A Morphogenetic Model for the Development of Cortical Convolutions

doi:10.1093/cercor/bhi068

Cerebral Cortex Advance Access originally published online on March 9, 2005
Cerebral Cortex 2005 15(12):1900-1913; doi:10.1093/cercor/bhi068

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A Morphogenetic Model for the Development of Cortical Convolutions

Roberto Toro and Yves Burnod

Institut des Sciences Cognitives, UMR 5015 CNRS-Université Claude Bernard Lyon 1, 67, boulevard Pinel, 69675 Bron, France

Address correspondence to Roberto Toro Institut des Sciences Cognitives, UMR 5015 CNRS-Université Claude Bernard Lyon 1, 67, boulevard Pinel, 69675 Bron, France. Email: rtoro{at}snv.jussieu.fr.

The convolutions of the mammalian cortex are one of its mostintriguing characteristics. Their pattern is very distinctivefor different species, and there seems to be a remarkable relationshipbetween convolutions and the architectonic and functional regionalizationof the cerebral cortex. Yet the mechanisms behind the developmentof convolutions and their association with the cortical regionalizationare poorly understood. Here we propose a morphogenetic modelfor the development of cortical convolutions based on the structureof the cortex as a closed surface with glial and axonal fibrespulling radially, the fundamental mechanical properties of cortexand fibres (elasticity and plasticity), and the growth of thecortical surface. The computer simulations of this model suggestthat convolutions are a natural consequence of cortical growth.The model reproduces several aspects of convolutional development,such as the relationship between cortical surface and brainvolume among mammals, the period of compensation in the degreeof convolution observed in gyrencephalic brains and the dependenceof the degree of convolution on cortical thickness. We havealso studied the effect of early cortical regionalization onthe development of convolutions by introducing geometric, mechanicand growth asymmetries in the model. The morphogenetic modelis thus able to reproduce the gradients in the degree of convolution,the development of primary, secondary and tertiary convolution,and the overproduction of sulci observed in animals with alteredafferent cortical connections.

Key Words: development • evolution • gyrification • gyrogenesis • theoretical modelling

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