The Journal of Bone & Joint Surgery

The Journal of Bone & Joint Surgery, Volume 88, Issue 10

Scientific Articles | October 01, 2006

Effect of Early Full Weight-Bearing After Joint Injury on Inflammation and Cartilage Degradation

D.M. Green, MD¹; P.C. Noble, PhD²; J.R. BocellJr., MD²; J.S. Ahuero, MD²; B.A. Poteet, DVM³; H.H. Birdsall, MD, PhD¹

¹ Research Office, MS 151, Michael E. DeBakey Veterans Affairs Medical Center, 2002 Holcombe Boulevard, Houston, TX 77030. E-mail address for D.M. Green: dgreen@bcm.tmc.edu
² Department of Orthopedic Surgery, Baylor College of Medicine, Houston, TX 77030
³ Gulf Coast Veterinary Specialists, 1111 West Loop South, Houston, TX 77027

View Disclosures and Other Information

In support of their research for or preparation of this manuscript, one or more of the authors received grants or outside funding from the Institute of Orthopaedic Research and Education and the Baylor Orthopedic Research Fund. None of the authors received payments or other benefits or a commitment or agreement to provide such benefits from a commercial entity. No commercial entity paid or directed, or agreed to pay or direct, any benefits to any research fund, foundation, educational institution, or other charitable or nonprofit organization with which the authors are affiliated or associated. The Department of Veterans Affairs, Houston, Texas, provided laboratory space for the work.

Investigation performed at Baylor College of Medicine and Michael E. DeBakey Veterans Affairs Medical Center, Houston, Texas

The Journal of Bone and Joint Surgery, Incorporated

J Bone Joint Surg Am, 2006 Oct 01;88(10):2201-2209. doi: 10.2106/JBJS.E.00812

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Abstract

Background: Early full weight-bearing after an acute osteochondral injury avoids problems associated with immobility but may also be harmful by amplifying the inflammatory response. To investigate these effects, we developed an in vivo model of subchondral trauma.

Methods: After an impact injury to the femoral condyle, fourteen dogs were randomized to immediate full weight-bearing or to four weeks of minimal weight-bearing before full weight-bearing. Synovial fluid was sampled by aspiration at one, two, four, eight, twelve, sixteen, twenty, and twenty-four weeks. Neutrophils, monocytes, and lymphocytes were enumerated, and the concentrations of tumor necrosis factor-alpha, interleukin-10, nitric oxide, matrix metalloproteinases, and glycosaminoglycans were measured.

Results: Compared with the findings for uninjured joints, the synovial fluid from the impacted joints of full-weight-bearing dogs had significantly higher peak concentrations of neutrophils (p = 0.0006 at one week), mononuclear leukocytes (p = 0.001 at four weeks), tumor necrosis factor-alpha (p = 0.001 at one week), nitric oxide (p = 0.001 at one week), matrix metalloproteinases (p = 0.008 at one week), and glycosaminoglycans (p = 0.002 at four weeks and p = 0.001 at six months). The size of the bone bruise correlated with the peak concentrations of tumor necrosis factor-alpha (r² = 0.89, p = 0.007; Spearman rank test), matrix metalloproteinases (r² = 0.96, p = 0.0004), and glycosaminoglycans (r² = 0.96, p = 0.0004). However, restriction to minimal weight-bearing for four weeks after the injury led to a significant reduction in the synovial fluid concentrations of neutrophils (p = 0.007 at one week and p = 0.01 at two weeks), tumor necrosis factor-alpha (p = 0.0006 to 0.02 during the first four weeks), nitric oxide (p = 0.001 to 0.04 during the first four weeks), and matrix metalloproteinases (p = 0.007 to 0.01 from the second week to the eighth week). In contrast, interleukin-10 concentrations were significantly higher (p = 0.002 at one week) and glycosaminoglycan levels remained at normal levels in animals that were restricted from immediate full weight-bearing after the injury.

Conclusions: The magnitude of the inflammatory response is proportional to the size of the bone bruise. Restriction to minimal weight-bearing for four weeks reduces the magnitude of the inflammatory response and the cartilage degradation following articular cartilage impact injury.

Clinical Relevance: Strategies to minimize mechanical stress during the early postinjury period may help to preserve cartilage integrity and forestall the development of osteoarthritis.

