Introduction. Promoting bone mass homeostasis keeps skeleton away from osteoporosis. a-Ketoglutarate (a-KG) is an indispensable intermediate of tricarboxylic acid cycle (TCA) process for cellular energy production. a-KG mitigates cellular senescence, tissue degeneration, and oxidative stress. We investigated whether a-KG affected osteoblast activity or osteoporosis development. Method. Serum and bone specimens were biopsied from 26 patients with osteoporosis or 24 patients without osteoporosis who required spinal surgery. Ovariectomized or aged mice were fed 0.25% or 0.75% a-KG in drinking water for 8 – 12 weeks ad libitum. Bone mineral density, trabecular/cortical bone microarchitecture, mechanical strength, bone formation, and osteoclastic erosion were investigated using mCT, material testing device, in vivo calcein labelling, and TRAP histochemical staining. Serum a-KG, osteocalcin, and TRAP5b levels were quantified using ELISA kits. Bone-marrow mesenchymal cells and macrophages were incubated osteogenic and osteoclastogenic media. Histone H3K27me3 levels and enrichment were investigated using immunoblotting and chromatin precipitation-PCR. Result. Serum a-KG levels in patients with osteoporosis were less than controls; and were correlated with T-scores of hips (R2 = 0.6471, P < 0.0001) and lumbar spine (R2 = 0.7235, P < 0.001) in osteoporosis (AUC = 0.9941, P < 0.001). a-KG supplement compromised a plethora of osteoporosis signs in ovariectomized or aged mice, including bone mass loss, trabecular bone microarchitecture deterioration, and mechanical strength loss. It elevated serum osteocalcin levels and decreased serum TRAP5b. a-KG preserved caclein-labelling bone formation and repressed osteoclast resorption. It reversed osteogenic differentiation of bone-marrow stromal cells and reduced osteoclast formation in ovariectomized mice. Mechanically, a-KG attenuated H3K27 hypermethylation and Runx2 transcription repression, improving mineralized matrix production in osteogenic cells. Conclusion. Decreased serum a-KG is correlated with human and murine osteoporosis. a-KG reverses bone loss by repressing histone methylation in osteoblasts. This study highlighted a-KG supplement as a new biochemical option for protecting osteoporosis

Aims

Continuous local antibiotic perfusion (CLAP) has recently attracted attention as a new drug delivery system for orthopaedic infections. CLAP is a direct continuous infusion of high-concentration gentamicin (1,200 μg/ml) into the bone marrow. As it is a new system, its influence on the bone marrow is unknown. This study aimed to examine the effects of high-concentration antibiotics on human bone tissue-derived cells.

Bone regeneration is pivotal for the healing of fractures. In case this process is disturbed a non-union can occur. This can be induced by environmental factors such as smoking, overloading etc. Co-morbidities such as diabetes, osteoporosis etc. may be more intrinsic factors besides other disturbances in the process. Those pathways negatively influence the bone regeneration process. Several intrinsic signal transduction pathways (WNT, BMP etc.) can be affected. Furthermore, on the transcriptional level, important mRNA expression can be obstructed by deregulated miRNA levels. For instance, several miRNAs have been shown to be upregulated during osteoporotic fractures. They are detrimental for osteogenesis as they block bone formation and accelerate bone resorption. Modulating those miRNAs may revert the physiological homeostasis. Indeed, physiological fracture healing has a typical miRNA signature. Besides using molecular pathways for possible treatment of non-union fractures, providing osteogenic cells is another solution. In 5 clinical cases with non-union fractures with defects larger than 10 cm, successful administration of a 3D printed PCL-TCP scaffold with autologous bone marrow aspirate concentrate and a modulator of the pathogenetic pathway has been achieved. All patients recovered well and showed a complete union of their fractures within one year after start of the regenerative treatment. Thus, non-union fractures are a diverse entity. Nevertheless, there seem to be common pathogenetic disturbances. Those can be counteracted at several levels from molecular to cell. Compositions of those may be the best option for future therapies. They can also be used in a more personalized fashion in case more specific measurements such as miRNA signature and stem cell activity are applied

