This invention belongs to the technical field of neural networks and particularly relates to a closed-loop adaptive AC stimulation neural network control method and system.
Brain network synchronization is the basis of human cognition. The electrophysiological rhythm synchronization of the brain realizes the effective communication between brain networks. Typical brain network rhythms include: δ(1-4 Hz), θ(4-7 Hz), α(8-13 Hz), β(14-30 Hz) and γ(31-90 Hz). Each rhythm has its own characteristics and the cognitive function associated with it. For instance, the most prominent cognitive relevance of δ rhythm activity is detecting the targets in a series of interfering substances or stimuli. θ rhythm is most commonly associated with the memory process. Some studies have shown that θ rhythm reflects communication with the hippocampus. Many low frequency rhythms are associated with functional inhibition. However, the high-frequency γ rhythm is deemed to reflect the activation of the cerebral cortex and appears at high levels of concentration or in working memory activity in normal people. The synchronism of brain network rhythms promotes the coordination between functional networks. The communication between brain networks will be interrupted in case of brain rhythm disturbance, resulting in a series of neuropsychiatric disorders. Therefore, the regulation of brain network rhythms and the promotion of brain network phase synchronization are of great significance for the improvement of some neuropsychiatric disorders.
For the synchronous regulation of brain network rhythms, transcranial alternating current stimulation (TACS) is a highly effective non-invasive neuroregulatory technique. Regulating brain network rhythms by applying a low-intensity sinusoidal alternating current (the current is generally lower than 2 mA; and the frequency is generally lower than 100 Hz). This technique has some applications in cognitive neuroscience and clinical practices and has the advantages of low cost, high safety and few side effects. Relevant studies have shown that the field strength required for neural regulation should be greater than 0.2V/m. Therefore, the effective focus is required for the stimulation targets. TACS may regulate non-target positions during the regulation due to its poor focus. High-density transcranial alternating current stimulation (HD-TACS) effectively solves this problem, so that the regulated region is focused on the region enclosed by electrodes. However, HD-TACS has a problem that only a single region can be regulated. Therefore, for the whole neural network, multi-target regulation is required to realize the optimal regulatory effect. The distribution of electric fields in the brain differs greatly due to the existence of individual differences. Therefore, specific arrangements of stimulation electrodes should be customized for individualized brain networks. In order to enable external stimuli to effectively regulate brain network rhythms, external stimuli should be coupled to the real-time brain rhythm state.
This invention relates to a closed-loop adaptive AC stimulation neural network regulation method that is aimed at solving the above problems and realizing the effective regulation of neural network rhythms.
This invention is realized by a closed-loop adaptive AC stimulation neural network regulation method and includes the following steps:
Ulteriorly, S1 specifically includes: building a 5-layer head model composed of the scalp, skull, cerebrospinal fluid, gray matter, white matter with MRI data and simnibs software; generating a functional connectivity network with fMRI data and GRETNA kit.
Further, S1 also includes: comparing the fMRI and EEG data with the Brain functional network and rhythm of normal people to obtain the abnormal region and rhythm that are the target of electrical stimulation and the frequency of regulation.
Ulteriorly, in S1, the position of the stimulating electrode and the magnitude of the stimulating current are determined by optimizing multiple HD-TACS, specifically including: stimulate multiple targets with multiple electrodes to obtain the position of multiple stimulating electrodes by the least square method and based on the international 10/10 EEG system; perform parallel optimization by single electrode superposition method according to the superposition of electric field and the linear relation of current, after setting the common reference electrode, calculate the unit current of each electrode, realize the focus at the target position within the limited safe current range under the following evaluation conditions: the electric field in the target position in the region surrounded by the peripheral electrode is the largest; and the ratio of the electric field inside and outside the target is the smallest; change the current at the electrodes in each group to make the sum of the two conditions the minimum.
Further, the pre-processing steps in S3 include: removing the noise and artifacts from the data acquired by ASR.
This invention also relates to a closed-loop adaptive AC stimulation neural network regulation system that is aimed at solving the above problems and realizing the effective regulation of neural network rhythms.
A closed-loop adaptive AC stimulation neural network regulation system, including:
Further, the HD-TACS is composed of four peripheral electrodes and one central electrode.
Ulteriorly, the AC stimulation module is composed of a current calculation module, current generation module, current output module and impedance detection module. The current calculation module is used to calculate the current of each stimulating electrode according to the position information received. The current generation module is used to generate the stimulating waveform of each stimulating electrode based on the current calculated. The current output module is used to output electrical stimulation current and acquire EEG voltage. The impedance detection module is used to collect the current signal of electrodes and calculate the real-time resistance value.
Further, the current output module is equipped with a limit-voltage protection circuit with a limited voltage of 24V.
Ulteriorly, the current output module has 8 channels, each of which is composed of 5 electrodes, 4 for negative input and 1 for positive output.
