A system and method for controlling sexual stimulation devices using motion-sensing controllers. The system comprises a male sexual stimulation device and a motion sensing controller configured to control the operation of the reciprocating linear motion driver. In operation, natural motions of a user with the motion sensing controller result in corresponding motions of the male sexual stimulation device such as reciprocal linear motions and rotational motions.

Provided are an apparatus, method, and computer-readable medium for controlling a biological clock and a sleep cycle. The apparatus may include a collection unit configured to receive a brain image of a subject, a stimulation control unit configured to analyze the brain image, set a target point to be stimulated in a target region located in the brain, and derive optimized stimulation conditions, and a stimulation unit configured to apply stimulation according to the stimulation conditions derived by the stimulation control unit, wherein the stimulation control unit comprises a target setting unit configured to analyze the brain image, acquire anatomical central coordinates of the target region, and set the target point according to the acquired central coordinates and a stimulation setting unit configured to configure a stimulation electrode combination according to the set target point and derive a stimulation function according to a stimulation modulation depth maximization function (M.sub.MAX).

The present invention relates to a method of medical treatment of lameness in a mammal in need thereof, the method comprising applying pulsed radiofrequency (PRF) to the mammal so that an outcome selected from the group consisting of an improvement stance or gait, a stabilization in the decrease of a deviation from normal stance or gait, a decrease of the manifestation of pain, a stabilization in the manifestation of pain, a decrease in the mechanical restrictions causing alteration of stance or gait, a stabilization in the mechanical restrictions causing alteration of stance or gait, a decrease in neuromuscular disease, a stabilization in neuromuscular disease, and/or a decrease or stabilization of inflammation is achieved.

A wearable apparatus capable of altering a physiological parameter such as the heart rate of a user to provide a relaxing or stimulating effect on the user is provided. The apparatus comprises a device capable of engaging the patient's skin to provide a rhythmic tactile stimulus to the user that can alter the user's heart rate and an arrangement for securing the device to the user such that the device can apply the stimulus to the user. The apparatus may be part of a system enabling the device to be controlled remotely. The apparatus may also be configured to provide additional tactile stimuli.

The present method and system provides for the clinical application of neurostimulation and/or neuromodulation to a patient. The method and system includes receipt and acquisition of patient data, processing of that data relative to one or more known data sets, and determination of a good-fit trigger specific treatment protocol. The method and system provides for application of the protocol to the patient, including delivery of neuromodulation and biofeedback. Based thereon, the method and system re-iterates the goodness of fit determination for further treatment to the patient.

Disclosed are apparatuses comprising at least one electrode element having a skin-facing surface; a skin contact layer comprising an adhesive composite, and an adhesive tape or bandage. Disclosed are methods comprising positioning one or more electrode assemblies on a target site of a subject, the one or more electrode assemblies comprising at least one electrode element having a skin-facing surface; a skin contact layer comprising a conductive adhesive composite, and an adhesive tape or bandage, wherein the at least one electrode element is electrically coupled to the skin contact layer. In some aspects, the methods further comprise removing at least one of the one or more electrode assemblies from the target site of the subject after a period of time. In some aspects, after removal of the one or more electrode assemblies, the target site is evaluated for an adverse event.

Devices and methods for non-invasive stimulation of nerves, such as the vagus nerve, include a housing and an electrode spaced from the housing. The electrode is configured to be positioned adjacent to, or in contact with, an outer skin surface of a patient. A source of energy is positioned within the housing and operably coupled to the electrode, either wirelessly or via a lead or other wired connection. The source of energy emits an electrical impulse to the electrode such that the electrical impulse passes through the outer skin surface of the patient to a nerve at a target region in the patient sufficient to modulate the nerve. The electrical impulse comprises bursts each with a frequency from about 1 Hz to about 100 Hz, wherein each of the bursts comprises 2 pulses to 20 pulses.

A compact integrated patch may be used to collect physiological data. The patch may be wireless. The patch may be utilized in everyday life as well as in clinical environments. Data acquired by the patch and/or external devices may be interpreted and/or be utilized by healthcare professionals and/or computer algorithms (e.g., third party applications). Data acquired by the patch may be interpreted and be presented for viewing to healthcare professionals and/or ordinary users.

An apparatus for delivering a plurality of electromagnetic fields to a body of an individual. The apparatus includes a plurality of electrode elements and a control device coupled with the plurality of electrode elements. The control device is configured to detect temperatures of the plurality of electrode elements, determine alternate firing sequences of the plurality of electrode elements, and implement the determined alternate firing sequences for delivering the plurality of electromagnetic fields for treating tumors in the body of the individual and reducing temperatures of the plurality of electrode elements.

A non-invasive method and device for promoting a localized change in a flow of blood through a blood vessel in a limb segment of a body by a series of electrically stimulated contractions of muscle tissue in the limb segment, the method including the steps of: (a) providing a device including: (i) first, second and third electrodes, each adapted to operatively contact the limb segment; (ii) a signal generator, operatively connected to the electrodes, adapted to produce a series of electrical impulses to the limb segment via the electrodes, and (iii) a control unit adapted to control the signal generator to produce the series of electrical impulses; (b) positioning the electrodes on the limb segment, wherein the first electrode is positioned on a lower end of the lower leg, the second electrode is positioned on the lower leg, and the third electrode is positioned on an upper end of the lower leg, whereby the first and third electrodes are disposed on opposite ends of the lower leg, and the second electrode and one of the first and third electrodes are disposed on a same end of the lower leg; (c) effecting a sequence of muscular contractions of the lower leg, by operations including: (i) applying a first electrical impulse between the electrodes on the same end of the lower leg to induce a first muscular contraction of a first portion of the tissue; and (ii) applying at least a second electrical impulse between the first and third electrodes to induce a longitudinal muscular contraction of a second portion of the muscular tissue; and (d) repeating operations (i) and (ii), to repeatedly induce the contractions, to effect the increased flow of blood.