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The Primordium Of A Biological Joint Replacement: Coupling Of Two Stem Cell Pathways In Biphasic Ultrasound Compressed Gel Niches, Mariea Brady, Sureshan Sivananthan, Vivek Mudera, Qin Liu, Joerg Wiltfang, Patrick Warnke
The Primordium Of A Biological Joint Replacement: Coupling Of Two Stem Cell Pathways In Biphasic Ultrasound Compressed Gel Niches, Mariea Brady, Sureshan Sivananthan, Vivek Mudera, Qin Liu, Joerg Wiltfang, Patrick Warnke
Qin Liu
The impaired temporomandibular joint might be the first to benefit from applied tissue engineering techniques because it is small and tissue growth in larger amounts is challenging. Bone and cartilage require different competing environmental conditions to be cultivated in vitro. But coupling both the osteogenic and cartilaginous pathways of mesenchymal stem cell differentiation in homeostasis will be a key essential to grow osteochondral constructs or even the first biological joint replacement in the future.
The aim of this study was to test a single source biomaterial and a single source cell type to engineer a biphasic osteochondral construct in vitro …
Primordium Of An Artificial Bruch's Membrane Made Of Nanofibers For Engineering Of Retinal Pigment Epithelium Cell Monolayers, Patrick Warnke, Mohammad Alamein, Stuart Skabo, Sebastien Stephens, Robert Bourke, Peter Heiner, Qin Liu
Primordium Of An Artificial Bruch's Membrane Made Of Nanofibers For Engineering Of Retinal Pigment Epithelium Cell Monolayers, Patrick Warnke, Mohammad Alamein, Stuart Skabo, Sebastien Stephens, Robert Bourke, Peter Heiner, Qin Liu
Qin Liu
Transplanted Retinal Pigment Epithelium(RPE) cells hold promise for treatment of Age-related Macular Degeneration(AMD) and Stargardt Disease(SD), but it is conceivable that the degenerated host Bruch's membrane(BM) as a natural substrate for RPE might not optimally support transplanted cell survival with correct cellular organization. We fabricated novel ultrathin 3-dimensional(3D) nanofibrous membranes from Collagen type I and poly(lactic-co-glycolic acid) (PLGA) by an advanced clinical-grade needle-free-electrospinning process. The nanofibrillar 3D networks highly mimicked the fibrillar architecture of the native inner collagenous layer of human BM. Human RPE cells grown on our nanofibrous membranes bore striking resemblance to native human RPE. They exhibited a …