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Hip resurfacing

From Wikipedia, the free encyclopedia
Hip resurfacing
BHR compared with THR
SpecialtyOrthopedic surgery
ICD-9-CM00.85-00.86

Hip resurfacing has been developed as a surgical alternative to total hip replacement (THR). The procedure consists of placing a cap (usually made of cobalt-chrome metal), which is hollow and shaped like a mushroom, over the head of the femur while a matching metal cup (similar to what is used with a THR) is placed in the acetabulum (pelvis socket), replacing the articulating surfaces of the person's hip joint and removing very little bone compared to a THR. When the person moves the hip, the movement of the joint induces synovial fluid to flow between the hard metal bearing surfaces lubricating them when the components are placed in the correct position. The surgeon's level of experience with hip resurfacing is most important; therefore, the selection of the right surgeon is crucial for a successful outcome. Health-related quality of life measures are markedly improved and the person's satisfaction is favorable after hip resurfacing arthroplasty.[1]

Uses

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A person's suitability for hip resurfacing is decided by the person's anatomy and the surgeon. Hip resurfacing is generally more suitable for younger people who are not morbidly obese, are clinically qualified for a hip replacement (determined by the doctor), have been diagnosed with noninflammatory degenerative joint disease, do not have an infection, and are not allergic to the metals used in the implant.[2]

The potential advantages of hip resurfacing compared to THR include less bone removal (bone preservation), a reduced chance of hip dislocation due to a relatively larger femoral head size (given that the person has an anatomically correct femoral head size), and easier revision surgery for any subsequent revision to a THR device because a surgeon will have more original bone stock available.[3] Hip resurfacing has the potential of being a solution for life, allows a normal ROM (range of movement) and minimizes the amount of "stress shielding", compared with THR. Since the femoral neck is retained and the femoral cavity with its marrow not opened up two other advantages exist, namely no risk of blood clots by fatty marrow that can enter the blood stream with the THR procedure and no risk of introducing bacteria in the opened femoral canal resulting in a deep infection as can happen with the THR procedure. The potential disadvantages of hip resurfacing are femoral neck fractures (rate of 0–4%), aseptic loosening, and metal wear.[3] Due to the retention of the person's complete femoral neck other advantages exist: Surgeon induced discrepancies in leg length (as could happen with THR) are now minimized. Also, the toe-in or toe-out faults that could occur interoperatively with THR are now over because the femoral neck that determines foot direction is left undisturbed with hip resurfacing.

On February 10, 2011, the U.S. FDA issued a patient advisory on metal-metal hip implants, stating it was continuing to gather and review all available information about metal-on-metal hip systems.[4] On June 27–28, 2012, an advisory panel met to decide whether to impose new standards.[5][6][7] No new standards, such as routine checking of blood metal ion levels, were set, but guidance was updated.[8]

According to the Australian Orthopaedic Associate National Joint Replacement Registry (AOANJRR) 2018 Annual Report, hip (total) resurfacing is overwhelmingly used for males (98% of total resurfacing hip replacement were males), and has declined in popularity since the mid-2000s (the number of total resurfacing procedures in 2017 was 78.7% less than 2005). [9]

In 2006, the United States FDA approved hip resurfacing using the Birmingham Hip Resurfacing (BHR) system,[10] designed by British Orthopaedic surgeon Derek McMinn. All other FDA approved devices have been removed from the US Market. The BHR is no longer suggested for use in women. There are several other manufacturers of hip resurfacing systems, mainly in Europe.

Contra-indications

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Hip resurfacing should not be used on people who have severe bone loss in their femoral head, those with large femoral neck cysts present (typically found at surgery) or cysts that are close to the head neck junction, or people who have poor bone stock or osteoporosis.[3] Caution should be used for people who have rheumatoid arthritis, are tall, thin, or small boned,[11] those with osteonecrosis (poor blood supply) to the femoral head, or those with femoral head cysts > 1 cm on an x-ray taken before surgery.[3]

Metal-on-metal resurfacing systems are generally unsuitable for women of child-bearing age due to unknown effects of metal ion release on the fetus.[7] There are hip resurfacing components that have a ceramic coating on metal femoral head component and cross linked polyethylene plastic as a liner for the socket or cup area making it not metal on metal. The plastic sleeve can be replaced if needed without removing the main components.[citation needed]

Technique

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The hip resurfacing devices are metal-on-metal articulating devices which differ from total hip replacement devices because they are more bone conserving and retain the natural geometry (so-called large ball THR devices share this trait). A THR requires that the upper portion of the femur bone be cut off to accept the stem portion of a THR device. The femur cap of the hip resurfacing devices does not require the femur bone be cut off; instead the top of the femoral head is shaped to closely fit the underside of the cap. Both hip resurfacing and hip replacement require that a cup is placed in the acetabulum of the hip socket. The main advantage of the hip resurfacing surgery is that when a revision is required, there is still an intact femur bone left for a THR stem. When a THR stem requires a revision, the metal stem in the femur has to be removed and often more bone is lost in the process of removal and replacement with a larger diameter stem. Having a hip resurfacing at a younger age means that a revision will likely be easier to perform when required.[12]

Recent studies have shown that the outcome of a hip resurfacing is dependent on surgeon experience[13] and that proper positioning of hip resurfacing components is crucial.[14][15] Therefore, in addition to ensuring that a proven device is used, care should be taken in selecting a surgeon with experience and a good track record.[citation needed]

Although formal labeling restrictions exist in some countries, including the United States, hip resurfacing may allow younger, active people to return to many activities they enjoyed prior to their hip problems,[16][17] which is an advantage over a traditional hip arthroplasty.[18] The large size cap and cup of the hip resurfacing devices are the same size as a person's original ball and socket and thus are less prone to dislocation.