Growing evidence has suggested that paracrine mechanisms of Mesenchymal stem cell (MSC) may be involved in the underlying mechanism of MSC after transplantation, and extracellular vesicles (EVs) are an important component of this paracrine role. The aim of this study was to investigate the in vitro osteogenic effects of EVs derived from undifferentiated mesenchymal stem cells and from chemically induced to differentiate into osteogenic cells for 7 days. Further, the osteoinductive potential of EVs for bone regeneration in rat calvarial defects was assessed. We could isolate and characterize EVs from naïve and osteogenic-induced MSCs. Proteomic analysis revealed that EVs contained distinct protein profiles, with Osteo-EVs having more differentially expressed proteins with osteogenic properties. EVs were found to enhance the proliferation and migration of cultured MSC. In addition, the study found that Osteo-EVs/MEM combination scaffolds could enhance greater bone formation after 4 weeks as compared to native MEM loaded with serum-free media. The study suggests that EVs derived from chemically osteogenic-induced MSCs for 7 days can significantly enhance both the osteogenic differentiation activity of cultured hMSCs and the osteoinductivity of MEM scaffolds. The results indicate that Osteo-MSC-secreted nanocarriers-EVs combined with MEM scaffolds can be used for repairing bone defects

Anatomically, bone consists of building blocks called osteons, which in turn comprise a central canal that contains nerves and blood vessels. This indicates that bone is a highly innervated and vascularized tissue. The function of vascularization in bone (development) is well-established: providing oxygen and nutrients that are necessary for the formation, maintenance, and healing. As a result, in the field of bone tissue engineering many research efforts take vascularization into account, focusing on engineering vascularized bone. In contrast, while bone anatomy indicates that the role of innervation in bone is equally important, the role of innervation in bone tissue engineering has often been disregarded. For many years, the role of innervation in bone was mostly clear in physiology, where innervation of a skeleton is responsible for sensing pain and other sensory stimuli. Unraveling its role on a cellular level is far more complex, yet more recent research efforts have unveiled that innervation has an influence on osteoblast and osteoclast activity. Such innervation activities have an important role in the regulation of bone homeostasis, stimulating bone formation and inhibiting resorption. Furthermore, due to their anatomical proximity, skeletal nerves and blood vessels interact and influence each other, which is also demonstrated by pathways cross-over and joint responses to stimuli. Besides those closely connected sytems, the immune system plays also a pivotal role in bone regeneration. Certain cytokines are important to attract osteogenic cells and (partially) inhibit bone resorption. Several leukocytes also play a role in the bone regeneration process. Overall, bone interacts with several systems. Aberrations in those systems affect the bone and are important to understand in the context of bone regeneration. This crosstalk has become more evident and is taken more into consideration. This leads to more complex tissue regeneration, but may recapitulate better physiological situations

Autologous cancellous bone graft is the gold standard in large bone defect repair. However, studies using autologous bone grafting in rats are rare and donor sites as well as harvesting techniques vary. The aim of this study was to determine the feasibility of autologous cancellous bone graft harvest from 5 different anatomical sites in rats and compare their suitability as donor sites for autologous bone graft. 13 freshly euthanised rats were used to describe the surgical approaches for autologous bone graft harvest from the humerus, iliac crest, femur, tibia and tail vertebrae (n=4), determine the cancellous bone volume and microstructure of those five donor sites using µCT (n=5), and compare their cancellous bone collected qualitatively by looking at cell outgrowth and osteogenic differentiation using an ALP assay and Alizarin Red S staining (n=4). It was feasible to harvest cancellous bone graft from all 5 anatomical sites with the humerus and tail being more surgically challenging. The microstructural analysis showed a significantly lower bone volume fraction, bone mineral density, and trabecular thickness of the humerus and iliac crest compared to the femur, tibia, and tail vertebrae. The harvested volume did not differ between the donor sites. All donor sites apart from the femur yielded primary osteogenic cells confirmed by the presence of ALP and Alizarin Red S stain. Bone samples from the iliac crest showed the most consistent outgrowth of osteoprogenitor cells. The tibia and iliac crest may be the most favourable donor sites considering the surgical approach. However, due to the differences in microstructure of the cancellous bone and the consistency of outgrowth of osteoprogenitor cells, the donor sites may have different healing properties, that need further investigation in an in vivo study

