Your search keyword '"Chen, Nihong"' showing total 6 results

1. Learning Improves Peripheral Vision Via Enhanced Cortico-Cortical Communications.

Author

Cui Y, Lu X, Kwon M, and Chen N

Subjects

Humans, Animals, Visual Cortex physiology, Vision, Ocular physiology, Cerebral Cortex physiology, Learning physiology

Published

2024

2. Neural mechanisms of motion perceptual learning in noise.

Author

Chen N, Lu J, Shao H, Weng X, and Fang F

Subjects

Adult, Brain diagnostic imaging, Brain Mapping, Discrimination, Psychological physiology, Female, Humans, Magnetic Resonance Imaging, Male, Models, Theoretical, Neuronal Plasticity, Neuropsychological Tests, Photic Stimulation methods, Psychophysics, Young Adult, Brain physiology, Learning physiology, Motion Perception physiology

Abstract

Practice improves our perceptual ability. However, the neural mechanisms underlying this experience-dependent plasticity in adult brain remain unclear. Here, we studied the long-term neural correlates of motion perceptual learning. Subjects' behavioral performance and BOLD signals were tracked before, immediately after, and 2 weeks after practicing a motion direction discrimination task in noise over six daily sessions. Parallel to the specificity and persistency of the behavioral learning effect, we found that training sharpened the cortical tuning in MT, and enhanced the connectivity strength from MT to the intraparietal sulcus (IPS, a motion decision-making area). In addition, the decoding accuracy for the trained motion direction was improved in IPS 2 weeks after training. The dual changes in the sensory and the high-level cortical areas suggest that learning refines the neural representation of the trained stimulus and facilitates the information transmission in the decision process. Our findings are consistent with the functional specialization in the visual cortex, and provide empirical evidence to the reweighting theory of perceptual learning at a large spatial scale. Hum Brain Mapp 38:6029-6042, 2017. © 2017 Wiley Periodicals, Inc., (© 2017 Wiley Periodicals, Inc.)

Published

2017

3. Perceptual learning modifies the functional specializations of visual cortical areas.

Author

Chen N, Cai P, Zhou T, Thompson B, and Fang F

Subjects

Adult, Female, Humans, Magnetic Resonance Imaging, Male, Psychophysics, Transcranial Magnetic Stimulation, Learning, Motion Perception physiology, Neuronal Plasticity, Psychomotor Performance, Visual Cortex physiology

Abstract

Training can improve performance of perceptual tasks. This phenomenon, known as perceptual learning, is strongest for the trained task and stimulus, leading to a widely accepted assumption that the associated neuronal plasticity is restricted to brain circuits that mediate performance of the trained task. Nevertheless, learning does transfer to other tasks and stimuli, implying the presence of more widespread plasticity. Here, we trained human subjects to discriminate the direction of coherent motion stimuli. The behavioral learning effect substantially transferred to noisy motion stimuli. We used transcranial magnetic stimulation (TMS) and functional magnetic resonance imaging (fMRI) to investigate the neural mechanisms underlying the transfer of learning. The TMS experiment revealed dissociable, causal contributions of V3A (one of the visual areas in the extrastriate visual cortex) and MT+ (middle temporal/medial superior temporal cortex) to coherent and noisy motion processing. Surprisingly, the contribution of MT+ to noisy motion processing was replaced by V3A after perceptual training. The fMRI experiment complemented and corroborated the TMS finding. Multivariate pattern analysis showed that, before training, among visual cortical areas, coherent and noisy motion was decoded most accurately in V3A and MT+, respectively. After training, both kinds of motion were decoded most accurately in V3A. Our findings demonstrate that the effects of perceptual learning extend far beyond the retuning of specific neural populations for the trained stimuli. Learning could dramatically modify the inherent functional specializations of visual cortical areas and dynamically reweight their contributions to perceptual decisions based on their representational qualities. These neural changes might serve as the neural substrate for the transfer of perceptual learning.

Published

2016

4. Sharpened cortical tuning and enhanced cortico-cortical communication contribute to the long-term neural mechanisms of visual motion perceptual learning.

