The present invention provides an electroencephalogram measurement structure formed by an ear-hanging structure and a second circuit board. The ear-hanging structure includes a body. An ear-hanging member is disposed at the extension of the body. The body can be worn on the ear via the ear-hanging member. In addition, a first reference electrode and a second reference electrode are disposed on the body and coupled to a first circuit board. The first circuit board is coupled to an electrical jack; the second circuit board is coupled to the electrical jack via an electrical plug. Thereby, the electroencephalogram measurement can be performed simply by wearing the ear-hanging member on the ear of the person under test. Hence, the problems of complicated wiring and inconvenience in wearing can be solved concurrently.

A temperature sensing patch that is easy to use and capable of efficiently monitoring temperature change in human, body for a long time, capable of being used with a reading device, comprising the temperature sensing patch configured to attach to human skin, comprising a housing, a circuit board, a temperature sensing unit electrically connected with the circuit board, a battery, a processor chip, at least a memory unit, and at least a port; wherein the processor chip can automatically turn on the temperature sensing patch and reset the previous data by a predetermined program, rather than through a manual switch, when the temperature sensing patch is removed from the reading device.

The enclosed describes a sensor pad for wearing on a human body. The sensor pad is configured to be in contact with a substrate having a contoured surface, such as a surface of the body. The sensor pad comprises at least a sensor layer and a stiffener layer. The sensor layer comprises a surface area defining a sensing area configured to measure value at a plurality of locations of the sensing area. The stiffener layer is couples to the surface area of the sensor layer. The stiffener layer has a micro-cut pattern to reduce mechanical resistance of the stiffener layer. The micro-cut pattern facilitates the stiffener layer in stretching or compressing in one or more predefined directions, enabling the stiffener lay to conform to the contoured surface of the substrate.

Glucose monitoring devices and related systems and methods, the glucose monitoring devices including a sensor electronics unit having a housing and a printed circuit board disposed within the housing, a transcutaneous glucose sensor assembly, and a conductive sensor connector. The printed circuit board includes a first electrical contact, the transcutaneous glucose sensor assembly includes a distal portion having a working electrode and proximal portion having a working-electrode contact in electrical communication with the working electrode, and the conductive sensor connector electrically connects the working-electrode contact with the first electrical contact. Further, the conductive sensor connector extends through a hole in the proximal portion of the transcutaneous glucose sensor assembly and through a hole in the printed circuit board.

A system for electrically coupling a garment to a mating object and manufacture method thereof, the system comprising: a fabric interlayer of the garment including a set of ports; an electronics substrate having a first surface adjacent to a second side of the fabric interlayer and including a set of vias through a thickness of the electronics substrate, aligned with the set of ports, and a set of contacts at a second surface opposing the first surface; a mount assembly having a third surface adjacent to the second surface of the electronics substrate and including a set of holes aligned with the set of vias and the set of ports, as well as a set of openings that correspond to and receive portions of the set of contacts, and a fourth surface opposing the third surface and defining a cavity configured to receive and electrically interface the mating object to the electronics substrate; and a set of fasteners that 1) compress the backing plate, the fabric interlayer, the electronics substrate, and the mount assembly by way of the set of ports, the set of vias, and the set of holes in supporting a waterproof seal, and 2) electrically couple the set of embedded ports to the set of vias.

Disclosed is a method for remote presence detection and remote behavioral analysis of an individual in a living area, including furnishing detection data by a presence detection unit during the detection of the individual in at least one detection zone covered by the detection unit, the transmission of data by the detection unit to an electronic data acquisition module, remote sending of data, from the electronic data acquisition module via a communication unit, to a remote data processing unit for automatically generating at least one piece of information, with the remote data processing unit being associated with at least one software application that can automatically generate one or more pieces of information relative to the fall of an individual from a standing, seated or lying-down position, and/or relative to the behavior of an individual in the detection zone or zones in particular to deduce therefrom one or more behavioral anomalies.

A connector block that permits simultaneous and continuous interconnection of the three leads of the epicardial pacing wires, the pacemaker, and the ECG monitor on clear separately labeled connectors is provided. Circuitry is provided that allows the display of epicardial signals on the telemetry unit, while still preserving the ability to pace the heart from the pacemaker. When pacing the connector block prevents excessive loading of the pacer signals by the ECG monitor and/or damage to the monitor by the high-voltage pacer signals. The connector block may be used universally on all monitors without the need for sophisticated understanding of the electrical characteristics of the ECG monitor or concern for damage or improper signal loading.

An invasive medical device assembly includes an invasive medical device and a hub housing configured to surround a portion of the invasive medical device. The invasive medical device may be a needle or other invasive medical device, and the hub housing may be configured to surround a hub of the invasive medical device. In one aspect, the invasive medical device may include a transducer. The hub housing can include at least one integrated circuit embedded therein that is configured to contact the external surface of the needle to electrically connect the transducer to a power source. The hub housing can be configured to provide an ergonomic handle for a user.

The invention discloses a sleep quality monitoring system for the middle-aged and the elderly. The sleep quality monitoring system for the middle-aged and the elderly detects the sleep quality of the middle-aged and the elderly by a power socket A, an adapter A, a mobile phone APP, a cloud server, a bedside lamp, a power socket B, an adapter B, a transceiver controller, a humidity sensor, a temperature sensor, a pressure sensor, a heating pad, a signal collecting unit, a processor transmitting signal unit, a humidity sensing unit, a temperature sensing unit, an alarm unit, a preheating unit, a heating unit and a signal receiving processing unit.

A device includes a digit probe, a plurality of optical elements, a processor, and a communication module. The digit probe has an interior surface and has an exterior surface. The interior surface is configured to engage a digit and the exterior surface is configured to engage a tissue site associated with the digit. The plurality of optical elements is coupled to at least one of the interior surface and the exterior surface, The plurality of optical elements includes at least one emitter and includes at least one detector. The processor is coupled to the plurality of optical elements. The processor is configured to generate a measure of arterial oxygenation corresponding to the digit and configured to generate a measure of regional oxygenation corresponding to the tissue site. The communication module is coupled to the processor. The communication module is configured to communicate the measure of arterial oxygenation and regional oxygenation with a remote device.