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18th Asian BioCeramic (ABC) Selected, peer reviewed papers from the 18th Asian BioCeramic (ABC) Symposium, 19-20 September 2018, Bandung, Indonesia
This book is a compilation of the contributions by the outstanding scientists who attended the 1st Asian Biomaterials Congress. The 1st Asian Biomaterials Congress is the first integrated meeting on Asian biomaterials and was held in Tsukuba from 6 OCo 8 December 2007. The book showcases the latest and research developments in biomaterials and tissue engineering in Asia. It provides an overview of the recent advances of metallic, ceramic and polymeric materials, their composites, biomechanics, and bio-nanotechnology. It also includes the applications of biomaterials, including implantable medical devices, tissue engineering and drug delivery systems.
This book is a compilation of the contributions by the outstanding scientists who attended the 1st Asian Biomaterials Congress. The 1st Asian Biomaterials Congress is the first integrated meeting on Asian biomaterials and was held in Tsukuba from 6 - 8 December 2007. The book showcases the latest and research developments in biomaterials and tissue engineering in Asia. It provides an overview of the recent advances of metallic, ceramic and polymeric materials, their composites, biomechanics, and bio-nanotechnology. It also includes the applications of biomaterials, including implantable medical devices, tissue engineering and drug delivery systems.
Biologically functional ceramic materials have been known about for several decades, like phosphate cements and gypsum, and they are within the zeroth generation. Modern and artificially synthesized bioceramics include amorphous materials in the Bioglass® family that were developed in the early 1970's and derivative glass ceramics such as Bioverit® and Cerabone A-W® that came in 1980's. They are from the 2nd generation of materials, and mostly applicable to bone replacement or bone defect fillers. Since the late 1990's, newer technologies have been introduced to the biologically functional material fields; they are the syntheses of organic-inorganic hybrids of micro- and macroscopic scales as well as nano-scales, organic fragment-covered ceramic particles of varied sizes, with light-controlling abilities to modify the frequency of light, in addition synthesis of high strength and high-tribological durability that had not been available before. With the advent of additive manufacturing technology employing lasers, electron beams, and printers, clinical materials of complicated porous structures are now easily prepared. These materials are of the 3rd generation. This book will cover almost all kinds of such 3rd generation ceramic and ceramic-related biomaterials. This book conveys the current state-of-the-art on the science and technology of bioceramics, from nano-size dots or particles to macro-scale architectures, of a wide range of constitutions including quantum dots with peptide fragments, meso-scale therapeutic particles designed to involve drugs or genes, mesoporous organic-inorganic hybrids, nano-structured oxide layers on metals and alloys. - Comprehensively covers all aspects (research/experimental and commercial products) related to the latest progresses in bioceramic science, technology and applications, with emphasis on nanobioceramics - Pulls together a broad range of materials, concepts, and technologies based on nanomaterials - Features novel preparation procedures like additive manufacturing (3-D printing and related techniques) that have also been introduced and practiced for forming complicated architectures - Features innovative 3rd generation ceramic and ceramic-related biomaterials
Aggregated Book
Bioceramics is a collection of papers that deals in bioactive ceramics, glasses, and composites, focusing on the optimization of the implant-tissue interface. One paper discusses the osteogenic response of rat bone marrow cells in porous alumina, in hydroxyapatite, and in Kiel bone. Marrow cells loaded alumina and HA ceramics show new bone formation; Kiel bone use does not point to any consistent osteogenesis. Another paper presents the potential of an injectable form of Bioglass to treat urinary incontinence. When injected, it remains at the injection site by bonding to soft tissues without degrading, migrating, or producing an inflammatory reaction. Another paper presents an in vitro method that has shown osteoclast-like cells can resorb artificial calcium phosphate substrata in vitro. The differences in bone bonding mechanisms between surface active ceramics and resorbable ceramics show some chemical bonding and direct contact with the bone. The book also presents some clinical uses of bioactive ceramics such as the successful artificial root therapeutics involving 219 artificial roots implanted in 63 patients. This book can prove valuable to bio-chemists, cellular biologists, micro-biologists, developmental biologists, and scientists involved in biomaterials research.
This proceedings book of the Biolox Symposium in Seoul is composed of 10 sessions and plenary lectures of the most current knowledge available in the use of Bioceramics and alternative bearings. More than 50 speakers with world-famous reputations from 12 countries cover 52 topics on recent developments in Bioceramic and alternative bearings in arthroplasty.
This book introduces readers to the structure and characteristics of nanomaterials and their applications in dentistry. With currently available implant materials, the clinical failure rate varies from a few percent to over 10 percent and new materials are clearly needed. Nanomaterials offer the promise of higher strength, better bonding, less toxicity, and enhanced cytocompatibility, leading to increased tissue regeneration. Mieczyslaw Jurczyk, director of the Institute of Materials Science and Engineering at the Poznan University of Technology in Poland, has drawn from work in his laboratory and elsewhere in Poland to show that nanomaterials have important biological applications including in the stomatognathic system consisting of mouth, jaws, and associated structures. The book is written from a materials science and medical point of view and has 13 chapters and about 400 pages. The book can be divided approximately into three sections: the first five chapters introduce nanobiomaterials, the next five chapters describe their dental applications, and the last chapters describe their biocompatibility. Chapter 3 is a compendium on metallic biomaterials such as stainless steel, cobalt alloys, and titanium alloys; bioactive, bioresorbable polymers; and composites and ceramic biomaterials. The "top-down" approach to producing nanomaterials such as high-energy ballmilling and severe plastic deformation, as well as Feynman’s "bottom-up technique" of building atom by atom, are discussed in the next chapter. Subsequent chapters discuss each material in depth and point out how new architectures and properties emerge at the nanoscale. Chapter 8 is devoted to shape-memory materials, which now include not only NiTi but also polymers and magnetic materials. In order to improve bonding, nanomaterials can be used to synthesize implants with surface roughness similar to that of natural tissues. Chapter 9 is devoted to different surface treatments for Ti-based nanomaterials, such as anodic oxidation to improve the bioactivity of titanium and improve the corrosion resistance of porous titanium and its alloys. The use of carbon in various forms—nanoparticles, nanofibers, nanotubes, and thin films—is discussed next with emphasis on the microstructure and properties of these materials, their implant applications, and their interaction with subcutaneous tissues. Nanomaterials can be used in preventive dentistry and therefore can reduce the amount of dental treatment that is necessary to maintain a healthy mouth as argued in chapter 11. In a subsequent chapter, the author explains osseointegration (direct bone-to-metal interface) from a biological point of view and early tissue response. The mechanism of the interaction between the implanted materials with the cellular protein in the tissues is described. The last chapter discusses the application of new nanostructured materials in permanent and bioresorbable implants, nanosurface dental implants, and nanostructured dental composite restorative materials. This book not only focuses on nanomaterials but also on nanoengineering to achieve the best results in dentistry. It is recommended to anyone interested in nanomaterials and their applications in dental science. People with a background in materials, chemistry, physics, and biology will benefit from it.
Bioceramics: For Materials Science and Engineering provides a great working knowledge on the field of biomaterials, including the interaction of biomaterials with their biological surroundings. The book discussees the biomedical applications of materials, the standpoint of biomedical professionals, and a real-world assessment of the academic research in the field. It addresses the types of bioceramics currently available, their structure and fundamental properties, and their most important applications. Users will find this to be the only book to cover all these aspects. - Acts as the only introductory reference on bioceramics that covers both the theoretical basics and advanced applications - Includes an overview of the key applications of bioceramics in orthopedics, dentistry and tissue engineering - Uses case studies to build understanding and enable innovation