Many age-related diseases affect our skeletal system, but bone health-targeting drug development strategies still largely rely on 2D in vitro screenings. We aimed at developing a scaffold-free progenitor cell-based 3D biomineralization model for more physiological high-throughput screenings. MC3T3-E1 pre-osteoblast spheroids were cultured in V-shaped plates for 28 days in alpha-MEM (10% FCS, 1% L-Gln, 1X NEAA) with 1% pen/strep, changed every two days, and differentiation was induced by 10mM b-glycerophosphate and 50µg/ml ascorbic-acid. Osteogenic cell differentiation was assessed through profiling mRNA expression of selected osteogenic markers by efficiency corrected normalized 2^DDCq RT-qPCR. Biomineralization in spheroids was evaluated by histochemistry (Alizarin Red/von Kossa staining), Alkaline phosphatase (Alp) activity, Fourier transform infrared spectroscopy (FTIR) analyses, micro-CT analyses, and scanning electron microscopy on critical point-dried samples. GraphPad Prism 9 analyses comprised Shapiro-Wilk and Brown-Forsythe tests as well as 2-way ANOVA with Tukey post-hoc and non-parametric Kruskal-Wallis with Dunn post-hoc tests. During mineralization, as opposed to non-mineralizing conditions, characteristic mRNA expression profiles of selected early and late osteoblast differentiation markers (e.g., RunX, Alp, Col1a1, Bglap) were observed between day 0 and 28 of culture; Alp was strongly upregulated (p<0.001) from day 7 on, followed by its enzymatic activity (p<0.001). Bglap and Col1a1 expression peaked on (p<0.001) and from day 14 on (p<0.05), respectively. IHC revealed osteocalcin staining in the spheroid core regions at day 14, while type I collagen staining of the cores was most prominent from day 21 on. Alizarin Red and Von Kossa confirmed central and radially outwards expanding mineralization patterns between day 14 and day 28, which was accompanied by a steady increase in extracellular calcium deposition over time (p<0.001). Micro-CT analyses allowed quantitative appreciation of the overall increase in mineral density over time (day21, p<0.05; d28, p<0.001), while SEM-EDX and FTIR ultimately confirmed a bone-like hydroxyapatite mineral deposition in 3D. A novel and thoroughly characterized versatile bone-like 3D biomineralization in vitro model was established, which allows for studying effects of pharmacological interventions on bone mineralization ex vivo under physiomimetic conditions. Ongoing studies currently aim at elucidating in how far it specifically recapitulates intramembranous ossification

Aims

The aim of this study was to investigate the incidence and characteristics of instrumentation failure (IF) after total en bloc spondylectomy (TES), and to analyze risk factors for IF.

Cite this article: Bone Joint Res 2023;12(1):5–8.

Aims

Osteoarthritis (OA) is prevalent among the elderly and incurable. Intra-articular parathyroid hormone (PTH) ameliorated OA in papain-induced and anterior cruciate ligament transection-induced OA models; therefore, we hypothesized that PTH improved OA in a preclinical age-related OA model.

