Marieke E. Vianen

Iron deposits and catabolic properties of synovial tissue from patients with haemophilia

Haemophilic arthropathy is characterised by iron deposits in synovial tissues. We investigated the suggestion that iron plays an important role in synovial changes. We obtained synovial tissue from six patients with haemophilia during arthroplasty, finding that brown haemosideritic tissue was often adjacent to tissue with a macroscopically normal appearance in the same joint. Samples from both types of synovial tissue were analysed histologically and biochemically to determine catabolic activity. Macroscopically haemosideritic synovium showed a significantly higher inflammatory activity than that with a normal appearance. Cultures of abnormal synovial tissue gave a significantly enhanced production of IL-1, IL-6 and TNF alpha compared with cultures of synovial tissue with a normal appearance. In addition, the supernatant fluids from the cultures showed greater catabolic activity from haemosideritic tissue, as determined by the inhibition of the synthesis of articular cartilage matrix. We conclude that in patients with haemophilic arthropathy, local synovial iron deposits are associated with increased catabolic activity.

Blood-induced joint damage: a human in vitro study

OBJECTIVE To investigate mechanisms underlying cartilage damage caused by brief exposure of cartilage to blood, such as that occurring during intraarticular bleeding. METHODS Human articular cartilage was cultured for 4 days in the presence of blood (components; 7.5-50% volume/volume). The synthesis of cartilage matrix, as determined by proteoglycan synthesis (incorporation of 35SO4(2-)), was measured directly after exposure and after a recovery period of 20 days, during which the cartilage was cultured in the absence of blood or blood components. The production of the cytokines interleukin-1 (IL-1) and tumor necrosis factor a (TNFalpha), which have a destructive effect on cartilage, was determined by enzyme-linked immunosorbent assay, and the viability of chondrocytes was determined by measuring lactate dehydrogenase release and with electron microscopy. The involvement of oxygen metabolites was evaluated by using N-acetylcysteine. RESULTS Brief exposure to blood resulted in dose-dependent inhibition of proteoglycan synthesis. The combination of mononuclear cells and red blood cells was responsible for this effect. The effect was irreversible, independent of IL-1 and TNFalpha production, and was accompanied by chondrocyte death. These effects were partially prevented by N-acetylcysteine. CONCLUSION Brief exposure of cartilage to blood, as occurs after a single episode or a limited number of bleeding episodes, results in lasting cartilage damage in vitro, in which cytotoxic oxygen metabolites play a role.

Articular cartilage is more susceptible to blood induced damage at young than at old age.

OBJECTIVE It has been shown that cartilage is damaged upon intraarticular hemorrhage. We investigated differences in the susceptibility of cartilage from young adult and old animals to blood induced joint damage in a canine in vivo model. METHODS Right knees of 6 young adult beagles (aged 2.2 +/- 0.1 yrs) and 6 old beagles (7.4 +/- 0.3 yrs) were intraarticularly injected twice in 4 days with autologous blood. Dogs were killed 4 or 16 days after the first injection and cartilage matrix proteoglycan content and synthesis and collagen damage were determined. RESULTS Shortly after blood injection (Day 4), proteoglycan synthesis was inhibited and the proteoglycan content of the cartilage was decreased in both groups. However, the degree of the inhibition of proteoglycan synthesis was significantly greater in young adult animals than in old animals. On Day 16 proteoglycan synthesis was increased in both young adult and old cartilage, but more elevated in old cartilage. The proteoglycan content remained decreased in both young adult and old cartilage, but significantly more so in young adult cartilage than in old cartilage. CONCLUSION Results suggest that intraarticular bleeding influences cartilage metabolism and repair, and that the cartilage of young adult animals is more susceptible to these influences than cartilage of old animals. Differences in the aging of chondrocytes and age related changes in matrix integrity may be involved. Prevention and appropriate treatment of joint bleeding is indicated and this is especially relevant for young adult cartilage.

