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Neural Synchrony in Attention and Consciousness

Neural Synchrony in Attention and Consciousness. Lawrence M. Ward University of British Columbia. Collaborators: Sam Doesburg , Kei Kitajo, Alexa Roggeveen, Tony Herdman, Jessica Green, John J. McDonald. Funded by. Themes. Neural synchrony and its measurement

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Neural Synchrony in Attention and Consciousness

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  1. Neural Synchrony in Attention and Consciousness Lawrence M. Ward University of British Columbia Collaborators: Sam Doesburg, Kei Kitajo, Alexa Roggeveen, Tony Herdman, Jessica Green, John J. McDonald Funded by

  2. Themes • Neural synchrony and its measurement • Neural synchrony in attention: baton-passing in the cerebral cortex • Neural synchrony in consciousness: binocular rivalry and the thalamic dynamic core • Implications for LIDA

  3. Neural synchrony occurs when neural activity, spiking or dendritic currents, in disparate locations rises and falls in a fixed relationship Gray & Singer’s cats Ward et al’s humans Varela et al, 2001

  4. Spectral Power Spectral Power Spectral Power Theta 6 Hz Alpha 10 Hz Gamma 40 Hz 10 20 30 40 50 Frequency 10 20 30 40 50 Frequency 10 20 30 40 50 Frequency Spectral power in a given frequency range reflects local synchrony

  5. Roles of local neural synchrony • High fidelity neural communication • Perceptual/memorial/motor…. Binding: • Increase 30-70 Hz: amplify post-synaptic effect by increasing spike co-occurrence (Fries et al, 2001) • Decrease 6-15 Hz: increase post-synaptic impact by avoiding spike-frequency adaptation (Fries et al, 2001) Fries 2005

  6. Roles of global neural synchrony • Integration of neural activity through reciprocal (re-entrant) interactions between diverse brain regions (e.g., Varela et al, 2001) • Exchange of data (upward) and hypotheses/templates (downward); sensory/perceptual processing • Modulation of one region (e.g., hippocampus) by another (e.g., visual cortex) to store a memory (e.g., of a visual scene) • Modulation of one region (e.g., visual cortex) by another (e.g., prefrontal cortex) to enhance processing of attended information (e.g., a sign for a sushi bar) • Initiating an action in motor regions by computations from cognitive regions • Consciousness (?)

  7. EEG/MEG synchronization analysis: calculation of phase locking value (PLV) Step.1 Obtain SCD of filtered signals f(t) via bandpass filtering at chosen frequencies (µV) Fp1 Fp2 ● 10Hz Fz F7 F3 F4 F8 20Hz ● C3 Cz C4 T3 T4 (sec) 30Hz T5 P3 P4 T6 Pz C3 C3 40Hz O1 O1 O1 stimulus O2 ● Fz Fz stimulus (sec) Step.2 instantaneous phase and amplitude (sec) (sec) stimulus (sec) amplitude phase i.e. surface Laplacian, or MEG field strength, ^ SCD

  8. Step.3 Calculation of phase locking value (PLV) for each time point (sec) phase difference (5 trials) (sec) High PLV Low PLV PLV (50 trials) ⇒ complete synchronization:1 random phase difference:0 (sec) C3-O1 C3-Fz O1-Fz

  9. Step.4 standardization of PLV Standardized PLV To reduce the effect of volume conduction of stable sources and compare between electrode pairs at different distances (sec) Standardized PLV and surrogate PLV Step.5 statistical test using surrogate data (sec) significant PLV increase PLV (original) Median PLVsurrogate C3-O1 ±95 percentle PLVsurrogate (Hz) 100 99 98 3-97 2 1 0 sync 60 50 40 30 20 desync 10 (sec) -0.2 0 0.2 0.4 0.6 0.8 1 Note: Local and long-range PLVz must change together for spurious synchronization to be indicated (Doesburg,Ward, CC, 2007)

