Your search keyword '"Andrew J. Quinn"' showing total 81 results

1. Understanding Harmonic Structures Through Instantaneous Frequency

Author

Marco S. Fabus, Mark W. Woolrich, Catherine W. Warnaby, and Andrew J. Quinn

Subjects

Electrophysiology, Empirical Mode Decomposition, Harmonic Analysis, Hilbert Transform, Instantaneous Frequency, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The analysis of harmonics and non-sinusoidal waveform shape in time-series data is growing in importance. However, a precise definition of what constitutes a harmonic is lacking. In this paper, we propose a rigorous definition of when to consider signals to be in a harmonic relationship based on an integer frequency ratio, constant phase, and a well-defined joint instantaneous frequency. We show this definition is linked to extrema counting and Empirical Mode Decomposition (EMD). We explore the mathematics of our definition and link it to results from analytic number theory. This naturally leads to us to define two classes of harmonic structures, termed strong and weak, with different extrema behaviour. We validate our framework using both simulations and real data. Specifically, we look at the harmonic structures in shallow water waves, the FitzHugh-Nagumo neuronal model, and the non-sinusoidal theta oscillation in rat hippocampus local field potential data. We further discuss how our definition helps to address mode splitting in nonlinear time-series decomposition methods. A clear understanding of when harmonics are present in signals will enable a deeper understanding of the functional roles of non-sinusoidal oscillations.

Published

2022

2. The relationship between frequency content and representational dynamics in the decoding of neurophysiological data

Author

Cameron Higgins, Mats W.J. van Es, Andrew J. Quinn, Diego Vidaurre, and Mark W. Woolrich

Subjects

Representational dynamics, Decoding, Aliasing, Complex spectrum decoding, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Decoding of high temporal resolution, stimulus-evoked neurophysiological data is increasingly used to test theories about how the brain processes information. However, a fundamental relationship between the frequency spectra of the neural signal and the subsequent decoding accuracy timecourse is not widely recognised. We show that, in commonly used instantaneous signal decoding paradigms, each sinusoidal component of the evoked response is translated to double its original frequency in the subsequent decoding accuracy timecourses. We therefore recommend, where researchers use instantaneous signal decoding paradigms, that more aggressive low pass filtering is applied with a cut-off at one quarter of the sampling rate, to eliminate representational alias artefacts. However, this does not negate the accompanying interpretational challenges. We show that these can be resolved by decoding paradigms that utilise both a signal's instantaneous magnitude and its local gradient information as features for decoding. On a publicly available MEG dataset, this results in decoding accuracy metrics that are higher, more stable over time, and free of the technical and interpretational challenges previously characterised. We anticipate that a broader awareness of these fundamental relationships will enable stronger interpretations of decoding results by linking them more clearly to the underlying signal characteristics that drive them.

Published

2022

3. Delineating between-subject heterogeneity in alpha networks with Spatio-Spectral Eigenmodes

Author

Andrew J. Quinn, Gary G.R. Green, and Mark Hymers

Subjects

MEG, Alpha oscillation, Network, Autoregression, Eigenmodes, Spectral decomposition, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Between subject variability in the spatial and spectral structure of oscillatory networks can be highly informative but poses a considerable analytic challenge. Here, we describe a data-driven modal decomposition of a multivariate autoregressive model that simultaneously identifies oscillations by their peak frequency, damping time and network structure. We use this decomposition to define a set of Spatio-Spectral Eigenmodes (SSEs) providing a parsimonious description of oscillatory networks. We show that the multivariate system transfer function can be rewritten in these modal coordinates, and that the full transfer function is a linear superposition of all modes in the decomposition. The modal transfer function is a linear summation and therefore allows for single oscillatory signals to be isolated and analysed in terms of their spectral content, spatial distribution and network structure. We validate the method on simulated data and explore the structure of whole brain oscillatory networks in eyes-open resting state MEG data from the Human Connectome Project. We are able to show a wide between participant variability in peak frequency and network structure of alpha oscillations and show a distinction between occipital ’high-frequency alpha’ and parietal ’low-frequency alpha’. The frequency difference between occipital and parietal alpha components is present within individual participants but is partially masked by larger between subject variability; a 10Hz oscillation may represent the high-frequency occipital component in one participant and the low-frequency parietal component in another. This rich characterisation of individual neural phenotypes has the potential to enhance analyses into the relationship between neural dynamics and a person’s behavioural, cognitive or clinical state.

Published

2021

4. Revealing the Dynamic Nature of Amplitude Modulated Neural Entrainment With Holo-Hilbert Spectral Analysis

Author

Chi-Hung Juan, Kien Trong Nguyen, Wei-Kuang Liang, Andrew J. Quinn, Yen-Hsun Chen, Neil G. Muggleton, Jia-Rong Yeh, Mark W. Woolrich, Anna C. Nobre, and Norden E. Huang

Subjects

the dynamic visual entrainment, Holo-Hilbert spectral analysis, cross-frequency coupling, steady-state visual evoked potential, phase-amplitude coupling, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Patterns in external sensory stimuli can rapidly entrain neuronally generated oscillations observed in electrophysiological data. Here, we manipulated the temporal dynamics of visual stimuli with cross-frequency coupling (CFC) characteristics to generate steady-state visual evoked potentials (SSVEPs). Although CFC plays a pivotal role in neural communication, some cases reporting CFC may be false positives due to non-sinusoidal oscillations that can generate artificially inflated coupling values. Additionally, temporal characteristics of dynamic and non-linear neural oscillations cannot be fully derived with conventional Fourier-based analyses mainly due to trade off of temporal resolution for frequency precision. In an attempt to resolve these limitations of linear analytical methods, Holo-Hilbert Spectral Analysis (HHSA) was investigated as a potential approach for examination of non-linear and non-stationary CFC dynamics in this study. Results from both simulation and SSVEPs demonstrated that temporal dynamic and non-linear CFC features can be revealed with HHSA. Specifically, the results of simulation showed that the HHSA is less affected by the non-sinusoidal oscillation and showed possible cross frequency interactions embedded in the simulation without any a priori assumptions. In the SSVEPs, we found that the time-varying cross-frequency interaction and the bidirectional coupling between delta and alpha/beta bands can be observed using HHSA, confirming dynamic physiological signatures of neural entrainment related to cross-frequency coupling. These findings not only validate the efficacy of the HHSA in revealing the natural characteristics of signals, but also shed new light on further applications in analysis of brain electrophysiological data with the aim of understanding the functional roles of neuronal oscillation in various cognitive functions.

Published

2021

5. Biomagnetic biomarkers for dementia: A pilot multicentre study with a recommended methodological framework for magnetoencephalography

Author

Laura E. Hughes, Richard N. Henson, Ernesto Pereda, Ricardo Bruña, David López‐Sanz, Andrew J. Quinn, Mark W. Woolrich, Anna C. Nobre, James B. Rowe, Fernando Maestú, and the BioFIND Working Group

Subjects

Magnetoencephalography, Multi‐site, Mild cognitive impairment, Spectral analysis, Functional connectivity, Harmonization, Neurology. Diseases of the nervous system, RC346-429, Geriatrics, RC952-954.6

Abstract

Abstract Introduction An increasing number of studies are using magnetoencephalography (MEG) to study dementia. Here we define a common methodological framework for MEG resting‐state acquisition and analysis to facilitate the pooling of data from different sites. Methods Two groups of patients with mild cognitive impairment (MCI, n = 84) and healthy controls (n = 84) were combined from three sites, and site and group differences inspected in terms of power spectra and functional connectivity. Classification accuracy for MCI versus controls was compared across three different types of MEG analyses, and compared with classification based on structural MRI. Results The spectral analyses confirmed frequency‐specific differences in patients with MCI, both in power and connectivity patterns, with highest classification accuracy from connectivity. Critically, site acquisition differences did not dominate the results. Discussion This work provides detailed protocols and analyses that are sensitive to cognitive impairment, and that will enable standardized data sharing to facilitate large‐scale collaborative projects.

Published

2019

6. The role of transient spectral ‘bursts’ in functional connectivity: A magnetoencephalography study

Author

Zelekha A. Seedat, Andrew J. Quinn, Diego Vidaurre, Lucrezia Liuzzi, Lauren E. Gascoyne, Benjamin A.E. Hunt, George C. O’Neill, Daisie O. Pakenham, Karen J. Mullinger, Peter G. Morris, Mark W. Woolrich, and Matthew J. Brookes

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Neural oscillations dominate electrophysiological measures of macroscopic brain activity and fluctuations in these rhythms offer an insightful window on cortical excitation, inhibition, and connectivity. However, in recent years the ‘classical’ picture of smoothly varying oscillations has been challenged by the idea that many ‘oscillations’ may actually be formed from the recurrence of punctate high-amplitude bursts in activity, whose spectral composition intersects the traditionally defined frequency ranges (e.g. alpha/beta band). This finding offers a new interpretation of measurable brain activity, however neither the methodological means to detect bursts, nor their link to other findings (e.g. connectivity) have been settled. Here, we use a new approach to detect bursts in magnetoencephalography (MEG) data. We show that a time-delay embedded Hidden Markov Model (HMM) can be used to delineate single-region bursts which are in agreement with existing techniques. However, unlike existing techniques, the HMM looks for specific spectral patterns in timecourse data. We characterise the distribution of burst duration, frequency of occurrence and amplitude across the cortex in resting state MEG data. During a motor task we show how the movement related beta decrease and post movement beta rebound are driven by changes in burst occurrence. Finally, we show that the beta band functional connectome can be derived using a simple measure of burst overlap, and that coincident bursts in separate regions correspond to a period of heightened coherence. In summary, this paper offers a new methodology for burst identification and connectivity analysis which will be important for future investigations of neural oscillations.

