Introduction

Metabolic disorders are among known risk factors for tendinopathies or spontaneous tendon ruptures. However, the underlying cellular and molecular mechanisms remain unclear. We have previously shown that human and rat tendon cells produce and secrete insulin upon glucose stimulation. Therefore, we hypothesize that nutritional glucose uptake affects tendon healing in a rat model.

Materials and Methods

Unilateral full-thickness Achilles tendon defects were created in 60 female rats. Animals were randomly assigned to three groups receiving different diets for 2 weeks (high glucose diet, low glucose/high fat diet, control diet). Gait analysis was performed at three time points (n=20/group). In addition, tendon thickness, biomechanical (n=14/group), and histological and immunohistochemical analysis was conducted. Subsequently, a subtractive-suppression-hybridization (SSH) screen comparing cDNA pools (n=5) prepared from repair tissues of the high glucose and the control diet group was conducted to identify differentially expressed genes.

Introduction

Tendon disease and rupture are common in patients with diabetes and these are exacerbated by poor healing. although nanoscale changes in diabetic tendon are linked to increased strength and stiffness. The resistance to mechanical damage of a tissue may be measured using fatigue testing but this has not been carried out in diabetic tendon, although the toughness of diabetic bone is known to be reduced. The aim of this study was to measure the static fatigue behaviour of tendons from a streptozotocin (STZ)-induced rat model of diabetes, hypothesising that diabetes causes tendon to show lower resistance to mechanical damage than healthy tendon.

Materials and Methods

Diabetic (n=3, 12 weeks post-STZ) and age-matched control (n=3) adult male Sprague Dawley rats were culled, tails harvested and stored at −80ºC. Following defrosting, fascicles (5 per animal) were carefully dissected, mean diameter measured using an optical micrometer and mounted in a Bose Biodynamics test machine using custom grips in a PBS bath. Static fatigue testing at 30 MPa to failure enabled both elastic modulus (initial ramp) and steady state creep rate (gradient at creep curve inflexion) to be measured. Data are reported as median ± interquartile range and pw0.05 using a Mann-Whitney U test was taken as significant.

Introduction

Tendinopathies are among the most common musculoskeletal injuries. Nowadays, part of its diagnosis is established through subjective qualitative evaluation of 2D ultrasound (US). This enables limited diagnostic differentiation or therapeutic optimization and has limited added value to diagnosis in an earlier stage. It is generally accepted that extra diagnostic information can be obtained via strain evaluation. The accurate validation of strain estimation is challenging due to the lack of a ground-truth. Therefore we evaluate the repeatability of displacement and strain estimations in the longitudinal direction, using an easy, fast and interactive application to estimate local strain during dynamic loading of the tendon.

Materials and Methods

One healthy volunteer laid in a prone position with the foot fixed to an isokinetic device. Three sets of passive movement between −10° plantarflexion and +10° dorsiflexion were performed and repeated the following day. During this, US images with a spatial resolution of 0.02mm × 0.09mm were acquired at a frame-rate of 100Hz. The US system used was the Vevo2100 with a MS250 linear array transducer with a center frequency of 20MHz. After image collection, consecutive pairs of 2D images were registered in a multi-resolution scheme, using an affine and b-spline transformation optimized by the minimization of the sum-of-squared differences, to obtain deformation vector fields. Lastly the interactive application allows local analysis of tissue displacement and strain within selected regions of interest. Mean and standard deviation of the intra- and inter-day relative differences were calculated.

Introduction

Numerous risk factors have been identified for patellar tendinopathy (PT), often in small population studies. The aim was to use an online questionnaire internationally to generate a large database and identify significant risk factors.

Materials and Methods

Subjects were recruited from England, Spain and Italy with the questionnaire available in all three languages, with the questionnaire previously having been validated by Morton et al. (2014) as to be suitable for self-administration. The questionnaire can be viewed at: http://patellartendinopathyquestionnaire.blogspot.co.uk/ (English), http://tendinopatiarotuliana.blogspot.co.uk/ (Spanish) and http://tendinopatiarotulea.blogspot.co.uk/ (Italian). All data was anonymised and password protected. 825 data sets were collected with 23.4% having clinically diagnosed PT.

