement and stem initial temperature and total volume of cement (Little et al, 2008;Madrala and Nuño, 2010;. Recent experimental studies showed maximal temperatures of 80 1C (Madrala and Nuño, 2010) to 110 1C (Janssen et al, 2012;Race et al, 2007) for bone cement during curing: the current study's hypothesis of a 80 1C maxima is therefore not an extreme value.…”

Section: Discussionmentioning

confidence: 77%

Influence of the stem fixation scenario on load transfer in a hip resurfacing arthroplasty with a biomimetic stem

Caouette

Bureau

Vendittoli

et al. 2015

Journal of the Mechanical Behavior of Biomedical Materials

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Effect of cementing technique and cement type on thermal necrosis in hip resurfacing arthroplasty—a numerical study

Cited by 24 publications

References 38 publications

Tuberosity healing after reverse shoulder arthroplasty for acute proximal humerus fractures: the “black and tan” technique

Tuberosity healing after reverse shoulder arthroplasty for acute proximal humerus fractures: the “black and tan” technique

Are There Long-term Benefits to Cementing the Metaphyseal Stem in Hip Resurfacing?

Influence of the stem fixation scenario on load transfer in a hip resurfacing arthroplasty with a biomimetic stem

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