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Open Access

Research

High-fat/high-sucrose diet-induced obesity results in joint-specific development of osteoarthritis-like degeneration in a rat model



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Abstract

Objectives

Metabolic syndrome and low-grade systemic inflammation are associated with knee osteoarthritis (OA), but the relationships between these factors and OA in other synovial joints are unclear. The aim of this study was to determine if a high-fat/high-sucrose (HFS) diet results in OA-like joint damage in the shoulders, knees, and hips of rats after induction of obesity, and to identify potential joint-specific risks for OA-like changes.

Methods

A total of 16 male Sprague-Dawley rats were allocated to either the diet-induced obesity group (DIO, 40% fat, 45% sucrose, n = 9) or a chow control diet (n = 7) for 12 weeks. At sacrifice, histological assessments of the shoulder, hip, and knee joints were performed. Serum inflammatory mediators and body composition were also evaluated. The total Mankin score for each animal was assessed by adding together the individual Modified Mankin scores across all three joints. Linear regression modelling was conducted to evaluate predictive relationships between serum mediators and total joint damage.

Results

The HFS diet, in the absence of trauma, resulted in increased joint damage in the shoulder and knee joints of rats. Hip joint damage, however, was not significantly affected by DIO, consistent with findings in human studies. The total Mankin score was increased in DIO animals compared with the chow group, and was associated with percentage of body fat. Positive significant predictive relationships for total Mankin score were found between body fat and two serum mediators (interleukin 1 alpha (IL-1α) and vascular endothelial growth factor (VEGF)).

Conclusion

Systemic inflammatory alterations from DIO in this model system may result in a higher risk for development of knee, shoulder, and multi-joint damage with a HFS diet.

Cite this article: K. H. Collins, D. A. Hart, R. A. Seerattan, R. A. Reimer, W. Herzog. High-fat/high-sucrose diet-induced obesity results in joint-specific development of osteoarthritis-like degeneration in a rat model. Bone Joint Res 2018;7:274–281. DOI: 10.1302/2046-3758.74.BJR-2017-0201.R2

Article focus

  • Obesity and corresponding chronic low-grade systemic inflammation are linked to the onset and progression of knee osteoarthritis (OA).

  • A strong relationship exists between obesity and hand OA; however, the relationship between metabolic disturbance and structural OA-like changes in other synovial joints is unclear.

  • There is evidence of a systemic-to-local trajectory of metabolic OA-like knee joint damage in the high-fat/high-sucrose (HFS) diet-induced rat model.

  • The aim of this study was to investigate if diet-induced obesity (DIO) would also result in OA-like changes in the shoulders and hips of such animals.

Key messages

  • The HFS diet, in the absence of trauma, resulted in increased joint damage in the shoulder and knee joints of rats. Hip joint damage, however, was not significantly affected by DIO.

  • The predictive relationships between serum markers and body fat with total Mankin score reveal that systemic inflammation may be involved in the cumulative pathology observed here.

Strengths and limitations

  • This study evaluates the previously unknown relationships between DIO, shoulder, hip, and knee joint damage and serum biomarkers of inflammation, providing important information from which a mechanism of joint damage with DIO can be approached.

  • The pre-clinical findings in the shoulder and knee joints echo previous joint-specific relationships for metabolic dysfunction in knees and shoulders, and an absence of pathology in hips of OA patients.

  • Weaknesses include that the present analysis evaluates cross-sectional data and, by design, this is a descriptive study (not able to define a mechanism).

