Early changes within articular cartilage during human idiopathic osteoarthritis are poorly understood. However alterations to chondrocyte morphology occur with the development of fine cytoplasmic processes and cell clusters, potentially playing a role in cartilage degeneration. The aggrecanase ADAMTS-4 (A disintegrin and metalloproteinase with thrombospondin motifs-4) has been implicated as an important factor in cartilage degradation, so we investigated the relationship between chondrocyte morphology and levels of ADAMTS-4 in both non-degenerate and mildly osteoarthritic human cartilage. Human femoral heads were obtained following consent from patients undergoing hip arthroplasty following femoral neck fracture. Cartilage explants of normal (grade 0; G0) and mildly osteoarthritic (grade 1; G1) cartilage were labelled with the cytoplasmic dye CMFDA (5-chloromethylfluorescein-diacetate). Explants were cryosectioned (30μm sections), and labelled for ADAMTS-4 by fluorescence immunohistochemistry. Sections were imaged with confocal microscopy, allowing the semi-quantitative analysis of ADAMTS-4 and 3D visualisation of in situ cell morphology. With cartilage degeneration from G0 to G1, there was a decrease in the proportion of chondrocytes with normal rounded morphology (P<0.001) but an increase in the proportion of cells with processes (P<0.01) and those in clusters (P<0.001;[4(1653)]; femoral heads:cells). Although average levels of ADAMTS-4 for all cells was the same between G0 and G1 (P>0.05), a change was evident in the distribution curves for cell-specific ADAMTS-4 labelling. Cell-by-cell analysis showed that ADAMTS-4 levels were higher in chondrocytes with cytoplasmic processes compared to normal cells (P=0.044) however cells in clusters had lower levels than normal cells (P=0.003;[3(436)]). Preliminary data suggested that ADAMTS-4 levels increased with larger chondrocyte clusters. These results suggest complex heterogeneous changes to levels of cell-associated ADAMTS-4 with early cartilage degeneration – increasing in cells with processes and initially decreasing in clusters. Increased levels of ADAMTS-4 are likely to produce focal areas of matrix weakness potentially leading to early cartilage degeneration

Articular cartilage has poor repair potential and the tissue formed is mechanically incompetent. Mesenchymal stromal cells (MSCs) show chondrogenic properties and the ability to re-grow cartilage, however a viable human model for testing cartilage regeneration and repair is lacking. Here, we describe an ex vivo pre-clinical femoral head model for studying human cartilage repair using MSCs. Human femoral heads (FHs) were obtained following femoral neck fracture with ethical permission/patient consent and full-depth cartilage wells made using a 3mm biopsy punch. Pancreas-derived mesenchymal stromal cells (P-MSC) were prepared in culture media at ~5000 cells/20µl and added to each well and leakage prevented with fibrin sealant. After 24hrs, the sealant was removed and medium replaced with StemPro. TM. chondrogenesis differentiation medium. The FHs were incubated (37. o. C;5% CO. 2. ) for 3wks, followed by a further 3wks in standard medium with 10% human serum with regular medium changes throughout. Compared to wells with medium only, A-MSCs produced a thin film across the wells which was excised en-block, fixed with 4% paraformaldehyde and frozen for cryo-sectioning. The cell/tissue films varied in thickness ranging over 20-440µm (82±21µm; mean±SEM; N=3 FHs). The thickness of MSC films abutting the cartilage wells was variable but generally greater (15-1880µm) than across the wells, suggesting an attachment to native articular cartilage. Staining of the films using safranin O (for glycosaminoglycans; quantified using ImageJ) was variable (3±8%; mean±SEM; N=3) but in one experiment reached 20% of the adjacent cartilage. A preliminary assessment of the repair tissue gave an O'Driscoll score of 10/24 (24 is best). These preliminary results suggest the ex vivo femoral head model has promise for studying the capacity of MSCs to repair cartilage directly in human tissue, although optimising MSCs to produce hyaline-like tissue is essential. Supported by the CSO (TCS/17/32)

Various approaches have been implemented to enhance bone regeneration, including the utilization of autologous platelet-rich plasma and bone morphogenetic protein-2. The objective of this study was to evaluate the impact of Marburg Bone Bank-derived bone grafts in conjunction with platelet-rich plasma (PRP), recombinant human bone morphogenetic protein-2 (rhBMP-2), and zoledronic acid (ZA) on osteogenesis within rabbit bone defects. Methodology. Bone defects (5mm in diameter) were created in the femurs of 96 male rabbits. The animals were allocated into five groups: (1) bone graft + PRP (BG + PRP), (2) bone graft + 5μg rhBMP-2 (BG + rhBMP-2), (3) bone graft + 5μg ZA (BG + ZA), (4) bone graft + 10μg rhBMP-2 + 5μg ZA (BG + rhBMP-2 + ZA), and (5) bone graft (BG). Marburg Bone Bank-processed human femoral head allografts were utilized for bone grafting. The rabbits were euthanized at 14-, 30-, and 60-days post-surgery, and their femurs underwent histopathological and histomorphometric assessments. Results. Histomorphometric analysis revealed significantly enhanced de novo osteogenesis within the bone allografts in the BG + PRP and BG + rhBMP-2 groups compared to the BG, BG + ZA, and BG + rhBMP-2 + ZA groups at 14 and 30 days (p < 0.05). However, on day 60, the BG + rhBMP-2 group exhibited elevated osteoclastic activity (early resorption). The local co-administration of ZA with thermally treated grafts impeded both bone graft resorption and new bone formation within the bone defect across all time points. The addition of ZA to BG + rhBMP-2 resulted in diminished osteogenic activity compared to the BG + rhBMP-2 group (p < 0.000). Conclusion. The study findings indicated that the combination of PRP and rhBMP-2 with Marburg bone grafts facilitates early-stage osteogenesis in bone defect healing. Incorporating ZA into the thermally treated bone graft hinders both graft resorption and de novo bone formation

