Cortical thickness gradients in structural hierarchies

MRI, enabling in vivo analysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous measures used—the thickness of the cortex—shows abnormalities in a number of diseases and conditions, but the functional and biological corre...

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Published in	NeuroImage (Orlando, Fla.) Vol. 111; pp. 241 - 250
Main Authors	Wagstyl, Konrad, Ronan, Lisa, Goodyer, Ian M., Fletcher, Paul C.
Format	Journal Article
Language	English
Published	United States Elsevier Inc 01.05.2015 Elsevier Limited Academic Press
Subjects	Adult Animals Auditory Cortex - anatomy & histology Auditory Cortex - cytology Human subjects Humans Hypotheses Macaca Magnetic Resonance Imaging - methods Neurosciences Somatosensory Cortex - anatomy & histology Somatosensory Cortex - cytology Studies Visual Cortex - anatomy & histology Visual Cortex - cytology
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Abstract	MRI, enabling in vivo analysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous measures used—the thickness of the cortex—shows abnormalities in a number of diseases and conditions, but the functional and biological correlates of such alterations are unclear. If the functional connotations of structural MRI measures are to be understood, we must strive to clarify the relationship between measures such as cortical thickness and their cytoarchitectural determinants. We therefore sought to determine whether patterns of cortical thickness mirror a key motif of the cortex, specifically its structural hierarchical organisation. We delineated three sensory hierarchies (visual, somatosensory and auditory) in two species—macaque and human—and explored whether cortical thickness was correlated with specific cytoarchitectural characteristics. Importantly, we controlled for cortical folding which impacts upon thickness and may obscure regional differences. Our results suggest that an easily measurable macroscopic brain parameter, namely, cortical thickness, is systematically related to cytoarchitecture and to the structural hierarchical organisation of the cortex. We argue that the measurement of cortical thickness gradients may become an important way to develop our understanding of brain structure–function relationships. The identification of alterations in such gradients may complement the observation of regionally localised cortical thickness changes in our understanding of normal development and neuropsychiatric illnesses. [Display omitted] •Cortical thickness mirrors organisation of sensory hierarchies and cytoarchitecture.•Patterns replicated in macaque and humans.•Hierarchical level is strongly predicted by a gradient of cortical thickness.•Thickness gradient matches functional hierarchy in human visual cortex.
AbstractList	MRI, enabling in vivo analysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous measures used-the thickness of the cortex-shows abnormalities in a number of diseases and conditions, but the functional and biological correlates of such alterations are unclear. If the functional connotations of structural MRI measures are to be understood, we must strive to clarify the relationship between measures such as cortical thickness and their cytoarchitectural determinants. We therefore sought to determine whether patterns of cortical thickness mirror a key motif of the cortex, specifically its structural hierarchical organisation. We delineated three sensory hierarchies (visual, somatosensory and auditory) in two species-macaque and human-and explored whether cortical thickness was correlated with specific cytoarchitectural characteristics. Importantly, we controlled for cortical folding which impacts upon thickness and may obscure regional differences. Our results suggest that an easily measurable macroscopic brain parameter, namely, cortical thickness, is systematically related to cytoarchitecture and to the structural hierarchical organisation of the cortex. We argue that the measurement of cortical thickness gradients may become an important way to develop our understanding of brain structure-function relationships. The identification of alterations in such gradients may complement the observation of regionally localised cortical thickness changes in our understanding of normal development and neuropsychiatric illnesses. MRI, enabling in vivo analysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous measures used—the thickness of the cortex—shows abnormalities in a number of diseases and conditions, but the functional and biological correlates of such alterations are unclear. If the functional connotations of structural MRI measures are to be understood, we must strive to clarify the relationship between measures such as cortical thickness and their cytoarchitectural determinants. We therefore sought to determine whether patterns of cortical thickness mirror a key motif of the cortex, specifically its structural hierarchical organisation. We delineated three sensory hierarchies (visual, somatosensory and auditory) in two species—macaque and human—and explored whether cortical thickness was correlated with specific cytoarchitectural characteristics. Importantly, we controlled for cortical folding which impacts upon thickness and may obscure regional differences. Our results suggest that an easily measurable macroscopic brain parameter, namely, cortical thickness, is systematically related to cytoarchitecture and to the structural hierarchical organisation of the cortex. We argue that the measurement of cortical thickness gradients may become an important way to develop our understanding of brain structure–function relationships. The identification of alterations in such gradients may complement the observation of regionally localised cortical thickness changes in our understanding of normal development and neuropsychiatric illnesses. • Cortical thickness mirrors organisation of sensory hierarchies and cytoarchitecture. • Patterns replicated in macaque