Introduction

Metabolic syndrome and corresponding chronic low-grade systemic inflammation are associated with the onset and progression of osteoarthritis (OA).1 Several pre-clinical studies have demonstrated that diet-induced obesity (DIO) results in degenerative changes in murine and rabbit knee joints.1 Furthermore, among OA patients, individuals with obesity report more pain, worse function, and reduced quality of life compared with OA patients with a healthy weight.2-4 Obesity is also associated with the presence of bilateral OA, as well as OA in multiple joints.5 The relationship between obesity and OA is likely due to low-level systemic inflammation, rather than increased mechanical loading from body weight.1,6 Previous data from our laboratory provided evidence for a systemic-to-local disease trajectory of knee joint damage in a Sprague-Dawley rat model of high-fat/high-sucrose (HFS) DIO, in the absence of trauma.6-8 It is unclear if the systemic changes measured in this model system affected synovial joints other than the knee. Furthermore, there is an absence of data supporting or refuting OA in multiple synovial joints in pre-clinical models of DIO, indicating a critical gap in the metabolic OA literature.

A compelling link also exists between obesity and hand OA,1 a joint that is not subjected to mechanical load due to body weight. Furthermore, the presence of hand OA at baseline evaluation is associated with increased future risk of knee and hip OA.9 However, the relationship between metabolic disturbance and structural OA-like joint damage in other synovial joints, such as the shoulder and hip, is unclear and inconsistent.10,11 For example, metabolic syndrome components, such as hypertension and visceral obesity, are correlated with knee OA in human studies, and there is evidence of a link between adipokines and shoulder OA in obese patients.12-14 In patients with knee OA, shoulder OA is the next most common site of OA.15 A high prevalence of shoulder pain is reported in individuals with obesity compared with controls of normal weight, and there is a significant connection between obesity and shoulder repair surgery.16

Although the pathophysiology of shoulder OA is unclear, it has been shown that rotator cuff injury results in shoulder joint damage in rodents.17,18 Other studies demonstrate that shoulder morphology and biomechanical loading profiles may also play a role in the onset and progression of glenohumeral OA.19 Population-based studies demonstrate that age and hypertension are significant risk factors for shoulder OA.20 In the case of metabolic OA, it is likely that shoulder OA is the result of deleterious changes, perhaps due to metabolic disturbance in the absence of trauma, defining a new disease trajectory. There is a paucity of work in the area of shoulder OA in general; systemic and metabolic factors have been implicated in the onset and progression of shoulder OA21 but have yet to be tested.

Considering the proximity of the hip joint to the visceral adipose tissue, which is known to contribute to low-level systemic inflammation with metabolic disturbance,22 it is surprising that no significant relationships have been observed with metabolic syndrome components and hip OA.1,12,13 Increased fat mass and decreased lean mass have been reported in patients with hip OA when compared with control subjects.23 However, patients undergoing knee arthroplasty have higher body mass indices (BMI, kg/m2) when compared with patients who received hip arthroplasty.24 Of note, when structural damage is the primary outcome, there is a weak association or no association between obesity and hip OA.25 However, recent evidence demonstrates that weight gain > 20 kg in early and middle adulthood is associated with increased severe hip OA later in life.26 Taken together, these data suggest that while cross-sectional evaluations of hip OA show mixed links with obesity, long-term obesity exposure could influence the development of hip OA.

Clarifying the relationships between metabolic disturbance and shoulder, knee, and hip OA in pre-clinical models has been identified as a critical gap within the context of metabolic OA.1 Therefore, the purpose of this study was to determine if a HFS diet would result in OA-like joint damage in the shoulders, knees, and hips of rats after induction of obesity, in order to identify potential joint-specific risk for such OA-like changes. We hypothesized that DIO would increase the incidence of joint damage in the shoulder and knee joints, but not hip joints, of adult male rats after 12 weeks of HFS feeding.

