Mapping the brain in autism. A voxel-based MRI study of volumetric differences and intercorrelations in autism

doi:10.1093/brain/awh332

Brain Advance Access originally published online on November 17, 2004
Brain 2005 128(2):268-276; doi:10.1093/brain/awh332

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Mapping the brain in autism. A voxel-based MRI study of volumetric differences and intercorrelations in autism

Gráinne M. McAlonan¹, Vinci Cheung¹, Charlton Cheung¹, John Suckling², Grace Y. Lam¹^,3, K. S. Tai⁴, L. Yip⁴, Declan G. M. Murphy⁵ and Siew E. Chua¹

Departments of ¹ Psychiatry and ⁴ Diagnostic Radiology, University of Hong Kong, SAR China, ² Cambridge Brain Mapping Unit, University of Cambridge, UK, ³ School of Early Childhood Education, Hong Kong Institute of Education, Hong Kong, SAR China and ⁵ Department of Psychological Medicine, Institute of Psychiatry, London, UK

Correspondence to: Grainne M. McAlonan, Department of Psychiatry, University of Hong Kong, Pokfulam, Hong Kong, SAR China E-mail: mcalonan{at}hkucc.hku.hk

Autism is a disorder of neurodevelopment resulting in pervasiveabnormalities in social interaction and communication, repetitivebehaviours and restricted interests. There is evidence for functionalabnormalities and metabolic dysconnectivity in ‘socialbrain’ circuitry in this condition, but its structuralbasis has proved difficult to establish reliably. Explanationsfor this include replication difficulties inherent in ‘regionof interest’ approaches usually adopted, and variableinclusion criteria for subjects across the autism spectrum.Moreover, despite a consensus that autism probably affects widelydistributed brain regions, the issue of anatomical connectivityhas received little attention. Therefore, we planned a fullyautomated voxel-based whole brain volumetric analysis in childrenwith autism and normal IQ. We predicted that brain structuralchanges would be similar to those previously shown in adultswith autism spectrum disorder and that a correlation analysiswould suggest structural dysconnectivity. We included 17 stringentlydiagnosed children with autism and 17 age-matched controls.All children had IQ >80. Using Brain Activation and MorphologicalMapping (BAMM) software, we measured global brain and tissueclass volumes and mapped regional grey and white matter differencesacross the whole brain. With the expectation that volumes ofinterconnected regions correlate positively, we carried outa preliminary exploration of ‘connectivity’ in autismby comparing the nature of inter-regional grey matter volumecorrelations with control. Children with autism had a significantreduction in total grey matter volume and significant increasein CSF volume. They had significant localized grey matter reductionswithin fronto-striatal and parietal networks similar to findingsin our previous study, and additional decreases in ventral andsuperior temporal grey matter. White matter was reduced in thecerebellum, left internal capsule and fornices. Correlationanalysis revealed significantly more numerous and more positivegrey matter volumetric correlations in controls compared withchildren with autism. Thus, using similar diagnostic criteriaand image analysis methods in otherwise healthy populationswith an autistic spectrum disorder from different countries,cultures and age groups, we report a number of consistent findings.Taken together, our data suggest abnormalities in the anatomyand connectivity of limbic–striatal ‘social’brain systems which may contribute to the brain metabolic differencesand behavioural phenotype in autism.

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