Published

2020

7. Post-stimulus beta responses are modulated by task duration

Author

Daisie O. Pakenham, Andrew J. Quinn, Adam Fry, Susan T. Francis, Mark W. Woolrich, Matthew J. Brookes, and Karen J. Mullinger

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Modulation of beta-band neural oscillations during and following movement is a robust marker of brain function. In particular, the post-movement beta rebound (PMBR), which occurs on movement cessation, has been related to inhibition and connectivity in the healthy brain, and is perturbed in disease. However, to realise the potential of the PMBR as a biomarker, its modulation by task parameters must be characterised and its functional role determined. Here, we used MEG to image brain electrophysiology during and after a grip-force task, with the aim to characterise how task duration, in the form of an isometric contraction, modulates beta responses. Fourteen participants exerted a 30% maximum voluntary grip-force for 2, 5 and 10 s. Our results showed that the amplitude of the PMBR is modulated by task duration, with increasing duration significantly reducing PMBR amplitude and increasing its time-to-peak. No variation in the amplitude of the movement related beta decrease (MRBD) with task duration was observed. To gain insight into what may underlie these trial-averaged results, we used a Hidden Markov Model to identify the individual trial dynamics of a brain network encompassing bilateral sensorimotor areas. The rapidly evolving dynamics of this network demonstrated similar variation with task parameters to the ‘classical’ rebound, and we show that the modulation of the PMBR can be well-described in terms of increased frequency of beta events on a millisecond timescale rather than modulation of beta amplitude during this time period. Our results add to the emerging picture that, in the case of a carefully controlled paradigm, beta modulation can be systematically controlled by task parameters and such control can reveal new information as to the processes that generate the average beta timecourse. These findings will support design of clinically relevant paradigms and analysis pipelines in future use of the PMBR as a marker of neuropathology.

Published

2020

8. Spontaneous cortical activity transiently organises into frequency specific phase-coupling networks

Author

Diego Vidaurre, Laurence T. Hunt, Andrew J. Quinn, Benjamin A. E. Hunt, Matthew J. Brookes, Anna C. Nobre, and Mark W. Woolrich

Subjects

Science

Abstract

Coordination of neural activity between distant brain areas is necessary for cognition. Here, the authors report using MEG that various brain networks show dynamic phase coupling through specific frequency bands in the alpha and delta/theta range transiently during the resting state.

Published

2018

9. How Sensitive Are Conventional MEG Functional Connectivity Metrics With Sliding Windows to Detect Genuine Fluctuations in Dynamic Functional Connectivity?

Author

Lucrezia Liuzzi, Andrew J. Quinn, George C. O’Neill, Mark W. Woolrich, Matthew J. Brookes, Arjan Hillebrand, and Prejaas Tewarie

Subjects

dynamic functional connectivity, magnetoencephalography, multivariate autoregressive models, sliding window, neural mass model, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Despite advances in the field of dynamic connectivity, fixed sliding window approaches for the detection of fluctuations in functional connectivity are still widely used. The use of conventional connectivity metrics in conjunction with a fixed sliding window comes with the arbitrariness of the chosen window lengths. In this paper we use multivariate autoregressive and neural mass models with a priori defined ground truths to systematically analyze the sensitivity of conventional metrics in combination with different window lengths to detect genuine fluctuations in connectivity for various underlying state durations. Metrics of interest are the coherence, imaginary coherence, phase lag index, phase locking value and the amplitude envelope correlation. We performed analysis for two nodes and at the network level. We demonstrate that these metrics show indeed higher variability for genuine temporal fluctuations in connectivity compared to a static connectivity state superimposed by noise. Overall, the error of the connectivity estimates themselves decreases for longer state durations (order of seconds), while correlations of the connectivity fluctuations with the ground truth was higher for longer state durations. In general, metrics, in combination with a sliding window, perform poorly for very short state durations. Increasing the SNR of the system only leads to a moderate improvement. In addition, at the network level, only longer window widths were sufficient to detect plausible resting state networks that matched the underlying ground truth, especially for the phase locking value, amplitude envelope correlation and coherence. The length of these longer window widths did not necessarily correspond to the underlying state durations. For short window widths resting state network connectivity patterns could not be retrieved. We conclude that fixed sliding window approaches for connectivity can detect modulations of connectivity, but mostly if the underlying dynamics operate on moderate to slow timescales. In practice, this can be a drawback, as state durations can vary significantly in empirical data.

Published

2019

10. Task-Evoked Dynamic Network Analysis Through Hidden Markov Modeling

Author

Andrew J. Quinn, Diego Vidaurre, Romesh Abeysuriya, Robert Becker, Anna C. Nobre, and Mark W. Woolrich

Subjects

magnetoencephalography, MEG analysis, network, dynamic, hidden Markov model, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Complex thought and behavior arise through dynamic recruitment of large-scale brain networks. The signatures of this process may be observable in electrophysiological data; yet robust modeling of rapidly changing functional network structure on rapid cognitive timescales remains a considerable challenge. Here, we present one potential solution using Hidden Markov Models (HMMs), which are able to identify brain states characterized by engaging distinct functional networks that reoccur over time. We show how the HMM can be inferred on continuous, parcellated source-space Magnetoencephalography (MEG) task data in an unsupervised manner, without any knowledge of the task timings. We apply this to a freely available MEG dataset in which participants completed a face perception task, and reveal task-dependent HMM states that represent whole-brain dynamic networks transiently bursting at millisecond time scales as cognition unfolds. The analysis pipeline demonstrates a general way in which the HMM can be used to do a statistically valid whole-brain, group-level task analysis on MEG task data, which could be readily adapted to a wide range of task-based studies.

Published

2018

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

Author

Chetan Gohil, Rukuang Huang, Evan Roberts, Mats WJ van Es, Andrew J Quinn, Diego Vidaurre, and Mark W Woolrich

Subjects

oscillations, bursts, networks, dynamics, brain, machine learning, Medicine, Science, Biology (General), QH301-705.5

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.

Published

2024

12. Spatiotemporal organisation of human sensorimotor beta burst activity

Author

Catharina Zich, Andrew J Quinn, James J Bonaiuto, George O'Neill, Lydia C Mardell, Nick S Ward, and Sven Bestmann

Subjects

beta burst, sensorimotor cortex, travelling wave, oscillation, Medicine, Science, Biology (General), QH301-705.5

Abstract

Beta oscillations in human sensorimotor cortex are hallmark signatures of healthy and pathological movement. In single trials, beta oscillations include bursts of intermittent, transient periods of high-power activity. These burst events have been linked to a range of sensory and motor processes, but their precise spatial, spectral, and temporal structure remains unclear. Specifically, a role for beta burst activity in information coding and communication suggests spatiotemporal patterns, or travelling wave activity, along specific anatomical gradients. We here show in human magnetoencephalography recordings that burst activity in sensorimotor cortex occurs in planar spatiotemporal wave-like patterns that dominate along two axes either parallel or perpendicular to the central sulcus. Moreover, we find that the two propagation directions are characterised by distinct anatomical and physiological features. Finally, our results suggest that sensorimotor beta bursts occurring before and after a movement can be distinguished by their anatomical, spectral, and spatiotemporal characteristics, indicating distinct functional roles.

