Your search keyword '"Yang, Dalin"' showing total 5 results

1. A sucrose ferulate cycle linchpin for feruloylation of arabinoxylans in plant commelinids

Author

Yang, Dalin, Liu, Hui, Li, Xiaojie, Zhang, Yafeng, Zhang, Xingwang, Yang, Huanhuan, Liu, Mingyu, Koch, Karen E., McCarty, Donald R., Li, Shengying, and Tan, Bao-Cai

Published

2024

2. Mapping neural correlates of biological motion perception in autistic children using high-density diffuse optical tomography.

Author

Yang, Dalin, Svoboda, Alexandra M., George, Tessa G., Mansfield, Patricia K., Wheelock, Muriah D., Schroeder, Mariel L., Rafferty, Sean M., Sherafati, Arefeh, Tripathy, Kalyan, Burns-Yocum, Tracy, Forsen, Elizabeth, Pruett, John R., Marrus, Natasha M., Culver, Joseph P., Constantino, John N., and Eggebrecht, Adam T.

Subjects

*FUNCTIONAL magnetic resonance imaging, *OPTICAL tomography, *AUTISM spectrum disorders, *AUTISTIC children, *BRAIN imaging

Abstract

Background: Autism spectrum disorder (ASD), a neurodevelopmental disorder defined by social communication deficits plus repetitive behaviors and restricted interests, currently affects 1/36 children in the general population. Recent advances in functional brain imaging show promise to provide useful biomarkers of ASD diagnostic likelihood, behavioral trait severity, and even response to therapeutic intervention. However, current gold-standard neuroimaging methods (e.g., functional magnetic resonance imaging, fMRI) are limited in naturalistic studies of brain function underlying ASD-associated behaviors due to the constrained imaging environment. Compared to fMRI, high-density diffuse optical tomography (HD-DOT), a non-invasive and minimally constraining optical neuroimaging modality, can overcome these limitations. Herein, we aimed to establish HD-DOT to evaluate brain function in autistic and non-autistic school-age children as they performed a biological motion perception task previously shown to yield results related to both ASD diagnosis and behavioral traits. Methods: We used HD-DOT to image brain function in 46 ASD school-age participants and 49 non-autistic individuals (NAI) as they viewed dynamic point-light displays of coherent biological and scrambled motion. We assessed group-level cortical brain function with statistical parametric mapping. Additionally, we tested for brain-behavior associations with dimensional metrics of autism traits, as measured with the Social Responsiveness Scale-2, with hierarchical regression models. Results: We found that NAI participants presented stronger brain activity contrast (coherent > scrambled) than ASD children in cortical regions related to visual, motor, and social processing. Additionally, regression models revealed multiple cortical regions in autistic participants where brain function is significantly associated with dimensional measures of ASD traits. Limitations: Optical imaging methods are limited in depth sensitivity and so cannot measure brain activity within deep subcortical regions. However, the field of view of this HD-DOT system includes multiple brain regions previously implicated in both task-based and task-free studies on autism. Conclusions: This study demonstrates that HD-DOT is sensitive to brain function that both differentiates between NAI and ASD groups and correlates with dimensional measures of ASD traits. These findings establish HD-DOT as an effective tool for investigating brain function in autistic and non-autistic children. Moreover, this study established neural correlates related to biological motion perception and its association with dimensional measures of ASD traits. [ABSTRACT FROM AUTHOR]

Published

2024

3. Mapping neural correlates of biological motion perception in autistic children using high-density diffuse optical tomography

Author

Yang*, Dalin, primary, Svoboda*, Alexandra M., additional, George, Tessa G., additional, Mansfield, Patricia K., additional, Wheelock, Muriah D., additional, Schroeder, Mariel L., additional, Rafferty, Sean M., additional, Sherafati, Arefeh, additional, Tripathy, Kalyan, additional, Burns-Yocum, Tracy, additional, Forsen, Elizabeth, additional, Pruett, John R., additional, Marrus, Natasha M., additional, Culver, Joseph P., additional, Constantino, John N., additional, and Eggebrecht, Adam T., additional

Published

2024

4. FMCW Radar Human Action Recognition Based on Asymmetric Convolutional Residual Blocks.

Author

Zhang, Yuan, Tang, Haotian, Wu, Ye, Wang, Bolun, and Yang, Dalin

Subjects

HUMAN activity recognition, DEEP learning, FEATURE extraction, RADAR, MACHINE learning, MULTISPECTRAL imaging

Abstract

Human action recognition based on optical and infrared video data is greatly affected by the environment, and feature extraction in traditional machine learning classification methods is complex; therefore, this paper proposes a method for human action recognition using Frequency Modulated Continuous Wave (FMCW) radar based on an asymmetric convolutional residual network. First, the radar echo data are analyzed and processed to extract the micro-Doppler time domain spectrograms of different actions. Second, a strategy combining asymmetric convolution and the Mish activation function is adopted in the residual block of the ResNet18 network to address the limitations of linear and nonlinear transformations in the residual block for micro-Doppler spectrum recognition. This approach aims to enhance the network's ability to learn features effectively. Finally, the Improved Convolutional Block Attention Module (ICBAM) is integrated into the residual block to enhance the model's attention and comprehension of input data. The experimental results demonstrate that the proposed method achieves a high accuracy of 98.28% in action recognition and classification within complex scenes, surpassing classic deep learning approaches. Moreover, this method significantly improves the recognition accuracy for actions with similar micro-Doppler features and demonstrates excellent anti-noise recognition performance. [ABSTRACT FROM AUTHOR]

Published

2024

5. Repetitive Transcranial Alternating Current Stimulation to Improve Working Memory: An EEG-fNIRS Study.

Author

Yang D, Kang MK, Huang G, Eggebrecht AT, and Hong KS

Subjects

Humans, Electroencephalography, Brain physiology, Frontal Lobe physiology, Memory, Short-Term physiology, Transcranial Direct Current Stimulation methods

Abstract

Transcranial electrical stimulation has demonstrated the potential to enhance cognitive functions such as working memory, learning capacity, and attentional allocation. Recently, it was shown that periodic stimulation within a specific duration could augment the human brain's neuroplasticity. This study investigates the effects of repetitive transcranial alternating current stimulation (tACS; 1 mA, 5 Hz, 2 min duration) on cognitive function, functional connectivity, and topographic changes using both electroencephalography (EEG) and functional near-infrared spectroscopy (fNIRS). Fifteen healthy subjects were recruited to measure brain activity in the pre-, during-, and post-stimulation sessions under tACS and sham stimulation conditions. Fourteen trials of working memory tasks and eight repetitions of tACS/sham stimulation with a 1-minute intersession interval were applied to the frontal cortex of the participants. The working memory score, EEG band-wise powers, EEG topography, concentration changes of oxygenated hemoglobin, and functional connectivity (FC) were individually analyzed to quantify the behavioral and neurophysiological effects of tACS. Our results indicate that tACS increases: i) behavioral scores (i.e., 15.08, ) and EEG band-wise powers (i.e., theta and beta bands) compared to the sham stimulation condition, ii) FC of both EEG-fNIRS signals, especially in the large-scale brain network communication and interhemispheric connections, and iii) the hemodynamic response in comparison to the pre-stimulation session and the sham condition. Conclusively, the repetitive theta-band tACS stimulation improves the working memory capacity regarding behavioral and neuroplasticity perspectives. Additionally, the proposed fNIRS biomarkers (mean, slope), EEG band-wise powers, and FC can be used as neuro-feedback indices for closed-loop brain stimulation.

Published

2024