Using saccades as a research tool in the clinical neurosciences

doi:10.1093/brain/awh035

Brain Advance Access published online on November 7, 2003
Brain, doi:10.1093/brain/awh035
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Review

Using saccades as a research tool in the clinical neurosciences

R. J. Leigh ¹^* and Christopher Kennard ²

¹ Departments of Neurology, Biomedical Engineering and Neurosciences, Department of Veterans Affairs Medical Centre and University Hospitals, Case Western Reserve University, Cleveland, USA
² Division of Neurosciences and Psychological Medicine, Faculty of Medicine, Imperial College, London, UK

^* Corresponding author. E-mail: rjl4{at}po.cwru.edu.

Received 17 July 2003 ; revised 11 September 2003 ; accepted 11 September 2003

Abstract

Saccades are rapid eye movements that move the line of sightbetween successive points of fixation; they are among the bestunderstood of movements, possessing dynamic properties thatare easily measured. Saccades have become a popular means tostudy motor control, cognition and memory, and are often usedin conjunction with techniques such as functional imaging andtranscranial magnetic stimulation. It has been possible to identifyseveral, distinct populations of neurons, from brainstem tocerebral cortex, that contribute to behaviours ranging fromreflexive glances to memorized sequences of saccades duringlearned tasks. This progress has led to the development of schemesfor the neurobiology of saccades that imply an equivalence ofa region of the brain with specific behaviours (e.g. prefrontalcortex with memory-guided saccades). In fact, multiple neuronalpopulations contribute to each type of saccadic behaviour, beit ‘reflexive’ or ‘complex’. Furthermore,an important difference exists between cortical areas that encodevisual stimuli or desired saccades over a population of neuronsas ‘place maps’, and motoneurons in oculomotor, trochlearand abducens nuclei that dictate eye rotations in terms of theirdischarge rates. This dichotomy implies that a ‘spatial-temporaltransformation’ of saccadic signals must occur betweencerebral cortex and ocular motoneurons, to which the superiorcolliculus and cerebellum contribute. Consideration of suchfactors may broaden the value of saccades, which can be usedto test a range of hypotheses, and provide a simple scheme forunderstanding clinical disorders of saccades; some illustrativevideo clips are available as supplementary material at BrainOnline.

Keywords: cerebellum; eye fields; functional imaging; basal ganglia
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