Glucocorticoid excess is shown to deteriorate bone tissue integrity, increasing the risk of osteoporosis. Marrow adipogenesis at cost of osteogenesis is a prominent feature of this osteoporosis condition. Epigenetic pathway histone deacetylase (HDAC)-mediated histone acetylation regulates osteogenic activity and bone mass. This study is aimed to figure out what role of acetylated histone reader bromodomain-containing protein 4 (BRD4) did play in glucocorticoid-induced osteoporosis. Bone-marrow mesenchymal stem cells were incubated in osteogenic medium with or without 1 μM dexamethasone. Mineralized matrix and adipocyte formation were probed using von Kossa and Nile Red O staining, respectively. Osteogenic and adipogenic marker expression were quantified using RT-PCR. The binding of acetylated histone to promoter of transcription factors were detected using chromatin immunoprecipitation-PCR. Bone mineral density and microstructure in osteoporotic bone were quantified with microCT system. Glucocorticoid repressed osteogenic transcription factor Runx2 expression and mineralized matrix formation along with a low level of acetylated lysine 9 at histone 3 (H3K9ac), whereas BRD4 signaling and adipocytic formation were increased in cell cultures. BRD4 knockdown reversed the H3K9ac enrichment in Runx2 promoter and osteogenesis, but downregulated adipogenic differentiation. Silencing BRD4 attenuated H3K9ac occupancy in forkhead box P1 (Foxp1) relevant to lipid metabolism upon glucocorticoid stress. Foxp1 interference downregulated adipogenic activities of glucocorticoid-treated cells. In vivo, treatment with BRD4 inhibitor JQ-1 compromised the glucocorticoid-induced bone mineral density loss, spare trabecular structure, and fatty marrow, as well as improved biomechanical properties of bone tissue. Taken together, BRD4-mediated Foxp1 pathways drive mesenchymal stem cells shifting toward adipocytic cells rather than osteogenic cells to aggravates excessive marrow adipogenesis in the process of glucocorticoid-induced osteoporosis. Pharmacological inhibition of BRD4 signaling protects bone tissue from bone loss and fatty marrow in glucocorticoid-treated mice. This study conveys a new molecular insight into epigenetic regulation of osteogenesis and adipogenesis in osteoporotic skeleton and highlight the remedial effect of BRD4 inhibitor on glucocorticoid-induced bone loss

Numerous implanted hip and knee joint arthroplasties have to be replaced due to early or late loosening of the implant, a failure of osteointegration with fibrous tissue at the bone-implant-interface. This could be counteracted by ensuring that cells which attach to the implant surface differentiate towards bone cells afterwards. For this reason, human mesenchymal stem cells (hMSCs) will be included in this study. These cells are naturally available at the bone-implant-interface, multipotent and therefore ideal to study the osteoinductivity of a material. The goal of this pilot study was to test the cell response towards three different titanium grades with a novel surface structuring, as a first step towards achieving an improved implant surface for enhanced osteointegration. Disk-shaped titanium scaffolds with a diameter of 12 mm and a height of 1.2 mm were used. The surface topography (500 µm × 500 µm × 300 µm pores) was generated via laser treatment of the surface. By using nanosecond pulsed laser technique, a rough surface with micro- and nanostructural (titanium droplets) features was automatically formed. Three different batches made of commercially pure titanium grades 1 and 2 (Ti1/Ti2) or Ti6Al4V alloy grade 5 (Ti5) were produced. Four cell types were analysed on these batches: primary hMSCs from one donor (m, 25 y), periosteum derived cells (PDCs), human osteoblasts (hOBs) and periodontal ligament cells (PDLs). Cells were seeded on Ti1, Ti2 and Ti5 scaffolds in triplicates. Resazurin assay to examine cell viability was conducted with all cell types. Measurements were executed on several days after seeding, from day one up to day 14. Actin staining as well as live/dead staining was performed with hMSCs cultured on titanium for 1, 3, 5 or 7 days. The cell viability assay revealed early turning points of growth for osteogenic hOBs (day 3) and PDCs (day 7). HMSCs grew steadily on the material and non-osteogenic PDLs stayed in plateau throughout the cultivation period. With respect to the material, cells demonstrated better proliferation on Ti1 and Ti2 than on Ti5. Live/dead staining showed a high survival rate of hMSCs at each time point and on all three titanium grades, with a neglectable number of dead cells. Actin staining confirmed an enhanced spreading and stretching of hMSCs on Ti1 and Ti2 compared to hMSCs on Ti5. Our pilot data indicates that cells react to different titanium compositions, revealed by increased proliferation on commercially pure titanium (Ti1/2). Furthermore, our results demonstrate that osteogenic cells prefer the novel surface structuring in comparison to non-osteogenic PDL cells, which stayed in plateau. The turning points of growth (hOBs/PDCs) suggest an osteosupportiveness of the surface. Although hMSCs did not show a turning point in growth, their growth was steady and resulted in the highest number of cells along with a well stretched morphology. Due to their good proliferation and response to the material, hMSCs are currently being used for evaluating the osteogenic potential of the novel scaffolds

