Synchrony, oscillations, and phase relationships in collective neuronal activity: A highly comparative overview of methods
Fabiano Baroni, Ben D. Fulcher, Daniel Bush, Andrea E. Martin, Daniel Bush, Andrea E. Martin, Daniel Bush, Andrea E. Martin, Daniel Bush, Andrea E. Martin

TL;DR
This paper compares many methods for analyzing synchronized brain activity patterns to help researchers choose the best tools for their studies.
Contribution
The paper introduces a comprehensive comparison of 122+ methods for analyzing neuronal synchrony and oscillations, revealing their strengths and limitations.
Findings
Most methods are affected by factors like firing rate and population frequency, but to varying degrees.
The highly comparative approach enables detailed quantification of collective neural activity patterns in both synthetic and biological data.
There is no single best method; the choice depends on specific research criteria and experimental conditions.
Abstract
Neuronal activity is organized in collective patterns that are critical for information coding, generation, and communication between neural populations. These patterns are often described in terms of synchrony, oscillations, and phase relationships. Many methods have been proposed for the quantification of these collective states of dynamic neuronal organization. However, it is difficult to determine which method is best suited for which experimental setting and research question. This choice is further complicated by the fact that most methods are sensitive to a combination of synchrony, oscillations, and other factors; in addition, some of them display systematic biases that can complicate their interpretation. To address these challenges, we adopt a highly comparative approach, whereby spike trains are represented by a diverse library of measures. This enables unsupervised or…
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Taxonomy
TopicsNeural dynamics and brain function · Photoreceptor and optogenetics research · Neuroscience and Neural Engineering
