Method and system for three dimensional tomography of activity and connectivity of brain and heart electromagnetic waves generators
First Claim
1. A method for three dimensional tomography of activity and connectivity of brain electromagnetic waves generators, said method including the steps of:
- a) positioning a set of electrodes and magnetic sensors to detect and record brain electromagnetic signals representing physiological activity in the form of an electroencephalogram (EEG) and a magnetoencephalogram (MEG), and measuring exact positions of the electrodes and sensors with respect to a reference coordinate system determined by certain anatomical landmarks of a head of an experimental subject;
b) amplifying the electromagnetic signals detected at each electrode and sensor by connecting an amplifier to each electrode and sensor;
c) obtaining on-line digital spatio-temporal signals, consisting of said EEG and MEG, by connecting analog-digital converters to each amplifier, and digitizing all data as it is gathered;
d) determining a parametric description for an anatomy of the experimental subject'"'"'s head to obtain a descriptive parametric geometry;
e) using said descriptive parametric geometry for constructing a head phantom with volume conductor properties of the experimental subject'"'"'s head;
f) performing EEG and MEG measurements on said head phantom due to known current dipoles located in a corresponding neural tissue volume, for determining a linear operator which transforms original EEG and MEG measurements into equivalent infinite homogeneous medium measurements (anatomical deconvolution);
g) using said descriptive parametric geometry for determining anatomical and functional constraints for localizations, orientations, activities, and connectivities of the brain electromagnetic waves generators (generator constraints);
h) digitally pre-processing the EEG and MEG for artifact and noise elimination, and for separation of EEG and MEG samples related to said fiducial markers, for obtaining event related components (ERCs);
i) statistically analyzing said ERCs for determining the most adequate numerical description of spatio-temporal properties in terms of sufficient statistics;
j) computing activities and connectivities of the ERCs generators, based on a static solution to an inverse electromagnetic problem, under said generator constraints, using sufficient statistics for the ERCs transformed to an infinite homogeneous medium by means of said anatomical deconvolution;
k) in case said generator constraints do not allow a unique solution to the inverse problem, decreasing a number of ERCs generators sufficiently to allow for proper identifiability of the inverse problem;
l) statistically evaluating a goodness of fit of the static solution, taking into account an existence of colored spatial and temporal noise, and including statistical hypotheses for testing an absence of activity and connectivity of the ERCs generators; and
m) visually displaying three dimensional and two dimensional images corresponding to the localizations, orientations, activities, and connectivities of the ERCs generators.
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Abstract
A method and system for the localization and characterization of the generators of human brain electromagnetic physiological activity includes a set of bioelectromagnetic amplifiers, sensorial stimulators, and a computer based system for signal analog to digital conversion and recording. Sufficient statistics, including higher order statistical moments, for event related components are computed from the recorded signals, either in the time, frequency, or time-frequency domain, retaining stationary, non-stationary, linear, and non-linear information. The localizations, orientations, activities, and connectivities of the generators are obtained by solving the inverse problem using sufficient statistics under anatomical and functional constraints. Realistic head geometry and conductivity profiles are used to transform the measurements into infinite homogeneous medium measurements, through use of ananatomical deconvolution operator, thus simplifying optimally inverse solution computations. Goodness of fit tests for the inverse solution are provided. Generator characteristics are visually displayed in the form of three and two dimensional head images, and optionally include probability scaled images obtained by comparing estimated generator characteristics with those of a normal population sampled and stored in a normative data base.