Published

2023

13. A dynamic system of brain networks revealed by fast transient EEG fluctuations and their fMRI correlates.

Author

Borbála Hunyadi, Mark W. Woolrich, Andrew J. Quinn 0003, Diego Vidaurre, and Maarten De Vos

Published

2019

14. Tracking dynamic brain networks using high temporal resolution MEG measures of functional connectivity.

Author

Prejaas Tewarie, Lucrezia Liuzzi, George C. O'Neill, Andrew J. Quinn 0003, Alessandra Griffa, Mark W. Woolrich, Cornelis J. Stam, Arjan Hillebrand, and Matthew J. Brookes

Published

2019

15. Do the posterior midline cortices belong to the electrophysiological default-mode network?

Author

Martin Sjøgård, Xavier De Tiège, Alison Mary, Philippe Peigneux, Serge Goldman, Guy Nagels, Jeroen Van Schependom, Andrew J. Quinn 0003, Mark W. Woolrich, and Vincent Wens

Published

2019

16. Discovering dynamic brain networks from big data in rest and task.

Author

Diego Vidaurre, Romesh G. Abeysuriya, Robert Becker, Andrew J. Quinn 0003, Fidel Alfaro-Almagro, Stephen M. Smith 0001, and Mark W. Woolrich

Published

2018

17. EMD: Empirical Mode Decomposition and Hilbert-Huang Spectral Analyses in Python.

Author

Andrew J. Quinn 0003, Vitor Lopes-dos-Santos, David Dupret, Anna Christina Nobre, and Mark W. Woolrich

Published

2021

18. How reliable are MEG resting-state connectivity metrics?

Author

Giles L. Colclough, Mark W. Woolrich, Prejaas Tewarie, Matthew J. Brookes, Andrew J. Quinn 0003, and Stephen M. Smith 0001

Published

2016

19. Spectrally resolved fast transient brain states in electrophysiological data.

Author

Diego Vidaurre, Andrew J. Quinn 0003, Adam P. Baker, David Dupret, álvaro Tejero-Cantero, and Mark W. Woolrich

Published

2016

20. Transient spectral events in resting state MEG predict individual task responses.

Author

Robert Becker, Diego Vidaurre, Andrew J. Quinn 0003, Romesh G. Abeysuriya, Owen Parker Jones, Saâd Jbabdi, and Mark W. Woolrich

Published

2020

21. SAILS: Spectral Analysis In Linear Systems.

Author

Andrew J. Quinn 0003 and Mark Hymers

Published

2020

22. Author response: Spatiotemporal organisation of human sensorimotor beta burst activity

Author

Catharina Zich, Andrew J Quinn, James J Bonaiuto, George O'Neill, Lydia C Mardell, Nick S Ward, and Sven Bestmann

Published

2023

23. Automatic decomposition of electrophysiological data into distinct nonsinusoidal oscillatory modes

Author

Andrew J. Quinn, Mark W. Woolrich, Marco S. Fabus, and Catherine E. Warnaby

Subjects

Masking (art), Computer science, Physiology, Signal, Instantaneous phase, Hilbert–Huang transform, 03 medical and health sciences, 0302 clinical medicine, Decomposition (computer science), Animals, Waveform, Mixing (physics), 030304 developmental biology, Physics, 0303 health sciences, Noise (signal processing), General Neuroscience, Non-sinusoidal waveform, Electroencephalography, Signal Processing, Computer-Assisted, Brain Waves, Electrophysiological Phenomena, Rats, Electrophysiology, Transient (oscillation), Biological system, 030217 neurology & neurosurgery

Abstract

Neurophysiological signals are often noisy, non-sinusoidal, and consist of transient bursts. Extraction and analysis of oscillatory features (such as waveform shape and cross-frequency coupling) in such datasets remains difficult. This limits our understanding of brain dynamics and its functional importance. Here, we develop Iterated Masking Empirical Mode Decomposition (itEMD), a method designed to decompose noisy and transient single channel data into relevant oscillatory modes in a flexible, fully data-driven way without the need for manual tuning. Based on Empirical Mode Decomposition (EMD), this technique can extract single-cycle waveform dynamics through phase-aligned instantaneous frequency. We test our method by extensive simulations across different noise, sparsity, and non-sinusoidality conditions. We find itEMD significantly improves the separation of data into distinct non-sinusoidal oscillatory components and robustly reproduces waveform shape across a wide range of relevant parameters. We further validate the technique on multi-modal, multi-species electrophysiological data. Our itEMD extracts known rat hippocampal theta waveform asymmetry and identifies subject-specific human occipital alpha without any prior assumptions about the frequencies contained in the signal. Notably, it does so with significantly less mode mixing compared to existing EMD-based methods. By reducing mode mixing and simplifying interpretation of EMD results, itEMD will enable new analyses into functional roles of neural signals in behaviour and disease.New & NoteworthyWe introduce a novel, data-driven method to identify oscillations in neural recordings. This approach is based on Empirical Mode Decomposition and reduces mixing of components, one of its main problems. The technique is validated and compared with existing methods using simulations and real data. We show our method better extracts oscillations and their properties in highly noisy and non-sinusoidal datasets.Running HeadDecomposition of data into non-sinusoidal oscillatory modes

Published

2021

24. The GLM-Spectrum: A multilevel framework for spectrum analysis with covariate and confound modelling

Author

Andrew J Quinn, Lauren Atkinson, Chetan Gohil, Oliver Kohl, Jemma Pitt, Catharina Zich, Anna C Nobre, and Mark W Woolrich

Abstract

Spectrum estimators that make use of averaging across time segments are ubiquitous across neuroscience. The core of this approach has not changed substantially since the 1960s, though many advances in the field of regression modelling and statistics have been made during this time. Here, we propose a new approach, the General Linear Model (GLM) Spectrum, which reframes time averaged spectral estimation as multiple regression. This brings several benefits, including the ability to do confound modelling, hierarchical modelling and significance testing via non-parametric statistics.We apply the approach to a first-level EEG resting-state dataset alternating between eyes open and eyes closed resting-state. The GLM-Spectrum can model both conditions, quantify their differences, and perform denoising through confound regression in a single step. This application is scaled up from a single channel to a whole-head recording and, finally, applied to quantify age differences across a large group-level dataset. We show that the GLM-Spectrum lends itself to rigorous modelling of within- and between-subject contrasts as well as their interactions, and that the use of model-projected spectra provides an intuitive visualisation. The GLM-Spectrum is a flexible framework for robust multi-level analysis of power spectra, with adaptive covariance and confound modelling.

Published

2022

25. Spatiotemporal organization of human sensorimotor beta burst activity

Author

Catharina Zich, Andrew J Quinn, James J Bonaiuto, George O’Neill, Lydia C Mardell, Nick S Ward, and Sven Bestmann

Abstract

Beta oscillations in human sensorimotor cortex are hallmark signatures of healthy and pathological movement. In single trials, beta oscillations include bursts of intermittent, transient periods of high-power activity. These burst events have been linked to a range of sensory and motor processes, but their precise spatial, spectral, and temporal structure remains unclear. Specifically, a role for beta burst activity in information coding and communication suggests spatiotemporal patterns, or travelling wave activity, along specific anatomical gradients. We here show in human magnetoencephalography recordings that burst activity in sensorimotor cortex occurs in planar spatiotemporal wave-like patterns that dominate along two axes either parallel or perpendicular to the central sulcus. Moreover, we find that the two propagation directions are characterised by distinct anatomical and physiological features. Finally, our results suggest that sensorimotor beta bursts occurring before and after a movement share the same generator but can be distinguished by their anatomical, spectral and spatiotemporal characteristics, indicating distinct functional roles.

Published

2022

26. Transient beta activity and cortico-muscular connectivity during sustained motor behaviour

Author

Irene Echeverria-Altuna, Andrew J. Quinn, Nahid Zokaei, Mark W. Woolrich, Anna C. Nobre, Freek van Ede, and Cognitive Psychology

Subjects

Burst, SDG 3 - Good Health and Well-being, Electromyography, General Neuroscience, Movement, Motor Cortex, Beta, Humans, Magnetoencephalography, Neural oscillation

Abstract

Neural oscillations are thought to play a central role in orchestrating activity states between distant neural populations. For example, during isometric contraction, 13–30 Hz beta activity becomes phase coupled between the motor cortex and the contralateral muscle. This and related observations have led to the proposal that beta activity and connectivity sustain stable cognitive and motor states – or the ‘status quo’ – in the brain. Recently, however, beta activity at the single-trial level has been shown to be short-lived – though so far this has been reported for regional beta activity in tasks without sustained motor demands. Here, we measured magnetoencephalography (MEG) and electromyography (EMG) in 18 human participants performing a sustained isometric contraction (gripping) task. If cortico-muscular beta connectivity is directly responsible for sustaining a stable motor state, then beta activity within single trials should be (or become) sustained in this context. In contrast, we found that motor beta activity and connectivity with the downstream muscle were transient. Moreover, we found that sustained motor requirements did not prolong beta-event duration in comparison to rest. These findings suggest that neural synchronisation between the brain and the muscle involves short ‘bursts’ of frequency-specific connectivity, even when task demands – and motor behaviour – are sustained.

