Optic ataxia as a result of the breakdown of the global tuning fields of parietal neurones

doi:10.1093/brain/awf034

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Brain, Vol. 125, No. 2, 225-237, February 1, 2002
© 2002 Oxford University Press

Review Article

Optic ataxia as a result of the breakdown of the global tuning fields of parietal neurones

Alexandra Battaglia-Mayer¹ and Roberto Caminiti¹

Dipartimento di Fisiologia Umana e Farmacologia, Università di Roma ‘La Sapienza’, Piazzale Aldo Moro 5, 00185 Rome, Italy

Correspondence to: Dr Alexandra Battaglia-Mayer, Dipartimento di Fisiologia Umana e Farmacologia, Università di Roma ‘La Sapienza’, Piazzale Aldo Moro 5, 00185 Rome, Italy E-mail: alexandra.battagliamayer{at}uniroma1.it

Optic ataxia is characterized by an impaired visual controlof the direction of arm reaching to a visual target, accompaniedby defective hand orientation and grip formation. In humans,optic ataxia is associated with lesions of the superior parietallobule (SPL), which also affect visually guided saccades andother forms of eye–hand coordination. In the last 10 years,anatomical and physiological studies of the SPL have shed newlight on the role of parietal cortex in the control of combinedeye–hand movements to visual targets, and on the underlyingdistributed network which links parietal to frontal cortex.A main emerging functional feature of SPL neurones seems tobe their capacity to combine, in a spatially congruent fashion,different directional eye- and hand-related information, thatany coding scheme so far proposed, considers essential for thecomposition of motor commands for reaching. This integrationoccurs within the global tuning field of parietal neurones,is context-dependent and involves eye and hand information thatshares the same directional properties. Depending on task demands,this integration of signals can result in the representationof different reference frames for coordinated eye–handmovements. The dynamic operations occurring within the globaltuning fields might depend, at least in part, on the reciprocalsets of association connections linking the SPL and the premotorareas of the frontal lobe. From this picture, the SPL emergesas both a main source of visual input to the frontal cortexand a key structure for visuomotor integration based on re-entrantsignalling and, therefore, as a crucial node in the visual controlof movement. It is hypothesized that in parietal patients, thedirectional errors that characterize reaching are a consequenceof the breakdown of the combination of directional eye and handinformation within the global tuning fields of parietal neurones.In these patients, the spatial match among information abouttarget location, eye and hand position, and movement directionwould be prevented, so as to impair the composition of visuallyguided eye–hand movements. This breakdown could be dependent,at least in part, on the failure of a re-entrant frontoparietalsignalling, an obvious consequence of the degeneration of thecortico-cortical systems linking parietal and frontal cortex.Cortico-cortical connections are, in fact, essential for shapingthe dynamic properties of cortical neurones.

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