Role of frequency-dependent weighing of inputs on frequency regulation of a pacemaker-driven rhythm

Inbar Saraf-Sinik; Yair Manor

doi:10.1016/j.neucom.2005.12.054

Role of frequency-dependent weighing of inputs on frequency regulation of a pacemaker-driven rhythm

Inbar Saraf-Sinik, Yair Manor

Department of Life Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

We examined the frequency-dependent efficiency of positive and negative inputs onto pacemaker neurons of the pyloric rhythm. When neuromodulation to the pyloric circuit was blocked, pyloric neurons became quiescent. In the pacemaker neurons, we injected series of sinusoidal currents of different frequencies. At slow frequencies, voltage peak amplitudes were significantly larger than troughs. This trend reversed at higher frequencies. A computational model suggests that rapid A- and slower T-type currents can produce this excitability profile, and that a frequency dependence preference of negative and positive inputs impinging onto pacemaker neurons can play an important role in homeostatic stabilization of the rhythm.

Original language	English
Pages (from-to)	1103-1107
Number of pages	5
Journal	Neurocomputing
Volume	69
Issue number	10-12
DOIs	https://doi.org/10.1016/j.neucom.2005.12.054
State	Published - 1 May 2006

Keywords

Frequency-dependent excitability
Oscillation
Pacemaker
Pyloric rhythm
Stomatogastric ganglion

ASJC Scopus subject areas

Computer Science Applications
Cognitive Neuroscience
Artificial Intelligence

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10.1016/j.neucom.2005.12.054

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abstract = "We examined the frequency-dependent efficiency of positive and negative inputs onto pacemaker neurons of the pyloric rhythm. When neuromodulation to the pyloric circuit was blocked, pyloric neurons became quiescent. In the pacemaker neurons, we injected series of sinusoidal currents of different frequencies. At slow frequencies, voltage peak amplitudes were significantly larger than troughs. This trend reversed at higher frequencies. A computational model suggests that rapid A- and slower T-type currents can produce this excitability profile, and that a frequency dependence preference of negative and positive inputs impinging onto pacemaker neurons can play an important role in homeostatic stabilization of the rhythm.",

keywords = "Frequency-dependent excitability, Oscillation, Pacemaker, Pyloric rhythm, Stomatogastric ganglion",

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AU - Manor, Yair

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N2 - We examined the frequency-dependent efficiency of positive and negative inputs onto pacemaker neurons of the pyloric rhythm. When neuromodulation to the pyloric circuit was blocked, pyloric neurons became quiescent. In the pacemaker neurons, we injected series of sinusoidal currents of different frequencies. At slow frequencies, voltage peak amplitudes were significantly larger than troughs. This trend reversed at higher frequencies. A computational model suggests that rapid A- and slower T-type currents can produce this excitability profile, and that a frequency dependence preference of negative and positive inputs impinging onto pacemaker neurons can play an important role in homeostatic stabilization of the rhythm.

AB - We examined the frequency-dependent efficiency of positive and negative inputs onto pacemaker neurons of the pyloric rhythm. When neuromodulation to the pyloric circuit was blocked, pyloric neurons became quiescent. In the pacemaker neurons, we injected series of sinusoidal currents of different frequencies. At slow frequencies, voltage peak amplitudes were significantly larger than troughs. This trend reversed at higher frequencies. A computational model suggests that rapid A- and slower T-type currents can produce this excitability profile, and that a frequency dependence preference of negative and positive inputs impinging onto pacemaker neurons can play an important role in homeostatic stabilization of the rhythm.

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Role of frequency-dependent weighing of inputs on frequency regulation of a pacemaker-driven rhythm

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Keywords

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