The effects of dexamethasone (dex), during in vitro human osteogenesis, are contrasting. Indeed, dex downregulates SOX9 during osteogenic differentiation of human bone marrow mesenchymal stromal cells (HBMSCs). However, dex also promotes PPARG expression, resulting in the formation of adipocyte-like cells within the osteogenic monolayers. The regulation of both SOX9 and PPARG seems to be downstream the transactivation activity of the glucocorticoid receptor (GR), thus the effect of dex on SOX9 downregulation is indirect. This study aims at determining whether PPAR-γ regulates SOX9 expression levels, as suggested by several studies. HBMSCs were isolated from bone marrow of patients with written informed consent. HBMSCs were cultured in different osteogenic induction media containing 10 or 100 nM dex. Undifferentiated cells were used as controls. Cells were treated either with a pharmacological PPAR-γ inhibitor T0070907 (donors n=4) or with a PPARG-targeting siRNA (donors n=2). Differentiation markers or PPAR-γ target genes were analysed by RT-qPCR. Mineral deposition was assessed by ARS staining. Two-way ANOVA followed by a Tukey's multiple comparison test compared the effects of treatments. At day 7, T0070907 downregulated ADIPOQ and upregulated CXCL8, respectively targets of PPAR-γ-mediated transactivation and transrepression. RUNX2 and SOX9 were also significantly downregulated in absence of dex. PPARG was successfully downregulated by siRNA. ADIPOQ expression was also inhibited, while CXCL8 did not show any significant difference between siRNA treatment groups. RUNX2 was downregulated by the PPARG-siRNA treatment in presence of 100 nM dexamethasone, while SOX9 levels were not affected. ARS showed no change in the mineralization levels when PPARG expression or activity was inhibited. Understanding how dex regulates HBMSC differentiation is of pivotal importance to refine current in vitro models. These results suggest that PPARG does not mediate SOX9 downregulation. Unexpectedly, RUNX2 expression was also unaltered or even downregulated after PPAR-γ inhibition. Acknowledgements: AO Foundation, AO Research Institute (CH) and PRIN 2017 MUR (IT) for financial support

To characterize the microstructural organization of collagen fibers in human medial menisci and the response to mechanical loading in relation to age. We combine high resolution imaging with mechanical compression to visualize the altered response of the tissue at the microscale. Menisci distribute the load in the knee and are predominantly composed of water and specifically hierarchically arranged collagen fibers. Structural and compositional changes are known to occur in the meniscus during aging and development of osteoarthritis. However, how microstructural changes due to degeneration affect mechanical performance is still largely unknown [1]. Fresh frozen 4 mm Ø plugs of human medial menisci (n=15, men, 20-85 years) with no macroscopic damage nor known diseases from the MENIX biobank at Skåne University Hospital were imaged by phase contrast synchrotron tomography at the TOMCAT beamline (Paul Scherrer Institute, CH). A rheometer was implemented into the beamline to perform in-situ stress relaxation (2 steps 15% and 30% strain) during imaging (21 keV, 2.75μm pixel size). 40s scans were acquired before and after loading, while 14 fast tomographs (5s acquisitions) were taken during relaxation. The fiber 3D orientations and structural changes during loading were determined using a structure tensor approach (adapting a script from [1]). The 3D collagen fiber orientation in menisci revealed alternating layers of fibers. Two main areas are shown: surfaces and bulk. The surface layers are a mesh of randomly oriented fibers. Within the bulk 2-3 layers of fibers are visible that alternate about 30° to each other. Structural degeneration with age is visible and is currently being quantified. During stress-relaxation all menisci show a similar behavior, with samples from older donors being characterized by larger standard deviation Furthermore, the behavior of the different layers of fibers is tracked during relaxation showing how fibers with different orientation respond to the applied loading. Acknowledgments: We thank PSI for the beamtime at the TOMCAT beamline X02DA, and funding from Swedish Research Council (2019-00953), under the frame of ERA PerMed, and the Novo Nordisk Foundation through MathKOA (NNF21OC0065373)