Introduction

The healing of Achilles tendon rupture is slow and jogging is usually allowed already 6 months after injury. However, the metabolic status of the healing tendon is largely unknown at the time-points when increased loading is allowed. The purpose of this study was to investigate tendon metabolic response and blood flow at 3, 6 and 12 months after Achilles tendon rupture by positron emission tomography (PET) and ultrasound-Power Doppler (UPD).

Materials and Methods

23 patients that had surgical repair of a total Achilles tendon rupture (3 (n=7), 6 (n=7) or 12 (n=9) months earlier) participated in the study. The triceps surae complex was loaded during 20 min of slow treadmill walking. A radioactive tracer (FDG) was administered during this walking and glucose uptake was measured bilaterally by the use of PET. Blood flow was recorded by UPD and patient reported outcome scored by Achilles tendon rupture score (ATRS) and VISA-A. Non-parametric statistics were used for statistical analysis.

Introduction

Skeletal abnormalities caused by disproportioned bone overgrowth (LBO), are a common trait in Marfan syndrome (MFS), a connective tissue disease caused by mutations in the extracellular matrix (ECM) protein and TGFβ regulator fibrillin-1 (Fbn1). The cause of LBO in MFS is unknown and therapies are not available. Fibrillin-1 hypomorphic mouse model (Fbn1mgR/mgR) faithfully replicates MFS skeletal manifestations including elongated bones however, its early demise due aortic rupture limit the magnitude of LBO investigation.

Materials and Methods

To circumvent Fbn1mgR/mgR lethality and investigate the contribution of specific skeletal tissues to LBO, Fbn1 gene expression was targeted in developing limbs by crossing Fbn1Lox/Lox mice with Prx1-Cre, in or bone with Osx-Cre, in cartilage and perichondrium with Col2-Cre, in skeletal muscles with Mef2c-Cre, and ligaments and tendons with Scx-Cre. Bones length of Fbn1 conditional mice KO was measured and relevant histological, cellular and biomechanical parameters were assessed.

Introduction

Tendon cells originate from yet poorly described precursor cells and develop in a particular “niche” close to vascular walls. Several factors have been described to determine this niche such as mechanical stimuli, oxygen tension, composition and structure of the extracellular matrix (ECM). Also, the vasculature is considered to play a crucial role for tendon cell development, yet evidence of how this is accomplished is lacking. In this study we therefore focussed on the endothelium of tendon vessels postulating the existence of a paracellular barrier.

Materials and Methods

By electron microscopy, immunohistochemistry, and RT-PCR we investigated the presence of constituents making up such an endothelial barrier which we subsequently tested for its functionality by tracer injection. Moreover, we performed differentiation experiments into the adipogenic, chondrogenic and osteogenic lineage on tendon derived cells in the presence and absence of serum. Expression levels and activity of matrixmetalloproteinases (MMPs) were assessed by western blot and zymography.

Introduction

The two-dimensional (2D) monolayer culture paradigm has limited translational potential to physiological systems; chondrocytes and tenocytes in monolayer lose expression of hallmarks of differentiated status (dedifferentiation). Qualitative assessment of three-dimensional (3D) cultures in musculoskeletal biology relative to native tissues has been limited. An understanding of prevailing gene regulatory networks is required to define whether 3D culture systems faithfully restitute the native tissue phenotype (redifferentiation). Using a systems biology approach to explore the gene networks associated with de- and re-differentiation may define targetable regulators associated with phenotypic plasticity of adult musculoskeletal cells.

Materials and Methods

Global transcriptomic and proteomic profiling of matrix-depleted chondrocytes and tenocytes from the rat was performed for each of three conditions (native tissue, monolayer at passage three, or tissue-appropriate 3D cultures). Differential analysis of mRNA and protein abundance, gene ontology annotation, pathway topology impact analysis, and derivation of common mechanistic networks was undertaken to define consensus expression profiles, signalling pathways, and upstream regulators for de- and re-differentiation in each cell type.

Introduction

The hierarchical structure of tendon results in a complex mechanical strain environment, with tenocytes experiencing both tension and shear during loading. The mechanotransduction mechanisms involved in sensing these environments is currently unclear. To better understand the effects of shear and tension on cell behaviour, a fibre composite system able to recapitulate the physiological shear-tension ratio found in tendons, was used. Cell attachment within the composite was achieved by using either a collagen type I mimetic peptide, DGEA, or a fibronectin associated peptide, YRGDS, and the gene expression response analysed after loading.

