Thalamocortical oscillations
Maxim Bazhenov, The Salk Institute, San Diego, California
Igor Timofeev, Laval University, Quebec, Canada
Oscillatory activity is an emerging property of the thalamocortical system. The various oscillatory rhythms generated in
the thalamocortical system are mediated by two types of mechanisms:
intrinsic mechanisms, which depend on the interplay between specific intrinsic currents.
extrinsic or network mechanisms, which require the interaction of excitatory and inhibitory neurons within a
population.
Intrinsic and network mechanisms can work alone (e.g., thalamic delta oscillations depend on the intrinsic properties
of thalamic relay cells, cortical slow oscillation depends on network properties) or in combination (e.g., spindles
depend on the interaction between thalamic relay and reticular neurons as well as on their intrinsic properties). The
patterns and the dominant frequencies of thalamocortical oscillations depend on the functional state of the brain.
Oscillations
Normal thalamocortical oscillatory activities include
infra-slow: 0.02-0.1 Hz,
slow: 0.1-15 Hz (present mainly during slow-wave sleep or anesthesia), which are further divided on
slow oscillation (0.2-1 Hz),
delta (1-4 Hz),
spindle (7-15Hz),
theta, which is generated in the limbic system and described elsewhere,
fast: 20-60 Hz,
ultra-fast: 100-600 Hz.
The fast and ultra-fast activities may be present in various states of vigilance including sleep and frequently coexist
with slower rhythms (e.g., fast gamma oscillations may be found during depolarized phases of slow sleep oscillations).
Spontaneous brain rhythms during different states of vigilance may lead to increased responsiveness and plastic
changes in the strength of connections among neurons, thus affecting information flow in the thalamocortical system.
Each type of oscillation is generated by a particular set of intrinsic neuronal currents, synaptic interactions, and
extracellular factors. Oscillations may also be generated in a population of non-pacemaker neurons coupled through
gap junctions. Only "normal" thalamocortical activity is reviewed in this article; paroxysmal oscillations (such as
seizures) are described elsewhere.
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Figure 1: Cortical slow sleep oscillation in vivo (modified from Timofeev and Bazhenov 2005).
Infra-slow oscillation
This type of oscillatory activity has a period within the range of tens of seconds to a minute (Aladjalova, 1957). Very
little is known about the underlying mechanisms of these oscillations but at least some of the factors responsible for
their generation could depend on non-neuronal dynamics. Infra-slow activities likely have a cortical origin given that
they can be recorded from small regions of neocortex devoid of their inputs by means of a surgical undercut
(neocortical slabs; Aladjalova, 1962).
Functional role. Indirect evidence suggests that infra-slow oscillations synchronize faster activities, modulate
cortical excitability, and contribute to the aggravation of epileptic activity during sleep (Vanhatalo et al., 2004).
Slow oscillation
During slow-wave sleep and some types of anesthesia the dominant activity pattern is slow oscillation, with frequency
0.3 - 1 Hz (Steriade et al., 1993a; Steriade et al., 2001). The following observations point to an intracortical origin for
this rhythm:
It survives extensive thalamic lesions in vivo (Steriade et al., 1993b) and exists in cortical in vitro preparations
(Sanchez-Vives and McCormick, 2000).
It is absent in the thalamus of decorticated cats (Timofeev and Steriade, 1996).
During slow
oscillation the
entire cortical
network
alternates
between silent
(Hyperpolarizing, or Down) and active (Depolarizing, or Up) states, each lasting 0.2-1 sec. At EEG level, the slow
oscillation appears as periodic alterations of positive and negative waves (indicated by + and – signs in the figure).
During EEG depth-positivity, cortical neurons remain in hyperpolarized, silent state.
During EEG depth-negativity cortical neurons move to active states, reveal barrages of synaptic events and fire
action potentials.
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Figure 2: Spatiotemporal properties of SWS oscillations simulated in 1-D computer model
(modified from Bazhenov et al., 2002).
It was shown that during slow-wave sleep neocortical and thalamic neurons display phase relations that are restricted
to narrow time windows (Contreras and Steriade, 1995). Recent studies suggest that the onsets of silent states are
synchronized even better than the onsets of activity, and showed no latency bias for any location or cell type
(Volgushev et al., 2006).
