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Polylactic acid. --- PLA (Polylactic acid) --- Poly-lactide --- Polylactide --- Biodegradable plastics --- Polyesters --- Composite materials. --- Composites (Materials) --- Multiphase materials --- Reinforced solids --- Solids, Reinforced --- Two phase materials --- Materials

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The series Advances in Polymer Science presents critical reviews of the present and future trends in polymer and biopolymer science. It covers all areas of research in polymer and biopolymer science including chemistry, physical chemistry, physics, material science. The thematic volumes are addressed to scientists, whether at universities or in industry, who wish to keep abreast of the important advances in the covered topics. Advances in Polymer Science enjoys a longstanding tradition and good reputation in its community. Each volume is dedicated to a current topic, and each review critically surveys one aspect of that topic, to place it within the context of the volume. The volumes typically summarize the significant developments of the last 5 to 10 years and discuss them critically, presenting selected examples, explaining and illustrating the important principles, and bringing together many important references of primary literature. On that basis, future research directions in the area can be discussed. Advances in Polymer Science volumes thus are important references for every polymer scientist, as well as for other scientists interested in polymer science - as an introduction to a neighboring field, or as a compilation of detailed information for the specialist. Review articles for the individual volumes are invited by the volume editors. Single contributions can be specially commissioned. Readership: Polymer scientists, or scientists in related fields interested in polymer and biopolymer science, at universities or in industry, graduate students.

Polymers. --- Surfaces (Physics). --- Biomedical engineering. --- Polymer Sciences. --- Characterization and Evaluation of Materials. --- Materials Engineering. --- Biomedical Engineering and Bioengineering. --- Clinical engineering --- Medical engineering --- Bioengineering --- Biophysics --- Engineering --- Medicine --- Physics --- Surface chemistry --- Surfaces (Technology) --- Polymere --- Polymeride --- Polymers and polymerization --- Macromolecules --- Polylactic acid. --- PLA (Polylactic acid) --- Poly-lactide --- Polylactide --- Biodegradable plastics --- Polyesters --- Polymers  . --- Materials science. --- Engineering—Materials. --- Material science --- Physical sciences

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Additive manufacturing (AM) processes are gaining more and more attention from many industrial fields, mainly because they are revolutionizing the components’ designs and production lines. The complete industrialization of these processes has to be supported by the full understanding of correlation between AM building conditions and the final materials’ properties. Another critical aspect is that nowadays only a reduced number of materials processable by AM are available on the market. It is, therefore, fundamental to widen the materials’ portfolio, and to study and develop new materials that can take advantage of these unique building processes.

History of engineering & technology --- amorphous poly(lactide acid) --- poly(styrene-co-methyl methacrylate) --- polymer blends --- filament extrusion --- 3D printing --- additive manufacturing --- silicon nitride --- high performance ceramics --- photopolymerisation --- lithography-based ceramic manufacturing --- fused-deposition modeling --- mechanical properties --- thermal behavior --- polyetherimide --- fused filament modelling --- design of experiments --- directed energy deposition --- AISI 316L --- microstructure --- LPBF --- as-built --- as-cast --- microhardness --- tensile test --- Ni–Cu alloy --- materials development --- polymers --- metals --- ceramics --- amorphous poly(lactide acid) --- poly(styrene-co-methyl methacrylate) --- polymer blends --- filament extrusion --- 3D printing --- additive manufacturing --- silicon nitride --- high performance ceramics --- photopolymerisation --- lithography-based ceramic manufacturing --- fused-deposition modeling --- mechanical properties --- thermal behavior --- polyetherimide --- fused filament modelling --- design of experiments --- directed energy deposition --- AISI 316L --- microstructure --- LPBF --- as-built --- as-cast --- microhardness --- tensile test --- Ni–Cu alloy --- materials development --- polymers --- metals --- ceramics

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Beauty masks, diapers, wound dressings, wipes, protective clothes and biomedical products: all these high-value and/or large-volume products must be highly compatible with human skin and they should have specific functional properties, such as anti-microbial, anti-inflammatory and anti-oxidant properties. They are currently partially or totally produced using fossil-based sources, with evident issues linked to their end of life, as their waste generates an increasing environmental concern. On the contrary, biopolymers and active biomolecules from biobased sources could be used to produce new materials that are highly compatible with the skin and also biodegradable. The final products can be obtained by exploiting safe and smart nanotechnologies such as the extrusion of bionanocomposites and electrospinning/electrospray, as well as innovative surface modification and control methodologies. For all these reasons, recently, many researchers, such as those involved in the European POLYBIOSKIN project activities, have been working in the field of biomaterials with anti-microbial, anti-inflammatory and anti-oxidant properties, as well as biobased materials which are renewable and biodegradable. The present book gathered research and review papers dedicated to materials and technologies for high-performance products where the attention paid to health and environmental impact is efficiently integrated, considering both the skin-compatibility of the selected materials and their source/end of life.

