The superficial zone (SFZ) of articular cartilage has unique structural and biomechanical features, and is important for joint long-term function. Previous studies have shown that TGF-β/Alk5 signaling upregulating PRG4 expression maintains articular cartilage homeostasis. However, the exact role and molecular mechanism of TGF-β signaling in SFZ of articular cartilage homeostasis are still lacking. In this study, a combination of in vitro and in vivo approaches were used to elucidate the role of Alk5 signaling in maintaining the SFZ of articular cartilage and preventing osteoarthritis initiation. Mice with inducible cartilage SFZ-specific deletion of Alk5 were generated to assess the role of Alk5 in OA development. Alterations in cartilage structure were evaluated histologically. The chondrocyte apoptosis and cell cycle were detected by TUNEL and Edu staining, respectively. Isolation, culture and treatment of SFZ cells, the expressions of genes associated with articular cartilage homeostasis and TGF-β signaling were analyzed by qRT-PCR. The effects of TGF-β/Alk5 signaling on proliferation and differentiation of SFZ cells were explored by cells count and alcian blue staining. In addition, SFZ cells isolated from C57 mice were cultured in presence of TGF-β1 or SB505124 for 7 days and transplanted subcutaneously in athymic mice. Postnatal cartilage SFZ-specific deletion of Alk5 induced an OA-like phenotype with degradation of articular cartilage, synovial hyperplasia as well as enhanced chondrocyte apoptosis, overproduction of catabolic factors, and decreased expressions of anabolic factors in chondrocytes. qRT-PCR and IHC results confirmed that Alk5 gene was effectively deleted in articular cartilage SFZ cells. Next, the PRG4-positive cells in articular cartilage SFZ were significantly decreased in Alk5 cKO mice compared with those in Cre-negative control mice. The mRNA expression of Aggrecan and Col2 were decreased, meanwhile, expression of Mmp13 and Adamts5 were significantly increased in articular cartilage SFZ cells of Alk5 cKO mice. In addition, Edu and TUNEL staining results revealed that slow-cell cycle cell number and increase the apoptosis positive cell in articular cartilage SFZ of Alk5 cKO mice compared with Cre-negative mice, respectively. Furthermore, all groups of SFZ cells formed ectopic solid tissue masses 1 week after transplantation. Histological examination revealed that the TGF-β1-pretreated tissues was composed of small and round cells and was positive for alcian blue staining, while the SB505124-pretreated tissue contained more hypertrophic cells though it did stain with alcian blue. TGF-β/alk5 signaling is an essential regulator of the superficial layer of articular cartilage by maintaining chondrocyte number, its differentiation properties, and lubrication function. Furthermore, it plays a critical role in protecting cartilage from OA initiation

Aim. Despite the expanding research focusing on bacterial biofilm formation, specific histochemical biofilm stains have not been developed for light microscopy. Therefore, pathologists are often not aware of the presence of biofilm formation when examining slides for diagnosing bacterial infections, including orthopaedic infections. The aim of the present study was to develop a combined histochemical and immunohistochemical biofilm stain for simultaneous visualization of Staphylococcus aureus bacteria and extracellular matrix in different colours using light microscopy. Methods. Infected bone tissue was collected from two different porcine models of osteomyelitis inoculated with the biofilm forming S. aureus strain S54F9. The infection time was 5 and 15 days, respectively. First, 25 common histochemical protocols were used in order to find stains that could identify extracellular biofilm matrix. Hereafter, the histochemical protocols for Alcian Blue pH3, Luna and Methyl-pyronin green were combined with an immunohistochemical protocol based on a specific antibody against S. aureus. Finally, the three new combined protocols were applied to infected bone tissue from a child suffering from chronic staphylococcal osteomyelitis for more than a year. For all combined protocols applied on all types of tissue (porcine and human) the number of double stained bacterial aggregates were counted. On the same sections the percentage of extracellular matrix of representative bacterial aggregates was calculated by image analysis. Results. Simultaneous visualization of bacterial cells and extracellular matrix in different colours was detected in both porcine and human tissue sections with all three combined protocols. The bacterial cells were red to light brown and the extracellular matrix either light blue, blue or orange depending on the histochemical stain i.e. if it was Alcian blue pH3 (colouring polysaccharides), Luna or Methyl green-pyronin (both colouring extracellular DNA), respectively. In the porcine models, 10 percent of the bacterial aggregates in a 10× magnification field revealed both the extracellular matrix and bacteria simultaneously in two different colours. For the human case, this was seen in 90 percent of the bacterial aggregates. The percentage of extracellular matrix of representative bacterial aggregates was 60 and 20 percent in the human and porcine tissues, respectively. Conclusions. The amount of S. aureus biofilm extracellular matrix increased with infection time. A combination of histochemical and immunohistochemical staining is a practical method for identification and evaluation of S. aureus biofilm in orthopaedic infections

