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Electroplating --- Electrophoretic deposition --- Patents --- Patents
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Electrophoresis is defined as the transport of electrically charged particles in a direct current electric field. Electrophoretic separation is based on differential rates of migration in the bulk of the liquid phase and is not concerned with reactions occurring at the electrodes. In the early days, electrophoresis was carried out either in free solution or in the supporting media such as paper, cellulose acetate, starch, agarose, and polyacry lamide gel. In between 1950 to 1970, an enumeration of techniques and instrumentation for Electrophoresis were developed. The present book contains few fundamentals on capillary electrophoresis and diverse application of electrophoresis in general. We hope this collection will entertain the readers who are interested in fundamental as well as applications of electrophoresis in general.
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Electrophoretic deposition. --- Coating, Electrophoretic --- Deposition, Electrophoretic --- Electrophoretic coating --- Electrophoresis --- Painting, Industrial
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The contributions to this special collection cover a wide range of subject areas related to EPD and reflect the impressive versatility of that technique for materials processing. The topics discussed range from theoretical studies of the fundamental mechanisms of EPD, to novel techniques which exploit EPD for the efficient and cost-effective fabrication of a variety of advanced materials.
Electrophoretic deposition -- Congresses. --- Electrophoretic deposition. --- Electrophoretic deposition --- Art, Architecture & Applied Arts --- Arts & Crafts --- Coating, Electrophoretic --- Deposition, Electrophoretic --- Electrophoretic coating --- Electrophoresis --- Painting, Industrial --- Biomedical materials. --- Bones --- Tissue engineering. --- Tissue scaffolds. --- Tissues --- Tissue biomechanics --- Tissue mechanics --- Biomechanics --- Scaffolding, Tissue --- Scaffolds, Tissue --- Tissue scaffolding --- Guided tissue regeneration --- Tissue engineering --- Biomedical engineering --- Regenerative medicine --- Tissue culture --- Bone biomechanics --- Bone mechanics --- Mechanical properties of bones --- Bioartificial materials --- Biocompatible materials --- Biomaterials --- Hemocompatible materials --- Medical materials --- Medicine --- Materials --- Biocompatibility --- Prosthesis --- Mechanical properties. --- Equipment and supplies --- Nanoelectronics --- Nanostructured materials --- Metal oxide semiconductors --- Unipolar transistors --- Semiconductors --- Transistors --- Charge coupled devices --- Nanoscale electronics --- Nanoscale molecular electronics --- Electronics --- Nanotechnology --- Biomaterials (Biomedical materials)
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Acceptance or rejection of implanted biomaterials is strongly dependent on an appropriate bio-interface between the biomaterial and its surrounding tissue. Given the fact that most bulk materials only provide mechanical stability for the implant and may not interact with tissues and fluids in vivo, surface modification and engineering of biomaterials plays a significant role towards addressing major clinical unmet challenges. Increasing data showed that altering surface properties including physiochemical, topographical, and mechanical characteristics, is a promising approach to tackle these problems. Surface engineering of biomaterials could influence the subsequent tissue and cellular events such as protein adsorption, cellular recolonization, adhesion, proliferation, migration, and the inflammatory response. Moreover, it could be based on mimicking the complex cell structure and environment or hierarchical nature of the bone. In this case, the design of nano/micrometer patterns and morphologies with control over their properties has been receiving the attention of biomaterial scientists due to the promising results for the relevant biomedical applications. This Special Issue presents original research papers that report on the current state-of-the-art in surface engineering of biomaterials, particularly implants and biomedical devices.
Research & information: general --- surface modification --- micro-powder blasting --- aluminum anodization --- micro/nano-structure --- cell culture --- electrophoretic deposition --- enamel remineralization --- bioactive glass --- spectrophotometry --- nanoindentation --- rhBMP-2 --- rhPDGF-BB --- heparin --- implant surface --- osseointegration --- bone regeneration --- beagle dog --- diamond-like carbon --- frictional property --- hydrogen content --- sp2/sp3 ratio --- hydroxyapatite --- titanium implants --- mineralizing solution --- solution plasma treatment --- surface modification --- micro-powder blasting --- aluminum anodization --- micro/nano-structure --- cell culture --- electrophoretic deposition --- enamel remineralization --- bioactive glass --- spectrophotometry --- nanoindentation --- rhBMP-2 --- rhPDGF-BB --- heparin --- implant surface --- osseointegration --- bone regeneration --- beagle dog --- diamond-like carbon --- frictional property --- hydrogen content --- sp2/sp3 ratio --- hydroxyapatite --- titanium implants --- mineralizing solution --- solution plasma treatment
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Acceptance or rejection of implanted biomaterials is strongly dependent on an appropriate bio-interface between the biomaterial and its surrounding tissue. Given the fact that most bulk materials only provide mechanical stability for the implant and may not interact with tissues and fluids in vivo, surface modification and engineering of biomaterials plays a significant role towards addressing major clinical unmet challenges. Increasing data showed that altering surface properties including physiochemical, topographical, and mechanical characteristics, is a promising approach to tackle these problems. Surface engineering of biomaterials could influence the subsequent tissue and cellular events such as protein adsorption, cellular recolonization, adhesion, proliferation, migration, and the inflammatory response. Moreover, it could be based on mimicking the complex cell structure and environment or hierarchical nature of the bone. In this case, the design of nano/micrometer patterns and morphologies with control over their properties has been receiving the attention of biomaterial scientists due to the promising results for the relevant biomedical applications. This Special Issue presents original research papers that report on the current state-of-the-art in surface engineering of biomaterials, particularly implants and biomedical devices.
