KR102309022B1 - Artificial intelligence-based bio-signal remote monitoring system - Google Patents

Abstract

The present invention relates to an artificial intelligence-based bio-signal remote monitoring system, which enables real-time monitoring of received multiple bio-signals, requests reading to deep learning artificial intelligence through a heart disease analysis server and a prognosis analysis server to analyze the heart disease or prognosis, sends an alarm message to a monitor system of a hospital and mobile terminals of medical staff and patients when a preset alarm threshold is exceeded, and remotely sets the type or measurement period of the bio-signal of multiple bio-signal measuring devices manually or automatically depending on the severity or prognosis of the patient.

Description

AI-based biosignal remote monitoring system {ARTIFICIAL INTELLIGENCE-BASED BIO-SIGNAL REMOTE MONITORING SYSTEM}

The present invention relates to an artificial intelligence-based bio-signal remote monitoring device using a multi-biometric signal measuring device that can be directly worn by a user.

Recently, various biosensor technologies for measuring biosignals are becoming more sophisticated and miniaturized. In addition, the development of communication technology that can transmit data at high speed, the development of indoor and outdoor positioning technology, and medical devices that utilize accumulated hospital records and biometric information for analysis and diagnosis through artificial intelligence using big data are emerging. .

However, in the case of a patient monitoring device currently being used in hospitals, it is a fixed type and complicated function, so it is possible to use and analyze only by professional personnel with the relevant knowledge.

Therefore, in the present invention, by using such small sensor technology, communication technology, and artificial intelligence technology, it is possible to easily and remotely measure biometric information consciously and invisibly, and to monitor and respond to abnormalities through measurement data. It relates to a device and an artificial intelligence-based remote monitoring system using the same.

Republic of Korea Patent Registration No. 10-2210242 (2021.01.26) Republic of Korea Patent Registration No. 10-2210215 (2021.01.26.) Republic of Korea Patent Registration No. 10-2197112 (2020.12.31.) Republic of Korea Patent Registration No. 10-2208759 (2021.01.22.)

By measuring the patient's current biometric data, it is possible to judge the current severity of the patient or the prognosis after treatment. In general, in a medical institution, a nurse periodically measures a patient's blood pressure, pulse, body temperature, electrocardiogram, oxygen saturation, etc. to measure biometric data, and writes the measured values by hand. Nursing personnel and professional examination personnel are required to measure a patient's biometric data, and it takes a lot of time to measure and analyze biometric data. .

In addition, in the case of some biometric data, for example, in the case of an electrocardiogram for determining whether or not a heart disease is present, there is a shortage of specialists for reading the electrocardiogram data except in large hospitals, which takes a lot of time to read and analyze the data.

It is essential to check vital signs (blood pressure, pulse, respiration rate, body temperature) at various sites such as the waiting room and emergency room of a hospital, emergency room, screening clinic, life treatment center/isolation facility, infectious disease prevention site, and medical blind spot. Oxygen saturation and electrocardiography are additionally required for severe or semi-severe patients.

New infectious diseases, for example, MERS and Corona Virus Infectious Diseases (COVID-19) are spreading around the world. Due to the spread of infectious diseases, the fatigue of medical workers has reached an extreme, and there is a serious shortage of medical devices. In such a situation, repeated examination of biometric data is highly likely to cause fatigue accumulation of medical staff and exposure to infection.

Patient monitors, which are currently widely used in hospitals, are of a fixed type, so they are too large and heavy, difficult to carry, and expensive, so there are many restrictions on their use. In the case of hospitalized patients, it is difficult to measure even if they leave the ward for a while, and in particular, for post-discharge patients who need prognostic monitoring, it is necessary to measure and perform diagnosis only through a return visit to the hospital, which causes a lot of inconvenience.

Therefore, the present invention solves these problems in the prior art and can measure multiple bio-signals in a wearable form consciously or invisibly in a wearable form not only for hospitalized patients but also for discharged patients who need prognostic management, and can remotely and in real-time monitor the abnormal situation. It relates to a remote monitoring system using a wearable multi-biometric signal measuring device having a function of generating an alarm when this is detected so that an immediate response is made.

The wearable multi-biometric signal measuring device according to the present invention is worn by inpatients and discharged patients individually, so that multiple bio-signals are measured and transmitted to remote monitoring, either consciously or invisibly, so that changes in bio-signals of the patient can be monitored in real time. However, it is possible to acquire and monitor high-quality bio-signals for patients in hospital or after discharge by selectively extending and wearing the external high-precision sensor according to symptoms or severity.

The wearable multi-biometric signal measuring device according to the present invention enables the remote monitoring system to automatically or manually control the sensor or the measurement cycle of the wearable multiple bio-signal measuring device, thereby enabling customized biometric information measurement according to the patient's condition.

In the remote monitoring system according to the present invention, when a risk is detected or deviating from a normal standard value through a prognosis prediction analysis server through multiple biometric information as well as a heart disease analysis result through an artificial intelligence ECG analysis server and a medical history of a hospital information system, an alarm and provides a biosignal remote monitoring system that transmits an alarm signal to medical staff or patients.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

delete

delete

The biosignal remote monitoring system according to an embodiment of the present invention is connected to the wearable multiple biosignal measuring device through a wireless gateway. When the remote monitoring system transmits a biosignal measurement profile message to the wearable multiple biosignal measuring device, the wearable multiple biosignal measuring device performs multiple biosignal measurement according to the sensor type, period, and quarantine range according to the content of the biosignal measuring profile message. It transmits information and quarantine area departure information to the remote monitoring system through the gateway.