Introduction. It is essential to investigate the tribological maturation of tissue-engineered cartilage that is to be used in medical applications. The frictional performances of tissue engineered cartilage have been measured using flat counter surfaces such as stainless steel, glass or ceramics. However, the measured friction performances were significantly inferior to those of natural cartilage, likely because of cartilage adhesion to the counter surface. Tamura et al. reported that a poly (2- methacryloyloxyethyl phosphoryl-choline (MPC)) grafted surface shows low friction coefficient against cartilage without the adhesion to be equivalent to those for natural cartilage-on-cartilage friction. [1]. On the other hand, Yamamoto et al. reported that applying a relative sliding movement had a potential to alter the expression of tribological function of regenerated cartilage of chondrocytes. [2] In this paper, the effects of the relative sliding movement on the expression of bone marrow stromal cells (BMSC)s were investigated using the poly(MPC) grafted surface as a counter surface. Material and methods. BMSCs seeded onto fibroin sponge scaffolds were cultured by using the stirring chamber system (Figure 1), which can apply a relative tribological movement to the surface of the specimens. Three culture conditions were applied (dynamic in stirring chamber as frequency as 40 min [D1], as 40 sec [D2] and static in stirring chamber group [S]). The specimens were set into stirrer on a poly(MPC) grafted surface (MPC polymer coated surface, SANSYO). As a counter surface in friction tests, the poly(MPC) grafted surface was prepared by atom transfer radical polymerization, and the regenerated cartilage was prepared by seeding 5×10. 5. cells (BMSCs from rat bone marrow) onto fibroin sponge scaffolds (8 mm diameter and 1 mm thickness) and by 14 days culture. Results and Discussion. The friction coefficient in D1 group tended to be lower than that in S group. Similarly, D2 group tended to show lower value than S group (Figure 2). However, the value of D1 and D2 group was extraordinary high, compared to that of intact articular cartilage. The GAG amount of D1 and D2 group was significantly higher than that of S group. All of the groups showed Collagen type I and type II staining at the surface. S group showed wider staining region than D1 and D2 group. However there was no Alcian Blue staining (Figure 3). These results indicate that the stirring chamber system tended to improve the frictional performance of regenerated tissue. However this relative tribological movement has not a potential to induce effects on the differentiation of BMSCs to chondrocytes

A Ruys, School of Aerospace, Mechanical and Mechatronic Engineering, University of Sydney, Sydney. The effects of bone anabolics can be maximised by systemic co-treatment with an anti-catabolic. Local treatment may reduce the total drug required and produce superior outcomes, although high dose local bisphosphonate has been reported to impair bone formation. We have explored local co-delivery of anabolic/anti- catabolic bone drugs at different doses. We manufactured biodegradable poly-D,L-lactic acid (PDLLA) polymer pellets containing 25g BMP-7 as an anabolic with or without 0.002mg-2mg Pamidronate (PAM) as an anti-catabolic. Polymer pellets were surgically implanted into the hind limb muscle of female C57BL6 mice. Animals were sacrificed at three weeks post- implantation and bone formation was assessed by radiography, microcomputed tomography (microCT) and histology. Histological staining on five Âm paraffin sections included haematoxylin/eosin, alcian blue/picrosirius red, and tartrate- resistant acid phosphatase (TRAP). Radiographic and microCT data confirmed that 0.02mg and 0.2mg local PAM doses significantly augmented BMP-7 induced bone formation. In contrast, 2mg local PAM dramatically reduced the amount of bone present. This dose was comparable to that used by Choi et al who also reported impaired bone formation in a skull defect model.2 three-dimensional microCT and histological analyses of the ectopic bone and surrounding muscle showed a cortical shell covering the polymer pellet, which had not completely resorbed. Histological analysis at the pellet/bone interface showed tissue granulation and no inflammation, suggesting a high biocompatibility of the PDLLA polymer. The presence of bisphosphonate also decreased the amount of fatty marrow tissue seen within between the cortical shell and the unresorbed polymer. For the first time we can demonstrate synergy with local BMP/bisphosphonate. This study confirms that high local PAM doses can have negative effects, indicating a need to avoid overdosing. The lack of implant degradation suggests a need to optimise polymer degradation for bone tissue engineering application