Project description:Rationale: Stem cell-based tracheal replacement represents an emerging therapeutic option for patients with otherwise untreatable airway diseases including long-segment congenital tracheal stenosis and upper airway tumors. Clinical experience suggests an urgent need to restore mucociliary function in the lungs following transplantation of tissue-engineered grafts, while pre-clinical studies show that seeding scaffolds with autologous mucosa improves regeneration. Recent data suggest that high epithelial cell seeding densities are required in regenerative medicine and existing techniques are inadequate to achieve coverage of clinically suitable grafts. Objectives: To define a scalable airway epithelial cell culture system to deliver airway epithelial cells to clinical grafts. Methods: Human respiratory epithelial cells derived from endobronchial biopsies were cultured using a combination of mitotically inactivated fibroblasts and Rho-kinase (ROCK) inhibition. Cells were analyzed using immunofluorescence, qPCR and flow cytometry to assess airway stem cell marker expression. Differentiation capacity and ciliary beat were assessed in air-liquid interface cultures. Karyotyping and an in vivo tracheal xenograft model were used to investigate the suitability of expanded cells for tracheal reconstruction. Measurements and Main Results: 3T3 feeder cells and ROCK inhibition allowed rapid expansion of airway basal stem cells. These cells were capable of multipotent airway differentiation in vitro, forming epithelia containing both ciliated and goblet lineages. Cilia were functional with normal beat frequency and pattern. Cultured cells repopulated a decellularized tracheal scaffold in a heterotopic tracheal transplantation xenograft model. Conclusions: Our method addresses the clinical need to generate large numbers of airway basal epithelial cells in the time window demanded by clinical transplantation.

Project description:Scaffold-free cryopreservable cartilage grafts obtained from hiPSC-derived chondroprogenitor cells for airway reconstruction with growth adaptability

Project description:Understanding wound healing in vaginal tissue is crucial for improving female health outcomes, particularly in the context of surgeries like pelvic organ prolapse, post-radiation stricture formation and complications resulting from vaginal childbirth. Tissue-engineered grafts have proven successful for vaginal tissue repair, however, the mechanisms that stimulate tissue repair are unknown. This study aims to explore the transcriptomic signatures during tissue repair after using autologous micrografting versus acellular grafts in a rabbit model for surgical vaginal reconstruction. During a single surgical procedure, we created a graft for vaginal reconstruction consisting of autologous micrografts and supporting biomaterials. This graft was named "perioperative, layered, autologous, tissue expansion (PLATE)." We also produced acellular grafts that lacked autologous micrografts,. Our findings revealed distinct differences in gene expression patterns associated with wound healing, extracellular matrix organization, and smooth muscle regeneration between the two graft types. Notably, our findings revealed that micrografting showed an accelerated progression towards the final stages of wound healing, as evidenced by elevated matrix metalloproteinase (MMP) expression, particularly MMP-13. Additionally, Transforming Growth Factor Beta-1 (TGF-β1) emerged as an expected vaginal wound healing regulator. This study provides valuable insights into the molecular mechanisms of PLATE grafts and opens new avenues for the development of targeted therapies to improve wound healing in vaginal tissues.

Project description:Cartilage endplate-derived stem cells (CESCs) with chondro-osteogenic differentiation capacity may be responsible for the balance of chondrification and ossification in cartilage endplate (CEP). CEP is an avascular and hypoxic tissue, and hypoxia could influence the fate of CESCs. We used high-throughput scanning to identify differentially expressed genes (DEGs) and alternatively spliced genes (ASGs) of CESCs under hypoxia compared to those under normoxia. Human cartilage endplate-derived stem cells (CESCs) were cultured under normoxia and hypoxia for 21 days respectively.

Project description:We used label-free proteomics approach to analyze the protein expression dynamics of the antler tip in 6 developmental periods (15, 25, 45, 65, 100 and 130 days after the previous antler cast) and costal cartilage. the stages special proteins and differentially expressed proteins (DEPs) in different development stages were analyzed.

Project description:Cartilage endplate-derived stem cells (CESCs) with chondro-osteogenic differentiation capacity may be responsible for the balance of chondrification and ossification in cartilage endplate (CEP). CEP is an avascular and hypoxic tissue, and hypoxia could inhibit the osteogenic differentiation of CESCs. We used high-throughput scanning to identify differentially expressed genes (DEGs) and alternatively spliced genes (ASGs) during osteogenic differentiation of CESCs under hypoxia compared to those induced under normoxia. Human cartilage endplate-derived stem cells (CESCs) were treated with osteogenic differentiation medium under normoxia and hypoxia for 21 days respectively.

Project description:The signaling crosstalk between the tracheal mesenchyme and epithelium has not been researched extensively leaving a substantial gap of knowledge in the mechanisms dictating embryonic development of the proximal airways by the adjacent mesenchyme. Recently, we have reported that embryos lacking mesenchymal expression of Sox9 did not develop tracheal cartilage rings and showed aberrant differentiation of the tracheal epithelium. Herein, we propose that tracheal cartilage provides local inductive signals responsible for the proper differentiation, metabolism, and inflammatory status regulation of the tracheal epithelium. The tracheal epithelium of mesenchyme-specific Sox9D/D mutants showed altered mRNA expression of various epithelial markers such as Pb1fa1, Sftpb, Scgb1a1, and Tff-1. In vitro tracheal epithelial cell cultures confirmed that tracheal chondrocytes secrete factors that inhibit club cell differentiation. Whole gene expression profiling and ingenuity pathway analysis showed that the TNF-a, IFN-g and TGF-b signaling pathways were significantly altered in the Sox9 mutant trachea. Tnf-a and Ifn-g interfered with the differentiation of tracheal epithelial progenitor cells into mature epithelial cell types in vitro. Meanwhile, mesenchymal knockout of Tgf-b1 in vivo resulted in altered differentiation of the tracheal epithelium. Finally, mitochondrial enzymes involved in fat and glycogen metabolism Cox8b and Cox7a1 were strongly up-regulated in the Sox9 mutant trachea, with consequently increased number and size of glycogen storage vacuoles. Our results support an a role for tracheal cartilage in the modulation of the differentiation and metabolism, and the expression of inflammatory related genes in the tracheal epithelium by feeding into the TNF-a, IFN-g and TGF-b signaling pathways.

Project description:Cartilage endplate-derived stem cells (CESCs) with chondro-osteogenic differentiation capacity may be responsible for the balance of chondrification and ossification in cartilage endplate (CEP). CEP is an avascular and hypoxic tissue, and hypoxia could influence the fate of CESCs. We used high-throughput scanning to identify differentially expressed genes (DEGs) and alternatively spliced genes (ASGs) of CESCs under hypoxia compared to those under normoxia.

Project description:Cartilage endplate-derived stem cells (CESCs) with chondro-osteogenic differentiation capacity may be responsible for the balance of chondrification and ossification in cartilage endplate (CEP). CEP is an avascular and hypoxic tissue, and hypoxia could inhibit the osteogenic differentiation of CESCs. We used high-throughput scanning to identify differentially expressed genes (DEGs) and alternatively spliced genes (ASGs) during osteogenic differentiation of CESCs under hypoxia compared to those induced under normoxia.

Project description:To investigate the regenerative effects of the LA@PA-TA@C composite on tracheal reconstruction, comparative whole-transcriptome profiling was conducted between experimental cohorts and control groups.