The remote monitoring system It enables real-time monitoring of multiple received bio-signals and requests to be read with deep learning artificial intelligence through the heart disease analysis server and prognostic analysis server to perform heart disease or prognosis analysis. and send an alarm message to the mobile terminal of medical staff and patients.
The remote monitoring system Depending on the severity or prognosis of the patient, the type or measurement period of the biosignal of the multi-biosignal measuring device may be remotely set manually or automatically.

The present invention can measure multiple biosignals in an unconscious state using a wearable multiple biosignal measuring device provided to a severely hospitalized patient or an individual discharged patient who needs prognostic management, and allows the patient to measure the biosignal needed by himself/herself. In addition, the remote monitoring system is connected to the wearable multi-biometric signal measuring device through a wireless communication network to continuously monitor the multiple bio-signals received from the wearable multiple bio-signal measuring device in real time. For discharged patients who can monitor and need prognostic management, remote prognosis management is possible without visiting a hospital.

The present invention can significantly reduce the fatigue of medical personnel who have to periodically repeat the four vital signs (blood pressure, pulse, respiration rate, body temperature) tests for general patients, and oxygen saturation and ECG tests for severe or semi-severe patients. Not only that, but by minimizing contact between patients and medical personnel, the risk of infections such as MERS and COVID-19 can be minimized.

The present invention can improve nursing work through automation of multiple biosignal measurement and recording tasks for inpatient and discharged patients.

Since the present invention enables remote monitoring of discharged patients, it is possible to reduce the number of hospital visits, thereby providing an effect of reducing time and cost and preventing secondary infection of infectious diseases.

The remote monitoring system of the present invention allows the medical staff to use an external high-precision sensor or to change the measurement sensor or cycle automatically or manually in continuously remote monitoring the basic biosignal status and changes of inpatients and discharged patients. Close monitoring tailored to the patient is possible.

The remote monitoring system of the present invention generates an alarm in the monitor system terminal when the alarm threshold is exceeded for each patient/biological data and sends alarm information to the medical staff in charge and the on-call doctor. Immediate response is possible.

The remote monitoring system of the present invention can provide services such as identifying the patient's sleep state, exercise amount inquiry, fall notification, and snoring analysis using a wearable multi-biometric signal measuring device, and in the case of an exercise prescription patient, through exercise information monitoring Various additional services such as being able to inquire whether the patient's treatment efforts are being made normally and whether self-isolation is being followed in real time through the patient's location information, etc. are possible.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a service conceptual diagram for a wearable multi-biometric signal measuring apparatus and a remote monitoring system according to an embodiment of the present invention.
2 is a block diagram showing a hardware configuration of a wearable multi-biometric signal measuring apparatus according to an embodiment of the present invention.
3 is a diagram illustrating a wearable multi-biometric signal measuring apparatus in a band form according to an embodiment of the present invention.
FIG. 4 is a flowchart illustrating a power on sequence immediately after power is applied to the wearable multi-biometric signal measuring apparatus illustrated in FIG. 3 .
5A and 5B are flowcharts illustrating an interrupt service routine according to whether external sensors are connected or not.
6 is a diagram showing the configuration of a remote monitoring system in detail.
7 is a diagram illustrating an AI-based diagnosis algorithm for internal or external ECG data.
8 is a diagram showing the configuration of a prognosis prediction server that informs a prognosis prediction result for a disease by learning multiple bio-signals, heart disease analysis results, and medical history.

Advantages and features of the present invention, and a method for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. The present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and only the embodiments allow the disclosure of the present invention to be complete, and to those of ordinary skill in the art to which the present invention pertains. It is provided to fully understand the scope of the invention, and the present invention is only defined by the scope of the claims.

Since the shapes, sizes, proportions, angles, numbers, etc. disclosed in the drawings for explaining the embodiments of the present invention are exemplary, the present invention is not limited to the matters shown in the drawings. Like reference numerals refer to substantially like elements throughout. In addition, in describing the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In the case where “includes”, “includes”, “haves”, “consists of”, etc. mentioned in this specification are used, other parts may be added unless 'only' is used. When a component is expressed in the singular, it may be construed as the plural unless specifically stated otherwise.

In interpreting the components, it is interpreted as including an error range even if there is no separate explicit description.

In the case of a description of the positional relationship, for example, when the positional relationship between two components is described as 'on One or more other elements may be interposed between those elements in which 'directly' or 'directly' are not used.

1st, 2nd, etc. may be used to distinguish the components, but the functions or structures of these components are not limited to the ordinal number or component name attached to the front of the component.

The following embodiments may be partially or wholly combined or combined with each other, and technically various interlocking and driving are possible. Each embodiment may be implemented independently of each other or may be implemented together in a related relationship.

The wearable multi-biometric signal measuring device according to the present invention enables measurement of various bio-signals such as pulse wave, body temperature, blood pressure, and exercise amount as well as an electrocardiogram, and selectively uses an extended ECG electrode or a high-precision external sensor according to the patient's symptoms or severity. More sophisticated biosignal collection is possible.

