Epilepsy research has entered an exciting phase as advances in molecular analysis have supplemented in vitro and in vivo electrophysiologic and phenotypic characterization. Recent Advances in Epilepsy Research sets forth a series of chapter reviews by researchers involved in these advances. This volume is a composite profile of some exciting recent investigations in select areas of enquiry.
Key features: neurogenetics of seizure disorders, new developments in cellular and molecular neurobiology of seizure disorders, the role of growth factors in seizures, new advances in the roles of metabotropic glutamate receptors and GABA receptors and transporters, gap junctions, neuroimmunology of epilepsy, malformations of cortical development, neurogenesis, new animal models of epilepsy and the use of brain stimulation to treat epilepsy. This book should be of interest to a wide variety of audiences, including graduate students in neurobiology and related disciplines, neuroscientists, medical students, neurologists, neurosurgeons, and industry including pharmaceutical companies and medical device companies. There are many ideas in this book that will lead ingenious innovators in academia and industry to develop new and better therapies.

Brain functions are realized by the activity of neuronal networks composed of a huge number of neurons. The efficiency of information transfer within the networks is changeable. Even the networks themselves can change through experience. Information transfer between neurons is performed at the synapse (the site of the neurons contact) by release of neurotransmitters from the pre-synaptic cell and capture of neurotransmitters by the post-synaptic cell. The amount of released neurotransmitter or the efficacy of capture can change. Moreover, synapses are found to be newly formed upon activity or abandoned upon inactivity. These changes are called "synaptic plasticity."

This text focuses on one component of synaptic plasticity called transsynaptic signaling, or communication of synapses during their formation.

This book is dedicated to Dr. Philip A. Schwartzkroin. The book has a novel format because it is not intended to be a set of reviews. Instead, it is an effort to explore important topics in the epilepsy research field. Because articles are written by leaders in the field who have years of experience, and individuals with diverse expertise, articles are likely to have a long-lasting impact and be relevant for both epileptologists and neuroscientists. Authors address topics that are important, unresolved questions in the field of epilepsy research, drawing on available data from both the bench and the clinic to support their points. A given topic is addressed by one or more authors, each writing from his/her own unique perspective. For all of the individuals who have been trained or worked with Philip Schwartzkroin in the past, and/or have appreciated his contributions to the epilepsy field, this volume is an excellent way to celebrate his achievements and look to the ways they have moved the field forward, and continue to stimulate its growth.

This book is dedicated to Dr. Philip A. Schwartzkroin. The book has a novel format because it is not intended to be a set of reviews. Instead, it is an effort to explore important topics in the epilepsy research field. Because articles are written by leaders in the field who have years of experience and individuals with diverse expertise, articles are likely to have a long-lasting impact and be relevant for both epileptologists and neuroscientists. Authors address topics that are important, unresolved questions in the field of epilepsy research, drawing on available data from both the bench and the clinic to support their points. A given topic is addressed by one or more authors, each writing from his/her own unique perspective. For all of the individuals who have been trained or worked with Philip Schwartzkroin in the past and/or have appreciated his contributions to the epilepsy field, this volume is an excellent way to celebrate his achievements and look to the ways they have moved the field forward and continue to stimulate its growth.

Epilepsy research has entered an exciting phase as advances in molecular analysis have supplemented in vitro and in vivo electrophysiologic and phenotypic characterization. Recent Advances in Epilepsy Research sets forth a series of chapter reviews by researchers involved in these advances. This volume is a composite profile of some exciting recent investigations in select areas of enquiry.
Key features: neurogenetics of seizure disorders, new developments in cellular and molecular neurobiology of seizure disorders, the role of growth factors in seizures, new advances in the roles of metabotropic glutamate receptors and GABA receptors and transporters, gap junctions, neuroimmunology of epilepsy, malformations of cortical development, neurogenesis, new animal models of epilepsy and the use of brain stimulation to treat epilepsy. This book should be of interest to a wide variety of audiences, including graduate students in neurobiology and related disciplines, neuroscientists, medical students, neurologists, neurosurgeons, and industry including pharmaceutical companies and medical device companies. There are many ideas in this book that will lead ingenious innovators in academia and industry to develop new and better therapies.

Brain functions are realized by the activity of neuronal networks composed of a huge number of neurons. The efficiency of information transfer within the networks is changeable. Even the networks themselves can change through experience. Information transfer between neurons is performed at the synapse (the site of the neurons contact) by release of neurotransmitters from the pre-synaptic cell and capture of neurotransmitters by the post-synaptic cell. The amount of released neurotransmitter or the efficacy of capture can change. Moreover, synapses are found to be newly formed upon activity or abandoned upon inactivity. These changes are called "synaptic plasticity."

This text focuses on one component of synaptic plasticity called transsynaptic signaling, or communication of synapses during their formation.