  10. Local alpha power associated with active suppression Local gamma power associated with active processing Alpha suppression necessary for gamma binding? Roles of long-range alpha and gamma synchrony? Coordination of local and long-range synchronization? Theta-modulated gamma synchrony Alpha, gamma and attention e.g., Klimesch, Jensen & Colgin, Palva & Palva, Ward

  11. P8 P7 + P7 P8 0 250 500 750 1000ms 0 250 500 750 1000ms Alpha/gamma local synchrony (power) indexes spatial attention orienting • Arrow cued box to attend to • Press button only if + in attended box, not if x nor if in unattended box • Cue-target SOA 1000-1200 ms • Cue onset at 0 ms in figures Doesburg, Roggeveen, Kitajo & Ward, 2007, Cerebral Cortex

  12. Long-distance gamma synchrony establishes focused attention network • At 250 ms (same as local power max gamma/min alpha) increase in global phase locking at diverse frequencies • Lateralized in gamma band: P7 (left) for right target, P8 (right) for left target (orienting?) • Increased synch in beta band also but not lateralized (readying?) • Desynch at 100 ms in gamma: erasing old network?

  13. Left cue 14 Hz Right cue MEG replication • Increased lateralized synchronization in high alpha band from ~400 ms post cue onset until end of epoch • Decreased synchronization side ipsilateral to cue • Synchronization in alpha band associated with maintenance of attentional focus at cued location Doesburg, Ward, 2007, Proceedings BIOMAG2006

  14. What is SAM beamformer? • Synthetic Aperture Magnetometry (Vrba & Robinson 2001, Methods) • Based on time/space covariance matrix of sensors • Achieves estimate of source power for each voxel in brain region from weighted linear combination of all measurements (where weights are selected to attenuate signals from all other voxels): • Optimal coefficients found by minimizing total power over time (computational tricks used in practice).

  15. MEG Replication • MEG filtered at 14 Hz • SAM beamformer sources in parietal (SPL?) and visual cortices (n=5) • PLV analysis applied to broadband source activity filtered from 6 Hz to 60 Hz • 14 Hz PLV shows lateralized increased synchrony similar to sensor analysis from 400-1000 ms post cue onset (right; n=2) • 40 Hz (gamma-band) PLV shows burst of lateralized increased synchrony at ~200-250 ms post cue onset • Theta rate gamma synch bursts at least for right parietal-occipital when attending left Doesburg,Herdman, Ward, 2007, Cognitive Neuroscience Society

  16. MEG replication • Beamformer sources projected to cortical surface (star=source in a sulcus so projection done by hand) • Lateralized increases and decreases in synchrony between parietal and occipital sources in alpha band from 400-800 ms post cue onset (here 800 ms and 14 Hz) • Occipital 14 Hz power replicates EEG data (blue bars, 800 ms) Doesburg, Herdman, Ward, 2007, Cognitive Neuroscience Society

  17. MEG Replication • Endogenous orienting: dorsal fronto- parietal (FEF, IPS, V1/V2) • We also found FEF sources but not consistent enough for PLV analysis • Not enough to activate relevant areas - must be synchronized to be functionally effective? Corbetta and Shulman (2002) Nat Rev Neurosci; Wright & Ward, 2008, Orienting of Attention

  18. EEG Replication: BESA beamformer sources from theta band signals Green & McDonald, 2008, PLoS Biology

  19. EEG analyses • BESA beamformer sources in theta band identified • Broadband activity of dipoles at peak voxels computed based on EEG recordings • Broadband signals filtered and analytic signal, PLV etc., computed between sources

  20. Right brain Left-neutral Right-neutral Left brain 350 ms post cue onset until target onset: maintains attention at cued location Lateralized increased synchronization in the alpha band Doesburg, Green, Ward & McDonald, in prep.

