Search

Your search keyword '"He, Biyu J."' showing total 141 results
Start Over Author "He, Biyu J." Language english
141 results on '"He, Biyu J."'

5. Neural Mechanisms Determining the Duration of Task-free, Self-paced Visual Perception.

Author

Baror, Shira, Baumgarten, Thomas J, and He, Biyu J.

Subjects
VISUAL perception, INDEPENDENT sets, PUPILLOMETRY, ELECTROENCEPHALOGRAPHY, VARIABILITY (Psychometrics), PUPIL diseases
Abstract

Humans spend hours each day spontaneously engaging with visual content, free from specific tasks and at their own pace. Currently, the brain mechanisms determining the duration of self-paced perceptual behavior remain largely unknown. Here, participants viewed naturalistic images under task-free settings and self-paced each image's viewing duration while undergoing EEG and pupillometry recordings. Across two independent data sets, we observed large inter- and intra-individual variability in viewing duration. However, beyond an image's presentation order and category, specific image content had no consistent effects on spontaneous viewing duration across participants. Overall, longer viewing durations were associated with sustained enhanced posterior positivity and anterior negativity in the ERPs. Individual-specific variations in the spontaneous viewing duration were consistently correlated with evoked EEG activity amplitudes and pupil size changes. By contrast, presentation order was selectively correlated with baseline alpha power and baseline pupil size. Critically, spontaneous viewing duration was strongly predicted by the temporal stability in neural activity patterns starting as early as 350 msec after image onset, suggesting that early neural stability is a key predictor for sustained perceptual engagement. Interestingly, neither bottom–up nor top–down predictions about image category influenced spontaneous viewing duration. Overall, these results suggest that individual-specific factors can influence perceptual processing at a surprisingly early time point and influence the multifaceted ebb and flow of spontaneous human perceptual behavior in naturalistic settings. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

7. Integrating Consciousness Science with Cognitive Neuroscience: An Introduction to the Special Focus.

Author

He, Biyu J.

Subjects
*COGNITIVE neuroscience, *CONSCIOUSNESS, *RESEARCH personnel
Abstract

Consciousness science is experiencing a coming-of-age moment. Following three decades of sustained efforts by a relatively small group of consciousness researchers, the field has seen exponential growth over the past 5 years. It is increasingly recognized that although the investigation of subjective experiences is a difficult task, modern neuroscience need not and cannot shy away from the challenge of peeling away the mysteries of conscious experiences. In June 2023, with the joint support of the U.S. National Institutes of Health and the U.S. National Science Foundation, a 3-day workshop was held at the Bethesda, MD, campus of the National Institutes of Health, convening experts whose work focuses primarily on problems of consciousness, or an adjacent field, to discuss the current state of consciousness science and consider the most fruitful avenues for future research. This Special Focus features empirical and theoretical contributions from some of the invited speakers at the workshop. Here, I will cover the scope of the workshop, the content of this Special Focus, and advocate for stronger bridges between consciousness science and other subdisciplines of cognitive neuroscience. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

12. Opportunities and challenges for a maturing science of consciousness

Author

Michel, Matthias, Beck, Diane, Block, Ned, Blumenfeld, Hal, Brown, Richard, Carmel, David, Carrasco, Marisa, Chirimuuta, Mazviita, Chun, Marvin, Cleeremans, Axel, Dehaene, Stanislas, Fleming, Stephen M., Frith, Chris, Haggard, Patrick, He, Biyu J., Heyes, Cecilia, Goodale, Melvyn A., Irvine, Liz, Kawato, Mitsuo, Kentridge, Robert, King, Jean-Remi, Knight, Robert T., Kouider, Sid, Lamme, Victor, Lamy, Dominique, Lau, Hakwan, Laureys, Steven, LeDoux, Joseph, Lin, Ying-Tung, Liu, Kayuet, Macknik, Stephen L., Martinez-Conde, Susana, Mashour, George A., Melloni, Lucia, Miracchi, Lisa, Mylopoulos, Myrto, Naccache, Lionel, Owen, Adrian M., Passingham, Richard E., Pessoa, Luiz, Peters, Megan A. K., Rahnev, Dobromir, Ro, Tony, Rosenthal, David, Sasaki, Yuka, Sergent, Claire, Solovey, Guillermo, Schiff, Nicholas D., Seth, Anil, Tallon-Baudry, Catherine, Tamietto, Marco, Tong, Frank, van Gaal, Simon, Vlassova, Alexandra, Watanabe, Takeo, Weisberg, Josh, Yan, Karen, and Yoshida, Masatoshi

Published
2019
Full Text
View/download PDF

14. Next frontiers in consciousness research.

Author

He, Biyu J.

Subjects
*CONSCIOUSNESS
Abstract

Consciousness science has matured over the past three decades and is currently on the cusp of explosive growth, with the potential to transform medicine and technology. The global community recently met to synthesize the current state of knowledge and define the most exciting approaches to advance the field. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

