Cellular mechanisms of brain state–dependent gain modulation in visual cortex

Polack, Pierre-Olivier; Friedman, Jonathan; Golshani, Peyman

doi:10.1038/nn.3464

Cited by 607 publications

(844 citation statements)

References 53 publications

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“…Neuromodulators such as noradrenaline seem to boost the gain of neural interactions in the cortex (5,7,26). It is tempting to speculate that such a transient boost in gain during decision formation enables conservative subjects to overcome their bias against responding "yes."…”

Section: Discussionmentioning

confidence: 99%

“…These neuromodulatory systems also activate briefly ("phasically") during perceptual decisions, such as visual target detection (5,(20)(21)(22)(23)(24), likely mediated via feedback connections from the prefrontal cortex (5,25). The modulatory neurotransmitters released from the projections of these brainstem systems, in turn, shape the internal state of cortical networks, for instance, by boosting the gain of neural interactions (5,7,26). Thus, these brainstem systems might also shape decision computations in cortical networks-provided that they are activated already during decision formation.…”

mentioning

confidence: 99%

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Decision-related pupil dilation reflects upcoming choice and individual bias

Gee

Knapen

Donner

2014

Proc. Natl. Acad. Sci. U.S.A.

332

389

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A number of studies have shown that pupil size increases transiently during effortful decisions. These decision-related changes in pupil size are mediated by central neuromodulatory systems, which also influence the internal state of brain regions engaged in decision making. It has been proposed that pupil-linked neuromodulatory systems are activated by the termination of decision processes, and, consequently, that these systems primarily affect the postdecisional brain state. Here, we present pupil results that run contrary to this proposal, suggesting an important intradecisional role. We measured pupil size while subjects formed protracted decisions about the presence or absence ("yes" vs. "no") of a visual contrast signal embedded in dynamic noise. Linear systems analysis revealed that the pupil was significantly driven by a sustained input throughout the course of the decision formation. This sustained component was larger than the transient component during the final choice (indicated by button press). The overall amplitude of pupil dilation during decision formation was bigger before yes than no choices, irrespective of the physical presence of the target signal. Remarkably, the magnitude of this pupil choice effect (yes > no) reflected the individual criterion: it was strongest in conservative subjects choosing yes against their bias. We conclude that the central neuromodulatory systems controlling pupil size are continuously engaged during decision formation in a way that reveals how the upcoming choice relates to the decision maker's attitude. Changes in brain state seem to interact with biased decision making in the face of uncertainty.detection | neuromodulation | arousal | perceptual psychophysics

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Decision-related pupil dilation reflects upcoming choice and individual bias

Gee

Knapen

Donner

2014

Proc. Natl. Acad. Sci. U.S.A.

332

389

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“…Finally, neuromodulatory brain stem systems are in a position to stabilize the perceptual dynamics because they can dynamically alter key cortical circuit parameters in profound ways. In particular, neuromodulators suppress cortical variability (Polack et al 2013) and may amplify inhibitory interactions in cortical circuits (Haider et al 2013). In competitive networks underlying multistable perception (Braun and Mattia 2010;Moreno-Bote et al 2007), a transient boost of mutual inhibition is equivalent into the deepening of valleys shown in Fig.…”

Section: Replayactivementioning

confidence: 99%

Top-down modulation in human visual cortex predicts the stability of a perceptual illusion

Kloosterman

Meindertsma

Hillebrand

et al. 2015

Journal of Neurophysiology

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“…All traces (n = 8) were 90 seconds long and contained at least 10 seconds of movement. Locomotion modulates subthreshold and spiking activity in a large number of brain regions (Dombeck, Graziano, and Tank, 2009;Polack, Friedman, and Golshani, 2013;Schiemann et al, 2015). In cerebellar interneurons, locomotion is associated with increased excitatory input drive, Fig.…”

Section: Inference Methods Applied To Cerebellar In Vivo Datamentioning

confidence: 99%

Extraction of Synaptic Input Properties in Vivo

et al. 2017

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Knowledge of synaptic input is crucial to understand synaptic integration and ultimately neural function. However, in vivo the rates at which synaptic inputs arrive are high, that it is typically impossible to detect single events. We show here that it is nevertheless possible to extract the properties of the events, and particular to extract the event rate, the synaptic time-constants, and the properties of the event size distribution from in vivo voltage-clamp recordings. Applied to cerebellar interneurons our method reveals that the synaptic input rate increases from 600Hz during rest to 1000Hz during locomotion, while the amplitude and shape of the synaptic events are unaffected by this state change. This method thus complements existing methods to measure neural function in vivo. Significance StatementNeurons in vivo typically receive thousands of synaptic events per second. While methods have been developed to measure the total synaptic current that results from these events, extraction of the constituent events has proven very difficult given their high degree of overlap. To resolve this, we introduce a probabilistic method that extracts the statistics of synaptic event amplitudes and their frequency from voltage clamp recordings, which is then applied to recordings from cerebellar interneurons. With this method it becomes possible to better understand synaptic input and how it changes with behavioral state.

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Cellular mechanisms of brain state–dependent gain modulation in visual cortex

Cited by 607 publications

References 53 publications

Decision-related pupil dilation reflects upcoming choice and individual bias

Decision-related pupil dilation reflects upcoming choice and individual bias

Top-down modulation in human visual cortex predicts the stability of a perceptual illusion

Extraction of Synaptic Input Properties in Vivo

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