Background. Sclerostin is a secreted glycoprotein that inhibits the intracellular Wnt signaling pathway, which when inactivated bone formation is stimulated. This stimulation has been proven in fracture studies, showing larger and stronger calluses with accelerated fracture healing, both in sclerostin knockout and sclerostin antibody injection models. The effects of these two mechanisms have not been compared to assess the accurate effect of the Scl-Ab injections. Therefore we designed a study to compare the effect of sclerostin depletion (sclerostin knockout) and inhibition (Scl-Ab injection). Methods. 10-week-old male SOST knockout (KO) (N=20) and Wild-type (WT) (N=40) mice underwent insertion of a tibial intramedullary pin after which a mid-shaft tibial osteotomy was performed. The mice were divided into three groups: SOST KO (N=20), WT with Scl-Ab injection “intravenous dose of 100mg/kg weekly” (N=20) and WT with saline injection (N=20). Each group was managed and sacrificed according to the specified protocol. Results. Both Scl-Ab and KO groups showed significantly increased trabecular bone volume/ total volume at the fracture site compared to the saline group at all time points and also showed no significant difference between them (except at 28 days postoperative). On biomechanical testing the Scl-Ab and KO groups showed significant increased strength in stiffness at days 14, 28 and 35 compared to the saline group. Discussion and Conclusion. Scl-Ab injections showed promising results, which were comparable to the complete depletion of sclerostin, especially at earlier stages of the healing process and thus completing the process of healing at an earlier time point

The increased incidence of type 2 Diabetes Mellitus is associated with an impaired skeletal structure and a higher prevalence of bone fractures. Sclerostin is a negative regulator of bone formation produced by osteocytes and there is recent evidence that its expression in serum is elevated in diabetic patients compared to control subjects. In this study, we test whether hyperglycemia affects serum and bone sclerostin levels in a rat model of type 2 Diabetes as well as sclerostin production by osteoblasts in culture. We used Zucker diabetic fatty (ZDF) male rats (n=6) that spontaneously develop obesity and frank diabetes around 8–9 weeks of age and Zucker lean rats as controls (n=6) to examine sclerostin expression in serum at 9, 11 and 13 weeks using a specific ELISA. Sclerostin expression in bone tibiae was examined at 12 weeks using immunocytochemistry. Rat osteoblast-like cells UMR-106 were cultured in the presence of increasing concentrations of glucose (5, 11, 22 and 44 mM) during 48 hours and sclerostin mRNA expression and release in the supernatant determined by quantitative PCR and ELISA, respectively. Our results show that serum sclerostin levels are higher in the diabetic rats compared to lean rats at 9 weeks (+ 140%, p<0.01). Our preliminary results using immunocytochemistry for sclerostin did not show any major difference in sclerostin expression in tibiae of diabetic rats compared to lean ones, although we observed many osteocytic empty lacunae in cortical bone from diabetic rats. Glucose dose-dependent stimulated sclerostin mRNA and protein production in mature UMR106 cells while it had no effect on osteocalcin expression. Altogether, our data suggest that sclerostin production by mature osteoblasts is increased by hyperglycemia in vitro and enhanced in serum of diabetic rats. Furthers studies are required to determine whether sclerostin could contribute to the deleterious effect of Diabetes on bone

