The present invention relates to an electrocardiogram analysis matching support service system that supports timely and real-time analysis of an individual's electrocardiogram, and it is characterized in that it includes: a patient service app module that is installed and executed in a patient's mobile communication terminal, transmits an electrocardiogram measurement data received from a wearable electrocardiogram measurement device, requests for reading, and receives and displays the result of the reading; and a patient and medical staff matching server that reads the electrocardiogram measurement data transmitted from the patient service app module using a deep learning trained artificial intelligence network model, selects pre-registered medical staff according to the result of the reading, and supports reading the electrocardiogram measurement data.

A medical device system. The system includes a first medical device, a first remote interface, and a second remote interface in communication with the first remote interface and the first medical device, wherein the first medical device sends a command to the first medical device through the second remote interface, and wherein when the second remote interface receives the command, the command must be confirmed by the second remote interface before the command is send by the second remote interface to the first medical device.

A medical device system. The system includes a first medical device, a first remote interface, and a second remote interface in communication with the first remote interface and the first medical device, wherein the first medical device sends a command to the first medical device through the second remote interface, and wherein when the second remote interface receives the command, the command must be confirmed by the second remote interface before the command is send by the second remote interface to the first medical device.

A method and system for connecting, capturing, managing and predicting outcomes for an improved care for home based patients by collecting data from caregivers and home-based patients. The method and system implemented as a mobile technology is more efficient and effective method for delivering healthcare that will ease the caregiving burden. Providing resources and information to communicate, capture and deliver by the caregivers (formal and informal), patients and healthcare providers communicate helps integrate essential data and care. Through the use of this mobile technology and associated devices vital information from informal caregivers, which is currently not regularly used in remotely located patients, can be captured and implemented in the decisions and adjustments to patients' care plans. In addition, the technology helps with adherence of patient specific treatment guidelines for home-based patients.

A method and system for connecting, capturing, managing and predicting outcomes for an improved care for home based patients by collecting data from caregivers and home-based patients. The method and system implemented as a mobile technology is more efficient and effective method for delivering healthcare that will ease the caregiving burden. Providing resources and information to communicate, capture and deliver by the caregivers (formal and informal), patients and healthcare providers communicate helps integrate essential data and care. Through the use of this mobile technology and associated devices vital information from informal caregivers, which is currently not regularly used in remotely located patients, can be captured and implemented in the decisions and adjustments to patients' care plans. In addition, the technology helps with adherence of patient specific treatment guidelines for home-based patients.

Provided is a process, including: obtaining geographic regions and geolocations that are places of interest within those geographic regions; obtaining first data about at least some of the plurality of geolocations, wherein the first data is not pathogen specific; obtaining second data about at least some of the plurality of geolocations, wherein the second data is pathogen-specific; determining geolocation-pathogen-risk scores of the geographic regions based on both the first data and the second data; determining geolocation-pathogen-risk scores of the places of interest with a machine learning model trained to allocate risk of geographic regions to places of interest based on at least some of the first data.

Provided is a process, including: obtaining geographic regions and geolocations that are places of interest within those geographic regions; obtaining first data about at least some of the plurality of geolocations, wherein the first data is not pathogen specific; obtaining second data about at least some of the plurality of geolocations, wherein the second data is pathogen-specific; determining geolocation-pathogen-risk scores of the geographic regions based on both the first data and the second data; determining geolocation-pathogen-risk scores of the places of interest with a machine learning model trained to allocate risk of geographic regions to places of interest based on at least some of the first data.

The present disclosure provides a medical system and devices useable to perform a medical procedure such as an ocular surgery on one or more patients. The medical system includes a camera and a microscope operable to capture surgical images of the portion of the patient subject to the procedure. The medical system is structured to receive the image of the machine-readable information attached to the patient from the camera, decrypt the machine-readable information to identify the patient and retrieve an indication of a scheduled medical procedure for the patient, receive an input from a user of the medical system via a user interface that indicates a planned procedure step of an intended medical procedure using the medical system, determine that the scheduled medical procedure includes the planned procedure step and, in response, activate the microscope such that the surgical images acquired via the microscope are presented on a display.

The present invention relates to a meal service management system and an operating method therefor, the system being capable of providing information on food ingested by a user to whom a meal service is to be provided and customized information related thereto, and managing food leftover in a meal service. According to an embodiment of the present invention, a scanner device is used such that a user to whom a meal service is to be provided and a food tray before and after meals are identified, and thus a meal service amount and a leftovers food amount are acquired, and leftovers food information of each user and useful information associated therewith are provided on the basis of the same, and thus users can easily determine their eating habits, nutritional status and the like and the users can be induced to attempt reducing leftovers food by themselves.

A cardiac health assessment system includes a memory, a circuit board, and a touchscreen controller integrated into a handheld electronic device (HED). The memory stores a classification model, a regression model, and instructions about a cardiac monitoring application. The circuit board includes a microphonic sensor, an Inertial Measurement Unit (IMU) sensor, a camera sensor, and a processor. The microphonic sensor captures cardiac sound wave signals indicative of the cardiac health of a user. The IMU sensor captures seismic signals indicative of the cardiac health of the user. The camera sensor enables visual data collection of tissue and photoplethysmography. The processor is configured to: execute the instructions, display commands to position the HED against the chest of the user, detect abnormal heart activity by deploying the classification model, and estimate intracardiac pressure by deploying the regression model. The touchscreen controller displays cardiac diagnostic information.