DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT.

J Daniel; C Pradhan; H Ziaee; DJW McMinn

doi:10.1302/0301-620X.90BSUPP_II.0900305c

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DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT.

J Daniel
C Pradhan
H Ziaee
DJW McMinn

DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT.

Daniel J, Pradhan C, Ziaee H, McMinn D. DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT.. Orthop Procs. 2008;90-B(SUPP_II):305-305. doi:10.1302/0301-620X.90BSUPP_II.0900305c

Daniel, J, et al. “DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT..” Orthopaedic Proceedings, vol. 90-B, no. SUPP_II, 2008, pp. 305-305., https://doi.org/10.1302/0301-620X.90BSUPP_II.0900305c

Daniel, J., Pradhan, C., Ziaee, H., & McMinn, D. (2008). DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT.. Orthopaedic Proceedings, 90-B(SUPP_II), 305-305. https://doi.org/10.1302/0301-620X.90BSUPP_II.0900305c

Daniel, J., Pradhan, C., Ziaee, H. and McMinn, D. (2008) “DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT..” Orthopaedic Proceedings, 90-B(SUPP_II), pp. 305-305. Available at: https://doi.org/10.1302/0301-620X.90BSUPP_II.0900305c

Daniel, J, C Pradhan, H Ziaee, and DJW McMinn. “DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT..” Orthopaedic Proceedings 90-B, no. SUPP_II (2008): 305-305. https://doi.org/10.1302/0301-620X.90BSUPP_II.0900305c

Daniel J, Pradhan C, Ziaee H, McMinn D. DISLOCATION RATE IN PRIMARY LARGE DIAMETER METAL-ON-METAL TOTAL HIP REPLACEMENT.. Orthop Procs. 2008 Jul 1;90-B(SUPP_II):305-305. https://doi.org/10.1302/0301-620X.90BSUPP_II.0900305c

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Abstract

Introduction: Dislocation rates with THA vary from 3% to 15%. One specialist centre reported a 6.4% early dislocation rate with a 28mm ceramic on polyethylene THA in young patients (mean age 56 years) in a single surgeon series. Although young patients have the advantage of better soft tissues, their greater mobility demands increase dislocation risk.

Dislocation rates in large headed metal-on-metal resurfacings are extremely low. However, many patients are unsuitable for resurfacing and need a replacement. In such cases, it is attractive to transfer the large-headed metal-metal bearing advantage to replacement arthroplasty in order to reduce wear and dislocation rates. Does large diameter metal-metal total hip replacement really reduce the early dislocation rate?

Methods: 206 consecutive primary metal-metal THRs (189 patients) were included. The device consists of an uncemented cup, a matching modular cobalt chrome head (head diameter ranged 38 – 58mm) fixed on a stem through a 12/14 cone. Cemented stems were used in 107 procedures and 99 were proximal-porous uncemented stems.

Age at operation ranged from 37 to 83 years. Thirty patients were 55 years or under, eighty one were 56 – 65 years and ninety five were over 65 years. There were 122 females and 67 males. Posterior approach was used in all.

Results: There were no dislocations in these 206 consecutive procedures.

Discussion: Metal-metal hips have lower dislocation rates than hips containing polyethylene (0.9% against 6.4% in a matched series). This is attributed to the suction-fit effect of metal-metal bearings. Large diameter bearings have the additional benefit of having to translate a greater jump distance before a dislocation. This dual advantage leading to extremely low dislocation rates was first noted in metal-metal resurfacings. In large headed metal-metal THRs, the head-neck ratio is even more favourable and these devices appear to eliminate early dislocation as a major complication.

Correspondence should be addressed to The Secretary, BHS, c/o BOA, The Royal College of Surgeons, 35–43 Lincoln’s Inn Fields, London WC2A 3PE.