INTRODUCTION. In order to address high failure rates following rotator cuff repairs, a greater understanding is required of the underlying structural changes so that treatments can be appropriately targeted and biomarkers of failure can be identified. As collagen is the primary constituent of tendon and determines force transmission, collagen structural changes may affect responses to loading. For example changes in collagen 1 and 5 are associated with the hyperelastic Ehlers-Danlos syndrome, which is diagnosed by looking for pathopneumonic altered collagen fibres or ‘collagen flowers’ in skin using transmission electron microscopy (TEM). To date no study has been performed on the microstructure of torn human rotator cuff tendons using TEM. It was hypothesized that normal, small and massive human rotator cuff tendons tears will have altered microscopic structures. The unique study aimed to use TEM to compare the ultrastructure of small and massive rotator cuff tears, to normal rotator cuff tendons. METHODS. Samples from 7 human rotator cuff tendons repairs were obtained, including 4 massive (>5 cm) and 3 small (< 1 cm) tears, and 3 matched normal controls with no history of connective tissue disorders. Specimens were fixed in 4% glutaraldehyde in 0.1M phosphate buffer, processed and examined blind using routine TEM examination. To assess whether changes in the relative expression of collagen 1 and 5 (COL1A1, COL5A1 and COL5A2) occurred in all tears, qPCR was performed on another 6 phenotypically matched patients. RESULTS. The basic structure of the normal tendon consisted of tightly packed clumps of dense packed parallel running collagen fibers with few fibroblasts and small amounts of fine filamentous material between clumps. In contrast, torn samples were more variable with areas of less dense packing of collagen fibers and larger areas of filamentous material plus variable numbers of lipid droplets both within the fibroblast and between the collagen bundles. There was also evidence of twisting and random orientation of individual collagen fibers. All torn tendons showed evidence of a proportion of the fibers within the collagen bundles being enlarged with a serrated outline, similar in appearance to ‘collagen flowers’. Clear differences between the small and massive tears were not identified. qRT-PCR of torn rotator cuff tendon specimens demonstrated no altered collagen expression compared to normal tendons. DISCUSSION. This novel study has identified the previously unreported presence of atypical collagen fibers with focal swelling resulting in the appearance of ‘collagen flowers’ in torn rotator cuff tendons only. This appearance is considered pathognomonic of Ehlers-Danlos syndrome, classical type 1 and 2. Torn tendons also showed an increase in filamentous material, and infiltration with fat droplets. These novel findings may offer insight into the mechanisms of structural damage that contribute to rotator cuff failure. Further examination is required, to evaluate the significance of these observations

Introduction. The pathophysiology of high failure rates following rotator cuff tendon repairs, particularly massive tears, is not fully understood. Collagen structural changes have been shown to alter tendon thermal and mechanical properties. Thermal changes in small biopsies, detected by differential scanning calorimetry (DSC) can help to quantify collagen structural differences in torn rotator cuff tendons. This study aimed to form a quantitative rather than qualitative assessment, of whether differences in collagen structure and integrity existed between small biopsies of normal, small and massive rotator cuff tears using DSC. Methods. Thermal properties were measured for 27 human biopsies taken intra-operatively from normal, small, and massive rotator cuff tendon tears. 3 samples were taken from each patient and subjected to a modulated temperature ramp between 20–80°C at a rate of 2°C per minute with 0.318°C amplitude. The melting temperature (TM) is proposed to represent amide-amide hydrogen bond breakage and resulting protein backbone mobility. Denaturing temperature (TD) reportedly corresponds to the temperature at which the proteins fall out of solution. Denaturation enthalpy (H) should correlate with the amount of triple helical structure. Based upon a pre-study power calculation, this study had 90% power to detect a 10% difference in melting and denaturation temperature between groups with alpha=0.05. 1 specimen per patients was also frozen and cryosectioned and polarised light microscopy was used for quantitative validation. The effect of tear size on heat related parameters were performed using a one-way ANOVA test. A student's unpaired t-test was used to search for differences between individual groups (small tears, massive tears and normal tendons). Results. Small and massive rotator cuff tears had significantly higher melting temperature (TM), and denaturation enthalpy (H) compared to controls. The denaturing temperature (TD) was higher in the massive tears only compared to normal tears. No difference was detected between small and massive tears. Histology of massive tendon tears confirmed greater collagen structural disruption compared to small tears and controls. Conclusion. These novel findings suggest greater quantifiable collagen structural disruption in rotator cuff tears, compared to controls. A decrease in important thermal properties of torn tendons suggests that the material is intrinsically less stable. It is likely that torn tendons cannot withstand changes in temperature or stress as well as a perfect material could, particularly for massive tears which are more amenable to denaturation. This study offers insight into possible mechanisms for, or adaptation to, failure in tears and reduced strength

INTRODUCTION. There is increasing evidence for a multi-stage model of rotator cuff (RC) tendon tears, wherein healing is affected by tear size. The underlying pathophysiology however is not fully understood. Changes in the production and remodeling of the RC extracellular matrix (ECM) are likely to be important determinants of RC tendinopathy as they affect healing and the ability to bear loads. This study aimed to gain greater insight into size related tear pathogenesis by analyzing gene expression profiles from normal, small and massive RC tears. METHODS. The genetic profiles of 28 human RC tendons were analyzed using microarrays representing the entire genome. 11 massive and 5 small torn RC tendon specimens were obtained from tear edges intraoperatively, and compared to 12 age matched normal controls. Semiquantitative real-time polymerase chain reaction (RT-PCR) and immunohistochemistry were performed for validation. RESULTS. Numerous insightful gene changes were detected. Key changes included upregulation of aggrecan in massive tendon tears compared to normal controls, but not in small tears (p < 0.05 and > 2-fold change). Matrix metallopeptidases (MMP)-3,-10,-12,-13,-15,-21,-25 and a disintegrin and metallopeptidase (ADAMs)-12,-15,-22 were significantly upregulated in tears. Aggrecan was upregulated in massive tendon tears but not in small tears. Amyloid was downregulated in the small and massive tear groups when compared to normals. BMP-5 was upregulated in small tears only when compared to normals. As part of the chemotaxis pathway, IL-3,-10,-13,-15,-18 were upregulated in tears, whereas downregulation of IL-1,-8,-11,-27, was seen. RT-PCR and immunohistochemistry confirmed altered gene expression. CONCLUSION. The gene profiles of normal, small and massive RC tear groups suggested they are biologically distinct groups. In addition to confirming altered gene expression in pathways reported in previous studies, this study has identified a number of novel pathways which are affected between the different tendon tear and normal groups. This study identified that RC tear pathogenesis is contributed to by ECM remodeling genes, chemotaxis genes, aggrecan and amyloid. Further investigation is required to determine whether some of these genes may potentially have a role as biomarkers of failure. Modulating these ECM pathways may be a useful treatment strategy for improving clinical outcomes

Aims

In order to determine whether and for whom serial radiological evaluation is necessary in one-part proximal humerus fractures, we set out to describe the clinical history and predictors of secondary displacement in patients sustaining these injuries.