FR3008300A1 - DEVICE FOR MONITORING A PHYSIOLOGICAL CONDITION AND ALERT THROUGH AN INTELLIGENT CLOTHING WITH INTEGRATED BIOMETRIC SENSORS, AN APPLICATION AND A CLOUD SYSTEM - Google Patents

Abstract

An intelligent device for monitoring a physiological condition by minimizing false alerts. The system would be more reliable at a lower cost and with intervention support compared to current systems. The device consists of a smart garment with integrated sensors (1) that communicates to an application installed on a remote device (2). The application performs custom processing of data received from different sensors, analyzes the status of the individual and can trigger an alert and then sends the data to a cloud for archiving. In the cloud, state changes are analyzed by individual and population to update the application. The application can trigger an active system with the monitored individual in case of emergency. The device according to the invention is particularly intended for the surveillance of children at risk of seizures.

Description

The present invention relates to the field of monitoring a physiological state and comprises a device for monitoring and monitoring a physiological state through a smart garment with integrated biometric sensors, an application operating on a connected remote device. intelligent clothing, the application of the remote device itself being connected to a cloud computing system hereinafter called cloud. Although physician recommendations over the last decade 10 have led to a significant reduction in deaths, in most developed countries, sudden infant death remains the leading cause of death in young children (age 0-12 months). . Current surveillance systems are not effective. Some systems are disconnected during the movements of the child, others 15 trigger many false alarms because of trigger thresholds prefixed. Finally most are mono-sensor and are not able to communicate to other systems. Epilepsy is also a major problem in developed countries. In France, nearly 500,000 people have epilepsy, half of whom are under 20 years of age. Surveillance systems exist but are difficult to obtain because of their high cost (about 17,000e for an EG), but one in 1,000 epileptic persons suddenly dies (Sudden Death in Epilepsy or SUDEP) and this figure is one per fifty in people with drug-resistant epilepsy. The device of the invention is a monitoring system that is easy to put on but does not easily remove using nested sensors in a smart garment. The device of the invention is also an intelligent and adaptive monitoring system which uses an application exploiting the computing capacity of an existing remote device such as a smartphone, a tablet or a laptop. The device of the invention is also a communicating system that uses the communication capabilities of the remote apparatus to communicate information to other systems. The device of the invention is also a system that can be deployed anywhere an Internet connection is available without significant infrastructure facility and consulted by others to better understand the physiological state of an individual or a physiological state in using cloud systems. Finally, the device of the invention is a system that facilitates intervention with a supervised individual by having a system that can re-buckle towards the individual equipped with an active system. Figure 1 is a block diagram of the system with the three main elements. Figure 2 is an example block diagram showing how smart clothing retrieves and communicates information. Figure 3 is an example of sudden death monitoring. 4 is an example of monitoring of epilepsy Figure 5 is an example of oxygen monitoring in blood Figure 6 is an example of using analytics tools on the cloud system invention is the assembly of three main elements. The first element is an intelligent garment comprising one or more clothing elements each comprising one or more biometric or environmental sensors. These sensors are connected via a polyurethane fabric in which copper circuits are integrated into a microprocessor that transforms the recovered analog signal into a digital signal. The digital information is then sent to a transmitter, such as a Bluetooth transmitter to communicate with the remote device such as a smartphone (smartphone): The second element is a software application installed on a remote electronic system such as a smartphone (smartphone ), a tablet pc, a phablette, a laptop, a pda, a computer, a GPS device. The application is coded and developed for a device-specific operating system. The user installs the application on his remote device. The user logs on to the application and selects the launch parameters of the monitoring system for a given physiological state for a given user. The application retrieves information from the smart garment, analyzes it and combines it to know if the physiological condition being monitored is normal. The analysis is done according to an algorithm defined in the application. If the levels observed are abnormal the application triggers an alert. The application sends the information collected from the smart garment via the Internet to a cloud system. The third element is the cloud system. It is a computer system using a network of remote servers connected to the Internet that archive, manage and process data. -3- This system is accessible from any platform that can connect to the Internet by authorized users. This system collects the information sent by the application running on the remote electronic device such as the smart phone. Once the information is stored in databases, an analytic system allows users to access a better understanding of the evolution of a physiological state in an individual or group of individuals using reports produced from data. The user can also use queries, dashboards or search and data organization systems to better analyze the data. Following a better understanding of a state, it is possible to update the application from the cloud to better monitor an individual or a population.