An often forgotten but very important advantage of hip resurfacing and thereby the retention of the femoral neck is the fact that hip resurfacing has the least measurable amount of "stress shielding" when compared to any type of THR. This means that with hip resurfacing the femur's upper portion fully retains its natural mechanical characteristics under load, also ensuring less disturbance of the processes that take place inside bone that is alive.[citation needed]

History

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Hip Resurfacing has a long history paralleling the advances of THR. Similar designs appear to have begun in the 1940s, with the first prostheses and procedures (called double-cup arthroplasty) using congruent femoral and acetabular components emerging in the 1970s. These early designs used metal-on-polyethylene bearings, and had poor results compared to THR at the time. It has since been observed that these poor results were strongly tied with polyethylene wear debris associated with the use of air-sterilised ultra high molecular weight polyethylene (UHMWPE) at the time.[19]

A more modern style of Hip Resurfacing emerged in the 1990s, using cobalt-chrome bearings. Clinical results using these material choice were good, prompting the popularity of resurfacing procedures to rise into the early 2000s. [19]

Starting around 2008, a body of research was conducted around metal-on-metal bearings in general and questioning their value, finding (for instance) failures associated with metal ions due to fretting and corrosion. In 2010, the ASR device (produced by DePuy, also a metal-on-metal resurfacing implant) was recalled, and resulted in many cases of litigation. [19]

It has been suggested that research in the area at the time focused on metal-on-metal bearings “as a class” and insufficiently distinguished the role of prosthesis design and surgical technique. Therefore, the current state of hip-resurfacing is an ongoing debate over material choice, implant design and surgical technique.[19]

See also

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References

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  1. ^ Koutras C, Antoniou SA, Talias MA, Heep H (19 May 2015). "Impact of Total Hip Resurfacing Arthroplasty on Health-Related Quality of Life Measures: A Systematic Review and Meta-Analysis". J Arthroplasty. 30 (11): 1938–52. doi:10.1016/j.arth.2015.05.014. PMID 26067708.
  2. ^ Mont MA, Seyler TM, Ulrich SD, et al. (December 2007). "Effect of changing indications and techniques on total hip resurfacing". Clin. Orthop. Relat. Res. 465: 63–70. doi:10.1097/BLO.0b013e318159dd60. PMID 17891034. S2CID 30254202.
  3. ^ a b c d Mont MA, Ragland PS, Etienne G, Seyler TM, Schmalzried TP (August 2006). "Hip resurfacing arthroplasty". J Am Acad Orthop Surg. 14 (8): 454–63. doi:10.5435/00124635-200608000-00003. PMID 16885477. S2CID 12775356.
  4. ^ "Metal-on-Metal Hip Implants". Food and Drug Administration. February 10, 2011. Retrieved January 4, 2012.
  5. ^ "FDA seeks more advice on metal hip implants". Reuters. 29 March 2012. Retrieved 20 May 2012.
  6. ^ "Orthopaedic and Rehabilitation Devices Panel of the Medical Devices Advisory Committee Meeting Announcement". Food and Drug Administration. 27 March 2012. FDA-2012-N-0293. Retrieved 20 May 2012.
  7. ^ a b FDA Executive Summary Memorandum - Metal-on-Metal Hip Implant System (PDF) (Report). Food and Drug Administration. 27 June 2012. Retrieved 15 March 2013.
  8. ^ "Concerns about Metal-on-Metal Hip Implants". Food and Drug Administration. 17 January 2013. Retrieved 15 March 2013.
  9. ^ 2018 Annual Report (Report). Australian Orthopaedic Associate National Joint Replacement Registry. 2018.
  10. ^ Tavares S (November 2005). "Controversial topics in orthopaedics: the best bearing couple for hip arthroplasty". Ann R Coll Surg Engl. 87 (6): 411–418. doi:10.1308/003588405X71090. PMC 1964129. PMID 16263007.
  11. ^ De Haan R, Pattyn C, Gill HS, Murray DW, Campbell PA, De Smet K (October 2008). "Correlation between inclination of the acetabular component and metal ion levels in metal-on-metal hip resurfacing replacement". J Bone Joint Surg Br. 90 (10): 1291–7. doi:10.1302/0301-620X.90B10.20533. PMID 18827237.
  12. ^ Resurfaced hips converted to THA show similar clinical results to primary total hips
  13. ^ Outcome of Hip Resurfacing May be dependent on experience
  14. ^ Metal-on-Metal Hip Resurfacing: The Effect of Component Position Archived 2011-07-07 at the Wayback Machine
  15. ^ De Haan R, Campbell PA, Su EP, De Smet KA (September 2008). "Revision of metal-on-metal resurfacing arthroplasty of the hip: the influence of malpositioning of the components". J Bone Joint Surg Br. 90 (9): 1158–63. doi:10.1302/0301-620X.90B9.19891. PMID 18757954.
  16. ^ "Results of Hip Resurfacing in patients under 55 years with osteoarthritis". Archived from the original on 2011-07-07. Retrieved 2010-09-04.
  17. ^ Naal FD, Maffiuletti NA, Munzinger U, Hersche O (May 2007). "Sports after hip resurfacing arthroplasty". Am J Sports Med. 35 (5): 705–11. doi:10.1177/0363546506296606. PMID 17218652. S2CID 27937148.
  18. ^ Barrack RL (September 2007). "Metal-metal hip resurfacing offers advantages over traditional arthroplasty in selected patients". Orthopedics. 30 (9): 725–6. doi:10.3928/01477447-20070901-16. PMID 17899914.
  19. ^ a b c d Amstutz HC, Le Duff MJ (July 2015). "Hip resurfacing: history, current status, and future". Hip Int. 25 (4): 330–338. doi:10.5301/hipint.5000268. PMID 26109156. S2CID 46689989.