The present disclosure provides an oral data collection device comprising a mouthguard and at least two sensors, a medical analytics system comprising the device, and methods of using the device and system to provide a personalized treatment protocol, stage a health condition, measure a response to therapy, phenotype for selection to participate in drug trials, measure stability of an anatomical structure, or predict a rate of change of a health condition in a subject in need thereof.

Provided are location devices that identify the location for measuring physiological conditions, methods of operating the device, and computer program products for use with the device. The location device provides improved reliability in measurement data since it consistently provides the location for the measurements. In the context of a location device, an apparatus is provided that includes a structure configured to be attached to the skin of a user and configured to identify a location for physiological measurement. The structure has a shape configured to correspond to a portion of the user that is in a predefined positional relationship to the location for the physiological measurement. As such, the structure is configured to engage the portion of the user in order to identify the location for the physiological measurement. The location device may include one or more sensors for measuring physiological conditions or may work in conjunction with one or more sensors.

A head mount apparatus mounted on a head of a user is disclosed, which includes: detection means to detect a variation of a bloodflow rate of the head; and transfer means to transfer a detection value of the detection means to a predetermined transfer destination. An information processing apparatus is also disclosed, which includes; receiving means to receive a detection value transferred from transfer means; and service providing means to provide a user with a service based on the received detection value.

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.

The present disclosure generally relates to the field of temporal and spatial risk mapping and risk response. More particularly, the present disclosure relates to spatial and temporal mapping of outcomes, risk analysis, and responsive and preventative actions derived through artificial intelligence driven workflow augmentation using spatial and temporal data mapping of data from a plurality of historical and streaming data sources.

Systems, devices, and methods are provided to facilitate the implementation of a “proning protocol” to improve a clinical outcome for a person having SARS-CoV-2 (COVID-19) or other condition that may benefit from spending time in the prone position. For example, a system may include a mobile device (e.g., smartphone, tablet, etc.) providing a proning application configured to manage a configuration and implementation of a proning protocol for a person and configured to receive sensor data from (a) a wearable sensor device secured to the person and including sensor(s) (e.g., accelerometer(s)) that monitor the person body position, and/or (b) other sensor(s) that monitor other physiological parameters relative to the proning protocol. The proning application may determine and output feedback to manage the person's position based at least on the received sensor data and defined parameters of the proning protocol.

A flexible circuit may be provided that allows for the monitoring of a physical object. The flexible circuit includes a plurality of flexible conductive segments that are disposed in a geometric pattern. The flexible conductive segments include nodes, and the physical object is monitored by analyzing changes in electrical resistance in the conductive segments between the nodes. The flexible circuit may also include sensors disposed on the nodes for monitoring additional conditions. A processor monitors the flexible conductive segments and sensors. and may provide an output regarding the status of the physical object.

A sensing assembly having: a sensing device having first and second opposing major surfaces, a first sensor located in the device and positioned for preferentially sensing a parameter at the first major surface and a second sensor located in the device and positioned for preferentially sensing the parameter at the second major surface; and a wearable carrier for embracing a part of the human or animal body, the carrier having a hole extending fully therethrough; the sensing device and the carrier being cooperatively configured so that the sensing device can be releasably lodged in the hole in the carrier so that when the carrier is embracing the body part the sensing device can be held against the body part by the carrier with one major surface of the sensing device facing the body part and with no part of the carrier between the sensing device and the body.

There is provided a hygiene monitoring device including a sensing panel. The sensing panel has an elongate flexible panel defining a longitudinal axis. The elongate flexible panel includes a first pair of plates spaced apart from each other in a direction crossing the longitudinal axis. The elongate flexible panel also includes a second pair of plates spaced apart from each other in a direction crossing the longitudinal axis. The first pair of plates and the second pair of plates are disposed on a flexible substrate of the elongate flexible panel. Each plate of the first pair of plates and each plate of the second pair of plates is elongate along the longitudinal axis of the elongate flexible panel. The hygiene monitoring device is configured to measure the impedance between two of the plates.

In a measuring device for measuring an intensive measurand, including at least one measuring chamber having at least one opening, the opening being placeable on the body to be examined. At least three sensors for measuring the intensive measurand are arranged in the measuring chamber, the sensors being arranged at different distances from the body to be examined during measurement. An evaluation device being provided which receives the values measured by the sensors and determines a total value for the intensive measured variable from the at least three measured values as well as a substance or energy diffusion rate.