Your search keyword '"Nataliia Kozhemiako"' showing total 6 results

1. Electroencephalographic Microstates During Sleep and Wake in Schizophrenia

Author

Michael Murphy, Chenguang Jiang, Lei A. Wang, Nataliia Kozhemiako, Yining Wang, Jun Wang, Jen Q. Pan, Shaun M. Purcell, Guanchen Gai, Kai Zou, Zhe Wang, Xiaoman Yu, Guoqiang Wang, Shuping Tan, Mei Hua Hall, Wei Zhu, Zhenhe Zhou, Lu Shen, Shenying Qin, Hailiang Huang, Lin Zhou, Shen Li, Robert Law, Minitrios Mylonas, Robert Stickgold, Dara Manoach, Mei-Hua Hall, Zhenglin Guo, Sinead Chapman, and Chenaugnag Jiang

Subjects

EEG, Microstates, Resting-state, Schizophrenia, Sleep, Spindles, Psychiatry, RC435-571

Abstract

Background: Aberrant functional connectivity is a hallmark of schizophrenia. The precise nature and mechanism of dysconnectivity in schizophrenia remains unclear, but evidence suggests that dysconnectivity is different in wake versus sleep. Microstate analysis uses electroencephalography (EEG) to investigate large-scale patterns of coordinated brain activity by clustering EEG data into a small set of recurring spatial patterns, or microstates. We hypothesized that this technique would allow us to probe connectivity between brain networks at a fine temporal resolution and uncover previously unknown sleep-specific dysconnectivity. Methods: We studied microstates during sleep in patients with schizophrenia by analyzing high-density EEG sleep data from 114 patients with schizophrenia and 79 control participants. We used a polarity-insensitive k-means analysis to extract a set of 6 microstate topographies. Results: These 6 states included 4 widely reported canonical microstates. In patients and control participants, falling asleep was characterized by a shift from microstates A, B, and C to microstates D, E, and F. Microstate F was decreased in patients during wake, and microstate E was decreased in patients during sleep. The complexity of microstate transitions was greater in patients than control participants during wake, but this reversed during sleep. Conclusions: Our findings reveal behavioral state–dependent patterns of cortical dysconnectivity in schizophrenia. Furthermore, these findings are largely unrelated to previous sleep-related EEG markers of schizophrenia such as decreased sleep spindles. Therefore, these findings are driven by previously undescribed sleep-related pathology in schizophrenia.

Published

2024

2. Classification of evoked responses to inverted faces reveals both spatial and temporal cortical response abnormalities in Autism spectrum disorder

Author

Adonay S. Nunes, Fahimeh Mamashli, Nataliia Kozhemiako, Sheraz Khan, Nicole M. McGuiggan, Ainsley Losh, Robert M. Joseph, Jyrki Ahveninen, Sam M. Doesburg, Matti S. Hämäläinen, and Tal Kenet

Subjects

Autism, Machine learning, Faces, Inverted faces, Magenetoencephalography, Computer applications to medicine. Medical informatics, R858-859.7, Neurology. Diseases of the nervous system, RC346-429

Abstract

The neurophysiology of face processing has been studied extensively in the context of social impairments associated with autism spectrum disorder (ASD), but the existing studies have concentrated mainly on univariate analyses of responses to upright faces, and, less frequently, inverted faces. The small number of existing studies on neurophysiological responses to inverted face in ASD have used univariate approaches, with divergent results. Here, we used a data-driven, classification-based, multivariate machine learning decoding approach to investigate the temporal and spatial properties of the neurophysiological evoked response for upright and inverted faces, relative to the neurophysiological evoked response for houses, a neutral stimulus. 21 (2 females) ASD and 29 (4 females) TD participants ages 7 to 19 took part in this study. Group level classification accuracies were obtained for each condition, using first the temporal domain of the evoked responses, and then the spatial distribution of the evoked responses on the cortical surface, each separately. We found that classification of responses to inverted neutral faces vs. houses was less accurate in ASD compared to TD, in both the temporal and spatial domains. In contrast, there were no group differences in the classification of evoked responses to upright neutral faces relative to houses. Using the classification in the temporal domain, lower decoding accuracies in ASD were found around 120 ms and 170 ms, corresponding the known components of the evoked responses to faces. Using the classification in the spatial domain, lower decoding accuracies in ASD were found in the right superior marginal gyrus (SMG), intra-parietal sulcus (IPS) and posterior superior temporal sulcus (pSTS), but not in core face processing areas. Importantly, individual classification accuracies from both the temporal and spatial classifiers correlated with ASD severity, confirming the relevance of the results to the ASD phenotype.