Similarities and discrepancies in subchondral bone structure in two differently induced canine models of osteoarthritis

In osteoarthritis (OA), cartilage degradation is accompanied by subchondral bone changes. The pathogenesis and physiology of bone changes in OA are still unclear. The changes in subchondral bone architecture and cartilage damage were compared in differently induced experimental models of OA. Experimental OA was induced bilaterally by anterior cruciate ligament transection (ACLT) or by cartilage trauma (Groove model); bilateral sham surgery served as control. Lysylpyridinoline (LP, bone resorption) and C‐telopeptide of type II collagen (CTX‐II, cartilage breakdown) were measured over time. At 20 weeks after surgery, the subchondral cortical plate and trabecular bone of the tibia were analyzed by micro–computed tomography (µCT) and cartilage degeneration was analyzed histologically and biochemically. In both models, cartilage degeneration and cortical subchondral plate thinning were present. CTX‐II levels were elevated over time in both models. Subchondral trabecular bone changes were observed only in the ACLT model, not in the Groove model. Correspondingly, LP levels were elevated over time in the ACLT model and not in the Groove model. Interestingly, the trabecular bone changes in the ACLT model were extended to the metaphyseal area. The early decrease in plate thickness, present in both models, as was cartilage damage, suggests that plate thinning is a phenomenon that is intrinsic to the process of OA independent of the cause/induction of OA. On the other hand, trabecular changes in subchondral and metaphyseal bone are not part of a common pathway of OA development and may be induced biomechanically in the destabilized and less loaded ACLT joint.

The canine bilateral groove model of osteoarthritis

In studies aimed at local treatment of experimental osteoarthritis (OA) it is optimal to have an internal (untreated) OA control. Such an approach excludes interanimal variation, and allows paired statistical evaluation of treatment efficacy. For this purpose, we developed and characterized a bilateral version of the canine Groove model. We hypothesized that the bilateral version of the canine Groove model would show consistent and clear development of features of OA similar to those found in the unilateral version. In six Beagle dogs, grooves were surgically made in the articular cartilage of the femoral condyles of both knee joints. Six additional dogs underwent bilateral sham surgery. The degree of OA was quantified 20 weeks after surgery and was compared in retrospect to 23 animals that undergone the same procedure in a single knee joint with the contralateral knee serving as a non‐OA control. Bilateral groove surgery resulted in OA. This was based on the observed ineffective repair response in which an increase in proteoglycan synthesis, a diminished retention of these newly formed proteoglycans, and an enhanced loss of resident proteoglycans resulted in a decreased cartilage proteoglycan content. These biochemical effects were corroborated by clear histological features of OA. All these effects were found in femor as well as in the (surgically untouched) tibia. Interestingly, features of OA were slightly more severe in the bilateral model than in the unilateral variant. The bilateral canine Groove model showed consistent and clear development of features of OA, comparable to the unilateral model.

The groove model of osteoarthritis applied to the ovine fetlock joint

OBJECTIVE Until now there have been no appropriate models for metacarpophalangeal osteoarthritis (OA), even though OA in this joint is a significant medical and economic problem in horses. A good model would be useful to evaluate progression and treatment of OA, particularly in this joint. Therefore, we translated the canine Groove model to the ovine metacarpophalangeal (fetlock) joint. METHOD Cartilage surfaces of the metacarpal side of one fetlock joint were surgically damaged (grooved), followed by intermittent forced loading of the experimental joint. After 15 and 37 weeks, cartilage, synovial tissue and subchondral bone were analyzed by the use of macroscopy, histology, biochemistry and micro-CT. RESULTS Technically, the model was difficult to use because cartilage surfaces were very thin. Nonetheless, all macroscopic, histologic, and biochemical cartilage parameters demonstrated adverse changes in chondrocyte activity and matrix integrity. Decreased proteoglycan content suggested slow progression of cartilage degeneration over time, while synovial inflammation diminished. Impaired subchondral bone quality and osteophyte formation were found. Although osteophyte formation was progressive, subchondral bone changes diminished over time. CONCLUSION The canine Groove model appears to a limited extent transferable to the ovine fetlock joint. However, despite development of adverse changes consistent with early changes of OA, use of the Groove model in the ovine fetlock joint has technical limitations. Using larger animals, such as horses, may significantly improve the technical procedures and with that may provide a more reliable model of metacarpophalangeal OA that is based primarily on intrinsic cartilage damage, appropriate to evaluate the progression and treatment of OA in this particular joint.