The present invention provides a skin patch for measuring a biometric parameter of a bodily fluid. The skin patch comprises a hydrophilic sensing bead and a sensor including at least one electrode embedded within the hydrophilic sensing bead, in which the sensor is configured to obtain data relating to the concentration of the hydrophilic sensing bead relating to the parameter. The skin patch further comprises a transport section for transporting a bodily fluid to contact the hydrophilic sensing bead. The skin patch also comprises a communication unit, which includes an input section communicating with the sensor via a connector, and an output section configured to output the obtained data.

The present invention relates generally to systems and methods for measuring an analyte in a host. More particularly, the present invention relates to systems and methods for transcutaneous measurement of glucose in a host.

An electronic system for monitoring a physical parameter includes an ADM comprising an accumulation mode sensor for measuring the physical parameter by generating electrical energy associated with the physical parameter in response to a surrounding condition, and an energy storing device coupled to the accumulation mode sensor for accumulatively storing the generated electrical energy; a power source; and an SoC coupling with the ADM and the power source, configured such that the stored electrical energy is monitored, and when the stored electrical energy is equal to or greater than a pre-defined threshold, a wake-up event is generated to trigger the SoC to operates in a run mode in which the physical parameter is wirelessly transmitted to a receiver and the stored electrical energy in the energy storing device is discharged, and then the SoC returns to a sleep mode in which a minimal power is consumed.

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.

A new system monitors ethanol alcohol levels of a vehicle operator by collecting sweat from the operator's hands, and detecting the presence, if any, of ethanol in the sweat. The system can then be used, if ethanol is present, to take action, such as immobile vehicle disablement, in the event of intoxication caused by an impermissibly high levels of ethanol of the operator. The system includes devices, referred to as pods in the description, which are sweat-collecting devices that are attached to the steering wheel of the vehicle. If the measurable ethanol in collected moisture from the operator's hands exceeds a preset threshold, the system could be configured to warn the operator to park the vehicle thereafter to disable operation of the vehicle, but if the operator does not so discontinue operation of the vehicle hazard warning lights and audible warnings within and without the vehicle will be activated alerting near vehicles of a dangerous vehicle being operated in close proximity. Likewise the new system monitors for pulse rate and oxygen levels of the operator can be used to recommend operator action when the pulse rate and/or oxygen levels are outside of the normal range for an operator. When the pulse rate and or oxygen levels of the system are outside of the normal parameters for an operator, the system will warn the operator to park the vehicle and thereafter to disable operation of the immobile vehicle, but if the operator does not so discontinue operation of the vehicle the hazard warning lights, on board video, and audible warnings within and without the vehicle will be activated alerting near vehicles of a dangerous vehicle being operated in close proximity, and alarms will be sent to real time recording and monitoring devices.

A sweat sensor device (200) with analytical assurance includes at least one sensor (220) for detecting a first analyte, and at least one calibration medium (270) containing at least the first analyte. When the first analyte in the at least one calibration medium (270) comes into contact with the at least one sensor (220), the calibration medium (270) provides a calibration of the at least one sensor (220). A sweat sensor device (200) may further include a carrier (240) having at least one aperture (220a) and a reservoir (254) for storing the at least one calibration medium (270). The at least one aperture (220a) provides fluidic access to the at least one sensor (220) from the reservoir (254).

A wearable monitoring system includes a first flexible substrate encapsulating a current ramping system to provide a current to an electrode in direct contact with a predetermined location of skin of a user to promote bodily fluid secretion, and a second flexible substrate placed over the predetermined location, the second flexible substrate having an integrated electrochemical sensor to determine bodily fluid concentration levels secreted through the skin.

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.

A wearable medical device for collecting a biofluid and related methods are disclosed. The device has a patch adapted to removably couple to a user's skin. The patch has at least one flow channel, at least one sample chamber, and at least one biomarker detection chamber. The flow channel and/or the sample chamber conducts the biofluid towards the biomarker detection chamber. The sample chamber is adapted to create a high humidity environment adjacent the user's skin. The flow channel comprises a hydrophobic material and a hydrophilic material.

Described herein are apparatuses (e.g., garments, including but not limited to shirts, pants, and the like) for detecting and monitoring physiological parameters, such as respiration, cardiac parameters, and the like. Also described herein are methods of forming garments having one or more stretchable conductive ink patterns and methods of making 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.