A system or method for motor rehabilitation of a paretic limb including: a first plurality of sensors for registering brain neurosignals; a body-actuator; a hybrid brain machine interface for decoding brain neurosignals into movements of the body-actuator; a second plurality of EMG sensors couplable to the paretic limb for registering its EMG activity; a device for providing the patient with instructions relative to a series of exercises and/or tasks to be carried out with the paretic limb;
wherein upon carrying out a series of training sessions, each session comprising at least a set of such instructions, the hybrid brain machine interface is configured to switch between controlling the movements of the body-actuator based on the decoded brain neurosignals and a hybrid control of the movements of the body-actuator, when a significant level of decodable EMG activity has been registered, the hybrid control being an EMG-gated brain control.

Energy stimulated acupuncture, directed to a novel set of acupoints, is implemented to treat hypertension. The disclosed methods and systems are directed toward the application of electrical stimulation, or other forms of energy, to specific acupuncture points, using devices such as transcutaneous electrical stimulation electroacupuncture devices, laser acupuncture devices or ultrasound acupuncture devices, to treat hypertension, particularly in middle-aged women.

A patient treatment unit and method analyzes and treats pain in tissues by applying an electrical pulse train to the affected tissue. The impedance of the affected tissue is measured, and the measured impedance is correlated to a level of pain in the patient. The pulse train is further applied in response to the measured impedance to reduce the patient's pain. The patient treatment unit includes a probe stimulus generator that outputs the pulse train. The treatment unit also includes a pair of probes for contacting the patient's body and receiving the pulse train. The pulse has improved shaping based on isolation of high voltage from a low voltage control. The unit further includes a body impedance analysis circuit that senses voltage and current via the probes when the probes are contacting the patient and observe the impedance. A monitor is electrically coupled to the body impedance analysis circuit and provides an indication of the measured impedance indicative of the patient's level of pain in real-time.

A method of treating hypertension in a patient includes 1) generating, by an electroacupuncture device implanted beneath a skin surface of the patient at an acupoint corresponding to a target tissue location within the patient, stimulation sessions at a duty cycle that is less than 0.05, wherein the duty cycle is a ratio of T3 to T4, each stimulation session included in the stimulation sessions has a duration of T3 minutes and occurs at a rate of once every T4 minutes, and the electroacupuncture device comprises a central electrode of a first polarity and an annular electrode of a second polarity and that is spaced apart from the central electrode; and 2) applying, by the electroacupuncture device, the stimulation sessions to the target tissue location by way of the central electrode and the annular electrode in accordance with the duty cycle.

The invention relates to a device for the punctual stimulation of endings, located in the region of the ears, of nerves leading to brain stem nuclei, and device (1) having a battery-powered therapeutic current generator (3), which is arranged in a housing (2) to be worn in the ear region and is provided with an electronic circuit that forms a low-frequency therapeutic current, and said device also having at least one flexible line (5) proceeding from the therapeutic current generator (3) for connecting to an electrode to be positioned at a nerve ending and having a base electrode (7), which is likewise connected to the therapeutic current generator and by means of which the therapeutic circuit leading across the former electrode is closed, wherein the device (1), at least by means of an external part of said device (1), can be adapted to the shape of the body point of patient intended for the positioning of the device due to a mechanically pliable structure.

A device (100) for the treatment of depression, anxiety and pain, the device comprising: a plurality of adjacent dots (11) or other shapes, each comprising means for providing a signal being sensible by a touch sense, the signal comprising mechanical signal and/or electrical signal and/or temperature signal and/or magnetic signal; and a controller (32) for executing each of the means independently, for providing pre-programmed shapes (30, 40, 40A, 40B, 42, 46, 48, 50, 52, 54) being sensible by the touch sense, thereby allowing treating the depression, anxiety and pain by generating to the brain, signals resembling the pre-programmed shapes (30, 40, 40A, 40B, 42, 46, 48, 50, 52, 54) through the signals being sensible by the touch sense.

A patient treatment unit for delivering non-invasive pulsed energy to living tissue with a probe stimulus generator circuit configured to output, as a treatment signal, a sequence of DC electrical pulses at a controlled pulse frequency of about 20 kHz and having a pulse voltage defined by a variable supply voltage of the probe stimulus generator circuit. The unit includes primary and secondary probes for contacting a body, an intensity adjustment circuit configured to control the variable supply voltage, and an electronic timer display configured to display an elapsed time in decimal numbers in minute and second format. An electrical current of the pulses is in a range of 0.1-2 mA while the probes are contacting the body. An operating output voltage across the probes while conducting the treatment signal does not exceed a maximum operating output voltage of 165 VDC while the probes are contacting the body.

A transcutaneous electrostimulation device includes an electrostimulation generator providing at an output a nerve electro stimulation signal, an electronic signal conduit conductively connected to the output of the generator, and an electrode coupler shaped to form fit an ear canal of a human ear and having at least one electrostimulation electrode. The electrode is conductively connected to the electronic signal conduit to receive the nerve electrostimulation signal and is positioned at the electrode coupler to contact tissue within an ear canal and apply the nerve electrostimulation signal to the tissue transcutaneously. An audio source outputs audio signals. The electrode coupler has a speaker receiving the audio signals for output into the ear canal when the electrode coupler is worn. The generator sends the nerve electrostimulation signal to the electrode coupler while the audio signals are output. The generator modulates the nerve electrostimulation signal based upon the audio signals.

A beauty instrument capable of imparting a massaging effect to skin. A beauty instrument is configured such that a pair of balls is supported at the tip of a handle. The balls are positioned at a distance from each another, and are capable of rotating around respective axes thereof.

A system or method for motor rehabilitation of a paretic limb including: a first plurality of sensors for registering brain neurosignals; a body-actuator; a hybrid brain machine interface for decoding brain neurosignals into movements of the body-actuator; a second plurality of EMG sensors couplable to the paretic limb for registering its EMG activity; a device for providing the patient with instructions relative to a series of exercises and/or tasks to be carried out with the paretic limb;
wherein upon carrying out a series of training sessions, each session comprising at least a set of such instructions, the hybrid brain machine interface is configured to switch between controlling the movements of the body-actuator based on the decoded brain neurosignals and a hybrid control of the movements of the body-actuator, when a significant level of decodable EMG activity has been registered, the hybrid control being an EMG-gated brain control.