22. Spontaneous perception: a framework for task-free, self-paced perception.

Author

Baror, Shira and He, Biyu J

Subjects
SOCIAL media, MUSEUM exhibits
Abstract

Flipping through social media feeds, viewing exhibitions in a museum, or walking through the botanical gardens, people consistently choose to engage with and disengage from visual content. Yet, in most laboratory settings, the visual stimuli, their presentation duration, and the task at hand are all controlled by the researcher. Such settings largely overlook the spontaneous nature of human visual experience, in which perception takes place independently from specific task constraints and its time course is determined by the observer as a self-governing agent. Currently, much remains unknown about how spontaneous perceptual experiences unfold in the brain. Are all perceptual categories extracted during spontaneous perception? Does spontaneous perception inherently involve volition? Is spontaneous perception segmented into discrete episodes? How do different neural networks interact over time during spontaneous perception? These questions are imperative to understand our conscious visual experience in daily life. In this article we propose a framework for spontaneous perception. We first define spontaneous perception as a task-free and self-paced experience. We propose that spontaneous perception is guided by four organizing principles that grant it temporal and spatial structures. These principles include coarse-to-fine processing, continuity and segmentation, agency and volition, and associative processing. We provide key suggestions illustrating how these principles may interact with one another in guiding the multifaceted experience of spontaneous perception. We point to testable predictions derived from this framework, including (but not limited to) the roles of the default-mode network and slow cortical potentials in underlying spontaneous perception. We conclude by suggesting several outstanding questions for future research, extending the relevance of this framework to consciousness and spontaneous brain activity. In conclusion, the spontaneous perception framework proposed herein integrates components in human perception and cognition, which have been traditionally studied in isolation, and opens the door to understand how visual perception unfolds in its most natural context. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

23. A Gradient of Sharpening Effects by Perceptual Prior across the Human Cortical Hierarchy.

Author

González-García, Carlos and He, Biyu J.

Subjects
*PERCEPTUAL learning, *PRIOR learning, *HIERARCHIES, *FUNCTIONAL magnetic resonance imaging, *VISUAL perception
Abstract

Prior knowledge profoundly influences perceptual processing. Previous studies have revealed consistent suppression of predicted stimulus information in sensory areas, but how prior knowledge modulates processing higher up in the cortical hierarchy remains poorly understood. In addition, the mechanism leading to suppression of predicted sensory information remains unclear, and studies thus far have revealed a mixed pattern of results in support of either the "sharpening" or "dampening" model. Here, using 7T fMRI in humans (both sexes), we observed that prior knowledge acquired from fast, one-shot perceptual learning sharpens neural representation throughout the ventral visual stream, generating suppressed sensory responses. In contrast, the frontoparietal and default mode networks exhibit similar sharpening of content-specific neural representation, but in the context of unchanged and enhanced activity magnitudes, respectively: a pattern we refer to as "selective enhancement." Together, these results reveal a heretofore unknown macroscopic gradient of prior knowledge's sharpening effect on neural representations across the cortical hierarchy. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

24. Task-evoked activity quenches neural correlations and variability across cortical areas.

Author

Ito, Takuya, Brincat, Scott L., Siegel, Markus, Mill, Ravi D., He, Biyu J., Miller, Earl K., Rotstein, Horacio G., and Cole, Michael W.

Subjects
FUNCTIONAL magnetic resonance imaging, FUNCTIONAL connectivity
Abstract

Many large-scale functional connectivity studies have emphasized the importance of communication through increased inter-region correlations during task states. In contrast, local circuit studies have demonstrated that task states primarily reduce correlations among pairs of neurons, likely enhancing their information coding by suppressing shared spontaneous activity. Here we sought to adjudicate between these conflicting perspectives, assessing whether co-active brain regions during task states tend to increase or decrease their correlations. We found that variability and correlations primarily decrease across a variety of cortical regions in two highly distinct data sets: non-human primate spiking data and human functional magnetic resonance imaging data. Moreover, this observed variability and correlation reduction was accompanied by an overall increase in dimensionality (reflecting less information redundancy) during task states, suggesting that decreased correlations increased information coding capacity. We further found in both spiking and neural mass computational models that task-evoked activity increased the stability around a stable attractor, globally quenching neural variability and correlations. Together, our results provide an integrative mechanistic account that encompasses measures of large-scale neural activity, variability, and correlations during resting and task states. Author summary: Statistical estimates of correlated neural activity and variability are widely used to characterize neural systems during different states. However, there is a conceptual gap between the use and interpretation of these measures between the human neuroimaging and non-human primate electrophysiology literature. For example, in the human neuroimaging literature, "functional connectivity" is often used to refer to correlated activity, while in the non-human primate electrophysiology literature, the equivalent term is "noise correlation". In an effort to unify these two perspectives under a single theoretical framework, we provide empirical evidence from human functional magnetic resonance imaging and non-human primate mean-field spike rate data that functional connectivity and noise correlations reveal similar statistical patterns during task states. In short, we found that task states primarily quench neural variability and correlations in both data sets. To provide a theoretically rigorous account capable of explaining this phenomena across both data sets, we use mean-field dynamical systems modeling to demonstrate the deterministic relationship between task-evoked activity, neural variability and correlations. Together, we provide an integrative account, showing that task-evoked activity quenches neural variability and correlations in large-scale neural systems. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

25. Neuromodulation of Brain State and Behavior.

Author

McCormick, David A., Nestvogel, Dennis B., and He, Biyu J.

Subjects
NEURAL pathways, BEHAVIOR, CEREBRAL cortex, COGNITION
Abstract

Neural activity and behavior are both notoriously variable, with responses differing widely between repeated presentation of identical stimuli or trials. Recent results in humans and animals reveal that these variations are not random in their nature, but may in fact be due in large part to rapid shifts in neural, cognitive, and behavioral states. Here we review recent advances in the understanding of rapid variations in the waking state, how variations are generated, and how they modulate neural and behavioral responses in both mice and humans. We propose that the brain has an identifiable set of states through which it wanders continuously in a nonrandom fashion, owing to the activity of both ascending modulatory and fast-acting corticocortical and subcortical-cortical neural pathways. These state variations provide the backdrop upon which the brain operates, and understanding them is critical to making progress in revealing the neural mechanisms underlying cognition and behavior. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

26. State-aware detection of sensory stimuli in the cortex of the awake mouse.

Author

Sederberg, Audrey J., Pala, Aurélie, Zheng, He J. V., He, Biyu J., and Stanley, Garrett B.

