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Since their development a decade ago, human induced pluripotent stem cells (iPSC) have revolutionized the study of human disease, given rise to regenerative medicine technologies, and provided exceptional opportunities for pharmacologic research. These cells provide an essentially unlimited supply of cell types that are difficult to obtain from patients, such as neurons or cardiomyocytes, or are difficult to maintain in primary cell culture. iPSC can be obtained from patients afflicted with a particular disease but, in combination with recently developed gene editing techniques, can also be modified to generate disease models. Moreover, the new techniques of 3 Dimensional printing and materials science facilitate the generation of organoids that can mirror organs under disease conditions. These properties make iPSC powerful tools to study how diseases develop and how they may be treated. In addition, iPSC can also be used to treat conditions in which the target cell population has been lost and such regenerative approaches hold great promise for currently untreatable diseases, including cardiac failure or photoreceptor degenerations.
Phenotyping of Human iPSC-derived Neurons: Patient-Driven Research examines the steps in a preclinical pipeline that utilizes iPSC-derived neuronal technology to better understand neurological disorders and identify novel therapeutics, also providing considerations and best practices. By presenting example projects that identify phenotypes and mechanisms relevant to autism spectrum disorder and epilepsy, this book allows readers to understand what considerations are important to assess at the start of project design. Sections address reproducibility issues and advances in technology at each stage of the pipeline and provide suggestions for improvement. From patient sample collection and proper controls to neuronal differentiation, phenotyping, screening, and considerations for moving to the clinic, these detailed descriptions of each stage of the pipeline will help everyone, regardless of stage in the pipeline. In recent years, drug discovery in the neurosciences has struggled to identify novel therapeutics for patients with varying indications, including epilepsy, chronic pain, and psychosis. Current treatment options for such patients are decades old and offer little relief with many side effects. One explanation for this lull in novel therapeutics is a lack of novel target identification for neurological disorders (and target identification requires exemplar preclinical data). To improve on the preclinical work that often relies on rodent modeling, the field has begun utilizing patient-derived induced pluripotent stem cells (iPSCs) to differentiate neurons in vitro for preclinical characterization of neurological disease and target identification. Discusses techniques and new technology for iPSC culturing and neuronal differentiation to establish best practices in the lab Outlines considerations for phenotypic assay development Provides information about the successes, failures, and implications of phenotyping and screening with iPSC-derived neurons Describes how human iPSC-derived neurons are being used for preclinical discovery research as well as the development of therapeutics utilizing hiPSC-derived neurons
"[A]ddresses how induced pluripotent stems cells can be differentiated into distinct progenitors. Progenitors are often the first step to making more differentiating cell types. This volume addresses a variety of iPSC-derived progenitors, such as neural stem cells, craniofacial mesenchymal progenitors, astrocyte progenitors, mesothelial progenitors, keratinocyte progenitors, bone progenitors, chondrocyte progenitors, dental pulp stem cells, nephron progenitors, mesenchymal stem cells, hematopoietic stem cells, and cancer stem cells. The volume is written for researchers and scientists in stem cell therapy, cellular and molecular biology, and regenerative medicine and is contributed by world-renowned authors in the field"--Page 4 of cover.
The series Advances in Stem Cell Biology is a timely and expansive collection of comprehensive information and new discoveries in the field of stem cell biology. iPSCs - Novel Concepts, Volume 15 addresses how important induced pluripotent stems cells are and how can they can help treat certain diseases. Somatic cells can be reprogrammed into induced pluripotent stem cells by the expression of specific transcription factors. These cells have been transforming biomedical research over the last 15 years. This volume will address the advances in research of how induced pluripotent stem cells are being used for treatment of different disorders, such as liver disease, type-1 diabetes, Parkinson's disease, macular degeneration of the retina and much more. The volume is written for researchers and scientists in stem cell therapy, cell biology, regenerative medicine and organ transplantation; and is contributed by world-renowned authors in the field. - Provides overview of the fast-moving field of stem cell biology and function, regenerative medicine and therapeutics - Covers spinal cord injuries, type-1 diabetes, liver disease, Parkinson's disease, graft vs. host disease, and much more - Contributed by world-renown experts in the field
Drug Discovery Approaches for the Treatment of Neurodegenerative Disorders: Alzheimer's Disease examines the drug discovery process for neurodegenerative diseases by focusing specifically on Alzheimer's Disease and illustrating the paradigm necessary to ensure future research and treatment success. The book explores diagnosis, epidemiology, drug discovery strategies, current therapeutics, and much more to provide a holistic approach to the discovery, development, and treatment of Alzheimer's Disease. Through its coverage of the latest research in targeted drug design, preclinical studies, and mouse and rat models, the book is a must-have resource for all pharmaceutical scientists, pharmacologists, neuroscientists, and clinical researchers working in this area. It illustrates why these drugs tend to fail at the clinical stage, and examines Alzheimer's Disease within the overall context of improving the drug discovery process for the treatment of other neurodegenerative disorders. - Provides a compilation of chemical considerations required in drug discovery for the treatment of neurodegenerative disorders - Examines different classes of compounds currently being used in discovery and development stages - Explores in vitro and in vivo models with respect to their ability to translate these models to human conditions - Distills the most significant information across multiple areas of Alzheimer's disease research to provide a single, comprehensive, and balanced resource
Pluripotent stem cells have distinct characteristics: self-renewal and the potential to differentiate into various somatic cells. In recent years, substantial advances have been made from basic science to clinical applications. The vast amount knowledge available makes obtaining concise yet sufficient information difficult, hence the purpose of this book. In this book, embryonic stem cells, induced pluripotent stem cells, and mesenchymal stem cells are discussed. The book is divided into five sections: pluripotency, culture methods, toxicology, disease models, and regenerative medicine. The topics covered range from new concepts to current technologies. Readers are expected to gain useful information from expert contributors.
