Project description:This study aimed to examine the effects of loading different concentmus musculusions of metformin onto an α-hemihydmus musculuse calcium sulfate/nano-hydroxyapatite (α-CSH/ nHA) composite. The material characteristics, biocompatibility, and bone formation were compared as functions of the metformin concentmus musculusion. X-ray diffraction results indicated that the metformin loading had little influence on the phase composition of the composite. The hemolytic potential of the composite was found to be low, and a CCK-8 assay revealed only weak cytotoxicity. However, the metformin-loaded composite was found to enhance the osteogenic ability of MC3T3- E1 cells, as revealed by alkaline phosphate and alizarin red staining, real-time PCR, and Western blotting, and the optimal amount was 500 μM. RNA sequencing results also showed that the composite material increased the expression of osteogenic-related genes. Cranial bone lacks muscle tissue, and the low blood supply leads to poor bone regenemus musculusion. As most mammalian cranial and maxillofacial bones are membranous and of similar embryonic origin, the Mus musculus cranial defect model has become an ideal animal model for in vivo experiments in bone tissue engineering. Thus, we introduced a Mus musculus cranial defect with a diameter of 5 mm as an experimental defect model. Micro-computed tomography, hematoxylin and eosin staining, Masson staining, and immunohistochemical staining were used to determine the effectiveness of the composite as a scaffold in a Mus musculus skull defect model. The composite material loaded with 500 μM of metformin had the strongest osteoinduction ability under these conditions. These results are promising for the development of new methods for repairing craniofacial bone defects.

Project description:Titanium is widely used in bone prostheses due to its excellent biocompatibility and osseointegration capacity. To understand the effect of sandblasted acid-etched (SAE) Ti implants on the biological responses of human osteoblast (HOb), their proteomic profiles were analysed using nLC-MS/MS. The cells were cultured with the implant materials, and 2544 distinct proteins were detected in samples taken after 1, 3 and 7 days. Comparative analyses of proteomic data were performed using Perseus software. The expression of proteins related to EIF2, mTOR, insulin-secretion and IGF pathways showed marked differences in cells grown with SAE-Ti in comparison with cells cultured without Ti. Moreover, the proteomic profiles obtained with SAE-Ti were compared over time. The affected proteins were related to adhesion, immunity, oxidative stress, coagulation, angiogenesis, osteogenesis and extracellular matrix formation functions. The proliferation, mineralisation and osteogenic gene expression in HObs cultured with SAE-Ti were characterised in vitro. The results showed that the osteoblasts exposed to this material increase their mineralisation rate and expression of COLI, RUNX2, SP7, CTNNB1, CAD13, IGF2, MAPK2 and mTOR. Overall, the observed proteomic profiles can explain the SAE-Ti osteogenic properties, widening our knowledge of key signalling pathways taking part in the early stages of the osseointegration process in this type of implantations.

Project description:This study clarified how implant surfaces influence early osseointegration by coupling untargeted RNA sequencing with histomorphometry. Four rabbits each received three tibial implants: turned commercially pure titanium (Ti), sandblasted/large-grit/acid-etched titanium (SLA-Ti), and turned copper (Cu). Surface morphology was characterized by scanning electron microscopy, confocal microscopy, and energy dispersive spectroscopy. After 10 days, bone-to-implant contact (BIC), bone area (BA), and peri-implant transcriptomes were analyzed. Differentially expressed genes and Gene ontology (GO) enrichment were computed. SLA-Ti showed the greatest roughness. Both Ti groups yielded significantly higher BIC and BA than Cu (p < 0.001). GO terms on SLA-Ti were enriched for immune regulation and turned Cu was dominated by mitochondrial-stress pathways. Turned Ti showed minimal enrichment. SLA-Ti simultaneously up-regulated pro-inflammatory cytokines and immunoregulatory genes plus stress-adaptive markers, suggesting a balanced inflammatory milieu conducive to bone formation. Turned Cu markedly elevated mitochondrial genes and oxidative-stress markers, while suppressing antioxidant and innate-defense genes, reflecting immune-metabolic dysregulation. Turned Ti induced only modest transcript changes, consistent with passive biocompatibility. Early osseointegration hinges on a finely tuned immune-metabolic equilibrium rather than surface roughness alone. Optimal integration demands implant surfaces that trigger controlled immunomodulation while limiting oxidative stress, guiding the design of next-generation dental implants.

