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Electrospun Nanofibers for Biomedical Applications

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ISBN: 9783039287741 / 9783039287758 Year: Pages: 308 DOI: 10.3390/books978-3-03928-775-8 Language: eng
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Technology (General)
Added to DOAB on : 2020-06-09 16:38:57
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Abstract

Electrospinning is a versatile and effective technique widely used to manufacture nanofibrous structures from a diversity of materials (synthetic, natural or inorganic). The electrospun nanofibrous meshes’ composition, morphology, porosity, and surface functionality support the development of advanced solutions for many biomedical applications. The Special Issue on “Electrospun Nanofibers for Biomedical Applications” assembles a set of original and highly-innovative contributions showcasing advanced devices and therapies based on or involving electrospun meshes. It comprises 13 original research papers covering topics that span from biomaterial scaffolds’ structure and functionalization, nanocomposites, antibacterial nanofibrous systems, wound dressings, monitoring devices, electrical stimulation, bone tissue engineering to first-in-human clinical trials. This publication also includes four review papers focused on drug delivery and tissue engineering applications.

Keywords

sol-gel --- electrospinning --- hydroxyapatite --- nanofiber --- antibacterial --- titanium --- antibacterial coatings --- electrospinning --- nanocomposite coatings --- TiO2 photocatalytic --- orthopedic infections --- electrospinning --- 3D printing --- nanofibers --- encapsulation --- protein diffusion --- in vivo tissue engineering --- immuno-isolation --- transplantation --- electrospinning --- sputtering --- drug delivery --- wound dressing --- biocompatibility --- tissue engineering --- biomimetic scaffolds --- gelatin --- electrospinning --- micromolding --- biomaterials --- poly(lactic acid) (PLLA) --- bioactive glass --- scaffolds --- electrospinning --- composite fibres --- bone regeneration --- poly(vinylidene fluoride) --- composite nanofiber --- piezoelectricity --- antioxidant activity --- well-aligned nanofibers --- P(VDF-TrFE) --- piezoelectric nanogenerator --- preosteoblasts electrospinning --- silicone modified polyurethane nanofibers --- physical properties --- cell attachment --- cell proliferation --- cytotoxicity --- biopolymers --- packaging --- pharmaceutical --- biomedical --- electrospinning --- alginate --- gelatin fibers --- ZnO particles --- antibacterial activity --- electrospinning --- nanofibers --- fabrication --- therapeutics --- biomedical applications --- antibody immobilization --- electrospun nanofibers --- TNF-? capture --- human articular chondrocytes --- rheumatoid arthritis --- nanofibers --- microfluidic chip --- electrospinning --- live assay --- hepatocellular carcinoma cells --- PLA95 --- biocompatibility --- guided tissue regeneration (GTR) --- electrospinning --- electrospun fiber mats --- mechanobiology --- glioblastoma --- biomaterials --- finite element modeling --- electrospun nanofibers --- cancer treatment --- drug release --- nanomedicine --- biocompatible polymers --- hyperthermia

Biomaterials for Bone Tissue Engineering

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ISBN: 9783039289653 / 9783039289660 Year: Pages: 244 DOI: 10.3390/books978-3-03928-966-0 Language: eng
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Technology (General) --- General and Civil Engineering
Added to DOAB on : 2020-06-09 16:38:57
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Abstract

Bone tissue engineering aims to develop artificial bone substitutes that partially or totally restore the natural regeneration capability of bone tissue lost under circumstances of injury, significant defects, or diseases such as osteoporosis. In this context, biomaterials are the keystone of the methodology. Biomaterials for bone tissue engineering have evolved from biocompatible materials that mimic the physical and chemical environment of bone tissue to a new generation of materials that actively interacts with the physiological environment, accelerating bone tissue growth. Mathematical modelling and simulation are important tools in the overall methodology. This book presents an overview of the current investigations and recent contributions in the field of bone tissue engineering. It includes several successful examples of multidisciplinary collaboration in this transversal area of research. The book is intended for students, researchers, and professionals of a number of disciplines, such as engineering, mathematics, physics, chemistry, biomedicine, biology, and veterinary. The book is composed of an editorial section and 16 original research papers authored by leading researchers of this discipline from different laboratories across the world

Keywords

Pelvis --- Bone tumor --- 3D-printed implant --- Fixation design --- von Mises stress --- dental implants --- osseointegration --- resonance frequency analysis --- biomaterials --- titanium --- powder metallurgy --- loose sintering --- finite element method --- mechanical behaviour --- bone tissue regeneration --- computed tomography --- Xenografts --- stem cell --- cartilage --- finite element --- finite-element simulation --- electric stimulation --- bone regeneration --- computational modelling --- electrically active implants --- bioelectromagnetism --- critical size defect --- maxillofacial --- minipig --- oxygen delivery --- optimization --- mass transfer --- transport --- bone tissue engineering --- computational fluid dynamics --- Lattice Boltzmann method --- scaffold design --- culturing protocol --- Lagrangian scalar tracking --- cortical bone --- damage --- finite elements --- numerical results --- adipogenesis --- bone marrow --- MSCs --- prediction marker --- bone tissue --- elastoplasticity --- finite element method --- fracture risk --- osteoporosis --- trabeculae --- trabecular bone score --- vertebra --- biomechanics --- finite element modelling --- pelvis --- bone adaptation --- musculoskeletal modelling --- bone tissue engineering --- biomaterials --- computational mechanobiology --- numerical methods in bioengineering --- Ti6Al4V scaffolds --- triply periodic minimal surfaces --- selective laser melting --- additive manufacturing --- biomaterial applications --- finite element analysis --- spark plasma sintering --- wollastonite --- human dental pulp stem cells --- substrate-mediated electrical stimulation --- direct current electric field --- osteo-differentiation --- bone morphogenesis proteins --- cortical bone --- digital image correlation --- multiscale analysis --- micromechanics --- computational mechanics --- cone beam computed tomography --- automatic segmentation --- sliding window --- 3D virtual surgical plan --- Otsu’s method --- n/a

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MDPI - Multidisciplinary Digital Publishing Institute (2)


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CC by-nc-nd (2)


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eng (2)


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2020 (2)