Compared with existing techniques, the beneficial effect of this invention is: this invention discloses a closed-loop adaptive AC stimulation neural network regulation method and system. After the magnetic resonance image and functional magnetic resonance image of the regulation object are input into the individualized navigation module, the functional connectivity network is generated to finalize regulatory targets. The position of stimulating electrodes and the magnitude of the stimulating current are determined according to the target to be regulated. The stimulating frequency is determined according to the EEG of the regulation object and then input into the AC stimulation module for regulation. During the regulation, the EEG acquired by the EEG acquisition module is input into the adaptive coupling module. The current of the AC stimulation module is regulated according to the EEG during the regulation to realize phase coupling with the waveform, so as to realize accurate closed-loop neural network regulation.
In order to make the objective, technical scheme and advantages of this invention clearer, this invention will be further detailed in combination with drawings and embodiments. It should be understood that the specific embodiments described are only used to explain this invention and are not used to limit this invention.
In the description of this invention, the orientations or positional relations indicated by such terms are based on the orientations or positional relations shown in drawings, are only used to facilitate the description of this invention and simplify the description, and are not used to indicate or imply that the device or element mentioned must have a specific orientation or should be constructed and operated in a specific orientation. Therefore, these orientations or positional relations should not be interpreted as limitations of this invention. In addition, unless otherwise expressly specified, the “multiple” in the description of this invention means two or more.
A closed-loop adaptive AC stimulation neural network regulation method, including the following steps:
In S1: build a 5-layer head model composed of the scalp, skull, cerebrospinal fluid, gray matter, white matter with MRI data and simnibs software; generate a func
Specifically, in S1: compare the fMRI and EEG data with the Brain functional network and rhythm of normal people to obtain the abnormal region and rhythm that are the target of electrical stimulation and the frequency of regulation.
The position of the stimulating electrode and the magnitude of the stimulating current are determined by optimizing multiple HD-TACS: stimulate multiple targets with multiple electrodes to obtain the position of multiple stimulating electrodes by the least square method and based on the international 10/10 EEG system; perform parallel optimization by single electrode superposition method according to the superposition of electric field and the linear relation of current, after setting the common reference electrode, calculate the unit current of each electrode, realize the focus at the target position within the limited safe current range under the following evaluation conditions: the electric field in the target position in the region surrounded by the peripheral electrode is the largest; and the ratio of the electric field inside and outside the target is the smallest; change the current at the electrodes in each group to make the sum of the two conditions the minimum.
S3 includes: removing the noise and artifacts from the data acquired by ASR.
This invention relates to a closed-loop adaptive AC stimulation neural network regulation system, which is aimed at realizing the effective focused regulation of neural network rhythms and is composed of an individualized navigation module, AC stimulation module, EEG acquisition module and adaptive coupling module that are sequentially connected.
The Individualized navigation module builds of the head model and functional connectivity network with the image data of the regulation object, identifies the multiple targets to be regulated, determines the regulation frequency according to the EEG data of the regulation object, and optimizes the position of stimulating electrode and current by means of multiple HD-TACS to realize the multi-target electrical stimulation focused regulation;
The AC stimulation module obtains the electrode position and current parameters with the individualized navigation module, realizes the configuration of electrode parameters, and regulates the output current in real time combined with impedance detection to realize accurate electrical stimulation regulation while realizing limited protection;
The electrodes of this system have the function of two-way regulation and are provided on the head of the regulation object. The system can perform electrical stimulation via electrodes to regulate brain networks and can regulate the stimulation output parameters of devices by acquiring EEG from brain networks.
The EEG acquisition module acquires the EEG after electrical stimulation and pre-processes EEG.
The Adaptive coupling module analyzes and processes the EEG pre-processed by the EEG acquisition module, and then predicts the phase, re-sets the stimulating current and frequency of electrical stimulation and realizes the closed-loop neural network regulation.
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The method mentioned in the previous step is used to determine the position of stimulating electrodes and the magnitude of stimulating current to achieve the optimal stimulation effect. The traditional HD-TACS has a high focus effect and is composed of a total of 5 electrodes: four peripheral electrodes and one central electrode. It can focus the stimulation area within the peripheral area surrounded by 4 electrodes. The 5 electrodes are defined as a group. Multiple electrodes are used to stimulate the multiple targets obtained. For the center electrode of each electrode, the position of multiple stimulating electrodes is obtained by the least square method and based on the international 10/10 EEG system. After obtaining the position of stimulating electrodes, parallel optimization is performed by the single electrode superposition method according to the superposition of the electric field and the linear relation of current. After setting the common reference electrode, the unit current of each electrode is calculated first. The evaluation conditions are as follows: the electric field in the target position in the region surrounded by the peripheral electrode is the largest a=min(Ein); and the ratio of the electric field inside and outside the target is the smallest b=min(Eout/Ein); change the current at the electrodes in each group to make the sum of the two conditions the minimum min(a+b), so as to realize the focus at the target position.
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The above-mentioned embodiments are only the optimal embodiments of this invention, and cannot be used to limit this invention. Any modification, equivalent replacement or improvement within the spirit and principle of this invention should be included in the protection scope of this invention.
Number | Date | Country | Kind |
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2022104065989 | Apr 2022 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2022/098478 | 6/13/2022 | WO |