Project description:Exosomes are nanoscale extracellular vesicles. Several studies have shown that exosomes participate in intercellular communication and play a key role in osseointegration. However, it is unclear whether exosomes and their contents participate in the communication between the immune and skeletal systems in the process of osseointegration. In this study, we obtained smooth titanium disks by polishing and micro-/nano-texture hierarchical topography titanium disks by sandblasted large-grit acid-etched (SLA) technology combined with alkali thermal reaction. After stimulating rat RAW264.7 cells with these two kinds of titanium disks, we co-cultured the MC3T3-E1 cells and the RAW264.7 cells, obtained and identified the exosomes derived from RAW264.7 cells, and studied the effect of the osteoimmune microenvironment and the exosomes on the osseointegration of rat MC3T3-E1 cells. Cell counting kit-8 (CCK-8), real time quantitative PCR, western blotting, alizarin red staining, and quantitative and confocal fluorescence microscopy were used to study the effects of exosomes on MC3T3-E1 cells; RNA sequencing and correlation analysis were performed. We found that the osteoimmune microenvironment could promote the osseointegration of MC3T3-E1 cells. We successfully isolated exosomes and found that RAW264.7 cell-derived exosomes can promote osteogenic differentiation and mineralization of MC3T3-E1 cells. Through RNA sequencing and gene analysis, we found differentially expressed microRNAs that targeted the signal pathways that may be related, such as mTOR, AMPK, Wnt, etc, and thus provide a reference for the mechanism of osteoimmunue regulation of implant osseointegration. The study further elucidated the mechanism of implant osseointegration and provided new insights into the effect of exosomes on implant osseointegration, and provided reference for clinical improvement of implant osseointegration and implant success rate.

Project description:Intensive efforts are focused on identifying regulators of human pancreatic islet cell growth and maturation to accelerate development of therapies for diabetes. In the present study we evaluate the contribution of the physical properties of the extracellular matrix in supporting long term culture of human islets in vitro. We used metal oxide layers with tailored nanoscale roughness to fabricate scaffolds. Their suitability to support long term culture of human islets was investigated through assessment of β-cell survival, differentiation and function by using a proteomic approach to evaluate the molecular mechanisms involved. Proteomic analysis confirmed that ns-ZrOx promoted the activation of a transcriptional and translational program leading to activation of pro-survival and pro-differentiation signalling pathways. The process was driven by a mechanotransductive pathway driven by nanostructured topology, via remodelling of the actin cytoskeleton nuclear architecture and increase of oxygen sensor PDH2 Our data suggest that β-cells relay on nanotopography features to regulate their differentiation and survival. Tailored nanostructured substrates may provide a unique strategy to identify novel hints for tissue engineering and molecular /pharmacological targets of intervention to treat diabetes mellitus.

Project description:To investigate the molecular mechanism underlying osteogenic and angiogenic differentiation induced by the De-HA scaffold, we conducted an in-depth gene microarray analysis on day 3 of MC3T3-E1 culture. We found that De-HA could enhance the transcription of osteogenic and angiogenic genes by activating FAK and downstream MAPK/ERK signaling to induce MC3T3-E1 differentiation. More importantly, our findings indicated that EGFR, a kind of transmembrane glycoprotein, played a key role in the osteogenic differentiation of MC3T3-E1, suggesting that the activation of the FAK/MAPK/ERK signaling cascade might be driven by EGFR.

Project description:Mesenchymal stem cells (MSc) show diminished osteogenic differentiation upon complete knockout of all known Hyaluronan (HA) synthases (Has). We demonstrated that Has-knockout completely abrogated the release of HA into the culture medium by MSc and that these MSc showed an impaired osteogenic differentiation detected by Alizarin red staining at days 7 and 12 of differentiation compared to wildtype MSc. To gain insight intor the transcriptomic changes due to Has knockout we compared differentiating MSc at day 7 of differentiation.

Project description:Here we describe an improved tandem MOAC combined phosphoprotein / phosphopeptide enrichment strategy, a scalable phosphoproteomics approach that allows rapid identification of thousands of phophopeptides in plant material. We apply this technology to generate time-resolved maps of boron signaling in Arabidopsis roots.