Subjects
SENSORY defensiveness, SOMATOSENSORY cortex, DETECTION of microorganisms, AVERSIVE stimuli, HIGHER nervous activity
Abstract

Cortical responses to sensory inputs vary across repeated presentations of identical stimuli, but how this trial-to-trial variability impacts detection of sensory inputs is not fully understood. Using multi-channel local field potential (LFP) recordings in primary somatosensory cortex (S1) of the awake mouse, we optimized a data-driven cortical state classifier to predict single-trial sensory-evoked responses, based on features of the spontaneous, ongoing LFP recorded across cortical layers. Our findings show that, by utilizing an ongoing prediction of the sensory response generated by this state classifier, an ideal observer improves overall detection accuracy and generates robust detection of sensory inputs across various states of ongoing cortical activity in the awake brain, which could have implications for variability in the performance of detection tasks across brain states. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

28. Beyond Trial-Based Paradigms: Continuous Behavior, Ongoing Neural Activity, and Natural Stimuli.

Author

Huk, Alexander, Bonnen, Kathryn, and He, Biyu J.

Subjects
SENSORY perception, COGNITION, STATISTICAL models, BEHAVIOR, BRAIN
Abstract

The vast majority of experiments examining perception and behavior are conducted using experimental paradigms that adhere to a rigid trial structure: each trial consists of a brief and discrete series of events and is regarded as independent from all other trials. The assumptions underlying this structure ignore the reality that natural behavior is rarely discrete, brain activity follows multiple time courses that do not necessarily conform to the trial structure, and the natural environment has statistical structure and dynamics that exhibit long-range temporal correlation. Modern advances in statistical modeling and analysis offer tools that make it feasible for experiments to move beyond rigid independent and identically distributed trial structures. Here we review literature that serves as evidence for the feasibility and advantages of moving beyond trial-based paradigms to understand the neural basis of perception and cognition. Furthermore, we propose a synthesis of these efforts, integrating the characterization of natural stimulus properties with measurements of continuous neural activity and behavioral outputs within the framework of sensory-cognitive-motor loops. Such a framework provides a basis for the study of natural statistics, naturalistic tasks, and/or slow fluctuations in brain activity, which should provide starting points for important generalizations of analytical tools in neuroscience and subsequent progress in understanding the neural basis of perception and cognition. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

29. Initial-state-dependent, robust, transient neural dynamics encode conscious visual perception.

Author

Baria, Alexis T., Maniscalco, Brian, and He, Biyu J.

Subjects
NEURAL circuitry, BRAIN physiology, CEREBRAL cortex, MAGNETOENCEPHALOGRAPHY, BRAIN anatomy
Abstract

Recent research has identified late-latency, long-lasting neural activity as a robust correlate of conscious perception. Yet, the dynamical nature of this activity is poorly understood, and the mechanisms governing its presence or absence and the associated conscious perception remain elusive. We applied dynamic-pattern analysis to whole-brain slow (< 5 Hz) cortical dynamics recorded by magnetoencephalography (MEG) in human subjects performing a threshold-level visual perception task. Up to 1 second before stimulus onset, brain activity pattern across widespread cortices significantly predicted whether a threshold-level visual stimulus was later consciously perceived. This initial state of brain activity interacts nonlinearly with stimulus input to shape the evolving cortical activity trajectory, with seen and unseen trials following well separated trajectories. We observed that cortical activity trajectories during conscious perception are fast evolving and robust to small variations in the initial state. In addition, spontaneous brain activity pattern prior to stimulus onset also influences unconscious perceptual making in unseen trials. Together, these results suggest that brain dynamics underlying conscious visual perception belongs to the class of initial-state-dependent, robust, transient neural dynamics. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

30. Volition and Action in the Human Brain: Processes, Pathologies, and Reasons.

Author

Fried, Itzhak, Haggard, Patrick, He, Biyu J., and Schurger, Aaron

Subjects
NEUROPSYCHOLOGY, WILL, NEUROLOGY, EFFERENT pathways, MOTOR ability, BRAIN stimulation
Abstract

Humans seem to decide for themselves what to do, and when to do it. This distinctive capacity may emerge from an ability, shared with other animals, to make decisions for action that are related to future goals, or at least free from the constraints of immediate environmental inputs. Studying such volitional acts proves a major challenge for neuroscience. This review highlights key mechanisms in the generation of voluntary, as opposed to stimulus-driven actions, and highlights three issues. The first part focuses on the apparent spontaneity of voluntary action. The second part focuses on one of the most distinctive, but elusive, features of volition, namely, its link to conscious experience, and reviews stimulation and patient studies of the cortical basis of conscious volition down to the single-neuron level. Finally, we consider the goal-directedness of voluntary action, and discuss how internal generation of action can be linked to goals and reasons. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

31. Task-Driven Activity Reduces the Cortical Activity Space of the Brain: Experiment and Whole-Brain Modeling.

Author

Ponce-Alvarez, Adrián, He, Biyu J., Hagmann, Patric, and Deco, Gustavo

Subjects
*BRAIN physiology, *CEREBRAL cortex, *FUNCTIONAL magnetic resonance imaging, *TASK performance, *NEURAL transmission, *NEURAL stimulation, *MATHEMATICAL models
Abstract

