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Ocular neuroprotection is aimed at protecting the death of photoreceptors, retinal ganglion, or other important neurons in cases of disease or trauma. Levin (ophthalmology and neurology, U. of Wisconsin at Madison, US) and Di Polo (pathology and cell biology, U. of Montreal, Canada) present 18 chapt.
This book provides the latest findings on neuroprotection and neuroregeneration as potential therapeutic strategies for various eye diseases, namely, glaucoma, age-related macular degeneration (AMD), retinal detachment, and retinitis pigmentosa. Glaucoma is one of the main causes of blindness throughout the world, and other diseases such as AMD and retinitis pigmentosa also lead to loss of vision. All these conditions are characterized by degeneration of specific retinal cell types, making it essential to establish treatments to protect retinal neurons and the optic nerve. With that aim in mind, this book explains the mechanisms underlying aforementioned diseases and their experimental models. The novel strategy proposals for the treatment of retinal diseases based on the concept of neuroprotection are also discussed in the main body of the text, while the section on regenerative research discusses optic nerve regeneration, endothelial progenitor cells, and iPS cells. This book is recommended as a professional reference work for all doctors and trainees in the field of ophthalmology who are interested in neuroprotective and neuroregenerative treatments.
Glaucoma, just as many other neurodegenerative diseases, triggers neuronal death and remained incurable, hence representing a heavy burden for the society. Therefore, there is a critical need for developing new therapeutic strategies to delay the progression of and, ultimately, cure neurological conditions. For decades, neuroscientists studying injuries and diseases of the CNS have largely focused on understanding the mechanisms of axon degeneration to identify new targets for axonal protection and regeneration. But recent data indicates that dendritic deficits represent an early feature of neurodegeneration, a phenomenon now called dendritic pathology and playing a key role in the pathogenesis of neurodegenerative diseases including glaucoma. Because dendrites are essential structures for neuronal communication and function, it is therefore crucial to protect or restore connectivity as well as axons of surviving neurons to improve patients' condition. In spite of this, the ability of injured neurons to regenerate dendrites remains largely ignored. The central hypothesis of the thesis is that: i) adult CNS neurons can regrow their dendrites after axonal injury, and ii) the identification of underlying signalling pathways would offer new therapeutic avenues to slow or prevent retinal ganglion cell death during ocular neuropathies such as glaucoma. In the first part of my thesis, I demonstrated that mammalian neurons are endowed with the ability to restore their dendritic arbor and synaptic connectivity. Using adult transgenic mice subjected to optic nerve axotomy, we have shown that retinal ganglion cells (RGCs) rapidly undergo dendritic shrinkage before cell death or axonal damage become visible. We also demonstrated that daily insulin, administered topically (eye drops) or systemically (intraperitoneal) after dendritic arbour shrinkage and prior to neuronal loss results in a robust regeneration of dendrites and successful reconnection with presynaptic targets. Moreover, insulin-mediated restoration of dendritic arbors extended neuronal survival and rescued lighttriggered retinal responses. Targeted loss-of-function experiments using siRNAs revealed that insulin-dependent regeneration requires both the activity of both mTOR complexes, mTORC1 and mTORC2 which act synergistically, mTORC1 promoting new dendritic branching to restore arbor complexity, while mTORC2 drives dendritic process elongation. In the second study presented in my thesis, we showed for the first time that morgana, a chaperone protein downstream of mTORC2, is expressed by RGCs and severely downregulated soon after axonal injury. We also demonstrate that morgana is required for successful insulinmediated regeneration of RGC dendrites and neuroprotection. Morgana specific knockdown using siRNA designed against morgana resulted in substantial alterations of dendrite elongation, without changes in arbor complexity. Further, we showed that AAV-mediated rescue of morgana expression selectively in RGCs promoted striking regeneration of dendrites and synapses. Hence, our findings identified a new role for morgana in the regulation of dendritic arbor morphology in adult mammalian neurons Collectively, the findings presented in this thesis contribute to a better understanding of the pathological mechanisms underlying RGC dendritic pathology and identified promising targets for the development of novel neuroprotective treatments for neurodegenerative diseases such as glaucoma.
