A garment worn by the patient is provided. The garment has a first module electrically connected to a second module. The first module has a first sub-control unit electrically connected to a first electrode and a second electrode placed at a first muscle and a third electrode and a fourth electrode placed at a second muscle. The sub-control unit is electrically connected to a master unit. The first muscle is stimulated with a first stimulation signal without shortening the first muscle by sending the first stimulation signal to the first electrode placed. The stimulation of the first muscle relaxes the second muscle.

The invention comprises a method and apparatus for delivering electrons to skin of a person, comprising the steps of: (1) attaching a longitudinal length of a flexible electrically conductive tape to the skin of the person, the flexible electrically conductive tape comprising: an electrically conductive strip and an adhesive layer, the adhesive layer comprising a top surface and an adhesive surface, (2) the adhesive surface affixing the electrically conductive strip to the skin, where the adhesive layer comprises a set of apertures therethrough to form longitudinally distributed electrical contact points along a length of the electrically conductive strip; and (3) an energy source delivering electrons, under control of an electrical control circuit of a controller, to the electrical contact points of the flexible electrically conductive tape.

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.

The disclosure relates to a brain stimulation system (102), comprising: a) a computer program product, e.g. a data carrier, preferably a non-transitory data carrier, or a data stream, comprising program code (P1, P1a) which, when loaded and executed on an electronic control unit (108), provides an operation control system, or b) an electronic control unit (108) with a program code (P1, P1a) loaded on the electronic control unit (108), wherein the program code (P1, P1a), when executed on the electronic control unit (108), provides an operation control system (200), wherein the operation control system (200) is configured to control a brain training and/or stimulation session for a brain, and wherein the operation control system (200) comprises a plurality of control system functionalities, the control system functionalities comprising:

a stimulation functionality (202) which is configured to cause the electronic control unit (108) to issue a stimulation command to an electrical brain stimulation device (122) to cause the electrical brain stimulation device (122) to perform an electrical brain stimulation procedure; and

a presentation functionality (204) which is configured to cause the electronic control unit (108) to issue a presentation command in order to present a task to be performed by a user (120) on a user interface (110), wherein preferably the stimulation functionality (202) and the presentation functionality (204) are linked (254 to 262) or linkable to one another.

A system and method for applying stimulation therapy to a patient, the system including a first stimulation strip that includes a first elongated portion configured to be placed on the upper eyelid of the first eye of the patient and a second elongated portion configured to be placed on the lower eyelid of the first eye of the patient, wherein the first stimulation strip includes: a first plurality of individually controlled electrodes configured to deliver a microcurrent stimulation therapy to the patient, a first plurality of individually controlled light emitters configured to deliver light stimulation therapy to the patient, and a first plurality of individually controlled heat sources configured to deliver heat therapy to the patient; and a controller operatively coupled to the first stimulation strip and configured to control delivery of the microcurrent stimulation therapy, the light stimulation therapy, and the heat therapy.

Described here are devices, systems, and methods for treating meibomian gland disease and/or blepharitis by providing intranasal stimulation. Generally, the devices may deliver electrical stimulation to the nasal mucosa. Intranasal stimulation may unblock obstructed meibomian glands and increase the lipid content of tears, both acutely during stimulation and subsequent to intranasal stimulation. The methods may include an initial round of stimulation to unblock obstructed meibomian glands, and subsequent shorter rounds of stimulation to cause meibum secretion and maintain the open glands.

The present specification discloses an intraoperative neurophysiological monitoring (IONM) system including a computing device capable of executing an IONM software engine, a stimulation module having multiple ports and various stimulation components and recording electrodes. The system is used to implement transcranial electrical stimulation and motor evoked potential monitoring by positioning at least one recording electrode on a patient, connecting the stimulation components to at least one port on the stimulation module, positioning the stimulation components on a patient's head, activating, using the IONM software engine, at least one port, delivering stimulation to the patient; and recording a stimulatory response on the patient.

The invention provides a therapeutic system comprising: a console, wherein the console comprises a controller and an energy generator; a therapeutic device comprising: an operational head configured for transmitting the energy output from to a biological tissue; and a memory device comprising control instructions, wherein said control instructions comprise instructions for controlling the console; a reversible memory operable linkage linking the memory device to the controller; and a reversible connector configured for operably linking the energy generator to the operational head. Optionally, the energy generator is a generator of ablation energy or heat energy (e.g. RF generator) and the control instructions comprise instructions for controlling the output of the energy generator. Optionally, the control instructions comprise one or more parameters of energy output or an algorithm configured for controlling the energy output. Optionally, the system further comprises one or more secondary therapeutic devices and the control instructions comprise instructions for controlling the one or more secondary therapeutic devices. Optionally, the system further comprises one or more sensors configured for sensing parameters of energy output or biological or environmental effects of the energy output and the control instructions comprise instructions for controlling the energy output and/or secondary therapeutic devices based on the parameters of energy output or biological or environmental effects. In some embodiments, one advantage provided by the present invention is the use of a single console with a plurality of interchangeable reversibly connected therapeutic devices.

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 neural control system comprises an input controller arranged to receive neural data regarding neural signals relating to a bodily state of a subject from at least one neural sensor, at least one machine learning means using at least one machine learning model to process the received neural data to determine at least one output signal required to achieve a desired value of the bodily state, and means arranged to send the determined output signal to at least one output device, whereby the neural control system forms a first control loop providing closed loop control of the bodily state.