Titlebook: Biomaterials- and Microfluidics-Based Tissue Engineered 3D Models; J. Miguel Oliveira,Rui L. Reis Book 2020 Springer Nature Switzerland AG

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https://doi.org/10.1007/978-3-8349-9829-3 . models do not truly replicate the native bone tissue environment. For so, new and improved . tissue models are necessary to obtain more reliable data, not only in a development point of view, but also to fasten the translation of new drugs into the clinics. In this reasoning, tissue-engineering s

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https://doi.org/10.1007/978-3-8349-9829-3ic processing of biomaterials, mainly polymeric materials of natural origin, focusing on water-soluble polymers that form non-flowing phases after crosslinking. Some polysaccharides and proteins, including agarose, alginate, chitosan, gellan gum, hyaluronic acid, collagen, gelatin, and silk fibroin

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https://doi.org/10.1007/978-3-8349-9829-3 rates of new drugs in clinical trials, which threaten cancer patient prognosis. Tremendous efforts have been directed towards the development of a new generation of highly predictable pre-clinical models capable to reproduce . the biological complexity of the human body. Recent advances in nanotech

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Konzeptionen gegen Jugendarbeitslosigkeit engineered tissue construct were centered on the concept of seeding cells onto biomaterial scaffold. By means of innovative manufacturing machineries, the conception of a preformed scaffold became possible. Nowadays, several tissue engineering challenges are associated with applying this scaffold t

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Exkurs: Ergebnisse eines Workshops,Wide range of micro-chambers with diversity of channel systems and multiple compartments enable users to create models which closely mimic nervous tissue structure which nowadays is often called as brain-on-a-chip technology. Heretofore experiments showing the influence of substance gradients, cell

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