Epilepsy : The Intersection of Neurosciences, Biology, Mathematics, Engineering, and Physics

Integrating the studies of epilepsy, neurosciences, computational neurosciences, mathematics, physics, engineering, and medicine, this volume provides the first means to a clear, structured, and enriching multidisciplinary perspective for developing students, researchers, and clinicians in the field of epilepsy. The text gives up to date information on the state of current research, possible future research, and clinical directions in the fields of epilepsy and seizure dynamics. Clear illustrations that illustrate the patterns of brain electrophysiology and behavioral manifestations are provided to aid comprehension. The authors include extensive references in each chapter to enhance further study.

Epilepsy, one of the most prevalent neurological disorders, affects approximately 1% (greater than 60 million) of the world''s population. In an estimated 20 million of these patients, seizures are not controlled even by multiple anti-seizure drugs, and are extremely difficult to predict. Epilepsy: The Intersection of Neurosciences, Biology, Mathematics, Engineering, and Physics seamlessly brings together the neurosciences, mathematics, computational sciences, engineering, physics, and clinical epileptology to present to readers a highly didactic, integrated, clear and practically useful knowledge base and research directions.

Laying out the foundations of signal analysis, data conditioning, linear and non-linear analysis, introduction to dynamical systems and fundamental anatomical and neurophysiological concepts, this book:

• Introduces non-physicians to language and concepts necessary to establish a meaningful dialog with epileptologists
• Introduces physicians to dynamical theory and signal processing without which interdisciplinary collaborations would not be productive
• Mines knowledge from fields devoted to the investigation of aperiodic paroxysmal relaxation phenomena, such as earthquakes, which bear dynamical similarities with epilepsy, so as to lay the proper scientific foundations for epileptology and foster much needed therapeutic advances efficiently
• Reviews spatiotemporal behavior of seizures, mechanisms of epileptogenesis and ictogenesis as well as of seizure control and ancillary technology
• Calls attention to nocturnal frontal lobe epilepsy as a potentially fruitful paradigm for advancing seizure prediction.

Of all neurological disorders, epilepsy demands of investigators the broadest and deepest knowledge of dynamical, control, and system theories, knowledge that cannot be amassed without possessing a certain level of sophistication in relevant areas of neurosciences, physics, mathematics, and engineering. Narrowing the inescapable cultural chasm that commonly fragments multidisciplinary efforts, this book captures and enriches the burgeoning interdisciplinary synergism in the nascent field of dynamical epileptology.