Forward and backward connections in the brain: A DCM study of functional asymmetries

In this paper, we provide evidence for functional asymmetries in forward and backward connections that define hierarchical architectures in the brain. We exploit the fact that modulatory or nonlinear influences of one neuronal system on another (i.e., effective connectivity) entail coupling between...

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Veröffentlicht in:	NeuroImage (Orlando, Fla.) Fla.), 2009-04, Vol.45 (2), p.453-462
Hauptverfasser:	Chen, C.C., Henson, R.N., Stephan, K.E., Kilner, J.M., Friston, K.J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Anatomy & physiology Asymmetry Backward connection Brain Mapping - methods Brain research Computer Simulation Dynamic causal modelling Evoked Potentials, Visual - physiology Female Functional Laterality - physiology Humans Induced responses Magnetoencephalography - methods Male Models, Neurological Nerve Net - physiology Neuronal dynamics Nonlinear coupling Pattern Recognition, Visual - physiology Predictive coding Recurrent connection Reentrant dynamics Software Spectral responses Studies
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creator	Chen, C.C. Henson, R.N. Stephan, K.E. Kilner, J.M. Friston, K.J.
description	In this paper, we provide evidence for functional asymmetries in forward and backward connections that define hierarchical architectures in the brain. We exploit the fact that modulatory or nonlinear influences of one neuronal system on another (i.e., effective connectivity) entail coupling between different frequencies. Functional asymmetry in forward and backward connections was addressed by comparing dynamic causal models of MEG responses induced by visual processing of normal and scrambled faces. We compared models with and without nonlinear (between-frequency) coupling in both forward and backward connections. Bayesian model comparison indicated that the best model had nonlinear forward and backward connections. Using the best model we then quantified frequency-specific causal influences mediating observed spectral responses. We found a striking asymmetry between forward and backward connections; in which high (gamma) frequencies in higher cortical areas suppressed low (alpha) frequencies in lower areas. This suppression was significantly greater than the homologous coupling in the forward connections. Furthermore, exactly the asymmetry was observed when we examined face-selective coupling (i.e., coupling under faces minus scrambled faces). These results highlight the importance of nonlinear coupling among brain regions and point to a functional asymmetry between forward and backward connections in the human brain that is consistent with anatomical and physiological evidence from animal studies. This asymmetry is also consistent with functional architectures implied by theories of perceptual inference in the brain, based on hierarchical generative models.
doi_str_mv	10.1016/j.neuroimage.2008.12.041
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We exploit the fact that modulatory or nonlinear influences of one neuronal system on another (i.e., effective connectivity) entail coupling between different frequencies. Functional asymmetry in forward and backward connections was addressed by comparing dynamic causal models of MEG responses induced by visual processing of normal and scrambled faces. We compared models with and without nonlinear (between-frequency) coupling in both forward and backward connections. Bayesian model comparison indicated that the best model had nonlinear forward and backward connections. Using the best model we then quantified frequency-specific causal influences mediating observed spectral responses. We found a striking asymmetry between forward and backward connections; in which high (gamma) frequencies in higher cortical areas suppressed low (alpha) frequencies in lower areas. This suppression was significantly greater than the homologous coupling in the forward connections. Furthermore, exactly the asymmetry was observed when we examined face-selective coupling (i.e., coupling under faces minus scrambled faces). These results highlight the importance of nonlinear coupling among brain regions and point to a functional asymmetry between forward and backward connections in the human brain that is consistent with anatomical and physiological evidence from animal studies. 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Furthermore, exactly the asymmetry was observed when we examined face-selective coupling (i.e., coupling under faces minus scrambled faces). These results highlight the importance of nonlinear coupling among brain regions and point to a functional asymmetry between forward and backward connections in the human brain that is consistent with anatomical and physiological evidence from animal studies. This asymmetry is also consistent with functional architectures implied by theories of perceptual inference in the brain, based on hierarchical generative models.</abstract><cop>United States</cop><pub>Elsevier Inc</pub><pmid>19162203</pmid><doi>10.1016/j.neuroimage.2008.12.041</doi><tpages>10</tpages><oa>free_for_read</oa></addata></record>
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subjects	Anatomy & physiology Asymmetry Backward connection Brain Mapping - methods Brain research Computer Simulation Dynamic causal modelling Evoked Potentials, Visual - physiology Female Functional Laterality - physiology Humans Induced responses Magnetoencephalography - methods Male Models, Neurological Nerve Net - physiology Neuronal dynamics Nonlinear coupling Pattern Recognition, Visual - physiology Predictive coding Recurrent connection Reentrant dynamics Software Spectral responses Studies
title	Forward and backward connections in the brain: A DCM study of functional asymmetries
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