Abstract. Objectives. Osteoarthritis (OA) is a complex joint disorder characterised by the loss of extracellular matrix (ECM) leading to cartilage degeneration. Changes to cartilage cell (chondrocyte) behaviour occur including cell swelling, the development of fine cytoplasmic processes and cell clustering leading to changes in cell phenotype and development of focal areas of mechanically-weak fibrocartilaginous matrix. [1]. To study the sequence of events in more detail, we have investigated the changes to in situ chondrocytes within human cartilage which has been lightly scraped and then cultured with serum. Methods. Human femoral heads were obtained with Ethical permission and consent from four female patients (mean age 74 yrs) undergoing hip arthroplasty following femoral neck fracture. Osteochondral explants of macroscopically-normal cartilage were cultured as a non-scraped control, or scraped gently six times with a scalpel blade and both maintained in culture for up to 2wks in Dulbecco's Modified Eagle's Medium (DMEM) with 25% human serum (HS). Explants were then labelled with CMFDA (5-chloromethylfluorescein-diacetate) and PI (propidium iodide) (10μM each) to identify the morphology of living or dead chondrocytes respectively. Explants were imaged using confocal microscopy and in situ chondrocyte morphology, volume and clustering assessed quantitatively within standardised regions of interest (ROI) using Imaris. ®. imaging software. Results. Within 2wks of culture with HS, chondrocyte volume increased significantly from 412±9.3µm. 3. (unscraped) at day 0 to 724±16.6 µm. 3. (scraped) [N(n) = 4(380)] (P=0.0002). Chondrocyte clustering was a prominent feature of HS culture as the percentage of clusters in the cell population increased with scraping from 4.8±1.4% to 14.9±3.9% [N(n) = 4(999)] at week 2 (P=0.0116). In addition, the % of the chondrocyte population within clusters increased from approximately 38% to 60%, and the number of cells per cluster increased significantly from 3.2±0.08 to 4±0.22 (P=0.031). The development of abnormal ‘fibroblastic-like’ chondrocyte morphology demonstrating long (>5µm) cytoplasmic processes also occurred, however the time course of this was more variable. For some samples, clustering occurred before abnormal morphology, but for others the opposite occurred. Typically, by the second week, 17±2.64% of the cell population had processes and this increased to 22±4.02% [N(n) = 4(759)] with scraping. Conclusions. Scraping the cartilage will remove surface constituents including lubricants (e.g. lubricin, hyaluronic acid, phospholipids), extracellular matrix constituents (collagen, proteoglycans – potentially the ‘lamina splendens’) and cells (chondrocytes and mesenchymal stromal cells (MSCs)). Although we do not know which of these component(s) is important, the effect is to dramatically increase the permeation of serum factors into the cartilage matrix and signal the development of cytoplasmic processes, cell clustering and swelling. It is notable that these cellular changes are similar to those occurring in early OA. [1]. This raises the interesting possibility that scraped cartilage cultured with human serum recapitulates some of the changes to in situ chondrocytes during early stages of cartilage degeneration and as such, could be a useful model for following the deleterious changes to matrix metabolism. Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Introduction. Homogenous and consistent preparations of mesenchymal stem cells (MSCs) can be acquired by selecting them for integrin α10β1 (integrin a10-MSCs). Safety and efficacy of intra-articular injection of allogeneic integrin a10-MSCs were shown in two post-traumatic osteoarthritis horse studies. The current study investigated immunomodulatory capacities of human integrin a10-MSCs in vitro and their cell fait after intra-articular injection in rabbits. Method. The concentration of produced immunomodulatory factors was measured after licensing integrin a10-MSCs with pro-inflammatory cytokines. Suppression of T-cell proliferation was determined in co-cultures with carboxyfluorescein N-succinimidyl ester (CFSE) labelled human peripheral blood mononuclear cells (PBMCs) stimulated with anti-CD3/CD28 and measuring the CFSE intensity of CD4+ cells. Macrophage polarization was assessed in co-cultures with differentiated THP-1 cells stimulated with lipopolysaccharide and analysing the M2 macrophage cell surface markers CD163 and CD206. In vivo homing and regeneration were investigated by injecting superparamagnetic iron oxide nanoparticles conjugated with Rhodamine B-labeled human integrin a10-MSCs in rabbits with experimental osteochondral defects. MSC distribution in the joint was followed by MRI and fluorescence microscopy. Result. The production of the immunomodulatory factors indoleamine 2,3-dioxygenase and prostaglandin E2 was increased after inflammatory licensing integrin a10-MSCs. Co-cultures with integrin a10-MSCs suppressed T-cell proliferation and increased the frequency of M2 macrophages. In vivo injected integrin a10-MSCs homed to osteochondral defects and were detected in the repair tissue of the defects up to 10 days after injection, colocalized with aggrecan and type II collagen. Conclusion. This study showed that human integrin a10-MSCs have immunomodulatory capacities and in vivo can home to the site of osteochondral damage and directly participate in cartilage regeneration. This suggests that human integrin α10β1-selected MSCs may be a promising therapy for osteoarthritis with dual mechanisms of action consisting of immunomodulation and homing to damage followed by early engraftment and differentiation into chondrocyte-like cells that deposit hyaline cartilage matrix molecules

