Titlebook: Computer-Aided Tissue Engineering; Methods and Protocol Alberto Rainer,Lorenzo Moroni Book 2021 Springer Science+Business Media, LLC, part

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Nanocomposite Clay-Based Bioinks for Skeletal Tissue Engineering form three-dimensional structures that can closely mimic tissues of interest. Our bioink formulation takes into account the potential for cell printing including a bioink nanocomposite that contains low fraction polymeric content to facilitate cell encapsulation and survival, while preserving hydro

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Additive Manufacturing Using Melt Extruded Thermoplastics for Tissue Engineeringaffold manufacturing is commonly achieved by one of the following extrusion-based techniques: fused deposition modelling (FDM), 3D-fiber deposition (3DF), and bioextrusion. FDM needs the input material to be strictly in the form of a filament, whereas 3DF and bioextrusion can be used to process inpu

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Computer-Aided Wet-Spinningng in controlling the external shape and macroporous structure of biomedical polymeric scaffold with those of wet-spinning in endowing the polymeric matrix with a spread microporosity. This book chapter is aimed at providing a detailed description of the experimental methods developed to fabricate b

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3D Bioprinting of Complex, Cell-laden Alginate Constructsifferent automated biofabrication techniques have been used to produce cell-laden alginate hydrogel structures, especially bioprinting approaches. These approaches have been limited to 2D or simple 3D structures, however. In this chapter, a novel bioprinting technique is disclosed for the production

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A Scaffold Free 3D Bioprinted Cartilage Model for In Vitro Toxicologynd proteins, which are sensitive to any other fabrication techniques. Bioprinting allows the generation of tissue constructs and models that closely mimic the anatomical and physiological attributes of a chosen tissue. In vitro toxicology assays can greatly benefit from bioprinting as drugs can be s

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