TY - JOUR
T1 - Cortical Membrane Potential Signature of Optimal States for Sensory Signal Detection
AU - McGinley, Matthew J.
AU - David, Stephen V.
AU - McCormick, David A.
N1 - Funding Information:
We thank Heather Read and Jamie Mazer for help with in vivo auditory approaches; Daeyeol Lee with behavior and feedback on the manuscript; Ethan Mohns regarding hippocampal rhythms; Bart Massi with wavelet analysis; Peter O’Brien and Tony Desimone for technical assistance; and John Christian, Lauren Croda, John Harringa, Keturah James, Saifullah Khan, Stephanie Madlener, Chelsea Mahoney, Donald Rodriguez, Megan Sanford, Paul Steffan, Gary Sulioti, and Danielle Young for help training animals. Supported by NIH 5R01N2026143 (D.A.M.), 1F132DC012449 (M.J.M.), R00DC010439 (S.V.D.) and the Kavli Institute of Neuroscience at Yale.
Publisher Copyright:
© 2015 Elsevier Inc.
PY - 2015/7/1
Y1 - 2015/7/1
N2 - The neural correlates of optimal states for signal detection task performance are largely unknown. One hypothesis holds that optimal states exhibit tonically depolarized cortical neurons with enhanced spiking activity, such as occur during movement. We recorded membrane potentials of auditory cortical neurons in mice trained on a challenging tone-in-noise detection task while assessing arousal with simultaneous pupillometry and hippocampal recordings. Arousal measures accurately predicted multiple modes of membrane potential activity, including rhythmic slow oscillations at low arousal, stable hyperpolarization at intermediate arousal, and depolarization during phasic or tonic periods of hyper-arousal. Walking always occurred during hyper-arousal. Optimal signal detection behavior and sound-evoked responses, at both sub-threshold and spiking levels, occurred at intermediate arousal when pre-decision membrane potentials were stably hyperpolarized. These results reveal a cortical physiological signature of the classically observed inverted-U relationship between task performance and arousal and that optimal detection exhibits enhanced sensory-evoked responses and reduced background synaptic activity.
AB - The neural correlates of optimal states for signal detection task performance are largely unknown. One hypothesis holds that optimal states exhibit tonically depolarized cortical neurons with enhanced spiking activity, such as occur during movement. We recorded membrane potentials of auditory cortical neurons in mice trained on a challenging tone-in-noise detection task while assessing arousal with simultaneous pupillometry and hippocampal recordings. Arousal measures accurately predicted multiple modes of membrane potential activity, including rhythmic slow oscillations at low arousal, stable hyperpolarization at intermediate arousal, and depolarization during phasic or tonic periods of hyper-arousal. Walking always occurred during hyper-arousal. Optimal signal detection behavior and sound-evoked responses, at both sub-threshold and spiking levels, occurred at intermediate arousal when pre-decision membrane potentials were stably hyperpolarized. These results reveal a cortical physiological signature of the classically observed inverted-U relationship between task performance and arousal and that optimal detection exhibits enhanced sensory-evoked responses and reduced background synaptic activity.
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U2 - 10.1016/j.neuron.2015.05.038
DO - 10.1016/j.neuron.2015.05.038
M3 - Article
C2 - 26074005
AN - SCOPUS:84937432924
SN - 0896-6273
VL - 87
SP - 179
EP - 192
JO - Neuron
JF - Neuron
IS - 1
ER -