Theoretical Relationship Between Two Measures of Spike Synchrony: Correlation Index and Vector Strength

Theoretical Relationship Between Two Measures of Spike Synchrony: Correlation Index and Vector Strength

Information processing in the nervous system critically relies on temporally precise spiking activity. In the auditory system, various degrees of phase-locking can be observed from the auditory nerve to cortical neurons. The classical metric for quantifying phase-locking is the vector strength (VS),...

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Published in:Frontiers in neuroscience Vol. 15; p. 761826
Main Authors: Kessler, Dominik, Carr, Catherine E, Kretzberg, Jutta, Ashida, Go
Format: Journal Article
Language:English
Published: Switzerland Frontiers Research Foundation 20-12-2021
Frontiers Media S.A
Subjects:
auditory brainstem
Auditory nerve
Auditory pathways
Auditory system
autocorrelogram
Brain stem
circular statistics
Firing pattern
Frequency dependence
Hearing
Histograms
Information processing
Nervous system
Neurons
Neuroscience
Periodicity
phase-locking
spike train analysis
temporal coding
spike train analysis
periodic signals
auditory brainstem
temporal coding
circular statistics
autocorrelogram
phase-locking
frequency-following response
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Summary:Information processing in the nervous system critically relies on temporally precise spiking activity. In the auditory system, various degrees of phase-locking can be observed from the auditory nerve to cortical neurons. The classical metric for quantifying phase-locking is the vector strength (VS), which captures the periodicity in neuronal spiking. More recently, another metric, called the correlation index (CI), was proposed to quantify the temporally reproducible response characteristics of a neuron. The CI is defined as the peak value of a normalized shuffled autocorrelogram (SAC). Both VS and CI have been used to investigate how temporal information is processed and propagated along the auditory pathways. While previous analyses of physiological data in cats suggested covariation of these two metrics, general characterization of their connection has never been performed. In the present study, we derive a rigorous relationship between VS and CI. To model phase-locking, we assume Poissonian spike trains with a temporally changing intensity function following a distribution. We demonstrate that VS and CI are mutually related via the so-called concentration parameter that determines the degree of phase-locking. We confirm that these theoretical results are largely consistent with physiological data recorded in the auditory brainstem of various animals. In addition, we generate artificial phase-locked spike sequences, for which recording and analysis parameters can be systematically manipulated. Our analysis results suggest that mismatches between empirical data and the theoretical prediction can often be explained with deviations from the distribution, including skewed or multimodal period histograms. Furthermore, temporal relations of spike trains across trials can contribute to higher CI values than predicted mathematically based on the VS. We find that, for most applications, a SAC bin width of 50 ms seems to be a favorable choice, leading to an estimated error below 2.5% for physiologically plausible conditions. Overall, our results provide general relations between the two measures of phase-locking and will aid future analyses of different physiological datasets that are characterized with these metrics.
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Reviewed by: Peter Heil, Leibniz Institute for Neurobiology, Germany; Satyabrata Parida, University of Pittsburgh, United States
Edited by: Enrique A. Lopez-Poveda, University of Salamanca, Spain
This article was submitted to Auditory Cognitive Neuroscience, a section of the journal Frontiers in Neuroscience
ISSN:1662-4548
1662-453X
1662-453X
DOI:10.3389/fnins.2021.761826