The communication between the smart garment and the application on the remote system and between the application and the cloud system can be directional, bi-directional, active, passive, synchronous or asynchronous and can be done by Bluetooth, Wifi, radio waves, cable, GSM system.

As the communications can be done in both directions, the system can also include an active element in the smart suit such as a vibrator that can be triggered by the application to attend the emergency in case of an alert. In one of the applications of the system, smart clothing is a baby pajamas in which sensors are integrated to monitor sudden infant death. A parent or guardian who wishes to monitor the infant dresses the child with the pajamas. Due to the nature of the garment the infant should not get rid of the sensors by moving. The parent or guardian must pair the garment and a smart phone (smartphone) on which the application is installed. He connects to the application and chooses what he wants to monitor. The application is based on the parameters related to the monitored individual, history and information collected from the cloud to choose the most suitable algorithm to have reliable results and avoid false alerts. If an alert is triggered the system loops back to the monitored individual and will trigger a vibrating system on in a smart sock to try to wake the child (young children being particularly sensitive to the soles of the feet).

In another application, a parent-licensed pediatrician logs in to the cloud system and uses the generated reports with the information collected on the child over several nights of supervision to see if the child is often having sleep apnea and adjust the alarm thresholds as much as possible. -4- In a third application, a health professional can connect to the cloud system and use the wide anonymous data (big data) collected on all individuals monitored. By using indexed databases, research tools and analytical systems, he can try to better understand how a physiological state develops in a group of individuals. This group can be determined by geographic proximity, age group, family history for example. This information is then injected into the system to improve the monitoring of individuals belonging to this group. More particularly, the invention relates to a device for monitoring a physiological state of an individual such as sleep apnea, sudden infant death, epilepsy, respiratory disorders, cardiovascular diseases, cardiovascular disorders, sleep disorders which is characterized in that it comprises a smart garment with integrated biometric sensors configurable to connect to an application that operates on a remote electronic device (1), the application that operates on a remote electronic device being configured to retrieve information from the smart garment, analyze the received information based on the characteristics of the individual, adapt and respond automatically according to the history of data received or entered manually, trigger alarms when certain thresholds are attained, securely communicating to a cloud system (2); a cloud system that is a computer system using a network of remote servers connected to the Internet to archive, manage, process received data, allow access to remote monitoring through multiple interfaces, update the application on a remote device, transmitting information to a third-party system via telecommunication networks, generating reports for users or health professionals (3). Alarms that can be emitted include making a loud sound, sending information to a third-party system, calling a third-party system, displaying information to help with the intervention, displaying lights, flashing. The smart garment (1) consists of one or more fabric garments including stretchable electronic systems, biometric and environmental sensors, polyurethane and copper stretchable printed circuits, rigid circuits, a microprocessor coupled to an analog-to-analog signal converter. digital, a method of extracting key biological information from the signal received from the sensors, the analog processing circuit with amplifiers and filters that format the analog signal from the sensors into a signal at the appropriate voltage, a transmitter , integrated biometric sensors, batteries and possibly a battery charging system with electronic circuits capable of charging a battery adequately by recovering the energy of a cable or inductive source from a specific charger. Biometric and environmental sensors include an electronic thermometer, a heart rate sensor, a respiration sensor, a blood pressure sensor, an electrocardiograph sensor, an electronic balance, electroencephalogram electrodes, electromyogram sensors, motion sensors, position sensors, a GPS positioning system, carbon dioxide sensors, a microphone.