Bone tissue engineering attempts at substituting critical size bone defects with scaffolds that can be primed with osteogenic cells, usually mesenchymal stem cells (MSC) from the bone marrow. Although overlooked, peripheral blood is a valuable source of MSC and circulating osteoprogenitors (COP), bearing a significant regenerative potential, and peripheral blood is easier to access than bone marrow. We thus studied osteodifferentiation of peripheral blood mononuclear cells (pbMNC) under different culture conditions, and how they compared to primary human osteoblasts. pbMNC were isolated from healthy adult volunteers by Ficoll density gradient centrifugation, and they were then cultured using media supplemented with 100nM Dexamethasone, 10mM sodium β-glycero phosphate and ascorbic acid (either 40mM or 0.05mM). For comparison, primary osteoblasts were isolated from the femoral heads of patients undergoing hip arthroplasty. After 4 weeks of culture, osteogenic activation was quantified with spectrometric measurement of alkalic phosphatase (ALP) and lactate dehydrogenase (LDH) levels. The extent of osteoid mineralization was measured with Alizarin red staining. We studied the effects of 1) varying cell concentration at seeding, 2) surface coating of culture wells with collagen and 3) high compared to low ascorbic acid (40mM and 0.05mM) media. Higher numbers of pbMNC (0.5–5.9 versus 0.062–0.25 million cells per well) at seeding resulted in a lower ALP/LDH-ratio (mean ± standard deviation), 0.39 ± 0.33 arbitrary units (AU) versus 1.36 ± 1.06 AU, but led to higher amount of osteoid production, 0.10 ± 0.06 versus 0.065 ± 0.02 AU, p < 0.05. Culture of pbMNC on collagen did not confer any difference in ALP/LDH-ratios, with 0.43 ± 0.3 AU for collagen-coated and 0.43 ± 0.41 AU for uncoated wells (p = 0.95), and we also observed no relevant difference in osteoid production (0.07 ± 0.01 AU for collagen-coated versus 0.1 ± 0.08 AU for uncoated wells, p = 0.28). Cultures of pbMNC on collagen in media supplemented with a higher concentration of ascorbic acid showed a 130% higher ALP/LDH-ratio when compared to cultures exposed to a lower ascorbic acid concentration (p < 0.05). Cultures with a low initial concentration of pbMNC (0.5 − 1 million cells) had no significantly different ALP/LDH-ratio when compared to primary human osteoblasts, but the cultures of pbMNC resulted in a 90% increase in osteoid mineralization when compared to primary human osteoblasts (p < 0.05). These findings indicate that progenitor cells derived from peripheral blood have a significant osteogenic potential, rendering them interesting candidates for seeding of scaffolds intended to fill critical sized bone defects. pbMNC produced almost double the amount of osteoid as primary osteoblasts. The isolation of pbMSC and COP is non-invasive and easy, and they might be seeded directly onto scaffolds without prior ex-vivo expansion, a question that we intend to pursue further