Figures in this Article

There is controversy with regard to the best way to restore strength and range of motion after a knee joint injury¹. Some physicians recommend restricted range of motion and limited weight-bearing², whereas others encourage their patients to return to normal weight-bearing and to engage in vigorous exercise in order to regain quadriceps function and full knee extension¹. Magnetic resonance imaging scans that are acquired after a joint injury show that there is often more osteochondral damage than was appreciated^3,4. For example, subchondral edema or "bone bruising" is found in association with 47% to 80% of tears of the anterior cruciate ligament^5,6. The cartilage overlying bone bruises is softer⁷, and there is chondrocyte death and loss of extracellular matrix^8-12. After a knee injury, the synovial fluid contains proinflammatory cytokines¹³, metalloproteinases^14-20, and glycosaminoglycans that are released when matrix is degraded²¹. In view of the severity of these inflammatory sequelae, it is unclear whether the current practice of early weight-bearing following joint injury prolongs inflammation and/or delays healing. We postulated that injured tissue is unusually vulnerable to further damage with early weight-bearing and that patients might be better served by avoiding full weight-bearing during rehabilitation of the knee in the early postinjury phase. In addition, we postulated that the extent of subchondral edema is directly correlated to the magnitude of inflammation. To test our hypothesis, we developed a canine model of articular trauma, measured the extent of the bone bruising with use of magnetic resonance imaging, and evaluated the effect of immediate full weight-bearing as compared with four weeks of minimal weight-bearing on the ensuing inflammation and cartilage degeneration.

Materials and Methods

Materials and Methods | Results | Discussion | References

Canine Bone Bruise Model

Acanine femoral condyle injury model was developed under a protocol approved by the Institutional Animal Care and Use Committee. Fourteen adult dogs weighing 25 to 34 kg were anesthetized, the synovial capsule on one side was incised, and an impact was delivered to the articular surface of the lateral condyle. The average peak compressive stress delivered to the articular surface was 23.4 MPa (range, 18 to 25 MPa), a stress that has been documented to cause a bone bruise in other models²². The same operative procedure was performed on the contralateral limb of each animal without the delivery of an impact. After surgery, seven dogs were randomized to full weight-bearing with free joint motion. The impacted limb of the other seven dogs was splinted to keep the foot in plantar flexion; this allowed full motion of the knee and hip but prevented full weight-bearing. At the end of four weeks, the splints were removed and all animals were allowed to resume full weight-bearing and normal activity. Dogs were kept in 6 by 9-ft (1.8 by 2.7-m) cages. There was no regimented exercise program, but the dogs were allowed to run freely in a 10 by 30-ft (3.0 by 9.1-m) room twice a day.

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Fig. 1: Magnetic resonance images of cartilage before and after the impact injury. Panel A shows a T2-weighted fat-saturated magnetic resonance imaging scan of the sham-treated (control) canine femoral joint, and Panel B shows the contralateral joint after the impact injury. Arrows indicate the extent of the subchondral edema.

Radiographic Analysis

Prior to surgery, T1-weighted magnetic resonance imaging scans of the knee were acquired (with use of a 3.0-T magnet) to assess preexisting abnormalities. Additional scans (including T1-weighted scans, T2-weighted scans, and T2-weighted scans with fat saturation) were acquired and plain radiographs were made three to five days after impact to document the bone bruise adjacent to the impact site. Magnetic resonance images were interpreted by a board-certified veterinary radiologist (B.A.P.). The radiologist was blinded to the group allocation of each set of images (impacted or nonimpacted, full or minimal weight-bearing), but we did not specifically evaluate intratester error. Measurements of the bone bruise were determined on the sagittally-oriented slice where the defect was the largest (Fig. 1, B). The measurement was made with a manual caliper along an axis perpendicular to the articular surface.

Collection of Synovial Fluid and Enumeration of Leukocytes

Synovial fluid was aspirated from both knees intraoperatively, at one, two, and four weeks and then monthly thereafter for a total of six months. Five milliliters of lactated Ringer solution were injected through a 16-gauge intravenous catheter, the joint was flexed and extended ten times, and all of the fluid in the joint was aspirated. Joint aspirates were centrifuged, and the synovial fluid from the supernatant was stored as aliquots in liquid nitrogen until assayed for soluble factors. Cells in the pellet were restored to the initial volume of the aspirate in Dulbecco's phosphate-buffered saline solution (GIBCO, Carlsbad, California). Cells were diluted to 1:5 in 0.1N HCl to facilitate the discrimination between lymphocytes, monocytes, and neutrophils on the basis of nuclear morphology and cytoplasmic characteristics²³ and were counted in duplicate with use of a hemocytometer.