Introduction. Sclerostin has been implicated in mechanotransduction in bone and recent data show a lack of response to loading in the sclerostin transgenic mouse. Sclerostin, the protein product of the SOST gene, is an attractive therapeutic target for low bone mass conditions, including osteoporosis. It is expressed exclusively by mature osteocytes in bone and we have shown that sclerostin targets pre-osteocytes/osteocytes to regulate bone mineralization and osteoclast activity, as well as inducing catabolic gene expression in osteocytes themselves and promoting osteocyte-mediated bone loss (osteocytic osteolysis). The aim of this study was to examine the direct effects of sclerostin on anabolic responses to loading in bone ex vivo. Methods. 10 × 5mm bovine sternum trabecular bone cores were perfused with osteogenic media at 37°C for up to 3 weeks in individual bone culture chambers. The cores were divided into 3 groups; a) mechanically loaded (300 cycles, 4000 μstrain, 1 Hz/day), b) identical loading regime with continuous perfusion of 50 ng/ml recombinant human sclerostin and c) unloaded controls. Loading was accomplished using a second-generation Zetos™ bone loading system. Daily measurements of bone stiffness (Young's modulus), media pH and ionic calcium concentrations were made. Histomorphometric assessment, including fluorochrome labelling analysis, was made of resin-embedded, non-decalcified samples at the end of the experiment. Gene expression in the bovine bone was examined by real-time RT-PCR. Results. Bovine bone cores showed a steady increase in Young's modulus with daily application of mechanical loading. This increase in stiffness was blocked by the co-addition of sclerostin. Sclerostin also induced bone acidification and a net release of bone calcium, indicated by the decrease in media pH and the relative increase in ionic calcium concentrations in the presence of sclerostin. Sclerostin also completely abrogated loading-induced calcium/calcein uptake. Sclerostin induced an increase in the expression of the bone resorption genes, tartrate resistant acid phosphatase (TRAP), carbonic anhydrase and cathepsin K and induced the release of β-CTX. Histological examination revealed a significant increase in the size of the osteocyte lacunae in sclerostin-treated bone cores, suggesting a role for osteocytic osteolysis in this effect. Discussion/Conclusion. The observation that sclerostin abrogated the loading-induced increase in bone stiffness constitutes direct evidence for a negative effect of sclerostin on the anabolic response to mechanical loading. Our findings may be explained in part by the observation that sclerostin negatively controls mineralization by late osteoblasts and pre-osteocytes (1). It is also possible that osteocytes themselves are capable of releasing bone mineral in response to sclerostin. This study demonstrates that sclerostin directly antagonises the anabolic effects of mechanical loading in the absence of external (circulating, neural, hormonal) influences. The mechanisms, by which sclerostin exerts these effects, warrant further study

Sclerostin (SOST) is an endogenous inhibitor of Wnt/β-catenin signalling pathway to impair osteogenic differentiation and bone anabolism. SOST immunotherapy like monoclonal antibody has been observed to control bone remodeling and regeneration. This study is aimed to develop a SOST vaccine and test its protective effects on estrogen deficiency-induced bone loss in mice. Gene sequences coded SOST peptide putative targeting Wnt co-receptor LRP5 were cloned and constructed into vectors expressing Fc fragment to produced SOST-Fc fusion protein. Mice were subcutaneously injected SOST-Fc to boost anti-SOST antibody. Bone mineral density, microstructure, and mechanical property were quantified using μCT scanning and material testing system. Serum bone formation and resorption markers and anti-SOST levels were measured using ELISA. SOST-Fc injections significantly increased serum anti-SOST antibody levels but reduced serum SOST concentrations. SOST-Fc vaccination significantly reduced estrogen deficiency-induced serum bone resorption markers CTX-1 increased serum bone formation marker osteocalcin. Of note, it significantly alleviated the severity of estrogen-induced loss of bone mineral density, trabecular morphometric properties, and biomechanical forces of bone tissue. Mechanistically, SOSF-Fc vaccination attenuated trabecular loss histopathology and restored immunostaining of Wnt pathway like Wnt3a, β-catenin, and TCF4 in bone tissue along with increased serum osteoclast inhibitor OPG levels but decreased serum osteoclast enhancer RANKL concentrations. Taken together, SOST-Fc vaccination boosts anti-SOST antibody to neutralize SOST and mitigates the estrogen deficiency-induced bone mass and microstructure deterioration through preserving Wnt signalling. This study highlights an innovative remedial potential of SOST vaccine for preventing osteoporosis

