Cortical Plasticity and Motor Activity Studied with Transcranial Magnetic Stimulation

• Published in: Reviews in the neurosciences Vol. 17; no. 5; pp. 469 - 496
• Main Authors: Tyc, François, Boyadjian, Alain
• Format: Journal Article
• Language: English
• Published: Germany De Gruyter 2006
• Subjects: Adaptation, Physiological; Animals; Brain - physiology; Brain Mapping; Humans; Learning - physiology; Motor Activity - physiology; Neuronal Plasticity - physiology; Transcranial Magnetic Stimulation
• ISSN: 0334-1763; 2191-0200
• DOI: 10.1515/REVNEURO.2006.17.5.469

For decades cortical representations of the parts of the body have been considered to be unchangeable. This view has changed radically during the past 20 years using new tools designed to study plasticity in the adult human brain. Transcranial magnetic stimulation (TMS) is a valuable non-invasive technique for exploring the ability of the motor cortex to change during motor skill acquisition. Results obtained with TMS in neurological patients as well as in normal subjects demonstrate that cortical plasticity is a necessity for correct adaptation to the continuously changing environment. Topographical reorganization of the motor cortex depends on the types of movements performed by the subjects. During simple training, the cortical representation is enlarged, and it returns to its initial size when the task is overlearned. These transient modifications characterize simple motor training. Motor skills in which coordination of distal and proximal muscles, precision of the task and spatio-temporal constraints are associated, has a different impact on cortical reorganization. We propose that years of practice of a complex motor skill induces a new cortical topography that must be interpreted as structural plasticity which provides the capacity to execute a plastic behaviour instead of a stereotypical movement. We review the neuronal mechanisms underlying plasticity in different types of movement. We stress new emerging notions, such as overlap of cortical maps, and system dynamics at single neuron and network levels, to explain the reorganization of movement representations that encode motor skill. Dendritic arborizations as functional computing elements, newly generated neurons in adult brain, and plastic architectures of cortical networks operating as distributed functional modules are new hypotheses for structural plasticity.