Published

2022

27. Transcranial Direct Current Stimulation Alters the Waveform Shape of Cortical Gamma Oscillations

Author

Tom R. Marshall, Andrew J. Quinn, Ole Jensen, and Til Ole Bergmann

Abstract

Neuronal oscillations in different frequency bands have been linked to a wide variety of cognitive functions, and may even be a fundamental mechanism of inter-regional communication. For this reason, manipulation of oscillatory activity via brain stimulation is a central goal in neuroscience research. However, the vast majority of studies characterise oscillatory activity solely in terms of amplitude and frequency. Oscillations can also be characterised by their waveform shape; the degree to which they resemble or deviate from sinusoids. Here we exploit Empirical Mode Decomposition (EMD), a novel method that allows quantification of oscillatory waveform shape. We show for the first time that transcranial direct current stimulation (tDCS) alters the waveform shape of gamma oscillatory activity in the visual cortex. Notably, changes in waveform shape were limited to one half of the phase cycle; anodal stimulation led to a relatively slower, and cathodal to a relatively faster, descending half-wave. tDCS is generally believed to affect cortical excitability via alteration of resting membrane potential. Interestingly, simulations of altered cortical excitability in a gamma-generating neuronal population indicated the waveform shape changes observed experimentally likely stem from stimulation of pyramidal neurons. These findings have implications for understanding the neural consequences of tDCS at the level of neuronal population phenomena such as cortical oscillations and underscore the importance of waveform shape as an important feature of neuronal oscillations.

Published

2022

28. Alpha power is associated with hippocampal volume in Alzheimer’s disease: A combined MEG and MRI study

Author

Jemma Pitt, Andrew J. Quinn, Ece Kocagoncu, Melek Karadag‐Assem, Juliette Lanskey, Anastasia Klimovich‐Gray, Yun‐Ju Cheng, Vanessa Raymont, James B. Rowe, Anna Christina Nobre, and Mark W. Woolrich

Subjects

Psychiatry and Mental health, Cellular and Molecular Neuroscience, Developmental Neuroscience, Epidemiology, Health Policy, Neurology (clinical), Geriatrics and Gerontology

Published

2021

29. Decision letter: Coupling of pupil- and neuronal population dynamics reveals diverse influences of arousal on cortical processing

Author

Martin Dahl, Tzvetan Popov, and Andrew J Quinn

Published

2021

30. Within-cycle instantaneous frequency profiles report oscillatory waveform dynamics

Author

Andrew J. Quinn, N Huang, David Dupret, Juan C-H., Yeh J-R., Mark W. Woolrich, Liang W-K., V Lopes Dos Santos, and A De Ozorio Nobre

Subjects

Oscillations, Physiology, Phase (waves), Waveform Shape, Local field potential, Shape dynamics, Instantaneous phase, Article, Hilbert–Huang transform, Mice, 03 medical and health sciences, 0302 clinical medicine, EMD, Animals, Waveform, Theta Rhythm, CA1 Region, Hippocampal, 030304 developmental biology, Physics, 0303 health sciences, Oscillation, General Neuroscience, Non-sinusoidal waveform, Instantaneous Frequency, Electroencephalography, Signal Processing, Computer-Assisted, Brain Waves, Amplitude, Non-sinusoidal, Biological system, 030217 neurology & neurosurgery

Abstract

Non-sinusoidal waveform is emerging as an important feature of neuronal oscillations. However, the role of single cycle shape dynamics in rapidly unfolding brain activity remains unclear. Here, we develop an analytical framework that isolates oscillatory signals from time-series using masked Empirical Mode Decomposition to quantify dynamical changes in the shape of individual cycles (along with amplitude, frequency and phase) using instantaneous frequency. We show how phase-alignment, a process of projecting cycles into a regularly sampled phase-grid space, makes it possible to compare cycles of different durations and shapes. ‘Normalised shapes’ can then be constructed with high temporal detail whilst accounting for differences in both duration and amplitude. We find that the instantaneous frequency tracks non-sinusoidal shapes in both simulated and real data. Notably, in local field potential recordings of mouse hippocampal CA1, we find that theta oscillations have a stereotyped slow-descending slope in the cycle-wise average, yet exhibiting high variability on a cycle-by-cycle basis. We show how Principal Components Analysis allows identification of motifs of theta cycle waveform that have distinct associations to cycle amplitude, cycle duration and animal movement speed. By allowing investigation into oscillation shape at high temporal resolution, this analytical framework will open new lines of enquiry into how neuronal oscillations support moment-by-moment information processing and integration in brain networks.

Published

2021

31. A dynamic system of brain networks revealed by fast transient EEG fluctuations and their fMRI correlates

Author

Diego Vidaurre, M. De Vos, Mark W. Woolrich, Andrew J. Quinn, and Borbála Hunyadi

Subjects

Computer science, Cognitive Neuroscience, Models, Neurological, ROBUST, Neuroimaging, Electroencephalography, Brain mapping, 050105 experimental psychology, 03 medical and health sciences, REMOVAL, ARTIFACTS, 0302 clinical medicine, medicine, Humans, 0501 psychology and cognitive sciences, ELECTROPHYSIOLOGICAL SIGNATURES, RESTING-STATE NETWORKS, Brain Mapping, Science & Technology, INDEPENDENT COMPONENT ANALYSIS, medicine.diagnostic_test, Resting state fMRI, STOCHASTIC-MODEL, Functional connectivity, Radiology, Nuclear Medicine & Medical Imaging, 05 social sciences, Neurosciences, Brain, SPATIOTEMPORAL DYNAMICS, Magnetic resonance imaging, FUNCTIONAL CONNECTIVITY, HEMODYNAMIC-RESPONSE, Magnetic Resonance Imaging, Markov Chains, Electrophysiology, Neurology, Neurosciences & Neurology, Nerve Net, Functional magnetic resonance imaging, Life Sciences & Biomedicine, Neuroscience, 030217 neurology & neurosurgery

Abstract

Resting state brain activity has become a significant area of investigation in human neuroimaging. An important approach for understanding the dynamics of neuronal activity in the resting state is to use complementary imaging modalities. Electrophysiological recordings can access fast temporal dynamics, while functional magnetic resonance imaging (fMRI) studies reveal detailed spatial patterns. However, the relationship between these two measures is not fully established. In this study, we used simultaneously recorded electroencephalography (EEG) and fMRI, along with Hidden Markov Modelling, to investigate how network dynamics at fast sub-second time-scales, accessible with EEG, link to the slower time-scales and higher spatial detail of fMRI. We found that the fMRI correlates of fast transient EEG dynamic networks show highly reproducible spatial patterns, and that their spatial organization exhibits strong similarity with traditional fMRI resting state networks maps. This further demonstrates the potential of electrophysiology as a tool for understanding the fast network dynamics that underlie fMRI resting state networks. ispartof: NEUROIMAGE vol:185 pages:72-82 ispartof: location:United States status: published

Published

2019

32. Human motor cortical gamma activity relates to GABAergic signalling and to behaviour

Author

Emily L. Hinson, Catharina Zich, Martin A. Nowak, Andrew J. Quinn, Mark W. Woolrich, and Charlotte J. Stagg

Subjects

Neocortex, medicine.diagnostic_test, medicine.medical_treatment, Hippocampus, Magnetoencephalography, Biology, Transcranial magnetic stimulation, medicine.anatomical_structure, Brain stimulation, medicine, Primary motor cortex, Motor learning, Neuroscience, Motor cortex

Abstract

Gamma activity (γ, >30 Hz) is universally demonstrated across brain regions and species. However, the physiological basis and functional role of γ sub-bands (slow-γ, mid-γ, fast-γ) have been predominantly studied in rodent hippocampus; γ activity in the human neocortex is much less well understood.Here we combined neuroimaging and non-invasive brain stimulation to examine the properties of γ activity sub-bands in the primary motor cortex (M1), and their relationship to both local GABAergic activity and to motor learning. In 33 healthy individuals, we quantified movement-related γ activity in M1 using magnetoencephalography, assessed GABAergic signaling using transcranial magnetic stimulation (TMS), and estimated motor learning via a serial reaction time task.We characterised two distinct γ sub-bands (slow-γ, mid-γ) which show movement-related increase in activity during unilateral index finger movements and are characterised by distinct temporal-spectral-spatial profiles. Bayesian correlation analysis revealed strong evidence for a positive relationship between slow-γ (∼30-60Hz) peak frequency and endogenous GABA signalling during movement preparation (as assessed using the TMS-metric short interval intracortical inhibition). There was also moderate evidence for a relationship between power of the movement-related mid-γ activity (60-90Hz) and motor learning. These relationships were neurochemically- and frequency-specific.These data provide new insights into the neurophysiological basis and functional roles of γ activity in human M1 and allow the development of a new theoretical framework for γ activity in the human neocortex.Significance StatementGamma (γ) activity is ubiquitous in the brain, yet our understanding of the mechanisms and function of γ activity in the human neocortex, and particularly in the human motor cortex, is limited. Using a multimodal approach, we characterised two patterns of movement-related γ activity in the human motor cortex (slow-γ and mid-γ), with different spatial, temporal and spectral properties. Slow-γ peak frequency was correlated to local GABA-A activity, whereas mid-gamma power predicted performance in a subsequent motor learning task. Based on these findings and previous research, we propose a theoretical framework to explain how human motor cortical γ activities may arise and their potential role in plasticity and motor learning, providing new hypotheses to be tested in future studies.Key PointsWe combined neuroimaging (i.e. MEG) and non-invasive brain stimulation (i.e. TMS) to examine the properties of γ activity sub-bands in the primary motor cortex.Two distinct γ sub-bands (slow-γ, mid-γ) show a movement-related increase in activity during finger movements and are characterised by distinct temporal-spectral-spatial profiles.We found strong evidence for a positive relationship between slow-γ (∼30-60Hz) peak frequency and endogenous GABA signalling during movement preparation (as assessed using the TMS-metric short interval intracortical inhibition).

