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David C. Reutens
Researcher at University of Queensland
Publications - 367
Citations - 11854
David C. Reutens is an academic researcher from University of Queensland. The author has contributed to research in topics: Epilepsy & Cognition. The author has an hindex of 55, co-authored 356 publications receiving 10668 citations. Previous affiliations of David C. Reutens include Royal Perth Hospital & Royal Melbourne Hospital.
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Exercise-induced temporal lobe epilepsy
TL;DR: Prolonged hyperventilation, simple movements, and visualization of a competitive game did not produce epileptiform discharges on the interictal EEG.
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Effect of levetiracetam on cortical excitability : a transcranial magnetic stimulation study
TL;DR: The effect of levetiracetam (LEV), an anticonvulsant with a novel mechanism of action, on cortical excitability, measured using transcranial magnetic stimulation (TMS) was studied.
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An MRI atlas of the mouse basal ganglia
Jeremy F.P. Ullmann,Charles Watson,Charles Watson,Andrew L. Janke,Nyoman D. Kurniawan,George Paxinos,George Paxinos,David C. Reutens +7 more
TL;DR: A three-dimensional minimum deformation atlas is created, which includes the segmentation of 35 striatal, pallidal, and basal ganglia-related structures, and enables researchers to perform automated segmentation in genetic models of basalganglia disorders.
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Altered regional connectivity reflecting effects of different anaesthesia protocols in the mouse brain
TL;DR: The results show that anaesthesia induced by the investigated anaesthetics through different molecular targets promote agent‐specific regional connectivity in most brain areas, and ReHo is a data‐driven method with minimum user interaction, easy to use and fast to compute.
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Thickness profile generation for the corpus callosum using Laplace's equation
Chris Adamson,Amanda G. Wood,Jian Chen,Sarah Barton,David C. Reutens,Christos Pantelis,Dennis Velakoulis,Dennis Velakoulis,Mark Walterfang,Mark Walterfang +9 more
TL;DR: An automatic thickness measurement method that was originally used on magnetic resonance images of the cerebral cortex is adapted and compared with the orthogonal projection technique previously published, finding similar patterns of statistically significant differences in regional callosal thickness.