The present invention is directed to transcutaneous electrical nerve stimulation (TENS) devices which utilize novel stimulation waveforms and novel arrangements of TENS electrodes to improve the efficiency of power consumption while enhancing therapeutic effects.

The present invention relates to systems for providing noninvasive cranial nerve stimulation and methods for using the same. The present invention administers therapy through electrodes that are noninvasively attached to one or more of a subject's cranial nerve. The systems can be used to enhancing rehabilitation and recovery by improving neuroplasticity and coupling muscle training with feedback.

Wearable devices for providing therapy to a patient may include disposable or reusable treatment pads. The treatment pads may include electrodes and are configured to apply energy to various regions around the head and eyes. The treatment pads may provide therapy when the eyes are open or closed. The wearable device may include a battery and/or control circuitry for issuing therapy pulses through the electrodes.

A neuromodulation apparatus and method of using the same. The neuromodulation apparatus includes a plurality of electrodes each of the plurality of electrodes having an electrically conductive element applicable to or under a skin of a patient, a pulse generator electrically connected to each of the plurality of electrodes for transmitting electrical pulses to the plurality of electrodes and a control unit coupled to the pulse generator and adapted to measure a resistance and/or a current-voltage characteristic between at least two electrodes of the plurality of electrodes. The control unit is adapted to control a shape of the electric pulses based on the measured resistance and/or current-voltage characteristic.

There is disclosed a system for providing transcutaneous electrical stimulation to the vagus nerve of an individual comprising: an electrode unit mountable within the auricle of the individual and having at least a first electrode and a second electrode for applying the transcutaneous electrical stimulation at the cymba conchae and the tragus of the individual's auricle, and a controller for controlling the transcutaneous electrical impulse delivered by each of the first electrode and second electrode.

Described herein are noninvasive electrical stimulation devices, systems and methods for stimulation of the Vagus nerve through its auricular branch to provide beneficial physiological responses in subjects, including alleviation, mitigation or elimination of symptoms of various disorders, including metabolic and inflammatory disorders.

A biomagnetic field measurement processing apparatus includes circuitry; and a memory storing computer-executable instructions that cause the circuitry to execute reconfiguring a current signal from a biomagnetic field signal; extracting a current component from the current signal; and based on the extracted current component, adding to each other at least two current waveforms among current waveforms of a plurality of inward currents that are current components directed toward a nerve axon from around the nerve axon, or adding to each other at least two current waveforms among current waveforms of a plurality of inward currents that are current components directed toward a muscle fiber from around the muscle fiber, and generating a current waveform to be displayed on a display device, according to the at least two current waveforms added to each other.

A system for monitoring vital signs, configured to be used in conjunction with a computerized mobile device, the system including: a cover sensor assembly adapted to be operably engaged with the computerized mobile device, the cover sensor assembly having integrated therein at least one physiological sensor; a physiological data acquisition module configured to generate a physiological parameter measurement descriptive of a physical stimulus received by the at least one physiological sensor; and a validation module configured to control a validity status of the physiological parameter measurement.

A system for controlling blood pressure includes a wearable interface having an internal contact surface, the wearable interface configured to at least partially encircle a first portion of a first limb of a subject, a sensing module carried by the wearable interface and configured to determine at least a change in blood pressure of the first limb of the subject, and an energy application module carried by the wearable interface and configured to apply energy of two or more types to the first limb of the subject.

Presented herein are systems, methods, and devices that provide for stimulation of nerves and/or targets such as mechanoreceptors, tissue regions, mechanoresponsive proteins, and vascular targets through generation and delivery of mechanical vibrational waves. In certain embodiments, the approaches described herein utilize a stimulation device (e.g., a wearable device) for generation and delivery of the mechanical vibrational waves. As described herein, the delivered vibrational waves can be tailored based on particular targets (e.g., nerves, mechanoreceptors, vascular targets, tissue regions) to stimulate and/or to elicited particular desired responses in a subject.