Author

Chen N, Bi T, Zhou T, Li S, Liu Z, and Fang F

Subjects

Adult, Brain Mapping, Decision Making physiology, Discrimination, Psychological physiology, Female, Humans, Magnetic Resonance Imaging, Male, Models, Neurological, Oxygen blood, Psychomotor Performance physiology, Synaptic Transmission physiology, Visual Cortex physiology, Young Adult, Cerebral Cortex physiology, Learning physiology, Motion Perception physiology, Nerve Net physiology, Visual Perception physiology

Abstract

Much has been debated about whether the neural plasticity mediating perceptual learning takes place at the sensory or decision-making stage in the brain. To investigate this, we trained human subjects in a visual motion direction discrimination task. Behavioral performance and BOLD signals were measured before, immediately after, and two weeks after training. Parallel to subjects' long-lasting behavioral improvement, the neural selectivity in V3A and the effective connectivity from V3A to IPS (intraparietal sulcus, a motion decision-making area) exhibited a persistent increase for the trained direction. Moreover, the improvement was well explained by a linear combination of the selectivity and connectivity increases. These findings suggest that the long-term neural mechanisms of motion perceptual learning are implemented by sharpening cortical tuning to trained stimuli at the sensory processing stage, as well as by optimizing the connections between sensory and decision-making areas in the brain., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

5. Learning to discriminate face views.

Author

Bi T, Chen N, Weng Q, He D, and Fang F

Subjects

Educational Measurement, Female, Humans, Learning Curve, Male, Young Adult, Discrimination, Psychological physiology, Face, Form Perception physiology, Learning physiology

Abstract

Although perceptual learning of simple visual features has been studied extensively and intensively for many years, we still know little about the mechanisms of perceptual learning of complex object recognition. In a series of seven experiments, human perceptual learning in discrimination of in-depth orientation of face view was studied using psychophysical methods. We trained subjects to discriminate face orientations around a face view (i.e., 30°) over eight daily sessions, which resulted in a significant improvement in sensitivity to the face view orientation. This improved sensitivity was highly specific to the trained orientation and persisted up to 6 mo. Different from perceptual learning of simple visual features, this orientation-specific learning effect could completely transfer across changes in face size, visual field, and face identity. A complete transfer also occurred between two partial face images that were mutually exclusive but constituted a complete face. However, the transfer of the learning effect between upright and inverted faces and between a face and a paperclip object was very weak. These results shed light on the mechanisms of the perceptual learning of face view discrimination. They suggest that the visual system had learned how to compute face orientation from face configural information more accurately and that a large amount of plastic changes took place at a level of higher visual processing where size-, location-, and identity-invariant face views are represented.

Published

2010

6. Neural mechanisms of motion perceptual learning in noise

Author

Chen, Nihong, Lu, Junshi, Shao, Hanyu, Weng, Xuchu, and Fang, Fang

Subjects

Adult, Male, Brain Mapping, Neuronal Plasticity, Motion Perception, Brain, Models, Theoretical, Neuropsychological Tests, Magnetic Resonance Imaging, Young Adult, Discrimination, Psychological, Psychophysics, Humans, Learning, Female, Research Articles, Photic Stimulation

Abstract

Practice improves our perceptual ability. However, the neural mechanisms underlying this experience-dependent plasticity in adult brain remain unclear. Here, we studied the long-term neural correlates of motion perceptual learning. Subjects' behavioral performance and BOLD signals were tracked before, immediately after, and 2 weeks after practicing a motion direction discrimination task in noise over six daily sessions. Parallel to the specificity and persistency of the behavioral learning effect, we found that training sharpened the cortical tuning in MT, and enhanced the connectivity strength from MT to the intraparietal sulcus (IPS, a motion decision-making area). In addition, the decoding accuracy for the trained motion direction was improved in IPS 2 weeks after training. The dual changes in the sensory and the high-level cortical areas suggest that learning refines the neural representation of the trained stimulus and facilitates the information transmission in the decision process. Our findings are consistent with the functional specialization in the visual cortex, and provide empirical evidence to the reweighting theory of perceptual learning at a large spatial scale. Hum Brain Mapp 38:6029-6042, 2017. © 2017 Wiley Periodicals, Inc.

Published

2017