A device for functional electrical stimulation, including a garment mountable on a user's body part, an assembly having a socket and an electrode in turn having electrode pads and a stimulator with a controlling mechanism for activating/deactivating stimulating electrical signals to be provided to at least some of the electrode pads. The garment defines a hollow area configured to receive the socket, the socket configured to house the stimulator. In use of the device, a first portion of the electrode is in contact with an inner surface of the garment, the electrode pads are in a fixed position with respect to the garment, and a second portion of the electrode is in contact with a surface of the socket for receiving the stimulating electrical signals delivered by the stimulator. A system may include the device and a sensor configured to be positioned on either user or in proximity thereto.

A system for treating soft tissue of a patient. The system includes a treatment head and a computer portion. The treatment head includes a probe and an electrode operably coupled to the probe. The probe and electrode are configured to respectively deliver a mechanical force impulse and an electrical stimulation to the soft tissue when placed in operable contact with the soft tissue. The computer portion includes a CPU and is configured to coordinate the delivery of the mechanical force impulse and electrical stimulation relative to each other. The system is configured to sense a shockwave in the soft tissue of the patient, the shockwave resulting from the mechanical force impulse delivered to the soft tissue via the probe. The system is also configured to analyze a characteristic of the sensed shockwave and configure the electrical stimulation to be delivered to the soft tissue via the electrode based on the characteristic analysis of the sensed shockwave. The characteristic may be at least one of frequency of the sensed shockwave, amplitude of the sensed shockwave, and/or wave shape (form) of the sensed shockwave.

A system, method, and apparatus for treating a medical condition by applying transcutaneous electrical stimulation to a target peripheral nerve of a subject. Electrical stimulation is applied to the peripheral nerve via a stimulation electrode pattern under closed-loop control in which EMG responses are monitored and used to adjust stimulation parameters. In response to detecting an unacceptable recording, electrical stimulation is applied to the peripheral nerve under open-loop control.

A portable and wearable hand-grasp neuro-orthosis is configured for use in a home environment to restore volitionally controlled grasp functions for a subject with a cervical spinal cord injury (SCI). The neuro-orthosis may include: a wearable sleeve with electrodes; electronics for operating the wearable sleeve to perform functional electrical stimulation (FES) and electromyography (EMG), the electronics configured for mounting on a wheelchair; and a controller configured for mounting on a wheelchair. The controller controls the electronics to read EMG via the sleeve, decode the read EMG to determine an intent of the user, and operate the electronics to apply FES via the sleeve to implement the intent of the user. The neuro-orthosis may restore hand function. The controller may include a display arranged to be viewed by the subject, for example mounted on an articulated arm attached to the wheelchair.

A device comprises: an array of electrodes configured to be disposed on a body part; an electrical stimulation transmitter operatively coupled with the array of electrodes; and a data processing module including an electronic processor and a non-transitory storage medium storing spatiotemporal electrical stimulation patterns for generating corresponding somatosensations and further storing instructions readable and executable by the electronic processor to apply a spatiotemporal electrical stimulation pattern stored in the non-transitory storage medium using the electrical stimulation transmitter and the array of electrodes to generate the somatosensation corresponding to the applied spatiotemporal electrical stimulation pattern. The stored patterns may for example include patterns for generating a sensation of skin exposure to a steam vent, a sensation of a weapon charge fire, a sensation of a rotating athletic ring, a sensation of raindrops, a sensation of a crawling arachnid, or a sensation of a shield strike borne by an arm.

The invention provides a system for inhibition or treatment of an aberrant neurological event in a subject. The system comprises: one or more detectors; a controller; and one or more stimulators of the vagus nerve. The invention also provides a method for treating and preventing epileptic seizures and the onset or pre-onset of epileptic seizures. The method includes the steps of: collecting signals from each of one or more detector indicating the presence of a repetitive movement; analyzing signals received from the one or more detector to determine the intensity of the stimulation of the auricular branch of the vagus nerve (ABVN) required to control, moderate or prevent current and future repetitive movements; and when required, signaling one or more stimulator to stimulate the ABVN so that the repetitive motion ceases using the determined stimulation intensities.

An orthopedic device with a base body for applying to a body part of a wearer, and at least one electrode for transcutaneously transmitting electrical signals. The at least one electrode features an electrically conductive textile and an electrically conductive polymer, wherein the electrically conductive textile is partially penetrated by the electrically inductive polymer and arranged in such a way that it comes into contact with the body part when the base body is applied.

A conductive transfer for application to an article comprises first and second non-conductive layers and a conductive layer positioned between the two non-conductive layers. The conductive transfer further comprises an adhesive layer for adhering the conductive transfer to an article, such as a wearable item. The conductive layer comprises a plurality of tessellated cells defined by a printed conductive ink. The conductive layer comprises a main element and an input track with the plurality of tessellated cells being comprised over the input track of said conductive layer.

In electrical stimulation fitness wear, multiple electrode parts 30 are provided in a clothing portion, at positions that respectively face multiple target body parts such as to be respectively in proximity to the multiple target body parts, so as to provide electrical stimulation to the multiple target body parts, and the multiple electrode parts 30 each have a surface formed of a conductive polymer fabric 31. Multiple electrical cables 36 respectively connect the multiple electrode parts 30 to a connection part of a control unit electrically. The multiple electrode parts 30 include a first electrode part 30 to which a first electrical cable 36 is connected and a second electrode part 30 to which a second electrical cable 36 is connected. The first electrode part 30 and the second electrode part 30 are provided at separate positions such that a current can be applied to a certain body part between the electrodes.

Disclosed herein are a system and a method for volitional electromyography (vEMG) signal detection from an EMG signal when functional electrical stimulation (FES) is applied. The system for vEMG signal detection includes a receiver for receiving data from an EMG electrode when FES is applied, a memory for storing a program for detecting a vEMG signal using the received data, and a processor for executing the program, wherein the processor cuts the data received from the EMG electrode disposed at a predetermined position, calculates a difference between data for previous FES and data for current FES, and detects the vEMG signal using the calculated difference.