Your search keyword '"Mingxiong Huang"' showing total 5 results

1. Noninvasive vagus nerve stimulation alters neural response and physiological autonomic tone to noxious thermal challenge.

Author

Imanuel Lerman, Bryan Davis, Mingxiong Huang, Charles Huang, Linda Sorkin, James Proudfoot, Edward Zhong, Donald Kimball, Ramesh Rao, Bruce Simon, Andrea Spadoni, Irina Strigo, Dewleen G Baker, and Alan N Simmons

Subjects

Medicine, Science

Abstract

The mechanisms by which noninvasive vagal nerve stimulation (nVNS) affect central and peripheral neural circuits that subserve pain and autonomic physiology are not clear, and thus remain an area of intense investigation. Effects of nVNS vs sham stimulation on subject responses to five noxious thermal stimuli (applied to left lower extremity), were measured in 30 healthy subjects (n = 15 sham and n = 15 nVNS), with fMRI and physiological galvanic skin response (GSR). With repeated noxious thermal stimuli a group × time analysis showed a significantly (p < .001) decreased response with nVNS in bilateral primary and secondary somatosensory cortices (SI and SII), left dorsoposterior insular cortex, bilateral paracentral lobule, bilateral medial dorsal thalamus, right anterior cingulate cortex, and right orbitofrontal cortex. A group × time × GSR analysis showed a significantly decreased response in the nVNS group (p < .0005) bilaterally in SI, lower and mid medullary brainstem, and inferior occipital cortex. Finally, nVNS treatment showed decreased activity in pronociceptive brainstem nuclei (e.g. the reticular nucleus and rostral ventromedial medulla) and key autonomic integration nuclei (e.g. the rostroventrolateral medulla, nucleus ambiguous, and dorsal motor nucleus of the vagus nerve). In aggregate, noninvasive vagal nerve stimulation reduced the physiological response to noxious thermal stimuli and impacted neural circuits important for pain processing and autonomic output.

Published

2019

2. Resting-state neuronal oscillatory correlates of working memory performance.

Author

David Heister, Mithun Diwakar, Sharon Nichols, Ashley Robb, Anne Marie Angeles, Omer Tal, Deborah L Harrington, Tao Song, Roland R Lee, and Mingxiong Huang

Subjects

Medicine, Science

Abstract

Working memory (WM) represents the brain's ability to maintain information in a readily available state for short periods of time. This study examines the resting-state cortical activity patterns that are most associated with performance on a difficult working-memory task.Magnetoencephalographic (MEG) band-passed (delta/theta (1-7 Hz), alpha (8-13 Hz), beta (14-30 Hz)) and sensor based regional power was collected in a population of adult men (18-28 yrs, n = 24) in both an eyes-closed and eyes-open resting state. The normalized power within each resting state condition as well as the normalized change in power between eyes closed and open (zECO) were correlated with performance on a WM task. The regional and band-limited measures that were most associated with performance were then combined using singular value decomposition (SVD) to determine the degree to which zECO power was associated with performance on the three-back verbal WM task.Changes in power from eyes closed to open revealed a significant decrease in power in all band-widths that was most pronounced in the posterior brain regions (delta/theta band). zECO right posterior frontal and parietal cortex delta/theta power were found to be inversely correlated with three-back working memory performance. The SVD evaluation of the most correlated zECO metrics then provided a singular measure that was highly correlated with three-back performance (r = -0.73, p

Published

2013

3. Divergent cortical generators of MEG and EEG during human sleep spindles suggested by distributed source modeling.

Author

Nima Dehghani, Sydney S Cash, Chih C Chen, Donald J Hagler, Mingxiong Huang, Anders M Dale, and Eric Halgren

Subjects

Medicine, Science

Abstract

Sleep spindles are approximately 1-second bursts of 10-15 Hz activity, occurring during normal stage 2 sleep. In animals, sleep spindles can be synchronous across multiple cortical and thalamic locations, suggesting a distributed stable phase-locked generating system. The high synchrony of spindles across scalp EEG sites suggests that this may also be true in humans. However, prior MEG studies suggest multiple and varying generators.We recorded 306 channels of MEG simultaneously with 60 channels of EEG during naturally occurring spindles of stage 2 sleep in 7 healthy subjects. High-resolution structural MRI was obtained in each subject, to define the shells for a boundary element forward solution and to reconstruct the cortex providing the solution space for a noise-normalized minimum norm source estimation procedure. Integrated across the entire duration of all spindles, sources estimated from EEG and MEG are similar, diffuse and widespread, including all lobes from both hemispheres. However, the locations, phase and amplitude of sources simultaneously estimated from MEG versus EEG are highly distinct during the same spindles. Specifically, the sources estimated from EEG are highly synchronous across the cortex, whereas those from MEG rapidly shift in phase, hemisphere, and the location within the hemisphere.The heterogeneity of MEG sources implies that multiple generators are active during human sleep spindles. If the source modeling is correct, then EEG spindles are generated by a different, diffusely synchronous system. Animal studies have identified two thalamo-cortical systems, core and matrix, that produce focal or diffuse activation and thus could underlie MEG and EEG spindles, respectively. Alternatively, EEG spindles could reflect overlap at the sensors of the same sources as are seen from the MEG. Although our results generally match human intracranial recordings, additional improvements are possible and simultaneous intra- and extra-cranial measures are needed to test their accuracy.

