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Main Authors: Wanken, Paulina, Edelman, Bradley, Behera, Leafy, Martinez de Paz, Jose Maria, McCarthy, Patrick, Macé, Emilie
Format: Recurso digital
Language:English
Published: Zenodo 2026
Subjects:
Online Access:https://doi.org/10.5281/zenodo.18492450
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author Wanken, Paulina
Edelman, Bradley
Behera, Leafy
Martinez de Paz, Jose Maria
McCarthy, Patrick
Macé, Emilie
author_facet Wanken, Paulina
Edelman, Bradley
Behera, Leafy
Martinez de Paz, Jose Maria
McCarthy, Patrick
Macé, Emilie
contents <p><span>Animals exhibit behavior in the absence of external stimuli or explicit tasks. Is the initiation of such spontaneous behavior shaped by internal brain states in a predictable manner? If so, does it engage specific brain circuits independent of behavioral form? Here, we studied the initiation of uninstructed behaviors of head-fixed mice in two contexts: a virtual burrow and a running wheel. Across both contexts, mice spent most of the time in quiet wakefulness and spontaneously initiated bouts of egress (exiting the burrow), running, or grooming. We employed functional ultrasound imaging (fUS) to record whole-brain activity and to identify whether the initiation of spontaneous behavior could be predicted from hemodynamic signals. We first identified distinct hemodynamic patterns associated with each behavior and subsequently performed time-resolved decoding to predict behavioral transitions from fUS data. We found that whole-brain hemodynamic signals could decode spontaneous egress and running around 10 seconds before their onset, a timescale that cannot be accounted for by preceding behavioral changes alone. Furthermore, we found a network of regions, including the medial septum (MS), that decreased their signal several seconds before the onset of egress and running. Mimicking this decrease by inhibiting neurons in the MS via optogenetics increased the probability of egress, running, and grooming. Through this unbiased approach, our work sheds light on a whole-brain transition-prone state that precedes uninstructed behavior transitions.</span></p>
format Recurso digital
id zenodo_https___doi_org_10_5281_zenodo_18492450
institution Zenodo
language eng
publishDate 2026
publisher Zenodo
record_format zenodo
spellingShingle Codes of "A transition-prone brain state precedes spontaneous behavioral switching"
Wanken, Paulina
Edelman, Bradley
Behera, Leafy
Martinez de Paz, Jose Maria
McCarthy, Patrick
Macé, Emilie
Neuroscience
functional Ultrasound Imaging
Behavior
Functional Neuroimaging
<p><span>Animals exhibit behavior in the absence of external stimuli or explicit tasks. Is the initiation of such spontaneous behavior shaped by internal brain states in a predictable manner? If so, does it engage specific brain circuits independent of behavioral form? Here, we studied the initiation of uninstructed behaviors of head-fixed mice in two contexts: a virtual burrow and a running wheel. Across both contexts, mice spent most of the time in quiet wakefulness and spontaneously initiated bouts of egress (exiting the burrow), running, or grooming. We employed functional ultrasound imaging (fUS) to record whole-brain activity and to identify whether the initiation of spontaneous behavior could be predicted from hemodynamic signals. We first identified distinct hemodynamic patterns associated with each behavior and subsequently performed time-resolved decoding to predict behavioral transitions from fUS data. We found that whole-brain hemodynamic signals could decode spontaneous egress and running around 10 seconds before their onset, a timescale that cannot be accounted for by preceding behavioral changes alone. Furthermore, we found a network of regions, including the medial septum (MS), that decreased their signal several seconds before the onset of egress and running. Mimicking this decrease by inhibiting neurons in the MS via optogenetics increased the probability of egress, running, and grooming. Through this unbiased approach, our work sheds light on a whole-brain transition-prone state that precedes uninstructed behavior transitions.</span></p>
title Codes of "A transition-prone brain state precedes spontaneous behavioral switching"
topic Neuroscience
functional Ultrasound Imaging
Behavior
Functional Neuroimaging
url https://doi.org/10.5281/zenodo.18492450