A method and system for tissue impedance measurement are disclosed. In examples, the system comprises electrical contacts configured to be coupled to a first tissue and a first device configured to apply a first electrical signal to the first tissue via the electrical contacts. The system further comprises a second device configured to determine a first impedance phase angle of epithelial tissue of the first tissue site based on the first applied electrical signal, determine a baseline impedance phase angle of epithelial tissue corresponding to a second tissue, determine information indicative of epithelial tissue characteristics based on a ratio of the first impedance phase angle and the baseline impedance phase angle, and output information indicative of the epithelial tissue characteristics.

A highly integrated analyte detection device is provided. The transmitter is composed of a shell, a cover body, a circuit module and an electrical connection module. The circuit module is fixedly connected with the shell, one end of the electric connection module is fixedly connected with the circuit module, the other end extends to the outside through the through hole on the shell, and is electrically connected with other structural parts. The sealing material is filled between the electric connection module and the through hole, and the cover body and the shell are clamped together to form a seal for the circuit module, which makes the transmitter structure simpler. The shell and the circuit module can be processed separately and then assembled. The production process is less difficult and the production cost is reduced at the same time.

A method for detecting stress in organisms with a cardiac organ is provided. A cardiac waveform is input to an analysis system which decomposes the incoming signal to detect patterns within the decomposed segments. The patterns are comprised of one or more of the following: the overall waveform of a series of beats, a single beat or segments contained within a beat. The decomposed parts of the cardiac waveform are classified according to types of stress patterns both known in the art and dynamically learned through feedback. When the system detects that a sufficient threshold of stress has been exceeded, a notification can be generated and the details of the stress, such as the severity and type can be communicated to an external module, system, user or host. Patterns indicating a future or rapidly increasing stress level, signaled by evolving patterns in the cardiac waveform can be detected and an alert generated before a major or difficult to control stressful event is externalized by the organism.

It is provided a fastening device for temporarily fastening a portable sensor device to a human body, the fastening device comprising: a device holder for releasably holding a portable sensor device configured to capture electrocardiogram signals and audio signals; a skin sealer configured to form an essentially airtight interface with a human body; and a bellows provided between the skin sealer and the device holder, the bellows, configured to fasten the fastening device to the human body using a suction effect after a portable sensor device held in the device holder is pushed towards the human body to let air escape from the bellows via the skin sealer.

The present invention protects a system for monitoring the vital signs of a user of a disposable absorbent article that comprises a sensor device, a bi-dimensional code and a receiver, such that the sensor device is placed in contact with the user and the system is triggered by the reading of the bi-dimensional code through the receiver, such that the bi-dimensional code is place inside the packaging of the disposable absorbent article.

A biological information measuring apparatus includes a first electrode provided in contact with a user's external auditory canal and a second electrode provided in contact with the user's concha cavum.

On-body analyte sensors may be designed for extended wear to provide ongoing measurement of physiological analyte levels. However, on-body analyte sensors may be susceptible to damage or dislodgment during wear due to routine interactions that occur with one's surroundings. Guard rings may be adapted to protect on-body analyte sensors from such interactions. Guard rings may comprise an annular body comprising an inner perimeter face, an outer perimeter face, a top edge, and a bottom face adapted for contacting a tissue surface. The inner perimeter face is shaped to circumferentially surround a sensor housing of an on-body analyte sensor. At least a portion of the outer perimeter face defines a chamfered surface extending between the top face and the bottom face. Adhesive pads or strips may further be engaged with the guard rings and aid in securing the guard rings to a surface, such as skin.

A mouthpiece for a fitness tracking and/or monitoring system, the mouthpiece comprising a retainer member shaped and configured to be worn, in use, within a user's mouth, the retainer member being formed of at least two layers of elastomeric material having a physiological sensor therebetween.

A non-invasive method and system for monitoring core body temperature (Tc) of a user continuously so as to prevent the risk of over-heating. The system comprises a detection unit to be worn in the user's ear for measuring physiological data of the user by a plurality of sensors and an analysis unit connected to the detection unit via a communication link for computing Tc of the user with a prediction model using the physiological data measured by the detection unit where the effects of heart rate and external environmental temperature on auditory canal temperature of the user are taken into account. The sensors comprise two sensors (207, 208) for measuring auditory canal temperatures and sensors (209, 210) for measuring heart rate and external auricle temperature respectively. The prediction model is preferably a random forest prediction model or a linear or polynomial regression model. An over-heating state of the user is determined when the computed Tc is above a threshold level (e.g. above 40° C.).

A controller corrects a spectrum S (λ) detected at a wavelength λ of signal light to S′ (λ) in accordance with expressions below: I(λ)=(I2−I1)×(λ−λ1)/(λ2−λ1)−I1, and S′(λ)=S(λ)−I(λ), where I1 is the intensity of infrared light detected at a wavelength λ1 of reference light and I2 is the intensity of infrared light detected at a wavelength λ2 of correction light.