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The ElectroEncephaloGramm

The ElectroEncephaloGramm. Cognitive Neuropsychology January 16th, 2001. Outline. History of the EEG Biological Foundations of the EEG Measuring the EEG Analyzing the EEG Applications of the EEG. The History of the EEG. 1875 Caton records brain potentials from cortex

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The ElectroEncephaloGramm

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  1. The ElectroEncephaloGramm Cognitive Neuropsychology January 16th, 2001

  2. Outline • History of the EEG • Biological Foundations of the EEG • Measuring the EEG • Analyzing the EEG • Applications of the EEG

  3. The History of the EEG 1875 Caton records brain potentials from cortex 1883 Marxow discovers evoked potentials 1929 Berger records electrical activity from the skull 1936 Gray Walter finds abnormal activity with tumors 1957 The toposcope (imaging of electrical brain activity) 1980 Color brain mapping (quantitative EEG)

  4. Hans Berger – EEG Pioneer In 1929, Hans Berger • Recorded brain activity from the closed skull • Reportet brain activity changes according to the functional state of the brain • Sleep • Hypnothesis • Pathological states (epilepsy) First EEG recorded by Berger

  5. Gray Walter – Brain Imaging In 1957, Gray Walter • Makes recordings with large numbers of electrodes • Visualizes brain activity with the toposcope • Shows that brain rhythms change according to the mental task demanded The toposcope by Gray Walter

  6. Outline • History of the EEG • Biological Foundations of the EEG • Brain Rhythms • Information Processing in the Neocortex • Summation Potentials • Measuring the EEG • Analyzing the EEG • Applications of the EEG

  7. EEG in the States of Vigilance Frequency Ranges Beta: 14 – 30 Hz Alpha: 8 – 13 Hz Theta: 5 – 7 Hz Delta: 1 – 4 Hz

  8. Alpha Rhythm Frequency: 8 – 13 Hz Amplitude: 5 – 100 microVolt Location: Occipital, Parietal State of Mind: Alert Restfulness Alpha blockade occurs when new stimulus is processed Source: oscillating thalamic pacemaker neurons

  9. Beta Rhythm Frequency: 14 – 30 Hz Amplitude: 2 – 20 microVolt Location: Frontal State of Mind: Mental Activity Reflects specific information processing between cortex and thalamus

  10. Theta Rhythm Frequency: 5 – 7 Hz Amplitude: 5 – 100 microVolt Location: Frontal, Temporal State of Mind: Sleepiness Nucleus reticularis slows oscillating thalamic neurons Therefore diminished sensory throughput to cortex

  11. Delta Rhythm Frequency: 1 – 4 Hz Amplitude: 20 – 200 microVolt Location: Variable StateofMind: Deep sleep Oscillations in Thalamus and deep cortical layers Usually inibited by ARAS (Ascending Reticular Activation System)

  12. Outline • History of the EEG • Biological Foundations of the EEG • Brain Rhythms • Information Processing in the Neocortex • Summation Potentials • Measuring the EEG • Analyzing the EEG • Applications of the EEG

  13. Cortex Structure The neocortex consists of six distinct layers I Molecular layer II External granular layer III External pyramidal layer IV Internal granular layer V Internal pyramidal layer VI Polymorphic or multiform layer

  14. Cortex Structure Layer I I Molecular layer Molekularschicht • Apical dendrites of pyramidal cells • Axons of stellate cells (parallel to cortex surface) • Few cell bodies • Local (intracortical) information exchange

  15. Cortex Structure Layer II/ III II External granular layer Äußere Körnerschicht III External pyramidal layer Äußere Pyramidenschicht • Stellate & Small Pyramidal Cells • Intercortical Information Exchange • Afferent fibers from other cortical areals enter the layers • Association (to the same hemisphere) and commisural (to the other hemisphere) fibers leave cortex (reentry at destination)

  16. Cortex Structure Layer IV IV Internal granular layer Innere Körnerschicht • Stellate cells • Afferents from Thalamus • Numerous and complex synaptic connections • Relay of thalamic information to other cortical layers • Information input layer (well developed in sensory cortex)

  17. Cortex Structure Layer V V Internal pyramidal layerInnere Pyramidenschicht • Large pyramidal cells • Projection fibers to subthalamic brain areas • Basal ganglia • Brain stem • Spinal chord • Information output layer (well developed in motor cortex)

  18. Cortex Structure Layer VI VI Multiform layerSpindelzellschicht • Neurons of various shapes (mainly fusiform) • Adjacent to white matter • Corticothalamical information exchang

  19. Cytoarchitecture Neocortex Input layers: II/IV (granular) Output layers: III/V (pyramidal) 1: heterotypical agranular cortex • Mainly pyramidal layers (output) • Primary motor cortex 5: heterotypical granular cortex • Mainly granular layers (input) • Primary sensory cortex 2-4: homotypical cortex • Association areas • All layers developed

  20. Outline • History of the EEG • Biological Foundations of the EEG • Brain Rhythms • Information Processing in the Neocortex • Summation Potentials • Measuring the EEG • Analyzing the EEG • Applications of the EEG

  21. Summation Potentials The EEG measures • not action potentials • not summation of action potentials • but summation of graded Post Synaptic Potentials (PSPs) (only pyramidal cells: dipoles between soma and apical dendrites)

  22. Outline • History of the EEG • Biological Foundations of the EEG • Measuring the EEG – The international 10/20 system • Analyzing the EEG • Applications of the EEG