Millions of patients each year suffer from challenging non-healing bone defects secondary to trauma or disease (e.g. cancer, osteoporosis or osteomyelitis). Tissue engineering approach to non-healing bone defects has been investigated over the past few decades in a search for a novel solution for critical size bone defects. The success of the tissue engineering approach relies on three main pillars, the right type of cells; and appropriate scaffold; and a biologically relevant biochemical/ biophysical stimuli. When it comes to cells the mesodermal origin of mesenchymal stem cells and its well demonstrated multipotentiality makes it an ideal option to be used in musculoskeletal regeneration. For the presented set of experimental assays, fully characterised (passage 3 to 5)ovine adipose-derived mesenchymal stems cells (Ad-MSC) were cultured either in growth medium (GM) consisting of Dulbecco's Modification of Eagle's Medium (DMEM) supplemented with 10% (v/v) foetal bovine serum and 1% penicillin-streptomycin as a control or in osteogenic differentiation medium (DM), consisting of GM further supplemented with L- ascorbic acid (50 μg/ml), β-glycerophosphate (10 mM) and dexamethasone (100nM). Osteogenic differentiation was assessed biochemically by quantifying alkaline phosphatase (ALP) enzyme activity and alizarin red staining after 3, 7, 14 and 21 days in culture (where 1×105 cells/well were seeded in 24 well-plate, n=6/media type/ time point). Temporal patterns in osteogenic gene expression were quantified using real-time PCR for Runx-2, osteocalcin (OC), osteonectin (ON) and type 1 collagen (Col 1) at days 7, 15 and 21 (where 1×105 cells were seeded in T25 cell culture flasks for RNA extraction, n= 4 / gene/ media type/time point). The morphology of osteogenic cells was additionally evaluated by scanning electron microscopy (SEM) of cells seeded at low-density (1×102 cells) on glass coverslips for 2 weeks in GM or DM. The level of ALP activity of cells grown in osteogenic DM was significantly higher than the control growing in the standard growth medium (p ≤ 0.05) at days 3, 7 and 14. At 21 days there was a sharp drop in ALP values in the differentiating cells. Mineralisation, as evidenced by alizarin red staining, increased significantly by day 14 and then peaked at day 21. Quantitative real-time PCR confirmed early increases in Runx-2, Col 1 and osteonectin, peaking in the second week of culture, while osteocalcin peaked at 21 days of culture. Taken as a whole, these data indicate that ovine-MSCs exhibit a tightly defined pathway of initial proliferation and matrix maturation (up to 14 days), followed by terminal differentiation and mineralisation (days 14 to 21). SEM analysis confirmed the flattened, roughened appearance of these cells and abandoned extracellular matrix which resembled mature osteoblasts. Given the ready availability of adipose tissues, the use of Ad-MSCs as progenitors for bone tissue engineering applications is both feasible and reasonable. The data from this study indicate that Ad-MSCs follow a predictable pathway of differentiation that can be tracked using validated molecular and biochemical assays. Additional work is needed to confirm that these cells are osteogenic in vivo, and to identifying the best combination of scaffold materials and cell culture techniques (e.g. static versus dynamic) to accelerate or stimulate osteogenic differentiation for bone tissue engineering applications

Aims

The purpose of this study was to: review the efficacy of the induced membrane technique (IMT), also known as the Masquelet technique; and investigate the relationship between patient factors and technique variations on the outcomes of the IMT.

