This book marries stem cell biology, tissue engineering, and regenerative biology into a single, interdisciplinary volume. The chapters also explore embryonic stem cells, induced pluripotent stem cells, cardiovascular regeneration, skeletal development, inflammation, polymeric biomaterials, neural injury, cartilage regeneration, regeneration in ambystoma, models for regeneration using salamander and zebrafish, and more. The volume also discusses recent advances and their potential in developing future therapies. Innovations in Molecular Mechanisms and Tissue Engineering combines perspectives from the biomedical, bioengineering, and medical fields to present a cutting-edge, multifaceted picture of the tissue engineering and regenerative medicine fields. This installment of Springer's Stem Cell Biology and Regenerative Medicine series is ideal for scientists, clinicians, and researchers in the fields of stem cell biology, regenerative medicine, biomedical engineering, and tissue engineering.

Our understanding of the genetic and developmental mechanisms underlying scoliosis is rapidly evolving, this timely second edition of The Genetics and Development of Scoliosis is to provide researchers, clinicians, and students with the most current views in this field. This volume brings together leaders in understanding congenital and idiopathic scoliosis to present the current state of research, and to compare the genetic etiology of these conditions, in order to identify potential shared developmental mechanisms. This book will summarize the recent advances in studies of spinal development and how disruptions during embryogenesis in embryonic segmentation can lead to congenital vertebral defects. In addition, recent reports of genetic loci predisposing patients to develop juvenile and adolescent idiopathic scoliosis will be presented, and key clinical features are reviewed. Finally, there will be discussion of how genetic heterogeneity and gene-environment interactions may contribute to congenital scoliosis and isolated vertebral malformations.

Developmental genetic studies of the spine and linkage and family-based association studies have led to recent advances in understanding the genetic etiology of idiopathic, neuromuscular, and congenital forms of scoliosis. The book is written by leaders in genetic and developmental research on scoliosis and developmental studies of the spine.

Our understanding of the genetic and developmental mechanisms underlying scoliosis is rapidly evolving, this timely second edition of The Genetics and Development of Scoliosis is to provide researchers, clinicians, and students with the most current views in this field. This volume brings together leaders in understanding congenital and idiopathic scoliosis to present the current state of research, and to compare the genetic etiology of these conditions, in order to identify potential shared developmental mechanisms. This book will summarize the recent advances in studies of spinal development and how disruptions during embryogenesis in embryonic segmentation can lead to congenital vertebral defects. In addition, recent reports of genetic loci predisposing patients to develop juvenile and adolescent idiopathic scoliosis will be presented, and key clinical features are reviewed. Finally, there will be discussion of how genetic heterogeneity and gene-environment interactions may contribute to congenital scoliosis and isolated vertebral malformations.

This book marries stem cell biology, tissue engineering, and regenerative biology into a single, interdisciplinary volume. The chapters also explore embryonic stem cells, induced pluripotent stem cells, cardiovascular regeneration, skeletal development, inflammation, polymeric biomaterials, neural injury, cartilage regeneration, regeneration in ambystoma, models for regeneration using salamander and zebrafish, and more. The volume also discusses recent advances and their potential in developing future therapies. Innovations in Molecular Mechanisms and Tissue Engineering combines perspectives from the biomedical, bioengineering, and medical fields to present a cutting-edge, multifaceted picture of the tissue engineering and regenerative medicine fields. This installment of Springer's Stem Cell Biology and Regenerative Medicine series is ideal for scientists, clinicians, and researchers in the fields of stem cell biology, regenerative medicine, biomedical engineering, and tissue engineering.