  21. Baton-passing in the cerebral cortex • Auditory cues and targets • Cue types: up or down glide for orient left or right (or vice versa), both for do not orient; each on 1/3 of trials • White noise targets (respond to all targets) for gap discrimination presented left (1/3 of trials) or right (1/3 of trials) at random regardless of cue type; probes (respond only if at cued location) presented on 1/3 of trials at random • BESA beamformer source analyses for theta-band signal Green,Doesburg, Ward & McDonald, submitted

  22. Theta-band BESA beamformer source activations • Baton-passing: • 1 Cue activates STG which in turn activates IPL and SPL • 2 IPL/SPL activate IFG • 3. IFG interprets cue • 4. IFG tells IPL/SPL where to orient • 5. IPL/SPL activate relevant STG and maintain activation until target Green,Doesburg, Ward & McDonald, submitted

  23. Interim Summary • Brain configured to attend to a specific location by • Confluence of burst of decreased local alpha power, increased local gamma power and increased long-range gamma synchrony at 250 ms post cue • Attention maintained at specific location by increased long-range alpha-band synchrony (at least parietal-visual) that coincides with decreased local alpha power • Information/control signals passed between brain regions by establishing and breaking synchronization in gamma band between those regions • Still not understood: mechanism of synchrony used (thalamic control?); nature of signals exchanged (control/compliance signals?); how reactivity of sensory cortex is increased by control signal; ……

  24. Binocular rivalry: window to awareness Stimuli Apparent locus of fused object Prisms Eyes Constant stimulation, involuntarily alternating experience Corresponding retinal areas

  25. Neural synchrony and consciousness Cosmelli et al, (2004) Waves of consciousness: Ongoing cortical patterns during binocular rivalry. NeuroImage, 23, 128-140

  26. Widespread 5 Hz synchrony associated with perception of the 5 Hz stimulus Face Rings Face Rings Face Rings Face Rings Face

  27. Synchrony of brain areas at 5 Hz for different subjects; note individual differences in both locations of active brain areas and in amount of synchrony between them.

  28. Corresponding retinal areas Binocular rivalry: window to awareness Constant stimulation, involuntarily alternating experience; subjects press one of two buttons to indicate which pattern they see, neither to indicate parts of both Stimuli Apparent locus of fused object Prisms Eyes

  29. Frequency (Hz) Button press at 0 Time (ms) Long-range theta-rate bursts of gamma-band synchrony in binocular rivalry of striped patterns 45Hz -450 -400 -350 -300 -250 -200 -150 -100 -50 0 50 100ms 7Hz -450 -400 -350 -300 -250 -200 -150 -100 -50 0 50 100ms Doesburg, Kitajo & Ward, 2005, NeuroReport

  30. R Frequency (Hz) L Time (ms – 0 indicates button press) BESA beamformer (280-220 ms pre-button-press, 36-46 Hz) applied to replication • Average PLVz over 8 active sources: R/L V1/V2, R sup occipital, R parietal, L temporal pole, L DLPF, R/L prefrontal • Bursts of gamma-band synchronization occur at theta rate (arrows) around button press in presence of persisting synchronization in theta band; also bursts of synchronization in beta band

  31. Left V1/V2 – Left DLPFC Right brain Left V1/V2 – Right parietal Left brain Right parietal – Right occipital 40-50 Hz alt synch/desynch 20-30 Hz synch 40-50 Hz synch 40-50 Hz desynch 30-40 Hz synch 30-40 Hz desynch surrogate level 0.025/0.025 Theta-modulated synchronization

  32. Dynamic core hypothesis • Neural correlate of conscious awareness is what Tononi & Edelman called the "dynamic core" • Large-scale (brain-wide, 200-msec time scale) • Coherent (statistically synchronous) activity • Millions of neurons involved

  33. Dynamic core hypothesis • DC simultaneously integrates activities of many brain areas (not all of them, a constantly changing subset) … • And also differentiates current conscious state from many other, possible conscious states. • My (radical) proposal: the thalamic dynamic core is the neural correlate of phenomenal awareness • Cortex computes, thalamus experiences • Human cortex, with more neurons and more cortico-cortical fibers per thalamic fiber computes much more complex contents than do, e.g., rat, dog, or chimp cortices; pace Paul Nunez • Cortical DC arises from synchronous activity in thalamus

