Abstract
Background Pelvic organ prolapse (POP) is a common debilitating condition affecting about 30–40% of women. The application of stem cells therapy and growth factor has greatly promoted the development of pelvic tissue engineering, which remains a promising approach, but there is no consensus on the therapeutic mechanism of stem cells and the application of growth factors. Stem cells were mainly used as seed cells to differentiate into target tissue cells, fuse with target tissue after transplantation and paracrine effect to play a therapeutic role in pelvic tissue engineering. However, whether stem cells can be differentiated into target tissue cells is still to be a question,in this regard, the contemporary trend is to investigated the effect of adipose-derived stem cells (ADSCs) as the seed cells of pelvic tissue engineering on the repair of POP and the underlying mechanisms.Methods In the present study,we evaluated the therapeutic potential of gene-modified ADSC that overexpress basic fibroblast growth factor(bFGF)and evaluated its effects on paracrine function and directional differentiation ability.Results The results showed that following ADSCs are designed to continuously release controllable levels of growth factors during the control period of repair, taking advantage of the paracrine function of stem cells to accelerate cell growth and extracellular matrix (ECM) reconstruction during the early stage of stem cell implantation, and then stem cells are differentiated into target tissues-fibroblasts to accelerate the reconstruction of pelvic floor tissues.Conclusions We suggest that the observed effects are determined by pleiotropic effects of bFGF, along with the multifactorial paracrine action of ADSC which remain viable and functionally active within the engineered cell construct.Thus, we demonstrated the high therapeutic potential of the utilized approach for pelvic tissue engineering.
Retracted: Use of Decellularized Scaffolds Combined with Hyaluronic Acid and Basic Fibroblast Growth Factor for Skin Tissue Engineering
