Integrin α2β1 is one of the major transmembrane receptors for fibrillary collagen. In native bone we could show that the absence of this protein led to a protective effect against age-related osteoporosis. The objective of this study was to elucidate the effects of integrin α2β1 deficiency on fracture repair and its underlying mechanisms. Standardised femoral fractures were stabilised by an intramedullary nail in 12 week old female C57Bl/6J mice (wild type and integrin α2. -/-. ). After 7, 14 and 28 days mice were sacrificed. Dissected femura were subjected to µCT and histological analyses. To evaluate the biomechanical properties, 28-day-healed femura were tested in a torsional testing device. Masson goldner staining, Alizarin blue, IHC and IF staining were performed on paraffin slices. Blood serum of the animals were measured by ELISA for BMP-2. Primary osteoblasts were analysed by in/on-cell western technology and qRT-PCR. Integrin α2β1 deficient animals showed earlier transition from cartilaginous callus to mineralized callus during fracture repair. The shift from chondrocytes over hypertrophic chondrocytes to bone-forming osteoblasts was accelerated. Collagen production was increased in mutant fracture callus. Serum levels of BMP-2 were increased in healing KO mice. Isolated integrin deficient osteoblast presented an earlier expression and production of active BMP-2 during the differentiation, which led to earlier mineralisation. Biomechanical testing showed no differences between wild-type and mutant bones. Knockout of integrin α2β1 leads to a beneficial outcome for fracture repair. Callus maturation is accelerated, leading to faster recovery, accompanied by an increased generation of extra-cellular matrix material. Biomechanical properties are not diminished by this accelerated healing. The underlying mechanism is driven by an earlier availability of BMP-2, one main effectors for bone development. Local inhibition of integrin α2β1 is therefore a promising target to accelerate fracture repair, especially in patients with retarded healing

Matrix metalloproteinase enzymes (MMPs) play a crucial role in the remodeling of articular cartilage, contributing also to osteoarthritis (OA) progression. The pericellular matrix (PCM) is a specialized space surrounding each chondrocyte, containing collagen type VI and perlecan. It acts as a transducer of biomechanical and biochemical signals for the chondrocyte. This study investigates the impact of MMP-2, -3, and -7 on the integrity and biomechanical characteristics of the PCM. Human articular cartilage explants (n=10 patients, ethical-nr.:674/2016BO2) were incubated with activated MMP-2, -3, or -7 as well as combinations of these enzymes. The structural degradative effect on the PCM was assessed by immunolabelling of the PCM's main components: collagen type VI and perlecan. Biomechanical properties of the PCM in form of the elastic moduli (EM) were determined by means of atomic force microscopy (AFM), using a spherical cantilever tip (2.5µm). MMPs disrupted the PCM-integrity, resulting in altered collagen type VI and perlecan structure and dispersed pericellular arrangement. A total of 3600 AFM-measurements revealed that incubation with single MMPs resulted in decreased PCM stiffness (p<0.001) when compared to the untreated group. The overall EM were reduced by ∼36% for all the 3 individual enzymes. The enzyme combinations altered the biomechanical properties at a comparable level (∼36%, p<0.001), except for MMP-2/-7 (p=0.202). MMP-induced changes in the PCM composition have a significant impact on the biomechanical properties of the PCM, similar to those observed in early OA. Each individual MMP was shown to be highly capable of selectively degrading the PCM microenvironment. The combination of MMP-2 and -7 showed a lower potency in reducing the PCM stiffness, suggesting a possible interplay between the two enzymes. Our study showed that MMP-2, -3, and -7 play a direct role in the functional and structural remodeling of the PCM. Acknowledgements: This work was supported by the Faculty of Medicine of the University of Tübingen (grant number.: 2650-0-0)

