Spatial properties and interhemispheric differences of the sensory hand cortical representation: a neuromagnetic study

Abstract

We performed a neuromagnetic investigation of the sensory hand cortical representation in the two hemispheres of 20 healthy volunteers. The localizations within the brain hemispheres of the cortical Equivalent Current Dipoles (ECDs) activated with the shortest latencies (N20 m and P30 m components) by separate stimulation of contralateral median nerve, thumb and little finger were analysed. The ECD spatial coordinates were in agreement with the known somatotopy of the sensory homunculus: little finger more medial and posterior, thumb more lateral and anterior, median nerve in-between. By considering the ECDs to thumb and little finger stimulation the boundaries of the hand cortical representation in primary sensory cortex, the `hand extension' was evaluated as the distance between the two. This parameter was similar on the two hemispheres, the `hand extension' being 17 mm and 12 mm for N20 m and P30 m components, respectively, with a standard deviation of 5 mm. We provide for the first time the ECDs localization of left and right median nerve, thumb and little finger, as well as the `hand extension' values, and their interhemispheric differences as a normative data set describing the organization of primary sensory cortical areas reserved to the hand in the healthy population. This approach permits objective measurements of absolute values, as well as of interhemispheric differences, of the sensory hand area following a monohemispheric lesion as well as to non-invasively follow-up its reorganization during clinical recovery.