Self-directed health screening systems and methods utilizing user navigation and device integration, health analyzing algorithms, and/or self-learning techniques for the detection, quantifying, prevention, and management of health risks and discoverable health conditions. Implementations herein may include components or involve aspects associated with information collection, information processing, display/provision/rendering of professional advice, and/or processing of various associated data and information via network(s). Implementations herein provide for innovatively configured, easily upgradable, efficient, portable, scalable, easy-to-use, usage-encouraging, and/or effective implementations for screening, predicting points of inflection of pending health issues, preventing and/or managing users' health, provided via various and multiple embodiments having numerous advantages over other known techniques. Screenings, health information, and user-selectable choices may be optimized for each unit by offering different combinations over a period of time and iterating to produce the greatest usage and user traffic thereby best serving the specific health needs of the user base and sponsoring advertisers.

The present invention provides compositions and methods of delivery of the compositions, as well as diagnostic method steps that greatly alleviate symptoms associated with IBS and/or IBD. Diagnostic procedures determine a likelihood of one or both of IBS and IBD within a patient. The methods disclosed act to determine relevant biometrics and a cycle time for a specific digestive tract transit time in order to determine a proper dosage amount and potency and a time of administration of the compositions to facilitate delivery of active agents to targeted areas of the GI tract.

A vital signs sensor includes an identifier storage device that stores an identifier of a subject, and a signal processing device that acquires a vital sign from the subject, and that wirelessly transmits the vital sign and the identifier that is stored in the identifier storage device, with correlating the vital sign with the identifier, wherein the identifier storage device has a structure where the identifier storage device is attachable to and detachable from the signal processing device.

A user device configured to monitor use of an injection device and disease progression is described. The user device includes a scanning device, a wireless transceiver, and a touch sensitive display. The user device is configured to use the scanning device to scan a package containing a plurality of injection devices or an individual injection device, use the wireless transceiver to transmit and receive signals representing data associated with the plurality of injection devices or the individual injection device, receive via the display a user input confirming that the plurality of injection devices or the individual injection device is suitable to store in a storage device, remind the patient to use a specific injection device on a specific day, remind a patient to capture an image of a skin lesion, and compile data associated with a series of images of skin lesions and transmit the data to a third party.

A radio frequency identification (RFID) tag includes a power harvesting circuit that operates generate power for the RFID tag from a continuous wave of a radio frequency (RF) signal. The RFID tag further includes a tuning circuit that is tuned based on a capacitance setting, where the capacitance setting is indicative of a power level of the power. The RFID tag further includes a processing module operably coupled to the tuning circuit, where the processing module operates to generate the capacitance setting to obtain a desired power level for the power.

At least one embodiment is a portable medical station comprising a main body, which is disposed at least partially inside of a bag. Coupled to the main body is at least one tray and a plurality of handles. There are also a plurality of screens coupled to the main body and at least one computer coupled to the main body, wherein the portable medical station is foldable inside of the bag so that the portable medical station is movable while being substantially folded inside of the bag.

A computing device receives analyte data produced by an analyte monitoring sensor over a communications link from at least one first device. Health data, comprising at least part of the analyte data, may be communicated over a communications link to at least one second device in response to a request. The first device may be positioned over the analyte monitoring sensor using signal strength and location information. External analyte data may be employed to calibrate the analyte monitoring sensor.

An electronic medical record (EMR) management system includes a data server configured to store an EMR of a patient; an imaging device configured to capture an image medically related to the patient and transmit the captured image; and an information management system communicatively coupled to the imaging device and to the data server, where the information management system is configured to receive the captured image from the imaging device, automatically associate the captured image with the patient, and store the captured image in the EMR of the patient in the data server.

An electronics module for a wearable sensor system has a housing that includes an outer wall, at least one contact element, and a carrier for the at least one contact element. The contact element extends through the at least one outer wall and is attached to the carrier, the carrier including at least one electrical conductor for electrical connection of the contact element and being designed to be flexible. Furthermore, a wearable sensor system is shown.

A radio frequency identification (RFID) tag includes a power harvesting circuit, an RF front-end, and a processing module. The power harvesting circuit generates power for the RFID tag from a continuous wave of an inbound radio frequency (RF) signal. The RF front-end receives the inbound RF signal and transmits an outbound RF signal. The RF front-end includes a tuning circuit that is tuned based on a capacitance setting. The tuning of the tuning circuit effects a characteristic of the RF front-end. The processing module generate the capacitance setting to adjust the characteristic of the RF front-end to a desired characteristic.