Embodiments of the present invention provide a passive radio frequency identification (RFID) moisture sensor. This moisture sensor includes one or more antenna structures having a tail. The tail is operable to transport a disturbance such as, but not limited to fluid or moisture from a monitored location wherein the antenna has an impedance and varies with proximity to the disturbance. An integrated circuit couples to the antenna structure. This IC includes a power harvesting module operable to energize the integrated circuit, an impedance-matching engine coupled to the antenna, a memory module, and a wireless communication module. The impedance-matching engine may vary a reactive component to reduce a mismatch between the antenna impedance and the IC and produce an impedance value (sensor code) representative of the reactive component impedance. The memory module stores the impedance value (sensor code) until the wireless communication module communicates with an RFID reader and sends the impedance value/sensor code to the RFID reader. The RFID reader may then determine an environmental condition such as the presence of moisture or fluids at the tail of the RFID sensor. This sensor may deploy several antenna and/or tails sensitive to unique disturbances. These tails may be used to monitor different locations as well as different types of fluids. In one particular embodiment, the disturbance is a fluid or moisture within the gutter of a vehicle body.

A system for tracking a medical procedure includes a set of macros, a scanning device, and a control unit. Each macro in the set of macros is associated with instructions that execute a tracking step of a medical procedure. The scanning device is controlled by a user during the medical procedure to select a macro from the set of macros. The control unit executes the instructions associated with the selected macro to track the medical procedure.

Systems, devices, and methods are provided that allow the authentication of devices within analyte monitoring systems. The analyte monitoring systems can be in vivo systems and can include a sensor control device with a sensor and accompanying circuitry, as well as a reader device for communicating with the sensor control device. The analyte monitoring systems can interface with a trusted computer system located at a remote site. Numerous techniques of authentication are disclosed that can enable the detection of counterfeit components, such as a counterfeit sensor control device.

Systems, devices, and methods are provided for the management of multiple sensor control devices and/or multiple reader devices in an in vivo analyte monitoring environment, and also for resolving conflicts when merging data collected by different reader devices.

It is known in the art to use an apparatus to enhance the visual appearance of the veins and arteries in a patient to facilitate insertion of needles into those veins and arteries. This application discloses a number of inventions that add additional data collection and presentation capabilities to a handheld vein enhancement apparatus and a set of processes for the collection of blood and the delivery of IV medicines that use the handheld device to mediate the process.

Methods, devices, systems, and kits are provided that buffer the time spaced glucose signals in a memory, and when a request for real time glucose level information is detected, transmit the buffered glucose signals and real time monitored glucose level information to a remotely located device, process a subset of the received glucose signals to identify a predetermined number of consecutive glucose data points indicating an adverse condition such as an impending hypoglycemic condition, confirm the adverse condition based on comparison of the predetermined number of consecutive glucose data points to a stored glucose data profile associated with the adverse condition, where confirming the adverse condition includes generating a notification signal when the impending hypoglycemic condition is confirmed, and activate a radio frequency (RF) communication module to wirelessly transmit the generated notification signal to the remotely located device only when the notification signal is generated.

In some embodiments, apparatuses and methods are provided herein useful to screening a body temperature of a human. In some embodiments, there is provided a temperature screening system that screens a body temperature of a human including a housing comprising an output interface; one or more first sensors; a temperature sensor; and a control circuit configured to: cause the output interface to provide one or more messages; receive the one or more user inputs indicative of responses to at least one of the one or more messages; receive temperature data corresponding to the body temperature; determine whether the human meets a health criteria; and transmit a control signal indicative of the human meeting the health criteria in response to the human meeting the health criteria.

A monitor configuration system which communicates with a physiological sensor, the monitor configuration system including one or more processors and an instrument manager module running on the one or more processors. At least one of the one or more processors communicates with the sensor and calculates at least one physiological parameters responsive to the sensor. The instrument manager controls the calculation, display and/or alarms based upon the physiological parameters. A configuration indicator identifies the configuration profile. In one aspect of the invention, the physiological sensor is a optical sensor that includes at least one light emitting diode and at least one detector.

In some embodiments, apparatuses and methods are provided herein useful to screening a body temperature of a human. In some embodiments, there is provided a touchless temperature screening system that screens a body temperature of a human including a housing comprising an output interface; one or more first sensors; a temperature sensor; and a control circuit configured to: cause the output interface to provide one or more messages; receive the one or more user inputs indicative of responses to at least one of the one or more messages; receive temperature data corresponding to the body temperature; determine whether the human meets a health criteria; and transmit a control signal indicative of the human meeting the health criteria in response to the human meeting the health criteria.