A Novel Framework Using Brain Computer Interfacing & EEG Microstates To Characterize Cognitive Functionality

Shaw, Saurabh Bhaskar

January 2016

The rapid advancements in the field of machine learning and artificial intelligence has led to the emergence of technologies like the Brain Computer Interface (BCI), which has revolutionized rehabilitation protocols. However, given the neural basis of BCIs and the dependence of its performance on cognitive factors, BCIs may be used to characterize the functional capacity of the user. A resting state segment can also be considered for characterization of the functional network integrity, creating a two part framework that probes the functional networks and their cognitive manifestations. This thesis explores such a two part framework using a simultaneous EEG-fMRI setup on a healthy population. The BCI accuracies for all subjects increased over the course of the scan and is thought to be due to learning processes on the subject's part. Since such learning processes require cognitive faculties such as attention and working memory, these factors might modulate the BCI performance profile, making it a potential metric for the integrity of such cognitive factors. The resting state analysis identified four EEG Microstates that have been previously found to be associated with verbal, visual, saliency and attention reorientation tasks. The proportion of each microstate that composed the corresponding fMRI resting state networks (RSN) were identified, opening up the potential for predicting fMRI-based RSN information, from EEG microstates alone. The developed protocol can be used to diagnose potential conditions that negatively affect the functional capacity of the user by using the results from this study as healthy control data. This is the first known BCI based system for characterization of the user's functional integrity, opening up the possibility of using BCIs as a metric for diagnosing a neuropathology. / Thesis / Master of Applied Science (MASc)

Brain Computer Interfacing

Microstates

Resting State Networks

EEG-fMRI

Multimodal

Investigating the role of APOE-ε4, a risk gene for Alzheimer's disease, on functional brain networks using magnetoencephalography

Luckhoo, Henry Thomas

January 2013

Alzheimer's disease (AD) is developing into the single greatest healthcare challenge in the coming decades. The development of early and effective treatments that can prevent the pathological damage responsible for AD-related dementia is of utmost priority for healthcare authorities. The role of the APOE-ε4 genotype, which has been shown to increase an individual's risk of developing AD, is of central interest to this goal. Understanding the mechanism by which possession of this gene modulates brain function, leading to a predisposition towards AD is an active area of research. Functional connectivity (FC) is an excellent candidate for linking APOE-related differences in brain function to sites of AD pathology. Magnetoencephalography (MEG) is a neuroimaging tool that can provide a unique insight into the electrophysiology underpinning resting-state networks (RSNs) - whose dysfunction is postulated to lead to a predisposition to AD. This thesis presents a range of methods for measuring functional connectivity in MEG data. We first develop a set of novel adaptations for preprocessing MEG data and performing source reconstruction using a beamformer (chapter 3). We then develop a range of analyses for measuring FC through correlations in the slow envelope oscillations of band-limited source-space MEG data (chapter 4). We investigate the optimum time scales for detecting FC. We then develop methods for extracting single networks (using seed-based correlation) and multiple networks (using ICA). We proceed to develop a group-statistical framework for detecting spatial differences in RSNs and present a preliminary finding for APOE-genotype-dependent differences in RSNs (chapter 5). We also develop a statistical framework for quantifying task-locked temporal differences in functional networks during task-positive experiments (chapter 6). Finally, we demonstrate a data-driven parcellation and network analysis pipeline that includes a novel correction for signal leakage between parcels. We use this framework to show evidence of stationary cross-frequency FC (chapter 7).

616.831

Changes in functional connectivity due to modulation by task and disease

Madugula, Sasidhar

January 2013

Soon after the advent of signal-recording techniques in the brain, functional connectivity (FC), a measure of interregional neural interactions, became an important tool to assess brain function and its relation to structure. It was discovered that certain groups of regions in the brain corresponding to behavioural domains are organized into intrinsic networks of connectivity (ICNs). These networks were shown to exhibit high FC during rest, and also during task. ICNs are not only delineated by areas which correspond to various behaviours, but can be modulated in the long and short-term in their connectivity by disease conditions, learning, and task performance. The significance of changes in FC, permanent and transient, is poorly understood with respect to even the simplest ICNs corresponding to motor and visual regions. A better grasp on how to interpret these changes could elucidate the mechanisms and implications of patterns in FC changes during therapy and basic tasks. The aim of this work is to examine long-term changes in the connectivity of several ICNs as a result of modulation by stroke and rehabilitation, and to assess short term changes due to simple, continuous task performance in healthy volunteers. To explore long-term changes in ICN connectivity, fifteen hemiparetic stroke patients underwent resting state scanning and behavioural testing before and after a two-week session of Constraint Induced Movement Therapy (CIMT). It was found that therapy led to localized increases in FC within the sensorimotor ICN. To assess transient changes in FC with task, sixteen healthy volunteers underwent a series of scans during rest, continuous performance of a non-demanding finger-tapping task, viewing of a continuous visual stimulus, and a combined (but uncoupled) visual and motor task. Group Independent Component Analysis (ICA) revealed that canonical ICNs remained robustly connected during task conditions as well as during rest, and dual regression/seed analyses showed that visual and sensorimotor ICNs showed divergent patterns of changes in FC, with the former showing increased intra-network connectivity and the latter decreased intra-network connectivity. Additionally, it was found that task activation within ICNs has a relationship to these changes in FC. Overall, these results suggest that modulation of functional connectivity is a valuable and informative tool in the study of disease recovery and task performance.