Materials and Methods

Fibre composites with 4 different shear-tension (S-T) ratios were made using both PEG-DGEA and PEG-YRGDS fibres. 4 composites were made for each S-T ratio, of which 2 were loaded and 2 used as non-strained controls. Bovine digital extensor tendon tenocytes were seeded within composites, with 3 biological repeats from different donors. Loaded samples were exposed to 5% cyclic strain (1Hz) for 24 hours maintained in an incubator. The gene expression of 14 matrix related genes were analysed after loading via RT-qPCR.

Introduction

The COL5A1 gene encodes for the α1 chain of type V collagen, a minor fibrillar collagen that is an important regulator of collagen fibrillogenesis. Several polymorphisms, including rs12722 (C/T), within the 3′-UTR of COL5A1 are associated with chronic Achilles tendinopathy and other musculoskeletal soft tissue injuries as well as exercise-related phenotypes. It is hypothesised that polymorphisms within the 3′-UTR regulate the amount of the α1(V) chain synthesised and type V collagen production. This in turn influencing the mechanical properties of tendons and other musculoskeletal soft tissues. In our laboratories, two major functional forms, namely the T- and C-allelic forms of the COL5A1 3′-UTR, were identified and associated predominately with severe chronic Achilles tendinopathy and healthy asymptomatic control individuals, respectively.

Materials and Methods

To further investigate the functional differences between the two major 3′-UTR functional forms as well as to start mapping the regions which are responsible for the tendinopathic phenotype, skin biopsies from donors having a known genotype at rs12722 and primary fibroblast cell lines were established in order to quantify COL5A1 and COL1A1 expression levels in a pilot study. Lastly, in preliminary RNA EMSAs, biotinylated C- and T-allelic RNA probes for a specific 57bp functional region within the 3′-UTR were incubated with either fibroblast nuclear or cytoplasmic protein extracts to investigate putative distinguishing RNA:RBP complex formation.

Introduction

Adult tendon injuries occur very frequently, but injured tendon heals very slowly and the mechanisms of the slow-healing response to injury are still largely unknown. Currently, the main barrier is our insufficient understanding of the mechanisms responsible for homeostasis, regeneration and repair of adult tendon. This gap in knowledge translates to a lack of experimental models. Therefore, using the combination of state-of-the-art genetic approaches, we have established novel cell biological tools to advance the understanding of tendon biology.

Materials and Methods

Adult mouse tendon progenitor lines and Adult mouse tenocyte lines: Primary adult tenocytes were isolated from Achilles tendon in Scleraxis(fl/fl)/Scleraxis-GFP/p21(−/−) mice, then CD90.2- and subsequent Sca1-positive cells were sorted by Flow Cytometry. Then Scleraxis-null progenitor lines were generated by the treatment of those cells with adenovirus-Cre. Adult Scleraxis(+/+) and Scleraxis-null tenocyte lines were also generated from Scleraxis(fl/fl)/Scleraxis-GFP/p21(−/−) mice. To establish Scleraxis-Flag overexpressing tenocyte lines, Scleraxis and Flag-tag fusion-protein expression construct was generated and transfected into Scleraxis-null tenocytes (Scleraxis transgenic mouse strains were provided by Dr Ronen Schweitzer).

Scleraxis antibody: DNA coding mouse Scleraxis residues were obtained by PCR, then the recombinant protein was expressed, immunized in rabbits, and an affinity-purified antibody was generated.

Introduction

The exact mechanisms leading to tendinopathies and tendon ruptures remain poorly understood while their occurrence is clearly associated with exercise. Overloading is thought to be a major factor contributing to the development of tendon pathologies. However, as animal studies have shown, heavy loading alone won't cause tendinopathies. It has been speculated, that malfunctioning adaptation or healing processes might be involved, triggering tendon tissue degeneration. By analysing the expression of the entirety of degrading enzymes (degradome) in pathological and non-pathological, strained and non-strained tendon tissue, the aim of this study was to identify common or opposite patterns in gene regulation. This approach may generate new targets for future studies.