This open access book focuses on the molecular mechanism of congenital heart disease and pulmonary hypertension, offering new insights into the development of pulmonary circulation and the ductus arteriosus. It describes in detail the molecular mechanisms involved in the development and morphogenesis of the heart, lungs and ductus arteriosus, covering a range of topics such as gene functions, growth factors, transcription factors and cellular interactions, as well as stem cell engineering technologies. The book also presents recent advances in our understanding of the molecular mechanism of lung development, pulmonary hypertension and molecular regulation of the ductus arteriosus. As such, it is an ideal resource for physicians, scientists and investigators interested in the latest findings on the origins of congenital heart disease and potential future therapies involving pulmonary circulation/hypertension and the ductus arteriosus.
Improving and Accelerating Therapeutic Development for Nervous System Disorders is the summary of a workshop convened by the IOM Forum on Neuroscience and Nervous System Disorders to examine opportunities to accelerate early phases of drug development for nervous system drug discovery. Workshop participants discussed challenges in neuroscience research for enabling faster entry of potential treatments into first-in-human trials, explored how new and emerging tools and technologies may improve the efficiency of research, and considered mechanisms to facilitate a more effective and efficient development pipeline. There are several challenges to the current drug development pipeline for nervous system disorders. The fundamental etiology and pathophysiology of many nervous system disorders are unknown and the brain is inaccessible to study, making it difficult to develop accurate models. Patient heterogeneity is high, disease pathology can occur years to decades before becoming clinically apparent, and diagnostic and treatment biomarkers are lacking. In addition, the lack of validated targets, limitations related to the predictive validity of animal models - the extent to which the model predicts clinical efficacy - and regulatory barriers can also impede translation and drug development for nervous system disorders. Improving and Accelerating Therapeutic Development for Nervous System Disorders identifies avenues for moving directly from cellular models to human trials, minimizing the need for animal models to test efficacy, and discusses the potential benefits and risks of such an approach. This report is a timely discussion of opportunities to improve early drug development with a focus toward preclinical trials.
Tissue Engineering: Current Status and Challenges bridges the gap between biomedical scientists and clinical practitioners. The work reviews the history of tissue engineering, covers the basics required for the beginner, and inspires those in the field toward future research and application emerging in this fast-moving field. Written by global experts in the field for those studying and researching tissue engineering, the book reviews regenerative technologies, stem cell research and regeneration of organs. It then moves to soft tissue engineering (heart, vascular, muscle and 3D scaffolding and printing), hard tissue engineering (bone, dental myocardial and musculoskeletal) and translational avenues in the field. - Introduces readers to the history and benefits of tissue engineering - Includes coverage of new techniques and technologies, such as nanotechnology and nanoengineering - Presents concepts, ideology and theories which form the foundation for next-generation tissue engineering
Mitochondrial Disorders in Neurology provides an overview of mitochondrial diseases. This book discusses the effects of mitochondrial dysfunction based on the relevant biochemistry and molecular genetics. The abnormal muscle and mitochondrial morphology in a variety of clinical presentations from isolated ophthalmoplegia to severe encephalopathy are also elaborated. This text likewise deliberates Leber's hereditary optic neuropathy, neurodegenerative disorders, and respiratory chain defects. Other topics covered include mitochondrial DNA and the genetics of mitochondrial disease; cytochrome ox ...