616.8

Temporal dynamics of resting state brain connectivity as revealed by magnetoencephalography

Baker, Adam

January 2014

Explorations into the organisation of spontaneous activity within the brain have demonstrated the existence of networks of temporally correlated activity, consisting of brain areas that share similar cognitive or sensory functions. These so-called resting state networks (RSNs) emerge spontaneously during rest and disappear in response to overt stimuli or cognitive demands. In recent years, the study of RSNs has emerged as a valuable tool for probing brain function, both in the healthy brain and in disorders such as schizophrenia, Alzheimer’s disease and Parkinson’s disease. However, analyses of these networks have so far been limited, in part due to assumptions that the patterns of neuronal activity that underlie these networks remain constant over time. Moreover, the majority of RSN studies have used functional magnetic resonance imaging (fMRI), in which slow fluctuations in the level of oxygen in the blood are used as a proxy for the activity within a given brain region. In this thesis we develop the use of magnetoencephalography (MEG) to study resting state functional connectivity. Unlike fMRI, MEG provides a direct measure of neuronal activity and can provide novel insights into the temporal dynamics that underlie resting state activity. In particular, we focus on the application of non- stationary analysis methods, which are able to capture fast temporal changes in activity. We first develop a framework for preprocessing MEG data and measuring interactions within different RSNs (Chapter 3). We then extend this framework to assess temporal variability in resting state functional connectivity by applying time- varying measures of interactions and show that within-network functional connectivity is underpinned by non-stationary temporal dynamics (Chapter 4). Finally we develop a data driven approach based on a hidden Markov model for inferring short lived connectivity states from resting state and task data (Chapter 5). By applying this approach to data from multiple subjects we reveal transient states that capture short lived patterns of neuronal activity (Chapter 6).

612.8

Transcranial stimulation to enhance cortical plasticity in the healthy and stroke-affected motor system

Amadi, Ugwechi

January 2012

This thesis investigated transcranial direct current stimulation (tDCS) as applied to the motor system, and its ability to modulate underlying cortical processes and resultant motor behaviours. Functional magnetic resonance imaging (fMRI) and transcranial magnetic stimulation (TMS) were employed to assess the extent to which tDCS induces quantifiable changes in neural structure and function in controls and stroke patients. Modifications in the connectivity of intrinsic functional networks following tDCS application were examined using resting state fMRI. Polarity-specific changes were found: cathodal (inhibitory) tDCS increased the strength of the default mode network and increased functional coupling between major nodes within the motor network. No significant effects were found following anodal (excitatory) tDCS. Although anodal tDCS elicited only subtle changes in resting activity, it is known to produce robust modifications of behaviour. Single and paired-pulse TMS were used to investigate the neurophysiological underpinnings of these changes. Consistent with the theory of homeostatic plasticity, anodal tDCS applied prior to task performance increased GABAA-mediated cortical inhibition and worsened behaviour. The specificity of these changes suggests a central role for the mechanism of surround inhibition. A longitudinal clinical trial in chronic stroke patients was conducted to determine the utility of tDCS as an adjunct in motor rehabilitation. Serial MRI scans revealed that, when combined with motor training, anodal tDCS increased functional activity and grey matter in primarily ipsilesional motor areas. These brain changes were correlated with behavioural improvements in the stroke-affected upper limb. The laterality of connectivity at baseline, as measured by resting state activity and corticospinal tract integrity, was predictive of response to the rehabilitation program, particularly in those stroke patients who received tDCS. Asymmetry favouring the contralesional hemisphere predicted greater behavioural gains. Such results underscore the importance of re-normalisation of structure and functional activity toward the lesioned hemisphere in stroke rehabilitation.