In addition, the remote monitoring system automatically sets the sensor or measurement cycle of the wearable multi-biometric information measurement device through the automatic measurement setting function, so that it can receive bio-signals through the gateway, either consciously or involuntarily, to monitor remotely, or to a heart disease analysis server. It is a system that provides real-time alarms through the prognosis prediction analysis server.

Therefore, through the wearable multi-biometric signal measuring device and remote monitoring system according to the present invention, real-time bio-signal monitoring is possible for severely inpatients or discharged patients who need prognostic monitoring, and it is possible to respond immediately when abnormal signals occur, and additionally, a patient's fall , it is possible to check the amount of sleep, sleep apnea, exercise amount, etc.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a service concept diagram for a wearable multi-biometric signal measuring apparatus 1000 and a remote monitoring system 2000 according to an embodiment of the present invention.

Referring to FIG. 1 , the present invention may provide a wearable multi-biometric signal measuring apparatus 1000 to a severely hospitalized patient or a discharged patient who needs prognostic management. The wearable multi-biometric signal measuring device 1000 consciously or unconsciously measures bio-signals or location information such as blood pressure, heart rate, respiration rate, body temperature, electrocardiogram, oxygen saturation, and exercise amount of a patient, and remotely monitors it through the gateway 4000 . to the system 2000 .

The wearable multi-biometric signal measuring apparatus 1000 operates in a form in which a sensor, a measurement period, and an isolation area range are set according to the content of a biosignal measurement profile message set and transmitted by the remote monitoring system 2000. Measure and transmit the measurement and whether or not the containment site has escaped.

In the remote monitoring system 2000, the wearable multi-biometric signal measuring device 1000 is registered to a severely hospitalized patient or discharged patient who needs prognosis monitoring through NFC/RFID reader. In addition, information about the patient is transmitted and recorded in the wearable multi-biometric signal measuring apparatus 1000 .

Thereafter, the remote monitoring system 2000 updates and transmits the multi-signal measurement profile message to the wearable multi-biometric signal measuring apparatus 1000 when changes are required in the measurement of various bio-signals according to the prognosis trend or the request of the medical staff. do.

This multi-signal measurement profile message includes information on the type of biosignal that needs to be measured for each patient, each measurement period and the range of the isolation site. change is possible

The remote monitoring system 2000 may include a heart disease diagnosis server 2200 , a prognosis prediction analysis server 2300 , and a biometric monitoring server 2100 .

The heart disease diagnosis server 2200 receives the electrocardiogram signal from the wearable multi-biometric signal measuring device 1000, and uses information obtained through waveform analysis and learning data obtained through deep learning image learning to diagnose various heart diseases and monitor the body. It is transmitted to the server 2100 .

The prognosis prediction analysis server 2300 is based on the current biometric information based on deep learning of the patient's medical history, disease, treatment and biometric information from the hospital information system (HIS) 3000. One prognostic prediction analysis result is transmitted to the biometric monitoring server 2100 .

The bio-monitoring server 2100 of the remote monitoring system 2000 performs a function of displaying bio-information from the wearable multi-biometric signal measuring device 1000 so that it can be monitored in real time, and this bio-signal is combined with the heart disease analysis server 2200 It is transmitted to the prognosis prediction analysis server (2300).

In addition, the bio-monitoring server 2100 of the remote monitoring system 2000 receives the heart disease analysis result and the prognosis prediction result from the heart disease analysis server 2200 and the prognosis prediction analysis server 2300. Generates an alarm.

These alarms are directly expressed from the bio-monitoring server 2100 of the remote monitoring system 2000 or transmitted to the wearable multi-biometric signal measuring device 1000 worn by medical staff, on-call doctors, and patients to quickly inform the patient of a dangerous situation. can

In addition, the remote monitoring system of the present invention makes it possible to inquire the patient's biometric information measurement history in the medical application or the patient application, and furthermore, each patient's activity amount, sleep time, sleep apnea symptoms, AI-based ECG reading result In addition to providing various diagnostic information such as heart disease prediction information through

The present invention automates repetitive measurement and recording of biometric information for each patient by using a wearable multiple biometric information measuring device 1000 and a remote monitoring system 2000 worn by each patient, and provides real-time monitoring and alarm services for hospital work. It can reduce unnecessary hospital visits for patients who need prognostic management after discharge, dramatically improve nursing work, and prevent secondary infection and spread of infectious diseases.

The remote monitoring system 2000 analyzes the data received from the wearable multi-biometric information measuring device 1000 in real time to monitor each patient's activity amount, sleep, sleep apnea or falls, or to use location information to identify the patient's location Thus, it is possible to provide monitoring services for departures from quarantine areas, etc.

When the wearable multi-biometric signal measuring apparatus 1000 acquires data from an internal or external sensor and transmits it to the remote monitoring system 2000 through the gateway 4000, the biometric monitoring server 2100 of the remote monitoring system 2000 Signal trends can be monitored in real time, and when it is determined that there is an abnormality through the analysis results of the heart disease analysis server 2001 and the prognosis prediction analysis server 2300, an alarm is generated, and the appropriate action is immediately transmitted to the patient as well as the medical staff. tells you you need it

2 is a block diagram showing the hardware configuration of the wearable multi-biometer 1000, the gateway, and the remote monitoring system according to an embodiment of the present invention.

