Dresden 2020 – scientific programme
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CPP: Fachverband Chemische Physik und Polymerphysik
CPP 91: Computational Biophysics (joint session BP/CPP)
CPP 91.6: Talk
Thursday, March 19, 2020, 10:45–11:00, SCH A251
The role of thickness inhomogeneities in brain folding — •Lucas da Costa Campos1, 2, Svenja Caspers2, 3, 4, Gerhard Gompper1, and Jens Elgeti1 — 1Theoretical Soft Matter and Biophysics (ICS-2 / IAS-2), Research Centre Jülich, Jülich, Germany — 2Institute of Neuroscience and Medicine (INM-1), Research Centre Jülich, Germany — 3JARA-Brain, Jülich-Aachen Research Alliance, Jülich, Germany — 4Institute for Anatomy I, Medical Faculty, Heinrich-Heine University, Düsseldorf, Germany
The morphology of the mammalian brain cortex is highly folded. Misfolds of the brain correlate with a long list of cognitive disabilities, such as schizophrenia and epilepsy. Having realistic models of gyrogenesis is the first step in the understanding of these issues. It has been hypothesized that mechanical instabilities play an essential role in gyrogenesis. However, the emergence of higher order folding, one of the main characteristics of the human brain, has not been fully tackled. We perform finite element simulations of rectangular slabs divided into two distinct regions. Differential growth is introduced by growing the top layer (gray matter) tangentially, while keeping the underlying layer (white matter) unchanged. The material is modelled as a Neohookean hyperelastic. Simulations are performed with system with either homogeneous or inhomogeneous cortical thickness. In early stages of development, we obtain structures reminiscent of the deep sulci in the brain, which can be mapped into the primary sulci. As the cortex continues to develop, we obtain secondary undulations whose characteristics are consistent with those of higher order folding.