Summary Statement. This study demonstrated that Sclerostin monoclonal antibody (Scl-Ab) enhanced bone healing in the rat osteotomy model. Scl-Ab increased callus size, callus bone volume fraction, rate of callus bone formation and fracture callus strength. Introduction. Sclerostin is a protein secreted by osteocytes and is characterized as a key inhibitor of osteoblast-mediated bone formation. Previous studies demonstrated that treatment with a sclerostin monoclonal antibody (Scl-Ab) results in significantly increased bone formation, bone mass and strength in rat closed fracture model (1–2). However, the effects of Scl-Ab on healing of open fracture model have not yet been reported in rats. Previously in ORS and ASBMR Annual Meeting, we have reported that Scl-Ab promoted the open fracture healing at week 3 and week 6 post-fracture. Here we extended our investigation for up to week 9 with additional histological assessments and dynamic histomorphometric analysis to investigate the effects of systemic administration of Scl-Ab on a later phase of fracture repair. Patients & Methods. Animal research ethics approval was obtained from our institute (reference No. 09/042/MIS), and the institute's guidelines for the care and use of laboratory animals were followed. In total, 120 six-month-old male SD rats were randomly divided into Scl-Ab group and vehicle group after a transverse osteotomy performed at the mid-shaft of right femur with internal fixation. One day post-surgery, rats were treated with a rodent Scl-Ab (Scl-Ab IV, s.c. injection, 25 mg/kg, 2 times per week) or vehicle for 3, 6 or 9 weeks. The progress of fracture healing for each animal was monitored weekly by digital radiography. Images acquired 3, 6 and 9 weeks post-operation were analyzed by ImageJ to quantify the total area of the fracture calluses. After euthanasia, femora were collected and subjected to the following analyses: micro-CT for bone mineral density (BMD) and callus volume fraction (BV/TV), micro-CT-based angiography for angiogenesis, histological evaluation and dynamic histomorphometry, and four-point mechanical testing for ultimate load, energy to failure and stiffness (3–6). Two-way ANOVA with Bonferroni post-hoc test was used to analyze the data. Significance level was set at P<0.05. Results. Radiographically, Scl-Ab treatment groups had significantly larger fracture calluses compared with respective vehicle group starting from week 3 post-fracture by quantitative analysis. Micro-CT analysis showed that Scl-Ab treatment groups had significantly higher callus bone volume fraction (+16–23%, P<0.01) and BMD (+15–16%, P<0.01) compared with respective vehicle groups at all time points post-fracture. Histological analysis also revealed more bone and less cartilage tissue in calluses in Scl-Ab group starting at week 3, which is explained by faster in the rate of new bone formation in fluorescence microscopy. Micro-CT based angiography demonstrated that Scl-Ab significantly enhanced neovasculation at the fracture calluses at week 3. Four-point bending test showed significantly higher ultimate load in Scl-Ab group than vehicle group at week 6 (+98%, P<0.01) and week 9 (+45%, P<0.05) post-fracture. In addition, ultimate load at week 6 of Scl-Ab group was at the similar level as seen at week 9 of the vehicle group, indicating the increased healing by Scl-Ab in this model. Stiffness (week 6 and 9) and energy to failure (week 6) were also tended higher in Scl-Ab group. Discussion/Conclusion. This study demonstrated that Scl-Ab enhanced bone healing in the rat osteotomy model. Scl-Ab increased callus size, callus bone volume fraction, rate of callus bone formation and fracture callus strength. Neovasculation was enhanced in the Scl-Ab group at week 3, implying Scl-Ab may enhance coupling of osteogenesis and angiogenesis. Scl-Ab treatment also resulted in more bone and less cartilage tissue in fracture calluses. Our results indicated that the systemic administration of Scl-Ab enhanced open fracture healing in rat femoral osteotomy model

