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Veterinary surgery : VS2001; 30(3); 228-239; doi: 10.1053/jvet.2001.23348

Arthroscopic mosaic arthroplasty in the equine third carpal bone.

Abstract: To investigate survival and function of autogenous heterotopic osteochondral grafts in a site where injuries are common. Methods: Three osteochondral grafts were harvested arthroscopically from the femoropatellar joint and transplanted to the third carpal bone (C(3)). Nine months later, histologic, histomorphometric, and biochemical comparisons were made between the transplanted grafts in C(3) and tissue adjacent to the recipient site, the opposing radial carpal bone (C(r)), the donor site in the femoropatellar joint, and the sham-operated contralateral C(3). Methods: One mixed-breed pony and 5 Standardbred horses aged 3 to 8 years old. Methods: Using instruments modified for equine use, four 4.5-mm-diameter osteochondral grafts were harvested arthroscopically from the distal aspect of the lateral trochlea of the right femur and inserted into the radial facet of the right third carpal bone. The fourth graft was kept as a donor-site control sample. Three months later, regular exercise was started and at 6 months, repeat arthroscopy was conducted to evaluate healing. The horses were euthanatized 9 months after transplantation, and comparisons were made between the grafts, opposing radial carpal bone, and contralateral third carpal bone. The assessment criteria included paravital staining, a modified Mankin scoring system, and biochemical analyses for collagen type, total collagen content, and sulfated glycosaminoglycan concentration. Results: All horses were sound 21 days' postoperatively. At 6 months, all 18 grafts were intact but somewhat soft and opaque compared with surrounding carpal cartilage. Nine months' postoperatively, the bony portions of the grafts were well integrated with the recipient sites, but 6 grafts had histologic evidence of cartilage degeneration. From biochemical analysis of grafts, there was little or no new repair tissue invading the experimental sites, but sulfated glycosaminoglycan (proteoglycan) loss from the transplanted cartilage was marked. Conclusions: Heterotopic transfer of osteochondral grafts from the distal aspect of the lateral femoral trochlea to the third carpal bone is feasible with minor modifications of human mosaic arthroplasty instruments. The bony portion of the osteochondral grafts was quickly remodeled to provide subchondral support to the transplanted articular cartilage. The loss of proteoglycan from the transplanted cartilage indicates that the grafts might have been injured during harvesting or insertion, or, more likely, did not remodel to meet the demands of a new biomechanical environment. Conclusions: These findings suggest that arthroscopic resurfacing of focal osteoarticular defects will not be successful in the long term unless donor and recipient sites can be matched with respect to cartilage thickness, biochemical constituents, and physical properties. Mosaic arthroplasty may be indicated in selected cases in which no other options exist to create a confluent cartilage-covered surface.
Copyright 2001 by The American College of Veterinary Surgeons
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Publication Date: 2001-05-08 PubMed ID: 11340554DOI: 10.1053/jvet.2001.23348Google Scholar: Lookup
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  • Journal Article
  • Research Support
  • Non-U.S. Gov't

Summary

This research summary has been generated with artificial intelligence and may contain errors and omissions. Refer to the original study to confirm details provided. Submit correction.

This research investigates the survival and functionality of autogenous heterotopic osteochondral grafts (transplanted bone and cartilage) in horses’ carpal bones, a common site of injury. It finds that while the bony part of the transplants integrated well, there was significant loss of proteoglycan (a component of the cartilage), suggesting challenges with the adaptation to a new biomechanical environment.

Methods

  • The study involved one mixed-breed pony and five Standardbred horses aged between 3 and 8 years. Modified instruments for equine use were utilized to harvest three osteochondral grafts from the femoropatellar joint of each horse, which were then transplanted to the third carpal bone (C(3)).
  • The fourth graft was kept as a control sample. After three months, regular exercise was initiated, and repeat arthroscopy was conducted at six months to evaluate the healing.
  • The horses were euthanized nine months after transplantation. Histologic, histomorphometric, and biochemical comparisons were made between the transplanted grafts in C(3) and tissue from the opposing radial carpal bone (C(r)), the donor site in the femoropatellar joint, and the contralateral C(3) that had undergone a sham operation.
  • In assessments, the researchers used paravital staining, a modified Mankin scoring system, and biochemical analyses to measure collagen type, overall collagen content, and the concentration of sulfated glycosaminoglycans (proteoglycans).

Results

  • All the horses were sound 21 days post-operatively. At six months, all 18 grafts were intact but appeared somewhat soft and opaque compared to the surrounding carpal cartilage.
  • After nine months, the bony parts of the grafts were well integrated at the recipient sites. However, six of the grafts showed histologic evidence of cartilage degeneration, indicating that the cartilaginous component of the grafts did not adapt as well.
  • The biochemical analysis revealed little or no new repair tissue invading the experimental sites and marked loss of proteoglycan from the transplanted cartilage. This loss could indicate injury during harvesting or insertion or difficulty adapting to a new biomechanical environment.

Conclusions

  • The research concluded that heterotopic transfer of osteochondral grafts from the femoral trochlea to the third carpal bone is feasible with minor modifications to human mosaic arthroplasty instruments.
  • Despite the successful integration of the bony parts of the grafts, the loss of proteoglycan (a vital component of the cartilage) suggests that the procedure is not successful in the long term unless the donor and recipient sites can be perfectly matched in terms of cartilage thickness, biochemical constituents, and physical properties.
  • Mosaic arthroplasty may be considered suitable only in peculiar cases where no other options exist to create a confluent cartilage-covered surface.

Cite This Article

APA
Hurtig M, Pearce S, Warren S, Kalra M, Miniaci A. (2001). Arthroscopic mosaic arthroplasty in the equine third carpal bone. Vet Surg, 30(3), 228-239. https://doi.org/10.1053/jvet.2001.23348

Publication

Veterinary surgery : VS
ISSN: 0161-3499
NlmUniqueID: 8113214
Country: United States
Language: English
Volume: 30
Issue: 3
Pages: 228-239

Researcher Affiliations

Hurtig, M
  • Department of Clinical Studies, Ontario Veterinary College, University of Guelph, Ontario, Canada N1G 2W1.
Pearce, S
    Warren, S
      Kalra, M
        Miniaci, A

          MeSH Terms

          • Animals
          • Arthroplasty / methods
          • Arthroplasty / veterinary
          • Arthroscopy / veterinary
          • Bone Transplantation / veterinary
          • Carpus, Animal / surgery
          • Cartilage, Articular / pathology
          • Femur / transplantation
          • Graft Survival
          • Horses / surgery
          • Lameness, Animal / diagnostic imaging
          • Radiography

          Citations

          This article has been cited 11 times.
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