Intracellular studies on anesthetized and non-anesthetized cats have shown that the hyperpolarizing (DOWN) phase of
the slow oscillation is associated with disfacilitation, a temporal absence of synaptic activity in all cortical and
thalamic neurons (Timofeev et al. 1996; Timofeev et al. 2001a). Even a moderate spontaneous hyperpolarization of
thalamic relay neurons during depth-positive EEG waves is sufficient to displace them from firing threshold, thereby
affecting transmission of information toward the cerebral cortex (Timofeev et al. 1996). Responses to peripheral
sensory stimuli still may reach the cerebral cortex during sleep or anesthesia, but the precision of cortical network to
respond to peripheral volley during hyperpolarized (DOWN) periods is lost. The spike timing is critical in cortical
information processing and therefore a minimal time interval of stable relay cells activity is required to achieve
conscious perceptions (Libet et al. 1967). Thus, the conscious perception is impaired during sleep and anesthesia,
likely, because the lost of precision in the sensory information transfer from periphery to the cerebral cortex.
At least two distinct mechanisms for the origin of slow cortical oscillations were proposed based on what causes the
transition to the active (UP) state of the slow-sleep oscillation:
Spontaneous miniature synaptic activities, or minis (Fatt and Katz, 1952), which are caused by the spike-
independent release of transmitter vesicles and regulated at the level of single synapses. Occasional summation of
the miniature EPSPs during the hyperpolarized (DOWN) phase of slow-sleep oscillations activates the persistent
sodium current and depolarizes the membrane of cortical pyramidal cells, which is sufficient for spike generation
(Timofeev et al., 2000; Bazhenov et al., 2002). This triggers the active phase, which propagates through the entire
network and is maintained by synaptic activities and the persistent sodium current.
Spontaneous
activity of layer V
cortical neurons
(Sanchez-Vives and
McCormick, 2000;
Compte et al.,
2003). It was shown,
using a cortical slice
preparation, that in
relatively high
concentrations (3.5
mM) of extracellular
K+, cortical slices
could oscillate in the
frequency range of slow sleep oscillations (Sanchez-Vives and McCormick, 2000). This activity was usually initiated
in layer V and propagated over the whole slice. A slight increase in extracellular K+ may depolarize some neurons to
the firing threshold. In these conditions the relatively large amplitude EPSPs, but not minis, might recruit
postsynaptic neurons into active states.
The total synaptic conductance progressively diminishes toward the end of active state in vivo (Contreras et al., 1996b).
This suggests that active state termination is accompanied by a progressive run-down of synaptic activity. It supports
either intrinsic mechanisms (build-up of a slow K+ conductance in single cells, reducing their firing) or synaptic
mechanisms (build-up of a depressed state of excitatory synapses) for active state termination (Bazhenov et al., 2002).
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Either of these mechanisms may potentially explain refractoriness of the active states of slow-wave sleep found in
slices (Sanchez and McCormick 2000). By contrast, in vivo, the waking state is associated with prolong depolarizing
states, eventually lasting for the duration of the waking state. Thus, the refractoriness of an active state seems to be
present in in vitro preparation only and could be attributed to the property of reduced network. Recent in vivo study
revealed surprisingly high synchrony of active states termination (Volgushev et al., 2006) that implies the existence of
a network mechanism which switches activity to silence.
A period and regularity of slow-wave sleep oscillations depend on the network size. While down states are relatively
short in vivo (few hundreds msec), their duration can be tens of seconds in relatively small cortical slabs (Timofeev et
al., 2000). It decreases approaching intact cortex in larger isolated gyrus preparations. This dependence on the
network size was predicted by minis-based model of slow-wave sleep oscillation (Timofeev et al., 2000).
Delta oscillation
Field potential recordings from neocortex in human and animal models during sleep reveal the presence of delta
oscillations (1-4 Hz). The delta oscillation likely has two different components, one of which originates in the neocortex
and the other in the thalamus.
Cortical delta activity. Both surgical removal of the thalamus and recordings from neocortical slabs in chronic
conditions result in the significant enhancement of neocortical delta activity (Ball et al. 1977; Villablanca and
Salinas-Zeballos 1972). Little is known about the cellular mechanisms mediating cortical delta oscillation. One of
the hypotheses suggests that cortical delta could be driven by the discharge of intrinsically bursting neurons
(Amzica and Steriade, 1998).