Probing resting-state functional connectivity in the infant brain: methods and potentiality

Mongerson, Chandler Rebecca Lee

13 July 2017

Early brain development is characterized by rapid growth and perpetual reconfiguration, driven by a dynamic milieu of heterogeneous processes. Moreover, potent postnatal brain plasticity engenders increased vulnerability to environmental stimuli. However, little is known regarding the ontogeny and temporal manifestations of inter- and intra-regional functional connectivity that comprise functional brain networks. Recently, resting-state functional magnetic resonance imaging (fMRI) emerged as a promising non-invasive neuroinvestigative tool, measuring spontaneous fluctuations in blood oxygen level dependent (BOLD) signal at rest that reflect baseline neuronal activity. Its application has expanded to infant populations in the past decade, providing unprecedented insight into functional organization of the developing brain, as well as early biomarkers of abnormal/ disease states. However, rapid extension of the resting-state technique to infant populations leaves many methodological issues need to be resolved prior to standardization of the technique. The purpose of this thesis is to describe a protocol for intrinsic functional connectivity analysis, and extraction of resting-state networks in infants <12 months of age using the data-driven approach independent component analysis (ICA). To begin, we review the evolution of resting-state fMRI application in infant populations, including the biological premise for neural networks. Next, we present a protocol designed such that investigators without previous knowledge in the field can implement the analysis and reliably obtain viable results consistent with previous literature. Presented protocol provides detailed, albeit basic framework for RSN analysis, with interwoven discussion of basic theory behind each technique, as well as the rationale behind selecting parameters. The overarching goal is to catalyze efforts towards development of robust, infant-specific acquisition and preprocessing pipelines, as well as promote greater transparency by researchers regarding methods used. Finally, we review the literature, current methodological challenges and potential future directions for the field of infant resting-state fMRI.

Neurosciences

Functional connectivity

Functional magnetic resonance imaging

Infant

Neurodevelopment

Resting-state networks

Automatic Sleep Scoring To Study Brain Resting State Networks During Sleep In Narcoleptic And Healthy Subjects : A Combination Of A Wavelet Filter Bank And An Artificial Neural Network

Viola, Federica

January 2014

Manual sleep scoring, executed by visual inspection of the EEG, is a very time consuming activity, with an inherent subjective decisional component. Automatic sleep scoring could ease the job of the technicians, because faster and more accurate. Frequency information characterizing the main brain rhythms, and consequently the sleep stages, needs to be extracted from the EEG data. The approach used in this study involves a wavelet filter bank for the EEG frequency features extraction. The wavelet packet analysis tool in MATLAB has been employed and the frequency information subsequently used for the automatic sleep scoring by means of an artificial neural network. Finally, the automatic sleep scoring has been employed for epoching the fMRI data, thus allowing for studying brain resting state networks during sleep. Three resting state networks have been inspected; the Default Mode Network, The Attentional Network and the Salience Network. The networks functional connectivity variations have been inspected in both healthy and narcoleptic subjects. Narcolepsy is a neurobiological disorder characterized by an excessive daytime sleepiness, whose aetiology may be linked to a loss of neurons in the hypothalamic region.

Automatic Sleep Scoring

Discrete Wavelet Transform

Filter Bank

Artificial Neural Network

Resting State Networks

Narcolepsy.

Network approaches to understanding the functional effects of focal brain lesions

Hart, Michael Gavin

January 2018

Complex network models of functional connectivity have emerged as a paradigm shift in brain mapping over the past decade. Despite significant attention within the neuroimaging and cognitive neuroscience communities, these approaches have hitherto not been extensively explored in neurosurgery. The aim of this thesis is to investigate how the field of connectomics can contribute to understanding the effects of focal brain lesions and to functional brain mapping in neurosurgery. This datasets for this thesis include a clinical population with focal brain tumours and a cohort focused on healthy adolescent brain development. Multiple network analyses of increasing complexity are performed based upon resting state functional MRI. In patients with focal brain tumours, the full complement of resting state networks were apparent, while also suggesting putative patterns of network plasticity. Connectome analysis was able to identify potential signatures of node robustness and connections at risk that could be used to individually plan surgery. Focal lesions induced the formation of new hubs while down regulating previously established hubs. Overall these data are consistent with a dynamic rather than a static response to the presence of focal lesions. Adolescent brain development demonstrated discrete dynamics with distinct gender specific and age-gender interactions. Network architecture also became more robust, particularly to random removal of nodes and edges. Overall these data provide evidence for the early vulnerability rather than enhanced plasticity of brain networks. In summary, this thesis presents a combined analysis of pathological and healthy development datasets focused on understanding the functional effects of focal brain lesions at a network level. The coda serves as an introduction to a forthcoming study, known as Connectomics and Electrical Stimulation for Augmenting Resection (CAESAR), which is an evolution of the results and methods herein.

Method for Identifying Resting State Networks following Probabilistic Independent Component Analysis

Drake, David M.

January 2014

No description available.

Biomedical Research

Resting State Networks

Independent Component Analysis

Functional MRI

Correlation Coefficients

R programming

UNIX programming

Magnetic Resonance Imaging Analysis of Neural Circuit Abnormalities in: Medication Naive Children with Obsessive-Compulsive Disorder, and Normal Healthy Adults During Acute Alcohol Intoxication

Weber, Alexander M.

