Book contents
- Frontmatter
- Contents
- List of contributors
- Preface and overview
- 1 Epilepsies as channelopathies
- 2 Epilepsy and movement disorders in the GABAA receptor β3 subunit knockout mouse: model of Angelman syndrome
- 3 Genetic reflex epilepsy from chicken to man: relations between genetic reflex epilepsy and movement disorders
- 4 Functional MRI of the motor cortex
- 5 Neuromagnetic methods and transcranial magnetic stimulation for testing sensorimotor cortex excitability
- 6 Motor dysfunction resulting from epileptic activity involving the sensorimotor cortex
- 7 Nocturnal frontal lobe epilepsy
- 8 Motor cortex hyperexcitability in dystonia
- 9 The paroxysmal dyskinesias
- 10 Normal startle and startle-induced epileptic seizures
- 11 Hyperekplexia: genetics and culture-bound stimulus-induced disorders
- 12 Myoclonus and epilepsy
- 13 The spectrum of epilepsy and movement disorders in EPC
- 14 Seizures, myoclonus and cerebellar dysfunction in progressive myoclonus epilepsies
- 15 Opercular epilepsies with oromotor dysfunction
- 16 Facial seizures associated with brainstem and cerebellar lesions
- 17 Neonatal movement disorders: epileptic or non-epileptic
- 18 Epileptic and non-epileptic periodic motor phenomena in children with encephalopathy
- 19 Epileptic stereotypies in children
- 20 Non-epileptic paroxysmal eye movements
- 21 Shuddering and benign myoclonus of early infancy
- 22 Epilepsy and cerebral palsy
- 23 Sydenham chorea
- 24 Alternating hemiplegia of childhood
- 25 Motor attacks in Sturge–Weber syndrome
- 26 Syndromes with epilepsy and paroxysmal dyskinesia
- 27 Epilepsy genes: the search grows longer
- 28 Genetics of the overlap between epilepsy and movement disorders
- 29 Seizures and movement disorders precipitated by drugs
- 30 Steroid responsive motor disorders associated with epilepsy
- 31 Drugs for epilepsy and movement disorders
- Index
- Plate section
4 - Functional MRI of the motor cortex
Published online by Cambridge University Press: 03 May 2010
- Frontmatter
- Contents
- List of contributors
- Preface and overview
- 1 Epilepsies as channelopathies
- 2 Epilepsy and movement disorders in the GABAA receptor β3 subunit knockout mouse: model of Angelman syndrome
- 3 Genetic reflex epilepsy from chicken to man: relations between genetic reflex epilepsy and movement disorders
- 4 Functional MRI of the motor cortex
- 5 Neuromagnetic methods and transcranial magnetic stimulation for testing sensorimotor cortex excitability
- 6 Motor dysfunction resulting from epileptic activity involving the sensorimotor cortex
- 7 Nocturnal frontal lobe epilepsy
- 8 Motor cortex hyperexcitability in dystonia
- 9 The paroxysmal dyskinesias
- 10 Normal startle and startle-induced epileptic seizures
- 11 Hyperekplexia: genetics and culture-bound stimulus-induced disorders
- 12 Myoclonus and epilepsy
- 13 The spectrum of epilepsy and movement disorders in EPC
- 14 Seizures, myoclonus and cerebellar dysfunction in progressive myoclonus epilepsies
- 15 Opercular epilepsies with oromotor dysfunction
- 16 Facial seizures associated with brainstem and cerebellar lesions
- 17 Neonatal movement disorders: epileptic or non-epileptic
- 18 Epileptic and non-epileptic periodic motor phenomena in children with encephalopathy
- 19 Epileptic stereotypies in children
- 20 Non-epileptic paroxysmal eye movements
- 21 Shuddering and benign myoclonus of early infancy
- 22 Epilepsy and cerebral palsy
- 23 Sydenham chorea
- 24 Alternating hemiplegia of childhood
- 25 Motor attacks in Sturge–Weber syndrome
- 26 Syndromes with epilepsy and paroxysmal dyskinesia
- 27 Epilepsy genes: the search grows longer
- 28 Genetics of the overlap between epilepsy and movement disorders
- 29 Seizures and movement disorders precipitated by drugs
- 30 Steroid responsive motor disorders associated with epilepsy
- 31 Drugs for epilepsy and movement disorders
- Index
- Plate section
Summary
Festina lente
The Decade of the Brain has witnessed important methodological innovations that have greatly facilitated the study and the knowledge of brain functions. Among the new tools which are nowadays at the disposition of researchers, neuroimaging techniques have attracted much interest not only among neuroscientists but also in the media since the assumption has been made public that these methodologies allow us to ‘see’ the brain at work. We will see in the following that this is partly natural exaggeration by the media. It is the feeling of the authors that a certain amount of caution should be taken into account in the case of a methodology (functional magnetic resonance imaging, fMRI) which, at present, is certainly most promising in revealing brain functions under various, and not restrictive, cerebral events such as those concerning sensory, motor and cognitive functions. This will be done in the following under the form of three questions which, we think, should be considered every time a patient (or a normal subject) is under study.
A short introduction
Neuroimaging techniques such as MRI belong to the progeny of physics which has brought a commendable intuition to become an extremely complex discipline. To clearly understand the physical principles of MRI, the knowledgeable intervention of quantum mechanics is an obligatory step. As a prerequisite, it is thus advisable to approach this methodology from a multidisciplinary standpoint, with a multidisciplinary team, and to constantly remember that what one sees might potentially be a multidisciplinary methodological artefact.
It is not within the scope of the present chapter to describe the theory of MRI. Excellent reviews have been written on the subject (see, for example, Aine, 1995).
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- Epilepsy and Movement Disorders , pp. 47 - 58Publisher: Cambridge University PressPrint publication year: 2001