Tissue repair is believed to rely on tissue-resident progenitor cell populations proliferating, migrating, and undergoing differentiation at the site of injury. During these processes, the crosstalk between mesenchymal stromal/stem cells (MSCs) and macrophages has been shown to play a pivotal role. However, the influence of extracellular matrix (ECM) remodelling in this crosstalk, remains elusive. Human MSCs cultured on tissue culture plastic (TCP) and encased within fibrin in vitro were treated with/without TNFα and IFNγ. Human monocytes were cocultured with untreated/pretreated MSCs on TCP or within fibrin. After seven days, the conditioned media (CM) were collected. Human chondrocytes were exposed to CM in a migration assay. The impact of TGFβ was assessed by adding an inhibitor (TGFβRi). Cell activity was assessed using RT-qPCR and XL-protein-profiler-array. Previously, we demonstrated that culturing human MSCs within 3D-environments significantly enhances their immunoregulatory activity in response to pro-inflammatory stimuli. In this study, monocytes were co-cultured with MSCs within fibrin, acquiring a distinct M2-like repair macrophage phenotype in contrast to TCP co-cultures. MSC/macrophage CM characterization using a protein array demonstrated differences in release of several factors, including chemokines, growth factors and ECM components. Chondrocyte migration was significantly reduced in CM from untreated MSC/monocytes co-cultures in fibrin compared to CM of untreated MSCs/monocytes on TCP. This impact on migration was not seen with chondrocytes cultured in CM of monocytes co-cultured with pretreated MSCs in fibrin. The CM of monocytes co-cultured with pretreated MSCs in fibrin up-regulates COL2A1 and SOX9 compared to TCP. Chondrogenesis and migration were TGFβ dependent. MSC/macrophage crosstalk and responsiveness to cytokines are influenced by the ECM environment, which subsequently impacts tissue-resident cell migration and chondrogenesis. The direct effects of ECM on MSC/macrophage secretory phenotype is complemented by the dynamic ECM binding and release of growth factors such as TGFβ

Abstract. Objectives. Tissue repair is believed to rely on tissue-resident progenitor cell populations proliferating, migrating, and undergoing differentiation at the site of injury. During these processes, the crosstalk between mesenchymal stromal/stem cells (MSCs) and macrophages has been shown to play a pivotal role. However, the influence of extracellular matrix (ECM) remodelling in this crosstalk, remains elusive. Methods. Human MSCs cultured on tissue culture plastic (TCP) and encased within fibrin in vitro were treated with/without TNFα and IFNγ. Human monocytes were cocultured with untreated/pretreated MSCs on TCP or within fibrin. After seven days, the conditioned media (CM) were collected. Human chondrocytes were exposed to CM in a migration assay. The impact of TGFβ was assessed by adding an inhibitor (TGFβRi). Cell activity was assessed using RT-qPCR and XL-protein-profiler-array. Results. Previously, we demonstrated that culturing human MSCs within 3D-environments significantly enhances their immunoregulatory activity in response to pro-inflammatory stimuli. In this study, monocytes were co-cultured with MSCs within fibrin, acquiring a distinct M2-like repair macrophage phenotype in contrast to TCP co-cultures. MSC/macrophage CM characterization using a protein array demonstrated differences in release of several factors, including chemokines, growth factors and ECM components. Chondrocyte migration was significantly reduced in CM from untreated MSC/monocytes co-cultures in fibrin compared to CM of untreated MSCs/monocytes on TCP. This impact on migration was not seen with chondrocytes cultured in CM of monocytes co-cultured with pretreated MSCs in fibrin. The CM of monocytes co-cultured with pretreated MSCs in fibrin up-regulates COL2A1 and SOX9 compared to TCP. Chondrogenesis and migration were TGFβ dependent. Conclusion. MSC/macrophage crosstalk and responsiveness to cytokines are influenced by the ECM environment, which subsequently impacts tissue-resident cell migration and chondrogenesis. The direct effects of ECM on MSC/macrophage secretory phenotype is complemented by the dynamic ECM binding and release of growth factors such as TGFβ. Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Introduction. Supraspinatus tears comprise most rotator cuff injuries, the leading cause of shoulder pain and an increasing problem with ageing populations. Surgical repair of considerable or persistent damages is customary, although not invariably successful. Tissue engineering presents a promising alternative to generate functional tissue constructs with improved healing capacities. This study explores tendon tissue constructs’ culture in a platform providing physiological mechanical stimulation and reports on the effect of different loading regimes on the viability of human tendon cells. Method. Porcine decellularized tendon scaffolds were fixed into flexible, self-contained bioreactor chambers, seeded with human tenocytes, allocated in triplicates to either static control, low (15±0.8Newtons [N]), medium (26±0.5N), or high (49±2.1N)-force-regime groups, connected to a perfusion system and cultured under standard conditions. A humanoid robotic arm provided 30-minute adduction/abduction stimulation to chambers daily over a week. A metabolic activity assay served to assess cell viability at four time points. Statistical significance = p<0.05. Result. One day after beginning mechanical stimulation, chambers in the medium and high-force regimes displayed a rise in metabolic activity by 3% and 5%, respectively. By the last experimental day, all mechanical stimulation regimes had induced an augment in cell viability (15%, 57% and 39% with low, medium, and high loads, respectively) matched against the static controls. Compared to all other conditions, the medium-force regime prompted an increased relative change in metabolic activity for every time point set against day one (p<0.05). Conclusion. Human tenocytes’ viability reflected by metabolic activity in a physiologically relevant bioreactor system is enhanced by loading forces around 25N when mechanically stimulating using adduction/abduction motions. Knowing the most favourable load regime to stimulate tenocyte growth has informed the ongoing exploration of the distinctive effect of different motions on tendon regeneration towards engineering tissue grafts. This work was supported by the Engineering and Physical Sciences Research Council EP/S003509/1

