CN111374650A - A remote medical monitoring and rescue platform system and its realization method - Google Patents

Abstract

The invention discloses a remote medical monitoring and rescue platform system, which comprises: a user server, used for monitoring the cardiovascular function of the user and feeding back monitoring data to a remote monitoring center; a doctor server, used for receiving data transmitted by the remote monitoring center and Feedback suggestions to the user end through the remote monitoring center; the remote monitoring center is used to connect the user server and the doctor server to realize the information exchange between the two. Based on the remote monitoring center, the present invention realizes the communication between the user server and the doctor server, and at the same time, records the relevant data files of the user. , to ensure the integrity of the monitoring data and the monitoring effect. On the other hand, the user data is fed back to the remote monitoring center, and the doctor server will provide guidance and suggestions after reviewing the data.

Description

A remote medical monitoring and rescue platform system and its realization method

technical field

The invention belongs to the technical field of medical detection, and specifically relates to a remote medical monitoring and rescue platform system and an implementation method thereof.

Background technique

The heart and blood vessels form the organic circulatory system of the human body. The heart is continuously stimulated by the electrocardiogram to perform an orderly alternating activity of contraction and relaxation. Electrocardiogram (ECG) is a record of the changes of myocardial electrical signals transmitted to the surface of human skin. During the orderly contraction and relaxation of the heart, blood is continuously ejected from the heart into the arteries, and then returned to the heart by the veins. . Every time the heart contracts, the pressure in the arteries fluctuates periodically, which in turn causes arterial (carotid, brachial, radial, ankle, etc.) blood vessels to fluctuate, which is called arterial pulse wave. It contains a wealth of human physiological and pathological information. Whether it is TCM pulse diagnosis or Western medicine cardiovascular disease examination, various physiological and pathological information must be extracted from the pressure and waveform changes of the pulse wave.

According to statistics, the number of people suffering from cardiovascular disease in my country is at least 230 million, and 2 out of every 10 adults are patients with cardiovascular disease; 3 million people die from cardiovascular disease every year in my country; as my country's population structure is getting older, more and more Many elderly people suffer from chronic diseases such as hypertension, coronary heart disease, and cardiovascular disease. Moreover, the age of cardiovascular onset tends to be younger, especially among young adults aged 35 to 54, the number of deaths increases most rapidly. Cardiovascular disease has become the first major disease endangering human health, and the World Health Organization has listed it as a killer that seriously endangers human health in the 21st century.

The direct medical expenses for cardiovascular diseases in my country have reached 130 billion yuan each year. The high incidence, high disability rate, and high mortality rate of cardiovascular diseases have caused great misfortune to families and brought an overwhelming economic burden. and mental burden.

At present, there are various cardiovascular detection and diagnosis and treatment instruments and equipment on the market, and the technology is relatively mature. However, hospital equipment is bulky, complicated to operate, and expensive, and is generally only suitable for medical diagnosis, and cannot be used for long-term, real-time dynamic monitoring of individuals.

On the other hand, the current remote ECG monitoring equipment can only perform single detection of ECG information, and cannot perform comprehensive analysis in combination with cardiac hemodynamic parameters. Therefore, the market is in urgent need of a miniaturized, multi-parameter capable 24-hour synchronous dynamic monitoring device for pulse and ECG, which can be connected with a powerful back-end support system through remote wireless communication and the Internet to realize remote control centers, physicians A complete service system for real-time contact and interaction between expert teams and users.

SUMMARY OF THE INVENTION

The purpose of the present invention is to overcome the above-mentioned problems, provide a miniature multi-parameter synchronous dynamic monitoring based on a wristwatch, and connect with a powerful background support system through long-distance wireless communication and the Internet, so as to realize the communication between the remote control center, the team of doctors and experts and the user. Real-time contact and interaction between remote medical monitoring and rescue platform system.

The object of the present invention is achieved through the following technical solutions:

A remote medical monitoring and rescue platform system, comprising:

The user server is used to monitor the cardiovascular function of the user and feed back the monitoring data to the remote monitoring center; said;

The doctor server is used to receive the data transmitted by the remote monitoring center and feed back suggestions to the user through the remote monitoring center;

The remote monitoring center is used to connect the user server and the doctor server to realize the information exchange between the two;

Further, the user server is a wristwatch-type micro-monitoring device, which includes: a wristwatch body and a watchband, a central processing unit integrated on the wristwatch body, a data storage management module, a human-computer interaction module, and a positioning module. module, a local alarm module, a data transmission module, a pulse signal processing circuit, an ECG signal monitoring module and a power management module; the watch body is also provided with a number of external connection interfaces for connecting to the external connection detection equipment, which are provided with There is a signal processing circuit for signal processing; a pulse wave sensor connected to the pulse signal processing circuit is arranged on the watch band.