Materials and Methods

A total of 16 male Sprague-Dawley rats aged between ten and 12 weeks were allocated to either the DIO group (40% fat, 45% sucrose, custom Diet #102412; Dyets, Inc., Bethlehem, Pennsylvania; n = 9) or a standard chow control diet (chow; 12% fat, 0% sucrose, Lab Diet 5001; n = 7) for 12 weeks, and were individually housed on a 12-hour dark/light cycle. All experiments were approved by the University of Calgary Life and Environmental Sciences Animal Care Committee. Prior to sacrifice, body composition was evaluated using dual-energy x-ray absorptiometry (DXA). Blood serum was collected, prepared, and analyzed for protein as previously described.6,8 A total of 27 markers were quantified in serum using a rat 27-plex multiplex assay and Luminex xMAP technology (Eve Technologies, Calgary, Canada).6

Histological assessments

After sacrifice, shoulder, hip, and knee joints were harvested, decalcified, and cut into serial sagittal 8 µm thick sections according to previously described methods.7,8 A Modified Mankin score was used to describe the damage in each knee joint as previously described.6

Briefly, five areas were evaluated (the medial and lateral tibial plateau, the medial and lateral femoral condyle, and the patella) on the standard 14-point Mankin scale,27 and meniscal damage was scored on a scale of 0 to 5. Hip joint surfaces (acetabulum and femur) and shoulder joint surfaces (scapula and humerus) were scored according to the 14-point Mankin criteria.27 All joints were evaluated for subchondral bone and synovium pathology using a five- and four-point set of criteria, respectively, that was adapted from the rat-specific Osteoarthritis Research Society International (OARSI) metric.28 The final Modified Mankin score for each joint was obtained by adding the site-specific Mankin scores within a joint and the two corresponding bone and synovium OARSI scores.7,8,27-29

To operationalize the cumulative joint damage in a given animal, a total Mankin score was calculated by adding the scores across all three joints. This represents an indirect approximation of multi-joint damage in this model system. Furthermore, as we hypothesized that shoulder and knee joint damage would be increased in DIO animals compared with in chow animals, we also evaluated the sum of shoulder and knee damage between dietary groups. The interrater reliability between histology outcomes between the two independent blinded assessors used in this study was r > 0.90.

Statistical analysis

Levene’s test for equality of variance was conducted on all outcomes. If significant (p ⩽ 0.05), Mann–Whitney U tests were used to evaluate DIO compared with control. If equal variances were found, Student’s t-tests were performed between DIO and control (IBM SPSS Statistics for Windows, Version 21.0; IBM Corp., Armonk, New York; α = 0.05). Odds ratios (OR) were calculated for total Mankin score and the sum of shoulder and knee Mankin scores to evaluate the odds of a DIO animal being in the upper 50th percentile of cumulative joint damage. To understand systemic contributors to single-joint and multi-joint damage, Pearson and Spearman correlations were run between body fat, all serum markers, individual joint damage, and total joint damage across all animals. Linear regression modelling was performed on analytes with a significant positive relationship with total Mankin score, in order to evaluate predictive relationships with serum mediators and total body fat to total Mankin score.

Results

Body composition

After 12 weeks of HFS feeding, DIO animals gained more body mass than the chow-fed controls (DIO, mean 802 g, 95% confidence interval (CI) 797 to 859; chow, mean 650 g, 95% CI 599 to 689, p = 0.002). This was accompanied by an approximate twofold increase in body fat in DIO animals compared with chow-fed controls (DIO, mean 39%, 95% CI 37 to 42; chow, mean 21% (95% CI 17 to 24), p = 0.001).

Joint damage

DIO animals demonstrated significantly higher Modified Mankin knee joint scores than the chow-fed control animals (Figs 1 and 2), as previously described. Modified Mankin scores for shoulder joints were also significantly increased in DIO animals compared with chow control diet animals. Modified Mankin scores for hip joints, however, were not significantly different between DIO and chow-fed animals.

Fig. 1 
            Graph showing that diet-induced obesity (DIO) leads to increases in the severity of joint damage in the shoulders, knees, and hips of rats. DIO animals (n = 9) had increased Modified Mankin scores at the shoulder and knee compared with chow-fed animals (n = 7). Overlapping scores are represented by one point on the graph. Each line indicates the scores for one animal across the three joints. Hip scores were similar between groups. The blue line corresponds with the DIO animal depicted in Figure 2 for shoulder and hip, the purple line corresponds with the DIO animal depicted in Figure 2 for knee, and the green line corresponds with the chow animal illustrated in Figure 2. *p ⩽ 0.05 between DIO versus chow for shoulder and knee joints.

