A discovery of new features of gastropod local field potentials by application of wavelet tools

Odor input evokes characteristic, time-evolving (non-stationary) events in the spontaneously active central ganglia of the snail Helix pomatia. Assuming stationarity for the signals, one could, as the first approach, apply the Fourier-based methods, frequency amplitude characteristics (FAC) measures...

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Detalles Bibliográficos
Autores principales: Schütt, A., Rosso, O.A., Figliola, A.
Formato: JOUR
Materias:
Fourier transform
Helix pomatia
Odor evoked activities
Wavelet transform
animal experiment
article
autonomic ganglion
controlled study
electric potential
entropy
ganglion
gastropod
nonhuman
odor
priority journal
sensorimotor function
Animals
Entropy
Evoked Potentials
Fourier Analysis
Ganglia, Invertebrate
Helix (Snails)
Neuropil
Numerical Analysis, Computer-Assisted
Odors
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_01650270_v119_n1_p89_Schutt
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
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spelling todo:paper_01650270_v119_n1_p89_Schutt2023-10-03T15:02:33Z A discovery of new features of gastropod local field potentials by application of wavelet tools Schütt, A. Rosso, O.A. Figliola, A. Fourier transform Helix pomatia Odor evoked activities Wavelet transform animal experiment article autonomic ganglion controlled study electric potential entropy ganglion gastropod nonhuman odor priority journal sensorimotor function Animals Entropy Evoked Potentials Fourier Analysis Ganglia, Invertebrate Helix (Snails) Neuropil Numerical Analysis, Computer-Assisted Odors Odor input evokes characteristic, time-evolving (non-stationary) events in the spontaneously active central ganglia of the snail Helix pomatia. Assuming stationarity for the signals, one could, as the first approach, apply the Fourier-based methods, frequency amplitude characteristics (FAC) measures, for analyzing such events. We could thus for the first time describe such events in frequency and amplitude and show that the frequency, at which power increases most, is specific to the odor or its class [Comp. Biochem. Physiol. 123A (1999a) 95; Comp. Biochem. Physiol. 124A (1999b) 297]. Wavelet tools assume no record stationarity and are suitable for describing the dynamically evolving brain electrical signals precisely and quantitatively. We, therefore, tested these tools for the typical odor experiments with the procerebrum (PC), the pedal ganglion (PG) and the visceral ganglion (VG) of the Helix, which we earlier analyzed by the FAC measures and compared both results. The two basic findings of the present wavelet analysis are as follows: (i) the wavelet energy fluctuations clearly visualize dynamical interactions among the major bands (0.1-3.1 Hz), implying a possible 'mutual exclusion' between slow components <0.8 Hz and faster ones >0.8 Hz. (ii) Entropy behavior was characteristically different for each of the three brain regions. Only in PC the response to aversive odorants (decrease of entropy=more ordered state) is differentiated in entropy from that to attractive ones (increase of entropy=more disordered or more complexly ordered state) indicating the odor-discriminating function of this region. In VG entropy of the intrinsic activity is so high (highly disordered state) due to the strong wideband activity reaching >50 Hz that odor stimulation results mainly in lowering of entropy (=more ordered state) regardless of the nature of the odor. In PG, however, odor presentation generally increases entropy due to the robust, wide-band activation at >3 Hz (sensorimotor function) that is generated as a secondary, but dominant and robust, response. In respect to describing time evolution of different frequency band components the present wavelet tools can much more sensitively do so, as compared with the FAC measures. They can also characterize a change in the neuroelectrical state in terms of entropy. © 2002 Elsevier Science B.V. All rights reserved. Fil:Figliola, A. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_01650270_v119_n1_p89_Schutt
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Fourier transform
Helix pomatia
Odor evoked activities
Wavelet transform
animal experiment
article
autonomic ganglion
controlled study
electric potential
entropy
ganglion
gastropod
nonhuman
odor
priority journal
sensorimotor function
Animals
Entropy
Evoked Potentials
Fourier Analysis
Ganglia, Invertebrate
Helix (Snails)
Neuropil
Numerical Analysis, Computer-Assisted
Odors
spellingShingle Fourier transform
Helix pomatia
Odor evoked activities
Wavelet transform
animal experiment
article
autonomic ganglion
controlled study
electric potential
entropy
ganglion
gastropod
nonhuman
odor
priority journal
sensorimotor function
Animals
Entropy
Evoked Potentials
Fourier Analysis
Ganglia, Invertebrate
Helix (Snails)
Neuropil
Numerical Analysis, Computer-Assisted
Odors
Schütt, A.