How a stimulus or a task alters the spontaneous dynamics of the brain remains a fundamental open question in neuroscience. One of the most robust hallmarks of task/stimulus-driven brain dynamics is the decrease of variability with respect to the spontaneous level, an effect seen across multiple experimental conditions and in brain signals observed at different spatiotemporal scales. Recently, it was observed that the trial-to-trial variability and temporal variance of functional magnetic resonance imaging (fMRI) signals decrease in the task-driven activity. Here we examined the dynamics of a large-scale model of the human cortex to provide a mechanistic understanding of these observations. The model allows computing the statistics of synaptic activity in the spontaneous condition and in putative tasks determined by external inputs to a given subset of brain regions. We demonstrated that external inputs decrease the variance, increase the covariances, and decrease the autocovariance of synaptic activity as a consequence of single node and large-scale network dynamics. Altogether, these changes in network statistics imply a reduction of entropy, meaning that the spontaneous synaptic activity outlines a larger multidimensional activity space than does the task-driven activity. We tested this model’s prediction on fMRI signals from healthy humans acquired during rest and task conditions and found a significant decrease of entropy in the stimulus-driven activity. Altogether, our study proposes a mechanism for increasing the information capacity of brain networks by enlarging the volume of possible activity configurations at rest and reliably settling into a confined stimulus-driven state to allow better transmission of stimulus-related information. [ABSTRACT FROM AUTHOR]

Published
2015
Full Text
View/download PDF

32. Modulating Conscious Movement Intention by Noninvasive Brain Stimulation and the Underlying Neural Mechanisms.

Author

Douglas, Zachary H., Maniscalco, Brian, Hallett, Mark, Wassermann, Eric M., and He, Biyu J.

Subjects
PSYCHOLOGY of movement, BRAIN stimulation, NEUROBIOLOGY, BRAIN waves, MOTOR cortex physiology, COMPUTATIONAL neuroscience
Abstract

Conscious intention is a fundamental aspect of the human experience. Despite long-standing interest in the basis and implications of intention, its underlying neurobiological mechanisms remain poorly understood. Using high-definition transcranial DC stimulation (tDCS), we observed that enhancing spontaneous neuronal excitability in both the angular gyrus and the primary motor cortex caused the reported time of conscious movement intention to be~60 -70 ms earlier. Slow brain waves recorded~2-3 s before movement onset, as well as hundreds of milliseconds after movement onset, independently correlated with the modulation of conscious intention by brain stimulation. These brain activities together accounted for 81% of interindividual variability in the modulation of movement intention by brain stimulation. A computational model using coupled leaky integrator units with biophysically plausible assumptions about the effect of tDCS captured the effects of stimulation on both neural activity and behavior. These results reveal a temporally extended brain process underlying conscious movement intention that spans seconds around movement commencement. [ABSTRACT FROM AUTHOR]

Published
2015
Full Text
View/download PDF

33. A cross-modal investigation of the neural substrates for ongoing cognition.

Author

Wang, Megan, He, Biyu J., Jerbi, Karim, and Sigman, Mariano

Subjects
CONSCIOUSNESS, COGNITION research, FUNCTIONAL magnetic resonance imaging, SENSORY stimulation, STIMULUS & response (Biology)
Abstract

What neural mechanisms underlie the seamless flow of our waking consciousness? A necessary albeit insufficient condition for such neural mechanisms is that they should be consistently modulated across time were a segment of the conscious stream to be repeated twice. In this study, we experimentally manipulated the content of a story followed by subjects during functional magnetic resonance imaging (fMRI) independently from the modality of sensory input (as visual text or auditory speech) as well as attentional focus. We then extracted brain activity patterns consistently modulated across subjects by the evolving content of the story regardless of whether it was presented visually or auditorily. Specifically, in one experiment we presented the same story to different subjects via either auditory or visual modality. In a second experiment, we presented two different stories simultaneously, one auditorily, one visually, and manipulated the subjects' attentional focus. This experimental design allowed us to dissociate brain activities underlying modality-specific sensory processing from modality-independent story processing. We uncovered a network of brain regions consistently modulated by the evolving content of a story regardless of the sensory modality used for stimulus input, including the superior temporal sulcus/gyrus (STS/STG), the inferior frontal gyrus (IFG), the posterior cingulate cortex (PCC), the medial frontal cortex (MFC), the temporal pole (TP), and the temporoparietal junction (TPJ). Many of these regions have previously been implicated in semantic processing. Interestingly, different stories elicited similar brain activity patterns, but with subtle differences potentially attributable to varying degrees of emotional valence and self-relevance. [ABSTRACT FROM AUTHOR]

Published
2014
Full Text
View/download PDF

34. Spatiotemporal Dissociation of Brain Activity Underlying Subjective Awareness, Objective Performance and Confidence.

Author

Qi Li, Hill, Zachary, and He, Biyu J.

