A head guard is provided. The head guard includes one or more sensors as part of an sensory input and communications system. The head guard wirelessly communicates data to remote computing devices for intelligent data collection.

The application relates to a chemical monitoring system comprising a skin patch for detecting an analyte in perspiration and a processor adapted to receive parameter data and to return an output indicative of a presence of an analyte in a subject's body based on the parameter data. The skin patch (100) includes a first layer (105) permeable to perspiration; a second layer (110) coupled to the first layer, the second layer being adapted to receive the perspiration; wherein a property of the second layer changes upon receiving the analyte; an electrical detector coupled to the second layer, adapted to detect parameter data indicative of the property o f the second layer; and a flexible electronic circuit (140) coupled to the second layer, comprising a readout circuit for reading parameter data from the electronic detector and a transmitter adapted to transmit the parameter data to a processor.

A system to measure sweat vapor may include a skin contact sensor, a sweat vapor sensor, and a processor. The skin contact sensor may be configured to measure one or more aspects indicative of whether the measuring device is in contact with skin of a user of the measuring device. The sweat vapor sensor may be configured to measure one or more properties of sweat vapor of the user; and the processor may be communicatively coupled to the skin contact sensor and the sweat vapor sensor. The processor may be configured to confirm operation of the measuring device based on the one or more aspects measured by the skin contact sensor, and the sweat vapor sensor receiving the sweat vapor.

Methods and apparatuses for blood glucose measurement are provided. A first glucose concentration in a body fluid of a user is detected based on a first measurement interval. A first blood glucose level of the user is determined based on the first glucose concentration. A glucose concentration measurement interval is changed from the first measurement interval to a second measurement interval according to an occurrence of an event. A second glucose concentration in the body fluid is detected based on the second measurement interval. A second blood glucose level of the user is determined based on the second glucose concentration.

Methods of forming garments having one or more stretchable conductive ink patterns. Described herein are method of making garments (including compression garments) having one or more highly stretchable conductive ink pattern formed of a composite of an insulative adhesive, a conductive ink, and an intermediate gradient zone between the adhesive and conductive ink. The conductive ink typically includes between about 40-60% conductive particles, between about 30-50% binder; between about 3-7% solvent; and between about 3-7% thickener. The stretchable conductive ink patterns may be stretched more than twice their length without breaking or rupturing.

The present disclosure discloses a novel omniphobic, paper-based, smart bandage (OPSB) devices, and the methods to make and use the omniphobic, paper-based, smart bandage devices. The OPSB device of the present disclosure provides a simple, low-cost, and non-invasive strategy to monitor open wound status wirelessly. This disclosure also provides the demonstration of in-vivo early detection and monitoring of pressure ulcers using wireless smart bandages.

Embodiments of the invention include devices, systems, methods and software applications that automatically detect measured blood alcohol content (BAC). In aspects, a blood alcohol content sensor detects blood alcohol content by measuring an amount of sweat via a wearable device. The systems and methods can also predict the future BAC of a subject by considering the present BAC along with physiological events and/or historical data. The results can be reported to a server to applying a protocol in response to the reported results.

Methods of diagnosing and/or monitoring tuberculosis (TB) in a subject by analyzing a test sample comprising at least one volatile organic compound (VOC) or semi-volatile organic compound (SVOC) emitted or excreted from the skin of the subject. The test sample can be analyzed by a sensing unit comprising nanomaterials- and/or polymer-based sensors. Further provided is a skin-mountable device comprising a fixing unit and said sensing unit. Also discloses a method of diagnosing and/or monitoring tuberculosis, comprising analyzing specific skin-emitted VOCs or SVOCs, which are indicative of tuberculosis in a subject.

Provided is a perspiration amount measuring device that includes: an air flow path through which inside air flows; a first thermo-hygro sensor that is disposed at a place opened to an external field, and measures a temperature and a relative humidity of outside air that is taken in from a place on a side opposite to the wearer as viewed from the air flow path; a fan that sucks the inside air in the air flow path and discharges the inside air to an outside of the perspiration amount measuring device; and a second thermo-hygro sensor that is disposed in a flow of the inside air generated due to an operation of the fan, and measures a temperature and a relative humidity of the inside air. The perspiration amount measuring device is mounted on an edge portion of a helmet, and can accurately measure a head perspiration amount.

Systems and methods for a self-powered wireless wearable sensor system include a freestanding triboelectric nanogenerator (FTENG), used as a power source for a wearable sensor. The FTENG includes stator panels and corresponding slider panels with a grating pattern. Movement, such as cardiovascular exercise causes the slider panel(s) to slide across the stator panel(s) inducing a charge and powering a wearable device sufficiently to support data transmission and continuous monitoring. An integrated self-powered wireless wearable sensor system includes a microfluidic sweat sensor patch which may be connected to lower-power wireless sensor circuitry for regulating power efficiently and is powered by the FTENG.