1. Behavior modulates effective connectivity between cortex and striatum
- Author
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Masanori Shimono, Lucas L. Dwiel, Leslie M. Grasse, Alexander Nakhnikian, George V. Rebec, and John M. Beggs
- Subjects
Central Nervous System ,Anatomy and Physiology ,lcsh:Medicine ,Striatum ,Local field potential ,Synaptic Transmission ,Basal Ganglia ,Neurological Signaling ,Behavioral Neuroscience ,0302 clinical medicine ,Cortex (anatomy) ,Basal ganglia ,Neural Pathways ,Molecular Cell Biology ,lcsh:Science ,Cerebral Cortex ,Neurons ,0303 health sciences ,Multidisciplinary ,Behavior, Animal ,Signaling in Selected Disciplines ,Single Neuron Function ,medicine.anatomical_structure ,Cerebral cortex ,Cellular Types ,Sense of coherence ,Research Article ,Signal Transduction ,Sense of Coherence ,Neurophysiology ,Biology ,Neurotransmission ,Neurological System ,03 medical and health sciences ,medicine ,Animals ,Animal behavior ,030304 developmental biology ,Computational Neuroscience ,Motor Systems ,Behavior ,lcsh:R ,Computational Biology ,Corpus Striatum ,Rats ,Neuroanatomy ,Cellular Neuroscience ,lcsh:Q ,Neuroscience ,030217 neurology & neurosurgery - Abstract
It has been notoriously difficult to understand interactions in the basal ganglia because of multiple recurrent loops. Another complication is that activity there is strongly dependent on behavior, suggesting that directional interactions, or effective connections, can dynamically change. A simplifying approach would be to examine just the direct, monosynaptic projections from cortex to striatum and contrast this with the polysynaptic feedback connections from striatum to cortex. Previous work by others on effective connectivity in this pathway indicated that activity in cortex could be used to predict activity in striatum, but that striatal activity could not predict cortical activity. However, this work was conducted in anesthetized or seizing animals, making it impossible to know how free behavior might influence effective connectivity. To address this issue, we applied Granger causality to local field potential signals from cortex and striatum in freely behaving rats. Consistent with previous results, we found that effective connectivity was largely unidirectional, from cortex to striatum, during anesthetized and resting states. Interestingly, we found that effective connectivity became bidirectional during free behaviors. These results are the first to our knowledge to show that striatal influence on cortex can be as strong as cortical influence on striatum. In addition, these findings highlight how behavioral states can affect basal ganglia interactions. Finally, we suggest that this approach may be useful for studies of Parkinson's or Huntington's diseases, in which effective connectivity may change during movement.
- Published
- 2014