Fig. 1

Graph showing that diet-induced obesity (DIO) leads to increases in the severity of joint damage in the shoulders, knees, and hips of rats. DIO animals (n = 9) had increased Modified Mankin scores at the shoulder and knee compared with chow-fed animals (n = 7). Overlapping scores are represented by one point on the graph. Each line indicates the scores for one animal across the three joints. Hip scores were similar between groups. The blue line corresponds with the DIO animal depicted in Figure 2 for shoulder and hip, the purple line corresponds with the DIO animal depicted in Figure 2 for knee, and the green line corresponds with the chow animal illustrated in Figure 2. *p ⩽ 0.05 between DIO versus chow for shoulder and knee joints.

Fig. 2 
            Histology images taken at ×10, showing that DIO leads to increases in joint damage in shoulder and knee joints, but not hip joints. Scale bars indicate 500 μm. Black arrows indicate lesions.

Fig. 2

Histology images taken at ×10, showing that DIO leads to increases in joint damage in shoulder and knee joints, but not hip joints. Scale bars indicate 500 μm. Black arrows indicate lesions.

When the scores for all three joints were added, the total Mankin score was increased in DIO animals compared with in the chow-fed animals (Fig. 3a). Additionally, when knee and shoulder Mankin scores were summed, DIO animals also demonstrated increased cumulative scores compared with the chow-fed controls (Fig. 3b). The odds ratio of a DIO animal being in the upper half of the total Modified Mankin score was 21 (1.5 to 293.26). Since the same animals were in the upper 50th percentile of total Mankin score damage as were in the upper 50th percentile of the sum of knee and shoulder damage, the odds of a DIO animal being in the upper half of knee and shoulder damage were also 21 (1.5 to 293.26). Furthermore, the total Mankin scores and the knee and shoulder sum Mankin scores were both significantly and positively associated with body fat percentage across all animals, although each individual joint score was not significantly associated with body fat percentage (Figs 3c and 3d).

 
            Graphs showing that: a) total Mankin score is increased in diet-induced obesity (DIO) animals versus chow-fed controls; b) the sum of knee and shoulder Mankin scores is increased in DIO animals versus chow-fed controls; c) total Mankin score is positively significantly associated with percentage of body fat across all animals; and d) the sum of knee and shoulder Mankin scores is positively significantly associated with percentage of body fat across all animals. Empty squares represent DIO animals (n = 9) and black squares represent chow-fed control animals (n = 7). *p ⩽ 0.05 in DIO versus chow.

Fig.

Graphs showing that: a) total Mankin score is increased in diet-induced obesity (DIO) animals versus chow-fed controls; b) the sum of knee and shoulder Mankin scores is increased in DIO animals versus chow-fed controls; c) total Mankin score is positively significantly associated with percentage of body fat across all animals; and d) the sum of knee and shoulder Mankin scores is positively significantly associated with percentage of body fat across all animals. Empty squares represent DIO animals (n = 9) and black squares represent chow-fed control animals (n = 7). *p ⩽ 0.05 in DIO versus chow.

Serum mediator profiles

Several serum mediators were increased in DIO animals compared with chow-fed controls (p ⩽ 0.05, Table I). Specifically, DIO animals demonstrated significantly increased protein levels for leptin, interleukin 1 beta (IL-1β), IL-10, IL-18, macrophage chemoattractant protein-1 (MCP-1), and tumour necrosis factor alpha (TNF-α). Protein levels for vascular endothelial growth factor (VEGF), fractalkine, and macrophage inflammatory protein 1 alpha (MIP-1α) exhibited trends for increases in DIO animals (p ⩽ 0.15), but were not significantly increased in this cohort of animals.

