Gene therapy has tremendous potential for the treatment of neurological disorders. There has been substantial progress in the development of gene therapy strategies for neurological disorders over the last two decades. Gene Therapy in Neurological Disorders thoroughly reviews currently available gene therapy tools and presents examples of their application in a variety of neurological diseases. The book begins with general reviews of gene therapy strategies with a focus on neurological disorders. The remainder of the chapters present approaches to specific neurological disorders. Each chapter gives an in-depth introduction to the relevant field before diving into the specific tool or application. The book aims to help investigators, students and research staff better understand the principles of gene therapy and its application in the nervous system. - Provides background information and experimental details of gene therapy tools applied for neuroscience research and neurological disorders - Covers a broad range of gene delivery and regulation tools, therapeutic agents, and target cells, including emerging new technologies such as CRISPR/Cas9 genome editing - Discusses applications of gene therapy tools to neurological disorders including neurodegeneration, muscular dystrophy, trauma and chronic pain, and neoplastic diseases

Cell and Gene Therapies for Neurologic Diseases, Volume 205 comprehensively covers the scientific background, translational efforts, clinical developments and registered biologics that have entered into clinical practice. Coverage includes types of therapies available and in development, and best practice uses for a variety of neurological disorders including Parkinson's, Huntington's, ALS, stroke, spinal cord RP, demyelination, and epilepsy. As the emergence of gene and cellular therapeutics has changed the clinical landscape for a variety of disorders, and is now ready to do so for neurological diseases, these therapeutic modalities currently complement, and may in time, supplant small molecule drugs. - Summarizes advances in cell and gene therapy for neurological diseases - Describes the therapies available and in development - Includes surgical, ethical, and manufacturing considerations - Identifies best practices for specific neurological diseases - Covers Huntington's, Parkinson's, ALS, Stroke, Demyelination, epilepsy, and more

STEM CELL BIOLOGY AND GENE THERAPY Edited by Peter J. Quesenberry, Gary S. Stein, Bernard Forget, and Sherman Weissman Advances in molecular genetics and recombinant DNA technology have ushered in a new era in medical therapeutic research. New insights into the molecular basis of human disease and the role played by biological regulatory mechanisms have precipitated tremendous drug development efforts backed by intensive research into human gene therapy worldwide. Stem Cell Biology and Gene Therapy is the first book to thoroughly cover major advances in the field and their applications to novel molecular therapies. This self-contained volume integrates biological and clinical components of stem cell biology, examines some of the most difficult aspects of gene therapy, and provides a systematic review of advanced gene modification techniques. Twenty essays by leading researchers address some of the most compelling topics in contemporary medical research, including: * Fundamental regulatory mechanisms that operate in stem cells * Stem cells from a therapeutic perspective, including preparations of stem cells and their therapeutic potential as vehicles for gene therapy * Delivery systems for therapeutic genes, including an overview of the most promising vectors * Clinical applications for gene therapy, covering a broad range of diseases such as hemophilia, cancers, neurological disease, and more Complete with illustrations and real-world examples of a variety of disorders, Stem Cell Biology and Gene Therapy is essential for researchers in gene therapy and members of the biotechnology industry who are developing human molecular therapies for commercial use. It is also an important reference for molecular biologists, cell biologists, immunologists, molecular geneticists, hematologists, cancer researchers, biochemists, and anyone working in internal medicine.

Jasper's Basic Mechanisms, Fourth Edition, is the newest most ambitious and now clinically relevant publishing project to build on the four-decade legacy of the Jasper's series. In keeping with the original goal of searching for "a better understanding of the epilepsies and rational methods of prevention and treatment.", the book represents an encyclopedic compendium neurobiological mechanisms of seizures, epileptogenesis, epilepsy genetics and comordid conditions. Of practical importance to the clinician, and new to this edition are disease mechanisms of genetic epilepsies and therapeutic approaches, ranging from novel antiepileptic drug targets to cell and gene therapies.

Translational Neuroscience offers a far-reaching and insightful series of perspectives on the effort to bring potentially revolutionary new classes of therapies to the clinic, thereby transforming the treatment of human nervous system disorders. Great advances in the fields of basic neuroscience, molecular biology, genomics, gene therapy, cell therapy, stem cell biology, information technology, neuro devices, rehabilitation and others over the last 20 years have generated unprecedented opportunities to treat heretofore untreatable disorders of the nervous system. This book provides a wide-ranging yet detailed sample of many of these efforts, together with the methods for pursuing clinical translation and assessing clinical outcomes. Among the topics covered are Alzheimer’s disease, Parkinson’s disease, stroke, multiple sclerosis, epilepsy, motor neuron disease, pain, inborn errors of metabolism, brain tumors, spinal cord injury, neuroprosthetics, rehabilitation and clinical trial design/consideration. Translational Neuroscience is aimed at basic neuroscientists, translational neuroscientists and clinicians who seek to gain a perspective on the nature and promise of translational therapies in the current era. Both students and established professionals will benefit from the content.

Autoimmune Neurology presents the latest information on autoimmune neurologic disease, the immune response to the body where organs run wild, causing the immune system to attack itself. Autoimmunity is a main element in numerous nervous system diseases and can target any structure within the central or peripheral nervous system. Over the past 20 years, significant advances in our understanding of the pathophysiology of autoimmune disorders, including the use of biomarkers has led to new diagnosis and treatment options. Neurologic conditions associated with autoimmune reactions include dementia, neuromuscular disease, epilepsy, sleep disorders, diabetes, and other common neurologic disorders and disease. This current tutorial-reference will be a must-have title for clinical neurologists, research neurologists, neuroscientists, and any medical professional working with autoimmune disease and disorders. - Includes comprehensive coverage of autoimmune neurology - Details the latest techniques for the study, diagnosis, and treatment of diseases and disorders, including dementia, neuromuscular disease, epilepsy, and sleep disorders - Presents a focused reference for clinical practitioners and the clinical neurology and neurology research communities

This book provides a cutting-edge review of polyglutamine disorders. It primarily focuses on two main aspects: (1) the mechanisms underlying the pathologies’ development and progression, and (2) the therapeutic strategies that are currently being explored to stop or delay disease progression. Polyglutamine (polyQ) disorders are a group of inherited neurodegenerative diseases with a fatal outcome that are caused by an abnormal expansion of a coding trinucleotide repeat (CAG), which is then translated in an abnormal protein with an elongated glutamine tract (Q). To date, nine polyQ disorders have been identified and described: dentatorubral-pallidoluysian atrophy (DRPLA); Huntington’s disease (HD); spinal–bulbar muscular atrophy (SBMA); and six spinocerebellar ataxias (SCA 1, 2, 3, 6, 7, and 17). The genetic basis of polyQ disorders is well established and described, and despite important advances that have opened up the possibility of generating genetic models of the disease, the mechanisms that cause neuronal degeneration are still largely unknown and there is currently no treatment available for these disorders. Further, it is believed that the different polyQ may share some mechanisms and pathways contributing to neurodegeneration and disease progression.