Materials and Methods

RNA was extracted from different tendon tissues: normal (n=7), tendinopathic (n=4) and ruptured (n=4) Achilles tendon; normal (n=4) and tendinopathic (n=4) posterior tibialis tendon; normal hamstrings tendon with or without subjection to static strain (n=4). The RNA was reverse transcribed, then pooled per group The expression of 538 protease genes was analysed using Taqman low-density array quantitative RT-PCR. To be considered relevant, changes had to be at least 4fold and measurable at a level below 36 Cts.

Introduction

We previously reported that disruption of TGFβ signaling in limb mesenchyme resulted in complete failure of tendon differentiation.

Materials and Methods

To bypass this early function and study additional roles of TGFβ signaling in tendon development we disrupted TGFβ signaling in tenocytes after they assumed the tendon cell fate by using the tendon deletor ScxCre to target the floxed type2 TGFβ receptor.

Introduction

Exercise increases tendon collagen synthesis and cross-link formation. Exercise also increases the expression of TGF-β₁. TGF-β₁ may contribute to the upregulation of tendon collagen synthesis during exercise, but this relationship has not been established in vivo. The purpose of this study was to evaluate the effects of TGF-β₁ receptor inhibition on tendon collagen.

Materials and Methods

Male Wistar rats were divided into sedentary (SED, n = 9) or exercised (RUN, n=15) groups. Exercised animals completed four days of treadmill exercise (60 minutes/days). The peritendinous space of one Achilles tendon was injected with LY-364947 (ALK5 inhibitor; INHIB) while the opposite leg was injected with a vehicle (SHAM). Injections were given daily after each exercise bout. ERK and Smad 2/3 phosphorylation was evaluated by Western blotting. Collagen I and III gene expression were evaluated via qRT-PCR. Tendon hydroxyproline and hydroxylyslpyridinoline (HP) cross-linking were assayed via HPLC. A longitudinal section of tendon was stained with H&E for evaluation of cell numbers and fibril organization.

Introduction

Tendons and ligaments (TLs) play key roles in the musculoskeletal system. However, they are commonly damaged due to age-related wear and tear or torn in traumatic/sport related incidents resulting in pain and immobility. TLs contain cells and extracellular matrix (ECM) comprised of collagen, elastin, glycoproteins and proteoglycans. Although TLs are composed of similar components, their precise composition and arrangement of matrix macromolecules differ to provide specific mechanical properties and functions. To date little is known about how the main ECM proteins are arranged between the two tissue types. This data will provide essential information on fundamental structure of TLs leading to increased understanding of the function relationship between these tissue types. The aim of this study was to compare tendon-ligament differences in their ECM distribution of collagens, proteoglycans and elastic fibres.

Materials and Methods

Anterior cruciate ligament (ACL) and long digital extensor tendon (LDET) were harvested from disease free cadaveric canine knee joints (n=3). Distributions of the main ECM components were assessed on longitudinal sections of ACL and LDET mid-substance. Antibody staining were assessed for collagen type I, III, VI, agreccan, versican, decorin, biglycan, elastin, fibrillin 1 and fibrillin 2.

Introduction

The rabbit common calcanean (Achilles) tendon is a compound apparatus frequently used in studies considering novel interventions to facilitate tendon regeneration. These studies often employ complete surgical transection of the apparatus. Due consideration of the translational relevance to human tendinopathy is often lacking and refinement of this injury model, consistent with the principles of the 3Rs, has not been forthcoming.

Materials and Methods

Wild rabbit cadavers (n=10) were obtained from a licensed game dealer. For gross anatomy studies the caudal crus was dissected and transverse sections obtained every 5 mm. Ultrasongraphic examination of the entire apparatus was peformed with a 15 Hz transducer in transverse sections.

Introduction

The equine SDFT tendon is a complex hierarchal structure that transmits force from muscle to bone and stores energy through its stretching and recoiling action. It is a common site of pathology in athletic horses. Our aim was to describe the ultrastructural anatomy of the SDFT as part of a larger programme to understand the structure-functional relationship of this tendon.

Materials and Methods

Fifteen SDFT from different aged horses, sectioned transversely (2–3 mm thickness) and then photographed using Canon EOS 5D Mark III (100 mm focal length). Images processed through ImageJ and IMOD software for 3D reconstruction.

