Coordinated investigations into the interactions between biologically mimicking(biomimetic)material constructs and stem cells advance the potential for the regeneration and possible direct replacement of diseased cell...Coordinated investigations into the interactions between biologically mimicking(biomimetic)material constructs and stem cells advance the potential for the regeneration and possible direct replacement of diseased cells and tissues.Any clinically relevant therapies will require the development and optimization of methods that mass produce fully functional cells and tissues.Despite advances in the design and synthesis of biomaterial scaffolds,one of the biggest obstacles facing tissue engineering is understanding how specific extracellular cues produced by biomaterial scaffolds influence the proliferation and differentiation of various cell sources.Matrix elasticity is one such tailorable property of synthetic scaffolds that is known to differ between tissues.Here,we investigate the interactions between an elastically tailorable polyethylene glycol(PEG)-based hydrogel platform and human bone marrow-derived mesenchymal stem cells(hMSCs).For these studies,two different hydrogel compositions with elastic moduli in the ranges of 50-60 kPa and 8-10 kPa were implemented.Our findings demonstrate that the different elasticities in this platform can produce changes in hMSC morphology and proliferation,indicating that the platform can be implemented to produce changes in hMSC behavior and cell state for a broad range of tissue engineering and regenerative applications.Furthermore,we show that the platform’s different elasticities influence stem cell differentiation potential,particularly when promoting stem cell differentiation toward cell types from tissues with stiffer elasticity.These findings add to the evolving and expanding library of information on stem cell-biomaterial interactions and opens the door for continued exploration into PEG-based hydrogel scaffolds for tissue engineering and regenerative medicine applications.展开更多
基金This work was funded by the Louisiana Biomedical Research Network(LBRN)NIH INBRE P20GM103424the Center for Cardiovascular Diseases and Sciences at LSU Health Shreveport in the form of the Partners Across Campus grants.
文摘Coordinated investigations into the interactions between biologically mimicking(biomimetic)material constructs and stem cells advance the potential for the regeneration and possible direct replacement of diseased cells and tissues.Any clinically relevant therapies will require the development and optimization of methods that mass produce fully functional cells and tissues.Despite advances in the design and synthesis of biomaterial scaffolds,one of the biggest obstacles facing tissue engineering is understanding how specific extracellular cues produced by biomaterial scaffolds influence the proliferation and differentiation of various cell sources.Matrix elasticity is one such tailorable property of synthetic scaffolds that is known to differ between tissues.Here,we investigate the interactions between an elastically tailorable polyethylene glycol(PEG)-based hydrogel platform and human bone marrow-derived mesenchymal stem cells(hMSCs).For these studies,two different hydrogel compositions with elastic moduli in the ranges of 50-60 kPa and 8-10 kPa were implemented.Our findings demonstrate that the different elasticities in this platform can produce changes in hMSC morphology and proliferation,indicating that the platform can be implemented to produce changes in hMSC behavior and cell state for a broad range of tissue engineering and regenerative applications.Furthermore,we show that the platform’s different elasticities influence stem cell differentiation potential,particularly when promoting stem cell differentiation toward cell types from tissues with stiffer elasticity.These findings add to the evolving and expanding library of information on stem cell-biomaterial interactions and opens the door for continued exploration into PEG-based hydrogel scaffolds for tissue engineering and regenerative medicine applications.