While the COVID-19 pandemic highlighted the need for more accessible anatomy instruction tools, it is also well known that the time allocated to practical anatomy teaching has reduced in the past decades. Notably, the opportunity for anatomy students to learn osteology is not prioritised, nor is the ability of students to appreciate osteological variation. As a potential method of increasing accessibility to bone models, this study describes the process of developing 3D-printed replicas of human bones using a combination of structured light scanning (SLS) technology and 3D printing. Human bones were obtained from the Anatomy Lab at the University of Edinburgh and were digitised using SLS via an Einscan H scanner. The resulting data was then used to print multiple replicas of varying materials, colours, scales and resolutions on an Ultimaker S3 3D printer. To gather opinion on these models and their variables, surveys were completed by anatomy students and educators (n=57). Data was collected using a Likert scale response, as well as free-text answers to gather qualitative information. 3D scans of the scapula, atlas (C1 vertebrae) and femur were successfully obtained. Plastic replicas were produced with defined variables in 4 separate stations e.g. different colours, to obtain results from survey respondents. For colour, 87.7% of survey respondents preferred white models, with 7% preferring orange and 5.3% preferring blue. For material, 47.4% of respondents preferred PLA (Polylactic acid), while 33.3% preferred ABS (Acrylonitrile butadiene styrene), 12.3% preferred Pet-G (Polyethylene terephthalate glycol), 3.5% preferred Glassbend and 3.5% had no preference. Additional results based on scale and resolution were also collected. This initial study has demonstrated a proof-of-concept workflow for SLS technology to be combined with 3D printing to produce plastic replicas of human bones. Our study has provided key information about the colour, scale, material and resolution required for these models. Our future work will focus on determining accuracy of the models and their use as teaching aids for osteology education

Osteoarthritis (OA) is the most prevalent degenerative joint disease that is a leading cause of disability worldwide. Existing therapies of OA only address the symptoms. Liraglutide is a well-known anti-diabetic medication that is used to treat type 2 diabetes and obesity. In inflammatory and post-traumatic OA animal models, liraglutide has demonstrated anti-inflammatory, pain-relieving, and cartilage-regenerating effects1 . The objective of this study is to investigate liraglutide's ability to reduce inflammation and promote anabolism in human OA chondrocytes in vitro. Pellets formed with human OA chondrocytes were cultured with a chondrogenic medium for one week to form cartilage tissue. Afterward, pellets were cultured for another 2 weeks with a chondropermissive medium. The OA group was treated with IL-1β to mimic an inflammatory OA condition. The drug group was treated with 0.5 or 10 µM liraglutide. On days 0, 1, and 14, pellets were collected. Conditioned medium was collected over the 2 weeks culture period. The gene and protein expression levels of regenerative and inflammatory biomarkers were evaluated and histological analyzes were performed. Results showed that the nitric oxide release of the OA + 0.5 µM liraglutide and OA + 10 µM liraglutide groups were lower than the OA group. The DNA content of the OA + 0.5 µM liraglutide and OA + 10 µM liraglutide groups were higher than the OA group on day 14. The RT-qPCR results showed that the anabolism (ACAN, COMP, and COL2) markers were higher expressed in the OA + 0.5 µM liraglutide and OA + 10 µM liraglutide groups when compared with the OA group. The inflammation (CCL-2 and IL-8) markers and catabolism markers (MMP-1, MMP-3, ADAMTS4, and ADAMTS5) had lower expression levels in the OA + liraglutide groups compared to the OA group. The histomorphometric analysis (Figure 1) supported the RT-qPCR results. The results indicate that liraglutide has anabolic and anti-inflammatory effects on human OA chondrocyte pellets. Acknowledgments: This project has received funding from the Eurostars-2 joint program with co-funding from the European Union Horizon 2020 research and innovation program. The funding agencies supporting this work are (in alphabetical order of participating countries): France: BPI France; Germany: Project Management Agency (DLR), which acts on behalf of the Federal Ministry of Education and Research (BMBF); The Netherlands: Netherlands Enterprise Agency (RVO); Switzerland: Innosuisse (the Swiss Innovation Agency). For any figures and tables, please contact the authors directly