  23. The International 10/20 System

  24. Terminology: 10/20 System Nasion: point between the forehead and the skull Inion: bump at the back of the skull Location: Frontal, Temporal, Parietal, Occipital, Centralz for the central line Numbers: Even numbers (2,4,6) right hemisphere, odd (1,3,5) left

  25. EEG channels Channel: Recording from a pair of electrodes (here with a common reference: A1 – left ear) Multichannel EEG recording: up to 40 channels recorded in parallel

  26. Participants with Electrodes EEG in clinical diagnostics EEG in scientific research

  27. Outline • History of the EEG • Biological Foundations of the EEG • Measuring the EEG • Analyzing the EEG • Event Related Potentials • Spectral Analysis • Topographical Mapping • Applications of the EEG

  28. Averaging of trials following a stimulus Noise reduction: The noise decreases by the squareroot of the number of trials Far field potentials require up to 1000 measurements Assumption: no habituation occurs (participants don‘t get used to stimulation) Event Related Potentials

  29. N400: Semantic mismatch marker P600: Syntactic mismatch marker Example Sentences: Correct (Baseline): The cats won't eat the food Mary gives them. Semantic mismatch: The cats won't bake the food Mary gives them. Syntactic mismatch: The cats won't eating the food Mary gives them. Semantic and syntactic mismatch: The cats won't baking the food Mary gives them. Language specific ERP Components

  30. EEG Spectral Analysis • Fast Fourier Transform seperates spontaneous EEG signal to component frequencies and amplitudes • Restriction: high frequency resolution demands long (in the range of seconds) analysis windows

  31. Topographical Maps Topographical maps plot EEG data on a map of the brain. Data is interpolated between electrodes. Usual data plotted: • ERP maps • potential changes • Spectral maps • frequency changes • Statistical maps • comparison of measurements

  32. Outline • History of the EEG • Biological Foundations of the EEG • Measuring the EEG • Analyzing the EEG • Applications of the EEGWeiss, Rappelsberger (2000) Long-range EEG synchronization during word encoding correlates with successful memory performance

  33. A set of 19 gold-cup electrodes was glued to the scalp according to the international 10/20-placement system. Data were recorded against the average signals of both earlobes ((A1 + A2) /2) which turned out to be the most suitable reference for coherence analysis. The electrooculogram (EOG) was recorded from two electrodes located at the left later outer cantus and above the right eye. Electrode impedance did not exceed 8 kΩ and signal bandpass was 0.3 –35 Hz. Data were simultaneously monitored by an ink-writer system and digitally sampled at 256 Hz to be stored on hard disk. After recording, the EEG data were screened for artefacts (eye blinks, horizontal and vertical eye movements, muscle activities) by visual inspection on a monitor and on paper. These two methods allowed a very reliable exclusion of the artefacts. Impedance did not exceed 8 kΩ and signal bandpass was 0.3 –35 Hz. Data were simultaneously monitored by an ink-writer system and digitally sampled at 256 Hz to be stored on hard disk. After recording, the EEG data were screened for artefacts (eye blinks, horizontal and vertical eye movements, muscle activities) by visual inspection on a monitor and on paper. These two methods allowed a very reliable exclusion of the artefacts. Methods Section 1

  34. EEG was recorded during memorization of the different lists of nouns and during four interspersed resting periods with eyes open lasting one minute each. According to the behavioral results epochs of recalled and of not recalled ones were selected for further analysis. The beginning of each noun was marked by a trigger and the following 1 s EEG epoch was Fourier-transformed. All 1-s artefact-free epochs of the resting EEG were also Fourier-transformed. On the average, per subject, 16  4 epochs for recalled nouns auditorily presented were analysed, 28  5 for not recalled nouns auditorily presented, 7  2 for recalled nuons visually presented, 14  4 for not recalled nouns visually presented and 198  45 for the resting EEG. Then averaged power spectra and cross-power spectra were computed for each subject. According to the 19 elctrode positions, 19 averaged power spectra were computed. Cross power spectra were computed. Cross power spectra were computed between all possible pairs, which yielded 171 values per frequency. Methods Section 2

  35. To reduce the large data set the adjacent spectral values vere averaged to obtain broadband parameters for the following frequency bands: delta-1 (1 – 2 Hz), delta-2 (3 – 4 Hz), theta (5 – 7 Hz), alpha-1 (8 – 10 Hz), alpha-2 (11 – 12 Hz), and beta-1 (13 – 18 Hz). Finally, 19 mean amplitudes (square root of power) per frequency band were computed and the normalization of the 171 cross-power spectra yielded 171 coherence values per frequency band. Grand mean values were obtained by averaging amplitude and coherence values across subjects. Since it has been demonstrated that, especially, lower EEG frequencies were correlated with memory processes, we predominantely investigated lower frequency bands in the present study. The division into distinct, well-selected frequency bands was made since several studies point at their different functional role during cognitive processing. Methods Section 3

  36. Coherence Map A coherence map plots differences in coherence between recalled and not recalled nouns.

  37. Results • Overall increase of coherence for recalled vs. not recalled nouns • Long range synchronization of frontal and temporal/parietal neuronal assemblies increases for recalled nouns.

  38. Outline • History of the EEG • Biological Foundations of the EEG • Measuring the EEG • Analyzing the EEG • Applications of the EEG Thank you for your attention!

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