Published

2021

33. Rhythmic modulation of visual perception by continuous rhythmic auditory stimulation

Author

Andrew J. Quinn, Freek van Ede, Anna-Katharina R. Bauer, Anna C. Nobre, and Cognitive Psychology

Subjects

Adult, Male, Periodicity, Visual perception, SDG 16 - Peace, genetic structures, media_common.quotation_subject, Behavioral/Cognitive, Frequency-modulated sounds, Sensory system, neural entrainment, Stimulus (physiology), Electroencephalography, multisensory perception, Young Adult, Stimulus modality, Rhythm, Perception, medicine, rhythmic attentional sampling, Humans, Eeg, EEG, Research Articles, media_common, Visual Cortex, Cross-modal influences, medicine.diagnostic_test, General Neuroscience, Multisensory perception, SDG 16 - Peace, Justice and Strong Institutions, Association Learning, Entrainment (biomusicology), Justice and Strong Institutions, Rhythmic attentional sampling, Acoustic Stimulation, Neural entrainment, Visual Perception, frequency-modulated sounds, Female, cross-modal influences, Psychology, Entrainment (chronobiology), Neuroscience

Abstract

At any given moment our sensory systems receive multiple, often rhythmic, inputs from the environment. Processing of temporally structured events in one sensory modality can guide both behavioural and neural processing of events in other sensory modalities, but whether this occurs remains unclear. Here, we used human electroencephalography (EEG) to test the cross-modal influences of a continuous auditory frequency-modulated (FM) sound on visual perception and visual cortical activity. We report systematic fluctuations in perceptual discrimination of brief visual stimuli in line with the phase of the FM sound. We further show that this rhythmic modulation in visual perception is related to an accompanying rhythmic modulation of neural activity recorded over visual areas. Importantly, in our task, perceptual and neural visual modulations occurred without any abrupt and salient onsets in the energy of the auditory stimulation and without any rhythmic structure in the visual stimulus. As such, the results provide a critical validation for the existence and functional role of cross-modal entrainment and demonstrates its utility for organising the perception of multisensory stimulation in the natural environment.Significance StatementOur sensory environment is filled with rhythmic structures that are often multi-sensory in nature. Here we show that the alignment of neural activity to the phase of an auditory frequency-modulated sound has cross-modal consequences for vision: yielding systematic fluctuations in perceptual discrimination of brief visual stimuli that is mediated by accompanying rhythmic modulation of neural activity recorded over visual areas. These cross-modal effects on visual neural activity and perception occurred without any abrupt and salient onsets in the energy of the auditory stimulation and without any rhythmic structure in the visual stimulus. The current work shows that continuous auditory fluctuations in the natural environment can provide a pacing signal for neural activity and perception across the senses.

Published

2021

34. Decision letter: The structural connectome constrains fast brain dynamics

Author

Andrew J Quinn and George O'Neill

Published

2021

35. Transient beta activity and connectivity during sustained motor behaviour

Author

Mark W. Woolrich, Anna C. Nobre, Andrew J. Quinn, Nahid Zokaei, Freek van Ede, and I Echeverria-Altuna

Subjects

medicine.anatomical_structure, Resting state fMRI, medicine.diagnostic_test, medicine, Cognition, Context (language use), Electromyography, Isometric exercise, Magnetoencephalography, Biology, Beta (finance), Neuroscience, Motor cortex

Abstract

Neural oscillations are thought to play a central role in orchestrating activity states between distant neural populations. In humans, long-range neural connectivity has been particularly well characterised for 13-30 Hz beta activity which becomes phase coupled between the motor cortex and the contralateral muscle during isometric contraction. Based on this and related observations, beta activity and connectivity have been linked to sustaining stable cognitive and motor states – or the ‘status quo’ – in the brain. Recently, however, beta activity has been shown to be short-lived, as opposed to sustained – though so far this has been reported for regional beta activity in tasks without sustained motor demands. Here, we measured magnetoencephalography (MEG) and electromyography (EMG) in 18 human participants performing an isometric-contraction (gripping) task designed to yield sustained behavioural output. If cortico-muscular beta connectivity is directly responsible for sustaining a stable motor state, then beta activity should be (or become) sustained in this context. In contrast, we found that beta activity and connectivity with the downstream muscle were transient, even when participants engaged in sustained gripping. Moreover, we found that sustained motor requirements did not prolong beta-event duration in comparison to rest. These findings suggest that long-range neural synchronisation may entail short ‘bursts’ of frequency-specific connectivity, even when task demands – and behaviour – are sustained.HighlightsTrial-average 13-30 Hz beta activity and connectivity with the muscle appear sustained during stable motor behaviourSingle-trial beta activity and connectivity are short-lived, even when motor behaviour is sustainedSustained task demands do not prolong beta-event duration in comparison to resting state

Published

2021

36. Dynamic analysis on simultaneous iEEG-MEG data via hidden Markov Model

Author

Umesh Vivekananda, Bomin Sun, Siqi Zhang, Mark W. Woolrich, Chunyan Cao, Shikun Zhan, Andrew J. Quinn, Wei Liu, Vladimir Litvak, and Qing Lu

Subjects

Adult, Data Analysis, Male, Oscillations, Adolescent, Brain activity and meditation, Computer science, Cognitive Neuroscience, Neurosciences. Biological psychiatry. Neuropsychiatry, Context (language use), Local field potential, Intracranial Electroencephalography, Article, 050105 experimental psychology, Temporal lobe, Correlation, Young Adult, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, medicine, Humans, 0501 psychology and cognitive sciences, Ictal, Resting state, Hidden Markov model, Independence (probability theory), Resting state fMRI, medicine.diagnostic_test, business.industry, 05 social sciences, Brain, Magnetoencephalography, Pattern recognition, Middle Aged, medicine.disease, Markov Chains, Dynamics, Group analysis, Neurology, Female, Electrocorticography, Artificial intelligence, business, 030217 neurology & neurosurgery, RC321-571, Human

Abstract

Highlights • We applied Hidden Markov Model (HMM) to concurrent MEG and intracranial EEG (iEEG). • Epilepsy cohort HMM analysis yielded states similar to those of healthy subjects. • iEEG power correlated with the time course of HMM states. • Functional clusters of iEEG electrodes agreed with those based on spatial location. • Our pipeline can be used for group analysis of concurrent MEG and invasive data., Background Intracranial electroencephalography (iEEG) recordings are used for clinical evaluation prior to surgical resection of the focus of epileptic seizures and also provide a window into normal brain function. A major difficulty with interpreting iEEG results at the group level is inconsistent placement of electrodes between subjects making it difficult to select contacts that correspond to the same functional areas. Recent work using time delay embedded hidden Markov model (HMM) applied to magnetoencephalography (MEG) resting data revealed a distinct set of brain states with each state engaging a specific set of cortical regions. Here we use a rare group dataset with simultaneously acquired resting iEEG and MEG to test whether there is correspondence between HMM states and iEEG power changes that would allow classifying iEEG contacts into functional clusters. Methods Simultaneous MEG-iEEG recordings were performed at rest on 11 patients with epilepsy whose intracranial electrodes were implanted for pre-surgical evaluation. Pre-processed MEG sensor data was projected to source space. Time delay embedded HMM was then applied to MEG time series. At the same time, iEEG time series were analyzed with time-frequency decomposition to obtain spectral power changes with time. To relate MEG and iEEG results, correlations were computed between HMM probability time courses of state activation and iEEG power time course from the mid contact pair for each electrode in equally spaced frequency bins and presented as correlation spectra for the respective states and iEEG channels. Association of iEEG electrodes with HMM states based on significant correlations was compared to that based on the distance to peaks in subject-specific state topographies. Results Five HMM states were inferred from MEG. Two of them corresponded to the left and the right temporal activations and had a spectral signature primarily in the theta/alpha frequency band. All the electrodes had significant correlations with at least one of the states (p

Published

2021

37. Subjective SES is associated with children’s neurophysiological response to auditory oddballs

Author

Edwin S. Dalmaijer, Alexander L. Anwyl-Irvine, Andrew J. Quinn, Duncan E. Astle, Amy Johnson, Anwyl-Irvine, Alexander [0000-0002-3792-7745], Astle, Duncan [0000-0002-7042-5392], and Apollo - University of Cambridge Repository