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Citations
35 Claims
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1. A method for three dimensional tomography of activity and connectivity of brain electromagnetic waves generators, said method including the steps of:
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a) positioning a set of electrodes and magnetic sensors to detect and record brain electromagnetic signals representing physiological activity in the form of an electroencephalogram (EEG) and a magnetoencephalogram (MEG), and measuring exact positions of the electrodes and sensors with respect to a reference coordinate system determined by certain anatomical landmarks of a head of an experimental subject; b) amplifying the electromagnetic signals detected at each electrode and sensor by connecting an amplifier to each electrode and sensor; c) obtaining on-line digital spatio-temporal signals, consisting of said EEG and MEG, by connecting analog-digital converters to each amplifier, and digitizing all data as it is gathered; d) determining a parametric description for an anatomy of the experimental subject'"'"'s head to obtain a descriptive parametric geometry; e) using said descriptive parametric geometry for constructing a head phantom with volume conductor properties of the experimental subject'"'"'s head; f) performing EEG and MEG measurements on said head phantom due to known current dipoles located in a corresponding neural tissue volume, for determining a linear operator which transforms original EEG and MEG measurements into equivalent infinite homogeneous medium measurements (anatomical deconvolution); g) using said descriptive parametric geometry for determining anatomical and functional constraints for localizations, orientations, activities, and connectivities of the brain electromagnetic waves generators (generator constraints); h) digitally pre-processing the EEG and MEG for artifact and noise elimination, and for separation of EEG and MEG samples related to said fiducial markers, for obtaining event related components (ERCs); i) statistically analyzing said ERCs for determining the most adequate numerical description of spatio-temporal properties in terms of sufficient statistics; j) computing activities and connectivities of the ERCs generators, based on a static solution to an inverse electromagnetic problem, under said generator constraints, using sufficient statistics for the ERCs transformed to an infinite homogeneous medium by means of said anatomical deconvolution; k) in case said generator constraints do not allow a unique solution to the inverse problem, decreasing a number of ERCs generators sufficiently to allow for proper identifiability of the inverse problem; l) statistically evaluating a goodness of fit of the static solution, taking into account an existence of colored spatial and temporal noise, and including statistical hypotheses for testing an absence of activity and connectivity of the ERCs generators; and m) visually displaying three dimensional and two dimensional images corresponding to the localizations, orientations, activities, and connectivities of the ERCs generators. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31)
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19. A method as claimed in 18 wherein multivariate metrics corresponding to comparison with norms are also displayed by superposition.
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32. A system for the three dimensional tomography of activity and connectivity of brain electromagnetic waves generators comprising:
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a) A set of electrodes and magnetic sensors adapted to be positioned to detect brain electromagnetic signals representative of physiological activity in the form of an electroencephalogram (EEG) and a magnetoencephalogram (MEG), and means for measuring exact positions of the electrodes and sensors with respect to a reference coordinate system determined by certain anatomical landmarks of a head of an experimental subject. b) Means for amplification of said electromagnetic signals detected at each electrode and sensor; c) Means for obtaining on-line digital spatio-temporal signals consisting of said EEG and MEG; d) Means for the presentation of visual, auditory, and somato-sensorial stimulation to the experimental subject during EEG and MEG recording; e) Means for recording vocal or movement responses produced by the experimental subject during EEG and MEG recording; f) A central digital computer subsystem, comprising; means for reading the experimental subject'"'"'s image data, and means for computing and storing a descriptive parametric geometry, an anatomical deconvolution operator, and generator constraints; means for constructing a head phantom based on the descriptive parametric geometry, and means for the implantation of current dipoles in a corresponding neural tissue volume of the phantom; means controlling experiments including means for causing stimulation of the experimental subject, recording of the subject'"'"'s responses, detection and recording of special EEG and MEG events, and simultaneous recording of said electromagnetic signals; means for pre-processing the recorded electromagnetic signals for artifact and noise elimination; means for estimating event related components (ERCs) means for computing sufficient statistics of the ERCs; means for estimating an additive non-white spatio-temporal noise due to diffuse generators; means for performing tests of hypothesis about the goodness of fit of an estimated inverse solution; means for estimating localizations, orientations, activities, and connectivities of generators of the ERCs; means for comparing characteristics of the ERCs generators with a normative data base and means for computing multivariate metrics; means for the visual display of ERCs generators characteristics and of the multivariate metrics. - View Dependent Claims (33, 34, 35)
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Specification