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Proteoglycan loss occurred sooner from implants wrapped with cotton (2 mg), beginning
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The implantation of homologous femoral head cartilage in subcutaneous tissues of random bred Wistar rats results in both subchondral and articular surfaces becoming overlaid by an adherent granulation tissue comprising predominantly fibroblast-like cells. The response of the tissue to cartilage encapsulated with cotton fibres was also similar but e...
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Objective. To investigate the effects of physiologic levels of sex steroids on inflammation and cytokine production and their consequential cartilage degradation.
Methods. We used an in vivo model of inflammation-induced cartilage degradation in female mice to study the effects of ovariectomy and hormone treatment, and in vitro culture systems to examine the influence of sex steroids on cartilage metabolism, interleukin-1 (IL-1) production by granulomatous tissue, and its effects on female mouse articular cartilage.
Results. Ovariectomy resulted in accelerated cartilage breakdown associated with increased production of IL-1 by granulomatous tissue. The effects of ovariectomy on cartilage were reversed by treatment with estradiol and androgen, but not by progesterone treatment. Estradiol and progesterone reduced both spontaneous and IL-1–induced cartilage degradation in vitro. Testosterone antagonized the effects of IL-1 on both proteoglycan loss and proteoglycan synthesis.
Conclusion. These data suggest that sex steroids have an important influence on inflammation-induced cartilage breakdown in female animals, with protective effects of both estradiol and androgens. Multiple mechanisms may be involved, and they are likely to include direct immunomodulatory effects as well as interactions with the effects of cytokine and of the glucocorticoid response to inflammation.
The rat subcutaneous air pouch model was adapted to examine the in vivo degradation of implanted rabbit articular cartilage, both with and without induced air pouch inflammation, over a 7-day period. The effects of 3 drugs, glycosaminoglycan polysulfate (Arteparon), pentosan polysulfate (SP-54), and zinc-chelated pentosan polysulfate (DH-40J), on inflammation-induced cartilage degradation were also examined. Implanted articular cartilage from noninflamed air pouches showed a reduction in total proteoglycan (PG) content (as hexuronic acid), but not in PG extractability or aggregation, compared with cartilage maintained in tissue culture. The injection of peptone into the air pouch as an inflammogen caused an influx of leukocytes and plasma exudate and a reduction in implanted articular cartilage PG content, extractability, and aggregation, which was significantly greater than that which occurred in noninflamed air pouches. In vitro experiments demonstrated that peptone did not have a direct effect on cartilage PG degradation. Daily injection of Arteparon, SP-54, or DH-40J (10 mg/kg) into peptone-inflamed air pouches significantly increased the PG content, extractability, and aggregation in implanted articular cartilage, compared with that in cartilage from non-drug-treated control animals. The infiltration of leukocytes into the peptone-inflamed air pouches was significantly reduced by daily administration of Arteparon, 10 mg/kg. At an equivalent dose, DH-40J increased leukocyte numbers in the pouch fluid, whereas SP-54 had no significant effect on leukocyte accumulation.
Production of a granulomatous tissue adjacent to cartilage implants in subcutaneous tissues of mice by prior wrapping of cartilage with cotton, induces matrix depletion and a rise in serum levels of the acute phase protein haptoglobin. The granulomatous reaction to cotton could be inhibited partially, following treatment of mice with indomethacin, dexamethasone and cyclophosphamide but only the latter two reduced cartilage matrix loss. D-penicillamine was inactive. Regarding the acute phase response, dexamethasone and D-penicillamine appeared to lower and indomethacin and cyclophosphamide to elevate, serum levels of haptoglobin, but these effects were not statistically significant.
The encapsulation of intact rat femoral head cartilage or discs of bovine nasal cartilage with cotton-gauze before implantation in the subcutaneous tissues of mice, results in an accelerated loss of cartilage proteoglycan. Loss of proteoglycan from bovine nasal cartilage occurred later than rat femoral head cartilage, but eventually brought about complete dissolution of the cartilage. Freeze-thaw killing of bovine nasal cartilage did not alter the amount of proteoglycan lost. Destruction of both femoral and nasal cartilage was related to the mass of cotton implanted and to the growth of connective tissue within the implanted cotton. Mice previously implanted with femoral head cartilage were able to show enhanced degradation to new implants; this was even greater if the original implants were encapsulated with cotton. Presoaking of cotton-cartilage implants with the non-specific irritant, carrageenan inhibited the breakdown of cartilage. Autoradiographs of 35sulphate pulsed femoral cartilage following implantation with cotton showed reduced incorporation of radiolabel by chondrocytes.