Further, the remote monitoring center includes:

Database server for providing data storage and calling services;

Query management server, used to provide doctor services and user remote data query services;

Data analysis call server, used for consulting services, notifying and assisting users to solve emergencies;

The data communication server is used for data communication between the user server and the doctor server and the database server;

The data processing server is used to process the received human body sign data from the user server.

Further, the ECG signal monitoring module includes an ECG signal collector interface lead and an ECG signal processing circuit connected to it for processing the collected signal, and the output of the ECG signal processing circuit is connected to a central processing unit.

Further, the pulse wave sensor includes a piezoelectric material transducer sheet with electrode leads, a casing and a silica gel filling layer; the casing is located on the lower side of the piezoelectric material transducer sheet and is connected with the piezoelectric material transducer sheet. The combination constitutes a sealed resonant cavity, and the silica gel filling layer is located on the upper side of the piezoelectric material transducer sheet.

Further, the human-computer interaction module includes a capacitive screen input module and a display module.

Further, the positioning module adopts an AGPS positioning system.

Further, the local alarm module is a sound and light alarm device.

Further, the external connection interface includes one or more of a blood oxygen saturation probe interface, a blood glucose test strip interface, a temperature sensor interface, and an attitude sensor interface.

The present invention also provides an implementation method of the remote medical monitoring and rescue platform system, including:

(1) Create a user file in the remote monitoring center; the doctor server matches the corresponding user file;

(2) Collect the monitoring data of the user's body through the user server, and upload the data to the remote monitoring center through the data transmission module;

(3) After the remote monitoring center processes the received data, it stores the data for inquiries by doctors and user servers;

(4) The doctor server retrieves user data through the remote monitoring center and gives guidance and suggestions to the remote monitoring center;

(5) The remote monitoring center transmits the doctor's guidance and suggestions to the user server, or the remote monitoring center stores the doctor's guidance and suggestions for the user server to consult.

Further, after the remote monitoring center receives the uploaded data, it compares the uploaded data with the user profile data or with the normal human body data, and when the data is abnormal, the following processing is performed:

(a) The remote monitoring center actively feeds back abnormal data to the doctor server; (b) The doctor server establishes real-time communication with the user server; (c) The user server performs local sound and light alarms.

Compared with the prior art, the present invention also has the following advantages and beneficial effects:

(1) In the present invention, the remote monitoring center, the user server and the client server realize remote communication, the monitoring data of the client is transmitted to the remote monitoring center in real time, and the doctor server can consult at any time and give medical advice and feedback to the user server. This enables real-time contact and interaction between physician expert teams and users.

(2) In the present invention, the user server adopts a watch-type micro-monitoring device to continuously monitor the pulse and cardiovascular health status of the user for 24 hours. Like wearing a watch, it can be used for 24 hours all year round without affecting the work and life of the user. Pulse and ECG are monitored hourly. Among them, the pulse monitoring can flexibly set the collection frequency according to the needs of the user's health status. Even if the user is sleeping, the watch can automatically collect and send data.

(3) The present invention realizes the acquisition and synchronous display of pulse signal and ECG signal, which effectively overcomes that the existing remote ECG monitoring equipment can only perform single detection of ECG information, and cannot perform comprehensive analysis in combination with cardiac hemodynamic parameters .

(4) The long-term effective data collection of human body signs of the present invention constitutes big data of human health data, and comprehensive analysis and calculation of human health data can play a good disease prevention effect and benefit the society.

(5) When the device of the present invention obtains the abnormal signal of the user's body, it can alert the user himself or his relatives and friends by sound and light, and at the same time, the alarm signal can be sent to the remote control center through the background, and the expert team of remote doctors can provide professional assistance in time, which can Win precious "golden rescue time" for the rescue of patients.

Description of drawings

FIG. 1 is a schematic block diagram of a wristwatch-type micro-monitoring device in the present invention.

FIG. 2 is a principle block diagram of the remote monitoring in the present invention.

FIG. 3 is a schematic diagram of the collection, processing and transmission of data information in the present invention.

FIG. 4 is a side view of the pulse wave sensor of the present invention.

FIG. 5 is a top view of the pulse wave sensor of the present invention.

Among them, the names corresponding to the reference signs are as follows: 1- blood oxygen saturation probe interface, 2- blood glucose test paper interface, 3- temperature sensor interface, 4- attitude sensor interface, 5- pulse wave sensor, 6- three-lead heart Electric vest, 7-operational amplifier, 8-filter, 9-central processing unit, 10-display module, 11-data storage management module, 12-remote monitoring center, 51-sealed resonant cavity, 52-piezoelectric material changer Energy sheet, 53-shell, 54-silicone filling layer, 55-electrode lead.