Published

2010

4. Resting-state neuronal oscillatory correlates of working memory performance

Author

Deborah L. Harrington, Ashley Robb, Roland R. Lee, David Heister, Sharon Nichols, Mithun Diwakar, Tao Song, Omer Tal, Anne Marie Angeles, and Mingxiong Huang

Subjects

Male, Anatomy and Physiology, lcsh:Medicine, Audiology, Social and Behavioral Sciences, 0302 clinical medicine, Learning and Memory, Psychology, Attention, lcsh:Science, Physics, Cerebral Cortex, Neurons, Clinical Neurophysiology, education.field_of_study, Multidisciplinary, medicine.diagnostic_test, 05 social sciences, Magnetoencephalography, Signal Processing, Computer-Assisted, Memory, Short-Term, Medicine, Research Article, Adult, medicine.medical_specialty, Adolescent, Rest, Cognitive Neuroscience, Population, Alpha (ethology), Posterior parietal cortex, Neurophysiology, 050105 experimental psychology, Neurological System, 03 medical and health sciences, Young Adult, Diagnostic Medicine, Memory, medicine, Humans, 0501 psychology and cognitive sciences, Working Memory, Association (psychology), education, Biology, Computational Neuroscience, Resting state fMRI, Working memory, lcsh:R, Cognitive Psychology, Computational Biology, lcsh:Q, 030217 neurology & neurosurgery, Neuroscience

Abstract

Purpose Working memory (WM) represents the brain’s ability to maintain information in a readily available state for short periods of time. This study examines the resting-state cortical activity patterns that are most associated with performance on a difficult working-memory task. Methods Magnetoencephalographic (MEG) band-passed (delta/theta (1–7 Hz), alpha (8–13 Hz), beta (14–30 Hz)) and sensor based regional power was collected in a population of adult men (18–28 yrs, n = 24) in both an eyes-closed and eyes-open resting state. The normalized power within each resting state condition as well as the normalized change in power between eyes closed and open (zECO) were correlated with performance on a WM task. The regional and band-limited measures that were most associated with performance were then combined using singular value decomposition (SVD) to determine the degree to which zECO power was associated with performance on the three-back verbal WM task. Results Changes in power from eyes closed to open revealed a significant decrease in power in all band-widths that was most pronounced in the posterior brain regions (delta/theta band). zECO right posterior frontal and parietal cortex delta/theta power were found to be inversely correlated with three-back working memory performance. The SVD evaluation of the most correlated zECO metrics then provided a singular measure that was highly correlated with three-back performance (r = −0.73, p

Published

2013

5. Divergent Cortical Generators of MEG and EEG during Human Sleep Spindles Suggested by Distributed Source Modeling.

Author

Dehghani, Nima, Cash, Sydney S., Chih C. Chen, Hagler Jr., Donald J., Mingxiong Huang, Dale, Anders M., and Halgren, Eric

Subjects

SLEEP physiology, CEREBRAL cortex, BIOLOGICAL divergence, ELECTROENCEPHALOGRAPHY, MAGNETOENCEPHALOGRAPHY, MAGNETIC resonance imaging, THALAMUS, BRAIN stimulation, BOUNDARY element methods

Abstract

Background: Sleep spindles are ∼1-second bursts of 10-15 Hz activity, occurring during normal stage 2 sleep. In animals, sleep spindles can be synchronous across multiple cortical and thalamic locations, suggesting a distributed stable phaselocked generating system. The high synchrony of spindles across scalp EEG sites suggests that this may also be true in humans. However, prior MEG studies suggest multiple and varying generators. Methodology/Principal Findings: We recorded 306 channels of MEG simultaneously with 60 channels of EEG during naturally occurring spindles of stage 2 sleep in 7 healthy subjects. High-resolution structural MRI was obtained in each subject, to define the shells for a boundary element forward solution and to reconstruct the cortex providing the solution space for a noise-normalized minimum norm source estimation procedure. Integrated across the entire duration of all spindles, sources estimated from EEG and MEG are similar, diffuse and widespread, including all lobes from both hemispheres. However, the locations, phase and amplitude of sources simultaneously estimated from MEG versus EEG are highly distinct during the same spindles. Specifically, the sources estimated from EEG are highly synchronous across the cortex, whereas those from MEG rapidly shift in phase, hemisphere, and the location within the hemisphere. Conclusions/Significance: The heterogeneity of MEG sources implies that multiple generators are active during human sleep spindles. If the source modeling is correct, then EEG spindles are generated by a different, diffusely synchronous system. Animal studies have identified two thalamo-cortical systems, core and matrix, that produce focal or diffuse activation and thus could underlie MEG and EEG spindles, respectively. Alternatively, EEG spindles could reflect overlap at the sensors of the same sources as are seen from the MEG. Although our results generally match human intracranial recordings, additional improvements are possible and simultaneous intra- and extra-cranial measures are needed to test their accuracy. [ABSTRACT FROM AUTHOR]

Published

2010