Inhibition of subliminally primed responses is mediated by the caudate and thalamus: evidence from functional MRI and Huntington's disease

doi:10.1093/brain/awg067

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Brain, Vol. 126, No. 3, 713-723, March 2003
© 2003 Guarantors of Brain
doi: 10.1093/brain/awg067

Inhibition of subliminally primed responses is mediated by the caudate and thalamus: evidence from functional MRI and Huntington’s disease

A. R. Aron¹, F. Schlaghecken⁵, P. C. Fletcher¹, E. T. Bullmore¹^,2, M. Eimer⁶, R. Barker³, B. J. Sahakian¹ and T. W. Robbins⁴

¹ Brain Mapping Unit, Department of Psychiatry, University of Cambridge, ² Wolfson Brain Imaging Centre, ³ Cambridge Centre for Brain Repair and ⁴ Department of Experimental Psychology, Downing Street, Cambridge, ⁵ Department of Psychology, University of Warwick, Coventry and ⁶ Department of Psychology, Birkbeck College, London, UK

Correspondence to: Professor Trevor Robbins, Department of Experimental Psychology, University of Cambridge, Cambridge CB2 2EB, UK E-mail: twr2{at}cam.ac.uk

Masked prime tasks have shown that sensory information thathas not been consciously perceived can nevertheless triggerthe preactivation of a motor response. Automatic inhibitorycontrol processes prevent such response tendencies from interferingwith behaviour. The present study investigated the possibilitythat these inhibitory control processes are mediated by a cortico-striatal-pallidal-thalamicpathway by using a masked prime task with Huntington’sdisease patients (Experiment 1) and with healthy volunteersin a functional MRI (fMRI) study (Experiment 2). In the maskedprime task, clearly visible left- or right-pointing target arrowsare preceded by briefly presented and subsequently masked primearrows. Participants respond quickly with a left or right key-pressto each target. Trials are either compatible (prime and targetpointing in the same direction) or incompatible (prime and targetpointing in different directions). Prior behavioural and electrophysiologicalresults show that automatic inhibition of the initially primedresponse tendency is reflected in a ‘negative compatibilityeffect’ (faster reaction times for incompatible trialsthan for compatible trials), and is shown to consist of threedistinct processes (prime activation, response inhibition andresponse conflict) occurring within 300 ms. Experiment1 tested the hypothesis that lesions of the striatum would interruptautomatic inhibitory control by studying early-stage Huntington’sdisease patients. Findings supported the hypothesis: there wasa bimodal distribution for patients, with one-third (choreic)showing disinhibition, manifested as an absent negative compatibilityeffect, and two-thirds (non-choreic) showing excessive inhibition,manifested as a significantly greater negative compatibilityeffect than that in controls. Experiment 2 used fMRI and a regionof interest (ROI) template-based method to further test thehypothesis that structures of the striatal-pallidal-thalamicpathway mediate one or more of the processes of automatic inhibitorycontrol. Neither prime activation nor response conflict significantlyengaged any ROIs, but the response inhibition process led tosignificant modulation of both the caudate and thalamus. Takentogether, these experiments indicate a causal role for the caudatenucleus and thalamus in automatic inhibitory motor control,and the results are consistent with performance of the taskrequiring both direct and indirect striatal-pallidal-thalamicpathways. The finding that Huntington’s disease patientswith greater chorea were disinhibited is consistent with thetheory that chorea arises from selective degeneration of striatalprojections to the lateral globus pallidus, while the exaggeratedinhibitory effect for patients with little or no chorea maybe due to additional degeneration of projections to the medialglobus pallidus.

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