Thalamic delta (1-4 Hz) is a well known example of rhythmic activity generated intrinsically by thalamic relay
neurons as a result of the interplay between their low-threshold Ca2+ current (IT) and hyperpolarization activated
cation current (Ih). As such, the delta oscillation may be observed during deep sleep when thalamic relay neurons
are hyperpolarized sufficiently to deinactivate IT (McCormick and Pape, 1990). The mechanism of single cell delta
activity is the following: a long-lasting hyperpolarization of thalamic relay neuron leads to slow Ih activation that
depolarizes the membrane potential and triggers rebound burst, mediated by IT, which was deinactivated by the
hyperpolarization. Both Ih (because of its voltage dependency) and IT (because of its transient nature) inactivate
during burst, so membrane potential becomes hyperpolarized after burst termination. This afterhyperpolarization
starts next cycle of oscillations.
Periods of delta-like oscillation in thalamocortical neuron in decorticated cats can start from subtle fluctuations of the
membrane potential. The amplitude of such activity increases and decreases without changes in frequency.
Synchrony between different thalamic relay neurons during delta activity has not been found in decorticated cats
(Timofeev and Steriade 1996). Thus, it is unlikely that thalamic delta activity could play a leading role in the initiation
and maintenance of cortical delta rhythm. However, the presence of a corticothalamic feedback in intact-cortex
animals could synchronize thalamic burst-firing at delta frequency and generate field potentials.
At a certain level of leak current (Ileak), the ‘window’ component of IT in thalamocortical neurons, may create
oscillations similar in frequency to the intrinsic thalamic delta oscillation (Williams et al., 1997).
Functional role of slow and delta oscillations. Slow wave sleep may be essential for memory consolidation and
memory formation (Gais et al., 2000; Stickgold et al., 2000; Maquet, 2001; Huber et al., 2004). It has been proposed
that synaptic plasticity associated with slow and delta oscillations could contribute to the consolidation of memory
traces acquired during wakefulness (Steriade and Timofeev, 2003). Based on the analysis of multiple extracellular
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Figure 3: Waxing and waning delta activity (2.2 Hz) in LP thalamo-cortical neuron in decorticated cats
(Ketamine-xylazine anesthesia; modified from Timofeev and Bazhenov 2005).
Figure 4: Spindle oscillations in the model circuit of 2 thalamic
reticular and 2 relay neurons (modified from Timofeev and
Bazhenov 2005).
recordings
of slow
oscillations
during
natural
sleep, it was
suggested
that fast
oscillations
during
active states
of slow-
wave sleeps
could reflect
recalled
events experienced previously; these events are "imprinted" in the network via synchronized network events that
appear as slow-wave complexes in the EEG (Destexhe et al., 1997).
Sleep spindle oscillations
Sleep spindle oscillations consist of waxing-and-waning field potentials at 7-14 Hz, which last 1-3 seconds and recur
every 5-15 seconds. In vivo, spindle oscillations are typically observed during the early stages of sleep or during active
phases of slow-wave sleep oscillations.
In vivo, in vitro, and in silico studies suggest that the minimal substrate accounting for spindle oscillations consists in
the interaction between thalamic reticular and relay cells (Steriade and Deschénes, 1984; Steriade et al., 1985; von
Krosigk et al., 1993). Burst firing of reticular thalamic neurons induces inhibitory postsynaptic potentials in
thalamocortical neurons. This deinactivates low-threshold Ca2+ current (IT), inducing burst firing in thalamocortical
neurons which, in turn, excite reticular thalamic neurons allowing the cycle to start again. Spontaneous spindle
oscillations are synchronized over large cortical areas during natural sleep and barbiturate anesthesia. After complete
ipsilateral decortication, however, the long-range synchronization of thalamic spindles changes into disorganized
patterns with low spatiotemporal coherence (Contreras et al., 1996).
During spindle oscillations thalamocortical neurons
do not fire every cycle of oscillations but intermit
bursting with subthreshold oscillations. A simplest
circuit model sufficient to generate this type of
activity includes 2 reciprocally coupled reticular cells
and 2 relay neurons providing excitation to and
receiving inhibition from reticular neurons (Destexhe
et al., 1996).
