Project description:This study investigated early host reactions to implanted materials to predict successful tissue regeneration with implant. Three kinds of scaffold, i.e., non-coat, collagen-coated, and PMB-coated porous polystylene scaffolds were implanted subcutaneously in mice dorsal area. Those scaffolds were used as bio-incomopatible materials, appropriate materials for tissue regeneration (bio active), and inappropriate to regenration (bio-inert) scaffolds. Seven days after implantation, scaffolds were explanted and total RNA was isolated from infiltrated host cells into scaffold by laser microdissection. Gene expressions of cells in collagen- and PMB-coated scaffold were normalized using results of non coat scaffold. Genes with more than 2-fold difference between collagen and PMB were picked up and narrowed to related keywords; inflammation, angiogenesis, wound healing, and mcrophage polarization. Among those genes, interluekin (IL)-1beta which promote both inflammation and wound healing was up-regulated in collagen-coated scaffold. On the other hand, IL-10 which suppress both inflammation and wound healing was up-regulated in PMB-coated scaffold. Angiogenesis-promoting genes were up-regulated and angiogenesis suppressve genes were suppressed in collagen. Up-regulation of IL-1b and the angiogenesis-relating genes inside the porous scaffolds are the possibly important factors for controlling tissue regeneration. Three-condition experiment, host cells infiltrated in non coat (reference), collagen-coated, and PMB-coated scaffolds. Two-microarray condition experiments, collagen vs. non coat and PMB coat vs. non coat. Hybridization: 2 replicates. Scanning: 3 replicates. Biological experiments: once.

Project description:Infectious bone defects (IBDs) pose a significant clinical challenge due to the simultaneous requirements for effective infection control and robust bone regeneration, and guided bone regeneration (GBR) using multifunctional scaffolds offers a promising therapeutic strategy. Herein, we developed a bilayer hydrogel scaffold (DSHM) based on methacrylated silk fibroin (SilMA) integrated with hydroxyapatite (HA) and minocycline hydrochloride (MH) to address these demands. By precisely optimizing the concentrations of SilMA, photoinitiator, HA, and MH, we engineered a bilayer structure featuring a porous HA-loaded layer (PSH, ~432.1 μm) to enhance mechanical strength and support osteogenic differentiation, and a dense MH-loaded layer (DSM, ~34.6 μm) to act as a barrier against fibrous tissue ingrowth and provide sustained antibacterial effects. The interface-crosslinked DSHM scaffold exhibited a well-defined heterogeneous architecture, improved mechanical properties, tunable degradation, and excellent biocompatibility. Notably, DSHM demonstrated synergistic multifunctionality, including inhibition of fibroblast infiltration, promotion of bone tissue regeneration, and effective infection control. Overall, the DSHM scaffold presents a robust approach for localized and targeted treatment of IBDs, with strong potential for clinical translation.

Project description:The poor osseointegration of dental implants in diabetic patients has become a long-standing clinical problem. Magnesium has been proved to promote bone healing under normal conditions. Here, we elucidate the mechanism by which Mg2+ promotes vascularized osseointegration in diabetic status. We generated a diabetic mice model and demonstrated the alveolar bone healing was compromised, with significantly decreased angiogenesis. We then developed Mg-coating implants with hydrothermal synthesis. These implants sucessfully improved the vascularization and osseointegration in diabetic status. Mechanically, Mg2+ promoted the degradation of Kelch-like ECH associated protein 1 (Keap1) and the nucleation of nuclear factor erythroid 2-related factor 2 (Nrf2) by up-regulating the expression of sestrin 2 (SESN2) in endothelial cells, thus reducing the elevated levels of oxidative stress in mitochondria and relieving endothelial cell dysfunction under hyperglycemia. Altogether, our data proved that Mg2+ promoted vascularized osseointegration in diabetic mice by regulating endothelial mitochondrial metabolism.

Project description:This study investigated early host reactions to implanted materials to predict successful tissue regeneration with implant. Three kinds of scaffold, i.e., non-coat, collagen-coated, and PMB-coated porous polystylene scaffolds were implanted subcutaneously in mice dorsal area. Those scaffolds were used as bio-incomopatible materials, appropriate materials for tissue regeneration (bio active), and inappropriate to regenration (bio-inert) scaffolds. Seven days after implantation, scaffolds were explanted and total RNA was isolated from infiltrated host cells into scaffold by laser microdissection. Gene expressions of cells in collagen- and PMB-coated scaffold were normalized using results of non coat scaffold. Genes with more than 2-fold difference between collagen and PMB were picked up and narrowed to related keywords; inflammation, angiogenesis, wound healing, and mcrophage polarization. Among those genes, interluekin (IL)-1beta which promote both inflammation and wound healing was up-regulated in collagen-coated scaffold. On the other hand, IL-10 which suppress both inflammation and wound healing was up-regulated in PMB-coated scaffold. Angiogenesis-promoting genes were up-regulated and angiogenesis suppressve genes were suppressed in collagen. Up-regulation of IL-1b and the angiogenesis-relating genes inside the porous scaffolds are the possibly important factors for controlling tissue regeneration.

