Voltage-sensitive dye imaging of mouse neocortex during a whisker detection task

Kyriakatos, Alexandros; Sadashivaiah, Vijay; Zhang, Yifei; Motta, Alessandro; Auffret, Matthieu; Petersen, Carl C. H.

doi:10.1117/1.nph.4.3.031204

Cited by 33 publications

(41 citation statements)

References 50 publications

(82 reference statements)

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“…Large-scale imaging of dorsal cortex has recently been applied to mice performing a diversity of sensory-motor tasks (Goard et al 2016;Allen et al 2017;Kyriakatos et al 2016;Makino et al 2017;Stringer et al 2019;Musall et al 2019). An unexpected finding throughout these studies is the widespread activation of cortex during task performance.…”

Section: Introductionmentioning

confidence: 99%

Movement and performance predict widespread cortical activity in a visual detection task

Salkoff

Zagha

McCarthy

et al. 2019

Preprint

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Recent studies in mice reveal widespread cortical signals during task performance, however the various task-related and task-independent processes underlying this activity are incompletely understood. Here we recorded wide-field neural activity, as revealed by GCaMP6s, from dorsal cortex while simultaneously monitoring orofacial movements, walking, and arousal (pupil diameter) of head-fixed mice performing a Go/NoGo visual detection task and examined the ability of task performance and spontaneous or task-related movements to predict cortical activity. A linear model was able to explain a significant fraction (33-55% of variance) of widefield dorsal cortical activity, with the largest factors being movements (facial, walk, eye), response choice (hit, miss, false alarm), and arousal, and indicate that a significant fraction of trial-to-trial variability arises from both spontaneous and task-related changes in state (e.g. movements, arousal). Importantly, secondary motor cortex was highly correlated with lick rate, critical for optimal task performance (high d'), and was the first region to significantly predict the lick response on target trials. These findings suggest that secondary motor cortex is critically involved in the decision and performance of learned movements and indicate that a significant fraction of trial-to-trial variation in cortical activity results from spontaneous and task-related movements and variations in behavioral/arousal state.

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Section: Introductionmentioning

confidence: 99%

Movement and performance predict widespread cortical activity in a visual detection task

Salkoff

Zagha

McCarthy

et al. 2019

Preprint

View full text Add to dashboard Cite

show abstract

“…Mice adjust their whisker motor strategies according to task conditions. During tactile detection, whisking prior to and during stimulation reduces task performance, suggesting that mice might refrain from whisking in order to increase stimulus detection (Kyriakatos et al, 2017). In fact, facial nerve transection suggests that detection of passive deflection does not require whisker movement (Sachidhanandam et al, 2013).…”

Section: M1mentioning

confidence: 99%

Long‐range cortical dynamics: a perspective from the mouse sensorimotor whisker system

Chen

2017

Eur J of Neuroscience

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In the mammalian neocortex, the capacity to dynamically route and coordinate the exchange of information between areas is a critical feature of cognitive function, enabling processes such as higher-level sensory processing and sensorimotor integration. Despite the importance attributed to long-range connections between cortical areas, their exact operations and role in cortical function remain an open question. In recent years, progress has been made in understanding long-range cortical circuits through work focused on the mouse sensorimotor whisker system. In this review, we examine recent studies dissecting long-range circuits involved in whisker sensorimotor processing as an entry point for understanding the rules that govern long-range cortical circuit function.

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“…As an example, consider the detection of a sensory stimulus, which has been foundational in the human [17][18][19][20][21][22] and non-human primate psychophysical literature [23,24] and serves as one of the most widely utilized behavioral paradigms in rodent literature [25][26][27]. In an attempt to link the underlying neural variability to behavior, the principal framework for describing sensory perception of stimuli near the physical limits of detectability is signal detection theory [28].…”

Section: Introductionmentioning

confidence: 99%

State-aware detection of sensory stimuli in the cortex of the awake mouse

et al. 2019

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Cortical responses to sensory inputs vary across repeated presentations of identical stimuli, but how this trial-to-trial variability impacts detection of sensory inputs is not fully understood. Using multi-channel local field potential (LFP) recordings in primary somatosensory cortex (S1) of the awake mouse, we optimized a data-driven cortical state classifier to predict single-trial sensory-evoked responses, based on features of the spontaneous, ongoing LFP recorded across cortical layers. Our findings show that, by utilizing an ongoing prediction of the sensory response generated by this state classifier, an ideal observer improves overall detection accuracy and generates robust detection of sensory inputs across various states of ongoing cortical activity in the awake brain, which could have implications for variability in the performance of detection tasks across brain states.

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Voltage-sensitive dye imaging of mouse neocortex during a whisker detection task

Cited by 33 publications

References 50 publications

Movement and performance predict widespread cortical activity in a visual detection task

Movement and performance predict widespread cortical activity in a visual detection task

Long‐range cortical dynamics: a perspective from the mouse sensorimotor whisker system

State-aware detection of sensory stimuli in the cortex of the awake mouse

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