A tissue hydration monitor and method includes a sensor module having a plurality of LEDs positioned to emit a plurality of different wavelengths of light toward the user's skin and a detector that detects light transmitted and reflected through the user's skin to generate signals corresponding to an intensity of detected light at each of the different wavelengths. A processor/controller module generates a baseline hydration level based on the received signals, calculates a relative hydration level, and generates an output indicative of relative hydration personalized to the user. The housing is secured against the user's skin by an adhesive patch or a strap.

A volumetric sampling apparatus for volatile compounds comprises a structure, such as a channel structure that forms a continuous curve between the inlet port and the outlet port. A gas flow induced in the structure urges volatile compounds collected via transdermal diffusion toward the outlet port, where the volatile compounds may be collected and analyzed by a gas composition analyzer coupled to the outlet port.

A moisture-sensitive device is provided that includes a dissolvable conductive material. Exposure of the dissolvable conductive material to urine or some other fluid causes the dissolvable conductive material to dissolve, increasing an effective resistance of the dissolvable conductive material. This change in resistance can be detected to determine the presence of an aqueous fluid. In response to such detection, a transmitter can then provide a wireless transmission indicative of the presence of the fluid. This moisture-sensitive device can be provided in a diaper and transmissions produced by the device can be detected using a smart phone or other device and used to indicate to a user that the diaper has been soiled.

The invention relates to a device for accessing an area with restricted access or an area to which access is controlled, comprising a support, a sensor and access control stage, the support comprising a portion to be discarded and a portion to be retained, the sensor being borne by the portion to be discarded and being configured to measure at least one parameter of a subject's health, and to deliver a detection signal representative of the measurement of each health parameter, the access control stage being borne by the portion to be retained and being configured to store access information dependent on the detection signal delivered by the sensor, the portion to be retained being able to be mechanically separated from the portion to be discarded so as to form an access key allowing, depending on the access information, access or otherwise to the area with restricted access or to the area to which access is controlled.

Methods, systems, and devices are described herein for various embodiments of using a sample analysis system to analyze a sample of bodily fluid from a user to determine parameters associated with the user including states of hydration, dehydration, rehydration, electrolyte loss, wellness, recovery, and the like. In some embodiments, the methods disclosed can be implemented using a device worn by a user, and operatively coupled to a sample analysis system configured to collect a sample of bodily fluid, and measure and analyze the bodily fluid to determine a property of the bodily fluid and/or a physiological/wellness parameter (e.g., degree of hydration, electrolyte losses, perspiration rate, etc.) of the user.

Bodily fluid indicator devices and methods are provided. Such devices and methods can effectively indicate whether the amount of bodily fluid being produced is within a measurable range. In an exemplary embodiment, a bodily fluid indicator device includes a substrate having a surface. Some portions of the surface are covered with a region of absorbent material and other portions of the surface are devoid of the absorbent material. A graduated scale or a reactive feature is printed on the absorbent material. The device is configured to indicate an amount and/or a composition a bodily fluid present on an area of a patient or subject.

The present invention provides a display apparatus and a display method for realizing control for display operations by a user precisely reflecting the user's status, i.e., the user's intentions, visual state and physical conditions. Worn as an eyeglass-like or head-mount wearable unit for example, the display apparatus of the present invention enables the user to recognize visibly various images on the display unit positioned in front of the user's eyes thereby providing the picked up images, reproduced images, and received images. As control for various display operations such as switching between the display state and the see-through state, display operation mode and selecting sources, the display apparatus of the present invention acquires information about either behavior or physical status of the user, and determines either intention or status of the user in accordance with the acquired information, thereby controlling the display operation appropriately on the basis of the determination result.

A grating pattern element includes peaks which are periodically arranged and valleys provided between the peaks, and at least one of the peaks and at least one of the valleys includes an adsorbing material on a surface thereof which adsorbs a target material.

The disclosed devices and methods provide one or more sensors associated with a nasal insert to provide data on respiratory health from within a patient's nasal passage. The nasal insert may simply be a vehicle for carrying one or more sensors, or the nasal insert itself may form part of the treatment. For example, the nasal insert may be used to increase airflow through the nasal passages. The nasal insert can contain a bio-sensor that may be affixed to an internal or external surface of the insert, be embedded partially or fully in an internal or external surface of the insert, or may pass through an internal or external wall of the nasal insert. In addition, the insert may include grooves that can be used to attach a sensor to the insert, for example, in place of or in conjunction with a filter.

A tissue hydration monitor and method includes a sensor module having a plurality of LEDs positioned to emit a plurality of different wavelengths of light toward the user's skin and a detector that detects light transmitted and reflected through the user's skin to generate signals corresponding to an intensity of detected light at each of the different wavelengths. A processor/controller module generates a baseline hydration level based on the received signals, calculates a relative hydration level, and generates an output indicative of relative hydration personalized to the user. The housing is secured against the user's skin by an adhesive patch or a strap.