Analysis of Cytokines and Glycosaminoglycans

Freshly thawed samples were assayed in triplicate. The concentration of tumor necrosis factor-alpha (TNF-a) was measured with the WEHI 164 fibroblast cytotoxicity bioassay²⁴ with use of the MTS colorimetric assay (Promega, Madison, Wisconsin) to measure viability. A standard calibration curve was prepared with human TNF-a (R & D Systems, Minneapolis, Minnesota), and the specificity of the assay was confirmed with use of polyclonal antibody against TNF-a (Genzyme, Cambridge, Massachusetts) to block TNF-a-induced cytotoxicity. Nitric oxide (NO) concentrations were quantified with use of the Greiss reaction (R & D Systems)²⁵ after the synovial fluid samples were filtered through a 10,000 molecular weight cutoff microcentrifuge filter (Centricon; Millipore, Billerica, Massachusetts). Matrix metalloproteinase (MMP) activity was determined with use of the commercially available MMP-13 assay kit (Chondrex, Redmond, Washington) in which a fluorochromium-linked collagen-like peptide is used to assess enzymatic cleavage. All samples had an activator (APMA) and protease inhibitor to inhibit all noncollagenolytic proteases. Interleukin-10 (IL-10) was measured with use of a commercially available polyclonal enzyme-linked immunosorbent assay (Cytoimmune Sciences, College Park, Maryland) that has been shown to react with canine IL-10²⁶. Human IL-10 was used to create the standard curve. Glycosaminoglycans (GAGs) were assayed with use of a previously published technique²⁷ based on the specific interaction between sulfated polymers and the tetravalent cationic dye Alcian blue at pH 1.5 in 0.4-M guanidine-HCl with 0.25% Triton. The proteoglycan-Alcian blue complex formed by this reaction was collected by means of centrifugation and was dissociated in a guanidine-HCl/propanol mixture, and the absorbance of the dye solution was measured at 600 nm. Chondroitin-6 sulfate (Sigma-Aldrich, St. Louis, Missouri) was used to prepare a standard curve.

Statistical Analyses

The mean and the standard error of each of the measured parameters were calculated for the full-weight-bearing, minimal-weight-bearing, and uninjured (control) groups. Data from control joints in partial-weight-bearing dogs did not differ from control joints in full-weight-bearing dogs. Therefore, all analyses and figures used control data from the full-weight-bearing group. The significance of differences between groups was estimated with use of the nonparametric Mann-Whitney U test. This more conservative nonparametric test was used because the sample sizes were too small to allow verification that the data were normally distributed. Correlations between the size of the bone bruise and inflammatory parameters were expressed in terms of the Spearman rank correlation coefficient. The level of significance was set at p = 0.05.

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Fig. 2: Graphs illustrating the correlation between the size of the bone bruise and the quantity of TNF-a, MMP, and GAG in the synovial fluid of dogs in the full-weight-bearing group. The quantities of MMP and TNF-a at one week after the injury and GAG at two months after the injury were compared with the size of the initial bone bruise. The data were fitted to a regression curve, and r² and p values were calculated according to the Spearman test.

Results

Materials and Methods | Results | Discussion | References

Impact Injury and Radiographic Changes

The average peak compressive stress delivered to the articular surface during impact was 23.4 MPa (range, 18 to 25 MPa). All preoperative magnetic resonance imaging scans of the impacted and contralateral knees were within normal limits and were without evidence of osseous or soft-tissue abnormalities (Fig. 1, A). Scans acquired three to five days postoperatively showed formation of a "bone bruise" immediately beneath the point of impact, with varying levels of edema on the T2-weighted fat-saturated scans (Fig. 1, B). Six months after the injury, magnetic resonance imaging studies showed resolution of the bone bruise, although cartilage-sensitive imaging was not available to confirm that the cartilage overlying the region of subchondral edema had also returned to its preinjury state. The size of the bone bruise, as described by the depth to which the edema extended beneath the subchondral plate, ranged from 3 to 20 mm in the sagittal plane. With the numbers available, there was no significant difference between the mean size of the bone bruise in the full-weight-bearing group (10.7 ± 5.7 mm) and that in the minimal-weight-bearing group (9.43 ± 3.83 mm) (p = 0.63, unpaired t test).