Published

2021

3. Neuromagnetic activation and oscillatory dynamics of stimulus-locked processing during naturalistic viewing

Author

Adonay S. Nunes, Nataliia Kozhemiako, Alexander Moiseev, Robert A. Seymour, Teresa P.L. Cheung, Urs Ribary, and Sam M. Doesburg

Subjects

Naturalistic viewing, Magnetoencephalography, Face processing, Language, Neuromagnetic dynamics, Time-locked activation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Naturalistic stimuli such as watching a movie while in the scanner provide an ecologically valid paradigm that has the potential of extracting valuable information on how the brain processes complex stimuli in realistic visual and auditory contexts. Naturalistic viewing is also easier to conduct with challenging participant groups including patients and children. Given the high temporal resolution of MEG, in the present study, we demonstrate how a short movie clip can be used to map distinguishable activation and connectivity dynamics underlying the processing of specific classes of visual stimuli such as face and hand manipulations, as well as contrasting activation dynamics for auditory words and non-words.MEG data were collected from 22 healthy volunteers (6 females, 3 left handed, mean age – 27.7 ​± ​5.28 years) during the presentation of naturalistic audiovisual stimuli. The MEG data were split into trials with the onset of the stimuli belonging to classes of interest (words, non-words, faces, hand manipulations). Based on the components of the averaged sensor ERFs time-locked to the visual and auditory stimulus onset, four and three time-windows, respectively, were defined to explore brain activation dynamics. Pseudo-Z, defined as the ratio of the source-projected time-locked power to the projected noise power for each vertex, was computed and used as a proxy of time-locked brain activation. Statistical testing using the mean-centered Partial Least Squares analysis indicated periods where a given visual or auditory stimuli had higher activation. Based on peak pseudo-Z differences between the visual conditions, time-frequency resolved analyses were performed to assess beta band desynchronization in motor-related areas, and inter-trial phase synchronization between face processing areas. Our results provide the first evidence that activation and connectivity dynamics in canonical brain regions associated with the processing of particular classes of visual and auditory stimuli can be reliably mapped using MEG during presentation of naturalistic stimuli. Given the strength of MEG for brain mapping in temporal and frequency domains, the use of naturalistic stimuli may open new techniques in analyzing brain dynamics during ecologically valid sensation and perception.

Published

2020

4. Multiple constrained minimum variance beamformer (MCMV) performance in connectivity analyses

Author

Adonay S. Nunes, Alexander Moiseev, Nataliia Kozhemiako, Teresa Cheung, Urs Ribary, and Sam M. Doesburg

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Functional brain connectivity is increasingly being seen as critical for cognition, perception and motor control. Magnetoencephalography and electroencephalography are modalities that offer noninvasive mapping of electrophysiological interactions among brain regions, yet suffer from signal leakage and signal cancellation when estimating brain activity. This leads to biased connectivity values which complicate interpretation. In this study, we test the hypothesis that a Multiple Constrained Minimum Variance beamformer (MCMV) outperforms the more traditional Linearly Constrained Minimum Variance beamformer (LCMV) for estimation of electrophysiological connectivity. To this end, MCMV and LCMV performance is compared in task related analyses with both simulated data and human MEG recordings of visual steady state signals, and in resting state analyses with simulated data and human MEG data of 89 subjects. In task related scenarios connectivity was estimated using coherence and phase locking values, whereas envelope correlations were used for the resting state data. We also introduce a novel Augmented Pairwise MCMV (APW-MCMV) approach for signal leakage suppression in resting state analyses and assess its performance against LCMV and more conventional MCMV approaches. We demonstrate that with MCMV effects of signal mixing and coherent source cancellation are greatly reduced in both task related and resting state conditions, while in contrast to other approaches 0- and short time lag interactions are preserved. In addition, we demonstrate that in resting state analyses, APW-MCMV strongly reduces spurious connections while better controlling for false negatives compared to more conservative measures such as symmetrical orthogonalization.