Introduction and Objective. Achilles tendon defect is difficult problem for orthopedic surgeon, and therefore the development of new treatments is desirable. Platelet-rich fibrin (PRF), dense fibrin scaffold composed of a fibrin matrix containing many growth factors, is recently used as regenerative medicine preparation. However, few data are available on the usefulness of PRF on Achilles tendon healing after injury. The objective of this study is to examine whether PRF promotes the healing of Achilles tendon defect in vivo and evaluated the effects of PRF on tenocytes in vitro. Materials and Methods. PRF were prepared from rats according to international guidelines on the literature. To create rat model for Achilles tendon defect, a 4-mm portion of the right Achilles tendon was completely resected, and PRF was placed into the gap in PRF group before sewing the gap with nylon sutures. To assess the histological healing of Achilles tendon defect, Bonar score was calculated using HE, Alcian-blue, and Picosirius-red staining section. Basso, Beattie, Bresnahan (BBB) score was used for the evaluation of motor functional recovery. Biomechanical properties including failure tensile load, ultimate tensile stress, breaking elongation, and elastic modulus were measured. We examined the effects of PRF on tenocytes isolated from rat Achilles tendon in vitro. The number of viable cells were measured by MTS assay, and immunostaining of ki-67 was used for detection of proliferative cells. Migration of tenocytes was evaluated by wound closure assay. Protein or gene expression level of extracellular matrix protein, such as collagen, were evaluated by immunoblotting, immunofluorescence, or PCR. Phosphorylation level of AKT, FGF receptor, or SMAD3 was determined by western blotting. Inhibitory experiments were performed using MK-2206 (AKT inhibitor), FIIN-2 (FGFR inhibitor), SB-431542 (TGF-B receptor inhibitor), or SIS3 (SMAD3 inhibitor). All p values presented are two-sided and p values < 0.05 were considered statistically significant. Results. In rat Achilles tendon defects, Bonar score was significantly improved in PRF group compared to control group. Collagen deposition at the site of Achilles tendon defect was observed earlier in PRF group. Consistent with the histological findings, BBB score was significantly improved in PRF group. PRF also significantly improved the biomechanical properties of injured Achilles tendon. Furthermore, proliferating tenocytes, labelled by ki-67 were significantly increased in PRF group. These data suggested PRF prompted the healing of Achilles tendon defect. Thus, we further examined the effects of PRF on tenocytes in vitro. PRF significantly increased the number of viable cells, the proliferative cells labelled by ki-67, and migratory ability. Furthermore, PRF significantly increased the protein expression levels of collagen-I, collagen-III, α-SMA, and tenascin-C in tenocytes. Next, we examined the signalling pathway associated with PRF-induced proliferation of tenocytes. PRF increased the phosphorylation level and induced nuclear translocation of AKT, known as key regulator of cell survival. PRF also induced the phosphorylation of FGF receptor. Inhibition of AKT or FGF-receptor completely suppressed the positive effects of PRF on tenocytes. Furthermore, we found that inhibition of FGF receptor partially suppressed the phosphorylation of AKT by PRF. Thus, PRF induced the proliferation of tenocytes via FGFR/AKT axis. We further evaluated the signalling pathway associated with PRF-induced expression of extracellular matrix. PRF increased the phosphorylation levels of SMAD3 and induced nuclear translocation of SMAD3. Furthermore, inhibition of TGF-B receptor or SMAD3 suppressed increased expression level of extracellular matrix by PRF. Thus, PRF increased expression level of extracellular matrix protein via TGF-BR/SMAD3 axis. Conclusions. PRF promotes tendon healing of the Achilles tendon defect and recovery of exercise performance and biomechanical properties. PRF increases the proliferation ability or protein expression level of extracellular matrix protein in tenocytes via FGFR/AKT or TGF-βR/SMAD3 axis, respectively

Introduction. In recent years, there has been a growing interest, in many fields of medicine, in the use of bone adhesives that are biodegraded to non-toxic products and resorbed after fulfilling their function in contact with living tissue. Biomechanical properties of newly developed bone glue, such as adhesion to bone and elastic modulus were tested in our study. Material and methods. Newly developed injectable biodegradable “self-setting” bone adhesive prepared from inorganic tricalcium phosphate powder and aqueous solution of organic thermogelling polymers was used for ex-vivo fixing fractured pig femur. Ex-vivo biomechanical tests were performed on 45 fresh pig femurs. Control group consist of 10 healthy bones, tested group was created by 35 bones with artificial fractures in diaphysis – oblique (O) and bending wedge (BW) type of fracture. Tested group were divided to following 4 subgroups (sg); sg1 – O fracture (n=15) glued together with 3 different type of bone adhesives, sg2 BW fracture (n=5) glued together with bone adhesive (n=5); sg3 – BW fracture fixed with locking compression plate (LCP), n=5; sg4 – BW fracture fixed with LCP in combination with bone adhesive. Three-point bending force and shear compression tests were performed on linear electrodynamic test instrument (ElectroPuls E10000, Instron). Femurs from sg1, sg2 and sg4 were tested on Micro-CT before and after biomechanical testing. Results. Shear compression tests in sg1 without amino acids modification showed that it is needed force of 0.5 mPa to recreate fracture, however, modification with amino acids increased glue strength to 3 mPa. Three-point bending force test in sg2 showed reduced force of 250 N to recreate fracture, anyhow in sg4 force needed to initiate the fracture was increased up to 5000 N. Conclusion. Newly developed injectable biodegradable “self- setting” bone adhesive represents new possibility how to fix small bone fragments in comminuted fractures and simultaneous chance how to improve and accelerate bone healing process. Acknowledgement. Project no. AOTEU-R-2016-064 was supported by AOTRAUMA, Switzerland

