Saeb aigner biography examples
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Wissenschaftlicher Artikel in Font Nature , ()
Suzuki, K. ; Hatzikotoulas, K. ; Southam, L. ; Taylor, H.J. ; Yin, X. ; Lorenz, K.M. ; Mandla, R. ; Huerta-Chagoya, A. ; Melloni, G.E.M. ; Kanoni, S. ; Rayner, N.W. ; Bocher, O. ; Arruda, A.L. ; Sonehara, K. ; Namba, S. ; Lee, S.S.K. ; Preuss, M.H. ; Petty, L.E. ; Schroeder, P. ; Vanderwerff, B.R. ; Kals, M. ; Bragg, F. ; Lin, K. ; Guo, X. ; Zhang, W. ; Yao, J. ; Kim, Y.J. ; Graff, M. ; Takeuchi, F. ; Nano, J. ; Lamri, A. ; Nakatochi, M. ; Moon, S. ; Scott, R.A. ; Cook, J.P. ; Lee, J.J. ; Pan, I. ; Taliun, D. ; Parra, E.J. ; Chai, J.F. ; Bielak, L.F. ; Tabara, Y. ; Hai, Y. ; Thorleifsson, G. ; Grarup, N. ; Sofer, T. ; Wuttke, M. ; Sarnowski, C. ; Gieger, C. ; Nousome, D. ; Trompet, S. ; Kwak, S.H. ; Long, J.&
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Marine polymers in tissue bioprinting: Current achievements and challenges
1 Introduction
The development of regenerative medicine, and thus new opportunities so far unattained in tissue engineering, has been made possible by combining cell culture-related technologies, materials science, and 3D printing. The primary tissue engineering strategy is to produce functional in vitro constructs capable of restoring, preserving, and revitalizing lost tissues and organs using bioprinting [1,2]. The advantage of bioprinting over conventional cell scaffolds fabrication techniques such as solvent casting, gas forming, membrane lamination, salt leaching, and fiber binding makes it possible to mimic the complex microstructure of biological tissues. The bioprinting technique provides the ability and versatility to deliver cells from complex microstructures with excellent spatial distribution by focusing on three approaches: biomimicry, autonomous cell self-organization, and mini-tissue building blocks [3]. The first approach involves understanding the microenvironment of a given tissue. Therefore, when designing cellular scaffolds, the distribution of cells and the composition of the extracellular matrix (ECM), among other things, must be taken into account. On the other hand, autonomou
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Abstract
The pandemic of the coronavirus disease (COVID) has made biotextiles, including face masks and protective clothing, quite familiar in our daily lives. Biotextiles are one broad category of textile products that are beyond our imagination. Currently, biotextiles have been routinely utilized in various biomedical fields, like daily protection, wound healing, tissue regeneration, drug delivery, and sensing, to improve the health and medical conditions of individuals. However, these biotextiles are commonly manufactured with fibers with diameters on the micrometer scale (> 10 μm). Recently, nanofibrous materials have aroused extensive attention in the fields of fiber science and textile engineering because the fibers with nanoscale diameters exhibited obviously superior performances, such as size and surface/interface effects as well as optical, electrical, mechanical, and biological properties, compared to microfibers. A combination of innovative electrospinning techniques and traditional textile-forming strategies opens a new window for the generation of nanofibrous biotextiles to renew and update traditional microfibrous biotextiles. In the last two decades, the conventional electrospinning device has been widely modified to generate nanofiber yarns (NYs) with the