Osteoporotic fracture has become a major problem in ageing population and often requires prolonged healing time. Low Intensity Pulsed Ultrasound (LIPUS) can significantly enhance fracture healing through alteration of osteocyte lacuno-canalicular network (LCN). DMP1 in osteocytes is responsible for maintaining LCN and mineralisation. This study aims to investigate osteocyte-specific DMP1's role in enhanced osteoporotic fracture healing in response to mechanical stimulation. Bilateral ovariectomy was performed in 6-month-old female SD rats to induce osteoporosis. Metaphyseal fracture was created at left distal femur using oscillating micro-saw. Rats were randomised to groups: (1) DMP1 KD, (2) DMP1 KD + LIPUS, (3) Control, or (4) Control + LIPUS, where KD stands for knockdown by injection of shRNA into marrow cavity 2 weeks before surgery. Assessments included weekly radiography, microCT and immunohistochemistry on DMP1, E11, FGF23 and sclerostin. DMP1 KD significantly impaired LIPUS-accelerated fracture healing when comparing KD + LIPUS group to Control + LIPUS group. The X-ray relative opacity showed less tissue growth at all timepoints (Week 1, 3 & 6; p=0.000, 0.001 and 0.003 respectively) and the bone volume fraction was decreased after DMP1 KD at Week 3 (p=0.006). DMP1 KD also significantly altered the expression levels of osteocyte-specific DMP1, E11, FGF23 and sclerostin during healing process. The lower relative opacity and bone volume fraction in DMP1 KD groups indicated that knockdown of DMP1 was associated with poorer fracture healing process compared to non-knockdown groups. The similar results between knockdown group with and without LIPUS showed that blockage of DMP1 would negate LIPUS-induced enhancement on fracture healing. Acknowledgment: General Research Fund (Ref: 14113018)

Abstract. Objectives. The mechanisms underlying abnormal joint mechanics are poorly understood despite it being a major risk factor for developing osteoarthritis. This study investigated the response of a 3D in vitro bone cell model to mechanical load. Methods. Human MSC cells (Y201) embedded in 3D type I collagen gels were differentiated in osteogenic media for 7-days in deformable, silicone plates. Gels were loaded once (5000 µstrain, 10Hz, 3000 cycles), RNA extracted 1-hr post load and assessed by RT-qPCR and RNAseq analysis (n=5/treatment). Cell shape and phenotype were assessed by immunocytochemistry and phalloidin staining. Data was analysed by Minitab. Results. RTqPCR revealed cells expressed markers of mature osteocytes (E11, sclerostin, DMP-1) and osteoprotegerin (OPG), alkaline phosphatase and type I collagen (COL1A1). Immunolocalisation of sclerostin and DMP-1 protein along with phalloidin staining confirmed a dendritic osteocyte phenotype. Load almost abolished sclerostin gene expression (p=0.05) and reduced E11 (2-fold p=0.03); COL1A1 was unchanged (p=0.349). Using DEseq2 analysis, of the 981 genes differentially regulated more than 2-fold at FDR p<0.05, 159 were downregulated and 821 upregulated by load. These were involved in processes important in bone biology including the inflammatory response (56 genes), ECM organisation (27), ageing (30), response to mechanical load (23), ER stress (34), regulation of ossification (26), bone morphogenesis (14), cartilage development (14), programmed cell death (161), and positive regulation of bone mineralisation (6). Discussion. Y201 cells were successfully differentiated to osteocytes. The osteocytes’ mechanical response revealed regulation of factors that contribute to bone remodelling and inflammation. Since the biological mechanisms underlying mechanically induced joint degeneration are unclear, there is a need for humanised, cell models to delineate molecular pathways activated by mechanical load. Such pathways may reveal the molecular basis for genetic predispositions to osteoarthritis and identify new therapeutic targets. 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

3D cell culture studies more accurately represent the complex in vivo mechanical environment of human bone and are, thus, superior to 2D studies when testing the efficacy of osteoporosis therapies. As such, the objective of this study was to use a 3D model to investigate the effect of sclerostin antibodies. Sclerostin is a protein, which inhibits osteoblasts and is downregulated under mechanical stimulation. It is not yet known how expression of sclerostin mediates the site-specific and temporal changes in mineralisation. To address this, we developed a 3D cellular niche of MC3T3 osteoblasts encapsulated within gelatin and applied mechanical loading to the constructs using a custom-designed compression bioreactor system (0.5% strain at 0.5 Hz, 1 hr/day) (VizStim) under continuous perfusion of cell culture media. Osteoblasts were pretreated with estrogen for 14 days, followed by estrogen withdrawal (EW) to simulate postmenopausal conditions. 3D constructs were successfully fabricated and actin staining revealed the formation of dendritic cells under both static and stimulated conditions indicative of osteocyte-like cells. Under static conditions, estrogen treatment enhanced production of calcium by osteoblasts when compared to the same cells cultured under estrogen deficient conditions. Overall, preliminary results propose a link between mechanical stimulation, estrogen deficiency and mineral production by osteoblasts. Ongoing studies are comparing the static and stimulated groups after a longer culture period of 21 days using sclerostin antibodies. This research aims to deliver further understanding of the mechanical regulation of bone formation, and will inform novel approaches for regeneration of bone tissue and treatment of osteoporosis