Correlation Between Size of Bone Bruise and Inflammation

The impact injury induced a local inflammatory response that was characterized by an increase in the concentration of leukocytes, TNF-a, NO, MMP, and GAG in the synovial fluid. There was a significant correlation, as estimated with the Spearman rank test, between the size (depth) of the bone bruise as measured with magnetic resonance imaging and the peak concentration of TNF-a (r² = 0.89, p = 0.007), MMP (r² = 0.96, p = 0.0004), and GAG (r² = 0.96, p = 0.0004) in the synovial fluid of dogs in the full-weight-bearing group (Fig. 2). With the numbers studied, there was no correlation between the size of the bone bruise and the peak concentrations of neutrophils, monocytes, lymphocytes, NO, or IL-10 in the synovial fluid of these animals.

Synovial Fluid Leukocyte Counts

One week after the injury, synovial fluid from the injured joints in the full-weight-bearing group contained a mean (and standard error) of 7500 ± 1200 neutrophils/mL, which was significantly greater than the value for the uninjured (control) joints (1070 ± 430 neutrophils/mL) (p = 0.0006) (Fig. 3). Neutrophil counts were still significantly elevated in the full-weight-bearing group during the second week (p = 0.004) and then returned to normal by the fourth week (p = 0.53). Synovial fluid from the injured joints in the minimal-weight-bearing group had significantly more neutrophils as compared with the fluid from the uninjured (control) joints during the first week (p = 0.02) (Table I) but had significantly fewer neutrophils as compared with the fluid from the injured joints in the full-weight-bearing group (p = 0.007 at one week and p = 0.01 at two weeks) (Fig. 3 and Table I).

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TABLE I P Values for Leukocytes and Inflammatory Mediators in Synovial Fluid*

Weeks After Injury	Injured Joints in Full-Weight-Bearing Group Compared with Injured Joints in Minimal-Weight-Bearing Group	Injured Joints in Full-Weight-Bearing Group Compared with Control (Uninjured) Joints	Injured Joints in Minimal-Weight-Bearing Group Compared with Control (Uninjured) Joints
Tumor necrosis factor-alpha
1	0.0006	0.001	0.03
2	0.0006	0.0006
4	0.02	0.0006
8
12
Nitric oxide
1	0.001	0.001	0.02
2	0.009	0.02	0.04
4	0.04
8			0.01
12
Neutrophils
1	0.007	0.0006	0.02
2	0.01	0.004
4
8			0.03
12
Monocytes
1
2			0.002
4		0.001	0.004
8
12
16
Lymphocytes
1			0.0006
2			0.02
4		0.002
8
12
16
Matrix metalloproteinase
1		0.008	0.05
2	0.008	0.002
4	0.01	0.001
8	0.007
12
Interleukin-10
1	0.002		0.0002
2		0.02	0.03
4	0.02	0.007
8
12
Glycosaminoglycan
1		0.03
2		0.01
4		0.002
8	0.005	0.0003
12	0.05	0.006
16	0.016	0.005
20	0.05	0.007
24	0.01	0.001

Statistical differences between the quantities of mediators or leukocytes were analyzed with use of the Mann-Whitney U test. Synovial fluid was sampled at varying times after the injury as shown. Comparisons were made between the injured knees in the full-weight-bearing and minimal-weight-bearing groups, between the injured full-weight-bearing group and uninjured knees, and between the injured minimal-weight-bearing group and uninjured knees. Only significant values (p = 0.05) are listed in the table; nonsignificant values (p > 0.05) are left blank.