Research & information: general --- surface modification --- micro-powder blasting --- aluminum anodization --- micro/nano-structure --- cell culture --- electrophoretic deposition --- enamel remineralization --- bioactive glass --- spectrophotometry --- nanoindentation --- rhBMP-2 --- rhPDGF-BB --- heparin --- implant surface --- osseointegration --- bone regeneration --- beagle dog --- diamond-like carbon --- frictional property --- hydrogen content --- sp2/sp3 ratio --- hydroxyapatite --- titanium implants --- mineralizing solution --- solution plasma treatment
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Acceptance or rejection of implanted biomaterials is strongly dependent on an appropriate bio-interface between the biomaterial and its surrounding tissue. Given the fact that most bulk materials only provide mechanical stability for the implant and may not interact with tissues and fluids in vivo, surface modification and engineering of biomaterials plays a significant role towards addressing major clinical unmet challenges. Increasing data showed that altering surface properties including physiochemical, topographical, and mechanical characteristics, is a promising approach to tackle these problems. Surface engineering of biomaterials could influence the subsequent tissue and cellular events such as protein adsorption, cellular recolonization, adhesion, proliferation, migration, and the inflammatory response. Moreover, it could be based on mimicking the complex cell structure and environment or hierarchical nature of the bone. In this case, the design of nano/micrometer patterns and morphologies with control over their properties has been receiving the attention of biomaterial scientists due to the promising results for the relevant biomedical applications. This Special Issue presents original research papers that report on the current state-of-the-art in surface engineering of biomaterials, particularly implants and biomedical devices.
surface modification --- micro-powder blasting --- aluminum anodization --- micro/nano-structure --- cell culture --- electrophoretic deposition --- enamel remineralization --- bioactive glass --- spectrophotometry --- nanoindentation --- rhBMP-2 --- rhPDGF-BB --- heparin --- implant surface --- osseointegration --- bone regeneration --- beagle dog --- diamond-like carbon --- frictional property --- hydrogen content --- sp2/sp3 ratio --- hydroxyapatite --- titanium implants --- mineralizing solution --- solution plasma treatment
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This book provides a comprehensive overview of contemporary basic research, emerging technology, and commercial and industrial applications associated with the electrophoretic deposition of nanomaterials. This presentation of the subject involves a historical survey, as well as discussions of the underlying theory of electrophoresis, dielectrophoresis, and the colloidal deposition of microscale and nanoscale materials. This includes an assessment of the experimental equipment and procedures for electrophoretic aggregation, manipulation, and deposition of nanoparticles, nanotubes, and other nanomaterials. Additional chapters explore the specific science and technology of electrophoretic film formation, using widely studied and application-driven nanomaterials, such as carbon nanotubes, luminescent nanocrystals, and nanoscale ceramics. The concluding chapters explore industrial applications and procedures associated with the electrophoretic deposition of nanomaterials.
Electrophoretic deposition. --- Nanostructured materials. --- Nanotechnology. --- Nanotechnology --- Electrophoretic deposition --- Nanostructured materials --- Biology --- Engineering & Applied Sciences --- Health & Biological Sciences --- Biology - General --- Technology - General --- Nanomaterials --- Nanometer materials --- Nanophase materials --- Nanostructure controlled materials --- Nanostructure materials --- Ultra-fine microstructure materials --- Life sciences. --- Chemical engineering. --- Electrophoresis. --- Continuum physics. --- Condensed matter. --- Materials science. --- Life Sciences. --- Industrial Chemistry/Chemical Engineering. --- Materials Science, general. --- Classical Continuum Physics. --- Condensed Matter Physics. --- Molecular technology --- Nanoscale technology --- High technology --- Material science --- Physical sciences --- Condensed materials --- Condensed media --- Condensed phase --- Materials, Condensed --- Media, Condensed --- Phase, Condensed --- Liquids --- Matter --- Solids --- Classical field theory --- Continuum physics --- Physics --- Continuum mechanics --- Cataphoresis --- Electrochemistry --- Phase partition --- Chemistry, Industrial --- Engineering, Chemical --- Industrial chemistry --- Engineering --- Chemistry, Technical --- Metallurgy --- Biosciences --- Sciences, Life --- Science --- Microstructure --- Materials. --- Classical and Continuum Physics. --- Engineering materials --- Industrial materials --- Engineering design --- Manufacturing processes --- Materials
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