Your search keyword '"Cameron Higgins"' showing total 3 results

1. Spatiotemporally Resolved Multivariate Pattern Analysis for M/EEG

Author

Yunzhe Liu, Cameron Higgins, Diego Vidaurre, Mark W. Woolrich, Timothy E.J. Behrens, and Nils Kolling

Subjects

medicine.diagnostic_test, business.industry, Computer science, Brain activity and meditation, Pattern recognition, Electroencephalography, Regression, Temporal resolution, Encoding (memory), medicine, Artificial intelligence, business, Decoding methods, Interpretability, Test data

Abstract

An emerging goal in neuroscience is tracking what information is represented in brain activity over time as a participant completes some task. Whilst EEG and MEG offer millisecond temporal resolution of how activity patterns emerge and evolve, standard decoding methods present significant barriers to interpretability as they obscure the underlying spatial and temporal activity patterns. We instead propose the use of a generative encoding model framework that simultaneously infers the multivariate spatial patterns of activity and the variable timing at which these patterns emerge on individual trials. An encoding model inversion allows predictions to be made about unseen test data in the same way as in standard decoding methodology. These SpatioTemporally Resolved MVPA (STRM) models can be flexibly applied to a wide variety of experimental paradigms, including classification and regression tasks. We show that these models provide insightful maps of the activity driving predictive accuracy metrics; demonstrate behaviourally meaningful variation in the timing of pattern emergence on individual trials; and achieve predictive accuracies that are either equivalent or surpass those achieved by more widely used methods. This provides a new avenue for investigating the brain’s representational dynamics and could ultimately support more flexible experimental designs in future.HIGHLIGHTSWe introduce SpatioTemporally Resolved MVPA (STRM), an approach that explicitly models how successive stages of stimulus processing are distributed in both space and time in M/EEG data.We show that STRM is broadly applicable to diverse types of M/EEG data and outputs meaningful and interpretable maps of how neural representations evolve in space and time at millisecond resolution.The trial-specific deviations in activity pattern timings identified by STRM are not random, but vary systematically with inter-trial differences in behavioural, cognitive and physiological variables.These methods result in predictive accuracy metrics that are mostly equivalent to, or a modest improvement on, conventional methods.

Published

2021

2. Temporally delayed linear modelling (TDLM) measures replay in both animals and humans

Author

Yunzhe Liu, H. Freyja Ólafsdóttir, Caswell Barry, Timothy E.J. Behrens, Zeb Kurth-Nelson, Mark W. Woolrich, Hector Penagos, Raymond J. Dolan, and Cameron Higgins

Subjects

0301 basic medicine, reactivation, Time Factors, Mouse, Computer science, Inference, computer.software_genre, 0302 clinical medicine, Models of neural computation, Convergence (routing), Biology (General), Evoked Potentials, Sequence, Behavior, Animal, General Neuroscience, Brain, Magnetoencephalography, Cognition, General Medicine, Visual Perception, Graph (abstract data type), Medicine, Research Article, Human, decoding, QH301-705.5, Computation, Science, Models, Neurological, Neurophysiology, Machine learning, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, MEG/EEG, replay, Animals, Humans, Without loss of generality, Maze Learning, General Immunology and Microbiology, business.industry, electrophysiology, Rats, 030104 developmental biology, Mental Recall, Linear Models, Artificial intelligence, business, computer, Photic Stimulation, 030217 neurology & neurosurgery, Neuroscience

Abstract

There are rich structures in off-task neural activity which are hypothesized to reflect fundamental computations across a broad spectrum of cognitive functions. Here, we develop an analysis toolkit – temporal delayed linear modelling (TDLM) – for analysing such activity. TDLM is a domain-general method for finding neural sequences that respect a pre-specified transition graph. It combines nonlinear classification and linear temporal modelling to test for statistical regularities in sequences of task-related reactivations. TDLM is developed on the non-invasive neuroimaging data and is designed to take care of confounds and maximize sequence detection ability. Notably, as a linear framework, TDLM can be easily extended, without loss of generality, to capture rodent replay in electrophysiology, including in continuous spaces, as well as addressing second-order inference questions, for example, its temporal and spatial varying pattern. We hope TDLM will advance a deeper understanding of neural computation and promote a richer convergence between animal and human neuroscience.

Published

2021

3. Review for 'Recurrence Quantification Analysis of Dynamic Brain Networks'

Author

Cameron Higgins

Subjects

medicine.medical_specialty, business.industry, Recurrence quantification analysis, medicine, Radiology, business

Published

2020