In example implementations, an apparatus is provided. The apparatus includes a body portion and a plurality of legs movably coupled to the body portion. The body portion is to rest on a backside of a hand of a user. Each one of the plurality of legs include a curved portion to fit between fingers of a user. Respective ends of the plurality of legs are to contact a palm of the user.

An electronic device for signal interference compensation is provided. The first signal line is electrically connected to the transmitter. The second signal line is electrically connected to the receiver and coupled with the first signal line. The electrode is electrically connected to the second signal line and measures a physiological signal. The processor is electrically connected to the transmitter and the receiver, and configured to: transmit, via the transmitter, an active signal to the first signal line; receive, via the receiver, a coupling signal corresponding to the active signal from the second signal line, and calculate a compensation value according to the coupling signal; and receive, via the receiver, an interfered signal corresponding to the physiological signal, and restore the physiological signal according to the compensation value and the interfered signal in response to the compensation value matching the interfered signal.

An electronic device for signal interference compensation is provided. The first signal line is electrically connected to the transmitter. The second signal line is electrically connected to the receiver and coupled with the first signal line. The electrode is electrically connected to the second signal line and measures a physiological signal. The processor is electrically connected to the transmitter and the receiver, and configured to: transmit, via the transmitter, an active signal to the first signal line; receive, via the receiver, a coupling signal corresponding to the active signal from the second signal line, and calculate a compensation value according to the coupling signal; and receive, via the receiver, an interfered signal corresponding to the physiological signal, and restore the physiological signal according to the compensation value and the interfered signal in response to the compensation value matching the interfered signal.

A method of determining regularity of a bio-signal is provided. The method of determining regularity of a bio-signal according may include acquiring a plurality of pulse waveforms of the bio-signal, acquiring a plurality of slope waveforms corresponding to the plurality of pulse waveforms, binarizing the plurality of slope waveforms, acquiring synchronization information of the plurality of pulse waveforms based on binarizing the plurality of pulse waveforms; acquiring a synchronization rate of a reference interval based on the synchronization information, and determining whether the bio-signal is regular or irregular based on the synchronization rate of the reference interval.

A method of determining regularity of a bio-signal is provided. The method of determining regularity of a bio-signal according may include acquiring a plurality of pulse waveforms of the bio-signal, acquiring a plurality of slope waveforms corresponding to the plurality of pulse waveforms, binarizing the plurality of slope waveforms, acquiring synchronization information of the plurality of pulse waveforms based on binarizing the plurality of pulse waveforms; acquiring a synchronization rate of a reference interval based on the synchronization information, and determining whether the bio-signal is regular or irregular based on the synchronization rate of the reference interval.

Systems and methods for the treatment of gastroesophageal reflux disease (GERD) include at least one electrically stimulating electrode coupled to a pulse generator. Individuals with GERD are treated by implanting a stimulation device within and/or proximate the patient's lower esophageal sphincter, gastric fundus, or other nearby gastrointestinal structures and applying electrical stimulation to the patient's lower esophageal sphincter and/or fundus, in accordance with certain predefined protocols. Electrical stimulation provided by the disclosed systems results in an increase in the length of the high pressure zone of the LES and/or modulation of the receptive relaxation response of the fundus to decrease gastric pressure, creating a longer barrier to the reflux of gastric contents or increasing functional lower esophageal pressure respectively, thereby treating GERD.

A technique for using biofeedback to facilitate and quantify accurate patient assessments includes receiving brainwave activity readings of a provider and a recipient(s) before, during, and post an interaction between the provider and the recipient(s) for a procedure. The brainwave readings being indicative of the state of mind of the provider and the recipient(s). The provider performs a therapeutic or knowledge transfer to the patient(s)/recipient(s) and evaluates the impact/efficacy of the procedure on them. The system correlates the collected brainwave activity signals of the provider and the recipient(s) to determine the efficacy of the therapeutic or knowledge transfer procedure. The brainwave activity signals are collected using a headgear based on an electroencephalogram system and an electromyography system. The electromyography system positions electromyography sensors to measure scalp muscle movements of the provider and recipient(s) and remove the effects of scalp muscle movements from the electroencephalogram readings to provide true brainwave readings.

A technique for using biofeedback to facilitate and quantify accurate patient assessments includes receiving brainwave activity readings of a provider and a recipient(s) before, during, and post an interaction between the provider and the recipient(s) for a procedure. The brainwave readings being indicative of the state of mind of the provider and the recipient(s). The provider performs a therapeutic or knowledge transfer to the patient(s)/recipient(s) and evaluates the impact/efficacy of the procedure on them. The system correlates the collected brainwave activity signals of the provider and the recipient(s) to determine the efficacy of the therapeutic or knowledge transfer procedure. The brainwave activity signals are collected using a headgear based on an electroencephalogram system and an electromyography system. The electromyography system positions electromyography sensors to measure scalp muscle movements of the provider and recipient(s) and remove the effects of scalp muscle movements from the electroencephalogram readings to provide true brainwave readings.

Systems, methods and devices for promoting recovery from a stroke induced loss of motor function in a subject. In certain aspects, the system includes at least one electrode, and an operations system in electrical communication with at least one electrode, wherein the at least one electrode is constructed and arranged to apply current across the brain of the subject and to record low frequency oscillations from a perilesional region of the subject. In certain aspects, provided is a method comprising placing at least one recording electrode in electrical communication in a perilesional region of the subject; placing at least one stimulation electrode in electrical communication with the brain of the subject; recording low frequency oscillations from the perilesional region of the subject; and delivering current stimulation to the brain of the subject.

Systems, methods and devices for promoting recovery from a stroke induced loss of motor function in a subject. In certain aspects, the system includes at least one electrode, and an operations system in electrical communication with at least one electrode, wherein the at least one electrode is constructed and arranged to apply current across the brain of the subject and to record low frequency oscillations from a perilesional region of the subject. In certain aspects, provided is a method comprising placing at least one recording electrode in electrical communication in a perilesional region of the subject; placing at least one stimulation electrode in electrical communication with the brain of the subject; recording low frequency oscillations from the perilesional region of the subject; and delivering current stimulation to the brain of the subject.