Table I.

Serum inflammatory mediators. Summary of cytokine, adipokine, and growth factor protein levels that were increased in serum of obese animals. Data are categorized by diet-induced obesity (DIO) (n = 9) and chow (n = 7) animals, and presented as means and 95% confidence interval (CI)

Serum mediators DIO
Chow
p-value* R association with body fat p-value*
Mean (ng/ml) 95% CI Mean (ng/ml) 95% CI
Leptin 57.15 47.60 to 66.71 32.48 19.55 to 45.43 0.008 0.59 0.016
IL-1β 0.15 0.08 to 0.22 0.05 0.04 to 0.05 0.025 0.63 0.009
IL-10 0.16 0.10 to 0.23 0.08 0.06 to 0.10 0.031 0.54 0.030
IL-18 0.48 0.34 to 0.63 0.25 0.14 to 0.33 0.033 0.53 0.042
VEGF 0.08 0.05 to 0.12 0.05 0.03 to 0.07 0.128 0.52 0.037
MCP-1 1.11 0.90 to 1.32 0.78 0.56 to 0.99 0.046
TNF-α 0.01 0.01 to 0.01 0.01 0.00 to 0.01 0.050
Fractalkine 0.07 0.01 to 0.05 0.05 0.03 to 0.06 0.099
MIP-1a 0.02 0.00 to 0.02 0.01 0.01 to 0.02 0.079
IL-1α 0.75 0.21 to 1.49 0.47 0.20 to 0.83 0.500
  1. *

    Mann–Whitney U test

  1. Statistically significant

  1. VEGF, vascular endothelial growth factor; MCP-1, monocyte chemoattractant protein-1; TNF-α, tumour necrosis factor α; MIP-1a, macrophage inflammatory protein 1-a; IL-1α, interleukin 1 alpha.

Relationships between serum inflammatory profiles, body fat, individual joint damage, and total Mankin score

Significant positive relations were calculated between body fat percentage and leptin, IL-1β, VEGF, IL-10, and IL-18 (r > 0.50, p ⩽ 0.05) across all animals. Shoulder joint Mankin scores were positively and significantly correlated with serum levels of IL-1α (r = 0.61, p = 0.010), MIP-1a (r = 0.55, p = 0.024), and VEGF (r = 0.65, p = 0.005). No significant correlations were observed between hip joint Mankin scores and knee joint Mankin scores. While body fat was not significantly correlated with any of the individual joint Mankin scores, body fat was significantly positively correlated with the sum of knee and shoulder Mankin score (r = 0.50, p = 0.049) and total Mankin score for all three joints (r = 0.58, p = 0.018). Additionally, using logistic regression modelling, significant predictive relationships for total Mankin scores were calculated between body fat and IL-1α, and between body fat and VEGF (Table II).

Table II.

Summary of outputs from linear regression modelling estimating total Mankin scores across all animals: diet-induced obesity (DIO) (n = 9) and chow-fed (n = 7). β-coefficients and predicted Modified Mankin scores for each model are presented as mean and 95% confidence interval (CI). R-squared (r2), F-statistics, standard error of the estimate, and p-value of the model are also provided

Factor 1 Factor 2 r2 β-coefficient F-statistic Standard error of the estimate p-value* Predicted total Mankin score mean (95% CI)
Body fat Serum IL-1α 0.49 7.37 6.35 3.42 0.012 32.7 (26.3 to 39.5)
Body fat Serum VEGF 0.45 8.08 5.22 3.32 0.022 32.7 (26.5 to 40.0)
Body fat Serum IL-1β 0.34 10.42 3.31 3.33 0.069 32.8 (26.7 to 40.0)
Body fat Serum leptin 0.31 8.49 2.96 3.56 0.087 32.7 (26.0 to 40.4)
  1. *