Project description:Full osteochondral regeneration remains a major clinical challenge. Among other experimental cartilage regenerative approaches, decellularized cartilage (DCC) is considered a promising material for generating potentially implantable scaffolds useful as cartilage repair strategy. Bibliography is extensive, but decellularization methods are multiple and cartilage regenerative properties are limited. In this work, we focus on screening and comparing different decellularization methods, aiming to generate DCC potentially useful in biomedical context, and therefore, with biological activity and functional properties in terms of induction of differentiation and regeneration. Data indicate that enzymatic and detergents-based decellularization methods differentially affect ECM components, and that it has consequences in further biological behavior. SDS-treated DCC powder are not useful to be further processed in 2D or 3D structures, because these structures tend to rapidly solubilize, or disaggregate, in physiologic media conditions. Conversely, Trypsin-treated DCC powders processed to mechanically stable 2D films and 3D porous scaffolds, presumably due to partial digestion of collagens during decellularization. In vitro cell culture studies indicate that these structures are biocompatible and induce and potentiate chondrogenic differentiation. In vivo implantation of DCC derived 3D porous scaffolds in rabbit osteochondral defects induce subchondral bone regeneration and fibrocartilage tissue formation after implantation. Therefore, this work defines an optimal cartilage tissue decellularization protocol able to generate DCC powders processable to biocompative and bioactive 2D and 3D structures. These structures are useful for in vitro cartilage research and in vivo subchondral bone regeneration, while hyaline cartilage regeneration with DCC as implantable material remains elusive.

Project description:While cellular energy metabolism regulates tissue regeneration, it remains as a challenge with its limited understanding of activation by engineered scaffolds to regenerate tissue or organ for therapeutic purpose. This study presents a biosynthesized poly(3-hydroxybutyrate-co-4-hydroxybutyrate) [abbreviated as P(3HB-co-4HB)] and its major degradation product, 3-hydroxybutyrate (3HB), functioning as an endogenous bioenergetic molecule to facilitate bone regeneration and promote cellular anabolism via generations of adenosine triphosphate (ATP) and citrate that enhance the progression of human bone marrow mesenchymal stem cells (hBMSCs) towards osteoblastogenesis. Our studies demonstrate that 3HB not only significantly enhances in vitro ATP generation to elevate mitochondrial membrane potential (ΔΨm) and capillary-like tube formation, but also increases the content of intermediate metabolite, namely, citrate, in tricarboxylic acid (TCA) cycle, and ultimately promotes the formation of citrate-containing apatite during osteogenesis of hBMSCs. Furthermore, 3HB administration increases the bone mass in rats with ovariectomy (OVX)-induced osteoporosis. Results also show that the P(3HB-co-4HB) scaffold significantly enhances long-term induced bone repair in a rat model with critical-sized calvarial defects, compared to the commercialized available poly-L-lactic acid (PLLA) scaffold. Collectively, these findings uncover a previously undefined role of 3HB in promoting osteogenic differentiation of hBMSCs and highlight that the P(3HB-co-4HB) scaffold functions as a metabolically activated energetic material for bone regeneration.

Project description:3D printed scaffolds have been shown to be superior in promoting tissue repair, but the cell-level specific regulatory network activated by 3D printing scaffolds with different material components to form a symbiosis niche have not been systematically revealed. Here, three typical 3D printed scaffolds, including natural polymer hydrogel (Gelatin-methacryloyl, GelMA), synthetic polymer material (Polycaprolactone, PCL) and bioceramic (β-tricalcium phosphate, β-TCP), were fabricated to explore the regulating effect of the symbiotic microenvironment during bone healing. Enrichment analysis showed that hydrogel promotes tissue regeneration and reconstruction by improving blood vessel generation by enhancing oxygen transport and red blood cell development. The PCL scaffold regulates cell proliferation and differentiation by promoting cellular senescence, cell cycle and DNA replication pathways, accelerating the process of endochondral ossification and the formation of callus. The β-TCP scaffold can specifically enhance the expression of osteoclast differentiation and extracellular space pathway genes to promote the differentiation of osteoclasts and promote the process of bone remolding. In these processes, specific biomaterial properties can be used to guide cell behavior and regulate molecular network in the symbiotic microenvironment to reduce the barriers of regeneration and repair.

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:Scaffold architecture exerts a considerable influence on the osteogenic effect through stress transmission, as the deformation of scaffolds alters the mechanical microenvironment of cells adhering to scaffold surface. Despite extensive researches on bone regeneration influenced by scaffold architecture, present studies have not addressed the biological mechanism underlying scaffold architecture-induced stress stimulation (SASS) on cells yet, posing a great challenge in revealing the biomechanical cues between scaffold architecture and osteogenic progression. Therefore, Graphite (GP), Fullerene (FL), and Diamond (DM) scaffolds with gradient stress-stimulation to cells after deformation were prepared. The cellular biomechanical mechanisms of SASS through single-cell RNA sequencing indicated that architectures providing SASS can induce the enrichment of focal adhesion and osteogenic differentiation pathways of bone mesenchymal stem cells, and balance bone resorption of osteoclasts and bone formation of osteoblasts. Besides, SASS enhances bone regeneration for repairing critical-sized defects in vivo. These results provide insights for artificial bone scaffold design and clarify the biomechanical cues between SASS and osteogenic progression.

Project description:Bone Regeneration Facilitated by Autologous Bio-scaffold Material Liquid Concentrated Factors via Dental Follicle Stem Cell Loading