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TABLE I P Values for Leukocytes and Inflammatory Mediators in Synovial Fluid*

Weeks After Injury	Injured Joints in Full-Weight-Bearing Group Compared with Injured Joints in Minimal-Weight-Bearing Group	Injured Joints in Full-Weight-Bearing Group Compared with Control (Uninjured) Joints	Injured Joints in Minimal-Weight-Bearing Group Compared with Control (Uninjured) Joints
Tumor necrosis factor-alpha
1	0.0006	0.001	0.03
2	0.0006	0.0006
4	0.02	0.0006
8
12
Nitric oxide
1	0.001	0.001	0.02
2	0.009	0.02	0.04
4	0.04
8			0.01
12
Neutrophils
1	0.007	0.0006	0.02
2	0.01	0.004
4
8			0.03
12
Monocytes
1
2			0.002
4		0.001	0.004
8
12
16
Lymphocytes
1			0.0006
2			0.02
4		0.002
8
12
16
Matrix metalloproteinase
1		0.008	0.05
2	0.008	0.002
4	0.01	0.001
8	0.007
12
Interleukin-10
1	0.002		0.0002
2		0.02	0.03
4	0.02	0.007
8
12
Glycosaminoglycan
1		0.03
2		0.01
4		0.002
8	0.005	0.0003
12	0.05	0.006
16	0.016	0.005
20	0.05	0.007
24	0.01	0.001

Monocytes and lymphocytes began to migrate into the joint fluid within the first two weeks but did not reach their peak levels until one month after the injury (Fig. 3). In the full-weight-bearing group, monocyte and lymphocyte numbers were significantly higher in the injured joints than in the uninjured joints at four weeks (p = 0.001 and p = 0.002, respectively) (Fig. 3). However, lymphocyte counts did not differ significantly between the full and minimal-weight-bearing groups at any time after the injury (Fig. 3 and Table I). The kinetics of monocyte influx into the synovial fluid paralleled that of lymphocytes (data not shown) and did not differ significantly between the full and minimal-weight-bearing groups at any time-point (Table I).

Inflammatory Mediators

The TNF-a level for the injured joints in the full-weight-bearing group reached an average of 311 ± 40 pg/mL one week after the injury, almost an order of magnitude greater than that for the uninjured joints (38 ± 24 pg/mL) (p = 0.001) (Fig. 3). TNF-a levels were still elevated at four weeks (p = 0.0006) and then returned to baseline (Fig. 3). Animals in the minimal weight-bearing group had lower concentrations of TNF-a than did those in the full-weight-bearing group throughout the first four weeks after the injury (p = 0.0006 to 0.02) (Table I). In the minimal-weight-bearing group, synovial fluid TNF-a concentrations were only transiently elevated during the first week after the injury and thereafter returned to normal (Table I and Fig. 3).

The matrix metalloproteinase concentration in the synovial fluid peaked at one week and remained elevated above normal for four weeks after the injury in the full-weight-bearing group (p = 0.001) (Fig. 3). From the second week to the eighth week, the MMP concentration was lower in the minimal-weight-bearing-group than in the full-weight-bearing group (p = 0.007 to 0.01) (Fig. 3 and Table I). MMP activities in the minimal-weight-bearing group were higher than those in the control group only transiently during the first week after injury (p = 0.05).

The nitric oxide level for the injured joints in the full-weight-bearing group peaked at one week (p = 0.001) and remained elevated compared with that for the uninjured joints until four weeks after the injury (Fig. 3). Similarly, the NO concentration for the injured joints in the minimal-weight-bearing group was higher than that for the uninjured controls at one, two, and eight weeks (p = 0.01 to 0.04) (Table I and Fig. 3). However, the NO concentration in the minimal-weight-bearing group was lower than that in the full-weight-bearing group for the first four weeks after the injury (p = 0.001 to 0.04) (Table I and Fig. 3).

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Fig. 3: Graphs illustrating the kinetics of inflammatory mediators and leukocytes in the synovial fluid. Synovial fluid was sampled from the impacted joints of full-weight-bearing animals (closed symbols, solid lines), the impacted joints of minimal-weight-bearing animals (open symbols, dotted lines), and control (unimpacted) joints (X symbols and dashed lines) at the time of surgery and at one, two, four, eight, twelve, and sixteen weeks after surgery. Samples were assayed for the numbers of neutrophils and lymphocytes and for the quantities of TNF-a, NO, MMP, and IL-10. Error bars indicate ±1 standard error of the mean of seven subjects in each group. Asterisks mark time-points at which the full and minimal-weight-bearing groups had significantly different results (p < 0.05, Mann Whitney U test).