Rosso, O.A.
Figliola, A.
A discovery of new features of gastropod local field potentials by application of wavelet tools
topic_facet Fourier transform
Helix pomatia
Odor evoked activities
Wavelet transform
animal experiment
article
autonomic ganglion
controlled study
electric potential
entropy
ganglion
gastropod
nonhuman
odor
priority journal
sensorimotor function
Animals
Entropy
Evoked Potentials
Fourier Analysis
Ganglia, Invertebrate
Helix (Snails)
Neuropil
Numerical Analysis, Computer-Assisted
Odors
description Odor input evokes characteristic, time-evolving (non-stationary) events in the spontaneously active central ganglia of the snail Helix pomatia. Assuming stationarity for the signals, one could, as the first approach, apply the Fourier-based methods, frequency amplitude characteristics (FAC) measures, for analyzing such events. We could thus for the first time describe such events in frequency and amplitude and show that the frequency, at which power increases most, is specific to the odor or its class [Comp. Biochem. Physiol. 123A (1999a) 95; Comp. Biochem. Physiol. 124A (1999b) 297]. Wavelet tools assume no record stationarity and are suitable for describing the dynamically evolving brain electrical signals precisely and quantitatively. We, therefore, tested these tools for the typical odor experiments with the procerebrum (PC), the pedal ganglion (PG) and the visceral ganglion (VG) of the Helix, which we earlier analyzed by the FAC measures and compared both results. The two basic findings of the present wavelet analysis are as follows: (i) the wavelet energy fluctuations clearly visualize dynamical interactions among the major bands (0.1-3.1 Hz), implying a possible 'mutual exclusion' between slow components <0.8 Hz and faster ones >0.8 Hz. (ii) Entropy behavior was characteristically different for each of the three brain regions. Only in PC the response to aversive odorants (decrease of entropy=more ordered state) is differentiated in entropy from that to attractive ones (increase of entropy=more disordered or more complexly ordered state) indicating the odor-discriminating function of this region. In VG entropy of the intrinsic activity is so high (highly disordered state) due to the strong wideband activity reaching >50 Hz that odor stimulation results mainly in lowering of entropy (=more ordered state) regardless of the nature of the odor. In PG, however, odor presentation generally increases entropy due to the robust, wide-band activation at >3 Hz (sensorimotor function) that is generated as a secondary, but dominant and robust, response. In respect to describing time evolution of different frequency band components the present wavelet tools can much more sensitively do so, as compared with the FAC measures. They can also characterize a change in the neuroelectrical state in terms of entropy. © 2002 Elsevier Science B.V. All rights reserved.
format JOUR
author Schütt, A.
Rosso, O.A.
Figliola, A.
author_facet Schütt, A.
Rosso, O.A.
Figliola, A.
author_sort Schütt, A.
title A discovery of new features of gastropod local field potentials by application of wavelet tools
title_short A discovery of new features of gastropod local field potentials by application of wavelet tools
title_full A discovery of new features of gastropod local field potentials by application of wavelet tools
title_fullStr A discovery of new features of gastropod local field potentials by application of wavelet tools
title_full_unstemmed A discovery of new features of gastropod local field potentials by application of wavelet tools
title_sort discovery of new features of gastropod local field potentials by application of wavelet tools
url http://hdl.handle.net/20.500.12110/paper_01650270_v119_n1_p89_Schutt
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