The application running on the remote device (2) can identify and connect with a specific element of the smart garment and exchange data, can identify a specific user, display a specific interface according to the user and load a digital environment specific according to this identification, the identification of the user can be linked to the device or be made directly in the software application, the software application can display information on the device or issue sound information to assist the emergency response, the software application can send data to the cloud system via the communication system of the remote device. This data may be pure data coming from the smart garment, processed data or data not coming from the smart garment but from the remote device itself, the data coming from the remote device itself include information entered by the user, information from the capabilities of the device such as video, sound, photos or data. The cloud system (3) can identify a specific user, display a specific interface according to the user and load a specific digital environment according to this identification, the specific environment includes among others specific databases, sets of specific data, specific reports, specific data mining tools, specific indexed search systems, can receive data from all users through remote devices, can archive data and organize them among others by date , time, type of sensor and user, can contain an interface that allows the adjustment of parameters on a remote device for a specific user, such as the type of alarm, trigger thresholds, user parameters, sounds emitted, called numbers, algorithms, type of reaction, reaction programs, can update the application on a remote device. A method of tracking a physiological condition of an individual on the remote device (2) comprises the steps of connecting to an application installed on a remote device, identifying an individual and identifying the type of state it wishes to monitor, pairing a smart garment with a remote device, starting the data transmission of one or more sensors of the smart garment (I) to the remote device (2) using a microprocessor and a transmitter, retrieval of data received on the remote device, the triggering of software response based on the collected information that can generate an alarm and trigger an active system, sending data from the application on the remote device to a cloud system (3). A method for analyzing a physiological state on the cloud (3) comprises the steps of logging on to the cloud system (3), identifying a specific individual or a group of individuals to follow, starting a specific analysis tool, update the application on the remote device. The analysis of the physiological state includes the analysis of the state itself, the comparison of the state of an individual with the same condition in other individuals of the same sex, of the same age group of the same origin, of the same way of life, of the same region, of the same family history, of the same medical history, of the same treatment, of the same state of sleep of the same activity, of the same diet, of the same period of the year , of the same climate, of the same environment, the analysis of the evolution of a state in time, the analysis of the evolution of a state in a given geographical area, the analysis of the evolution of a state in a given population, updating the application on the remote device (2) to take into account the analysis on a given population or individual. The specific analysis tool is based on an indexed database and on which it is possible to carry out research, it includes data mining tools, analysis tools, query tools, analytics tools. health, reports, real-time views of information from sensors, dashboards, research tools. a method of activating an active system includes activation of an electric shock system, a vibrating system, a mechanical mechanism, a buzzer on the smart garment (1) following a manual user action on the cloud (3), a manual action on the application of the remote device (2), an automatic action on the cloud (3) or the application of the remote system based on reaching a limit, an interval statistic, of an adaptive limit, of a series of limits in a given order, of a specific algorithm, a combination of factors, a fixed limit, a calculated limit.

Individual parameter settings or grouping parameters for analysis include age, weight, height, gender, environmental conditions, date, time, season, family history, diet, family situation, health check, genetic predispositions, medical recommendations.

Claims (5)

CLAIMS 1) Device for monitoring a physiological state of an individual such as sleep apnea, sudden infant death, epilepsy, respiratory disorders, cardiovascular diseases, cardiovascular disorders, sleep disorders, characterized in that it comprises: A - A smart suit with integrated biometric sensors configurable to connect to an application that operates on a remote electronic device (1) B - A remote electronic device on which an application configured for retrieve information from the smart garment, analyze the received information based on the characteristics of the individual, adapt and respond automatically according to the history of the data received or entered manually, trigger alarms when certain thresholds are achieved, communicate securely to a cloud system (2); C- A cloud-like computer system (2) which is a computer system using a network of remote servers connected to the Internet to archive, manage, process the received data, allow access to remote monitoring through multiple interfaces , update the application on a remote device, transmit information to a third party system via telecommunication networks, generate reports for users or health professionals (3). 2) Device according to claim 1 characterized in that the alarms consist of means for emitting a loud sound, send information to a third party system, call a third party system, display information to assist the intervention, display lights, 30 flash. 3) Device according to claim 1, characterized in that the smart garment (1) consists of one or more fabric garments comprising stretchable electronic systems, biometric and environmental sensors, stretchable polyurethane and copper printed circuits, rigid circuits, a microprocessor coupled to an analog to digital signal converter, analog processing circuits with amplifiers and filters which format the analog signal from the sensors into a signal at the appropriate voltage, a transmitter, integrated biometric sensors 40, batteries and possibly a battery charging system.-9- 4) Device according to claim 3, characterized in that the biometric and environmental sensors are selected from an electronic thermometer, a heart rate sensor, a respiration sensor, a blood pressure sensor, an electrocardiogram sensor, an electronic scale. , electroencephalogram electrodes, electromyogram sensors, motion sensors, position sensors, GPS positioning system, carbon dioxide sensors, microphone. 5) Device according to one of the preceding claims characterized in that it further comprises an activation system intelligent trigger selected from an electric shock system, a vibrating system, a mechanical mechanism, a buzzer on the intelligent clothing that acts on the person who wears the smart garment, including waking or applying medical treatment.