1.The superior fault tolerance of artificial neural network training with a fault/noise injection-based genetic algorithm.
Feng SU ; Peijiang YUAN ; Yangzhen WANG ; Chen ZHANG
Protein & Cell 2016;7(10):735-748
Artificial neural networks (ANNs) are powerful computational tools that are designed to replicate the human brain and adopted to solve a variety of problems in many different fields. Fault tolerance (FT), an important property of ANNs, ensures their reliability when significant portions of a network are lost. In this paper, a fault/noise injection-based (FIB) genetic algorithm (GA) is proposed to construct fault-tolerant ANNs. The FT performance of an FIB-GA was compared with that of a common genetic algorithm, the back-propagation algorithm, and the modification of weights algorithm. The FIB-GA showed a slower fitting speed when solving the exclusive OR (XOR) problem and the overlapping classification problem, but it significantly reduced the errors in cases of single or multiple faults in ANN weights or nodes. Further analysis revealed that the fit weights showed no correlation with the fitting errors in the ANNs constructed with the FIB-GA, suggesting a relatively even distribution of the various fitting parameters. In contrast, the output weights in the training of ANNs implemented with the use the other three algorithms demonstrated a positive correlation with the errors. Our findings therefore indicate that a combination of the fault/noise injection-based method and a GA is capable of introducing FT to ANNs and imply that the distributed ANNs demonstrate superior FT performance.
Algorithms
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Humans
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Models, Genetic
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Neural Networks (Computer)
2.Noninvasive Tracking of Every Individual in Unmarked Mouse Groups Using Multi-Camera Fusion and Deep Learning.
Feng SU ; Yangzhen WANG ; Mengping WEI ; Chong WANG ; Shaoli WANG ; Lei YANG ; Jianmin LI ; Peijiang YUAN ; Dong-Gen LUO ; Chen ZHANG
Neuroscience Bulletin 2023;39(6):893-910
Accurate and efficient methods for identifying and tracking each animal in a group are needed to study complex behaviors and social interactions. Traditional tracking methods (e.g., marking each animal with dye or surgically implanting microchips) can be invasive and may have an impact on the social behavior being measured. To overcome these shortcomings, video-based methods for tracking unmarked animals, such as fruit flies and zebrafish, have been developed. However, tracking individual mice in a group remains a challenging problem because of their flexible body and complicated interaction patterns. In this study, we report the development of a multi-object tracker for mice that uses the Faster region-based convolutional neural network (R-CNN) deep learning algorithm with geometric transformations in combination with multi-camera/multi-image fusion technology. The system successfully tracked every individual in groups of unmarked mice and was applied to investigate chasing behavior. The proposed system constitutes a step forward in the noninvasive tracking of individual mice engaged in social behavior.
Animals
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Mice
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Deep Learning
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Zebrafish
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Algorithms
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Neural Networks, Computer
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Social Behavior
3.Restoration of FMRP expression in adult V1 neurons rescues visual deficits in a mouse model of fragile X syndrome.
Chaojuan YANG ; Yonglu TIAN ; Feng SU ; Yangzhen WANG ; Mengna LIU ; Hongyi WANG ; Yaxuan CUI ; Peijiang YUAN ; Xiangning LI ; Anan LI ; Hui GONG ; Qingming LUO ; Desheng ZHU ; Peng CAO ; Yunbo LIU ; Xunli WANG ; Min-Hua LUO ; Fuqiang XU ; Wei XIONG ; Liecheng WANG ; Xiang-Yao LI ; Chen ZHANG
Protein & Cell 2022;13(3):203-219
Many people affected by fragile X syndrome (FXS) and autism spectrum disorders have sensory processing deficits, such as hypersensitivity to auditory, tactile, and visual stimuli. Like FXS in humans, loss of Fmr1 in rodents also cause sensory, behavioral, and cognitive deficits. However, the neural mechanisms underlying sensory impairment, especially vision impairment, remain unclear. It remains elusive whether the visual processing deficits originate from corrupted inputs, impaired perception in the primary sensory cortex, or altered integration in the higher cortex, and there is no effective treatment. In this study, we used a genetic knockout mouse model (Fmr1KO), in vivo imaging, and behavioral measurements to show that the loss of Fmr1 impaired signal processing in the primary visual cortex (V1). Specifically, Fmr1KO mice showed enhanced responses to low-intensity stimuli but normal responses to high-intensity stimuli. This abnormality was accompanied by enhancements in local network connectivity in V1 microcircuits and increased dendritic complexity of V1 neurons. These effects were ameliorated by the acute application of GABAA receptor activators, which enhanced the activity of inhibitory neurons, or by reintroducing Fmr1 gene expression in knockout V1 neurons in both juvenile and young-adult mice. Overall, V1 plays an important role in the visual abnormalities of Fmr1KO mice and it could be possible to rescue the sensory disturbances in developed FXS and autism patients.
Animals
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Disease Models, Animal
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Fragile X Mental Retardation Protein/metabolism*
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Fragile X Syndrome/metabolism*
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Humans
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Mice
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Mice, Knockout
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Neurons/metabolism*