A microfluidic device for non-invasively and passively accessing interstitial fluid from a patient includes a substrate containing multiple vertical micro channels therethrough, wherein at a first end of each of the multiple vertical micro channels a microheater is formed for controllably ablating a portion of dry dead skin cells to access the interstitial fluid; and wherein at a second end of each of the multiple vertical micro channels is a horizontal micro channel for receiving accessed interstitial fluid from a vertical micro channel and guiding the accessed interstitial fluid to a common collection port.

The application relates to a device (100) for non-invasively sampling interstitial fluid comprising one or more analytes from dermis (101 a) to skin surface (101 b) by using the magneto-hydrodynamic effect. The device comprises a first electrode (102a) and a second electrode (102b) adapted to be positioned adjacent to the skin surface, the first electrode separated from the second electrode by a distance (103), a power source (104) adapted to induce an electric current through the first electrode, the interstitial fluid and the second electrode, and also a magnet (105) adapted to produce a magnetic field to the interstitial fluid. Direction of the magnetic field and direction of the electric current produced by the magnet and the power source, respectively, is such that Lorenz force drives the fluid from the dermis towards the skin surface.

A curtain airbag device mounting structure includes: a first pillar forming a part of a front pillar and extends substantially along a vehicle height direction; a second pillar forming another part of the front pillar, the second pillar being disposed on a rear side of a vehicle relative to the first pillar at a predetermined distance from the first pillar and extending substantially along the vehicle height direction; a transparent member bridged between the first pillar and the second pillar; and a curtain airbag device including a curtain airbag stored along a roof side rail and the second pillar, the curtain airbag being configured to inflate and deploy in a curtain-like fashion over a side portion of a cabin of the vehicle in case of a collision of the vehicle.

The present disclosure relates to a non-invasive and continuous biomedical detections and non-invasive and continuous monitoring methods and devices for extracting and analyzing interstitial fluid extracted non-invasively and continuously from the skin of a subject comprising non-invasively electroporating the skin using a non pulsed voltage in combination with a pulsed voltage and applying negative pressure.

A system and methods are provided for reducing electrochemical interference in a transdermal sampling and analysis device. A one-step transdermal glucose biosensor may calculate glucose concentrations that are artificially high compared to traditional home blood glucose sensors due to interference, which may be mitigated by forming an anti-interferent barrier layer over a sensing element. The anti-interferent barrier layer may be formed over a sensing layer and may possess a charge type which repels interferent molecules having the same charge type from interacting with the sensing layer disposed below the anti-interferent barrier layer.

Transdermal sampling and analysis device, method and system are provided for non-invasively and transdermally obtaining biological samples from a subject and determining levels of analytes of the obtained biological samples. The transdermal sampling and analysis device, method and system may cause disruption to the skin cells to create capillary-like channels from which biological samples may flow to the transdermal sampling and analysis device. The transdermal sampling and analysis device, method and system may collect the biological samples in a reservoir where the biological sample may chemically react with a biologically reactive element. A sensor may convert the produced electrons (ions) into measured electrical signals. The converted signals may be measured and the levels of an analyte may be determined based on the measured signals.

Methods and systems for manufacturing a transdermal sampling and analysis device for non-invasively and transdermally obtaining biological samples from a subject and determining levels of analytes of the obtained biological samples are provided. A method of manufacturing the device may improve performance and includes forming channel structures on the lid of the device, thereby making the spacer/channel support structures physically independent and separable from the sensing electrode. Other methods of manufacturing the device may improve performance and include forming at least one of the electrodes on each of the base and the lid, and forming a recessed second spacer layer over the channel support structures, thereby separating the channel support structures and the electrode on the lid to allow a larger area of the electrode to be exposed to the biological sample.

A device for introducing at least one antimicrobial in an exposed region of a user's skin caused while accessing interstitial fluid includes a substrate having thereon at least one electrically controllable microheating element including at least a microheater portion with multiple electrodes connected to the microheater portion for forming a micropore in the user's skin. A nanofiber mat loaded with at least one antimicrobial material is arranged on the substrate such that it contacts the user's skin and encircles an opening of the micropore formed by the microheating element. In a preferred embodiment, the at least one antimicrobial material is LL-37.