Temperature Induced Syllable Breaking Unveils Nonlinearly Interacting Timescales in Birdsong Motor Pathway

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The nature of telencephalic control over premotor and motor circuits is debated. Hypotheses range from complete usurping of downstream circuitry to highly interactive mechanisms of control. We show theoretically and experimentally, that telencephalic song motor control in canaries is consistent with...

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Detalles Bibliográficos
Autores principales: Goldin, M.A., Alonso, L.M., Alliende, J.A., Goller, F., Mindlin, G.B.
Formato: Artículo publishedVersion
Lenguaje:Inglés
Publicado: 2013
Materias:
animal experiment
article
birdsong
breathing pattern
canary
controlled study
forebrain
forebrain nucleus
male
motor control
motor system
nonhuman
respiration control
telencephalon
temperature
theoretical model
vocalization
Algorithms
Animals
Brain
Canaries
Male
Models, Neurological
Motor Cortex
Neural Pathways
Prosencephalon
Respiration
Temperature
Time Factors
Vocalization, Animal
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_19326203_v8_n6_p_Goldin
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paperaa:paper_19326203_v8_n6_p_Goldin
record_format dspace
spelling paperaa:paper_19326203_v8_n6_p_Goldin2023-06-12T16:51:47Z Temperature Induced Syllable Breaking Unveils Nonlinearly Interacting Timescales in Birdsong Motor Pathway PLoS ONE 2013;8(6) Goldin, M.A. Alonso, L.M. Alliende, J.A. Goller, F. Mindlin, G.B. animal experiment article birdsong breathing pattern canary controlled study forebrain forebrain nucleus male motor control motor system nonhuman respiration control telencephalon temperature theoretical model vocalization Algorithms Animals Brain Canaries Male Models, Neurological Motor Cortex Neural Pathways Prosencephalon Respiration Temperature Time Factors Vocalization, Animal The nature of telencephalic control over premotor and motor circuits is debated. Hypotheses range from complete usurping of downstream circuitry to highly interactive mechanisms of control. We show theoretically and experimentally, that telencephalic song motor control in canaries is consistent with a highly interactive strategy. As predicted from a theoretical model of respiratory control, mild cooling of a forebrain nucleus (HVC) led to song stretching, but further cooling caused progressive restructuring of song, consistent with the hypothesis that respiratory gestures are subharmonic responses to a timescale present in the output of HVC. This interaction between a life-sustaining motor function (respiration) and telencephalic song motor control suggests a more general mechanism of how nonlinear integration of evolutionarily new brain structures into existing circuitry gives rise to diverse, new behavior. © 2013 Goldin et al. Fil:Alonso, L.M. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. 2013 info:eu-repo/semantics/article info:ar-repo/semantics/artículo info:eu-repo/semantics/publishedVersion application/pdf eng info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_19326203_v8_n6_p_Goldin
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
language Inglés
orig_language_str_mv eng
topic animal experiment
article
birdsong
breathing pattern
canary
controlled study
forebrain
forebrain nucleus
male
motor control
motor system
nonhuman
respiration control
telencephalon
temperature
theoretical model
vocalization
Algorithms
Animals
Brain
Canaries
Male
Models, Neurological
Motor Cortex
Neural Pathways
Prosencephalon
Respiration
Temperature
Time Factors
Vocalization, Animal
spellingShingle animal experiment
article
birdsong
breathing pattern
canary
controlled study
forebrain
forebrain nucleus
male
motor control
motor system
nonhuman
respiration control
telencephalon
temperature
theoretical model
vocalization
Algorithms
Animals
Brain
Canaries
Male
Models, Neurological
Motor Cortex
Neural Pathways
Prosencephalon
Respiration
Temperature
Time Factors
Vocalization, Animal
Goldin, M.A.
Alonso, L.M.
Alliende, J.A.
Goller, F.
Mindlin, G.B.
Temperature Induced Syllable Breaking Unveils Nonlinearly Interacting Timescales in Birdsong Motor Pathway
topic_facet animal experiment
article
birdsong
breathing pattern
canary
controlled study
forebrain
forebrain nucleus
male
motor control
motor system
nonhuman
respiration control
telencephalon
temperature
theoretical model
vocalization
Algorithms
Animals
Brain
Canaries
Male
Models, Neurological
Motor Cortex
Neural Pathways
Prosencephalon
Respiration
Temperature
Time Factors
Vocalization, Animal
description The nature of telencephalic control over premotor and motor circuits is debated. Hypotheses range from complete usurping of downstream circuitry to highly interactive mechanisms of control. We show theoretically and experimentally, that telencephalic song motor control in canaries is consistent with a highly interactive strategy. As predicted from a theoretical model of respiratory control, mild cooling of a forebrain nucleus (HVC) led to song stretching, but further cooling caused progressive restructuring of song, consistent with the hypothesis that respiratory gestures are subharmonic responses to a timescale present in the output of HVC. This interaction between a life-sustaining motor function (respiration) and telencephalic song motor control suggests a more general mechanism of how nonlinear integration of evolutionarily new brain structures into existing circuitry gives rise to diverse, new behavior. © 2013 Goldin et al.
format Artículo
Artículo
publishedVersion
author Goldin, M.A.
Alonso, L.M.
Alliende, J.A.
Goller, F.
Mindlin, G.B.
author_facet Goldin, M.A.
Alonso, L.M.
Alliende, J.A.
Goller, F.
Mindlin, G.B.
author_sort Goldin, M.A.
title Temperature Induced Syllable Breaking Unveils Nonlinearly Interacting Timescales in Birdsong Motor Pathway
title_short Temperature Induced Syllable Breaking Unveils Nonlinearly Interacting Timescales in Birdsong Motor Pathway
title_full Temperature Induced Syllable Breaking Unveils Nonlinearly Interacting Timescales in Birdsong Motor Pathway
title_fullStr Temperature Induced Syllable Breaking Unveils Nonlinearly Interacting Timescales in Birdsong Motor Pathway
title_full_unstemmed Temperature Induced Syllable Breaking Unveils Nonlinearly Interacting Timescales in Birdsong Motor Pathway
title_sort temperature induced syllable breaking unveils nonlinearly interacting timescales in birdsong motor pathway
publishDate 2013
url http://hdl.handle.net/20.500.12110/paper_19326203_v8_n6_p_Goldin
work_keys_str_mv AT goldinma temperatureinducedsyllablebreakingunveilsnonlinearlyinteractingtimescalesinbirdsongmotorpathway
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