Morphologic study of repair of induced osteochondral defects of the distal portion of the radial carpal bone in horses by use of glued periosteal autografts [corrected].
Abstract: The use of periosteal autografts to resurface osteochondral defects was investigated in 10 horses (2 to 3 years old), and the repair tissue was characterized morphologically. Middle carpal joint arthrotomies were made, and osteochondral defects were induced bilaterally on the distal articular surface of each radial carpal bone. Each defect measured approximately 1 cm2 and extended 3 mm into the subchondral bone plate. Residual subchondral bone plate of control and principal defects was perforated by drilling. A sterile fibrin adhesive was made by mixing a fibrinogen component and a thrombin component. A periosteal autograft was harvested from the proximal portion of the tibia and was glued onto the recipient osseous surface, with its cambium facing the joint cavity. Control defects were glued, but not grafted. Horses were walked 1 hour daily on a walker, starting at postoperative week 7 and continuing for 9 weeks. Sixteen weeks after the grafting procedure was done, carpal radiography was performed, after which horses were euthanatized. Quality of repair tissue of control and grafted defects was evaluated and compared grossly, histologically, and histochemically. Using a reticule, the proportions of various repair tissue types filling each defect were quantitated. Seven weeks after the grafting procedure was done, bilateral arthroscopy revealed synovial adhesions and marginal pannus formation in control and grafted defects. None of the autografts was found floating unattached within the respective middle carpal joints. At 16 weeks, the gross appearance of most grafted and nongrafted defects was similar, and repair was dominated by a fibrous pannus. In 4 grafted defects, bone had formed either concentrically within the defect or eccentrically in the fibrous adhesions between the defect and the joint margin. Histologically, all grafted and nongrafted defects were repaired similarly by infiltration of a mixture of fibrous tissue, fibrocartilage, and bone. Fibrous tissue was the predominant tissue in most defects and its mean proportion was 56 and 59% in the grafted and nongrafted defects, respectively. Fibrocartilaginous tissue in the deeper layers approximated 20%, and woven bone at the base of the defect was 20% in all defects. Histochemically, difference in staining for proteoglycans was not observed between grafted and nongrafted defects. Little remaining original periosteal graft tissue was evident at the defect sites. The only distinguishing feature of grafted defects was the presence of islands of bone formation either at the defect site (n = 2 horses), or in somewhat dorsally displaced tissue that was incorporated in fibrous adhesions (n = 2 horses).(ABSTRACT TRUNCATED AT 400 WORDS)
Publication Date: 1991-02-01 PubMed ID: 2012344
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- Journal Article
- Research Support
- Non-U.S. Gov't
- Research Support
- U.S. Gov't
- Non-P.H.S.
Summary
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This research paper investigates the effectiveness of using periosteal autografts, harvested from the proximal portion of the tibia, to repair osteochondral defects in a sample group of 10 horses. The outcome of the procedure was assessed both qualitatively and quantitatively.
Methodology
- An osteochondral study was conducted on 10 horses with induced osteochondral defects on both sides of the distal part of each radial carpal bone. This invloved creating a damage of approximately 1 cm2 on the surface and extending it 3mm into the subchondral bone layer.
- These defects were then drilled into for perforation. A periosteal autograft, harvested from each horse’s proximal portion of the tibia, was attached to the osseous surface using sterile fibrin glue, ensuring that the cambium faced the joint cavity. For control, some defects were glued but not grafted.
- After grafting, daily walks on a walker were initiated from the 7th week post-surgery and maintained for 9 weeks. This was followed by carpal radiography examination at the 16th week, after which the horses were put to rest.
- Quality of the repair tissue in both control and grafted defects was evaluated and compared via gross, histological, and histochemical observation.
Results
- Observation at the seventh week revealed synovial adhesions and marginal pannus formation in both the control and grafted defects.
- By the 16th week, it was noticed that most grafted and non-grafted defects appeared similar, with repair dominated by fibrous pannus. Concentric bone formation within the defect or eccentrically in the fibrous adhesions between the defect and the joint margin was observed in 4 grafted defects.
- Both grafted and non-grafted defects showed similar repairs through the infiltration of a mixture of fibrous tissue, fibrocartilage, and bone. Fibrous tissue was the dominant repair tissue in most defects, constituting 56% in grafted and 59% in non-grafted defects. Fibrocartilaginous tissue in the deeper layers and woven bone at the base of the defect contributed around 20% in all defects.
- Histochemical analysis did not reveal any significant differences in proteoglycan staining between grafted and non-grafted defects, and little original periosteal graft tissue remained at the defect sites.
- The only distinguishing feature in grafted defects was the presence of islands of bone formation either at the defect site or in somewhat dorsally displaced tissue incorporated in fibrous adhesions.
Cite This Article
APA
Vachon AM, McIlwraith CW, Trotter GW, Norrdin RW, Powers BE.
(1991).
Morphologic study of repair of induced osteochondral defects of the distal portion of the radial carpal bone in horses by use of glued periosteal autografts [corrected].
Am J Vet Res, 52(2), 317-327.
Publication
Researcher Affiliations
- Department of Clinical Sciences, College of Veterinary Medicine, Colorado State University, Fort Collins 80523.
MeSH Terms
- Animals
- Carpal Bones / surgery
- Cartilage / injuries
- Horses / surgery
- Periosteum / transplantation
- Transplantation, Autologous / veterinary
- Wound Healing
Citations
This article has been cited 4 times.- McIlwraith CW, Fortier LA, Frisbie DD, Nixon AJ. Equine Models of Articular Cartilage Repair. Cartilage 2011 Oct;2(4):317-26.
- Mienaltowski MJ, Huang L, Frisbie DD, McIlwraith CW, Stromberg AJ, Bathke AC, Macleod JN. Transcriptional profiling differences for articular cartilage and repair tissue in equine joint surface lesions. BMC Med Genomics 2009 Sep 14;2:60.
- Waselau AC, Nadler D, Müller JM, Zlinszky K, Hilbe M, Auer JA, von Rechenberg B. The effect of cartilage and bone density of mushroom-shaped, photooxidized, osteochondral transplants: an experimental study on graft performance in sheep using transplants originating from different species. BMC Musculoskelet Disord 2005 Dec 15;6:60.
- Nakano T, Aherne FX. A study of repair cartilage from osteochondrotic humeral condyles of swine: preliminary report. Can J Vet Res 1992 Oct;56(4):376-8.
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