Sarah Bertlein
University of Würzburg
7 Papers
19 Citations
Sarah Bertlein is an academic researcher from University of Würzburg. The author has contributed to research in topics: Biofabrication & Self-healing hydrogels. The author has an hindex of 5, co-authored 7 publications.
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Papers
Thiol-Ene Clickable Gelatin: A Platform Bioink for Multiple 3D Biofabrication Technologies
Sarah Bertlein,Gabriella C. J. Brown,Khoon S. Lim,Tomasz Jungst,Thomas Boeck,Torsten Blunk,Joerg Tessmar,Gary J. Hooper,Tim B. F. Woodfield,Juergen Groll +9 more
TL;DR: It is demonstrated that GelAGE may serve as a platform bioink for several biofabrication technologies by fabricating constructs with high shape fidelity via lithography‐based (digital light processing) 3D printing and extrusion‐based 3D bioprinting, the latter supporting long‐term viability postprinting of encapsulated chondrocytes.
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Double printing of hyaluronic acid/poly(glycidol) hybrid hydrogels with poly(ε-caprolactone) for MSC chondrogenesis
Simone Stichler,Thomas Böck,Naomi C. Paxton,Sarah Bertlein,Riccardo Levato,Verena Schill,Willi Smolan,Jos Malda,Jörg Teßmar,Torsten Blunk,Jürgen Groll +10 more
TL;DR: Embedding of human and equine mesenchymal stem cells in the gels and subsequent in vitro culture showed promising chondrogenic differentiation after 21 d for cells from both origins, and cells could be printed with these gels, and embedded hMSCs showed good cell survival for at least 21 d in culture.
139
Development of Endothelial Cell Networks in 3D Tissues by Combination of Melt Electrospinning Writing with Cell-Accumulation Technology
Sarah Bertlein,Daichi Hikimoto,Gernot Hochleitner,Julia Hümmer,Tomasz Jungst,Michiya Matsusaki,Mitsuru Akashi,Jürgen Groll +7 more
TL;DR: The combination of 3D-printed poly-ε-caprolactone scaffolds via melt electrospinning writing with the cell-accumulation technique to enable the formation and control of capillary-like network structures is reported, yielding tissue thicknesses that are doubled.
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Live-cell super-resolution imaging of intrinsically fast moving flagellates*
Marius Glogger,Simone Stichler,Ines Subota,Sarah Bertlein,M. C. Spindler,Jörg Teßmar,Jürgen Groll,Markus Engstler,Susanne F. Fenz +8 more
TL;DR: An embedding method based on a in situ forming cytocompatible UV-crosslinked hydrogel that immobilizes trypanosomes efficiently to allow microscopy on the nanoscale and presents an image of a flagellar axoneme component recorded by using the intrinsic blinking behavior of eYFP.
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