Published

2020

5. Atypical neuromagnetic resting activity associated with thalamic volume and cognitive outcome in very preterm children

Author

Adonay S. Nunes, Nataliia Kozhemiako, Evan Hutcheon, Cecil Chau, Urs Ribary, Ruth E. Grunau, and Sam M. Doesburg

Subjects

Computer applications to medicine. Medical informatics, R858-859.7, Neurology. Diseases of the nervous system, RC346-429

Abstract

Children born very preterm, even in the absence of overt brain injury or major impairment, are at increased risk of cognitive difficulties. This risk is associated with developmental disruptions of the thalamocortical system during critical periods while in the neonatal intensive care unit. The thalamus is an important structure that not only relays sensory information but acts as a hub for integration of cortical activity which regulates cortical power across a range of frequencies. In this study, we investigate the association between atypical power at rest in children born very preterm at school age using magnetoencephalography (MEG), neurocognitive function and structural alterations related to the thalamus using MRI. Our results indicate that children born extremely preterm have higher power at slow frequencies (delta and theta) and lower power at faster frequencies (alpha and beta), compared to controls born full-term. A similar pattern of spectral power was found to be associated with poorer neurocognitive outcomes, as well as with normalized T1 intensity and the volume of the thalamus. Overall, this study provides evidence regarding relations between structural alterations related to very preterm birth, atypical oscillatory power at rest and neurocognitive difficulties at school-age children born very preterm.

Published

2020

6. Classification of evoked responses to inverted faces reveals both spatial and temporal cortical response abnormalities in Autism spectrum disorder

Author

Sheraz Khan, Adonay S. Nunes, Robert M. Joseph, Nataliia Kozhemiako, Nicole M. McGuiggan, Jyrki Ahveninen, Sam M. Doesburg, Fahimeh Mamashli, Matti Hämäläinen, Tal Kenet, Ainsley Losh, Harvard Medical School, Boston University, Simon Fraser University, Department of Neuroscience and Biomedical Engineering, Aalto-yliopisto, and Aalto University

Subjects

Adult, medicine.medical_specialty, Adolescent, Autism Spectrum Disorder, Cognitive Neuroscience, media_common.quotation_subject, Autism, Context (language use), Neutral stimulus, Audiology, lcsh:Computer applications to medicine. Medical informatics, 050105 experimental psychology, lcsh:RC346-429, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Machine learning, medicine, Humans, Contrast (vision), 0501 psychology and cognitive sciences, Radiology, Nuclear Medicine and imaging, Faces, Child, lcsh:Neurology. Diseases of the nervous system, media_common, 05 social sciences, Magenetoencephalography, Inverted faces, Regular Article, Sulcus, Neurophysiology, medicine.disease, Temporal Lobe, medicine.anatomical_structure, Neurology, Autism spectrum disorder, Face (geometry), lcsh:R858-859.7, Female, Neurology (clinical), Psychology, Facial Recognition, 030217 neurology & neurosurgery

Abstract

Highlights • Machine learning brain decoding identified distinct brain patters during inverted or neutral faces versus houses. • Decreased accuracy in classifying inverted faces stimuli was found in the ASD group. • Significant accuracy differences were found temporally between 100 and 240 ms and spatially in temporal and occipital areas. • ASD differences in accuracy were correlated to ADOS symptomatology., The neurophysiology of face processing has been studied extensively in the context of social impairments associated with autism spectrum disorder (ASD), but the existing studies have concentrated mainly on univariate analyses of responses to upright faces, and, less frequently, inverted faces. The small number of existing studies on neurophysiological responses to inverted face in ASD have used univariate approaches, with divergent results. Here, we used a data-driven, classification-based, multivariate machine learning decoding approach to investigate the temporal and spatial properties of the neurophysiological evoked response for upright and inverted faces, relative to the neurophysiological evoked response for houses, a neutral stimulus. 21 (2 females) ASD and 29 (4 females) TD participants ages 7 to 19 took part in this study. Group level classification accuracies were obtained for each condition, using first the temporal domain of the evoked responses, and then the spatial distribution of the evoked responses on the cortical surface, each separately. We found that classification of responses to inverted neutral faces vs. houses was less accurate in ASD compared to TD, in both the temporal and spatial domains. In contrast, there were no group differences in the classification of evoked responses to upright neutral faces relative to houses. Using the classification in the temporal domain, lower decoding accuracies in ASD were found around 120 ms and 170 ms, corresponding the known components of the evoked responses to faces. Using the classification in the spatial domain, lower decoding accuracies in ASD were found in the right superior marginal gyrus (SMG), intra-parietal sulcus (IPS) and posterior superior temporal sulcus (pSTS), but not in core face processing areas. Importantly, individual classification accuracies from both the temporal and spatial classifiers correlated with ASD severity, confirming the relevance of the results to the ASD phenotype.

Published

2021