Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability

Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability

The abilities to either flexibly adjust behavior according to changing demands (cognitive flexibility) or to maintain it in the face of potential distractors (cognitive stability) are critical for adaptive behavior in many situations. Recently, a novel human paradigm has found individual differences...

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Main Authors: S Helene Richter, Anne S Vogel, Kai eUeltzhöffer, Chiara eMuzzillo, Miriam A Vogt, Katja eLankisch, Diana J N Armbruster-Genc, Marco A Riva, Christian J Fiebach, Peter eGass, Barbara eVollmayr
Format: Article
Language:English
Published: Frontiers Media S.A. 2014-05-01
Series:Frontiers in Behavioral Neuroscience
Subjects:
Mice
executive functioning
translation
cognitive flexibility
dual state theory
Neurocomputational models
Online Access:http://journal.frontiersin.org/Journal/10.3389/fnbeh.2014.00154/full
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spelling doaj-33fef25536f54e47b229fd3cd23d7a612020-11-25T00:14:02ZengFrontiers Media S.A.Frontiers in Behavioral Neuroscience1662-51532014-05-01810.3389/fnbeh.2014.0015488229Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stabilityS Helene Richter0S Helene Richter1S Helene Richter2Anne S Vogel3Anne S Vogel4Kai eUeltzhöffer5Kai eUeltzhöffer6Chiara eMuzzillo7Miriam A Vogt8Miriam A Vogt9Katja eLankisch10Katja eLankisch11Diana J N Armbruster-Genc12Diana J N Armbruster-Genc13Marco A Riva14Christian J Fiebach15Christian J Fiebach16Peter eGass17Peter eGass18Barbara eVollmayr19Barbara eVollmayr20Central Institute of Mental Health, Medical Faculty Mannheim, University of HeidelbergBernstein Center for Computational NeuroscienceUniversity of MünsterCentral Institute of Mental Health, Medical Faculty Mannheim, University of HeidelbergBernstein Center for Computational NeuroscienceBernstein Center for Computational NeuroscienceGoethe UniversityUniversity of MilanCentral Institute of Mental Health, Medical Faculty Mannheim, University of HeidelbergBernstein Center for Computational NeuroscienceCentral Institute of Mental Health, Medical Faculty Mannheim, University of HeidelbergBernstein Center for Computational NeuroscienceBernstein Center for Computational NeuroscienceGoethe UniversityUniversity of MilanCentral Institute of Mental Health, Medical Faculty Mannheim, University of HeidelbergBernstein Center for Computational NeuroscienceCentral Institute of Mental Health, Medical Faculty Mannheim, University of HeidelbergBernstein Center for Computational NeuroscienceCentral Institute of Mental Health, Medical Faculty Mannheim, University of HeidelbergBernstein Center for Computational NeuroscienceThe abilities to either flexibly adjust behavior according to changing demands (cognitive flexibility) or to maintain it in the face of potential distractors (cognitive stability) are critical for adaptive behavior in many situations. Recently, a novel human paradigm has found individual differences of cognitive flexibility and stability to be related to common prefrontal networks. The aims of the present study were, first, to translate this paradigm from humans to mice and, second, to test conceptual predictions of a computational model of prefrontal working memory mechanisms, the Dual State Theory, which assumes an antagonistic relation between cognitive flexibility and stability.Mice were trained in a touchscreen-paradigm to discriminate visual cues. The task involved ‘ongoing’ and cued ‘switch’ trials. In addition distractor cues were interspersed to test the ability to resist distraction, and an ambiguous condition assessed the spontaneous switching between two possible responses without explicit cues. While response times did not differ substantially between conditions, error rates increased from the ‘ongoing’ baseline condition to the most complex condition, where subjects were required to switch between two responses in the presence of a distracting cue. Importantly, subjects switching more often spontaneously were found to be more distractible by task irrelevant cues, but also more flexible in situations, where switching was required. These results support a dichotomy of cognitive flexibility and stability as predicted by the Dual State Theory. Furthermore, they replicate critical aspects of the human paradigm, which indicates the translational potential of the testing procedure and supports the use of touchscreen procedures in preclinical animal research.http://journal.frontiersin.org/Journal/10.3389/fnbeh.2014.00154/fullMiceexecutive functioningtranslationcognitive flexibilitydual state theoryNeurocomputational models