Referring to FIG. 2 , the wearable multi-biometric signal measuring apparatus 1000 includes a sensor control unit 200 connected to built-in sensor units 202 to 210 , a central control unit 100 , a user interface unit 101 , and a positioning receiving unit 301 . ), the first to third wireless communication units (302 to 304), and a power supply unit (500). The wearable multi-biometric signal measuring apparatus 1000 may be detachably connected to external sensors 211 to 213 .

The built-in sensor units 202 to 205 and 209 of the wearable multi-biometric signal measuring apparatus 1000 include one or more built-in sensors 202 to 210 .

The built-in sensor includes a built-in electrocardiogram sensor. The built-in electrocardiogram sensor measures the electrocardiogram for the lead I of the patient through the first and second electrocardiogram electrodes 202 and 203 exposed to the outside of the wearable biomultiple signal measuring apparatus 1000 . The electrocardiogram electrode can be interpreted as an ECG electrode. The first electrocardiogram electrode 202 is a left-hand electrode LA that is in contact with the patient's left hand. The second electrocardiogram electrode 203 is a right hand electrode RA that is in contact with the patient's right hand.

When the patient wears the wearable multi-biometric signal measuring device 1000 , his/her wrist comes into contact with the first electrocardiogram electrode 202 . The first electrocardiogram electrode 202 has two electrode surfaces, which is the same electrode surface connected in a circuit to make a more reliable contact on the wrist during measurement. When the patient touches the finger of the opposite hand to the second electrocardiogram electrode 203 while wearing the wearable multiple biosignal measuring device 1000 , the lead I electrocardiogram signal is transmitted through the built-in electrocardiogram electrodes 202 and 203 . can get

The built-in sensors 204 to 210 of the wearable multi-biometric signal measuring device 1000 include a PPG sensor 204, a respiration rate sensor 205, an acceleration sensor 206, a gyrometer sensor 207, and a barometric pressure sensor. (Barometer 208 ), a body temperature sensor 209 , and a temperature sensor 210 . Built-in sensors are not limited to FIG. 1 , and some sensors may be omitted or added.

When the patient wears the wearable multi-biometric signal measuring device 1000 on the wrist, the PPG sensor 204 uses a light emitting part LED (Light Emitting Diode) and a light receiving part that face the patient's wrist to determine whether the wearable device is worn, pulse wave signals, and oxygen Measure the saturation. Blood pressure may be measured using a PPG signal output from the PPG sensor 204 and an ECG signal measured from the electrocardiogram electrodes 202 and 203 .

The respiration rate sensor 205 measures the respiration rate through the amount of change in the patient's body impedance when the patient wears the wearable multi-biometric signal measuring device 1000 and 1000 on the wrist.

The body temperature sensor 209 measures the patient's skin temperature by irradiating infrared (Infra Red ray) on the patient's forehead with the wearable multi-biometric signal measuring device 1000 .

The acceleration sensor 206 and the gyro sensor 207 recognize a change in the amount of exercise, posture, and sleep state of a patient wearing the wearable multi-biometric signal measuring device 1000 . For example, the remote monitoring system 2000 may detect the state of the patient based on the output signals of the acceleration sensor 206 and the gyro sensor 207 whether the patient is walking, exercising, sleeping, or stationary. and may generate a notification message notifying an emergency situation such as a fall.

The barometric pressure sensor 208 measures the atmospheric pressure level around the patient wearing the wearable multi-biometric signal measuring device 1000 . The temperature sensor 210 measures the temperature of the surrounding environment in which the patient is located.

The sensor control unit 200 converts the signal received from the electrocardiogram electrodes 202 and 203 and the output signal of the sensors 204 to 210 into a sensor value of a digital signal that can be processed by the central control unit 100 and converts it into a sensor value of the central control unit ( 100) is sent. The sensor control unit 200 includes an AFE (Analog Front End).

The AFE 201 is a built-in electrocardiogram measuring unit (hereinafter, “built-in ECG AFE”) that is initialized and driven when the external electrodes/sensors shown in FIGS. 4 and 4A and 4B are not connected to the wearable multi-biometric signal measuring apparatus 1000 . ”), a built-in oxygen saturation measurement unit (hereinafter referred to as “built-in PPG AFE”), and an external ECG measurement unit that is initialized and driven when an external sensor is connected to the wearable multi-biometric signal measurement device 1000 (hereinafter, “ external ECG AFE”) and an external ECG measurement unit (hereinafter referred to as “external PPG AFE”).

The built-in ECG AFE amplifies the analog signal (electrocardiogram measurement signal) received from the built-in ECG electrodes 202 and 203, removes noise, and then converts it into a digital signal through an analog-to-digital converter (A/D converter). The external ECG AFE amplifies an analog signal (ECG measurement signal) received from the external ECG electrodes 221 to 224, removes noise, and then converts it into a digital signal.