Samples were also taken from the proximal, middle and distal part of the SDFT from a foetal, one and nine years old horse, processed for H&E staining and sectioned longitudinally in series into 20 sections (5µm), additionally the mid metacarpal region of one year old was fully sectioned into 250 sections. The entire cut surface on the slide was imaged and transformed to one collated image using Inkscape. Using IMOD collated photos transformed to mrc file (Z-stack) and in order to reconstruct 3D forms.

Introduction

Traditionally Plantaris has been considered of little clinical importance and absent in 8–20% of the population. Recent evidence indicates that it is present in 98–100% of the population and that it may have a contributing role in Achilles tendinopathy due to its close anatomical relationship.

The aim of this study was to establish whether Plantaris was present in a sample of cadaveric limbs, to establish its position in relation to the Achilles tendon and to conduct measures of its thickness and width.

Materials and Methods

Forty eight cadaveric limbs which had been previously dissected were assessed. Plantaris was looked for in the region of the medial Achilles. If it could not be identified here, Gastrocnemius was reflected back to reveal Plantaris tendon beneath, and was then followed distally. All Plantaris tendon measurements were taken 2- 6 cm from the Achilles insertion using a vernier caliper.

Introduction

Energy storing tendons such as the equine superficial digital flexor tendon (SDFT) stretch and recoil with each stride and therefore require a high degree of compliance compared to tendons with a purely positional function, such as the equine common digital extensor tendon (CDET). This extra extensibility is provided by a specialised interfascicular matrix (IFM), which provides greater sliding and recoil between adjacent fascicles in energy storing tendons. However, the composition of the IFM remains largely undefined. We hypothesised that the IFM in the SDFT has a distinct composition, with a greater abundance of proteoglycans and elastin which facilitate extension and recoil.

Materials and Methods

Transverse and longitudinal sections were cut from the mid-metacarpal regions of SDFTs and CDETs from 5 horses aged 3–7 years. Sections were stained using Alcian blue/Periodic acid Schiff to detect proteoglycans, elastic Van Giesson's to detect elastin, and immunohistochemistry was performed using antibodies for decorin, biglycan, fibromodulin, lumican and lubricin. Resultant images were graded by blinded observers to assess staining intensity in the IFM and fascicular matrix (FM), and statistical significance determined using ANOVA.

Introduction

The ability of tendons to withstand stress generally decreases with age, often resulting in increased tissue degeneration and decreased regeneration capacity. However, the underlying molecular and cellular mechanisms of tendon senescence remain poorly characterized. Therefore, the aim of the current study was to identify genes showing an age-dependent altered expression profile in tendons.

Materials and Methods

A suppression-subtractive-hybridization (SSH) screen comparing cDNA libraries generated from Achilles tendons of mature-adult (3 months) and old (18 months) female C57BL/6 mice was conducted. Subsequently, the differential expression of the identified genes was validated by RT-qPCR and selected genes were then further analysed by immunohistochemistry and Western blot. To investigate age-related structural alterations in the collagenous extracellular matrix we applied SHG-microscopy and TEM. In vitro experiments with young and old tendon derived stem/progenitor cells (TDSCs) involved wounding assays, tendon-like constructs as well as collagen gel contraction assays.

Introduction

Tendons are critical to mobility, and are susceptible to degeneration through injury and ageing. Type I collagen is the most abundant protein in vertebrates; it is the main structural protein of the extracellular matrix in numerous musculoskeletal tissues, including tendons. Type I collagen predominantly is a heterotrimer, which consists of two alpha-1 chains and one alpha-2 chain (α1)₂(α2) encoded by the COL1A1 and COL1A2 genes, respectively. However, type I collagen can form homotrimers (α1)₃ which are protease-resistant, and are associated with age-related musculoskeletal diseases, fibrotic and connective tissue pathologies. Transforming growth factor beta (TGFβ) enhances collagen (I) gene expression, is involved in tendon mechanobiology and repair processes, while its effect on homotrimer formation is unknown. Our aim is to investigate the relative expressions of collagen (I) α1 and α2 polypeptide chains in tenocytes (tendon fibroblasts) stimulated with TGFβ.

Materials and Methods

Included RT-qPCR to measure the relative expression of COL1A1 and COL1A2 genes. [¹⁴C]-proline metabolic labelling was used to measure the expression of the collagen (I) α1 and α2 polypeptide chains. These techniques were performed in equine superficial digital flexor tendon (SDFT) tenocytes (n=3) and murine tail tendon tenocytes (n=3) with different concentrations of TGFβ (0.01 ng/ml-100 ng/ml).