Project description:Tissue response following implantation determines the success of the healing process. This response is not only dependent on the chemical properties of the implant surface but also by the surface topography or its roughness. Although in vitro and in vivo studies show improved results with rough- and fluoride-modified implants, the mechanisms behind these findings are still unknown. Here, we have used a two step procedure to identify novel genes related to the early cell response of primary human osteoblasts to roughness and fluoride-modified titanium implants. 217 genes were identified by microarray analysis as response genes to roughness and 198 genes as response genes to fluoride. 11 of these identified genes have been related to bone and mineralization and were further investigated by real-time RT-PCR. After one day of culture, TLR3, ANKH, DCN, OC and RUNX2 were classified as responsive genes to roughness; DLX2 and TUFT1 as responsive genes to fluoride treatment. COLL-I, PTHLH, HES1, FST, ENPP1 and THRA as responsive genes to both, roughness and fluoride treatment. In conclusion, our strategy was useful for identifying novel genes that might be involved in the early response of osteoblasts to roughness and fluoride treatment of titanium implants. Tissue response following implantation determines the success of the healing process. This response is not only dependent on the chemical properties of the implant surface but also by the surface topography or its roughness. Although in vitro and in vivo studies show improved results with rough- and fluoride-modified implants, the mechanisms behind these findings are still unknown. Here, we have used a two step procedure to identify novel genes related to the early cell response of primary human osteoblasts to roughness and fluoride-modified titanium implants. 217 genes were identified by microarray analysis as response genes to roughness and 198 genes as response genes to fluoride. 11 of these identified genes have been related to bone and mineralization and were further investigated by real-time RT-PCR. After one day of culture, TLR3, ANKH, DCN, OC and RUNX2 were classified as responsive genes to roughness; DLX2 and TUFT1 as responsive genes to fluoride treatment. COLL-I, PTHLH, HES1, FST, ENPP1 and THRA as responsive genes to both, roughness and fluoride treatment. In conclusion, our strategy was useful for identifying novel genes that might be involved in the early response of osteoblasts to roughness and fluoride treatment of titanium implants.

Project description:ChIP-Sequencing on Shox2-HA E12.5 and E13.5 Limb and Palate, as well as Pbx on E12.5 limb . Abstract: Vertebrate appendage patterning is programmed by Hox-TALE factors-bound regulatory elements. However, it remains enigmatic which cell lineages are commissioned by Hox-TALE factors to generate regional specific pattern and whether other Hox-TALE co-factors exist. In this study, we investigated the transcriptional mechanisms controlled by the Shox2 transcriptional regulator in limb patterning. Harnessing an osteogenic lineage-specific Shox2 inactivation approach we show that despite widespread Shox2 expression in multiple cell lineages, lack of the stylopod observed upon Shox2 deficiency is a specific result of Shox2 loss of function in the osteogenic lineage. ChIP-Seq revealed robust interaction of Shox2 with cis-regulatory enhancers clustering around skeletogenic genes that are also bound by Hox-TALE factors, supporting a lineage autonomous function of Shox2 in osteogenic lineage fate determination and skeleton patterning. Pbx ChIP-Seq further allowed the genome-wide identification of cis-regulatory modules exhibiting co-occupancy of Pbx, Meis, and Shox2 transcriptional regulators. Integrative analysis of ChIP-Seq and RNA-Seq data and transgenic enhancer assays indicate that Shox2 patterns the stylopod as a repressor via interaction with enhancers active in the proximal limb mesenchyme and antagonizes the repressive function of TALE factors in osteogenesis. Shox2/TALE For ChIP-Seq, the list of libraries below, including controls, were generated [listed in the format of (antibody)-target-tissue-stage]: (α-HA)-Shox2-Limb-E12.5, (α-HA)-Shox2-Limb-E13.5, (α-HA)-Shox2-Palate-E12.5, (α-HA)-Shox2-Limb/Palate-E12.5, (α-Pbx)-Pbx-Limb-E12.5, Input (control), (α-HA)-Mixed Limb/Palate from Shox2+/+ mice-E12.5 (control). *The attached signal tracks(*.bigwig) were generated by –bdgcmp (MACS2) to filter out background signal(by filtering against the signal track obtained from (α-HA)-Mixed Limb/Palate from Shox2+/+ mice-E12.5 (control)) and subsequently convert to bigwig for analysis and visualization.