The built-in PPG AFE amplifies the output signal (blood flow measurement signal flowing through the blood vessel) generated when the light generated from the LED of the built-in PPG sensor 204 is irradiated to the patient's wrist and converts it into a digital signal after removing noise. do. The external PPG AFE is a digital signal after amplifying the output signal (blood flow measurement signal flowing through the blood vessel) generated when the light generated from the LED of the external PPG sensor 225 is irradiated to the patient's fingertip and removing noise. convert to

The digital signal output from the sensor controller 200 is multi-biometric signal measurement data including electrocardiogram measurement data, oxygen saturation measurement data, and four vital sign measurement data (blood pressure, pulse, respiration rate, and body temperature).

The central control unit 100 may include a microcontroller unit (MCU) for controlling signal processing and input/output, a timer, and a memory.

The central controller 100 controls all components of the wearable multi-biometric signal measuring apparatus 1000 . The central control unit 100 processes the user's input data received through the user interface unit 101 . The central control unit 100 transmits the multi-biometric signal measurement data received from the sensor control unit 200 to the remote monitoring system 2000 through the gateway through the wireless communication units 302 to 304 as shown in FIG. 2 . The central control unit 100 stores data received from the remote monitoring system 2000, for example, message data such as a control command or notification indicating a biosignal measurement cycle, and a diagnosis result derived using an artificial intelligence-based diagnosis algorithm. It may be provided to the data output unit of the user interface unit 101 and displayed on the display. A control command for instructing measurement of a biosignal may be generated from the remote monitoring system 2000 .

The user interface unit 101 is connected to the central control unit 100 . The user interface unit 101 includes a user data input unit and a data output unit. The user data input unit receives a user input through the user data input unit, for example, a button or a touch screen. The data output unit may display the operating state of the wearable multi-biometric signal measuring apparatus 1000 and the patient's biosignal measurement value in real time, and output an alarm signal or a message as an acoustic signal. The biosignal measurement value may be displayed in a preset graph form. The data output unit may include a display implemented as a liquid crystal display (LCD), an organic light-emitting diode display (OLED) display, or the like. In addition, the data output unit may include a speaker that outputs an acoustic signal, a vibration generator, and the like.

The positioning receiving unit 301 receives a position signal of a multi-biometric signal measuring device. The central control unit 100 transmits the location information of the multi-biometric signal measuring device 1000 from the positioning receiving unit 301 to the remote monitoring system 2000 through the wireless communication units 302-304. The location positioning receiver 301 receives location information through GPS when outdoors and indoor-based location information when indoors where GPS is not received. The remote monitoring system 2000 may receive a coordinate signal and monitor the location of the patient in the hospital or the location of the discharged patient in real time. When a smart phone is used as a gateway, location information can be obtained by utilizing the location information of the smart phone, and this can be omitted.

The wireless communication units 302-304 are connected to the central control unit 100 and transmit biosignal measurement signals received from the central control unit 100 to the remote monitoring system 2000 through the gateway 4000 . The first wireless communication unit 302 is a communication unit for the multi-biometric signal measuring device 1000 to access the remote monitoring system 2000 without going through the user's smart phone, for example, via WiFi, NB-IoT, or LTE network. can be configured. The second wireless communication unit 303 is a case in which a user's smart phone is used as a gateway, and is usually connected through Bluetooth Low Energy (BLE) communication. The third wireless communication unit 304 may use NFC or RFID communication to register or release the multi-biometric signal measuring device 1000 to the remote monitoring system 2000 when hospitalized or discharged. In this case, patient information and measurement period setting data of the remote monitoring system 2000 are transmitted to the biosignal measuring device 1000 , and a unique identification code (ID) of the biosignal measuring device 1000 is transmitted to the remote monitoring system 2000 . ) is transmitted.

The power supply unit 500 is connected to the built-in sensor unit 221 to 210, the sensor control unit 200, the central control unit 100, the user interface unit 101, the positioning receiving unit 301, and the wireless communication unit 302-304). to supply power required to drive these driving elements. The power supply unit 500 may include a battery, a battery charging circuit, a DC adapter, a USB port, and the like.

When the external sensors 221 to 226 are connected to the multi-biometric signal measuring apparatus 1000, the sensor control unit 200 detects a change in potential of a port to which the external sensors 221 to 226 are connected to the interrupt ( interrupt) signal to determine whether the external sensors 221 to 226 are connected. One or more external ports to which the external sensors 221 to 226 are connected are exposed in the form of a jack or a USB connector on the side of the multi-biometric signal measuring device 1000, and a plurality of external sensors are shared in the same port You may.

In addition, the external ECG electrode 211 may include a unique identification code (ID) according to a measurable lead. The external ECG electrode 211 may include n (n is a natural number greater than or equal to 2) external channel electrodes. The central control unit 100 may classify the types of the external ECG electrodes 211 according to the unique identification code (ID) and recognize different external ECG channels.

When the external electrocardiogram electrode 211 or the external PPG sensor 212 is connected to the multi-biometric signal measuring apparatus 1000, the central control unit 100 deactivates the corresponding internal sensor and signals received from the external sensors 211 to 212 is converted to a digital signal.

The external sensors 211 to 213 are not provided in the case of a general patient with low severity, but are used when more precise biometric measurement is required according to the patient's lesion or prognosis.