Research & information: general --- pullulan --- biopolymers --- exopolysaccharides --- biodegradation --- biocompatibility --- poly(lactic acid) --- poly(butylene succinate) --- chitin nanofibrils --- starch --- skin compatibility --- anti-microbial --- poly(hydroxyalkanoate) --- biopolyesters --- beauty masks --- releasing --- skin compatible --- polyhydroxyalkanotes --- sugarcane molasses --- antibacterial materials --- essential oils --- coating --- poly(lactide) --- chitin–lignin nanocomplex --- grafting from --- lactide oligomers --- platelet-rich fibrin --- wound healing --- skin wounds --- wound dressing --- hyperspectral imaging --- principal component analysis --- spectroscopy --- chitosan --- partial least squares regression --- nir --- actives substances --- cn-nl/ga --- skin --- antifouling --- antimicrobial --- antiviral --- electrospinning --- breast implant --- ear prosthesis --- biomedical device --- chronic wound --- biopolymer --- bio-based --- surface modification --- nanolignin --- electrospray --- anti-inflammatory --- blends --- PLA --- PHBV --- nanocomposite --- tissue engineering --- biodegradable --- nanofiber --- n/a --- chitin-lignin nanocomplex

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Beauty masks, diapers, wound dressings, wipes, protective clothes and biomedical products: all these high-value and/or large-volume products must be highly compatible with human skin and they should have specific functional properties, such as anti-microbial, anti-inflammatory and anti-oxidant properties. They are currently partially or totally produced using fossil-based sources, with evident issues linked to their end of life, as their waste generates an increasing environmental concern. On the contrary, biopolymers and active biomolecules from biobased sources could be used to produce new materials that are highly compatible with the skin and also biodegradable. The final products can be obtained by exploiting safe and smart nanotechnologies such as the extrusion of bionanocomposites and electrospinning/electrospray, as well as innovative surface modification and control methodologies. For all these reasons, recently, many researchers, such as those involved in the European POLYBIOSKIN project activities, have been working in the field of biomaterials with anti-microbial, anti-inflammatory and anti-oxidant properties, as well as biobased materials which are renewable and biodegradable. The present book gathered research and review papers dedicated to materials and technologies for high-performance products where the attention paid to health and environmental impact is efficiently integrated, considering both the skin-compatibility of the selected materials and their source/end of life.

Research & information: general --- pullulan --- biopolymers --- exopolysaccharides --- biodegradation --- biocompatibility --- poly(lactic acid) --- poly(butylene succinate) --- chitin nanofibrils --- starch --- skin compatibility --- anti-microbial --- poly(hydroxyalkanoate) --- biopolyesters --- beauty masks --- releasing --- skin compatible --- polyhydroxyalkanotes --- sugarcane molasses --- antibacterial materials --- essential oils --- coating --- poly(lactide) --- chitin-lignin nanocomplex --- grafting from --- lactide oligomers --- platelet-rich fibrin --- wound healing --- skin wounds --- wound dressing --- hyperspectral imaging --- principal component analysis --- spectroscopy --- chitosan --- partial least squares regression --- nir --- actives substances --- cn-nl/ga --- skin --- antifouling --- antimicrobial --- antiviral --- electrospinning --- breast implant --- ear prosthesis --- biomedical device --- chronic wound --- biopolymer --- bio-based --- surface modification --- nanolignin --- electrospray --- anti-inflammatory --- blends --- PLA --- PHBV --- nanocomposite --- tissue engineering --- biodegradable --- nanofiber --- pullulan --- biopolymers --- exopolysaccharides --- biodegradation --- biocompatibility --- poly(lactic acid) --- poly(butylene succinate) --- chitin nanofibrils --- starch --- skin compatibility --- anti-microbial --- poly(hydroxyalkanoate) --- biopolyesters --- beauty masks --- releasing --- skin compatible --- polyhydroxyalkanotes --- sugarcane molasses --- antibacterial materials --- essential oils --- coating --- poly(lactide) --- chitin-lignin nanocomplex --- grafting from --- lactide oligomers --- platelet-rich fibrin --- wound healing --- skin wounds --- wound dressing --- hyperspectral imaging --- principal component analysis --- spectroscopy --- chitosan --- partial least squares regression --- nir --- actives substances --- cn-nl/ga --- skin --- antifouling --- antimicrobial --- antiviral --- electrospinning --- breast implant --- ear prosthesis --- biomedical device --- chronic wound --- biopolymer --- bio-based --- surface modification --- nanolignin --- electrospray --- anti-inflammatory --- blends --- PLA --- PHBV --- nanocomposite --- tissue engineering --- biodegradable --- nanofiber