A reverse electrodialysis device using a precipitation reaction, according to one embodiment of the present invention, comprises a first cell stack alternately forming solid salt chambers and precipitation chambers through cation-exchange membranes and anion-exchange membranes which are alternately provided, and a first water-soluble solid salt and a second water-soluble solid salt which are filled in the solid salt chambers, wherein the first water-soluble solid salt and the second water-soluble solid salt are alternately filled in the solid salt chambers, and can react with each other so as to generate a precipitate in neighboring precipitation chambers when water is supplied.

A device (100) for electrophoretic delivery of ions comprising a source electrode (200) in electric and ionic contact with a source electrolyte (202), and a target electrode (400) in electric and ionic contact target electrolyte (402), said source and target electrodes (200, 400) capable of conducting ions and electrons; an ion-conductive channel (302) connecting the source electrolyte (202) with the target electrolyte (402) to provide an ionic connection between said source and said target electrodes (200, 400), wherein said electrodes (200, 400) and said ion-conductive channel (302) are formed of solid or semi-solid materials, and a controller, operable to apply a drive voltage between said source and said target electrodes (200, 400), such that at least after a voltage is applied across said ion-conductive channel, a potential difference between said source and target electrodes (200, 400) is provided, further comprising a trapping electrode (300) comprising an effective amount of a Bronsted base, said trapping electrode (300) being arranged in ionic contact with the ion-conductive channel (302). Use of the device is also disclosed, as is a method of operating the device and a method electrophoretic delivery of ions.

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 invention is well-suited for delivering pharmaceuticals to patients transdermally. In some embodiments, the system includes two separate reservoirs and a mixing area thereby allowing precursors to be mixed immediately before transdermal delivery.

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 invention is well-suited for delivering pharmaceuticals to patients transdermally. In some embodiments, the system includes two separate reservoirs and a mixing area thereby allowing precursors to be mixed immediately before transdermal delivery.

A reverse electrodialysis device using a precipitation reaction, according to one embodiment of the present invention, comprises a first cell stack alternately forming solid salt chambers and precipitation chambers through cation-exchange membranes and anion-exchange membranes which are alternately provided, and a first water-soluble solid salt and a second water-soluble solid salt which are filled in the solid salt chambers, wherein the first water-soluble solid salt and the second water-soluble solid salt are alternately filled in the solid salt chambers, and can react with each other so as to generate a precipitate in neighboring precipitation chambers when water is supplied.

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.

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.

A device for increasing a concentration of at least one analyte in an advective flow of biofluid includes an agent for enhancing a paracellular permeability of an epithelial tissue; and an iontophoresis electrode and a counter electrode, which are adapted to increase the concentration of said analyte in the advective flow of the biofluid. A method of sensing an analyte in a biofluid includes increasing a paracellular permeability of an epithelial tissue layer; and inducing electro-osmotic flow by reverse iontophoresis to increase a concentration of said analyte in an advective flow of the biofluid, wherein said advective flow is driven by at least one of saliva generation, sweat generation, or reverse iontophoresis.

This disclosure provides self-applied wearable devices configured to electrically stimulate a user, generate and/or collect a user's electrophysiological data via electrodes, in contact with the outer layer of skin, that hydrate the skin surface using iontophoresis, reverse iontophoresis, and/or a combination thereof. The wearable devices provided herein increase conductivity and/or move biological ions and/or polar molecules from the electrode into the outer skin layer of skin surface to reduced impedance between the outer skin layer and electrode, wherein the impedance between electrodes is matched and/or minimized. This disclosure also provides systems comprising the same, and methods for making and using the same.

An integrated package comprising a lab-on-chip (LOC) is disclosed. The LOC includes at least one integrated device having a membrane portion having a membrane opening; the membrane portion having a first side and a second side, the first side opposite the second side, a MEMS portion disposed on the first side of the membrane portion, the MEMS portion having a sharp member disposed on an actuator stage within a MEMS cavity, and a fluidic portion disposed on the second side of the membrane portion, the fluidic portion having a fluidic cavity for flowing a fluid medium within the fluidic portion; and a fluidic cap forming a surface of the fluidic portion of the LOC, the fluidic cap having a fluidic inlet and a fluidic outlet. The method of operating the LOC includes power to the at least one integrated device to capture one or more particles for interrogation.