While the built-in ECG electrodes can measure only the ECG signal for lead I, in the case of external ECG electrodes, not only extremity guidance (leads I, II, III or aVr, aVl, aVf) but also chest view guidance v1 to v6 are external. Since it is possible to selectively activate the electrocardiogram according to the type of electrocardiogram, it is possible to obtain a wider range of electrocardiogram data and to classify a wide range of heart diseases.

Since the built-in PPG sensor is also measured from the wrist, it is not easy to block ambient light, which generates a lot of noise and causes errors in the measurement result. By doing so, it is possible to obtain a high-quality pulse wave signal.

An organic light-emitting diode display (OLED) may be applied to the display of the user interface unit 101 . The user interface 101 may further include a touch screen, a built-in speaker, and a vibrator for user input.

3 is a wearable multi-biometric signal measuring apparatus 1000 according to an embodiment of the present invention.

Referring to FIG. 3 , the multi-biometric signal measuring apparatus 1000 may be implemented in a main body 1010 . The band 1020 may be connected to the main body 1010 and wound around the user's wrist.

When the wristband is wound around the user's wrist, the main body 1020 faces the user's wrist and the built-in oxygen saturation sensor 204 and the left-hand electrode (or the first electrode, 202) of the built-in electrocardiogram sensor are exposed at the lower end of the device ( or the rear), a built-in body temperature sensor 209 , a right-hand electrode (or a second electrode, 203 ) of the built-in electrocardiogram sensor, and an upper end (or front) of the device to which the display of the user interface unit 101 is exposed.

The built-in sensor may include a built-in body temperature sensor 209 , an acceleration sensor 206 , a gyro sensor 207 , a barometric pressure sensor 208 , an ambient temperature sensor 210 , and the like applicable as an IR thermometer.

The built-in electrocardiogram electrodes 202 to 203 include a Right Ankle (RA) electrode 203 on the upper part (front) of the device and a Left Ankle on the lower part (rear) of the device so that the Lead I signal can be measured. LA) electrode 202 is disposed. In the case of the Left Ankle electrode 202, it has two electrode surfaces separated on both sides of the built-in PPG sensor.

In addition, since bio-impedance can also be measured from the electrocardiogram electrodes 202 to 203, respiration rate can also be measured through bio-impedance that changes during inhalation and exhalation.

The built-in PPG sensor 204 is disposed on the lower part (rear side) of the device so that ambient light is not penetrated as much as possible, and the built-in PPG sensor 204 is arranged in a structure that is recessed inside the device. It is also possible to determine whether or not the measuring device 1000 is being worn.

The external ECG electrode 211 is an example using a 5-pole ear-jack type connector, and includes RA (Right Ankle), LA (Left Ankle), LL (Left Leg) signals, detachable signals, and unique identification codes (IDs). ) is an example of using In this way, it is possible to read three types of extremity guidance signals from Lead I to Lead III.

The external PPG sensor 212 is an example of a structure of a finger clip having a shape that blocks ambient light well. A USB C-Type connector was used here, and this is an example of a design that can share a connector with a charger.

The external blood pressure monitor 213 is a wireless cuff-type blood pressure monitor, and is an example in which a multi-biometric signal measurement device can receive measurement results through Bluetooth Low Energy (BLE) communication.

FIG. 4 is a flowchart illustrating a power-on sequence immediately after power is applied to the embodiment of the multi-biometric signal measuring apparatus 1000 of FIG. 3 .

When the user selects the power ON button in the user interface unit 101 , power is supplied from the power unit 500 to the central control unit 100 and the micro control unit (MCU) starts up. First, various internal registers of the MCU or internal devices of the MCU are initialized (S201), and various timers necessary for system operation are generated and initialized (S202). In addition, initialization (S203) for several peripheral devices in the control board and initialization (S204) for devices for positioning are performed, and initialization (S205) for wireless communication functions such as BLE, WiFi, NFC/RFID is performed. Thereafter, it is determined whether the external extension sensor currently attached to the system is inserted (S207, 209), and the internal or external sensor is initialized (S207, S208, S210, S211) and enters an infinite loop. In the infinite loop, the event to be processed is continuously checked (S212), and when an event occurs, the event handler is called (S213) to process the event.

5A and 5B are flowcharts illustrating an interrupt service routine according to whether external sensors are connected or not.

When an external ECG electrode is inserted, when the GPIO (General Purpose Input Output) port for detecting the external ECG electrode changes from level 'H' to 'L', the sensor controller 200 detects this and generates an interrupt. In this case, the interrupt handler of FIG. 5A is called and performed. This interrupt handler checks the insertion state of the external ECG electrode. Since it is in the inserted state, the current internal ECG is deactivated and the external ECG is activated. Also, by reading the unique identification code (ID) of the inserted external ECG electrode, three ECG channels of ECG RA, LA, and LL are allocated. Even when the inserted external ECG is removed, the GPIO (General Purpose Input Output) port for detecting the external ECG sensor changes from level 'L' to 'H' and generates an interrupt, so that the interrupt handler of FIG. Since the external ECG electrode is removed, the current external ECG is deactivated and the internal ECG is activated. In this case, ECG channels are allocated to two channels of RA and LA.