More complex models suggest the presence of at least
three phases with different underlying mechanisms
that contribute to the spindle generation.
During the early phase of spindles, the reticular
nucleus single-handedly drives the spindle
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Figure 5: Cellular basis of spindle activity. In vivo recordings. Three phases of a spindle
sequence. Dual intracellular recording of cortical (area 4) and TC (VL) neurons (modified
from Timofeev and Bazhenov 2005).
oscillation via intrinsic
mechanisms (Steriade
et al., 1985). Several
different mechanisms
contributing to spindle
generation in the
isolated reticular
nucleus were proposed:
In the network
simulations,
thalamic reticular
neurons organized
with "dense
proximal
connectivity"
generate spindle-
like oscillations
when are slightly
depolarized (-60 to
-70 mV) (Destexhe
et al. 1994).
Self-sustained
spindle-like activity
is generated in the model of isolated reticular nucleus when postsynaptic potentials between thalamic reticular
cells reversed and became depolarizing at the relatively hyperpolarized membrane potentials that occur during
sleep (Bazhenov et al. 1999).
Gap junctions between thalamic reticular cells (Landisman et al., 2002) play an important role in the generation
and synchronization of spindling activities in the thalamus (Fuentealba et al., 2004).
The second component of spindles, on the other hand, primarily develops as a result of interactions between
reticular and relay neurons (Destexhe et al., 1996; Bazhenov et al., 2000). Additionally, cortical firing contributes to
spindle synchronization via cortico-thalamic neural firing, thereby imposing simultaneous excitation of reticular
and relay neurons (Contreras et al., 1996). The role of cortical firing for spindle synchronization was studied in
thalamocortical network models (Destexhe, et al., 1998, 1999). It was predicted that, in order to generate large-
scale coherent oscillations, the cortex had to recruit the thalamus primarily through the RE nucleus. This result
explains why propagating waves of spindle activity are found in vitro but not in vivo.
The waning phase occurs as a result of network desynchronization (Timofeev et al., 2001) and of Ca2+ induced
cAMP up-regulation of the hyperpolarization activated cation current, Ih, in relay cells (Bal and McCormick, 1996).
Ca2+ mediated Ih activation tends to depolarize TC neurons preventing their rebound spike-bursts. This effect of Ih
up-regulation was first predicted in the models (Destexhe et al., 1993) and later confirmed by in vitro experiments
(Luthi & McCormick, 1998). When this up-regulation is prevented, spindles in slices do not wax-wane anymore but
remain sustained (Luthi and McCormick, 1998). Ca2+ mediated Ih up-regulation can also explain refractoriness of
spindle oscillations that was demonstrated in vitro (Kim et al., J Neurophysiol 1995) and in vivo (Contreras et al., J
Neurosci 1997). The network desynchronization facilitates spindle termination in vivo and may have a few sources.
The first is related to generation of rebound bursts in thalamic relay neurons with different delays from the
onset of IPSP. The asynchronous burst firing of relay neurons will keep the membrane potential of thalamic
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reticular cells at relatively depolarized steady level, thus preventing the de-inactivation of IT and diminishing
the probability of burst firing.
Barrages of EPSPs from prethalamic relay stations (e.g. cerebellum) may produce a small but long-lasting
depolarization, decrease input resistance of relay neurons and impair their bursting ability (Timofeev and
Steriade, 1997) that could also desynchronize the thalamocortical network and disrupt the spindles.
Because the trains of prethalamic EPSPs would occur only randomly, the most important source of spindle
desynchronization, leading to decrease in their duration, is probably long-lasting spike-trains from neocortical
neurons.
Functional role. Recent studies show that sleep related spindle oscillations are essential for memory formation (Gais
et al., 2000) and demonstrate short- and middle term synaptic plasticity (reviewed by Steriade and Timofeev 2003).
Spindling may activate the protein kinase A molecular "gate", thus opening the door for gene expression (Sejnowski
and Destexhe, 2000) and allowing long-term changes to take place following subsequent inputs.
