A device, system, and methods are provided for remotely monitoring pump equipment. A monitoring device is mechanically mounted to a pump. The monitoring device includes internal vibration, temperature, and location sensors to periodically monitor a pump and upload data samples via cellular connection to a provider network. The monitoring device additionally includes connections to external sensors that can be sampled and uploaded with the other data samples, when the monitoring device is connected to external power. Authenticated users access the pump data though a user device that connects to the provider network.

A wearable device including at least one sensor configured to sense a physiological parameter of a user. The wearable device including a base housing and a removable housing attachable to the base housing. The base housing and the removable housing portions each including a battery and an electronic subsystem in communication with each other. The battery of the removable housing portion charges the battery of the base housing portion when the removable housing portion is attached to the base housing portion. A second embodiment includes two or more fitness trackers each having an enclosure. The enclosures of the two or more fitness trackers having complimentary shapes that form a unified enclosure when the enclosures are placed adjacently. In a third embodiment, a wearable device includes a first screen display and a second screen display. The second screen display is transparent in at least one operational mode of the wearable device.

An insertable cardiac monitor (ICM) with induction-based recharging capabilities and a transmitting coil for recharging the same are disclosed. The length of the monitoring performed by the ICM is extended and the functionality of the ICM enhanced, by including an internal energy harvesting module that allows for charging the ICM at a high speed without burning the patient or overheating components of the ICM. Internally, the energy harvesting module includes at least two overlapping receiving coils that are spaced to be orthogonal to each other and that have a tilt angle of substantially 45°. Such overlapping wire combination allows to minimize mutual inductance of the solenoid coils and increase the rate at which energy can be provided to the energy harvesting module. Further, the rate at which the energy is transmitted from the outside can be increased by defining in a transmitting coil a substantially triangular gap.

An electronic device and a method for controlling the same are provided. The electronic device includes a communicator including circuitry, a first sensor configured to detect movement information of the electronic device, a memory including a first determination module configured to determine whether a user carries the electronic device and a second determination module configured to determine a detecting method for detecting a user location, and a processor configured to identify whether a user of the electronic device carries the electronic device based on the movement information of the electronic device obtained by the first sensor by using the first determination module, and determine a detecting method for detecting location information of the user according to whether the user carries the electronic device by using the second determination module.

An electronic device is provided. The electronic device includes a housing including a portion of a conductive portion, a display visually exposed to an outside through a portion of the housing, a communication circuit electrically connected to the conductive portion, a sensor electrically connected to the conductive portion, a first blocking circuit connected between the conductive portion and the communication circuit and configured to block a signal in a first frequency range, a second blocking circuit connected between the conductive portion and the sensor to block a signal in a second frequency range, and a processor operatively connected to the display, the communication circuit and the sensor, wherein the conductive portion is configured to operate as an antenna of the communication circuit and a biometric electrode of the sensor.

A patient communication system having a medical sensing device operable to collect medical data, a network communication module operable to transmit the medical data onto a data network, a controller operable route the first medical sensing data to the network communication module, and a power source operable to provide power to the first medical sensing device, the controller, and the network communication module.

Provided herein are compositions for the ingestible administration of lisinopril. In some embodiments the compositions comprise lisinopril and silicon. In some embodiments, the compositions comprise lisinopril, silicon, magnesium metal, and copper (I) chloride. Also provided herein are apparatuses comprising the compositions provided herein. Also provided herein are methods for using the compositions and apparatuses provided herein.

A method for operating a medical device includes activating a processor that receives electrical power from a battery in the medical device, measuring a temperature within a housing of the medical device, identifying a low battery voltage threshold based on the temperature, measuring a first voltage level of the battery, commencing an operation sequence after measuring the first voltage level of the battery, generating a plurality of voltage comparisons between a reference voltage level and a voltage level delivered from the battery during the operation sequence, and generating, an output indicating a low battery condition if at least one of the first voltage level of the battery is less than the low battery voltage threshold and above a predetermined minimum operating voltage threshold, or at least one voltage comparison indicating the voltage level of the battery is less than the reference voltage level during the operation sequence.

An aspect of the present disclosure is a biosensor information collection system S including: a biosensor terminal 1-N that is to be attached to a living body and outputs sensor information on the living body; a hub terminal 2 that is to be attached to the living body and collects the sensor information on the living body, the biosensor terminal 1-N and the hub terminal 2 performing communication therebetween near a surface of the living body, the hub terminal 2 including: a reception intensity determination unit 26 that determines whether a reception intensity from the biosensor terminal 1-N coincides with a predetermined intensity with an allowable margin or deviates from the predetermined intensity beyond the allowable margin; and a sensor information request unit 25 that requests the sensor information on the living body of the biosensor terminal 1-N when the reception intensity from the biosensor terminal 1-N coincides with the predetermined intensity with the allowable margin and suspends the request for the sensor information on the living body of the biosensor terminal 1-N when the reception intensity from the biosensor terminal 1-N deviates from the predetermined intensity beyond the allowable margin.

An assembly for enabling a caregiver to secure a physiological monitoring device to an arm of a user can include the physiological monitoring device a cradle configured to removably secure to the physiological monitoring device and to the user's arm. The physiological monitoring device can include a first connector port configured to electrically connect to a first cable and a first locking tab movable between an extended position and a retracted position. The cradle can include a base, first and second sidewalls, a back wall connected to the base and the first and second sidewalls. The cradle can further include a first opening in the back wall configured to receive the first connector port and a second opening in the first sidewall configured to receive the first locking tab when the physiological monitoring device is secured to the cradle and the first locking tab is in the extended position.