In a microrunner structure, there are provided with components for a cleaning procedure required to conduct electrochemical sensing when a biosensor is activated for sensing; and a urine signal detection device that is a SoC (System on a Chip), which has a wireless transceiving circuit for receiving a urine measurement method and channel information transmitted from an intelligent device, and in turn, outputting a stimulus signal to trigger a biosensor or a non-biosensor in a multi-channel structure to conduct urine sense processing for a sensing area, as well as transmitting detection processing for a concentration of urine substances from the electrochemical sensing to the intelligent device through the wireless transceiving circuit to assess a risk index between a heart disease or diabetes and a kidney disease.

A system includes a sensor applicator, a sensor control device arranged within the sensor applicator and including an electronics housing and a sensor extending from a bottom of the electronics housing, and a cap coupled to one of the sensor applicator and the sensor control device, wherein the cap is removable prior to deploying the sensor control device from the sensor applicator.

A monitoring system comprises an intra-vascular support device and a sensor mounted to the support device and projecting into the vessel. The sensor generates a signal which is dependent on the level of deformation of a free end. The sensor signal is interpreted to enable detection of changes in the length of a deformable part of the sensor thereby to determine a level of bio-layer formation and also determine a level of flow. The sensor remains able to detect flow even when a bio-layer is formed and it can also detect the presence (and thickness) of the bio-layer, because part of the sensor becomes rigid when constrained by the bio-layer.

The present technology relates to an information processing device and a method of ventilating an information processing device, which are able to prevent getting sweaty and damp when the information processing device is worn. The information processing device is to be worn by a user and includes a main body portion having a contact surface that is brought into contact with a skin of the user, and a groove that crosses the contact surface. The present technology is able to be applied to a wearable device of a type such as a wrist-band type, an earphone type, a neckband type, an eyeglasses type, a watch type, a bracelet type, a neckless type, a headset type, or a head-mount type.

Sleeves and cases for protecting medical devices against contamination, and methods for cleaning and disinfecting medical devices are provided. The various embodiments enable a single medical device to be used by more than one patient successively while reducing the risk of disease transmission from patient to patient.

The systems and methods described herein can advantageously allow users to discretely measure their exhaled breath in an easy, cost-effective and non-invasive manner. A handheld breath sensing system may be provided with a main housing, a first mouthpiece, a lid, a sampling chamber, a sensor and a microprocessor. The first mouthpiece may be configured to allow a user to exhale into the mouthpiece. The lid may be movable between an open position and a closed position. The sampling chamber may be in fluid communication with the first mouthpiece. The sensor may be in fluid communication with the sampling chamber and configured to measure at least one property of a user's breath. The microprocessor may be configured to process electronic signals from the sensor such that at least one volatile organic compound in the user's breath can be quantified and a resulting biomarker measurement provided to the user in near real-time.

Sleeves and cases for protecting medical devices against contamination, and methods for cleaning and disinfecting medical devices are provided. The various embodiments enable a single medical device to be used by more than one patient successively while reducing the risk of disease transmission from patient to patient.

This exhalation measuring device is provided with a handle component, a chamber, a piezoelectric pump, and a drying mode controller. Exhalation is blown into the handle component. The chamber temporarily holds the exhalation that has been blown in. The piezoelectric pump supplies the exhalation held in the chamber to a measurement component. The dry mode controller executes a drying mode in which the piezoelectric pump is driven and outside air is drawn in from the handle component, after the measurement of exhalation by the measurement component.

The described embodiments relate to a sensor patch that can be temporarily removed and re-applied in the same location using a side element of the sensor patch. The side element can be folded onto the sensor patch when the sensor patch is adhered to an object such as an appendage of a person. The side element can be unfolded and adhered to the appendage in order to preserve the placement of the sensor patch on the appendage. In this way, maintenance such as cleaning can be performed on the area where the sensor patch is located without having to dispose of the sensor patch. Once maintenance is completed, the side element can be folded back onto a surface of the sensor patch until maintenance is to be performed again.

A multi-lead multi-electrode system and method of manufacturing the multi-lead multi-electrode system includes a multi-electrode lead that may be used to deploy multiple separable electrodes to different spaced apart contact sites, such as nerve or muscle tissues, for example, that are spatially distributed over a large area.