Fang Qiu scite author profile

Brain stimulation is a critical technique in neuroscience research and clinical application. Traditional transcranial brain stimulation techniques, such as transcranial magnetic stimulation (TMS), transcranial direct current stimulation (tDCS), and deep brain stimulation (DBS) have been widely investigated in neuroscience for decades. However, TMS and tDCS have poor spatial resolution and penetration depth, and DBS requires electrode implantation in deep brain structures. These disadvantages have limited the clinical applications of these techniques. Owing to developments in science and technology, substantial advances in noninvasive and precise deep stimulation have been achieved by neuromodulation studies. Second-generation brain stimulation techniques that mainly rely on acoustic, electronic, optical, and magnetic signals, such as focused ultrasound, temporal interference, near-infrared optogenetic, and nanomaterial-enabled magnetic stimulation, offer great prospects for neuromodulation. This review summarized the mechanisms, development, applications, and strengths of these techniques and the prospects and challenges in their development. We believe that these second-generation brain stimulation techniques pave the way for brain disorder therapy.

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Influence of Electrode Configuration on Muscle-Fiber-Conduction-Velocity Estimation Using Surface Electromyography

Wang

Jin

et al. 2022

IEEE Trans. Biomed. Eng.

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Characteristics Of Muscle Oxygen Saturation And Electromyography Parameters During Incremental Exercise

Qiu

Liu

2021

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Neural inputs from spinal motor neurons to lateralis vastus muscle: Comparison between sprinters and nonathletes

Qiu

Liu²,

Yang³

et al. 2022

Front. Physiol.

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The adaptation of neural contractile properties has been observed in previous work. However, the neural changes on the motor unit (MU) level remain largely unknown. Voluntary movements are controlled through the precise activation of MU populations. In this work, we estimate the neural inputs from the spinal motor neurons to the muscles during isometric contractions and characterize the neural adaptation during training by comparing the MU properties decomposed from sprinters and nonathletes. Twenty subjects were recruited and divided into two groups. The high-density surface electromyography (EMG) signals were recorded from the lateralis vastus muscle during the isometric contraction of knee extension and were then decomposed into MU spike trains. Each MU’s action potentials and discharge properties were extracted for comparison across subject groups and tasks. A total of 1097 MUs were identified from all subjects. Results showed that the discharge rates and amplitudes of MUAPs from athletes were significantly higher than those from nonathletes. These results demonstrate the neural adaptations in physical training at the MU population level and indicate the great potential of EMG decomposition in physiological investigations.

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Analysis Of Motor Unit Activities Decoded From Thigh Muscles During Multiple Contraction Conditions

Liu¹,

Qiu²,

Zhang³

et al. 2021

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Fang Qiu

Review of Noninvasive or Minimally Invasive Deep Brain Stimulation

Influence of Electrode Configuration on Muscle-Fiber-Conduction-Velocity Estimation Using Surface Electromyography

Characteristics Of Muscle Oxygen Saturation And Electromyography Parameters During Incremental Exercise

Neural inputs from spinal motor neurons to lateralis vastus muscle: Comparison between sprinters and nonathletes

Analysis Of Motor Unit Activities Decoded From Thigh Muscles During Multiple Contraction Conditions

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