    Mann–Whitney U test

  1. Statistically significant

  1. IL-1α, interleukin 1 alpha; VEGF, vascular endothelial growth factor

Discussion

This study addresses important gaps in the literature and contributes a series of novel insights into the pathogenesis of metabolic OA-like joint damage across three synovial joints: the shoulder, hip, and knee. The key finding from these data is that a HFS diet, in the absence of trauma, resulted in increased OA-like changes in the shoulder and knee joints of rats after a standard 12-week obesity induction period, which is concordant with previous work in knee joints in this model system.6,7 These data suggest that metabolic disturbance, in the absence of trauma, may also define a unique pathophysiological trajectory for shoulder OA. Hip joint damage, however, was not significantly affected by DIO, concordant with unclear or absent cross-sectional relationships often reported between metabolic disturbance and hip OA.1,12,13,30 Importantly, our findings echo previous joint-specific relationships for metabolic dysfunction in knees and shoulders, and an absence of pathology in hips of OA patients.1,12,13,30 Furthermore, preliminary odds ratio analysis revealed that DIO increased the odds of higher damage across all three joints. There is also evidence in the literature for a stronger link between metabolic dysfunction and OA pathology in women compared with in men, and future work will aim to understand better the role of gender in the joint-specific pathogenesis of metabolic OA in this model system.1

It may be that the shoulder, knee, and hip progress to overt damage with different timelines, and thus, perhaps an effect of DIO on hip joint integrity would be observed if given more time on the HFS diet. This speculation is supported by reports that weight gain > 20 kg in early and middle adulthood is associated with increased severe hip OA later in life.26 Previously, an increase in Mankin scores for the knee was observed after 28 weeks compared with 12 weeks on the HFS diet, suggesting that prolonged exposure to HFS results in increased knee joint damage, and overrides potential protective mechanisms due to obesity resistance.6 The hip joint may be intrinsically more resistant to developing OA-like pathology with diet for, as yet, unknown reasons, underscored by previous reports of no significant link between BMI and hip OA.31,32 Although some epidemiological studies demonstrate increased risk for hip OA among individuals with obesity, the odds ratio for hip OA in individuals with previous hip injury is substantially higher than that of obesity (4.3 vs 1.7).33 Taken together, these data potentially implicate other factors (i.e. post-traumatic, developmental, genetic/epigenetic variables, prolonged exposure to obesity or metabolic disturbance) for the origins or risk for pathogenesis leading to hip joint damage.

Obesity-related chronic inflammation likely results from metabolic disturbance, and has previously been described in this animal model.6-8,34 The associations between total Mankin score and body fat suggest that fat-related low-level inflammation may play an influential role in the development of pathogenesis leading to multi-joint damage. This hypothesis is supported by the significant predictive relationships between serum markers and body fat with total Mankin scores, which reveals that systemic inflammation may be involved in the cumulative multi-joint damage observed here. Links between synovial fluid IL-1α and serum VEGF and Modified Mankin knee score have been previously reported in this animal model.6,8 It is unclear if these low-level systemic mediators are a cause or a consequence of the cumulative pathology observed here, but future studies will aim to clarify the relationships between these markers (i.e. IL-1α, VEGF) and joint-specific changes with HFS. Although a significant positive relationship was not observed with knee joint damage and body fat or any individual systemic mediator, such significant associations and predictive relationships have been reported previously with exposure to HFS over 12 weeks in a different cohort of animals.6-8 The present study demonstrated a tighter clustering in body fat in animals from the present study compared with previous studies.6-8 This narrow range of body fat percentages may contribute to the lack of distinct relationships between Modified Mankin scores for each joint and body fat, and the more modest differences in inflammatory mediators in this study compared with what has been previously reported at this timepoint.6