Wear debris from implant interfaces is the major factor leading to periprosthetic osteolysis. Fibroblast-like synoviocytes (FLSs) populate the intimal lining of the synovium and are in direct contact with wear debris. This study aimed to elucidate the effect of Ti particles as wear debris on human FLSs and the mechanism by which they might participate in the bone remodeling process during periprosthetic osteolysis. FLSs were isolated from synovial tissue from patients, and the condition medium (CM) was collected after treating FLSs with sterilized Ti particles. The effect of CM was analyzed for the induction of osteoclastogenesis or any effect on osteogenesis and signaling pathways. The results demonstrated that Ti particles could induce activation of the NFκB signaling pathway and induction of COX-2 and inflammatory cytokines in FLSs. The amount of RANL in the conditioned medium collected from Ti particle-stimulated FLSs (Ti CM) showed the ability to stimulate osteoclast formation. The Ti CM also suppressed the osteogenic initial and terminal differentiation markers for osteoprogenitors, such as alkaline phosphate activity, matrix mineralization, collagen synthesis, and expression levels of Osterix, Runx2, collagen 1α, and bone sialoprotein. Inhibition of the WNT and BMP signaling pathways was observed in osteoprogenitors after the treatment with the Ti CM. In the presence of the Ti CM, exogenous stimulation by WNT and BMP signaling pathways failed to stimulate osteogenic activity in osteoprogenitors. Induced expression of sclerostin (SOST: an antagonist of WNT and BMP signaling) in Ti particletreated FLSs and secretion of SOST in the Ti CM were detected. Neutralization of SOST in the Ti CM partially restored the suppressed WNT and BMP signaling activity as well as the osteogenic activity in osteoprogenitors. Our results reveal that wear debris-stimulated FLSs might affect bone loss by not only stimulating osteoclastogenesis but also suppressing the bone-forming ability of osteoprogenitors. In the clinical setting, targeting FLSs for the secretion of antagonists like SOST might be a novel therapeutic approach for preventing bone loss during inflammatory osteolysis

Abstract. INTRODUCTION. The mechanisms underlying abnormal joint mechanics are poorly understood despite it being a major risk factor for developing osteoarthritis. Glutamate signalling has been implicated in osteoarthritic bone changes and AMPA/kainate glutamate receptor (GluR) antagonists alleviate degeneration in rodent models of osteoarthritis. We investigated whether glutamate signalling molecules are mechanically regulated in a human, cell-based 3D model of bone. METHODS. Human Y201 MSC cells embedded in 3D type I collagen gels (0.05 × 106 cell/gel) differentiated to osteocytes were mechanically loaded in silicone plates (5000 µstrain, 10Hz, 3000 cycles) or not loaded (n=5/group). RNA extracted 1-hr post load was quantified by RTqPCR and RNAseq whole transcriptome analysis (NovaSeq S1 flow cell 2 × 100bp PE reads). Differentially expressed GluRs and glutamate transporters (GluTs) were identified using DEseq2 analysis on normalised count data. Genes were considered differentially expressed if >2 fold change and FDR p<0.05. RESULTS. Cells expressed mature osteocyte markers (E11, sclerostin, DMP-1). DEseq2 analysis, revealed 981 mechanically regulated genes. Mechanical loading upregulated kainate GluRs, GRIK2 (1.6 fold, p=0.024) and GRIK5 (4.2 fold, p=0.045); the NMDA GluR GRIN3B (3.25 fold, p=0.047) and the GluT SLC1A1 (3 fold, p=0.037). Conversely, AMPA GRIA3, NMDA GluRs GRIN2A&C, and the GluT SLC1A2 were down regulated by 50–60%, although not significant. Kainate GRIK3&4; AMPA GRIA2, NMDA GRIN1, and GluTs SLC1A6&A7 were not expressed in control or loaded osteocytes, whereas GluRs (GRIK1, GRIA1&4, GRIN2B&2D&3A) and GluT SLC1A3 were expressed but not regulated by mechanical loading. DISCUSSION. Mechanical loading of human osteocytes in 3D revealed that they regulated expression of glutamate receptors and transporters. This is consistent with our observation that mechanical perturbation after joint injury in rodent models of OA regulates glutamatergic signalling in the bone thus linking mechanical stimuli to inflammatory and nociceptive pathways mediated by glutamate receptors. Declaration of Interest. (a) fully declare any financial or other potential conflict of interest