Neural Regeneration provides an overview of cutting-edge knowledge on a broad spectrum of neural regeneration, including: Neural regeneration in lower vertebrates Neural regeneration in the peripheral nervous system Neural regeneration in the central nervous system Transplantation-mediated neural regeneration Clinical and translational research on neural regeneration The contributors to this book are experts in their fields and work at distinguished institutions in the United States, Canada, Australia, and China. Nervous system injuries, including peripheral nerve injuries, brain and spinal cord injuries, and stroke affect millions of people worldwide every year. As a result of this high incidence of neurological injuries, neural regeneration and repair is becoming a rapidly growing field dedicated to the new discoveries to promote structural and functional recoveries based on neural regeneration. The ultimate goal is to translate the most optimal regenerative strategies to treatments of human nervous system injuries. This valuable reference book is useful for students, postdoctors, and basic and clinical scientists who are interested in neural regeneration research. Provides an overview of cutting-edge knowledge on a broad spectrum of neural regeneration Highly translational and clinically-relevance International authors who are leaders in their respective fields Vivid art work making the chapters easily understood
Published since 1959, International Review of Neurobiology is a well-known series appealing to neuroscientists, clinicians, psychologists, physiologists, and pharmacologists. Led by an internationally renowned editorial board, this important serial publishes both eclectic volumes made up of timely reviews and thematic volumes that focus on recent progress in a specific area of neurobiology research. This volume reviews existing theories and current research surrounding Axon Growth and Regeneration. Leading authors review state-of-the-art in their field of investigation and provide their views and perspectives for future research Chapters are extensively referenced to provide readers with a comprehensive list of resources on the topics covered All chapters include comprehensive background information and are written in a clear form that is also accessible to the non-specialist
This dissertation, "Neuroprotection of Low Energy Laser on Retinal Ganglion Cells Survival After Optic Nerve Injury" by 林瑋源, Wai-yuan, Leon, Lam, was obtained from The University of Hong Kong (Pokfulam, Hong Kong) and is being sold pursuant to Creative Commons: Attribution 3.0 Hong Kong License. The content of this dissertation has not been altered in any way. We have altered the formatting in order to facilitate the ease of printing and reading of the dissertation. All rights not granted by the above license are retained by the author. DOI: 10.5353/th_b3122286 Subjects: Retinal ganglion cells Optic nerve - Wounds and injuries Optic nerve - Laser surgery
Mitogen-activated protein (MAP) kinase (MAPK) cascades are key signaling components that govern essentially all cellular processes evoked by any type of stimulation, and it has been well established that the malfunctioning of these cascades leads to various diseases including cancer, autoimmunity, and diabetes. In MAP Kinase Signaling Protocols, Second Edition, expert researchers fully update the popular first edition the key techniques used in the study of MAPK signaling cascades in various cellular contexts. This thorough volume explores essential topics such as activation and function of components of the MAPK signaling cascades, the study of MAPK cascades as transmitters of membranal receptor signals, structure-function relationships of MAPKs, studies on the regulation of MAPK cascades, the use of lower organisms, animal models, and human genetics in the study of MAPKs, as well as the study of MAPKs in specific systems and diseases. Written in the highly successful Methods in Molecular BiologyTM series format, chapters includes introductions to their respective subjects, lists of the necessary materials, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Comprehensive and cutting-edge, MAP Kinase Signaling Protocols, Second Edition aims to facilitate the study of MAPKs and allow for quicker progress in our knowledge of many vital cellular processes as well as devastating diseases.
Leading authors review state-of-the-art in their field of investigation and provide their views and perspectives for future research. Chapters are extensively referenced to provide readers with a comprehensive list of resources on the topics covered. All chapters include comprehensive background information and are written in a clear form that is also accessible to the non-specialist Leading authors review state-of-the-art in their field of investigation and provide their views and perspectives for future research Chapters are extensively referenced to provide readers with a comprehensive list of resources on the topics covered All chapters include comprehensive background information and are written in a clear form that is also accessible to the non-specialist