Introduction

Tendon healing begins with inflammation and results in an incomplete repair with fibrosis, culminating in tendon pathology along with tissue degeneration. Inflammatory mediators regulate the expression of growth factors, and members of the TGFβ superfamily including BMPs have been suggested to play a key role in the development of fibrosis. In established tendon diseases where inflammation and reparative processes persists, the cellular phenotype of tendon cells has been implied to undergo a transformation from that of normal tissue. This study investigates the inflammation-driven mechanisms of tendon pathology using an in vitro tendon cell model. We hypothesized that cells from diseased tendons will exhibit dysregulation of TGFβ superfamily members in response to inflammatory mediators when compared to cells derived from healthy tendons.

Materials and Methods

Diseased human tendon cells were isolated from patients with large to massive rotator cuff tears (n=4). Cells isolated from healthy human hamstring tendons served as control tissue (n=5). Cells were treated with human recombinant IL-1β (5ng/ml), oncostatin M (10ng/ml), IL-6 (10ng/ml), IL-10 (10ng/ml) in serum-free medium, or serum-free medium alone (control) for 24 hours. Cell viability was monitored by Alamar Blue assay, and expression of TGFB1, TGFBR1, TGFBR2, CTGF, BMP2 and BMP7 were quantified by quantitative reverse transcription polymerase chain reaction (RT-QPCR).

Introduction

Tendon is prone to degeneration through ageing and injury and current therapies are largely ineffective. The recent identification of a cell population within tendon with stem cell-like characteristics holds potential for regeneration of tendon. The local stem cell environment (niche) is important for stem cell maintenance and function. This study aims to characterize extracellular matrix (ECM) components of the stem cell niche in equine tendon, which is prone to age-related degeneration and rupture.

Materials and Methods

Putative tendon stem cells (TSCs) were isolated from equine superficial digital flexor tendon by low-density plating and differential adhesion to fibronectin. Cells were analysed by flow cytometry using antibodies to mesenchymal stem cell markers, as well as qRT-PCR for stem cell and tenogenic markers. The multipotency of cells was assessed using tri-lineage differentiation assays. ECM components of the tenocyte and TSC niche were analysed using radio-isotope labelling, immunohistochemistry and histology.

Introduction

Obesity is one of risk factors of anterior cruciate ligament tear in man or cranial cruciate ligament (CCL) tear in dog. Adipokines are biologically active mediators released from adipocytes, and correlate with changes in body mass index. In order to study the possibility that adipocytes play a role in the pathogenesis of CCL disease, we investigated alterations of the matrix degradation biomarker genes (matrix metalloproteinase-13 [MMP-13], aggrecan) in CCL cells after stimulating with adipokines.

Materials and Methods

We collected CCLs from 6 dog cadavers that had been euthanased for reasons other than musculoskeletal disease. CCL cells were isolated and treated with key adipokines including of adiponectin, leptin and visfatin at different concentration (0.1 ng/mL, 1 ng/mL and 10 ng/mL), and at three different time points (1 h, 6 h and 24 h). Real-time PCR was used to determine gene expression for MMP-13 and aggrecan in CCL cells comparing with negative control. In addition, lipopolysaccharide was used as a positive control. The statistical significance of differences between groups was determined using non-parametric Friedman test, followed by the Conover post-hoc test, and data were considered statistically significant at P<0.05.

Introduction

Platelet Rich Plasma (PRP) is widely used in clinical praxis. Especially the effects in musculoskeletal repair studies are diverse and an augmentation of healing processes stays questionable. However, diverse cell culture studies reported promising results, which seem not be transferable into the clinical situation. We therefore performed a cell culture study which better reflects the clinical situation: the autologous stimulation of human tendon cells with PRP.

Materials and Methods

Human tenocyte-like cells (hTLCs) from 24 donors (12 male/female) with supraspinatus tendon tears were isolated and characterized. The donors were grouped into 4 groups according to their age (</> 65 years) and sex. During follow up, approximately 2.5 years after initial surgery, the patients donated blood for PRP preparation (Ethic vote and written informed consent). Growth factors and platelets were quantified and the effect of autologous stimulation of the hTLCs was measured by analysis of cell proliferation, Collagen I synthesis and expression of Collagen I, III and Osteocalcin.