and humans. • Hierarchical level is strongly predicted by a gradient of cortical thickness. • Thickness gradient matches functional hierarchy in human visual cortex. MRI, enabling in vivo analysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous measures used—the thickness of the cortex—shows abnormalities in a number of diseases and conditions, but the functional and biological correlates of such alterations are unclear. If the functional connotations of structural MRI measures are to be understood, we must strive to clarify the relationship between measures such as cortical thickness and their cytoarchitectural determinants. We therefore sought to determine whether patterns of cortical thickness mirror a key motif of the cortex, specifically its structural hierarchical organisation. We delineated three sensory hierarchies (visual, somatosensory and auditory) in two species—macaque and human—and explored whether cortical thickness was correlated with specific cytoarchitectural characteristics. Importantly, we controlled for cortical folding which impacts upon thickness and may obscure regional differences. Our results suggest that an easily measurable macroscopic brain parameter, namely, cortical thickness, is systematically related to cytoarchitecture and to the structural hierarchical organisation of the cortex. We argue that the measurement of cortical thickness gradients may become an important way to develop our understanding of brain structure–function relationships. The identification of alterations in such gradients may complement the observation of regionally localised cortical thickness changes in our understanding of normal development and neuropsychiatric illnesses. [Display omitted] •Cortical thickness mirrors organisation of sensory hierarchies and cytoarchitecture.•Patterns replicated in macaque and humans.•Hierarchical level is strongly predicted by a gradient of cortical thickness.•Thickness gradient matches functional hierarchy in human visual cortex. MRI, enablingin vivoanalysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous measures used--the thickness of the cortex--shows abnormalities in a number of diseases and conditions, but the functional and biological correlates of such alterations are unclear. If the functional connotations of structural MRI measures are to be understood, we must strive to clarify the relationship between measures such as cortical thickness and their cytoarchitectural determinants. We therefore sought to determine whether patterns of cortical thickness mirror a key motif of the cortex, specifically its structural hierarchical organisation. We delineated three sensory hierarchies (visual, somatosensory and auditory) in two species--macaque and human--and explored whether cortical thickness was correlated with specific cytoarchitectural characteristics. Importantly, we controlled for cortical folding which impacts upon thickness and may obscure regional differences. Our results suggest that an easily measurable macroscopic brain parameter, namely, cortical thickness, is systematically related to cytoarchitecture and to the structural hierarchical organisation of the cortex. We argue that the measurement of cortical thickness gradients may become an important way to develop our understanding of brain structure-function relationships. The identification of alterations in such gradients may complement the observation of regionally localised cortical thickness changes in our understanding of normal development and neuropsychiatric illnesses.
Author	Ronan, Lisa Goodyer, Ian M. Wagstyl, Konrad Fletcher, Paul C.
AuthorAffiliation	c Cambridge and Peterborough Foundation Trust, UK a Brain Mapping Unit, Department of Psychiatry, University of Cambridge, Cambridge, CB2 3EB, UK b Developmental and Life-course Research Group, Department of Psychiatry, University of Cambridge, Cambridge, CB2 8AD, UK
AuthorAffiliation_xml	– name: c Cambridge and Peterborough Foundation Trust, UK – name: b Developmental and Life-course Research Group, Department of Psychiatry, University of Cambridge, Cambridge, CB2 8AD, UK – name: a Brain Mapping Unit, Department of Psychiatry, University of Cambridge, Cambridge, CB2 3EB, UK
Author_xml	– sequence: 1 givenname: Konrad surname: Wagstyl fullname: Wagstyl, Konrad email: kw350@cam.ac.uk organization: Brain Mapping Unit, Department of Psychiatry, University of Cambridge, Cambridge, CB2 3EB, UK – sequence: 2 givenname: Lisa surname: Ronan fullname: Ronan, Lisa organization: Brain Mapping Unit, Department of Psychiatry, University of Cambridge, Cambridge, CB2 3EB, UK – sequence: 3 givenname: Ian M. surname: Goodyer fullname: Goodyer, Ian M. organization: Developmental and Life-course Research Group, Department of Psychiatry, University of Cambridge, Cambridge, CB2 8AD, UK – sequence: 4 givenname: Paul C. surname: Fletcher fullname: Fletcher, Paul C. organization: Brain Mapping Unit, Department of Psychiatry, University of Cambridge, Cambridge, CB2 3EB, UK
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Copyright	2015 The Authors Copyright © 2015. Published by Elsevier Inc. Copyright Elsevier Limited May 1, 2015 2015 The Authors. Published by Elsevier Inc. 2015
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Snippet	MRI, enabling in vivo analysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous... MRI, enablingin vivoanalysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous... MRI, enabling in vivo analysis of cortical morphology, offers a powerful tool in the assessment of brain development and pathology. One of the most ubiquitous...
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SubjectTerms	Adult Animals Auditory Cortex - anatomy & histology Auditory Cortex - cytology Human subjects Humans Hypotheses Macaca Magnetic Resonance Imaging - methods Neurosciences Somatosensory Cortex - anatomy & histology Somatosensory Cortex - cytology Studies Visual Cortex - anatomy & histology Visual Cortex - cytology
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