The present invention is directed to systems, devices and methods for stimulating perceived motion, and more particularly to stimulating perceived motion in three axes. The invention is further directed to stimulating such perceived motion when accompanied by visual stimuli. The invention is further directed to utilizing as few as two distinct pairs of electrodes to administer electrical stimulation to generate the perceived motion. The invention is further directed to systems, devices and methods to minimize side effects while utilizing electrical currents create the perceived motion.

A hand-held device for electrically powered skin treatment includes a housing which is adapted to be grasped by a hand of a user, a first outer electrode which is adapted to be in contact with the hand of the user when the device is held in the hand of the user for use, a second outer electrode disposed on a side of the housing where the second outer electrode is placeable on an area of skin to be treated, and an electrically operated vibrator where the electrically operated vibrator is fixed by a socket on a side wall of the housing and is adapted to vibrate the side wall together with the second outer electrode when operated so that during operation of the device, the device produces an intensified massaging effect on the area of skin to be treated.

Aspects of the disclosure relate to methods of conducting an intraoperative procedure including providing an electrode assembly having a pledget substrate having a surface that is hydrophilic, at least one electrode supported by and positioned within the pledget substrate, and a lead wire assembly interconnected to the at least one electrode. Methods can further include creating an incision to access bioelectric tissue of a patient and applying the pledget substrate to the tissue, such as a nerve, for example. The pledget substrate conforms and fixates to the tissue to secure the electrode assembly in position. The electrode is then activated to record bioelectric responses of or stimulate the tissue. In some embodiments, the pledget substrate includes two bodies, each including at least one electrode, the two bodies being selectively separable so that the bodies can be repositioned with respect to one another.

A method of treating a patient comprises the steps of generating a first series of pulses having a frequency in a range from about 1 Hz to about 5 kHz, a voltage range from about 0 (zero) volts to about 100 (one hundred) volts, and a duty cycle of about 1% to about 90%; generating a second series of pulses having a frequency in a range from about 5 kHz to about 50 kHz, a voltage range from about 0 (zero) volts to about 100 (one hundred) volts, and a duty cycle of about 1% to about 90%; modulating the first series of pulses and the second series of pulses into a combined waveform of pulses; and delivering the combined waveform of pulses to the skin of said patient via an electrical circuit to thereby treat the patient.

The present disclosure relates to devices and systems for targeted and controlled delivery of a therapeutic agent to a treatment site of an eye. Particularly, aspects are directed to a therapeutic agent delivery device that includes a polymeric substrate having a release region, a delivery region, and a receiving region; one or more reservoirs formed within the release region; a therapeutic agent disposed within the one or more reservoirs; an active, passive, or combination thereof controlled release mechanism for release of the therapeutic agent from the one or more reservoirs into the delivery region; and a circuit formed on the polymeric substrate, the circuit having a current source, a first iontophoresis electrode located within the delivery region for transport of the therapeutic agent from the delivery region into a target tissue via electromigration, and a second iontophoresis electrode located within the receiving region for maintaining electroneutrality within the tissue.

Disclosed is an iontophoresis-based patch type skin care device for allowing a functional substance for skin care to be effectively absorbed into a user's skin by causing iontophoresis on the user's skin through a conductive patch. The iontophoresis-based patch type skin care device for allowing the functional substance for the skin care to be absorbed into the user's skin by the iontophoresis includes a skin care device body that generates power to cause the iontophoresis. The skin care device body includes a power circuit that is provided in an interior space of a body and that includes a power unit that generates the power for the iontophoresis and one or more electrodes to which the power is applied, and a bridge that is provided so as to be combinable with the body and that receives the power through the one or more electrodes. The bridge includes a bridge body provided so as to be combinable with the body and a plurality of bridge legs arranged along a circumferential direction of the bridge body and formed of a conductive material.

A patch-type skincare device is provided. A patch-type skincare device according to an exemplary embodiment of the present invention comprises: a light source part comprising a flexible plate-shaped substrate member having a circuit pattern formed on at least one surface thereof, and at least one LED mounted on one surface of the substrate member; a pair of cover members disposed on both surfaces of the substrate member so as to prevent the light source part from being exposed to the outside; and a connection cable for supplying the light source part with power that is externally supplied.

An active molecule delivery system whereby active molecules can be released on demand and/or a variety of different active molecules can be delivered from the same system and/or different concentrations of active molecules can be delivered from the same system. The active molecule delivery system includes a first electrode, a plurality of microcells, and a porous conductive layer. The microcells are filled with a medium including active molecules.

Various systems and methods provide iontophoretic delivery of anesthesia at a patient's tympanic membrane. At least one example is a method including: performing iontophoresis within a first ear canal by driving, by a control unit, a DC signal to an electrode of a first iontophoresis device positioned within the first ear canal, the electrode at least partially submerged within an iontophoresis fluid within the first ear canal; measuring, by the control unit, a mixed capacitance associated with the electrode by driving a first AC signal having a first frequency to the electrode; and determining, based on a change in the mixed capacitance, that an air bubble is present in the iontophoresis fluid.

A device for treating human keratin materials that delivers a cosmetic or dermatological composition onto the latter together with the application of an electric current, in particular an electrophoresis device, the composition applied being contained in a cartridge carried by the device, the cartridge having a body that forms a reservoir and a piston through which a drive screw passes and which can move in the body under the effect of the relative rotation of the screw and the piston, the device comprising an electric drive motor for bringing about this relative rotation of the screw and of the piston, and an electronic circuit for controlling the electric motor.