Abstract. Objectives. The development of promising therapeutics for cartilage repair/regeneration have been hampered by the inadequacy of existing animal models and lack of suitable translational ex-vivo human tissue models. There is an urgent unmet need for these to assess repair/regenerative (orthobiologic) treatments directly in human tissue. We describe methodology allowing the successful long-term ex-vivo culture of non-degenerate whole human femoral heads that may be used as a model for testing new orthobiologic therapies. Methods. Fifteen fresh, viable human femoral heads were obtained from 15 patients (with ethical permission/consent) undergoing hemiarthroplasty for hip fracture, and cultured aseptically (37°C) for up to 10wks. Culture conditions included static/stirred standard media (Dulbecco's modified Eagle's medium; DMEM) and supplementation with 10% human serum (HS). Chondrocyte viability, density, cell morphology, cell volume, glycosaminoglycan(GAG)/collagen content, surface roughness and cartilage thickness were quantified over time. Results. Chondrocyte viability remained highest (>95%;P<0.01;N(n)=3(12)) under static culture conditons in DMEM+10%HS and was maintained over 10wks. In static DMEM culture without 10%HS, viability remained high for ∼4wks, then decreased rapidly (N(n)=4(16)). Chondrocyte viability declined to <35% over 10wks under all other conditions (N(n)=4(16)). Culturing femoral heads in optimal media (DMEM+10%HS) for 10wks increased the number of chondrocytes producing cytoplasmic processes (P<0.002), but decreased cartilage thickness (P<0.002) and GAG content (P=0.028). Cartilage surface roughness, cellular density, chondrocyte volume and collagen content remained unchanged (P>0.05). Conclusions. The viability of human femoral head articular cartilage could be maintained over 10wks in ex-vivo culture. The model may allow testing of a wide range of orthobiologic therapies directly in human tissue, paving the way for subsequent targeted clinical studies of laboratory-proven strategies with the potential to repair/regenerate articular cartilage. Funder. Chief Scientist's Office, Scotland (Grant TCS/18/01). Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Introduction:. Exercise has showed to reduce pain and improve function in patients with discogenic low back pain (LBP). Although there is currently no biologic evidence that the intervertebral disc (IVD) can respond to physical exercise in humans, a recent study has shown that chronic running exercise is associated with increased IVD hydration and hypertrophy1. Irisin, a myokine released upon muscle contraction, has demonstrated to yield anabolic effects on different cell types, including chondrocytes2. This study aimed to investigate the effect of irisin on human nucleus pulposus cells (hNPCs). Our hypothesis is that irisin may improve hNPCs metabolism and proliferation. METHODS:. The hNPCs, isolated from discectomy surgical waste material (n = 5), were expanded and encapsulated in alginate beads. The hNPCs were treated with: i) only growth medium (control); ii) medium with recombinant irisin (r-IR) at different concentrations (5, 10 and 25 ng / mL); iii) medium with Interleukin-1β (IL1β); iv) medium with IL1β for 24 h and then with IL1β and r-IR; v) medium with r-IR for 24 h and then with r-IR and IL1 β. We evaluated proliferation (trypan blue and PicoGreen), metabolic activity (MTT), nitrite concentration (Griess), and expression levels of catabolic and anabolic genes via real-time polymerase chain reaction (qPCR). Each analysis was performed in triplicate for each donor and each experiment was performed three times. Data were expressed as mean ± S.D. One-way ANOVA was used for the groups under exam. RESULTS:. Irisin increased hNPCs proliferation (p < 0.001), metabolic activity at 10 ng/mL (p < 0.05), and GAG content at concentration of 10 ng/mL and 25 ng/mL (p < 0.01; p < 0.001, respectively). The production of nitrites, used as an indicator of cellular oxidative stress, was significantly decreased (p < 0.01). Gene expression levels compared to the control group increased for COL2A1 (p < 0.01), ACAN (p < 0.05), TIMP-1 and −3 (p < 0.01), while a decrease in mRNA levels of MMP-13 (p < 0.05) and IL1β (p < 0.001) was noticed. r-IR pretreatment of hNPCs cultured in pro-inflammatory conditions resulted in a rescue of metabolic activity (p < 0.001), as well as a decrease of IL-1β (p < 0.05) levels. Similarly, incubation of hNPCs with IL-1β and subsequent exposure to r-IR led to an increment of hNPC metabolic activity (p < 0.001), COL2A1 gene expression (p < 0.05) and a reduction of IL-1β (p < 0.05) and ADAMTS-5 gene levels (p < 0.01). CONCLUSIONS:. The present study suggested that irisin may stimulate hNPCs proliferation, metabolic activity, and anabolism by reducing the expression of IL-1β and catabolic enzymes while promoting the synthesis of extracellular matrix components. Furthermore, this myokine was able to blunt the catabolic effect of in vitro inflammation. Our results indicate that irisin may be one of the mediators by which physical exercise and muscle tissues modulate IVD metabolism, thus suggesting the existence of a biological cross-talk mechanism between the muscle and the IVD

The development of cytoplasmic processes from in situ chondrocytes is a characteristic feature of early osteoarthritis in human cartilage. The processes involve cytoskeletal elements and are distinct from the short primary cilia described in human chondrocytes. Vimentin is an intermediate filament playing an essential structural and signal-transduction role. We determined cellular levels and distribution of vimentin in chondrocytes of different morphologies in non-degenerate and mildly osteoarthritic cartilage. Femoral heads were obtained after consent from patients undergoing hip arthroplasty following femoral neck fracture. Cartilage explants were graded as non-degenerate (grade 0;G0) or mildly osteoarthritic (grade 1;G1) and labelled with the cytoplasmic dye CMFDA (5-chloromethylfluorescein-diacetate) for cell shape. Explants were cryosectioned and labelled for vimentin by fluorescence immunohistochemistry. In situ chondrocyte morphology was identified by confocal microscopy as either normal (rounded/elliptical) or abnormal (with one or more cytoplasmic process of ≥2µm) and vimentin levels and distribution determined semi-quantitatively and related to chondrocyte morphology. When all cells in G0 and G1 cartilage were compared, there was no difference between average levels of vimentin per cell (P=0.144)[6(261)];femoral heads:cells). When cells were separated on the basis of morphology, there was no difference between vimentin levels in cells with one or more cytoplasmic process compared to those of normal morphology (P>0.05;[6(261)]). However vimentin levels were much greater at the base of cytoplasmic processes compared to distant areas of the same cells (P=0.021)[5(29)]). Although overall levels of chondrocyte vimentin do not change in these early stages of osteoarthritis, the formation and structure of these substantial chondrocyte cytoplasmic processes involves changes to its distribution. These morphological changes are similar to those occurring during chondrocyte de-differentiation to fibroblasts reported in osteoarthritis which results in the formation of mechanically-inferior fibro-cartilage. Alterations to chondrocyte vimentin distribution either directly or indirectly may play a role in cartilage degeneration