Beta-gamma oscillation
The waking state of the brain is characterized by the predominance of frequencies in the beta (15-30 Hz) and gamma
(30-80 Hz) ranges (Bressler, 1990; Freeman, 1991). The fast rhythms are also synchronized between neighboring
cortical sites during some forms of anesthesia, natural slow-wave, and REM sleep (Steriade et al., 1996a; Steriade et al.,
1996b), when consciousness is either suspended or bizarre. During slow-wave sleep the fast rhythms follow the onset
of depth-negative EEG wave.
Gamma activity can exist in transient and
persistent forms:
Experimentally, transient (hundreds
of milliseconds) gamma oscillations
can be induced by tetanic stimulation
of the hippocampus (Traub et al.,
1996a). In this case, both fast spiking
interneurons and pyramidal cells fire
at the population frequency.
Persistent gamma activity is found in
CA3 (Fisahn et al., 1998) and
neocortex (Buhl et al., 1998); this
form of gamma can be induced by
bath application of carbachol or
kainate and the oscillations last
minutes to hours. During persistent
gamma activity interneurons fire on
every cycle or every two cycles and
pyramidal cells fire at lower
frequencies.
Finally, it was found that GABAergic
interactions in isolated interneuron
networks may lead to network oscillation
in the gamma frequency range (Traub et
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Figure 6: Gamma oscillation is an important component of sleep wave slow
oscillation. Upper panel, a fragment of EEG trace recorded from the depth of
area 5. Slow oscillation, spindles and gamma activities are indicated. Below,
Fast Fourier Transformation of a fragment shown above (modified from
Timofeev and Bazhenov, 2005).
al., 1996b; Wang and Buzsaki, 1996). In
both model and experiments it was
shown that the frequency of these
oscillations depends on the conductance
and decay time of GABAA currents
(Traub et al., 1996b). Large-scale network
simulations revealed that coherent gamma range oscillations may appear through occasional increases in spiking
synchrony within local groups of cortical neurons (Rulkov et al., 2004).
Origin of gamma oscillation. At least two non-exclusive basic mechanisms have been proposed to explain the
origin of beta-gamma oscillations. One of them emphasizes extracortical and another one intracortical origin of these
activities:
A transient feed-forward synchronization to high-frequency peripheral (retinal, lemniscal or cerebelar) oscillations
(Castelo-Branco et al. 1998; Timofeev and Steriade 1997) could impose the peripheral fast activities onto the
thalamocortical system.
Intracortical mechanisms themselves include several possibilities. The first one is based on the intrinsic property of
fast rhythmic-bursting (FRB) neurons to fire fast spike-bursts at frequencies 20-60 Hz. These neurons were first
described as fast pyramidal tract neurons from somatosensory cortex (Calvin and Sypert 1976), later they were
found in layer II-III visual cortex (small pyramids called “chattering cells” (Gray and McCormick 1996)). The
second intracortical mechanism of gamma activity generation depends on the activity of inhibitory interneurons
and was described both in vitro and computational models (Borgers and Kopell 2003; Lytton and Sejnowski 1991;
Traub et al. 1996a; Traub et al. 1997; Traub et al. 1998; Traub et al. 1999). Transitions between gamma and beta
oscillations were simulated by alternating excitatory coupling between pyramidal neurons and by change in K+-
conductances (Kopell et al. 2000; Traub et al. 1999). Lastly, role for gap junctions between axons of pyramidal cells
in generating gamma oscillation was proposed (Traub et al. 2000). In this model spontaneous spiking activity in
pyramidal cell axons was critical for persistent gamma oscillations. Transition from asynchronous network state to
persistent gamma oscillations triggered by increase of pyramidal neurons excitability was later described in
simplified network model with all-to-all connectivity (Borgers et al. 2005).
Gamma oscillations induced by visual stimuli can be synchronized over distances a few millimeters with near zero
phase lag (Gray et al., 1989). Such precise synchronization in gamma frequency range was found between primary and
associational visual cortexes (Engel et al., 1991; Frien et al., 1994) and between contralateral and parietal cortical areas
(Desmedt and Tomberg, 1994). Synchronized gamma band activities were described in the visual cortex of
anesthetized cats (Eckhorn et al., 1988; Gray et al., 1989) and awake monkeys (Kreiter and Singer, 1992). A number of
experiments suggest that gamma-range synchronization in visual cortex may be restricted to few millimeters even with
large coherent stimuli (large objects). Still the local features of these stimuli are perceived as coherently bound (Frien
and Eckhorn, 2000). Propagating waves of gamma activity were described in primary visual cortex (Gabriel and
Eckhorn, 2003) and the phase continuity of such gamma-waves (as opposite to strict long-rage synchrony) was
proposed to be a basis of spatial feature binding across entire objects (Eckhorn et al., 2004).