Previous studies have described an age-dependent distortion of bone microarchitecture for α-CGRP-deficient mice (3). In addition, we observed changes in cell survival and activity of osteoblasts and osteoclasts isolated from young wildtype (WT) mice when stimulated with α-CGRP whereas loss of α-CGRP showed only little effects on bone cell metabolism of cells isolated from young α-CGRP-deficient mice. We assume that aging processes differently affect bone cell metabolism in the absence and presence of α-CGRP. To further explore this hypothesis, we investigated and compared cell metabolism of osteoblasts and bone marrow derived macrophages (BMM)/osteoclast cultures isolated from young (8–12 weeks) and old (9 month) α-CGRP-deficient mice and age matched WT controls. Isolation/differentiation of bone marrow macrophages (BMM, for 5 days) to osteoclasts and osteoblast-like cells (for 7/14/21 days) from young (8–12 weeks) and old (9 month) female α-CGRP−/− and WT control (both C57Bl/6J) mice according to established protocols. We analyzed cell migration of osteoblast-like cells out of femoral bone chips (crystal violet staining), proliferation (BrdU incorporation) and caspase 3/7-activity (apoptosis rate). Alkaline phosphatase (ALP) activity reflects osteoblast bone formation activity and counting of multinucleated (≥ 3 nuclei), TRAP (tartrate resistant acid phosphatase) stained osteoclasts reflects osteoclast differentiation capacity. We counted reduced numbers of BMM from young α-CGRP−/− mice after initial seeding compared to young WT controls but we found no differences between old α-CGRP−/− mice and age-matched controls. Total BMM number was higher in old compared to young animals. Migration of osteoblast-like cells out of bone chips was comparable in both, young and old α-CGRP−/− and WT mice, but number of osteoblast-like cells was lower in old compared to young animals. Proliferation of old α-CGRP−/− BMM was higher when compared to age-matched WT whereas proliferation of old α-CGRP−/− osteoblasts after 21 days of osteogenic differentiation was lower. No differences in bone cell proliferation was detected between young α-CGRP−/− and age-machted WT mice. Caspase 3/7 activity of bone cells from young as well as old α-CGRP−/− mice was comparable to age-matched controls. Number of TRAP-positive multinucleated osteoclasts from young α-CGRP−/− mice was by trend higher compared to age-matched WT whereas no difference was observed in osteoclast cultures from old α-CGRP−/− mice and old WT. ALP activity, as a marker for bone formation activity, was comparable in young WT and α-CGRP−/− osteoblasts throughout all time points whereas ALP activity was strongly reduced in old α-CGRP−/− osteoblasts after 21 days of osteogenic differentiation compared to age-matched WT. Our data indicate that loss of α-CGRP results in a reduction of bone formation rate in older individuals caused by lower proliferation and reduced activity of osteogenic cells but has no profound effects on bone resorption rate. We suggest that the osteopenic bone phenotype described in aged α-CGRP-deficient mice could be due to an increase of dysfunctional matured osteoblasts during aging resulting in impaired bone formation

Osteoporosis accounts for a leading cause of degenerative skeletal disease in the elderly. Osteoblast dysfunction is a prominent feature of age-induced bone loss. While microRNAs regulate osteogenic cell behavior and bone mineral acquisition, however, their function to osteoblast senescence during age-mediated osteoporosis remains elusive. This study aims to utilize osteoblast-specific microRNA-29a (miR-29a) transgenic mice to characterize its role in bone cell aging and bone mass. Young (3 months old) and aged (9 months old) transgenic mice overexpressing miR-29a (miR-29aTg) driven by osteocalcin promoter and wild-type (WT) mice were bred for study. Bone mineral density, trabecular morphometry, and biomechanical properties were quantified using μCT imaging, material testing system and histomorphometry. Aged osteoblasts and senescence markers were probed using immunofluorescence, flow cytometry for apoptotic maker annexin V, and RT-PCR. Significantly decreased bone mineral density, sparse trabecular morphometry (trabecular volume, thickness, and number), and poor biomechanical properties (maximum force and breaking force) along with low miR-29a expression occurred in aged WT mice. Aging significantly upregulated the expression of senescence markers p16INK4a, p21Waf/Cip1, and p53 in osteoporotic bone in WT mice. Of note, the severity of bone mass and biomechanical strength loss, as well as bone cell senescence, was remarkably compromised in aged miR-29aTg mice. In vitro, knocking down miR-29a accelerated senescent (β-galactosidase activity and senescence markers) and apoptotic reactions (capsas3 activation and TUNEL staining), but reduced mineralized matrix accumulation in osteoblasts. Forced miR-29a expression attenuated inflammatory cytokine-induced aging process and retained osteogenic differentiation capacity. Mechanistically, miR-29a dragged osteoblast senescence through targeting 3′-untranslated region of anti-aging regulator FoxO3 to upregulate that of expression as evident from luciferase activity assessment. Low miR-29a signaling speeds up aging-induced osteoblast dysfunction and osteoporosis development. Gain of miR-29a function interrupts osteoblast senescence and shields bone tissue from age-induced osteoporosis. The robust analysis sheds light to the protective actions of miR-29a to skeletal metabolism and conveys a perspective of miR-29a signaling enhancement beneficial for aged skeletons