Introduction. In vitro expansion of human articular chondrocytes (HACs) is required for cell-based strategies to treat cartilage defects. We have earlier shown that culturing HACs at increased osmolarity (i.e., 380 mOsm), as compared to plasma osmolarity (i.e., 280 mOsm), increases collagen type II (COL2A1) expression in vitro. Our earlier results showed that knockdown of TGF-β2, a prototypic member of the TGF-β superfamily and an accepted key regulator of chondrocyte differentiation, resulted in increased COL2A1 production. BMPs are members of the TGF-β superfamily which are known to be involved in the regulation of COL2A1 expression. In this study, we aimed to elucidate the role of BMP signaling, in the upregulation of COL2 production upon TGF-β2 knockdown (KD) under hyperosmotic culture conditions. Methods. HACs from five OA patients (passage 1) were cultured in cytokine-free medium, under 280 or 380 mOsm respectively, under standard 2D in vitro conditions. TGF-β2 knockdown (KD) by siRNA was performed in the presence or absence of the established bone morphogenetic protein (BMP) type I receptor (BMPRI) inhibitor dorsomorphin (10 μM). Expression of COL2A1 was evaluated by qRT-PCR. Results. Culturing HACs at 380 mOsm increased COL2A1 mRNA expression. Addition of dorsomorphin decreased COL2A1 mRNA expression at both 280 and 380 mOsm, but its expression was still significantly higher at 380 mOsm. In hyperosmotic 380 mOsm culture conditions, TGF-β2 KD further increased COL2A1 mRNA expression, while addition of dorsomorphin under these conditions abrogated this effect. Still, expression of COL2A1 mRNA levels remained higher as compared to 280 mOsm. Conclusion. This study confirms that BMP signalling is involved in the expression of the single best accepted key chondrocyte marker, COL2A1, in osteoarthritic HACs. However, inhibition of BMP signalling could not abrogate the increase in COL2A1 expression under hyperosmotic culture conditions. Our data suggest an inverse regulation of TGF-β2 and COL2A1, under these conditions, which may largely be dependent on increased BMPRI-mediated cell signaling. Our findings further suggest that hyperosmotic culture improves COL2A1 expression by means that are independent of TGF-β- and BMPRI-signaling. Further elucidation of the molecular network underlying this observation is ongoing

Introduction. Bone and joint infection (BJI) is often characterized by severe inflammation and progressive bone destruction. Osteocytes are the most numerous and long-lived bone cell type, and therefore represent a potentially important long-term reservoir of bacterial infection. Staphylococcus aureus is known to establish stable intracellular osteocytic infections, however, little is known about the less virulent yet second most prevalent BJI pathogen, S. epidermidis, associated with late-diagnosed, chronic BJI. Thus, this study sought to establish an in vitro model to study the infection characteristics of S. epidermidis in human osteocyte-like cells. Methods. SaOS2 cells (1 ×10. 4. cells/cm. 2. ) were grown to confluence either without differentiation, representing an osteoblast-like (OB) state (SaOS2-OB) or differentiated to an osteocyte-like stage (SaOS2-OY), using established methods. Four S. epidermidis strains used (ATCC-12228, ATCC-14990, ATCC-35984 and a clinical osteomyelitis strain RAH-SE1) were tested to be Lysostaphin-resistant, necessitating antibiotic (Levofloxacin) control of extracellular bacteria. Infection of host cells (OB or OY) was tested at three multiplicities of infection (MOI: 10, 100 and 1000). Extracellular bacteria were controlled by overnight incubation at a 10X minimum inhibitory concentration (MIC) of Levofloxacin and thereafter at 1XMIC. At each time point (days 1, 3, 5) viable intra- and extracellular bacteria were quantified. Result. All strains displayed similar intracellular infection and persistence capabilities in SaOS2-OB and SaOS2-OY. Independent of MOI, intracellular bacteria in SaOS2-OB decreased over time, becoming non-culturable by day 5. In contrast, SaOs2-OY displayed enhanced intracellular bacterial persistence at each time point. In the presence of increased Levofloxacin concentration (10XMIC), S. epidermidis could persist intracellularly for at least 14 days. Conclusion. This study showed for the first time that S. epidermidis can infect human osteocytes and persist intracellularly. Additionally, even a 10xMIC antibiotic concentration failed to eradicate intracellular bacteria, suggesting that persistence within osteocytes could contribute to treatment failure and establishment of chronic BJI