Fragility fractures are skeletal complications associated with type 2 diabetes (T2D) causing disability, hospitalization, impaired quality of life, and increased mortality. Increased circulating sclerostin and accumulation of advanced glycation end-products (AGEs) are two potential mechanisms underlying low bone turnover and increased fracture risk. We have recently shown that T2D affects the expression of genes controlling bone formation (SOST and RUNX2) and that accumulation of AGEs is associated with impaired bone formation in T2D. We hypothesized that Wnt/B- catenin target genes are down-regulated in bone of T2D subjects as a consequence of decreased SOST and AGEs accumulation. To this end, we studied gene expression in extracts of bone samples obtained from femoral heads of 14 subjects with relatively well-controlled T2D (HbA1c 6.5±1.7%) and 21 control, non-diabetic postmenopausal women (age >65 years) undergoing hip replacement. There were no differences in age (73.2± .8 vs. 75.2±8.5 years) or BMI (27.7±5.6 vs. 29.9±5.4 kg/m2) between control and T2D groups, respectively. Expression of LEF1 mRNA was significantly lower in T2D compared to non-diabetic subjects (p=0.002), while DKK1 was not different between groups (p=0.108). Correlation analysis showed that DKK1 (r2=0.038; p=0.043) and HbA1c (r2=0.503; p=0.048) increased with age in T2D. COL1A1 mRNA trended lower in T2D compared to controls (p=0.056). Bone volume (9,333 ± 1,443 vs. 15,53 ± 2,442 mm2; p=0.048), mineralized volume (9,278 ± 1,418 vs. 15,45 ± 2,444 mm. 2. ; p=0.048) and BV/TV (0,2125 ± 0,03114 vs. 0,3719 ± 0,03196 %; p=0.002) measured by bone histomorphometry were lower in T2D compared to controls. Our data show that even in patients with relatively good glycemic control, T2D decreases expression of Wnt/B-catenin target genes andCOL1A1, associated with decreased bone density. These results may help understand the mechanisms underlying bone fragility in T2D