Subjects
MAGNETOENCEPHALOGRAPHY, METACOGNITION, HIGHER nervous activity, AWARENESS, VISUAL perception
Abstract

Despite intense recent research, the neural correlates of conscious visual perception remain elusive. The most established paradigm for studying brain mechanisms underlying conscious perception is to keep the physical sensory inputs constant and identify brain activities that correlate with the changing content of conscious awareness. However, such a contrast based on conscious content alone would not only reveal brain activities directly contributing to conscious perception, but also include brain activities that precede or follow it. To address this issue, we devised a paradigm whereby we collected, trial-by-trial, measures of objective performance, subjective awareness, and the confidence level of subjective awareness. Using magnetoencephalography recordings in healthy human volunteers, we dissociated brain activities underlying these different cognitive phenomena. Our results provide strong evidence that widely distributed slow cortical potentials (SCPs) correlate with subjective awareness, even after the effects of objective performance and confidence were both removed. The SCP correlate of conscious perception manifests strongly in its waveform, phase, and power. In contrast, objective performance and confidence were both contributed by relatively transient brain activity. These results shed new light on the brain mechanisms of conscious, unconscious, and metacognitive processing. [ABSTRACT FROM AUTHOR]

Published
2014
Full Text
View/download PDF

35. Average Is Optimal: An Inverted-U Relationship between Trial-to-Trial Brain Activity and Behavioral Performance.

Author

He, Biyu J. and Zempel, John M.

Subjects
*BRAIN physiology, *EVOKED potentials (Electrophysiology), *CLINICAL trials, *ANALYTICAL mechanics, *MENTAL illness, *BROADBAND communication systems, *REACTION time
Abstract

It is well known that even under identical task conditions, there is a tremendous amount of trial-to-trial variability in both brain activity and behavioral output. Thus far the vast majority of event-related potential (ERP) studies investigating the relationship between trial-to-trial fluctuations in brain activity and behavioral performance have only tested a monotonic relationship between them. However, it was recently found that across-trial variability can correlate with behavioral performance independent of trial-averaged activity. This finding predicts a U- or inverted-U- shaped relationship between trial-to-trial brain activity and behavioral output, depending on whether larger brain variability is associated with better or worse behavior, respectively. Using a visual stimulus detection task, we provide evidence from human electrocorticography (ECoG) for an inverted-U brain-behavior relationship: When the raw fluctuation in broadband ECoG activity is closer to the across-trial mean, hit rate is higher and reaction times faster. Importantly, we show that this relationship is present not only in the post-stimulus task-evoked brain activity, but also in the pre-stimulus spontaneous brain activity, suggesting anticipatory brain dynamics. Our findings are consistent with the presence of stochastic noise in the brain. They further support attractor network theories, which postulate that the brain settles into a more confined state space under task performance, and proximity to the targeted trajectory is associated with better performance. [ABSTRACT FROM AUTHOR]

Published
2013
Full Text
View/download PDF

36. Spontaneous and Task-Evoked Brain Activity Negatively Interact.

Author

He, Biyu J.

Subjects
*EVOKED potentials (Electrophysiology), *BRAIN function localization, *CONDITIONED response, *TASK performance, *SENSORY stimulation, *MAGNETIC resonance imaging
Abstract

A widely held assumption is that spontaneous and task-evoked brain activity sum linearly, such that the recorded brain response in each single trial is the algebraic sum of the constantly changing ongoing activity and the stereotypical evoked activity. Using functional magnetic resonance imaging signals acquired from normal humans, we show that this assumption is invalid. Across widespread cortices, evoked activity interacts negatively with ongoing activity, such that higher prestimulus baseline results in less activation or more deactivation. As a consequence of this negative interaction, trial-to-trial variability of cortical activity decreases following stimulus onset. We further show that variability reduction follows overlapping but distinct spatial pattern from that of task-activation/deactivation and it contains behaviorally relevant information. These results favor an alternative perspective to the traditional dichotomous framework of ongoing and evoked activity. That is, to view the brain as a nonlinear dynamical system whose trajectory is tighter when performing a task. Further, incoming sensory stimuli modulate the brain's activity in a manner that depends on its initial state. We propose that across-trial variability may provide a new approach to brain mapping in the context of cognitive experiments. [ABSTRACT FROM AUTHOR]

Published
2013
Full Text
View/download PDF

37. Scale-free dynamics and critical phenomena in cortical activity.

Author

Boonstra, Tjeerd W., He, Biyu J., and Daffertshofer, Andreas

Subjects
BRAIN anatomy, CEREBRAL cortex, NEURONS, CREATIVE ability, BEHAVIOR, COMPLEXITY (Philosophy)
Abstract

The article discusses the scale-free dynamics and critical phenomena in cortical activity of the brain. It notes that interconnected neurons that form a complex system where thought, behavior and creativity emerge have also composed the brain. It states that modern complexity science can be used to investigate the principles of complex networks. It mentions that the study in scale-free brain dynamics has raised issues on whether the brain operates permanently in critical state.

Published
2013
Full Text
View/download PDF

38. Scale-Free Properties of the Functional Magnetic Resonance Imaging Signal during Rest and Task.

Author

He, Biyu J.

Abstract

It has been shown recently that a significant portion of brain electrical field potentials consists of scale-free dynamics. These scale-free brain dynamics contain complex spatiotemporal structures and are modulated by task performance. Here we show that the fMRI signal recorded from the human brain is also scale free; its power-law exponent differentiates between brain networks and correlates with fMRI signal variance and brain glucose metabolism. Importantly, in parallel to brain electrical field potentials, the variance and power-law exponent of the fMRI signal decrease during task activation, suggesting that the signal contains more long-range memory during rest and conversely is more efficient at online information processing during task. Remarkably, similar changes also occurred in task-deactivated brain regions, revealing the presence of an optimal dynamic range in the fMRI signal. The scale-free properties of the fMRI signal and brain electrical field potentials bespeak their respective stationarity and nonstationarity. This suggests that neurovascular coupling mechanism is likely to contain a transformation from nonstationarity to stationarity. In summary, our results demonstrate the functional relevance of scale-free properties of the fMRI signal and impose constraints on future models of neurovascular coupling. [ABSTRACT FROM AUTHOR]

Published
2011
Full Text
View/download PDF

39. The Temporal Structures and Functional Significance of Scale-free Brain Activity

Author

He, Biyu J., Zempel, John M., Snyder, Abraham Z., and Raichle, Marcus E.