An identification code (ID) for distinguishing an inserted external device is provided among interface pins of the charger and each of the external sensors. The identification code (ID) is a value that distinguishes each of the external sensors, and is preset to each of the external sensors to distinguish them. When the charger is connected to the external PPG port, the identification code (ID) of the charger is read through the pins of the external PPG port. The sensor control unit 200 detects a voltage change of the pins of the external PPG port to generate an interrupt, and the central control unit compares the ID received through the pins of the external PPG port with a preset ID to determine whether the charger is connected, It is possible to determine the type of connected external sensor.

When a charger or an external PPG sensor 212 is inserted into the external PPG port, the GPIO (General Purpose Input Output) port for detecting the external PPG sensor 212 changes from the level 'H' to 'L', and from the sensor control unit 200 An interrupt is generated.

In this case, the interrupt handler of FIG. 5B is called and performed. In this interrupt handler, when the insertion state of the external PPG sensor 212 is checked, the unique identification code (ID) is read again, and if it is 'H', charging is displayed and the handler is terminated. However, when the unique identification code (ID) is 'L', since the external PPG is inserted, the current built-in PPG sensor 204 is deactivated and the external PPG sensor 212 is activated. When the inserted external PPG sensor 212 or charger is removed, the GPIO (General Purpose Input Output) port for detecting the external PPG sensor 212 changes from level 'L' to 'H' and generates an interrupt. Since the interrupt handler of FIG. 5b is performed and the external PPG sensor 212 or the charger is removed, if the current external PPG sensor 212 is activated, it is deactivated, the built-in PPG sensor 204 is activated, and the charging indication is turned off.

In the case of an external ECG electrode, since the lead signal is different, it has a unique identification code (ID) in addition to the signal to inform the attachment or detachment of the external electrode. aVr, aVl, aVf) or thoracic view induction (v1-v6). Table 1 below is an example of an identification code (ID) for an external ECG electrode. It should be noted that the identification code (ID) is not limited to Table 1.

ID number of channels ECG channel '000' 1 channel (Lead I) CH1 Lead I - N electrode CH2 Lead I - P electrode '101' 3 channels (Lead I to Lead III) CH1 Lead I - N electrode CH2 Lead I - P electrode CH3 LL (Left Leg) '110' 5 channels (Lead I~ Lead III, v1, v6) CH1 RA (Right Ankle) CH2 LA (Left Ankle) CH3 LL (Left Leg) CH4 V1 CH5 V6

6 is a diagram showing the configuration of the remote monitoring system 2000 in detail.

Referring to FIG. 6 , the remote monitoring system 2000 includes a biometric monitoring server 2100 , a heart disease analysis server 2200 , and a prognosis prediction analysis server 2300 .

The biometric monitoring server 2100 renders real-time changes in the biometric data received through the gateway, and interworks with the heart disease analysis result received through the heart disease analysis server 2200 and the hospital information system and analyzes the biometric data. It performs a function of generating or delivering an alarm by receiving the prognostic analysis result from the prognostic analysis server 2300 .

The biometric monitoring server 2100 performs a function of not only displaying a function for medical staff to monitor changes in biometric information of a registered patient, but also registering a patient who needs monitoring or registering a device for the patient, and performs login management and various other functions. It performs a function of transmitting or receiving a set value to the multi-biometric signal measuring apparatus 1000 . The biometric monitoring server 2100 may include a monitoring/notification system and a manager system. The monitoring/notification system may be in charge of data collection, user location tracking, message push service, measurement watch setting, prognosis prediction server linkage, and heart disease server linkage. The administrator system may be in charge of patient registration, device registration, authority management, login, setting management, and DB management.

The heart disease analysis server 2200 receives the electrocardiogram signal received from the multi-biometric signal measuring device 1000 through the gateway 4000 through the biometric monitoring server 2100, and drives a Lead I waveform analysis algorithm. It analyzes the ECG data waveform and operates the dual algorithm of AI ECG image analysis to perform the analyzed heart disease analysis function. In a state in which the multi-biometric signal measuring apparatus 1000 inserts the external ECG electrode 211, the multi-channel heart disease analysis function is performed according to the corresponding channel of the external ECG electrode.

The prognosis prediction analysis server 2300 interworks with the hospital information system 3000 to inquire a patient's medical history or treatment history, and heart disease information from the heart disease analysis server 2200 and real-time biometric information from the biometric monitoring server 20001 Based on this, it performs prognostic analysis function and risk prediction function for disease.

The heart disease analysis server 2200 and the prognosis prediction analysis server 2300 may be separated from the remote monitoring system 2000 and separately exist in the cloud.

7 is a diagram illustrating an AI-based diagnosis algorithm for internal or external ECG data. The heart disease analysis server 2200 may predict a heart disease by driving an AI-based diagnosis algorithm. The heart disease analysis server 2200 may be included in or separate from the remote monitoring system 2000 .

8 is a block diagram showing the configuration of a prognosis prediction server that informs a prognosis prediction result for a disease by learning multiple biosignals, heart disease analysis results, and medical history. The prognosis prediction server may be included in the remote monitoring system 2000 or installed separately.

Multiple biosignal measurement method using general patient equipment

In the case of a general patient device, when the patient wears the multi-biometric signal measuring device 1000 on the wrist, multiple bio-signals are automatically measured in a non-invasive manner in an unconscious state according to the measurement cycle provided by the bio-monitoring server 2100. can Respiratory rate, single-channel (or Lead I) electrocardiogram, and body temperature are directly measured by the user (patient) when a notification sound according to a measurement cycle is output or a notification message is received by the wearable wearable multi-biometric signal measuring apparatus 1000 .

