Transcranial Magnetic Stimulation: A Neurochronometrics of Mind (Bradford Books) [Paperback]

Vincent Walsh (Author), Alvaro Pascual-Leone (Author), Stephen M. Kosslyn (Foreword)

Book Description

Series: Bradford Books | Publication Date: August 12, 2005

The mainstays of brain imaging techniques have been positron emission tomography (PET), functional magnetic resonance imaging (fMRI), magnetoencephalography (MEG), and event-related potentials (ERPs). These methods all record direct or indirect measures of brain activity and correlate the activity patterns with behavior. But to go beyond the correlations established by these techniques and prove the necessity of an area for a given function, cognitive neuroscientists need to be able to reverse engineer the brain--i.e., to selectively remove components from information processing and assess their impact on the output.This book is about transcranial magnetic stimulation (TMS), a technique that emerged during the same period as neuroimaging and has made it possible to reverse engineer the human brain's role in behavioral and cognitive functions. The subject areas that can be studied using TMS run the gamut of cognitive psychology--attention, perception, awareness, eye movements, action selection, memory, plasticity, language, numeracy, and priming. The book presents an overview of historical attempts at magnetic brain stimulation, ethical considerations of the technique's use, basic technical and practical information, the results of numerous TMS studies, and a discussion of the future of TMS in the armamentarium of cognitive neuropsychology.

Editorial Reviews

Review

"Making reversible lesions in the human brain was until recently a secret dream in neuroscientists' minds; examining the effects of local brain stimulation something only neurosurgeons could aspire to. This extraordinary method has opened up a multitude of experimental possibilities that have been rapidly exploited -- notably by the authors of this volume. The use of TMS in its various guises with other non-invasive brain recording techniques such as imaging and encephalography promises another great step in the program of grounding the study of human psychology in biological facts."--Richard Frackowiak, Wellcome Department of Imaging Neuroscience, Institute of Neurology, University College London

About the Author

Vincent Walsh is a Royal Society Research Fellow and Reader in Psychology at the Institute of Cognitive Neuroscience, University College London. Alvaro Pascual-Leone is Director of Research at the Behavioral Neurology Unit of Beth Israel Deaconess Medical Center and Associate Professor of Neurology at Harvard Medical School.

Product Details

• Paperback: 319 pages
• Publisher: A Bradford Book; New Ed edition (August 12, 2005)
• Language: English
• ISBN-10: 0262731746
• ISBN-13: 978-0262731744
• Product Dimensions: 8.8 x 6.6 x 0.7 inches
• Shipping Weight: 1.2 pounds (View shipping rates and policies)
• Average Customer Review: 5.0 out of 5 stars  See all reviews (2 customer reviews)
• Amazon Best Sellers Rank: #1,255,472 in Books (See Top 100 in Books)

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20 of 25 people found the following review helpful:

5.0 out of 5 stars A new method for mental analyses, April 14, 2004

By 

Alwyn Scott (Tucson, AZ USA) - See all my reviews

This review is from: Transcranial Magnetic Stimulation: A Neurochronometrics of Mind (Bradford Books) (Hardcover)

Written for research neurologists, this handsomely printed book introduces the subject of transcranial magnetic stimulation (TMS), which joins electroencephalography (EEG), event related potentials (ERPs), magnetoencephalography (MEG), functional magnetic resonance imaging (fMRI), and positron emission tomography (PET) as a new tool for studying the dynamics of the human brain. In simplest terms, TMS floods a restricted region of the neocortex with a large magnetic field (about 2 tesla or 20,000 gauss) for a fraction of a millisecond. In order to influence brain dynamics, it is now understood, a magnetic field must be rather large (the earth's magnetic field is about 0.5 gauss), and it must be rapidly established. The broad effect of such a sudden intrusion of magnetic field energy is to introduce computational noise into the neocortical dynamics, interfering with motor activity and causing the perception of spots of light (phosphenes), in addition to more subtly influencing the brain's behavior in a variety of ways.

