osl-dynamics, a toolbox for modeling fast dynamic brain activity

Author:

Gohil Chetan1ORCID,Huang Rukuang1ORCID,Roberts Evan1,van Es Mats WJ1ORCID,Quinn Andrew J12,Vidaurre Diego13ORCID,Woolrich Mark W1

Affiliation:

1. Oxford Centre for Human Brain Activity, Wellcome Centre for Integrative Neuroimaging, Department of Psychiatry, University of Oxford

2. Centre for Human Brain Health, School of Psychology, University of Birmingham

3. Center for Functionally Integrative Neuroscience, Department of Clinical Medicine, Aarhus University

Abstract

Neural activity contains rich spatiotemporal structure that corresponds to cognition. This includes oscillatory bursting and dynamic activity that span across networks of brain regions, all of which can occur on timescales of tens of milliseconds. While these processes can be accessed through brain recordings and imaging, modeling them presents methodological challenges due to their fast and transient nature. Furthermore, the exact timing and duration of interesting cognitive events are often a priori unknown. Here, we present the OHBA Software Library Dynamics Toolbox (osl-dynamics), a Python-based package that can identify and describe recurrent dynamics in functional neuroimaging data on timescales as fast as tens of milliseconds. At its core are machine learning generative models that are able to adapt to the data and learn the timing, as well as the spatial and spectral characteristics, of brain activity with few assumptions. osl-dynamics incorporates state-of-the-art approaches that can be, and have been, used to elucidate brain dynamics in a wide range of data types, including magneto/electroencephalography, functional magnetic resonance imaging, invasive local field potential recordings, and electrocorticography. It also provides novel summary measures of brain dynamics that can be used to inform our understanding of cognition, behavior, and disease. We hope osl-dynamics will further our understanding of brain function, through its ability to enhance the modeling of fast dynamic processes.

Funder

Wellcome Trust

Engineering and Physical Sciences Research Council

Dementia Research UK

Novo Nordisk Fonden

Publisher

eLife Sciences Publications, Ltd

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