Subjects

Sensory processing, medicine.medical_treatment, media_common.quotation_subject, 050105 experimental psychology, Developmental psychology, socioeconomic status, 03 medical and health sciences, 0302 clinical medicine, Reading (process), auditory oddball, medicine, Semantic memory, 0501 psychology and cognitive sciences, Association (psychology), Socioeconomic status, General Environmental Science, media_common, MEG, 05 social sciences, Information processing, Cognition, Language development, General Earth and Planetary Sciences, Original Article, Psychology, language development, phonological processing, 030217 neurology & neurosurgery

Abstract

Language and reading acquisitions are strongly associated with a child’s socioeconomic status (SES). There are a number of potential explanations for this relationship. We explore one potential explanation—a child’s SES is associated with how children discriminate word-like sounds (i.e., phonological processing), a foundational skill for reading acquisition. Magnetoencephalography data from a sample of 71 children (aged 6 years and 11 months–12 years and 3 months), during a passive auditory oddball task containing word and nonword deviants, were used to test “where” (which sensors) and “when” (at what time) any association may occur. We also investigated associations between cognition, education, and this neurophysiological response. We report differences in the neural processing of word and nonword deviant tones at an early N200 component (likely representing early sensory processing) and a later P300 component (likely representing attentional and/or semantic processing). More interestingly we found “parental subjective” SES (the parents rating of their own relative affluence) was convincingly associated with later responses, but there were no significant associations with equivalized income. This suggests that the SES as rated by their parents is associated with underlying phonological detection skills. Furthermore, this correlation likely occurs at a later time point in information processing, associated with semantic and attentional processes. In contrast, household income is not significantly associated with these skills. One possibility is that the subjective assessment of SES is more impactful on neural mechanisms of phonological processing than the less complex and more objective measure of household income.

Published

2021

38. Reduced cortico-muscular beta coupling in Parkinson’s disease predicts motor impairment

Author

Nahid Zokaei, Freek van Ede, Andrew J. Quinn, Anna C. Nobre, Masud Husain, and Michele T.M. Hu

Subjects

musculoskeletal diseases, magnetoencephalography, medicine.medical_specialty, Parkinson's disease, Disease, Grip strength, Physical medicine and rehabilitation, Forearm, cortico-muscular coherence, Motor system, Medicine, Beta (finance), medicine.diagnostic_test, AcademicSubjects/SCI01870, business.industry, General Engineering, Coherence (statistics), Magnetoencephalography, medicine.disease, body regions, Coupling (electronics), medicine.anatomical_structure, nervous system, Parkinson’s disease, Original Article, AcademicSubjects/MED00310, medicine.symptom, business, Muscle contraction, Motor cortex

Abstract

Long-range communication through the motor system is thought to be facilitated by phase coupling between neural activity in the 15–30 Hz beta range. During periods of sustained muscle contraction (grip), such coupling is manifest between motor cortex and the contralateral forearm muscles—measured as the cortico-muscular coherence. We examined alterations in cortico-muscular coherence in individuals with Parkinson’s disease, while equating grip strength between individuals with Parkinson’s disease (off their medication) and healthy control participants. We show a marked reduction in beta cortico-muscular coherence in the Parkinson’s disease group, even though the grip strength was comparable between the two groups. Moreover, the reduced cortico-muscular coherence was related to motor symptoms, so that individuals with lower cortico-muscular coherence also displayed worse motor symptoms. These findings highlight the cortico-muscular coherence as a simple, effective and clinically relevant neural marker of Parkinson’s disease pathology, with the potential to aid monitoring of disease progression and the efficacy of novel treatments for Parkinson’s disease., Zokaei et al. report reduced cortico-muscular coherence—coupling between cortex and muscle—in individuals with Parkinson’s disease compared to controls, during well-equated muscle contraction between the two groups. This reduction is related to motor symptoms in patients. This measure can provide a sensitive and objective measure of disease-related motor deficits., Graphical Abstract Graphical Abstract

Published

2021

39. INAPPROPRIATE USE OF PROTON PUMP INHIBITORS IN HOSPITALIZED PATIENTS WITH LOWER GASTROINTESTINAL BLEEDING

Author

Andrew J. Quinn, Hannah Saven, Rozina Haile, Seung Jae Moon, April Lee, and Savanna Thor

Subjects

Gastroenterology, Radiology, Nuclear Medicine and imaging

Published

2022

40. Dissecting transient burst events

Author

Lydia C. Mardell, Sven Bestmann, Andrew J. Quinn, Catharina Zich, and Nick S. Ward

Subjects

burst events, Forum, Cognitive Neuroscience, 05 social sciences, Experimental and Cognitive Psychology, 050105 experimental psychology, 03 medical and health sciences, Neural activity, 0302 clinical medicine, Neuropsychology and Physiological Psychology, oscillations, 0501 psychology and cognitive sciences, multidimensional, Transient (oscillation), Psychology, Spatial domain, Neuroscience, 030217 neurology & neurosurgery

Abstract

Increasing efforts are being made to understand the role of intermittent, transient, high-power burst events of neural activity. These events have a temporal, spectral, and spatial domain. Here, we argue that considering all three domains is crucial to fully reveal the functional relevance of these events in health and disease.

Published

2020

41. Rapid evolution drives the rise and fall of carbapenem resistance during an acute Pseudomonas aeruginosa infection

Author

Jessica Hedge, Craig MacLean, Herman Goossens, Alexey Ruzin, Leen Timbermont, C. Recanatini, Basil Britto Xavier, J. Diaz Caballero, T. Van der Schalk, E. del Barrio-Tofino, Andrew J. Quinn, Gabriel Torrens, Surbhi Malhotra-Kumar, Rachel M. Wheatley, Jan Kluytmans, Natalia Kapel, Christine Lammens, Felipe Fernández-Cuenca, Omar Ali, Carla López-Causapé, A. Arenzana, Samir Kumar-Singh, Frangiscos Sifakis, and Antonio Oliver

Subjects

education.field_of_study, Pseudomonas aeruginosa, medicine.drug_class, Population, Antibiotics, Pathogenic bacteria, Biology, medicine.disease_cause, Meropenem, Microbiology, Colistin, medicine, Efflux, education, Pathogen, medicine.drug

Abstract

It is well established that antibiotic treatment selects for resistance in pathogenic bacteria. However, the evolutionary responses of pathogen populations to antibiotic treatment during infections remain poorly resolved, especially in acute infections. Here we map the evolutionary responses to treatment in high definition through genomic and phenotypic characterization of >100 isolates from a patient with P. aeruginosa pneumonia. Antibiotic therapy (meropenem, colistin) caused a rapid crash of the P. aeruginosa population in the lung, but this decline was followed by the spread of meropenem resistance mutations that restrict antibiotic uptake (oprD) or modify LPS biosynthesis (wbpM). Low fitness strains with high-level meropenem resistance (oprD) were then replaced by high fitness strains with ‘anti-resistance’ mutations in the MexAB-OprM efflux pump, causing a rapid decline in resistance to both meropenem and a collateral loss of resistance to a broad spectrum of antibiotics. In contrast, we did not observe any evolutionary responses to antibiotic treatment in the intestinal population of P. aeruginosa. Carbapenem antibiotics are key to the treatment of infections caused by Gram negative pathogens, and our work highlights the ability of natural selection to drive both the rapid rise and fall of carbapenem resistance during acute infections.

Published

2020

42. Delineating single subject oscillatory brain networks with Spatio-Spectral Eigenmodes

Author

Mark Hymers, Green Ggr., and Andrew J. Quinn

Subjects

Human Connectome Project, Quantitative Biology::Neurons and Cognition, Autoregressive model, Resting state fMRI, Oscillation, Computer science, Component (UML), Feature (machine learning), Biological system, Transfer function

Abstract

The spatial and spectral structure of oscillatory networks in the brain provide a readout of the underlying neuronal function. Within and between subject variability in these networks can be highly informative but also poses a considerable analytic challenge. Here, we describe a method that simultaneously estimate spectral and spatial network structure without assumptions about either feature distorting estimation of the other. This enables analyses exploring how variability in the frequency and spatial structure of oscillatory networks might vary both across the brain and across individuals. The method performs a modal decomposition of an autoregressive model to describe the oscillatory signals present within a time-series based on their peak frequency and damping time. Moreover, an alternate mathematical formulation for the system transfer function can be written in terms of these oscillatory modes; describing the spatial topography and network structure of each component. We define a set of Spatio-Spectral Eigenmodes (SSEs) from these parameters to provide a parsimonious description of oscillatory networks. Crucially, the SSEs preserve the rich between-subject variability and are constructed without pre-averaging within specified frequency bands or limiting analyses to single channels or regions. After validating the method on simulated data, we explore the structure of whole brain oscillatory networks in eyes-open resting state MEG data from the Human Connectome Project. We are able to show a wide variability in peak frequency and network structure of alpha oscillations and reveal a distinction between occipital ‘high-frequency alpha’ and parietal ‘low-frequency alpha’. The frequency difference between occipital and parietal alpha components is present within individual participants but is partially masked by larger between subject variability; a 10Hz oscillation may represent the high-frequency occipital component in one participant and the low-frequency parietal component in another. This rich characterisation of individual neural phenotypes has the potential to enhance analyses into the relationship between neural dynamics and a person’s behavioural, cognitive or clinical state