The kinetics of the appearance of IL-10 in the synovial fluid were very different from those seen with TNF-a, MMPs, or NO. In the minimal weight-bearing group, the concentration of IL-10 reached its peak within the first week after the injury and was, at that time, higher in the minimal-weight-bearing group than in the full-weight-bearing group (p = 0.002) (Fig. 3 and Table I). In the full-weight-bearing group, the IL-10 concentration did not reach its peak until the fourth week, and was, at that time, higher than that in the minimal-weight-bearing group (p = 0.02), which had already returned to baseline (Fig. 3). At no time did the concentration of IL-10 in the full-weight-bearing group reach as high as that seen in the minimal-weight-bearing group one week after the injury (Fig. 3).

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Fig. 4: Graph illustrating the kinetics of GAG in the synovial fluid. Synovial fluid was sampled from the impacted joints of full-weight-bearing animals (closed symbols, solid lines), the impacted joints of minimal weight-bearing animals (open symbols, dotted lines), and control (unimpacted) joints (X symbols and dashed lines) at the time of surgery and at one, two, four, eight, twelve, sixteen, twenty, and twenty-four weeks after surgery. Error bars indicated ±1 standard error of the mean of seven subjects in each group. Asterisks mark time-points at which full and minimal-weight-bearing groups had significantly different results (p < 0.05, Mann Whitney U test).

The increase in the glycosaminoglycan level was delayed relative to the appearance of cytokines. Although significantly elevated within one week (p = 0.03), the GAG level in the full-weight-bearing group did not reach its peak until two months after the injury (Fig. 4).

Animals in the full-weight-bearing group had persistently elevated concentrations of GAG throughout the six-month observation period (p = 0.0003 to 0.03) (Table I and Fig. 4). In contrast, GAG concentrations in the minimal-weight-bearing group never exceeded the levels recorded for the uninjured controls (Table I and Fig. 4).

Discussion

Materials and Methods | Results | Discussion | References

After joint trauma, magnetic resonance imaging scans may show concomitant damage to the contiguous cartilage and supporting bone in up to 80% of patients^3,4. Many physicians recommend early mobilization and weight-bearing to maintain muscle mass and range of motion. However, as the articular cartilage overlying a bone bruise is softer than the surrounding cartilage⁷, we hypothesized that weight-bearing on this damaged articular cartilage may promote or prolong the inflammatory response to the acute injury. In the present study, we created an isolated osteochondral injury in an animal model and documented the kinetics of release of inflammatory mediators, the influx of inflammatory cells, the degradation of matrix, and the effects of full as opposed to minimal weight-bearing on the inflammatory response.

Size of the Bone Bruise

Our data indicate that, after an impact injury, the size (depth) of the bone bruise is directly related to the extent of early inflammatiovn, as indicated by changes in TNF-a and MMP levels, and subsequent cartilage degradation, as indicated by the GAG level in the synovial fluid. In the clinical setting, this suggests that early magnetic resonance imaging findings may be utilized to identify patients who have sustained articular trauma secondary to joint injury. Moreover, the size of the subchondral lesion visible on magnetic resonance imaging can then serve as a prognostic indicator of subsequent cartilage breakdown. This information has potential value in allowing the clinician to modify the postoperative treatment of these injuries through adjustment of the intensity of postoperative rehabilitation and the staging of progression to full weight-bearing and other, more vigorous activity. In addition, if it is indeed possible for physicians to identify patients who are most at risk for cartilage degeneration after joint injury, treatment strategies and pharmacologic interventions that specifically target cartilage preservation and recovery may be considered.

Effect of Weight-Bearing

In the present study, we showed that TNF-a, nitric oxide, and matrix metalloproteinases are secreted into synovial fluid after an impact injury to the canine femoral condyle. After an injury, human synovial fluid has elevated concentrations of TNF-a and IL-6 and reduced concentrations of the IL-1 inhibitor, IL-1RA¹³. Potential cellular sources of these factors include chondrocytes, synoviocytes, and infiltrating leukocytes^28-31. TNF-a and IL-1 can induce endothelial cells and chondrocytes to display increased quantities of adhesion molecules and to secrete chemokines that promote the influx of leukocytes^29,32. TNF-a and nitric oxide can induce chondrocyte apoptosis, and proinflammatory cytokines also induce the production of matrix metalloproteinases that enzymatically degrade extracellular matrix proteins^14-16,18-20. The glycosaminoglycans that appear in the patient's synovial fluid after a joint injury are evidence of the matrix degradation that follows inflammation²¹.