10 1900

<p>The human brain is possibly the most complicated structure in the known world. It contains 100 billion neurons, each making contact with 1,000 to 10,000 other neurons. The neurons themselves have hundreds of excitatory and inhibitory neurotransmitters / receptors with which to use to activate or de-activate other neighbouring neurons. Ultimately these neurons are organized into locally defined functional neural networks, which in turn connect with other neural networks to create non-localized highly-complex brain circuits. These brain circuits are responsible for the higher order functions such as perception, emotions, learning, language and conscious thought. In healthy brain states, these networks and circuits are communicating and signalling appropriately. With mental illness, or in an intoxicated brain state, however, this network and circuit functioning can become disrupted: either in a very specific manner, or in a generalized form. Alcohol (in the form of ethanol) is one of the oldest and most widely used psychoactive drugs in the world. In recreational doses, it can have drastic effects on how a person thinks and behaves. Small doses will lead to feelings of euphoria, increased sociability, and impaired judgement, while larger doses will lead to impaired memory and comprehension, and at extreme doses will lead from confusion and stupor to coma and death. The current understanding of alcohol’s effects on the brain is that it acts in a very specific way on a variety of brain enzymes and receptors. This in turn affects specific brain circuitries, making alcohol intoxication a promising model of pharmacological neural network and brain circuit modulation. Obsessive-compulsive disorder (OCD) is a major psychiatric disorder that affects many (lifetime prevalence of between 1-2.5%) and can cause significant disability and impairment in one’s life. The onset of OCD is usually during childhood and adolescence, with more than 50% of adults with OCD reporting its onset occurring before the age of 18. The etiological origin of OCD lies ultimately in specific neuropathological processes, with current theories postulating either a neurochemical model that emphasizes the dysfunction of the serotonergic and possibly dopaminergic systems; or a neuroanatomical model that emphasizes the dysfunction of a specific corticostriatal pathway; or both. Magnetic resonance imaging (MRI), with its safe, non-invasive ability to image both anatomy, brain function and brain metabolism, provides a unique tool with which to probe brain circuit changes, such as in healthy subjects under a pharmacological challenge (ethyl alcohol), or in medication naïve children with OCD. In the ethanol intoxicated brain, functional MRI can be used to probe specific resting state networks (RSN; functionally connected networks that exhibit low frequency blood oxygen level dependent (BOLD) fluctuations), measure brain BOLD time-signal complexity using fractal analysis, and to correlate these findings with measured alcohol levels in the brain in vivo using magnetic resonance spectroscopy (MRS). In subjects with OCD, functional MRI can be used to once again probe RSNs, and as well, MRS can be used to look at potential differences in brain metabolites in axonal projections that connect OCD relevant brain circuits. It is the purpose of this thesis to show how brain circuits and neural networks in atypical brain states (such as intoxication or mental illness) can be probed and better understood using advanced MRI techniques, such as resting state fMRI. Over a series of three studies, one involving MRI scans of healthy male adults before and after drinking a substantial amount of ethanol, and two others comparing RSNs in children with OCD versus healthy matched controls, and MRS differences in prefrontal white matter between the same two groups, we examined brain circuit changes using advanced MRI techniques. In the alcohol study, evidence was found of brain signal complexity decreasing after 60min and 90min post alcohol consumption. Simultaneously, a mixture of increased and decreased functional connectivity in the default mode network was found after 60min post alcohol consumption, which became general decreased functional connectivity after 90min post alcohol consumption. These changes took place while alcohol in the brain increased substantially after 60min. These findings may help provide insight into the neurofunctional underpinnings of the cognitive and behavioural changes observed during acute alcohol intoxication. In the first study on medication naïve children with OCD, we observed increased connectivity (OCD>control) in the right section of Brodmann area 43 of the auditory cortex, as well as decreased connectivity in the right section of Brodmann area 8 and Brodmann area 40 in the cingulate network. In the second study looking at medication naïve children with OCD, we observed higher levels of N-acetyl-aspartate (NAA) and choline in the right prefrontal white matter (RPFWM) in children with OCD compared to healthy controls, as well as a positive correlation of creatine, NAA, and myo-inositol levels in the RPFWM and OCD symptom severity. Both studies lend further support to the cortico-striatal-thalamiccortical hypothesis of OCD, while the first study further implicates other regions of the brain outside of the CSTC. Both of these OCD studies further demonstrated the differences in brain circuits of neuropsychiatric disorders between children and adults.</p> / Doctor of Philosophy (PhD)

resting state networks

mri

brain circuits

neural networks

obsessive-compulsive disorder

alcohol