Litcius/Paper detail

A model of tension-induced fiber growth predicts white matter organization during brain folding

Kara Garcia, Xiaojie Wang, Christopher D. Kroenke

2021Nature Communications47 citationsDOIOpen Access PDF

Abstract

The past decade has experienced renewed interest in the physical processes that fold the developing cerebral cortex. Biomechanical models and experiments suggest that growth of the cortex, outpacing growth of underlying subcortical tissue (prospective white matter), is sufficient to induce folding. However, current models do not explain the well-established links between white matter organization and fold morphology, nor do they consider subcortical remodeling that occurs during the period of folding. Here we propose a framework by which cortical folding may induce subcortical fiber growth and organization. Simulations incorporating stress-induced fiber elongation indicate that subcortical stresses resulting from folding are sufficient to induce stereotyped fiber organization beneath gyri and sulci. Model predictions are supported by high-resolution ex vivo diffusion tensor imaging of the developing rhesus macaque brain. Together, results provide support for the theory of cortical growth-induced folding and indicate that mechanical feedback plays a significant role in brain connectivity.

Topics & Concepts

White matterDiffusion MRINeuroscienceMacaqueFolding (DSP implementation)Cortex (anatomy)Cerebral cortexBiologyBiophysicsAnatomyMedicineMagnetic resonance imagingElectrical engineeringRadiologyEngineeringAdvanced Neuroimaging Techniques and ApplicationsFunctional Brain Connectivity StudiesAdvanced MRI Techniques and Applications