The Geometric Induction of Bone Formation describes new biomimetic biomaterials that offer mechanistic osteogenic surfaces for the autonomous and spontaneous induction of bone formation without the addition of osteogenic soluble molecular signals of the transforming growth factor- supergene family. The chapters frame our understanding of regenerative medicine in primate species, including humans. The goal is to unravel the fundamental biological mechanisms of bone formation unique to non-human and human primates. The broad target audience dovetails with several disciplines both in the academic and private biotech sectors primarily involved in molecular biology, tissue biology, tissue engineering, biomaterial science, and reconstructive, orthopedic, plastic, and dental surgery. Key Features Includes outstanding images of undecalcified whole mounted sections Summarizes non-human primate research - ideal for clinical translation Reviews methods for creating devices capable of making bone autonomously, i.e. an intrinsically osteo-inductive bioreactor and/or biomaterial Describes the spontaneous induction of bone formation including a whole spectrum of tissue biology, from basic molecular biology to clear-cut morphology and pre-clinical application in non-human primate species Intended for audiences in both academic research and the biotech industry

The Geometric Induction of Bone Formation describes new biomimetic biomaterials that offer mechanistic osteogenic surfaces for the autonomous and spontaneous induction of bone formation without the addition of osteogenic soluble molecular signals of the transforming growth factor- supergene family. The chapters frame our understanding of regenerative medicine in primate species, including humans. The goal is to unravel the fundamental biological mechanisms of bone formation unique to non-human and human primates. The broad target audience dovetails with several disciplines both in the academic and private biotech sectors primarily involved in molecular biology, tissue biology, tissue engineering, biomaterial science, and reconstructive, orthopedic, plastic, and dental surgery. Key Features Includes outstanding images of undecalcified whole mounted sections Summarizes non-human primate research - ideal for clinical translation Reviews methods for creating devices capable of making bone autonomously, i.e. an intrinsically osteo-inductive bioreactor and/or biomaterial Describes the spontaneous induction of bone formation including a whole spectrum of tissue biology, from basic molecular biology to clear-cut morphology and pre-clinical application in non-human primate species Intended for audiences in both academic research and the biotech industry

Through the integration of strategies from life science, engineering, and clinical medicine, tissue engineering and regenerative medicine hold the promise of new solutions to current health challenges. This rapidly developing field requires continual updates to the state-of-the-art knowledge in all of the aforementioned sciences. Tissue Engineering and Regenerative Medicine: A Nano Approach provides a compilation of the important aspects of tissue engineering and regenerative medicine, including dentistry, from fundamental principles to current advances and future trends. Written by internationally renowned scientists, engineers, and clinicians, the chapters cover the following areas: Nanobiomaterials and scaffolds-including nanocomposites and electrospun nanofibers Tissue mechanics Stem cells and nanobiomaterials Oral and cranial implants and regeneration of bone Cartilage tissue engineering Controlled release-DNA, RNA, and protein delivery Animal science and clinical medicine The editors designed this textbook with a distinctive theme focusing on the utilization of nanotechnology, biomaterials science in tissue engineering, and regenerative medicine with the inclusion of important clinical aspects. In addition to injured veterans and other individuals, increased life expectancy in the industrialized world is creating a growing population that will require regenerative medicine, producing greater pressure to develop procedures and treatments to improve quality of life. This book bridges the gap between nanotechnology and tissue engineering and regenerative medicine, facilitating the merger of these two fields and the important transition from laboratory discoveries to clinical applications.

The effects of the bone morphogenetic proteins (BMPs) family on bone formation are well documented, but the transforming growth factor (TGF)-beta ( ) isoforms are much less studied. The product of 20 years of study, Induction of Bone Formation in Primates: The Transforming Growth Factor- 3 sums up editor Ugo Ripamonti's research into the osteogenic activity of the three mammalian TGF- isoforms, particularly in primates. It explores how the mammalian TGF- isoforms have the potential to shed light on the apparent redundancy of bone induction signaling. The book unearths the profound and important bone inductive activity of the TGF- 3 isoform. It includes accounts of extensive research in non-human primates from craniofacial tissue regeneration, heterotopic tissue induction, and chapters on periodontal tissue regeneration and synergistic induction of bone formation. It also discusses the future clinical role of the TGF- isoform, including in human studies. This book contributes to the fascinating history of BMP and TGF- research at the intersection of molecular biology, tissue induction, bone regeneration, and craniofacial surgery. It provides a revolutionary awakening to new possibilities in skeletal reconstruction, tissue engineering, and molecular and cellular biology.

The effects of the bone morphogenetic proteins (BMPs) family on bone formation are well documented, but the transforming growth factor (TGF)-beta ( ) isoforms are much less studied. The product of 20 years of study, Induction of Bone Formation in Primates: The Transforming Growth Factor- 3 sums up editor Ugo Ripamonti's research into the osteogenic activity of the three mammalian TGF- isoforms, particularly in primates. It explores how the mammalian TGF- isoforms have the potential to shed light on the apparent redundancy of bone induction signaling. The book unearths the profound and important bone inductive activity of the TGF- 3 isoform. It includes accounts of extensive research in non-human primates from craniofacial tissue regeneration, heterotopic tissue induction, and chapters on periodontal tissue regeneration and synergistic induction of bone formation. It also discusses the future clinical role of the TGF- isoform, including in human studies. This book contributes to the fascinating history of BMP and TGF- research at the intersection of molecular biology, tissue induction, bone regeneration, and craniofacial surgery. It provides a revolutionary awakening to new possibilities in skeletal reconstruction, tissue engineering, and molecular and cellular biology.