Research in the neurosciences in recent decades has shown that the central nervous system is not a structurally static organ as was believed previously, but instead is a dynamic system that constantly undergoes structural and functional reorganization. The term brain plasticity refers to the constant cellular and intercellular modifications that occur during normal development and after neurologic R esearch in the neurosciences in recent decades has revealed that the brain is not a structurally static organ as was believed previously, but instead is a dynamic system that continuously changes in structure and function. The term brain plasticity refers to the inherent capacity and resiliency of the brain to undergo structural and functional modifications. These changes are especially evident during development and after neurologic injury and can be best conceptualized as spanning throughout various levels: brain level (glial and vascular support), network level (changes in interconnection between neurons), intercellular level (qualitative and quantitative changes at the synaptic level, including synaptic sprouting), intracellular level (changes in mitochondrial and ribosomal function), biochemical level (protein conformation, enzyme mobilization), and genetic level (transcription, translation, and posttranslation modifications). 1 Because the brain is the source and end organ for neurologic, cognitive, and psychological functions, modifications in the brain's structure and function are mirrored by changes in these areas.Brain plasticity is of particular interest to neurologists because plastic changes are seen clearly after neurologic injury, and these changes correlate with either improvement or deterioration of neurologic function. Function is the cognitive and/or physical activity through which individuals interact with self and the external world and includes mobility, communication, cognition, and sexual ac-injury and result in changes in neurologic function. The discovery that central nervous system plasticity after injury can be directed toward functional improvement with use of specific modalities has opened up a new dimension in the care of the neurologically impaired patient, termed restorative neurology. Mayo Clin Proc. 2004;79:796-800 tivity. From a functional perspective, it is helpful to divide cortical reorganization after neurologic injury into functionenabling plasticity, which leads to an improvement in neurologic function, or function-disabling plasticity, which results in deterioration of function. Examples of functionenabling plasticity include changes in cortical representation and improved function seen with forced use of the affected extremity after injury. Examples of function-disabling plasticity include modifications in the cortical representation for a specific motor function after nonuse, which results in decreased motor capabilities. Other examples include late development of dystonias and other movement disorders seen after injury. Also, phantom limb and phantom sensation after spinal...