Subjects
*BRAIN physiology, *ELECTROPHYSIOLOGY, *BRAIN function localization, *TASK performance, *VISUAL cortex, *COGNITION
Abstract

Summary: Scale-free dynamics, with a power spectrum following P ∝f −β, are an intrinsic feature of many complex processes in nature. In neural systems, scale-free activity is often neglected in electrophysiological research. Here, we investigate scale-free dynamics in human brain and show that it contains extensive nested frequencies, with the phase of lower frequencies modulating the amplitude of higher frequencies in an upward progression across the frequency spectrum. The functional significance of scale-free brain activity is indicated by task performance modulation and regional variation, with β being larger in default network and visual cortex and smaller in hippocampus and cerebellum. The precise patterns of nested frequencies in the brain differ from other scale-free dynamics in nature, such as earth seismic waves and stock market fluctuations, suggesting system-specific generative mechanisms. Our findings reveal robust temporal structures and behavioral significance of scale-free brain activity and should motivate future study on its physiological mechanisms and cognitive implications. [Copyright &y& Elsevier]

Published
2010
Full Text
View/download PDF

40. Loss of Resting Interhemispheric Functional Connectivity after Complete Section of the Corpus Callosum.

Author

Johnston, James M., Vaishnavi, S. Neil, Smyth, Matthew D., Dongyang Zhang, He, Biyu J., Zempel, John M., Shimony, Joshua S., Snyder, Abraham Z., and Raichle, Marcus E.

Subjects
CORPUS callosum, TELENCEPHALON, EPILEPSY, BRAIN diseases, DEVELOPMENTAL disabilities
Abstract

Slow (-0.1 Hz), spontaneous fluctuations in the functional magnetic resonance imaging blood oxygen level-dependent (BOLD) signal have been shown to exhibit phase coherence within functionally related areas of the brain. Surprisingly, this phenomenon appears to transcend levels of consciousness. The genesis of coherent BOLD fluctuations remains to be fully explained. We present a resting state functional connectivity study of a 6-year-old child with a radiologically normal brain imaged both before and after complete section of the corpus callosum for the treatment of intractable epilepsy. Postoperatively, there was a striking loss of interhemispheric BOLD correlations with preserved intrahemispheric correlations. These unique data provide important insights into the relationship between connectional anatomy and functional organization of the human brain. Such observations have the potential to increase our understanding of large-scale brain systems in health and disease as well as improve the treatment of neurologic disorders. [ABSTRACT FROM AUTHOR]

Published
2008
Full Text
View/download PDF

41. Anatomical Correlates of Directional Hypokinesia in Patients with Hemispatial Neglect.

Author

Sapir, Ayelet, Kaplan, Julie B., He, Biyu J., and Corbetta, Maurizio

Subjects
UNILATERAL neglect, PERCEPTUAL disorders, CEREBRAL hemispheres, MOVEMENT disorders, HYPOKINESIA, PRECANCEROUS conditions, BASAL ganglia, DOPAMINE
Abstract

Unilateral spatial neglect (neglect) is a syndrome characterized by perceptual deficits that prevent patients from attending and responding to the side of space and of the body opposite a damaged hemisphere (contralesional side). Neglect also involves motor deficits: patients may be slower to initiate a motor response to targets appearing in the left hemispace, even when using their unaffected arm (directional hypokinesia). Although this impairment is well known, its anatomical correlate has not been established. We tested 52 patients with neglect after right hemisphere stroke, and conducted an anatomical analysis on 29 of them to find the anatomical correlate of directional hypokinesia. We found that patients with directional hypokinesia had a lesion involving the ventral lateral putamen, the claustrum, and the white matter underneath the frontal lobe. Most importantly, none of the patients without directional hypokinesia had a lesion in the same region. The localization of neglect's motor deficits to the basal ganglia establishes interesting homologies with animal data; it also suggests that a relative depletion of dopamine in the nigrostriatal pathway on the same side of the lesion may be an important pathophysiological mechanism potentially amenable to intervention. [ABSTRACT FROM AUTHOR]

Published
2007
Full Text
View/download PDF

42. Breakdown of Functional Connectivity in Frontoparietal Networks Underlies Behavioral Deficits in Spatial Neglect

Author

He, Biyu J., Snyder, Abraham Z., Vincent, Justin L., Epstein, Adrian, Shulman, Gordon L., and Corbetta, Maurizio

Subjects
*BRAIN, *CORTICEUS, *CHRONIC diseases, *UNILATERAL neglect
Abstract

Summary: Spatial neglect is a syndrome following stroke manifesting attentional deficits in perceiving and responding to stimuli in the contralesional field. We examined brain network integrity in patients with neglect by measuring coherent fluctuations of fMRI signals (functional connectivity). Connectivity in two largely separate attention networks located in dorsal and ventral frontoparietal areas was assessed at both acute and chronic stages of recovery. Connectivity in the ventral network, part of which directly lesioned, was diffusely disrupted and showed no recovery. In the structurally intact dorsal network, interhemispheric connectivity in posterior parietal cortex was acutely disrupted but fully recovered. This acute disruption, and disrupted connectivity in specific pathways in the ventral network, strongly correlated with impaired attentional processing across subjects. Lastly, disconnection of the white matter tracts connecting frontal and parietal cortices was associated with more severe neglect and more disrupted functional connectivity. These findings support a network view in understanding neglect. [Copyright &y& Elsevier]

