Feature-Selection-Based Transfer Learning for Intracortical Brain–Machine Interface Decoding

Zhang, Peng; Li, Wei; Ma, Xuan; He, Jiping; Huang, Jian; Li, Qiang

doi:10.1109/tnsre.2020.3034234

Cited by 8 publications

(2 citation statements)

References 59 publications

(67 reference statements)

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“…Future research aims to develop deep learning models integrating cognitive performance and task state labels for brain decoding. Recognizing the intricate relationship between brain decoding and classification, despite their distinct objectives, we intend to explore the application of zero-shot learning and advanced transfer learning models that can achieve mutual benefits for both brain function decoding and disease classification tasks (Zhang P. et al, 2021). An exciting prospect is the collection of psychiatric disorder data using appropriate task paradigms in clinical settings (Birba et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

TSP-GNN: a novel neuropsychiatric disorder classification framework based on task-specific prior knowledge and graph neural network

Lang,

Yang,

2023

Front. Neurosci.

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Neuropsychiatric disorder (ND) is often accompanied by abnormal functional connectivity (FC) patterns in specific task contexts. The distinctive task-specific FC patterns can provide valuable features for ND classification models using deep learning. However, most previous studies rely solely on the whole-brain FC matrix without considering the prior knowledge of task-specific FC patterns. Insight by the decoding studies on brain-behavior relationship, we develop TSP-GNN, which extracts task-specific prior (TSP) connectome patterns and employs graph neural network (GNN) for disease classification. TSP-GNN was validated using publicly available datasets. Our results demonstrate that different ND types show distinct task-specific connectivity patterns. Compared with the whole-brain node characteristics, utilizing task-specific nodes enhances the accuracy of ND classification. TSP-GNN comprises the first attempt to incorporate prior task-specific connectome patterns and the power of deep learning. This study elucidates the association between brain dysfunction and specific cognitive processes, offering valuable insights into the cognitive mechanism of neuropsychiatric disease.

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Section: Discussionmentioning

confidence: 99%

TSP-GNN: a novel neuropsychiatric disorder classification framework based on task-specific prior knowledge and graph neural network

Lang,

Yang,

2023

Front. Neurosci.

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“…Intracortical brain–computer interfaces (iBCIs) aim to improve the daily lives of paralyzed patients by restoring their motor functions [ 1 , 2 ]. An iBCI ascertains the patient’s movement intention and generates motor commands for assistive devices, such as computer cursors [ 3 ], and the functional electrical stimulation of paralyzed limbs [ 4 ].…”

Section: Introductionmentioning

confidence: 99%

Selection of Essential Neural Activity Timesteps for Intracortical Brain–Computer Interface Based on Recurrent Neural Network

Yang

Huang

et al. 2021

Sensors

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Intracortical brain–computer interfaces (iBCIs) translate neural activity into control commands, thereby allowing paralyzed persons to control devices via their brain signals. Recurrent neural networks (RNNs) are widely used as neural decoders because they can learn neural response dynamics from continuous neural activity. Nevertheless, excessively long or short input neural activity for an RNN may decrease its decoding performance. Based on the temporal attention module exploiting relations in features over time, we propose a temporal attention-aware timestep selection (TTS) method that improves the interpretability of the salience of each timestep in an input neural activity. Furthermore, TTS determines the appropriate input neural activity length for accurate neural decoding. Experimental results show that the proposed TTS efficiently selects 28 essential timesteps for RNN-based neural decoders, outperforming state-of-the-art neural decoders on two nonhuman primate datasets (R2=0.76±0.05 for monkey Indy and CC=0.91±0.01 for monkey N). In addition, it reduces the computation time for offline training (reducing 5–12%) and online prediction (reducing 16–18%). When visualizing the attention mechanism in TTS, the preparatory neural activity is consecutively highlighted during arm movement, and the most recent neural activity is highlighted during the resting state in nonhuman primates. Selecting only a few essential timesteps for an RNN-based neural decoder provides sufficient decoding performance and requires only a short computation time.

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A thermophysical mechanism exploration of the brain: Motor cortex modeling with canonical ensemble theory

Li,

Zhou,

Chen

et al. 2024

Neurocomputing

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Feature-Selection-Based Transfer Learning for Intracortical Brain–Machine Interface Decoding

Cited by 8 publications

References 59 publications

TSP-GNN: a novel neuropsychiatric disorder classification framework based on task-specific prior knowledge and graph neural network

TSP-GNN: a novel neuropsychiatric disorder classification framework based on task-specific prior knowledge and graph neural network

Selection of Essential Neural Activity Timesteps for Intracortical Brain–Computer Interface Based on Recurrent Neural Network

A thermophysical mechanism exploration of the brain: Motor cortex modeling with canonical ensemble theory

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