From homeostasis to behavior: Balanced activity in an exploration of embodied dynamic environmental-neural interaction.
In recent years, there have been many computational simulations of spontaneous neural dynamics. Here, we describe a simple model of spontaneous neural dynamics that controls an agent moving in a simple virtual environment. These dynamics generate interesting brain-environment feedback interactions t...
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| Language: | English |
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Public Library of Science (PLoS)
2017-08-01
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| Series: | PLoS Computational Biology |
| Online Access: | https://doi.org/10.1371/journal.pcbi.1005721 |
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doaj-76f971a1c2714b2a88aee618b057c9b32021-04-21T15:44:04ZengPublic Library of Science (PLoS)PLoS Computational Biology1553-734X1553-73582017-08-01138e100572110.1371/journal.pcbi.1005721From homeostasis to behavior: Balanced activity in an exploration of embodied dynamic environmental-neural interaction.Peter John HellyerClaudia ClopathAngie A KehagiaFederico E TurkheimerRobert LeechIn recent years, there have been many computational simulations of spontaneous neural dynamics. Here, we describe a simple model of spontaneous neural dynamics that controls an agent moving in a simple virtual environment. These dynamics generate interesting brain-environment feedback interactions that rapidly destabilize neural and behavioral dynamics demonstrating the need for homeostatic mechanisms. We investigate roles for homeostatic plasticity both locally (local inhibition adjusting to balance excitatory input) as well as more globally (regional "task negative" activity that compensates for "task positive", sensory input in another region) balancing neural activity and leading to more stable behavior (trajectories through the environment). Our results suggest complementary functional roles for both local and macroscale mechanisms in maintaining neural and behavioral dynamics and a novel functional role for macroscopic "task-negative" patterns of activity (e.g., the default mode network).https://doi.org/10.1371/journal.pcbi.1005721 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Peter John Hellyer Claudia Clopath Angie A Kehagia Federico E Turkheimer Robert Leech |
| spellingShingle |
Peter John Hellyer Claudia Clopath Angie A Kehagia Federico E Turkheimer Robert Leech From homeostasis to behavior: Balanced activity in an exploration of embodied dynamic environmental-neural interaction. PLoS Computational Biology |
| author_facet |
Peter John Hellyer Claudia Clopath Angie A Kehagia Federico E Turkheimer Robert Leech |
| author_sort |
Peter John Hellyer |
| title |
From homeostasis to behavior: Balanced activity in an exploration of embodied dynamic environmental-neural interaction. |
| title_short |
From homeostasis to behavior: Balanced activity in an exploration of embodied dynamic environmental-neural interaction. |
| title_full |
From homeostasis to behavior: Balanced activity in an exploration of embodied dynamic environmental-neural interaction. |
| title_fullStr |
From homeostasis to behavior: Balanced activity in an exploration of embodied dynamic environmental-neural interaction. |
| title_full_unstemmed |
From homeostasis to behavior: Balanced activity in an exploration of embodied dynamic environmental-neural interaction. |
| title_sort |
from homeostasis to behavior: balanced activity in an exploration of embodied dynamic environmental-neural interaction. |
| publisher |
Public Library of Science (PLoS) |
| series |
PLoS Computational Biology |
| issn |
1553-734X 1553-7358 |
| publishDate |
2017-08-01 |
| description |
In recent years, there have been many computational simulations of spontaneous neural dynamics. Here, we describe a simple model of spontaneous neural dynamics that controls an agent moving in a simple virtual environment. These dynamics generate interesting brain-environment feedback interactions that rapidly destabilize neural and behavioral dynamics demonstrating the need for homeostatic mechanisms. We investigate roles for homeostatic plasticity both locally (local inhibition adjusting to balance excitatory input) as well as more globally (regional "task negative" activity that compensates for "task positive", sensory input in another region) balancing neural activity and leading to more stable behavior (trajectories through the environment). Our results suggest complementary functional roles for both local and macroscale mechanisms in maintaining neural and behavioral dynamics and a novel functional role for macroscopic "task-negative" patterns of activity (e.g., the default mode network). |
| url |
https://doi.org/10.1371/journal.pcbi.1005721 |
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AT peterjohnhellyer fromhomeostasistobehaviorbalancedactivityinanexplorationofembodieddynamicenvironmentalneuralinteraction AT claudiaclopath fromhomeostasistobehaviorbalancedactivityinanexplorationofembodieddynamicenvironmentalneuralinteraction AT angieakehagia fromhomeostasistobehaviorbalancedactivityinanexplorationofembodieddynamicenvironmentalneuralinteraction AT federicoeturkheimer fromhomeostasistobehaviorbalancedactivityinanexplorationofembodieddynamicenvironmentalneuralinteraction AT robertleech fromhomeostasistobehaviorbalancedactivityinanexplorationofembodieddynamicenvironmentalneuralinteraction |
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1714667029760311296 |