Introduction

Tendinopathies are debilitating and painful conditions. They are believed to result from repetitive overuse, which can create micro-damage that accumulates over time, and initiates a catabolic cell response. The aetiology of tendinopathy remains poorly understood, therefore the ideal treatment remains unclear. However, current data support the use of eccentric exercise as an effective treatment. In a previous study, we have shown that eccentric loading generates perturbations in the tendon at 10Hz, which is not present during other less effective loading regimes. Consequently, we hypothesis that 10Hz loading initiates an increased anabolic response in tenocytes, that can promote tendon repair.

Materials and Methods

Human tenocytes from healthy hamstring tendons and tendinopathic Achilles tendons were derived by collagenase digest and outgrowth respectively. Tenocytes were seeded into 3D collagen gels. The gels were fixed in custom-made chambers and placed in an incubator for 24hrs whilst gene expression stabilised. After 24hrs, cyclic uniaxial strain at 1% ± 1% was applied to the cells, at either 1Hz (n=4) or 10Hz (n=4) using a Bose loading system. After 15 minutes of cyclic strain, the samples were maintained in chambers under 1% static strain for 24 hrs after which gene expression was characterised using RT-PCR.

Introduction

Primary cilia are organelles found singularly on almost every cell in the body, including tenocytes. Tendon is a hierarchical, composite structure, and previous work from our group has suggested that the cell populations in the inter-fascicular matrix (IFM) may be different from those within the fascicle matrix (FM). This study investigated how stress deprivation influenced the primary cilia of both cell types, and the mechanics of the IFM and the FM.

Materials and Methods

Rat tail tendons were dissected and then either tested immediately (fresh), or maintained in media for 1 week, either stress deprived or at 4% static strain. Fascicles and IFM were then either, fixed and imaged to determine cilia length (n = 80–160 cilia per group from across 3 rats), or mechanically tested to determine the static and viscoelastic properties of both the fascicles and the IFM (n = 6–8 per group).

Introduction

Whilst all tendons connect muscle to bone, energy storing (ES) tendons, such as the equine superficial digital flexor tendon (SDFT) play an additional role, storing energy to improve locomotion efficiency. ES tendons experience significantly higher strains during locomotion than other positional tendons, such as the common digital extensor tendon (CDET). Our previous work has demonstrated that the interfascicular matrix (IFM) is more extensible in ES tendons, allowing ES tendons to stretch further during use. However, ES tendons must also recoil efficiently to perform their energy storing function. It has not been yet established if the IFM is able to recoil and recover after loading. Thus, this project aimed to determine the recoil capacity of the IFM in both the ES and positional tendons from young and old horses.

Materials and Methods

Five young (3–7 years) and five old (17–20 years) SDFTs and CDETs were dissected from the forelimbs of 10 euthanized horses. Groups of 2 intact fascicles (bounded by IFM) were dissected from each tendon. Using a custom-made dissection rig and a polarised light microscope, samples were dissected, and the opposing end of each fascicle was cut transversely, leaving a 10 mm length of IFM. IFM samples were tested in shear, by preconditioning with 10 loading cycles then pulling to failure. The hysteresis and stress relaxation that occurred during preconditioning were calculated.

Introduction

Regular, repeated stretching increases joint range of movement (RoM), however the physiology underlying this is not well understood. The traditional view is that increased flexibility after stretching is due to an increase in muscle length or stiffness whereas recent research suggests that increased flexibility is due to modification of tolerance to stretching discomfort/pain. If the pain tolerance theory is correct the same degree of micro-damage to muscle fibres should be demonstrable at the end of RoM before and after a period of stretch training. We hypothesise that increased RoM following a 3 weeks hamstrings static stretching exercise programme may partly be due to adaptive changes in the muscle/tendon tissue.

Materials and Methods

Knee angle and torque were recorded in healthy male subjects (n=18) during a maximum knee extension to sensation of pain. Muscle soreness (pain, creatine kinase activity, isometric active torque, RoM) was assessed before knee extension, and 24 and 48 hours after maximum stretch. An exercise group (n=10) was given a daily home hamstring stretching programme and reassessed after 3 weeks and compared to a control group (n=8). At reassessment each subject's hamstring muscles were stretched to the same maximum knee extension joint angle as determined on the first testing occasion. After 24 hours, a reassessment of maximum knee extension angle was made.