Abstract. Background. Ultrasonic cutting of bone boasts many advantages over alternatively powered surgical instruments, including but not limited to: elimination of swarf, reduced reaction forces, increased precision in cutting and reduced adjacent soft tissue damage, reduced post-operative complications such as bleeding and bone fracture, reduced healing time, reduced intra-operative noise and ease of handling. Despite ultrasonic cutting devices being well established in oral and maxillofacial surgery, applications in orthopaedic surgery are more niche and are not as well understood. The aim of this study was to investigate the cutting speed (mm/s) and cutting forces (N) of orthopaedic surgeons using a custom-designed state of the art ultrasonic cutting tool to cut fresh human bone samples. Methods. A setup based on the Robot Operating System (ROS) and AprilTag was designed to track and to record the real time position of the ultrasonic cutting tool in space. Synchronised load cell axial force readings of three separate orthopaedic surgeons during ultrasonic cutting were recorded. Each surgeon was asked to find a comfortable position that reflects as close as possible their clinical handling of a cutting instrument used in surgery, and to perform two cuts in each of three samples of human cortical bone. Bone samples were obtained following ethical approval from an institutional review board (ethics approval number: SR1342) and prior informed consent was obtained from all patients. Bone samples were extracted from the femoral neck region of three hip osteoarthritis patients. During cutting, surgeons were allowed a total cutting time of one minute and cutting was conducted using an ultrasonic tool with frequency of a 35kHz (35.7 µm peak to peak displacement amplitude) under constant irrigation using a MINIPULS® 3 Peristaltic pump (38 revolutions per minute) using Phosphate-Buffered Saline (PBS) at 25°C. From the recorded data, the average instantaneous cutting velocity was calculated and the maximum cutting force was identified. Results. All surgeons assumed a back-and-forth cutting motion, variation in the applied cutting force was observed. The average vertical cutting speed, axial cutting force and cutting depth across all surgeons and all samples was 1.64 mm/s, 1.91 N and 0.73 mm, respectively. While increasing the axial cutting force resulted in a deeper cut, overloading of the ultrasound transducer occurred when the tool advanced too quickly into the bone tissue during cutting. The exact force threshold, or the optimal speed at which the surgeon can maintain a constant force during cutting, requires further investigation. Conclusions. In this study, all surgeons cut using a back-and-forth cutting motion, with variation in the applied cutting force which may ultimately inform which clinical applications in orthopaedic engineering are most suitable for this technology. Applying too much force caused overloading of the ultrasound transducer, which is a limitation with the current cutting tool. The results from this study may facilitate the eventual uptake of ultrasonic cutting tools for application in orthopaedic surgery. Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Spontaneous muscle regenerative potential is limited, as severe injuries incompletely recover and result in chronic inflammation. Current therapies are restricted to conservative management, not providing a complete restitutio ad integrum; therefore, alternative therapeutic strategies are welcome, such as cell-based therapies with stem cells or Peripheral Blood Mononuclear Cells (PBMCs). Here, we described two different in vitro myogenic models: a 2D perfused system and a 3D bioengineered scaffold within a perfusion bioreactor. Both models were assembled with human bone marrow-derived mesenchymal stem cells (hBM-MSCs) and human primary skeletal myoblasts (hSkMs) to study induction and maintenance of myogenic phenotype in presence of PBMCs. When hBM-MSCs were cultured with human primary skeletal myoblasts (hSkMs) in medium supplemented with 10 ng/mL of bFGF; cells showed increased expression of myogenic-related gene, such as Desmin and Myosin Heavy Chain II (MYH2) after 21 days, and a prevalent expression of anti-inflammatory cytokines (IL10, 15-fold). Next, PBMCs were added in an upper transwell chamber and hBM-MSCs significantly upregulated myogenic genes throughout the culture period, while pro-inflammatory cytokines (e.g., IL12A) were downregulated. In 3D, hBM-MSCs plus hSkMs embedded in fibrin-based scaffolds, cultured in dynamic conditions, showed that all myogenic-related genes tended to be upregulated in the presence of PBMCs, and Desmin and MYH2 were also detected at protein level, while pro-inflammatory cytokine genes were significantly downregulated in the presence of PBMCs. In conclusion, our works suggest that hBM-MSCs have a versatile myogenic potential, enhanced and modulated by PMBCs. Moreover, our 3D biomimetic approach seemed to better resemble the tissue architecture allowing an efficient in vitro cellular cross-talk

Hip joint biomechanics can be altered by abnormal morphology of the acetabulum and/or femur. This may affect load distribution and contact stresses on the articular surfaces, hence, leading to damage and degradation of the tissue. Experimental hip joint simulators have been used to assess tribology of total hip replacements and recently methods further developed to assess the natural hip joint mechanics. The aim of this study was to evaluate articular surfaces of human cadaveric joints following prolonged experimental simulation under a standard gait cycle. Four cadaveric male right hips (mean age = 62 years) were dissected, the joint disarticulated and capsule removed. The acetabulum and femoral head were mounted in an anatomical hip simulator (Simulation Solutions, UK). A simplified twin peak gait cycle (peak load of 3kN) was applied. Hips were submerged in Ringers solution (0.04% sodium azide) and testing conducted at 1 Hertz for 32 hours (115,200 cycles). Soft tissue degradation was recorded using photogrammetry at intervals throughout testing. All four hips were successfully tested. Prior to simulation, two samples exhibited articular surface degradation and one had a minor scalpel cut and a small area of cartilage delamination. The pre-simulation damage got slightly worse as the simulation continued but no new areas of damage were detected upon inspection. The samples without surface degradation, showed no damage during testing and the labral sealing effect was more obvious in these samples. The fact that no new areas of damage were detected after long simulations, indicates that the loading conditions and positioning of the sample were appropriate, so the simulation can be used as a control to compare mechanical degradation of the natural hip when provoked abnormal conditions or labral tissue repairs are simulated