In our model, monocytes and lymphocytes entered the synovial fluid somewhat later than neutrophils did, and they did not reach peak concentration until one month after the injury, at which time the neutrophil count had returned to baseline. The mononuclear cell count in the synovial fluid returned to baseline within two to three months after the impact injury. The rise and fall of TNF-a, NO, and MMPs in the full-weight-bearing group closely paralleled the changes in neutrophil numbers and returned to baseline after four weeks.

Concentrations of neutrophils, TNF-a, NO, MMP, and GAG in the synovial fluid were significantly increased in the full-weight-bearing group as compared with the minimal-weight-bearing group. In the minimal-weight-bearing group, the magnitude of these inflammatory parameters was much lower and the concentrations were only transiently above normal. Our observation that GAG concentrations were never significantly elevated in the minimal-weight-bearing group is strong evidence supporting our hypothesis that weight-bearing stress exacerbates inflammation and cartilage degradation after injury.

How does weight-bearing increase inflammation? Previous studies have suggested that the application of a mechanical stress to cartilage generates signals in the chondrocytes that cause these cells to upregulate the expression of ICAM-1 (Intercellular Adhesion Molecule-1) (CD54)³³ and attract blood leukocytes. Interaction of these leukocytes with the chondrocyte cell surface is accompanied by the accumulation of oxidative radicals in the chondrocyte cytoplasm³⁴. In addition, the quantity of inflammatory mediators released into the synovial fluid is proportional to the size of the bone bruise. As the cartilage overlying the bone bruise is softer after impact, the increased deformation of the articular surface generated by weight-bearing may kill additional chondrocytes. Repeated shear stresses also may prolong the inflammatory phase and delay the onset of healing. The prolonged appearance of matrix metalloproteinases and the persistent elevation of GAG in the synovial fluid in the full-weight-bearing group would be consistent with this interpretation.

After acute joint injury, surviving chondrocytes located within and adjacent to the impact area are still at risk and can be killed by infiltrating mononuclear leukocytes³⁴. This leukocyte-mediated extension of chondrocyte injury may be opposed by the IL-10 that was released early after the injury in the minimal-weight-bearing group. IL-10 inhibits the expression of adhesion molecules and the generation of reactive oxygen intermediates, and it counteracts some of the proinflammatory effects of TNF-a, IL-1, and MMPs^33,35,36 and also supports chondrocyte proliferation^37,38. The early appearance of IL-10 as seen in the minimal-weight-bearing group may downregulate the products of the early inflammatory response and facilitate reparative processes. The source of the IL-10 in this model may have been the infiltrating lymphocytes. The peak level of IL-10 coincided with a significant elevation in the numbers of lymphocytes in the synovial fluid in the minimal weight-bearing group but not the full-weight-bearing group. Chondrocytes also can produce IL-10^29,39. Our findings are also consistent with the observations that small shear stresses induce an antiinflammatory response and large stressors induce a proinflammatory response in chondrocytes⁴⁰. It will be of interest to determine whether IL-10 is among the mediators that are regulated by shear stress response elements in chondrocytes.

The clinical importance of this work with respect to humans is unknown at this time. However, this work strengthens the likelihood that exacerbation of inflammation by early full weight-bearing may be as important a consideration in optimizing rehabilitation protocols to curtail the potential for early osteoarthritis as are concerns over the temporary loss of muscle mass caused by a delay of full weight-bearing. ?

References

Materials and Methods | Results | Discussion | References

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Topics

cytokine ; inflammation ; cartilage ; dog, domestic ; glycosaminoglycans ; interleukin-10 ; leukocytes ; lymphocyte ; matrix metalloproteinases ; neutrophil

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D.M. Green, P.C. Noble, J.R. BocellJr., J.S. Ahuero, B.A. Poteet, H.H. Birdsall; Effect of Early Full Weight-Bearing After Joint Injury on Inflammation and Cartilage Degradation. The Journal of Bone & Joint Surgery. 2006 Oct;88(10):2201-2209.

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