Add to ORKGWe investigated the biological response of human pluripotent stem cells (hPSCs) cultured on a carbon nanotube (CNT) array-based substrate with the long term goal to direct hPSC germ layer specification for a wide variety of tissue engineering applications. CNT arrays were fabricated using a chemical vapor deposition system allowing for control over surface roughness and mechanical stiffness. Our results demonstrated that hPSCs readily attach to hydrophilized and extracellular matrix coated CNT arrays. hPSCs cultured as colonies in conditions supporting self-renewal demonstrated the morphology and marker expression of undifferentiated hPSCs. Conditions inducing spontaneous differentiation lead to hPSC commitment to all three embryonic germ l...
Novel synthetic biomaterials able to support direct tissue growth and retain cellular phenotypical p...
New strategies for spatially controlled growth of human neurons may provide viable solutions to trea...
Carbon nanotube (CNT)–modified surfaces unequivocally demonstrate their biocompatibility and ability...
We investigated the biological response of human pluripotent stem cells (hPSCs) cultured on a carbon...
Here we show an industrially scalable and inexpensive method of fabricating entirely synthetic, non-...
Here we show an industrially scalable and inexpensive method of fabricating entirely synthetic, non-...
Stem cell research has been fueled by increasing evidence of their great promise in clinical regener...
In order to successfully utilize stem cells for therapeutic applications in regenerative medicine, e...
BACKGROUND & AIM: Carbon nanotubes (CNTs) are a promising material for implantation due to the fact ...
Carbon nanotube (CNT) networks on solid substrates have recently drawn attention as a means to direc...
Carbon nanotube (CNT) monolayer patterns are utilized to control the growth of mesenchymal stem cell...
The functionality of stem cells is tightly regulated by cues from the niche, comprising both intrins...
Biological tissues are compositionally and structurally exquisite – a complex network of proteins an...
We investigated the cellular adhesive features of mesenchymal stem cells (MSC) on non-coated and col...
Expansion of mesenchymal stem cells (MSCs) and maintenance of their self-renewal capacity in vitro r...
Novel synthetic biomaterials able to support direct tissue growth and retain cellular phenotypical p...
New strategies for spatially controlled growth of human neurons may provide viable solutions to trea...
Carbon nanotube (CNT)–modified surfaces unequivocally demonstrate their biocompatibility and ability...
We investigated the biological response of human pluripotent stem cells (hPSCs) cultured on a carbon...
Here we show an industrially scalable and inexpensive method of fabricating entirely synthetic, non-...
Here we show an industrially scalable and inexpensive method of fabricating entirely synthetic, non-...
Stem cell research has been fueled by increasing evidence of their great promise in clinical regener...
In order to successfully utilize stem cells for therapeutic applications in regenerative medicine, e...
BACKGROUND & AIM: Carbon nanotubes (CNTs) are a promising material for implantation due to the fact ...
Carbon nanotube (CNT) networks on solid substrates have recently drawn attention as a means to direc...
Carbon nanotube (CNT) monolayer patterns are utilized to control the growth of mesenchymal stem cell...
The functionality of stem cells is tightly regulated by cues from the niche, comprising both intrins...
Biological tissues are compositionally and structurally exquisite – a complex network of proteins an...
We investigated the cellular adhesive features of mesenchymal stem cells (MSC) on non-coated and col...
Expansion of mesenchymal stem cells (MSCs) and maintenance of their self-renewal capacity in vitro r...
Novel synthetic biomaterials able to support direct tissue growth and retain cellular phenotypical p...
New strategies for spatially controlled growth of human neurons may provide viable solutions to trea...
Carbon nanotube (CNT)–modified surfaces unequivocally demonstrate their biocompatibility and ability...