Greater glycosaminoglycan content in human patellar tendon biopsies is associated with more pain and a lower VISA score.

BACKGROUND: People with patellar tendinopathy experience chronic pain and activity limitation, but a pertinent biochemical marker correlated with these clinical features has not been identified. The Victoria Institute of Sport Assessment (VISA) questionnaire is a condition-specific patient-rated outcome measure. Since the quantity of glycosaminoglycans (GAGs) increases with advancing tendon pathology, we hypothesised that there would be a correlation between the quantity of GAGs in the patellar tendon and the VISA score. METHODS: Tissue biopsies from athletes with chronic patellar tendinopathy (confirmed by clinical examination and MRI) were recruited (n=7), as well as controls with no history of knee pain (n=4). The quantity of sulphated GAGs in the human patellar tendons was determined with a dimethyl methylene blue (DMMB) assay; this method was first validated with rat tendon tissue. The extent and distribution of GAG species and proteoglycans (decorin, versican and aggrecan) in the human tendon biopsies were examined using immunohistochemistry. RESULTS: Greater sulphated GAG content of the patellar tendon was correlated with the greater tendon dysfunction (R(2)=0.798). The quantity of aggrecan in the tendon, a chondroitin sulphate-rich proteoglycan, also increased with advancing tendon pathology. CONCLUSIONS: Increased GAGs in the pathological human patellar tendon are related to a worse clinical status. These findings indicate that the VISA score reflects the extent of tendon tissue pathology.

Early events of overused supraspinatus tendons involve matrix metalloproteinases and EMMPRIN/CD147 in the absence of inflammation.

BACKGROUND: The principal feature of tendon degeneration is structural change of the extracellular matrix (ECM) including collagens. In painful tendons, alterations of matrix metalloproteinases (MMPs) and tissue inhibitors of metalloproteinases (TIMPs) have been described; however, the initial molecular mechanism at the origin of these alterations is still poorly understood. A rat model of supraspinatus tendon overuse has been developed, which may be predictive of pathological tendon alterations. PURPOSE: To determine which MMPs are involved in early ECM remodeling during overuse and their relationship with the inflammatory context. STUDY DESIGN: Controlled laboratory study. METHODS: Analyses were performed on rat supraspinatus tendons at 2 and 4 weeks of overuse on a downhill treadmill. Transcript levels of MMPs and TIMPs were assessed by semiquantitative reverse transcription polymerase chain reaction. Western blotting and/or immunolabeling were used for MMP-2, MMP-3, MMP-13, and extracellular MMP inducer (EMMPRIN, also called cluster of differentiation [CD] 147) detection. In situ and/or sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) gelatin zymography was performed for MMP-2 and MMP-9. TIMP activity was revealed by reverse zymography. Inflammation was assessed by cytokine antibody array and/or immunolabeling. RESULTS: Compared with a control, overused supraspinatus tendons showed a significantly higher gelatinolytic activity at 2 weeks, which slightly decreased at 4 weeks. MMP-9 and MMP-13 were undetectable; MMP-3 was downregulated in overused tendons. Only MMP-2, particularly its active form, and the MMP-2 activator MMP-14 were upregulated at 2 weeks of overuse when an increase in TIMP-2 transcripts was observed. MMP-2 upregulation occurred in the absence of inflammation but was associated with an increase of EMMPRIN/CD147. CONCLUSION: EMMPRIN/CD147-regulated MMP-2 and MMP-14, associated with low MMP-3, appear as the main characteristics of ECM remodeling in early overused tendons. Whether alterations in the pattern of these MMPs are an adaptive response or a repair response that may degenerate into tendinosis, is still uncertain. Moreover, there seems to be no indication for an inflammatory response to overuse, suggesting that the increased metalloproteinase activity is rather a response to a mechanical stress than an inflammatory one. CLINICAL RELEVANCE: Any strategy aimed at preventing full-thickness tears resulting from initial tendon matrix alterations should consider these changes in MMP-3, MMP-2, and MMP-14, or further upstream, EMMPRIN.

Alterations of overused supraspinatus tendon: a possible role of glycosaminoglycans and HARP/pleiotrophin in early tendon pathology.

Supraspinatus tendon overuse injuries lead to significant pain and disability in athletes and workers. Despite the prevalence and high social cost of these injuries, the early pathological events are not well known. We analyzed the potential relation between glycosaminoglycan (GAG) composition and phenotypic cellular alteration using a rat model of rotator cuff overuse. Total sulfated GAGs increased after 4 weeks of overuse and remained elevated up to 16 weeks. GAG accumulation was preceded by up-regulation of decorin, versican, and aggrecan proteoglycans (PGs) mRNAs and proteins and biglycan PG mRNA after 2 weeks. At 2 weeks, collagen 1 transcript decreased whereas mRNAs for collagen 2, collagen 3, collagen 6, and the transcription factor Sox9 were increased. Protein levels of heparin affine regulatory peptide (HARP)/pleiotrophin, a cytokine known to regulate developmental chondrocyte formation, were enhanced especially at 4 weeks, without up-regulation of HARP/pleiotrophin mRNA. Further results suggest that the increased GAGs present in early lesions may sequester HARP/pleiotrophin, which could contribute to a loss of tenocyte's phenotype. All these modifications are characteristic of a shift towards the chondrocyte phenotype. Identification of these early changes in the extra-cellular matrix may help to prevent the progression of the pathology to more disabling, degenerative alterations.

Classification and pathogenic models of unintentional postural cranial deformities in infants: plagiocephalies and brachycephalies.

Unintentional postural deformities of the skull have increased in a pseudoepidemic manner in the last 15 years. Although dorsal decubitus and prenatal risk factors can play a role in the genesis of such deformities, we think that a crucial determinant is a postnatal defect of cervical mobility responsible for the infant's posture (ie, positional preference) when supine. Indeed, muscular factors, which limit the range of head and neck movements, have been underestimated in the genesis of skull deformities. Here, we have retrospectively analyzed data from 181 infants with unintentional skull deformities and propose a classification of these deformities into 3 types based on their pathogenic model and clinical appearance: fronto-occipital plagiocephalies due to severe muscle hypertonia in which the myogenic component is the first implicated, occipital plagiocephalies with muscle imbalance due to neurogenic muscle hypertonia, and posterior brachycephalies with neurogenic muscle hypertonia of the suboccipital muscles due to trauma to the occipitovertebral junction. Future studies on the size and density of specific muscles or group of muscles should help us to better understand their involvement in the pathogenesis of postural deformities. Our findings also highlight the importance of carefully assessing cervical mobility during the first week of life to detect possible limitations and to prescribe (if needed) an adapted rehabilitation. Rehabilitation should be associated with postural measures put in place when infants sleep supine to prevent the appearance of skull deformations.