Introduction

Proteomic analysis has the ability to reveal both the different types and abundances of proteins in a sample. To date, proteomic analysis has received limited attention in the field of tendon research, with mainly ex vivo investigations being undertaken to characterize the tendon proteome. A significant development would be the ability to detect in vivo changes in the proteomic composition as this could have clearer and more direct understanding on the efficiency of therapies. It is well documented that sample preparation is one of the most crucial steps in obtaining high quality resolution of proteins in mass spectrometry. Biological samples can vary in complexity, and minimization of this through sample handling and cleaning can drastically improve the resolved peptide spectra. During this investigation, samples of microdialysis media from the peritendinous space of the Achilles tendon pre or post shockwave therapy were used to establish whether the in vivo identification and quantification of proteins was possible.

Materials and Methods

Six microdialysis samples were obtained from human subjects before (controls) or after shock wave therapy on their achilles tendon. Samples were concentrated and intefering substances removed using StrataClean™ resin. Reduction, alkylation and an In-solution tryptic digestion was performed with the prior addition of 1% Rapigest SF solution. Samples were then analysed by Liquid Chromatography Mass Spectrometry/Mass Spectrometry. Data files were searched using IPI-human database using Mascot Search Engine. Relative quantification was performed between groups by ProgenesisQI.

Introduction

Tendon cross-sectional area (CSA) and stiffness increase in men during chronic exercise. The increase in tendon CSA and stiffness is not evident in women. In men, exercise increases tendon production of MMPs, IGF-1, and IL-6, which presumably contribute to tendon remodeling during chronic exercise. The purpose of this study was to determine if exercise-induced production of MMPs, IGF-1, and IL-6 are limited in women when compared to men.

Materials and Methods

Young men (n=9, 27±1 y) and women (n=8, 26±1 y) performed a single bout of calf press exercise (8 sets of 15 repetitions at 70% of 15-RM). A microdialysis fiber (3000 kDa cut-off) was inserted into the space anterior to the Achilles tendon immediately after exercise and during a control experiment. All proteins were evaluated with ELISA kits.

Introduction

Achilles tendinopathy (AT) is a highly prevalent injury in athletes and non-athletes with an unknown aetiology. Genetic risk factors have been a recent focus of investigation. The aim of this systematic review was to determine which loci have been linked with mid-portion AT and could potentially be used as biomarkers in tendinopathy risk models or as preventative or therapeutic targets.

Materials and Methods

Eight electronic bibliographic databases were searched from inception to April 2015 for cross-sectional, prospective cohort and case-control studies that included empirical research investigating genes associated with mid-portion AT. Potential publications were assessed by two independent reviewers (AAC and PRJ) for inclusion and quality. Quality was evaluated using a validated scale.

Introduction

An additional pathology should be considered for Achillodynia differentials – the intratendinous tear (ITT) – for which we describe symptoms, ultrasound findings and co-presenting pathology.

Materials and Methods

Examinations of 740 Achillodynic patients in one specialist centre were reviewed. ITTs were defined as a clearly visualised echopoor area situated centrally and extending to, but not through the tendon periphery, with pain on palpation and no clinical findings consistent with Achilles rupture. Descriptive statistics were used to analyse differences between pathological sub-groups, and images described qualitatively.

Introduction

High-volume image guided injections (HVIGI) followed by structured rehabilitation have been shown to be effective in various musculoskeletal conditions including Achilles tendinopathy and shoulder impingement syndrome. The aim was to explore the effect of a HVIGI in Hoffa's fat pad impingement, a common cause of anterior knee pain.

Materials and Methods

100 consecutive subjects who received a HVIGI followed by a standardised physiotherapy rehabilitation regime for Hoffa's fat pad impingement (diagnosed using clinical history, examination and magnetic resonance imaging) at one specialist MSK centre were sent a follow-up questionnaire. The questionnaire collected demographics, symptom length and the percentage improvement in symptoms following the HVIGI. All had received HVIGI consisting of 10ml of 0.5% Marcaine and 50mg of hydrocortisone followed by a structured rehabilitation programme with a focus on lower limb alignment control, flexibility, hip and knee strengthening in line with best practice. Data was analysed using SPSS version 20 at this interim stage; data collection is continuing.