Published
2007
Full Text
View/download PDF

44. A novel, semi-automatic procedure for generating slow change blindness stimuli.

Author

Frey HG, Koenig L, He BJ, and Brascamp JW

Abstract

Change blindness is the phenomenon that occurs when an observer fails to notice what would seem to be obvious changes in the features of a visual stimulus. Researchers can induce this experimentally by including visual disruptions (such as brief blanks) that coincide with the changes in question. However, change blindness can also occur in the absence of these disruptions if a change occurs sufficiently slowly. This "slow" or "gradual" change blindness phenomenon has not been extensively researched. Two plausible practical reasons for this are that there are few slow-change stimuli available, and that it is difficult to collect trial-specific responses without affecting expectations on later trials. Here, we describe a novel, semi-automatic procedure for quickly generating many slow-change stimuli. This procedure creates stimuli that have been specifically designed to allow assessment of change blindness on individual trials without influencing subsequent trials. We include the results of three validation experiments that demonstrate that these stimuli are effective and suitable for use in systematic studies of slow change blindness., Competing Interests: The authors have no competing interests to declare that are relevant to the content of this article., (© The Author(s) 2024. Published by Oxford University Press.)

Published
2024
Full Text
View/download PDF

45. Spatiotemporal neural dynamics of object recognition under uncertainty in humans.

Author

Wu YH, Podvalny E, and He BJ

Subjects
Humans, Uncertainty, Magnetic Resonance Imaging methods, Recognition, Psychology, Brain Mapping methods, Photic Stimulation methods, Pattern Recognition, Visual, Visual Perception
Abstract

While there is a wealth of knowledge about core object recognition-our ability to recognize clear, high-contrast object images-how the brain accomplishes object recognition tasks under increased uncertainty remains poorly understood. We investigated the spatiotemporal neural dynamics underlying object recognition under increased uncertainty by combining MEG and 7 Tesla (7T) fMRI in humans during a threshold-level object recognition task. We observed an early, parallel rise of recognition-related signals across ventral visual and frontoparietal regions that preceded the emergence of category-related information. Recognition-related signals in ventral visual regions were best explained by a two-state representational format whereby brain activity bifurcated for recognized and unrecognized images. By contrast, recognition-related signals in frontoparietal regions exhibited a reduced representational space for recognized images, yet with sharper category information. These results provide a spatiotemporally resolved view of neural activity supporting object recognition under uncertainty, revealing a pattern distinct from that underlying core object recognition., Competing Interests: YW, EP, BH No competing interests declared, (© 2023, Wu et al.)

Published
2023
Full Text
View/download PDF

46. Frequency-specific neural signatures of perceptual content and perceptual stability.

Author

Hardstone R, Flounders MW, Zhu M, and He BJ

Subjects
Brain, Humans, Magnetoencephalography, Visual Perception
Abstract

In the natural environment, we often form stable perceptual experiences from ambiguous and fleeting sensory inputs. Which neural activity underlies the content of perception and which neural activity supports perceptual stability remains an open question. We used a bistable perception paradigm involving ambiguous images to behaviorally dissociate perceptual content from perceptual stability, and magnetoencephalography to measure whole-brain neural dynamics in humans. Combining multivariate decoding and neural state-space analyses, we found frequency-band-specific neural signatures that underlie the content of perception and promote perceptual stability, respectively. Across different types of images, non-oscillatory neural activity in the slow cortical potential (<5 Hz) range supported the content of perception. Perceptual stability was additionally influenced by the amplitude of alpha and beta oscillations. In addition, neural activity underlying perceptual memory, which supports perceptual stability when sensory input is temporally removed from view, also encodes elapsed time. Together, these results reveal distinct neural mechanisms that support the content versus stability of visual perception., Competing Interests: RH, MF, MZ, BH No competing interests declared, (© 2022, Hardstone et al.)

Published
2022
Full Text
View/download PDF

47. Neural dynamics of visual ambiguity resolution by perceptual prior.

Author

Flounders MW, González-García C, Hardstone R, and He BJ

Subjects
Action Potentials, Adult, Attention, Female, Humans, Magnetic Resonance Imaging, Male, Models, Neurological, Young Adult, Learning, Recognition, Psychology, Visual Perception
Abstract

Past experiences have enormous power in shaping our daily perception. Currently, dynamical neural mechanisms underlying this process remain mysterious. Exploiting a dramatic visual phenomenon, where a single experience of viewing a clear image allows instant recognition of a related degraded image, we investigated this question using MEG and 7 Tesla fMRI in humans. We observed that following the acquisition of perceptual priors, different degraded images are represented much more distinctly in neural dynamics starting from ~500 ms after stimulus onset. Content-specific neural activity related to stimulus-feature processing dominated within 300 ms after stimulus onset, while content-specific neural activity related to recognition processing dominated from 500 ms onward. Model-driven MEG-fMRI data fusion revealed the spatiotemporal evolution of neural activities involved in stimulus, attentional, and recognition processing. Together, these findings shed light on how experience shapes perceptual processing across space and time in the brain., Competing Interests: MF, CG, RH, BH No competing interests declared, (© 2019, Flounders et al.)