collection DOAJ
language English
format Article
sources DOAJ
author S Helene Richter
S Helene Richter
S Helene Richter
Anne S Vogel
Anne S Vogel
Kai eUeltzhöffer
Kai eUeltzhöffer
Chiara eMuzzillo
Miriam A Vogt
Miriam A Vogt
Katja eLankisch
Katja eLankisch
Diana J N Armbruster-Genc
Diana J N Armbruster-Genc
Marco A Riva
Christian J Fiebach
Christian J Fiebach
Peter eGass
Peter eGass
Barbara eVollmayr
Barbara eVollmayr
spellingShingle S Helene Richter
S Helene Richter
S Helene Richter
Anne S Vogel
Anne S Vogel
Kai eUeltzhöffer
Kai eUeltzhöffer
Chiara eMuzzillo
Miriam A Vogt
Miriam A Vogt
Katja eLankisch
Katja eLankisch
Diana J N Armbruster-Genc
Diana J N Armbruster-Genc
Marco A Riva
Christian J Fiebach
Christian J Fiebach
Peter eGass
Peter eGass
Barbara eVollmayr
Barbara eVollmayr
Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability
Frontiers in Behavioral Neuroscience
Mice
executive functioning
translation
cognitive flexibility
dual state theory
Neurocomputational models
author_facet S Helene Richter
S Helene Richter
S Helene Richter
Anne S Vogel
Anne S Vogel
Kai eUeltzhöffer
Kai eUeltzhöffer
Chiara eMuzzillo
Miriam A Vogt
Miriam A Vogt
Katja eLankisch
Katja eLankisch
Diana J N Armbruster-Genc
Diana J N Armbruster-Genc
Marco A Riva
Christian J Fiebach
Christian J Fiebach
Peter eGass
Peter eGass
Barbara eVollmayr
Barbara eVollmayr
author_sort S Helene Richter
title Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability
title_short Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability
title_full Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability
title_fullStr Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability
title_full_unstemmed Touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability
title_sort touchscreen-paradigm for mice reveals cross-species evidence for an antagonistic relationship of cognitive flexibility and stability
publisher Frontiers Media S.A.
series Frontiers in Behavioral Neuroscience
issn 1662-5153
publishDate 2014-05-01
description The abilities to either flexibly adjust behavior according to changing demands (cognitive flexibility) or to maintain it in the face of potential distractors (cognitive stability) are critical for adaptive behavior in many situations. Recently, a novel human paradigm has found individual differences of cognitive flexibility and stability to be related to common prefrontal networks. The aims of the present study were, first, to translate this paradigm from humans to mice and, second, to test conceptual predictions of a computational model of prefrontal working memory mechanisms, the Dual State Theory, which assumes an antagonistic relation between cognitive flexibility and stability.Mice were trained in a touchscreen-paradigm to discriminate visual cues. The task involved ‘ongoing’ and cued ‘switch’ trials. In addition distractor cues were interspersed to test the ability to resist distraction, and an ambiguous condition assessed the spontaneous switching between two possible responses without explicit cues. While response times did not differ substantially between conditions, error rates increased from the ‘ongoing’ baseline condition to the most complex condition, where subjects were required to switch between two responses in the presence of a distracting cue. Importantly, subjects switching more often spontaneously were found to be more distractible by task irrelevant cues, but also more flexible in situations, where switching was required. These results support a dichotomy of cognitive flexibility and stability as predicted by the Dual State Theory. Furthermore, they replicate critical aspects of the human paradigm, which indicates the translational potential of the testing procedure and supports the use of touchscreen procedures in preclinical animal research.
topic Mice
executive functioning
translation
cognitive flexibility
dual state theory
Neurocomputational models
url http://journal.frontiersin.org/Journal/10.3389/fnbeh.2014.00154/full
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