Objectives. Bone tissue engineering is one of the fastest growing branches in modern bioscience. New methods are being developed to achieve higher grades of mineral deposition by osteogenically inducted mesenchymal stem cells. In addition to well established monolayer cell culture models, 3D cell cultures for stem cell-based osteogenic differentiation have become increasingly attractive to promote in vivo bone formation. One of the main problems of scaffold-based osteogenic cell cultures is the difficulty in quantifying the amount of newly produced extracellular mineral deposition, as a marker for new bone formation, without destroying the scaffold. In recent studies, we were able to show that . 99m. Tc-methylene diphosphonate (. 99m. Tc-MDP), a gamma radiation-emitting radionuclide, can successfully be applied as a reliable quantitative marker for mineral deposition as this tracer binds with high affinity to newly produced hydroxyapatite (HA). Methods. Within the present study, we evaluated whether this promising new method, using . 99m. Tc-hydroxydiphosphonate (. 99m. Tc-HDP), can be used to quantify the amount of newly formed extracellular HA in a 3D cell culture model. Highly porous collagen type II scaffolds were seeded with 1 × 106 human mesenchymal stem cells (hMSCs; n = 6) and cultured for 21 days in osteogenic media (group A – osteogenic (OSM) group) and in parallel in standard media (group B – negative control (CNTRL) group). After incubation with . 99m. Tc-HDP, the tracer uptake, reflected by the amount of emitted gamma counts, was measured. Results. We saw a higher uptake (up to 15-fold) of the tracer in the OSM group A compared with the CNTRL group B. Statistical analysis of the results (Student`s t-test) revealed a significantly higher amount of emitted gamma counts in the OSM group (p = 0.048). Qualitative and semi-quantitative analysis by Alizarin Red staining confirmed the presence of extracellular HA deposition in the OSM group. Conclusion. Our data indicate that . 99m. Tc-HDP labelling is a promising tool to track and quantify non-destructive local HA deposition in 3D stem cell cultures. Cite this article: T. L. Grossner, U. Haberkorn, T. Gotterbarm. . 99m. Tc-Hydroxydiphosphonate quantification of extracellular matrix mineralization in 3D human mesenchymal stem cell cultures. Bone Joint Res 2019;8:333–341. doi: 10.1302/2046-3758.87.BJR-2017-0248.R1

Objectives

Long bone defects often require surgical intervention for functional restoration. The ‘gold standard’ treatment is autologous bone graft (ABG), usually from the patient’s iliac crest. However, autograft is plagued by complications including limited supply, donor site morbidity, and the need for an additional surgery. Thus, alternative therapies are being actively investigated. Autologous bone marrow (BM) is considered as a candidate due to the presence of both endogenous reparative cells and growth factors. We aimed to compare the therapeutic potentials of autologous bone marrow aspirate (BMA) and ABG, which has not previously been done.

In therapeutic bone repairs, autologous bone grafts, conventional or vascularized allografts, and biocompatible artificial bone substitutes all have their shortcomings. Tissue engineering may be an alternative for cranial bone repair. Titanium (Ti) and its alloys are widely used in many clinical devices because of perfect biocompatibility, highly corrosion resistance and ideal physical properties. An important progress in treating bone defects has been the introduction of bone morphogenetic proteins (BMPs), specifically BMP-2. The proteins induce osteogenic cell differentiation in vitro, as well as bone defect healing in vivo. In this study, we fabricated the titanium plate with dioxide creating by microarc oxidation (MAO) and then electronic deposition of Ca.P that can carrier recombinant human bone morphogenetic protein-2 (rhBMP-2) to enhance osteogenesis in vitro and bone formation in vivo. The rhBMP-2 was controlled released from MAO-Ca.P-rhBMP2 implant was maintain within 35days longer than Ti without MAO modification group and without CaP electronic deposition group. In addition, the in vitro results revealed that the bioactivity of rhBMP-2 released from MAO-Ca.P-rhBMP2 implant with an ideal therapeutic dose was well maintained. In vivo, the critical-sized defect (20-mm diameter) of New Zealand White rabbits was used to experiment. We concluded that sustained controlled-release of rhBMP-2 above a therapeutic dose could induce osseointegration between the implant and surrounding bone the rate of bone formation into the implant and produce neovascularization. Our study combined the concept of osteoconductive and osteoinductive to do the bone tissue regeneration