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Line 40: The neural model in DCM for fMRI is a [[Taylor series\|Taylor approximation]] that captures the gross causal influences between brain regions and their change due to experimental inputs (see picture). This is coupled with a detailed biophysical model of the generation of the BOLD response and the MRI signal,<ref name="Friston 2003"/> based on the Balloon model of Buxton et al.,<ref>{{Cite journal\|last=Buxton\|first=Richard B.\|last2=Wong\|first2=Eric C.\|last3=Frank\|first3=Lawrence R.\|date=June 1998\|title=Dynamics of blood flow and oxygenation changes during brain activation: The balloon model\|journal=Magnetic Resonance in Medicine\|volume=39\|issue=6\|pages=855–864\|doi=10.1002/mrm.1910390602\|issn=0740-3194}}</ref> which was supplemented with a model of neurovascular coupling.<ref>{{Cite journal\|last=Friston\|first=K.J.\|last2=Mechelli\|first2=A.\|last3=Turner\|first3=R.\|last4=Price\|first4=C.J.\|date=October 2000\|title=Nonlinear Responses in fMRI: The Balloon Model, Volterra Kernels, and Other Hemodynamics\|journal=NeuroImage\|volume=12\|issue=4\|pages=466–477\|doi=10.1006/nimg.2000.0630\|pmid=10988040\|issn=1053-8119}}</ref><ref>{{Cite journal\|last=Stephan\|first=Klaas Enno\|last2=Weiskopf\|first2=Nikolaus\|last3=Drysdale\|first3=Peter M.\|last4=Robinson\|first4=Peter A.\|last5=Friston\|first5=Karl J.\|date=November 2007\|title=Comparing hemodynamic models with DCM\|journal=NeuroImage\|volume=38\|issue=3\|pages=387–401\|doi=10.1016/j.neuroimage.2007.07.040\|pmid=17884583\|pmc=2636182\|issn=1053-8119}}</ref> Additions to the neural model have included interactions between excitatory and inhibitory neural populations <ref>{{Cite journal\|last=Marreiros\|first=A.C.\|last2=Kiebel\|first2=S.J.\|last3=Friston\|first3=K.J.\|date=January 2008\|title=Dynamic causal modelling for fMRI: A two-state model\|journal=NeuroImage\|volume=39\|issue=1\|pages=269–278\|doi=10.1016/j.neuroimage.2007.08.019\|pmid=17936017\|issn=1053-8119\|citeseerx=10.1.1.160.1281}}</ref> and non-linear influences of neural populations on the coupling between other populations.<ref name="Stephan 2008">{{Cite journal\|last=Stephan\|first=Klaas Enno\|last2=Kasper\|first2=Lars\|last3=Harrison\|first3=Lee M.\|last4=Daunizeau\|first4=Jean\|last5=den Ouden\|first5=Hanneke E.M.\|last6=Breakspear\|first6=Michael\|last7=Friston\|first7=Karl J.\|date=August 2008\|title=Nonlinear dynamic causal models for fMRI\|journal=NeuroImage\|volume=42\|issue=2\|pages=649–662\|doi=10.1016/j.neuroimage.2008.04.262\|issn=1053-8119\|pmc=2636907\|pmid=18565765}}</ref> DCM for resting state studies was first introduced in Stochastic DCM,<ref>{{Cite journal\|date=2011-09-15\|title=Generalised filtering and stochastic DCM for fMRI\|url=~~https://www.sciencedirect.com/science/article/pii/S1053811911001406~~ \|journal=NeuroImage\|volume=58\|issue=2\|pages=442–457\|doi=10.1016/j.neuroimage.2011.01.085\|pmid=21310247\|issn=1053-8119\|last1=Li\|first1=Baojuan\|last2=Daunizeau\|first2=Jean\|last3=Stephan\|first3=Klaas E\|last4=Penny\|first4=Will\|last5=Hu\|first5=Dewen\|last6=Friston\|first6=Karl}}</ref> which estimates both neural fluctuations and connectivity parameters in the time ___domain, using [[Generalized filtering\|Generalized Filtering]]. A more efficient scheme for resting state data was subsequently introduced which operates in the frequency ___domain, called DCM for Cross-Spectral Density (CSD).<ref>{{Cite journal\|last=Friston\|first=Karl J.\|last2=Kahan\|first2=Joshua\|last3=Biswal\|first3=Bharat\|last4=Razi\|first4=Adeel\|date=July 2014\|title=A DCM for resting state fMRI\|journal=NeuroImage\|volume=94\|pages=396–407\|doi=10.1016/j.neuroimage.2013.12.009\|pmid=24345387\|pmc=4073651\|issn=1053-8119}}</ref><ref>{{Cite journal\|last=Razi\|first=Adeel\|last2=Kahan\|first2=Joshua\|last3=Rees\|first3=Geraint\|last4=Friston\|first4=Karl J.\|date=February 2015\|title=Construct validation of a DCM for resting state fMRI\|journal=NeuroImage\|volume=106\|pages=1–14\|doi=10.1016/j.neuroimage.2014.11.027\|issn=1053-8119\|pmc=4295921\|pmid=25463471}}</ref> Both of these can be applied to large-scale brain networks by constraining the connectivity parameters based on the functional connectivity.<ref>{{Cite journal\|last=Seghier\|first=Mohamed L.\|last2=Friston\|first2=Karl J.\|date=March 2013\|title=Network discovery with large DCMs\|journal=NeuroImage\|volume=68\|pages=181–191\|doi=10.1016/j.neuroimage.2012.12.005\|issn=1053-8119\|pmc=3566585\|pmid=23246991}}</ref><ref name="Razi 2017">{{Cite journal\|last=Razi\|first=Adeel\|last2=Seghier\|first2=Mohamed L.\|last3=Zhou\|first3=Yuan\|last4=McColgan\|first4=Peter\|last5=Zeidman\|first5=Peter\|last6=Park\|first6=Hae-Jeong\|last7=Sporns\|first7=Olaf\|last8=Rees\|first8=Geraint\|last9=Friston\|first9=Karl J.\|date=October 2017\|title=Large-scale DCMs for resting-state fMRI\|journal=Network Neuroscience\|volume=1\|issue=3\|pages=222–241\|doi=10.1162/netn_a_00015\|issn=2472-1751\|pmc=5796644\|pmid=29400357}}</ref> Another recent development for resting state analysis is Regression DCM<ref>{{Cite journal\|last=Frässle\|first=Stefan\|last2=Lomakina\|first2=Ekaterina I.\|last3=Razi\|first3=Adeel\|last4=Friston\|first4=Karl J.\|last5=Buhmann\|first5=Joachim M.\|last6=Stephan\|first6=Klaas E.\|date=July 2017\|title=Regression DCM for fMRI\|journal=NeuroImage\|volume=155\|pages=406–421\|doi=10.1016/j.neuroimage.2017.02.090\|pmid=28259780\|issn=1053-8119}}</ref> implemented in the Tapas software collection (see [[#Software implementations\|Software implementations]]). Regression DCM operates in the frequency ___domain, but linearizes the model under certain simplifications, such as having a fixed (canonical) haemodynamic response function. The enables rapid estimation of large-scale brain networks. [[File:DCM for ERP and CMC.svg\|thumb\|Models of the cortical column used in EEG/MEG/LFP analysis. Self-connections on each population are present but not shown for clarity. Left: DCM for ERP. Right: Canonical Microcircuit (CMC). 1=spiny stellate cells (layer IV), 2=inhibitory interneurons, 3=(deep) pyramidal cells and 4=superficial pyramidal cells.]]

Dynamic causal modeling: Difference between revisions