Published

2020

43. The psychological correlates of distinct neural states occurring during wakeful rest

Author

Daniel S. Margulies, Theodoros Karapanagiotidis, Thomas E. Nichols, Andrew J. Quinn, Robert Leech, Nerissa S.P. Ho, Giulia L. Poerio, Mark W. Woolrich, Diego Vidaurre, Deniz Vatansever, Boris C. Bernhardt, Elizabeth Jefferies, Adam Turnbull, Jonathan Smallwood, University of York [York, UK], Fudan University [Shanghai], King‘s College London, McConnell Brain Imaging Center (BIC), McGill University = Université McGill [Montréal, Canada], Institut du Cerveau et de la Moëlle Epinière = Brain and Spine Institute (ICM), Institut National de la Santé et de la Recherche Médicale (INSERM)-CHU Pitié-Salpêtrière [AP-HP], Sorbonne Université (SU)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Department of Statistics [Warwick], and University of Warwick [Coventry]

Subjects

Adult, Male, Computer science, media_common.quotation_subject, Rest, Variation (game tree), Space (commercial competition), 050105 experimental psychology, Article, Task (project management), Neural activity, 03 medical and health sciences, 0302 clinical medicine, Cognition, Discriminative model, Humans, 0501 psychology and cognitive sciences, Wakefulness, Function (engineering), Set (psychology), media_common, Retrospective Studies, Cognitive science, Rest (physics), Hierarchy, Multidisciplinary, Resting state fMRI, Continuum (topology), Repertoire, [SCCO.NEUR]Cognitive science/Neuroscience, 05 social sciences, Cognitive neuroscience, Magnetic Resonance Imaging, Markov Chains, Dynamics (music), Female, Psychology, Neurocognitive, 030217 neurology & neurosurgery, Cognitive psychology, Neuroscience

Abstract

When unoccupied by an explicit external task, humans engage in a wide range of different types of self-generated thinking. These are often unrelated to the immediate environment and have unique psychological features. Although contemporary perspectives on ongoing thought recognise the heterogeneity of these self-generated states, we lack both a clear understanding of how to classify the specific states, and how they can be mapped empirically. In the current study, we capitalise on advances in machine learning that allow continuous neural data to be divided into a set of distinct temporally re-occurring patterns, or states. We applied this technique to a large set of resting state data in which we also acquired retrospective descriptions of the participants’ experiences during the scan. We found that two of the identified states were predictive of patterns of thinking at rest. One state highlighted a pattern of neural activity commonly seen during demanding tasks, and the time individuals spent in this state was associated with descriptions of experience focused on problem solving in the future. A second state was associated with patterns of activity that are commonly seen under less demanding conditions, and the time spent in it was linked to reports of intrusive thoughts about the past. Finally, we found that these two neural states tended to fall at either end of a neural hierarchy that is thought to reflect the brain’s response to cognitive demands. Together, these results demonstrate that approaches which take advantage of time-varying changes in neural function can play an important role in understanding the repertoire of self-generated states. Moreover, they establish that important features of self-generated ongoing experience are related to variation along a similar vein to those seen when the brain responds to cognitive task demands.

Published

2020

44. Tau pathology in early Alzheimer's disease is linked to selective disruptions in neurophysiological network dynamics

Author

James B. Rowe, Deep, Simon Lovestone, Andrew J. Quinn, Richard N. Henson, Elisa Cooper, Ece Kocagoncu, Mark W. Woolrich, Gary G. R. Green, Azadeh Firouzian, Andrea Greve, Roger N. Gunn, Kocagoncu, Ece [0000-0002-6292-7472], Cooper, Elisa [0000-0003-3259-4408], Henson, Rik [0000-0002-0712-2639], Rowe, James [0000-0001-7216-8679], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Male, Aging, Disease, Synaptic Transmission, Deep and Frequent Phenotyping study team, 0302 clinical medicine, Cognition, Parietal Lobe, Aged, 80 and over, Connectivity, MEG, General Neuroscience, Magnetoencephalography, Middle Aged, Alzheimer's disease, Molecular Imaging, Female, Occipital Lobe, Tau pathology, Tau protein, tau Proteins, Biology, Protein Aggregation, Pathological, Article, 03 medical and health sciences, Alzheimer Disease, mental disorders, medicine, Dementia, Humans, Aged, Neurology & Neurosurgery, Disease mechanisms, 1103 Clinical Sciences, Neurophysiology, medicine.disease, Network dynamics, Graph theory, 030104 developmental biology, PET, Positron-Emission Tomography, biology.protein, Neurology (clinical), Geriatrics and Gerontology, Tau, Centrality, 1109 Neurosciences, Neuroscience, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Understanding the role of Tau protein aggregation in the pathogenesis of Alzheimer's disease is critical for the development of new Tau-based therapeutic strategies to slow or prevent dementia. We tested the hypothesis that Tau pathology is associated with functional organization of widespread neurophysiological networks. We used electro-magnetoencephalography with [18F]AV-1451 PET scanning to quantify Tau-dependent network changes. Using a graph theoretical approach to brain connectivity, we quantified nodal measures of functional segregation, centrality, and the efficiency of information transfer and tested them against levels of [18F]AV-1451. Higher Tau burden in early Alzheimer's disease was associated with a shift away from the optimal small-world organization and a more fragmented network in the beta and gamma bands, whereby parieto-occipital areas were disconnected from the anterior parts of the network. Similarly, higher Tau burden was associated with decreases in both local and global efficiency, especially in the gamma band. The results support the translational development of neurophysiological “signatures” of Alzheimer's disease, to understand disease mechanisms in humans and facilitate experimental medicine studies., Highlights • Alzheimer tau pathology linked to neurophysiological impairments in humans. • Higher Tau burden is linked to disconnection of posterior parts of the brain. • Higher Tau burden is linked to declines in local and global efficiency in gamma. • Eigenvector centrality of the occipital lobe shows declines in only 6 months.

Published

2020

45. The role of transient spectral ‘bursts’ in functional connectivity: A magnetoencephalography study

Author

George C. O'Neill, Matthew J. Brookes, Andrew J. Quinn, Mark W. Woolrich, Peter G. Morris, Hunt Bae., Daisie O. Pakenham, Karen J. Mullinger, Zelekha A. Seedat, Lauren E. Gascoyne, Lucrezia Liuzzi, and Diego Vidaurre

Subjects

Adult, Male, Brain activity and meditation, Cognitive Neuroscience, 050105 experimental psychology, lcsh:RC321-571, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Rhythm, Coincident, Connectome, medicine, Humans, 0501 psychology and cognitive sciences, Hidden Markov model, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Cerebral Cortex, Physics, medicine.diagnostic_test, Resting state fMRI, Quantitative Biology::Neurons and Cognition, 05 social sciences, Magnetoencephalography, Middle Aged, Brain Waves, Amplitude, Pattern Recognition, Visual, Neurology, Female, Nerve Net, Neuroscience, Psychomotor Performance, 030217 neurology & neurosurgery, Coherence (physics)

Abstract

Neural oscillations dominate electrophysiological measures of macroscopic brain activity and fluctuations in these rhythms offer an insightful window on cortical excitation, inhibition, and connectivity. However, in recent years the ‘classical’ picture of smoothly varying oscillations has been challenged by the idea that many ‘oscillations’ may actually be formed from the recurrence of punctate high-amplitude bursts in activity, whose spectral composition intersects the traditionally defined frequency ranges (e.g. alpha/beta band). This finding offers a new interpretation of measurable brain activity, however neither the methodological means to detect bursts, nor their link to other findings (e.g. connectivity) have been settled. Here, we use a new approach to detect bursts in magnetoencephalography (MEG) data. We show that a time-delay embedded Hidden Markov Model (HMM) can be used to delineate single-region bursts which are in agreement with existing techniques. However, unlike existing techniques, the HMM looks for specific spectral patterns in timecourse data. We characterise the distribution of burst duration, frequency of occurrence and amplitude across the cortex in resting state MEG data. During a motor task we show how the movement related beta decrease and post movement beta rebound are driven by changes in burst occurrence. Finally, we show that the beta band functional connectome can be derived using a simple measure of burst overlap, and that coincident bursts in separate regions correspond to a period of heightened coherence. In summary, this paper offers a new methodology for burst identification and connectivity analysis which will be important for future investigations of neural oscillations.

