Provided are an iontophoresis device for drug delivery, a method for preparing the iontophoresis device, a kit including the iontophoresis device, and a method for delivering a drug by using the iontophoresis device.

A wound treatment device includes a flexible substrate having a top side, a bottom side and an opening extending therebetween. A reservoir has a port in fluid communication with the opening, and an iontophoretic driver circuit is electrically coupled to a plurality of electrodes.

A hand-held device for electrically assisted skin treatment includes a skin electrode and a hand electrode. An absorbent carrier material is soaked with an active ingredient. The absorbent carrier material is fastened to a ring and the ring is clippable onto the hand-held device. The absorbent carrier material extends over the skin electrode when the ring is in a clipped-on state with respect to the hand-held device.

Disclosed is an iontophoresis-based patch type medicine absorption device for allowing a medicine for medical treatment or 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 medicine absorption device for allowing the medicine for medical treatment or the functional substance for the skin care to be absorbed into the user's skin by the iontophoresis includes a medicine absorption device body that generates power to cause the iontophoresis. The medicine absorption 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.

An iontophoresis system includes a preloaded reservoir containing one or more doses of a therapeutic agent. As a result, the therapeutic agent does not have to be loaded into the reservoir prior to use. In such a system, the preloaded reservoir is generally disposable. Various components of the iontophoresis system can be combined with the reservoir in a disposable cartridge that is selectively connectable to other, reusable components of the iontophoresis system. In addition, the entire iontophoresis system can be formed from one or more disposable, one-time-use modules.

A method and apparatus to treat hyperhidrosis is provided in which a battery provides a milliampere electrical current to the inside of a waterproof glove containing water and sealed to the user's arm so that circulation is not unduly restricted while the user can raise the water-filled gloves and hands above the user's head without leaking. A tapered portion on the proximal end of each glove is folded inside the glove to seal against the user's arm to form a pocket between the tapered portion which seals against the user's arms, and part of a wrist portion of the glove located radially outward of the tapered portion. When the user's gloves and hands rotate upward, water collects in the pocket(s) while the tapered portion provides a leakproof seal, thus allowing manual manipulation while wearing the water-filled gloves.

The device of the present invention comprises an intervening release liner as a common special feature, and the intervening release liner covers a part of an adhesive surface of a patch. The intervening release liner gets away from the patch, and is fixed to a patch application support (or porator tab). Due to such constitution, under a situation in use where the first part of the adhesive area of the patch adheres to a skin surface, the patch application support is slidable along the skin surface while peeling the intervening release liner from said part of the adhesive area of the patch to adhere to the skin surface.

Embodiments of the invention provide methods for transdermal delivery of therapeutic agents for treatment of addictive cravings e.g., from nicotine. Embodiment of a method for such delivery comprises positioning at least one electrode assembly in electrical communication with a patient's skin. The assembly includes a solution comprising a therapeutic agent which passively diffuses into skin. A dose of agent is delivered from the assembly into skin during a first period using a first current having a characteristic e.g., polarity and magnitude, to repel agent out of the assembly. During a second period, a second current having a characteristic to attract agent is used to retain agent in the assembly such that delivery of agent into skin is minimized. In particular embodiments, a dose of agent may be delivered on-demand using an input from the patient using an inhalation sensing device which mimics an inhaled form of tobacco.

Disclosed is an energy self-sufficient real time bio-signal monitoring and nutrient and/or drug delivery system based on salinity gradient power generation. The energy self-sufficient real time bio-signal monitoring and/or nutrient delivery system based on salinity gradient power generation includes: an electricity generation and nutrient and/or drug delivery module including a reverse electrodialysis device which generates electricity by using a nutrient and/or drug solution and discharge a diluted nutrient solution; and a bio-signal measuring unit inserted into the electricity generation and nutrient and/or drug delivery module and configured to receive electricity from the electricity generation and nutrient and/or drug delivery module and measure a bio-signal.

An applicator comprises a first structural element which has a shape determined according to a digital geometric representation of a target structure, the applicator further comprises an active agent located according to a diagnostic scan of the target structure.