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The Journal of Neuroscience, May 27, 2009, 29(21):6851-6859; doi:10.1523/JNEUROSCI.5983-08.2009
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Behavioral/Systems/Cognitive
Stability of Thalamocortical Synaptic Transmission across Awake Brain States
Carl R. Stoelzel, Yulia Bereshpolova, andHarvey A. Swadlow Department of Psychology, The University of Connecticut, Storrs, Connecticut 06269
Correspondence should be addressed to Harvey A. Swadlow, Department of Psychology, University of Connecticut, 406 Babbidge Road, Box U-1020, Storrs, CT 06269
Sensory cortical neurons are highly sensitive to brain state, with many neurons showing changes in spatial and/or temporal response properties and some neurons becoming virtually unresponsive when subjects are not alert. Although some of these changes are undoubtedly attributable to state-related filtering at the thalamic level, another likely source of such effects is the thalamocortical (TC) synapse, where activation of nicotinic receptors on TC terminals have been shown to enhance synaptic transmission in vitro. However, monosynaptic TC synaptic transmission has not been directly examined during different states of alertness. Here, in awake rabbits that shifted between alert and non-alert EEG states, we examined the monosynaptic TC responses and short-term synaptic dynamics generated by spontaneous impulses of single visual and somatosensory TC neurons. We did this using spike-triggered current source-density analysis, an approach that enables assessment of monosynaptic extracellular currents generated in different cortical layers by impulses of single TC afferents. Spontaneous firing rates of TC neurons were higher, and burst rates were much lower in the alert state. However, we found no state-related changes in the amplitude of monosynaptic TC responses when TC spikes with similar preceding interspike interval were compared. Moreover, the relationship between the preceding interspike interval of the TC spike and postsynaptic response amplitude was not influenced by state. These data indicate that TC synaptic transmission and dynamics are highly conserved across different states of alertness and that observed state-related changes in receptive field properties that occur at the cortical level result from other mechanisms.
Received Dec. 16, 2008; revised Jan. 23, 2009; accepted April 23, 2009.
Correspondence should be addressed to Harvey A. Swadlow, Department of Psychology, University of Connecticut, 406 Babbidge Road, Box U-1020, Storrs, CT 06269
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