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:Understanding how mechanical stimulation affects cellular behaviors during tissue regeneration offers valuable insight into the mechanisms that regulate injury repair. We incorporated a swim tunnel exercise regimen during zebrafish caudal fin regeneration to explore exercise loading impacts on a robust model of tissue regeneration. Early exercise loading, initiated before or during blastema formation, resulted in reduced regenerative outcomes. Long-term tracking of fluorescently labeled cell lineages showed exercise loading disrupted blastemal mesenchyme formation. Transcriptomic profiling and section staining indicated loading reduced an extracellular matrix (ECM) gene expression program, including for hyaluronic acid (HA) synthesis. Like exercise loading, HA synthesis inhibition or blastemal HA depletion disrupted blastema formation. We considered if injury-upregulated HA establishes a pro-regenerative environment facilitating mechanotransduction. HA density across the blastema correlated with nuclear localization of the mechanotransducer Yes-associated protein (Yap). Further, exercise loading or HA depletion decreased nuclear Yap and Proliferative Cell Nuclear Antigen staining. We conclude early loading during fin regeneration disrupts expression of an HA-rich ECM supporting blastema expansion. Our study of mechanical loading during fin regeneration reveals a stage-dependent response similar to that seen in mammalian skeletal repair, where early exercise—applied during blastema establishment—impairs regeneration, while delayed loading during outgrowth does not, suggesting a conserved sensitivity to the timing and intensity of mechanical stimuli in regenerative processes.

Project description:Myotendinous junction (MTJ) injury cannot be repaired efficiently due to the complex composition of two tissues with distinct biological structures and mechanical properties. Previous studies designed tissue engineering scaffolds with two or more materials to mimick the distinct mechanical properties of muscle and tendon, which was a difficult and time-consuming process. Herein, we developed an integrated SilMA-PLGA scaffold incorporated with Klotho protein and bone marrow mesenchymal stem cells (BMSCs) to regulate the pathological microenvironment and tissue-resident cells for the regeneration of MTJ. The photo-crosslinked porous silk-based hydrogel (SilMA) on the 3D-printed PLGA scaffold (SM-PA) enhanced the secretory activity of BMSCs, which ensured the biological functions of macrophages, tendon stem/progenitor cells (TSPCs) and myoblasts. Besides, the incorporation of Klotho protein endowed the SM-PA scaffold with anti-oxidative and immunomodulatory properties. In an MTJ injury model of rats, this composite hydrogel scaffold (Klo/BM@SM-PA) efficiently increased the survival of transplanted BMSCs in the early post-implantation period, and presented successful MTJ regeneration capacity as evidenced by histology and immunohistochemistry evaluation. The in vivo proteomics analysis provided additional verification that the Klo/BM@SM-PA could regulate the tissue microenvironment and promote tissue regeneration

Project description:The three groups of MH-S cells were control group, 20 μg/ml CuO NPs group, and 20 μg/ml CuO NPs + 10 μM TTM group. Total RNA of the MH-S cells were extracted using cell RNA isolation kit (Vazyme Biotech Co., Ltd, China). The number of MH-S cell sample for each group were three (n = 3 cell samples/group). All samples were sent to Majorbio Biotech (Shanghai, China) for transcriptome sequencing.

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:A honeycomb-like scaffold is constructed bionicly, with DCPD-coated magnesium alloy as the matrix and zinc ion-containing AlgMa hydrogel wrapped on the outside to promote the integrated repair of bone and cartilage damage. The scaffold promotes bidirectional differentiation of BMSCs, is antibacterial, provides mechanical support, and slowly degrades by slowly releasing magnesium ions and zinc ions.

Project description:Bilayer Heterogeneous Methacrylated-Silk Fibroin Scaffold with Antibacterial and Osteoinductive Functions for Treating Infectious Bone Defects

Project description:Facile Osteoimmunomodulatory Nanoparticles Augment 3D-Printed Scaffold-Mediated Bone Regeneration

Project description:To further study the transcriptome of Caco-2 human colon epithelial-like cells after exposure to S-nitrosoglutathione (GSNO, 1.4 μM), or Eudragit RL PO polymeric nanoparticles (NP-ERL, 50 μg/mL) or GSNO loaded nanoparticles (NP-GSNO, 50 μg/mL corresponding to (1.4 μM GSNO) we investigate whole genome microarray to identify genes regulates by exposure or not to GSNO (1.4 μM) or Eudragit RL PO polymeric nanoparticles (NP-ERL, 50 μg/mL) or GSNO loaded nanoparticles (NP-GSNO, 50 μg/mL corresponding to (1.4 μM GSNO).

Project description:The objective of our study was to use a microarray to distinguish the molecular responses between woven and lamellar bone formation induced through mechanical loading. The micorarray identified numerous genes and pathways that were differentially regulated for woven, but not lamellar bone formation. Rat forelimb loading was completed in a single bout to induce the formation of woven bone (WBF loading) or lamellar bone (LBF loading). A set of normal (non-loaded) rats were used as controls. Microarrays were performed at three timepoints after loading: 1 hr, 1 day and 3 days.