Published
2019
Full Text
View/download PDF

48. Content-specific activity in frontoparietal and default-mode networks during prior-guided visual perception.

Author

González-García C, Flounders MW, Chang R, Baria AT, and He BJ

Subjects
Adult, Brain Mapping, Female, Humans, Magnetic Resonance Imaging, Male, Young Adult, Brain physiology, Frontal Lobe physiology, Models, Neurological, Nerve Net physiology, Parietal Lobe physiology, Visual Perception physiology
Abstract

How prior knowledge shapes perceptual processing across the human brain, particularly in the frontoparietal (FPN) and default-mode (DMN) networks, remains unknown. Using ultra-high-field (7T) functional magnetic resonance imaging (fMRI), we elucidated the effects that the acquisition of prior knowledge has on perceptual processing across the brain. We observed that prior knowledge significantly impacted neural representations in the FPN and DMN, rendering responses to individual visual images more distinct from each other, and more similar to the image-specific prior. In addition, neural representations were structured in a hierarchy that remained stable across perceptual conditions, with early visual areas and DMN anchored at the two extremes. Two large-scale cortical gradients occur along this hierarchy: first, dimensionality of the neural representational space increased along the hierarchy; second, prior's impact on neural representations was greater in higher-order areas. These results reveal extensive and graded influences of prior knowledge on perceptual processing across the brain., Competing Interests: CG, MF, RC, AB, BH No competing interests declared

Published
2018
Full Text
View/download PDF

49. Neural Integration of Stimulus History Underlies Prediction for Naturalistically Evolving Sequences.

Author

Maniscalco B, Lee JL, Abry P, Lin A, Holroyd T, and He BJ

Subjects
Acoustic Stimulation, Adult, Algorithms, Auditory Perception physiology, Female, Humans, Magnetoencephalography, Male, Pitch Perception physiology, Psychomotor Performance physiology, Young Adult, Anticipation, Psychological physiology, Nerve Net physiology
Abstract

Forming valid predictions about the environment is crucial to survival. However, whether humans are able to form valid predictions about natural stimuli based on their temporal statistical regularities remains unknown. Here, we presented subjects with tone sequences with pitch fluctuations that, over time, capture long-range temporal dependence structures prevalent in natural stimuli. We found that subjects were able to exploit such naturalistic statistical regularities to make valid predictions about upcoming items in a sequence. Magnetoencephalography (MEG) recordings revealed that slow, arrhythmic cortical dynamics tracked the evolving pitch sequence over time such that neural activity at a given moment was influenced by the pitch of up to seven previous tones. Importantly, such history integration contained in neural activity predicted the expected pitch of the upcoming tone, providing a concrete computational mechanism for prediction. These results establish humans' ability to make valid predictions based on temporal regularities inherent in naturalistic stimuli and further reveal the neural mechanisms underlying such predictive computation. SIGNIFICANCE STATEMENT A fundamental question in neuroscience is how the brain predicts upcoming events in the environment. To date, this question has primarily been addressed in experiments using relatively simple stimulus sequences. Here, we studied predictive processing in the human brain using auditory tone sequences that exhibit temporal statistical regularities similar to those found in natural stimuli. We observed that humans are able to form valid predictions based on such complex temporal statistical regularities. We further show that neural response to a given tone in the sequence reflects integration over the preceding tone sequence and that this history dependence forms the foundation for prediction. These findings deepen our understanding of how humans form predictions in an ecologically valid environment., (Copyright © 2018 the authors 0270-6474/18/381541-17$15.00/0.)

Published
2018
Full Text
View/download PDF

50. Scale-Free Neural and Physiological Dynamics in Naturalistic Stimuli Processing.

Author

Lin A, Maniscalco B, and He BJ

Subjects
Acoustic Stimulation, Adult, Alpha Rhythm, Discrimination, Psychological physiology, Electrocardiography, Female, Heart Rate, Humans, Magnetoencephalography, Male, Neuropsychological Tests, Rest, Signal Processing, Computer-Assisted, Time Factors, Young Adult, Auditory Perception physiology, Brain physiology
Abstract

Neural activity recorded at multiple spatiotemporal scales is dominated by arrhythmic fluctuations without a characteristic temporal periodicity. Such activity often exhibits a 1/ f -type power spectrum, in which power falls off with increasing frequency following a power-law function: [Formula: see text], which is indicative of scale-free dynamics. Two extensively studied forms of scale-free neural dynamics in the human brain are slow cortical potentials (SCPs)-the low-frequency (<5 Hz) component of brain field potentials-and the amplitude fluctuations of α oscillations, both of which have been shown to carry important functional roles. In addition, scale-free dynamics characterize normal human physiology such as heartbeat dynamics. However, the exact relationships among these scale-free neural and physiological dynamics remain unclear. We recorded simultaneous magnetoencephalography and electrocardiography in healthy subjects in the resting state and while performing a discrimination task on scale-free dynamical auditory stimuli that followed different scale-free statistics. We observed that long-range temporal correlation (captured by the power-law exponent β) in SCPs positively correlated with that of heartbeat dynamics across time within an individual and negatively correlated with that of α-amplitude fluctuations across individuals. In addition, across individuals, long-range temporal correlation of both SCP and α-oscillation amplitude predicted subjects' discrimination performance in the auditory task, albeit through antagonistic relationships. These findings reveal interrelations among different scale-free neural and physiological dynamics and initial evidence for the involvement of scale-free neural dynamics in the processing of natural stimuli, which often exhibit scale-free dynamics., Competing Interests: Authors report no conflict of interest

Published
2016
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results