Functional role. Gamma activity is associated with attentiveness (Rougeul-Buser et al., 1975; Bouyer et al., 1981),
focused arousal (Sheer, 1989), sensory perception (Gray et al., 1989), movement (Murthy and Fetz, 1992; Pfurtscheller
and Neuper, 1992) and prediction (Womelsdorf et al., 2006). It has been proposed that synchronization in the gamma
frequency range is related to cognitive processing and important for temporal binding of sensory stimuli (Singer and
Gray, 1995).
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Ripples
Ultra-fast oscillations (>100 Hz), termed ripples, were described in CA1 hippocampal area and perirhinal cortex, where
they were associated with bursts of sharp potentials during anesthesia, behavioral immobility, and natural sleep
(Ylinen et al., 1995).
In the neocortex, ultra-fast oscillations (>200 Hz, up to 600 Hz) have been found
in sensory-evoked potentials in rat barrel cortex (Jones and Barth, 1999; Jones et al., 2000),
during high-voltage spike-and-wave patterns in rat (Kandel and Buzsáki, 1997). Neocortical networks seems to be
sufficient to produce ripples as it was demonstrated in isolated cortical preparations (Grenier et al., 2001).
In addition to active inhibition (Ylinen et al., 1995; Grenier et al., 2001), the electrical coupling mediated by gap
junctions contributes to the ripple synchronization (Draguhn et al., 1998; Grenier et al., 2003a). The electrical coupling
may occur between axons of principal cells (Schmidt et al., 2001) or via a network of inhibitory interneurons (Galarreta
and Hestrin, 1999; Gibson et al., 1999). Since ripples are recorded also in glial cells, the electrical coupling between
glial cells could also play a role in the synchronization of ripples (Grenier et al., 2003a). The field potentials increase
neuronal excitability, and by a positive feedback loop they could be also involved in the generation of neocortical
ripples (Grenier et al., 2003b).
Functional role. Cortical ripples are generated during large amplitude spontaneous or evoked field potential
deflections. These ample changes in the field potential are associated with synchronous activity of many neurons. This
suggests that ripples may "alarm" the brain network about the presence of a large firing neuronal constellation. The
danger of such a focal synchronous excitation of a neuronal pool is that it may overcome certain threshold of
excitability, leading to the onset of seizures (Grenier et al., 2003b; Grenier et al., 2003a).
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Internal references
Eugene M. Izhikevich (2006) Bursting. Scholarpedia, 1(3):1300.
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Roger D. Traub (2006) Fast oscillations. Scholarpedia, 1(12):1764.
Jeff Moehlis, Kresimir Josic, Eric T. Shea-Brown (2006) Periodic orbit. Scholarpedia, 1(7):1358.
Philip Holmes and Eric T. Shea-Brown (2006) Stability. Scholarpedia, 1(10):1838.
S. Murray Sherman (2006) Thalamus. Scholarpedia, 1(9):1583.
External links
Bazhenov's webpage (http://www.snl.salk.edu/~bazhenov/)
Timofeev's webpage (http://w3.fmed.ulaval.ca/dev/timofeevgroup/accueil/)
See also
Brain Rhythms, Cortex, Fast Oscillations, Thalamus
Sponsored by: Eugene M. Izhikevich, Editor-in-Chief of Scholarpedia, the peer-reviewed open-access encyclopedia
Reviewed by (http://www.scholarpedia.org/w/index.php?title=Thalamocortical_oscillations&oldid=2143) :
Anonymous
Reviewed by (http://www.scholarpedia.org/w/index.php?title=Thalamocortical_oscillations&oldid=2143) : Alain
Destexhe, CNRS, France
Accepted on: 2006-06-13 23:11:37 GMT (http://www.scholarpedia.org/w/index.php?
title=Thalamocortical_oscillations&oldid=2143)
Categories: Network dynamics Computational neuroscience Neuroscience
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