  34. Thalamic dynamic core • Dynamic core and supporting binocular rivalry data (Tononi & Edelman, Varela group); neural synchrony is key • Lesions, neurosurgery, and anesthetic action point to thalamic “relay” nuclei as critical (Penfield, Alkire et al) • Anatomy and function of thalamus and cortex (Mumford) • We experience results (products) of computations, not the computations (processes) themselves (Lashley, Kinsbourne, Prinz, Rees, Koch, Baars)

  35. Lesions: Karen Ann Quinlan Karen Ann Quinlan’s Brain at Autopsy (see Kinney et al 1994) Drug/alcohol reaction; permanent vegetative state for 14 years Thalamus-massive loss Cortex-little loss

  36. Penfield’s neurosurgery and stimulation mapping M.M.’s cerebral cortex mapped via electrical stimulation by Penfield Patient M.M. treated for intractable epilepsy

  37. Neurosurgery and stimulation mapping • Penfield (The Mystery of the Mind, 1975): • The mechanisms of epilepsy and electrical stimulation mapping imply that “…there are two brain mechanisms that have strategically placed gray matter in the diencephalon …, viz. (a) the mind’s mechanism (or highest brain mechanism); and (b) the computer (or automatic sensory-motor mechanism).” (p. 40).

  38. Penfield’s “mind mechanism” Merker (2006, BBS): argued SC is locus of conscious analog simulation of world

  39. General anesthesia • Alkire et al (2000) Consciousness & Cognition: • Common brain loci and mode of action of different general anesthetics imply that the critical mechanism of general anesthesia is a hyperpolarization block of the thalamic relay nuclei neurons

  40. Common brain areas where halothane and isoflurane anesthesia significantly depresses activity; a. thalamus, b. midbrain reticular formation Alkire et al (2000) Consciousness & Cognition

  41. The thalamus • Synchronizes cortical oscillations • “Gateway” to cortex for major sensory systems (except smell) • Evolved along with the cerebral cortex; a “seventh layer” of cortex (but with different neuron type) • Each cortical area has an associated subnucleus of thalamus with massive cortico-thalamic projections and smaller thalamo-cortical projections; most thalamic subnuclei have no other inputs!

  42. Where is the thalamus? Thalamus Pineal body

  43. Gross Anatomy of some cortico-thalamic circuits

  44. Roles of the thalamus • Relay station and gateway (attentional engagement) to cortex for sensory systems • Synchronizes neural activity in remote cortical areas • Active blackboard that echoes back to cortex results of latest computations (Mumford) • Site of dynamic core of neural activity that gives rise to phenomenal experience(?): thalamic dynamic core

  45. We experience products… • Crovitz: maximum rate of consciously following strobe light = 4 to 5 Hz (250 to 200 msec per cycle) • Sternberg STM scanning: no awareness of process; 40 Hz (25 ms/item) scan? • LTM search & Retrieval: no awareness of memory search codes, only memories • Speech: not aware of composing utterences, phonemes, (co-)articulation, etc.

  46. Conclusions • Synchronous neural oscillations occur at several scales and in particular frequency bands • Local and global synchrony coordinate to establish an attentional network that enhances processing of attended stimuli • Neural synchrony in the thalamo-cortical circuits, particularly in the thalamus, establishes a dynamic core of brain activity that supports (is?) conscious awareness

  47. Implications for GWT/LIDA • Dynamic core is the GW • GW (broadcasting) established by synchronization between various active processing modules mediated by thalamic dynamic core • Transient networks of brain regions (processing coalitions) established by low frequency synchronization (carrier?), with high frequency synchronization establishing transient information exchange between processing areas in necessary temporal sequences (baton passing) • Perception/action cycle governed by several temporal interactions based on processing speeds and communication requirements vis a vis available oscillation frequencies.

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