Published

2020

46. Impaired corticomuscular and interhemispheric cortical beta oscillation coupling in amyotrophic lateral sclerosis

Author

Andrew J. Quinn, Malcolm Proudfoot, Michael Benatar, Martin R Turner, Freek van Ede, Mark W. Woolrich, Giles L. Colclough, Joanne Wuu, Kevin Talbot, and Anna C. Nobre

Subjects

Adult, Male, 0301 basic medicine, Asymptomatic, 03 medical and health sciences, 0302 clinical medicine, Forearm, Isometric Contraction, Physiology (medical), Motor system, medicine, Humans, Beta Rhythm, Amyotrophic lateral sclerosis, Aged, Aged, 80 and over, Hand Strength, medicine.diagnostic_test, business.industry, Amyotrophic Lateral Sclerosis, Motor Cortex, Magnetoencephalography, Middle Aged, medicine.disease, Sensory Systems, Peripheral, 030104 developmental biology, medicine.anatomical_structure, Neurology, Female, Neurology (clinical), Primary motor cortex, medicine.symptom, business, Neuroscience, Photic Stimulation, Psychomotor Performance, 030217 neurology & neurosurgery

Abstract

Objectives The neural activity of the primary motor cortex is variably synchronised with contralateral peripheral electromyographic signals, which is thought to facilitate long-range communication through the motor system. Such corticomuscular coherence (CMC) is typically observed in the beta-band (15–30 Hz) range during steady force production. We aimed to measure pathological alteration to CMC resulting from ALS. Methods CMC was appraised during a forearm grip task in 17 ALS patients contrasted against age-matched healthy controls. An exploratory comparison with a group of asymptomatic ALS gene carriers and neuropathy disease mimics was also undertaken. Neural signals were acquired by whole-head magnetoencephalography and localised via structural MRI to the motor cortices. Results During light voluntary muscular contraction, beta-band CMC was significantly reduced in ALS patients compared to healthy controls. Propagation of motoric beta rhythms across the cortical hemispheres was also shown to be impaired in ALS patients. CMC was preserved in the asymptomatic gene carrier and did not distinguish ALS patients from neuropathy mimics. Conclusion Functional connectivity metrics reveal an ALS-related decrease in both corticomuscular and interhemispheric communication during bilateral grip force production. Significance MEG-derived beta oscillation coupling may be a potential biomarker of motor system dysfunction in ALS, against which to measure future therapeutic efficacy.

Published

2018

47. S3153 Iron Pill Gastritis Masquerading as a Gastric Mass: An Atypical Presentation

Author

Shivakumar Vignesh, Andrew J. Quinn, Raavi Gupta, Muhammad F. Ahmed, and Richard Ferstenberg

Subjects

medicine.medical_specialty, Hepatology, business.industry, Internal medicine, Pill, Gastroenterology, Medicine, Gastric mass, Presentation (obstetrics), Gastritis, medicine.symptom, business

Published

2021

48. Delineating between-subject heterogeneity in alpha networks with Spatio-Spectral Eigenmodes

Author

Mark Hymers, Andrew J. Quinn, and Gary G. R. Green

Subjects

Computer science, Cognitive Neuroscience, Neurosciences. Biological psychiatry. Neuropsychiatry, Network, Transfer function, Article, Matrix decomposition, Superposition principle, Connectome, Humans, Spectral decomposition, Eigenmodes, Alpha oscillation, MEG, Human Connectome Project, Quantitative Biology::Neurons and Cognition, Resting state fMRI, Oscillation, Brain, Magnetoencephalography, Alpha Rhythm, Modal, Neurology, Autoregressive model, Multivariate Analysis, Neural Networks, Computer, Biological system, Autoregression, RC321-571

Abstract

Highlights • A data-driven modal decomposition describes oscillations by their resonant frequency, damping time and network structure. • We show that the full multivariate transfer function can be rewritten as a linear superposition of these modes. • These modal coordinates factorise oscillatory systems without pre-specification of frequency bands or regions of interest. • Using these modes, we find a spatial gradient in alpha peak frequency between Occipital and Parietal cortex . • This gradient is highly variable between participants, showing shifts in spatial structure and peak frequency., Between subject variability in the spatial and spectral structure of oscillatory networks can be highly informative but poses a considerable analytic challenge. Here, we describe a data-driven modal decomposition of a multivariate autoregressive model that simultaneously identifies oscillations by their peak frequency, damping time and network structure. We use this decomposition to define a set of Spatio-Spectral Eigenmodes (SSEs) providing a parsimonious description of oscillatory networks. We show that the multivariate system transfer function can be rewritten in these modal coordinates, and that the full transfer function is a linear superposition of all modes in the decomposition. The modal transfer function is a linear summation and therefore allows for single oscillatory signals to be isolated and analysed in terms of their spectral content, spatial distribution and network structure. We validate the method on simulated data and explore the structure of whole brain oscillatory networks in eyes-open resting state MEG data from the Human Connectome Project. We are able to show a wide between participant variability in peak frequency and network structure of alpha oscillations and show a distinction between occipital ’high-frequency alpha’ and parietal ’low-frequency alpha’. The frequency difference between occipital and parietal alpha components is present within individual participants but is partially masked by larger between subject variability; a 10Hz oscillation may represent the high-frequency occipital component in one participant and the low-frequency parietal component in another. This rich characterisation of individual neural phenotypes has the potential to enhance analyses into the relationship between neural dynamics and a person’s behavioural, cognitive or clinical state.

Published

2021

49. Driving Human Motor Cortical Oscillations Leads to Behaviorally Relevant Changes in Local GABAAInhibition: A tACS-TMS Study

Author

Martin A. Nowak, Alek Pogosyan, Peter Brown, Charlotte J. Stagg, Andrew J. Quinn, Freek van Ede, Andrea Guerra, and Emily L. Hinson

Subjects

concurrent tACS and TMS, Adult, Male, 0301 basic medicine, tACS, GABA inhibition, medicine.medical_treatment, Transcranial Direct Current Stimulation, Inhibitory postsynaptic potential, Young Adult, 03 medical and health sciences, Concurrent tACS and TMS, Gamma oscillations, Motor excitability, Motor learning, Neuroscience (all), 0302 clinical medicine, Systems/Circuits, Interneurons, Reaction Time, medicine, Humans, Learning, Research Articles, Transcranial alternating current stimulation, Behavior, Cross-Over Studies, Electromyography, GABAA receptor, General Neuroscience, Motor Cortex, Magnetoencephalography, Motor control, Neurophysiology, Evoked Potentials, Motor, Receptors, GABA-A, Transcranial Magnetic Stimulation, Transcranial magnetic stimulation, stomatognathic diseases, 030104 developmental biology, medicine.anatomical_structure, motor excitability, Female, gamma oscillations, Psychology, motor learning, Neuroscience, Psychomotor Performance, 030217 neurology & neurosurgery, Motor cortex

Abstract

Beta and gamma oscillations are the dominant oscillatory activity in the human motor cortex (M1). However, their physiological basis and precise functional significance remain poorly understood. Here, we used transcranial magnetic stimulation (TMS) to examine the physiological basis and behavioral relevance of driving beta and gamma oscillatory activity in the human M1 using transcranial alternating current stimulation (tACS). tACS was applied using a sham-controlled crossover design at individualized intensity for 20 min and TMS was performed at rest (before, during, and after tACS) and during movement preparation (before and after tACS). We demonstrated that driving gamma frequency oscillations using tACS led to a significant, duration-dependent decrease in local resting-state GABAAinhibition, as quantified by short interval intracortical inhibition. The magnitude of this effect was positively correlated with the magnitude of GABAAdecrease during movement preparation, when gamma activity in motor circuitry is known to increase. In addition, gamma tACS-induced change in GABAAinhibition was closely related to performance in a motor learning task such that subjects who demonstrated a greater increase in GABAAinhibition also showed faster short-term learning. The findings presented here contribute to our understanding of the neurophysiological basis of motor rhythms and suggest that tACS may have similar physiological effects to endogenously driven local oscillatory activity. Moreover, the ability to modulate local interneuronal circuits by tACS in a behaviorally relevant manner provides a basis for tACS as a putative therapeutic intervention.SIGNIFICANCE STATEMENTGamma oscillations have a vital role in motor control. Using a combined tACS-TMS approach, we demonstrate that driving gamma frequency oscillations modulates GABAAinhibition in the human motor cortex. Moreover, there is a clear relationship between the change in magnitude of GABAAinhibition induced by tACS and the magnitude of GABAAinhibition observed during task-related synchronization of oscillations in inhibitory interneuronal circuits, supporting the hypothesis that tACS engages endogenous oscillatory circuits. We also show that an individual's physiological response to tACS is closely related to their ability to learn a motor task. These findings contribute to our understanding of the neurophysiological basis of motor rhythms and their behavioral relevance and offer the possibility of developing tACS as a therapeutic tool.

Published

2017

50. S3061 Progressive Gastric Siderosis and Pseudomelanosis Duodeni: Diagnostic Pitfalls and Therapeutic Implications

Author

Andrew J. Quinn, Cherif El Younis, and Brooks R. Crowe

Subjects

medicine.medical_specialty, Hepatology, Pseudomelanosis, business.industry, Gastroenterology, medicine, Siderosis, medicine.disease, business, Dermatology

Published

2020