In order to maintain the patient's posture stably during the unconscious measurement to increase the examination accuracy, a notification message is displayed on the display of the multi-biometric signal measuring device 1000 together with a preset measurement time with a notification sound, and the patient's posture is stable for a predetermined time or longer. If the state is maintained, the self-awareness measurement is performed automatically. The patient's posture may be detected in real time by the acceleration sensor 206 and the gyro sensor 207 .

After receiving a notification message requesting body temperature measurement from the multi-biometric signal measuring device 1000, if an external thermometer, for example, a non-contact thermometer that measures the forehead temperature, is brought to the patient's forehead, it is measured using the IR sensor and automatically written to the server. After receiving the ECG or respiration rate measurement notification message, if the finger of the opposite hand of the hand on which the multi-biometric signal measuring device 1000 is worn is placed on the second ECG electrode 203 for 30 seconds, the single channel ECG and respiration rate are measured and the server is automatically recorded in

By utilizing the acceleration sensor 206 and the gyro sensor 207 to check the patient's exercise amount and sleep information in real time, daily activity statistics and sleep information are provided through a dedicated application (APP) pre-installed on the patient's mobile terminal. Activity statistics and sleep information along with the measurement results of multiple bio-signals are provided in real-time to the mobile terminals of patients and medical staff and the hospital's monitor system.

Method for measuring multiple vital signs using devices for semi-severe or critically ill patients

In the case of a device for semi-severe or severe patients, a 3-lead ECG patch and/or an external PPG sensor to which external ECG electrodes are connected may be provided along with the general patient device according to the severity of the patient.

Basic multi-biometric signals are measured at a preset period in the same way as in a device for a general patient in a device for severe or critically ill patients. In addition, when an electrocardiogram measurement notification message is received by the multi-biometric signal measuring device 1000 according to the biosignal measurement set time, when an electrocardiogram patch connected to external electrocardiogram electrodes is attached to the chest, the 3-lead electrocardiogram measurement data is automatically sent to the server It is recorded. In addition, when an oxygen saturation measurement message is received by the external ECG electrode multi-biometric signal measuring device 1000 , when the external PPG sensor is attached to a finger, the oxygen saturation measurement data measured by the external PPG sensor is automatically recorded in the server.

Although the embodiments of the present invention have been described in more detail with reference to the accompanying drawings, the present invention is not necessarily limited to these embodiments, and various modifications may be made within the scope without departing from the technical spirit of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The protection scope of the present invention should be construed by the claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: central control unit 101: user interface unit
200: sensor control unit 201: ECG/PPG analog front end
202: left hand electrode (LA) 203: right hand electrode (RA)
204: PPG sensor 205: respiration rate sensor
206: acceleration sensor 207: gyro sensor
208: barometric pressure sensor 209: body temperature sensor
210: temperature sensor 211: external electrocardiogram electrode
212: external PPG sensor 213: external blood pressure sensor
301: positioning receiving unit 302-304: wireless communication unit
1000: multiple biosignal measuring device 2000: remote monitoring system
2100: bio-monitoring server 2200: heart disease analysis server
2300: prognostic analysis server 3000: hospital information system
4000: gateway

Claims (9)

delete delete delete delete Remote monitoring connected through a wireless communication network to a multi-biometric signal measuring device having a main body having one or more external ports, a wristband connected to the main body and wound around a user's wrist, and one or more external sensors connected to the external port In the system,
Multiple bio-signals received from the multi-biometric signal measuring device are displayed in time series using a graph in the bio-monitoring server,
Transmitting the received ECG signal to an artificial intelligence-based heart disease analysis server to receive analysis results for heart disease,
Receive prognostic prediction analysis results through artificial intelligence learning of the received multiple bio-signals, the analysis results of the heart analysis server of the heart disease analysis server, and the medical history of the hospital information system,
By analyzing the data received from the multi-biometric signal measuring device, the amount of activity, sleep, sleep apnea, and falls of the user wearing the multiple bio-signal measuring device are monitored in real time, and the location of the user is determined and whether or not the quarantine is deviated. and
An artificial intelligence-based biosignal remote monitoring server system that manually or automatically remotely sets the biosignal type or measurement cycle of multiple biosignal measuring devices according to the patient's severity or prognosis.
6. The method of claim 5,
The remote monitoring system,
An artificial intelligence-based bio-signal remote monitoring system that transmits a profile message including patient information, bio-signal type, measurement period, and quarantine range to the multi-biometric signal measuring device by contacting the NFC/RFID reader of the multi-biometric signal measuring device.
6. The method of claim 5,
When the result of prognostic prediction in the remote monitoring system exceeds the threshold value set for each patient, an alarm is generated and an alarm message is transmitted to the medical staff's mobile terminal or the patient's multiple biosignal measuring device, and messages can be exchanged between medical staff and patients. An artificial intelligence-based biosignal remote monitoring system.
6. The method of claim 5,
An artificial intelligence-based biosignal remote monitoring system for monitoring whether a patient is outside a predetermined location range by sending a location request signal for a location from the remote monitoring system to multiple biosignal measuring devices.

delete

Images