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Chapter 11: Cognition and neuroanatomy

Chapter 11: Cognition and neuroanatomy. Three general questions. How is the brain anatomically organized? How is the mind functionally organized? How is the functional organization of the kind reflected in the anatomical organization of the brain? The localization question

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Chapter 11: Cognition and neuroanatomy

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  1. Chapter 11:Cognition and neuroanatomy

  2. Three general questions How is the brain anatomically organized? How is the mind functionally organized? How is the functional organization of the kind reflected in the anatomical organization of the brain? The localization question The causation question

  3. Studying neural/mental architecture Three different frameworks for thinking about large-scale neural organization Anatomical connectivity Functional connectivity Effective connectivity

  4. Principle of segregation • Cerebral cortex is divided into segregated areas with distinct neuronal populations • Brodman used staining techniques to identify cortical areas • types of cell they contain • density of cells • Classification made on purely anatomical grounds – not a functional classification

  5. Anatomical connectivity Given by the anatomical connections between different cortical structures Can be mapped using Diffusion Tensor Imaging Using the diffusion of water molecules to track axonal connections between cortical regions The most reliable data are derived from tracing studies (invasive)

  6. Modeling anatomical connectivity • Network diagrams of cortical regions in non-human primates • Wiring diagrams derived from cortical connectivity matrices • Large-scale cortical networks can be analyzed graph-theoretically Seem to have small-world connectivity patterns

  7. Connectivity matrix and wiring diagram for macaque visual cortex (based on Felleman and Van Essen 1991)

  8. Analyzing networks as graphs Vertices = neural regions Edges = connections between regions Path = set of edges connecting two vertices

  9. Interesting network properties Characteristic path length The typical shortest path between any two vertices Clustering coefficient The extent to which the edges in the neighbourhood of each vertex are connected to each other e.g. cliquishness of a social network (the extent to which each individual’s acquaintances are acquainted with each other)

  10. Types of graph Annalysis of connection matrices from studies of cat and macaque cortex have shown that some brain networks have small world properties

  11. Studying neural/mental architecture Three different frameworks for thinking about large-scale neural organization Anatomical connectivity Functional connectivity Effective connectivity

  12. Functional connectivity Standardly defined in terms of statistical correlations between spatially remote neurophysiological events Frequently used to identify task-specific brain networks Researchers have claimed that some functional networks are impaired in particular disorders

  13. Example Functional connectivity data can be derived from resting state fMRI studies Has been used to support idea of default mode “network” including posterior cingulate cortex and ventral anterior cingulate cortex vACC = blue PCC = red

  14. Standard analysis of fMRI data STEP 1 Model correlation between BOLD response in individual volume elements (voxels) and some experimentally controlled variable STEP 2 Create a statistical parametric map (SPM) that shows which voxels have time-series correlated with a certain task component

  15. Implicit modeling assumptions The connections between elements of the system (e.g. specific voxels) are not taken into account in creating the SPM The analysis treats experimental variables as inputs that act directly on system elements What the SPM identifies are system elements that are correlated in the same way with the task This tells us nothing about how those system elements are related to each other

  16. Limits of functional connectivity “Patterns of functional connectivity are statistical signatures of hidden causal processes occurring within and among specific and time-varying subsets of neurons and brain regions. The identification of which subsets are currently causally engaged in a given task requires the inclusion of and reference to a structural model in order to access effective connectivity patterns.” Sporns and Tononi 2007

  17. Studying neural/mental architecture Three different frameworks for thinking about large-scale neural organization Anatomical connectivity Functional connectivity Effective connectivity

  18. Effective connectivity “The influence one neural system exerts on another” (Friston and Büchel 2003) “The functional connectivity between two brain regions simply tells us how correlated their activities are. Their effective connectivity, on the other hand, is the explicit influence that one region’s activity has on the activity of the second along the direct anatomical pathway linking the two.” (Horwitz, Friston, Taylor 2000)

  19. Models of effective connectivity Information about effective connectivity is not standardly derived from imaging data Rather, assumptions about effective connectivity are used to interpret imaging data These assumptions are derived from anatomical connectivity data

  20. Two ways of thinking about effective connectivity (1) A quasi-anatomical notion, corresponding to the existence of direct cortical pathways between cortical regions (2) An information-processing notion, tracking the flow of information through a brain network

  21. Differences In the quasi-anatomical sense, effective connectivity essentially provides a set of parameters for a systems analysis In the information-processing sense, we need something that will allow us: • to identify a series of discrete information-processing stages • to correlate information-processing stages with neural areas (possibly distributed)

  22. Effective connecticity in the information-processing sense fMRI tells us very little about how information-processing takes place • No consensus on what type of neural activity correlates with the BOLD signal • No distinction between excitatory and inhibitory connections Progress may come from calibrating fMRI with other tools for studying information-processing tools (neurophysiological, molecular, biological, computational. . .)

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