Objectives. Osteoporosis and osteomalacia lead to increased fracture risk. Previous studies documented dysregulated osteoblast and osteoclast activity, leading to a high-turnover phenotype, reduced bone mass and low bone mineral content. Osteocytes, the most abundant bone cell type, are involved in bone metabolism by enabling cell to cell interaction. Osteocytes presence and viability are crucial for bone tissue homeostasis and mechanical integrity. Osseo-integration and implant degradation are the main problems in developing biomaterials for systemically diseased bone. This study examines osteocyte localisation, morphology and on the implant surface and at the implant bone interface. Furthermore, the study investigates ECM proteins regulation correlated to osteocytes and mechanical competence in an ovariectomised rat model with a critical size metaphyseal defect. Methodology. After induction of osteoporosis, 60 female Sprague-Dawley rats were randomised into five groups: SrCPC (n=15), CPC (n=15), ScB30 (n=15), ScB30Sr20 (n=15) and empty defect (n=15). The left femur of all animals underwent a 4mm wedge-shaped metaphyseal osteotomy that was internally fixed with a T-shaped plate. The defect was then either filled with the above mentioned implants or left empty. After six weeks, histomorphometric analysis showed a statistically significant increase in bone formation at the tissue-implant interface in the SrCPC group compared to the other groups (p<0.01). Osteocyte morphology and networks were detected using silver and staining. ECM proteins were investigated through immunohistochemistry. Cellular populations were tested using enzyme histochemistry. Mineralisation was assessed using time of flight secondary ion mass spectrometry (TOF-SIMS). Statistical analysis was performed using Mann Whitney U test with Bonferroni correction. Results. In the SrCPC and compared to other test groups, osteocytes presence and morphology was enhanced. An increased osteocytic activity was also seen in ScB30Sr20 when compared to SCB30 alone. Local osteomalatic lesions characterised by the presence of excessive unmineralised osteoid as revealed by the VKVG staining in the intact bone was also seen. A regular pattern of osteocytes distribution reflecting a better bone maturation was also seen in case of the Sr substituted cements. Whereas in case of the ScB30 degenerated osteocytes with a comparatively irregular arrangement were seen. Nonetheless, ECM proteins indicating discrepant bone turnover (RANKL, OPG, BMP2, OCN; ASMA) were noticed to increase within these regions and were accompanied by the presence of apoptotic osteocytes. Interestingly, osteocytes were also localised near the blood vessels within the newly formed woven bone. On the other hand, osteocytes allocation at implant bone interface and on the implant surface were qualitatively better in the Sr substituted groups when compared to the other test groups. Furthermore, this correlates with healing enhancement and implant retention results obtained from the histomorphometry (BV/TV and Osteoclasts count). The first qualitative results of the sclerostin visualisation showed a lower expression in the Sr supplemented biomaterials compared to the Sr free ones. Conclusion. Osteoblasts, osteoclast and osteocytes are the key players to bone metabolism through production and mineralisation of ECM or resorption. The current study indicates the importance in therapeutically targeting osteocytes to regulate bone metabolism in osteoporotic/osteomalatic bone. Sr inhibits osteoclast activity which is important for implant degradation. However, in osteoporotic bone osteoclasts inhibition is crucial to enhance the healing. Our data suggest that osteocytes allocation at the bone implant interface and on the implant surface is aiding in implant degradation through osteocytes dependent resorption. Currently, discrepancies in mechanosensitivity, proliferation and fibrotic tissue formation are being investigated together with several anchorage proteins to quench further effects of osteocyte presence at the implant bone interface

Intermittently administered parathyroid hormone (PTH 1-34) has been shown to promote bone formation in both human and animal studies. The hormone and its analogues stimulate both bone formation and resorption, and as such at low doses are now in clinical use for the treatment of severe osteoporosis. By varying the duration of exposure, parathyroid hormone can modulate genes leading to increased bone formation within a so-called ‘anabolic window’. The osteogenic mechanisms involved are multiple, affecting the stimulation of osteoprogenitor cells, osteoblasts, osteocytes and the stem cell niche, and ultimately leading to increased osteoblast activation, reduced osteoblast apoptosis, upregulation of Wnt/β-catenin signalling, increased stem cell mobilisation, and mediation of the RANKL/OPG pathway. Ongoing investigation into their effect on bone formation through ‘coupled’ and ‘uncoupled’ mechanisms further underlines the impact of intermittent PTH on both cortical and cancellous bone. Given the principally catabolic actions of continuous PTH, this article reviews the skeletal actions of intermittent PTH 1-34 and the mechanisms underlying its effect.

Cite this article: L. Osagie-Clouard, A. Sanghani, M. Coathup, T. Briggs, M. Bostrom, G. Blunn. Parathyroid hormone 1-34 and skeletal anabolic action: The use of parathyroid hormone in bone formation. Bone Joint Res 2017;6:14–21. DOI: 10.1302/2046-3758.61.BJR-2016-0085.R1.

Objectives

Osteoporosis is a chronic disease. The aim of this study was to identify key genes in osteoporosis.