22 research outputs found
Chondrogenesis of Human Infrapatellar Fat Pad Stem Cells on Acellular Dermal Matrix
Acellular dermal matrix (ADM) has been in clinical use for decades in numerous surgical applications. The ability for ADM to promote cellular repopulation, revascularisation and tissue regeneration is well documented. Adipose stem cells have the ability to differentiate into mesenchymal tissue types, including bone and cartilage. The aim of this study was to investigate the potential interaction between ADM and adipose stem cells in vitro using TGFβ3 and BMP6. Human infrapatellar fat pad-derived adipose stem cells (IPFP-ASC) were cultured with ADM derived from rat dermis in chondrogenic (TGFβ3 and BMP6) medium in vitro for 2 and 4 weeks. Histology, qPCR, and immunohistochemistry were performed to assess for markers of chondrogenesis (collagen Type II, SOX9 and proteoglycans). At 4 weeks, cell-scaffold constructs displayed cellular changes consistent with chondrogenesis, with evidence of stratification of cell layers and development of a hyaline-like cartilage layer superficially, which stained positively for collagen Type II and proteoglycans. Significant cell-matrix interaction was seen between the cartilage layer and the ADM itself with seamless integration between each layer. Real time qPCR showed significantly increased COL2A1, SOX9, and ACAN gene expression over 4 weeks when compared to control. COL1A2 gene expression remained unchanged over 4 weeks. We believe that the principles that make ADM versatile and successful for tissue regeneration are applicable to cartilage regeneration. This study demonstrates in vitro the ability for IPFP-ASCs to undergo chondrogenesis, infiltrate, and interact with ADM. These outcomes serve as a platform for in vivo modelling of ADM for cartilage repair
Bioengineering of articular cartilage: Past, present and future
The treatment of cartilage defects poses a clinical challenge owing to the lack of intrinsic regenerative capacity of cartilage. The use of tissue engineering techniques to bioengineer articular cartilage is promising and may hold the key to the successful regeneration of cartilage tissue. Natural and synthetic biomaterials have been used to recreate the microarchitecture of articular cartilage through multilayered biomimetic scaffolds. Acellular scaffolds preserve the microarchitecture of articular cartilage through a process of decellularization of biological tissue. Although promising, this technique often results in poor biomechanical strength of the graft. However, biomechanical strength could be improved if biomaterials could be incorporated back into the decellularized tissue to overcome this limitation
Regulation of osteopontin expression by type 1 collagen in preosteoblastic UMR201 cells
When UMR201 cells, phenotypically preosteoblastic, were placed onto a type I collagen gel, expression of osteopontin (OP) mRNA and protein were strongly upregulated, compared to cells plated onto plastic. This upregulation was dose-dependent, with respect to the concentration of collagen gel, and was observable within hours of cells having attached and spread on the substrate. Retinoic acid (RA) acted synergistically with type I collagen at each concentration to induce a much greater increase in OP mRNA than in cells on plastic. In addition, RA increased the phosphorylation of secreted OP. The exogenous collagen substrate inhibited the growth of UMR201 cells, with the extent and duration of inhibition dependent on the collagen concentration. The effect of type I collagen was specific; plating cells on fibronectin, laminin or vitronectin did not upregulate OP expression. In contrast to the effects on OP expression, the strong RA induction of alkaline phosphatase (ALP) mRNA in cells on plastic was attenuated in cells plated on type I collagen. Growth on type I collagen did not change OP mRNA stability or transcription rate, although there was decreased stability of the ALP mRNA in cells on collagen