In symptomatic OA, shoulder pain predicts knee pain, suggesting that a pathophysiological link may exist between the multi-joint arthritis of these two synovial joints.15 The link between knee and shoulder pain with OA is proposed to be mediated by functional muscle weakness,15 implicating a role for skeletal muscle in metabolic OA of different synovial joints. Compromised vastus lateralis (VL) muscle integrity is associated with significant increases in knee Modified Mankin score in this model system35. It is possible that upper limb muscles with similar muscle fibre type to the VL could contribute to the shoulder joint damage observed here, as these and other data have fuelled a hypothesis regarding the central role of muscle in obesity-related musculoskeletal disease.36 Many rotator cuff muscles are of mixed fibre type,37 similar to the VL, suggesting that the muscles of the rotator cuff could be vulnerable with metabolic dysfunction. Fat infiltration in the teres minor muscle before surgery is associated with poorer outcomes (i.e. positioning, pain) after shoulder arthroplasty.38,39 These findings implicate a role for muscle in the pathophysiology of shoulder OA, but this hypothesis remains to be tested, especially in the context of metabolic shoulder OA.40

This study has limitations that should be addressed. The cross-sectional nature of these data does not allow for us to evaluate if the hip is resistant to damage with DIO, or whether damage to the hip occurs at a slower rate compared with the shoulder and knee joints. Longitudinal studies with multiple timepoints are needed to validate the proposed relationships observed here. Also, by design, this is a descriptive study and, as such, a mechanism is not defined based on the present data. Ongoing efforts aim to develop protocols for synovial fluid collection in the shoulder and hip joints to quantify the effects of diet on local inflammatory environments within each joint. Given the minimal number of animals used, the preliminary odds ratios presented here demonstrate wide 95% CIs. Future studies will consider an analysis of DIO animals that are prone or resistant to damage within the broader DIO group. Investigating the genetic underpinnings of the DIO,41 the role of inflammatory cell activation, and comparative synovial fluid constituents from multiple joints of DIO animals are also exciting areas for future evaluation.

In conclusion, this study demonstrates relations between diet, shoulder, hip, and knee joint damage and serum biomarkers of inflammation, providing important information from which a mechanism of joint damage with DIO can be approached. The pre-clinical findings in the shoulder and knee joint echo previous joint-specific relationships for metabolic dysfunction in knees and shoulders, and an absence of pathology in hips of OA patients. This work represents a pioneering effort in understanding the relationship between the development of pathology in different synovial joints with metabolic disturbance.


W. Herzog; email:
Author Contributions

K. H. Collins: Designing the study, Collecting, analyzing, and interpreting the data, Drafting, revising, and approving the manuscript.

D. A. Hart: Designing the study, Analyzing and interpreting the data, Drafting, revising, and approving the manuscript.

R. A. Seerattan: Designing the study, Collecting, analyzing, and interpreting the data, Providing adiministrative, technical, and logistical support, Approving the manuscript.

R. A. Reimer : Designing the study, Analyzing and interpreting the data, Revising and approving the manuscript.

W. Herzog: Obtaining funding, Designing the study, Provision of study materials, Analyzing and interpreting the data, Revising and approving the manuscript.


Open access

This is an open-access article distributed under the terms of the Creative Commons Attributions licence (CC-BY-NC), which permits unrestricted use, distribution, and reproduction in any medium, but not for commercial gain, provided the original author and source are credited.

The authors thank Carolyn Hewitt for technical contributions to these studies.

  • Funding Statement

    This work was supported by the Canadian Institutes of Health Research RT736475 and MOP 115076, the Canada Research Chair Programme, the Alberta Innovates Health Solutions Osteoarthritis Team Grant, Alberta Innovates Health Solutions, Alberta Health Services, Canadian Institutes of Health Research Banting and Best Canada Graduate Scholarship, and the Killam Foundation.

    The funding sources listed here had no role in the planning, execution, analysis, or presentation of this study.

  • Conflicts of Interest Statement

    None declared

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    Follow K. H. Collins @KelseyHCollins

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