Dura mater is a thick membrane that is the outermost of the three layers of the meninges that surround the brain and spinal cord. Appropriate dural healing is crucial to prevent cerebrospinal fluid leaks but the entire process has been barely understood so far. Understanding of dural healing and tissue neoformation over the dural grafts, which are usually used for duraplasty, is still partial. Therefore, implantation of decellular dura mater (DM) to recipient from different donor and vitalization with recipient”s mesenchymal stem cells for the treatment of tissue on transplantation process is significant approach. This approach prevents immunological reactions and provides long-term stabilization. According to this study, it is believed that this approach will provide DM healing and become crucial in DM transplantation. The aim of this study was to develop a new construct by tissue engineering of the human DM based on a decellular allograft. Thus human DM collected from forensic medicine and decellularized using the detergent sodium dodecyl sulfate (SDS) in the multiple process of physical, enzimatic and chemical steps. Decellularization were exposing the tissue to freeze-thaw cycles, incubation in hypotonic tris-HCl buffer, 0.1% (w/v) SDS in hypotonic buffer and hypertonic buffer followed by disinfection using 0.1% (v/v) peracetic acid and final washing in phosphate-buffered saline. As a result of all these processes, cellular components of DM were removed by preserving the extracellular matrix without any significant loss in mechanical properties. Based on the histological analysis of the decellularized DM revealed the absence of visible whole cells. Collagen and glycosaminoglycan (GAG) contents of decellular DM evaluated histological staining by Masson Trichrome and Alcian blue respectively. Also biochemical tests were carried out by spectrophotometry (Quickzym Biosciences, The Netherlands) and total GAG content were analyzed by 1.9 dimethylmethylene blue assay. The histoarchitecture was unchanged, and there were no significant changes of total collagen and GAG content. Biomechanical properties were determined by tensile tests, which has confirmed the retention of biomechanical properties following decellularization. The mean tensile strengths were 7,424±4,20 MPa for control group, 5,254±2,068 MPa for decellularization group. There was no statistically significant difference between tensile strength (p=0,277) and tissue thickness (p=0, 520) for both group. In conclusion, this study has developed biomechanically functional decellularized DM scaffold for use in DM repair. In addition, this study is a part of the progressing study and additional studies investigating the biocompatibility performance of the decellularized DM scaffold and there is need for in vivo studies. Keywords. Dura mater, Decellularization, Allografts, Scaffolds, Tissue Engineering

Objectives

We investigated the effects on fracture healing of two up-regulators of inducible nitric oxide synthase (iNOS) in a rat model of an open femoral osteotomy: tadalafil, a phosphodiesterase inhibitor, and the recently reported nutraceutical, COMB-4 (consisting of L-citrulline, Paullinia cupana, ginger and muira puama), given orally for either 14 or 42 days.

An understanding of the remodelling of tendon is crucial for the development of scientific methods of treatment and rehabilitation. This study tested the hypothesis that tendon adapts structurally in response to changes in functional loading. A novel model allowed manipulation of the mechanical environment of the patellar tendon in the presence of normal joint movement via the application of an adjustable external fixator mechanism between the patella and the tibia in sheep, while avoiding exposure of the patellar tendon itself. Stress shielding caused a significant reduction in the structural and material properties of stiffness (79%), ultimate load (69%), energy absorbed (61%), elastic modulus (76%) and ultimate stress (72%) of the tendon compared with controls. Compared with the material properties the structural properties exhibited better recovery after re-stressing with stiffness 97%, ultimate load 92%, energy absorbed 96%, elastic modulus 79% and ultimate stress 80%. The cross-sectional area of the re-stressed tendons was significantly greater than that of stress-shielded tendons.

The remodelling phenomena exhibited in this study are consistent with a putative feedback mechanism under strain control. This study provides a basis from which to explore the interactions of tendon remodelling and mechanical environment.