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EEG/MEG source reconstruction. Jean Daunizeau Vladimir Litvak Wellcome Trust Centre for Neuroimaging 9 / 05 / 2008. Outline. Introduction Forward problem Inverse problem Bayesian inference applied to the EEG/MEG inverse problem Conclusion. Outline. Introduction Forward problem
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EEG/MEGsource reconstruction Jean Daunizeau Vladimir Litvak Wellcome Trust Centre for Neuroimaging 9 / 05 / 2008
Outline Introduction Forward problem Inverse problem Bayesian inference applied to the EEG/MEG inverse problem Conclusion
Outline Introduction Forward problem Inverse problem Bayesian inference applied to the EEG/MEG inverse problem Conclusion
Introduction EEG/MEG and neuroimaging MRI MEG EEG invasivity weak strong OI EEG 20 spatial resolution (mm) MEG SPECT 15 OI PET 10 fMRI sEEG 5 MRI(a,d) 1 10 102 103 104 105 temporal resolution (ms)
Introduction forward/inverse problems : definitions Forward problem = modelling • Inverse problem = estimation of the model parameters
Outline Introduction Forward problem Inverse problem Bayesian inference applied to the EEG/MEG inverse problem Conclusion
Forward problem physical model of bioelectrical activity current dipole
Forward problem the general linear model noise dipoles gain matrix measurements Y = KJ + E1
Outline Introduction Forward problem Inverse problem Bayesian inference applied to the EEG/MEG inverse problem Conclusion
Inverse problem an ill-posed problem • Jacques Hadamard (1865-1963) • Existence • Unicity • Stability
Inverse problem an ill-posed problem • Jacques Hadamard (1865-1963) • Existence • Unicity • Stability
Inverse problem cortically distributed current dipoles
Inverse problem regularization Spatial and temporal constraints Adequacy with other modalities Data fit data fit constraint (regularization term) W = I : minimum norm method W =Δ : LORETA (maximum smoothness)
Outline Introduction Forward problem Inverse problem Bayesian inference applied to the EEG/MEG inverse problem Conclusion
Bayesian inference principle posterior pdf likelihood prior pdf model evidence
Bayesian inference hierarchical generative model sensor level source level Q : (known) variance components (λ,μ) : (unknown) hyperparameters
Bayesian inference hierarchical generative model λ1 λq J μ1 Y μq
Bayesian inference SPM implementations IID COH prior covariance structure ARD/GS generative model M
Outline Introduction Forward problem Inverse problem Bayesian inference applied to the EEG/MEG inverse problem Conclusion
Conclusion at the end of the day… Individual reconstructions in MRI template space L R SPM machinery RFX analysis p < 0.01 uncorrected R L
Conclusion summary • EEG/MEG source reconstruction: 1. forward problem; 2. inverse problem (ill-posed). • Prior information is mandatory to solve the inverse problem. • Bayesian inference is well suited for: 1. introducing such prior information… 2. … and estimating their weight wrt the data 3. providing us with a quantitative feedback on the adequacy of the model.
Many thanks to Karl Friston, Stephan Kiebel, Jeremie Mattout
Bayesian inference expectation-maximization (EM) average over J model associated with F generative model M
Bayesian inference expectation-maximization (EM) M-step E-step EM / ReML algorithm