The basic idea of TMS is simple---a steady voltage source (power supply) charges a storage capacitor to some 2 kilojoules of energy, which is suddenly discharged as magnetic field energy through a magnetic stimulating coil by closing a solid-state switch. In an interesting early chapter, the authors of Transcranial Magnetic Stimulation trace the checkered history of related ideas from the discovery of magnetic induction by Michael Faraday in 1831 to the practical realization of TMS by Anthony Barker and his colleagues at Sheffield, England in the mid-1980s. Why ``checkered''? Our brains are relatively insensitive to magnetic fields of ordinary strength (try waving a horseshoe magnet near your temple) so much of the nineteenth-century speculation on mental effects of magnetic fields was pseudoscientific or worse. The brain is insensitive to magnetic fields because it is not an electromagnetic medium. In other words, cortical dynamics are dominated by interacting electric fields and ionic currents, in which magnetic fields play only minor roles.

Normal cortical currents generate minute magnetic fields which are observed in MEG measurements, and the very large external magnetic fields that are suddenly turned on under TMS generate small transmembrane voltages that may influence the course of these currents, but this picture is very different from a true electromagnetic medium---such as a propagating radio wave or the output light beam from a laser---in which the total energy remains essentially conserved as it oscillates rapidly back and forth between electric and magnetic energy. In the brain, to the contrary, electric field energy is continually being generated by hydrolysis of adenosine triphosphate, stored in transmembrane potentials, and dissipated through myriad nonlinear electric field interactions with transmembrane ionic currents. Whatever small magnetic fields that are present do not influence normal functioning of the brain.

In neuroscience research, TMS has the advantage of acting as a noninvasive ``virtual lesion'' which can be rapidly induced over a region that penetrates an inch or so into the neocortex and is transversely localized to roughly a square inch. Because cortical fibers are somewhat randomly oriented, such a localized and rapidly rising TMS field generates a random spectrum of transmembrane voltages that are either excitatory or inhibitory depending on the local orientation of a particular fiber, thereby introducing the functional equivalent of computational noise. About 20 ms after the end of a TMS pulse, the major effects disappear, and an experiment can be repeated; thus it is feasible to measure changes in timing delays for various motor responses as the stimulating coil is moved over the scalp, a research activity of considerable current interest. In addition to such timing experiments, which the authors of this book describe in some detail, there is also the possibility of using TMS in a ``repetitive'' mode called rTMS. In this mode, a periodic series of magnetic pulses are generated, and the experimenter has the opportunity of introducing steady noise into a restricted volume of the cortical dynamics for a well defined interval of time. This leads to the possibility of observing subsequent effects on a variety of subtle cognitive activities, many of which are reviewed and described in this book.

TMS safety is evidently a key concern; the authors mention that no one with a history of epilepsy should be used as a subject. Clearly this is a matter that neuropsychological researchers should consider carefully as they put their subjects through an increasing variety of subjective experiences, including visual suppression and extinction, search interference, geometrical perception, perception of temporal sequence, variations in attention, perceptual learning, and memory inhibition. Considering all of these possible applications, it seems safe to predict that both TMS and rTMS will make important contributions to research in neuropsychology over the next few years. As an introduction, Transcranial Magnetic Stimulation is highly recommended for all who would take up this exciting activity.

Alwyn Scott
http://personal.riverusers.com/~rover/

5.0 out of 5 stars A different direction, September 9, 2011

By 

Michael Demidenko - See all my reviews
(REAL NAME)   

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This review is from: Transcranial Magnetic Stimulation: A Neurochronometrics of Mind (Bradford Books) (Paperback)

Being in the field of research, I'm hearing more and more that researchers will begin to move away from the fancy MRI's - seeing as they are clunky, expensive, and did I mention, huge? Unless there is something done to the MRI to make it smaller and equally efficient, TMS and EEG will be leading the way in research surrounding the brain.

Although this book is somewhat dry, I hope it is something you've realized on your own. The equipment is complex and the organ it is associated with is even more complex. So without attempting to prime you, I will steer clear of making you judge this book as boring - it is nothing of the sort. The information is interesting and the manner it is presented in, it allows the reader better understand TMS.
So if you're interested in learning about TMS, I'd recommend you pick this book up.