Catharina Zich scite author profile

Neurofeedback (NF) is a research and clinical technique, characterized by live demonstration of brain activation to the subject. The technique has become increasingly popular as a tool for the training of brain self-regulation, fueled by the superiority in spatial resolution and fidelity brought along with real-time analysis of fMRI (functional magnetic resonance imaging) data, compared to the more traditional EEG (electroencephalography) approach. NF learning is a complex phenomenon and a controversial discussion on its feasibility and mechanisms has arisen in the literature. Critical aspects of the design of fMRI-NF studies include the localization of neural targets, cognitive and operant aspects of the training procedure, personalization of training, and the definition of training success, both through neural effects and (for studies with therapeutic aims) through clinical effects. In this paper, we argue that a developmental perspective should inform neural target selection particularly for pediatric populations, and different success metrics may allow in-depth analysis of NF learning. The relevance of the functional neuroanatomy of NF learning for brain target selection is discussed. Furthermore, we address controversial topics such as the role of strategy instructions, sometimes given to subjects in order to facilitate learning, and the timing of feedback. Discussion of these topics opens sight on problems that require further conceptual and empirical work, in order to improve the impact that fMRI-NF could have on basic and applied research in future.

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Real-time EEG feedback during simultaneous EEG–fMRI identifies the cortical signature of motor imagery

Zich

et al. 2015

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Unpacking Transient Event Dynamics in Electrophysiological Power Spectra

et al. 2019

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Electrophysiological recordings of neuronal activity show spontaneous and task-dependent changes in their frequency-domain power spectra. These changes are conventionally interpreted as modulations in the amplitude of underlying oscillations. However, this overlooks the possibility of underlying transient spectral ‘bursts’ or events whose dynamics can map to changes in trial-average spectral power in numerous ways. Under this emerging perspective, a key challenge is to perform burst detection, i.e. to characterise single-trial transient spectral events, in a principled manner. Here, we describe how transient spectral events can be operationalised and estimated using Hidden Markov Models (HMMs). The HMM overcomes a number of the limitations of the standard amplitude-thresholding approach to burst detection; in that it is able to concurrently detect different types of bursts, each with distinct spectral content, without the need to predefine frequency bands of interest, and does so with less dependence on a priori threshold specification. We describe how the HMM can be used for burst detection and illustrate its benefits on simulated data. Finally, we apply this method to empirical data to detect multiple burst types in a task-MEG dataset, and illustrate how we can compute burst metrics, such as the task-evoked timecourse of burst duration.

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Motor Cortical Gamma Oscillations: What Have We Learnt and Where Are We Headed?

Nowak

Zich

Stagg

2018

Curr Behav Neurosci Rep

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Purpose of ReviewAn increase in oscillatory activity in the γ-frequency band (approximately 50–100 Hz) has long been noted during human movement. However, its functional role has been difficult to elucidate. The advent of novel techniques, particularly transcranial alternating current stimulation (tACS), has dramatically increased our ability to study γ oscillations. Here, we review our current understanding of the role of γ oscillations in the human motor cortex, with reference to γ activity outside the motor system, and evidence from animal models.Recent FindingsEvidence for the neurophysiological basis of human γ oscillations is beginning to emerge. Multimodal studies, essential given the necessarily indirect measurements acquired in humans, are beginning to provide convergent evidence for the role of γ oscillations in movement, and their relationship to plasticity.SummaryHuman motor cortical γ oscillations appear to play a key role in movement, and relate to learning. However, there are still major questions to be answered about their physiological basis and precise role in human plasticity. It is to be hoped that future research will take advantage of recent technical advances and the physiological basis and functional significance of this intriguing and important brain rhythm will be fully elucidated.

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Mobile EEG and its potential to promote the theory and application of imagery-based motor rehabilitation

Kranczioch

Zich

Schierholz

et al. 2014

International Journal of Psychophysiology

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Dissecting Transient Burst Events

Zich

Quinn

Mardell

et al. 2020

Trends in Cognitive Sciences

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Wireless EEG with individualized channel layout enables efficient motor imagery training

Zich

Vos

Kranczioch

et al. 2015

Clinical Neurophysiology

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Simultaneous EEG-fNIRS reveals how age and feedback affect motor imagery signatures

Zich

Debener

Thoene

et al. 2017

Neurobiology of Aging

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Catharina Zich

Current progress in real-time functional magnetic resonance-based neurofeedback: Methodological challenges and achievements

Real-time EEG feedback during simultaneous EEG–fMRI identifies the cortical signature of motor imagery

Unpacking Transient Event Dynamics in Electrophysiological Power Spectra

Motor Cortical Gamma Oscillations: What Have We Learnt and Where Are We Headed?

Mobile EEG and its potential to promote the theory and application of imagery-based motor rehabilitation

Dissecting Transient Burst Events

Wireless EEG with individualized channel layout enables efficient motor imagery training

Simultaneous EEG-fNIRS reveals how age and feedback affect motor imagery signatures

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