Detailed ways

Example 1

As shown in Figures 1 to 5, this embodiment provides a remote medical monitoring and rescue platform system. The system is based on a remote monitoring center to realize the communication between the user server and the doctor server. Data files are recorded and filed. On the one hand, 24-hour uninterrupted monitoring of users is realized through the user server to ensure the integrity and monitoring effect of monitoring data. On the other hand, user data is fed back to the remote monitoring center, and the doctor server After reviewing the data, it will give guidance and suggestions. In addition, the user files in the remote monitoring center, and all the physical health data of the user during the monitoring process are stored in the remote monitoring center, which constitutes the big data of human health data. Comprehensive analysis and calculation can play a good role in disease prevention.

The user server is mainly used to monitor the cardiovascular function of the user and feed back the monitoring data to the remote monitoring center. In this embodiment, a wristwatch-type micro-monitoring device is used as a user server to monitor human health data, and its structure is as follows: a wristwatch body and a watchband, a central processing unit integrated on the wristwatch body, Data storage management module, human-computer interaction module, positioning module, local alarm module, data transmission module, pulse signal processing circuit, ECG signal monitoring module and power management module; The external connection interface of the connected detection device is provided with a signal processing circuit for signal processing; the watchband is provided with a pulse wave sensor connected with the pulse signal processing circuit. Through the above settings, the miniaturization and multi-parameter monitoring of the human body monitoring device can be realized. The device such as a wrist watch can be worn on the wrist of the human body without affecting the normal life of the user. Compared with the traditional medical monitoring device, the volume is large and the operation is complicated. defects, and achieved significant beneficial effects.

In this embodiment, the main body of the watch adopts a regular geometric three-dimensional shape, such as a cube, a rectangular parallelepiped, a cylinder, etc., and the user can choose according to their own preferences. The watch strap is matched with the watch body, and it can be an existing conventional watch strap structure such as a retractable watch strap, a snap-on watch strap, etc., which is not particularly limited here. Several functional modules are integrated on the watch body to realize the dynamic monitoring function of the watch. In view of the defects of single monitoring by the traditional monitoring device, this embodiment integrates the pulse monitoring function and the ECG signal monitoring function on the watch body. The two are realized by the pulse signal processing circuit and the ECG signal monitoring module respectively. The pulse signal processing circuit is matched with the pulse wave sensor, and the ECG signal monitoring module is mainly composed of the interface lead of the ECG signal collector and connected to it for use. It is composed of an ECG signal processing circuit that processes the collected signals, wherein the output of the ECG signal processing circuit is connected to the central processing unit, and the ECG signal monitoring module is connected to the three-lead ECG vest through the interface lead of the ECG signal collector. The above structure realizes the collection of pulse wave information and ECG signal, and its advantages are as follows:

1. The pulse wave sensor is used for signal acquisition. The pulse wave signal processing circuit mainly includes an operational amplifier and a filter. The signal is first amplified and then filtered, and then output to the central processing unit. In this embodiment, the pulse wave sensor includes a piezoelectric material transducer sheet with electrode leads, a casing and a silica gel filling layer; the casing is located on the lower side of the piezoelectric material transducer sheet and combined with the piezoelectric material transducer sheet to form a sealed resonance In the cavity, the silica gel filling layer is located on the upper side of the piezoelectric material transducer, wherein the material of the shell is not particularly limited, and is generally made of plastic. When worn, the pulse wave sensor is located at the radial artery of the wrist. When the electric material transducer is subjected to the fluctuating radial artery pulsation pressure, the corresponding changing pressure on the surface of the piezoelectric transducer (for a single point, its The essence is that the system reciprocates elastic vibration at a certain point, and the quantitative index refers to the acceleration of the system.) According to the principle of Q=kF, F=ma, a simple Q=kma (where k is the piezoelectric constant, m is the system The overall mass of the vibration, a is the elastic vibration index in the electrification, which refers to the acceleration of the system.) Thus, a charge corresponding to the magnitude of the applied force is generated, and then the charge amplifier is used to amplify and filter, thereby Accurately reflect the pulse signal. The unique design of the pulse wave sensor in this embodiment gives full play to the advantages of piezoelectric materials, effectively filters out clutter, and obtains a pulse signal with high sensitivity, little interference, and stability and reliability, thus effectively overcoming the limitations of the existing pulse sensor. It has the disadvantages of relatively large volume, relatively low sensitivity, and poor anti-interference ability. The sensor can clearly collect hundreds of millivolts of clean and undistorted pulse waves without amplification.

2. The three-lead ECG vest and the ECG signal monitoring module are used to collect ECG signals. Human cells have electrical activity, so the normal beating of the heart can be checked according to the electrical activity, and the factors affecting the beating of the heart can be indirectly measured. The electrocardiogram refers to the successive excitation of the pacemaker, atrium, and ventricle of the heart in each cardiac cycle. Along with the changes in the bioelectricity of the electrocardiogram, various forms of potential changes are drawn from the body surface through the electrocardiograph (abbreviated as ECG). ECG). ECG is an objective indicator of the occurrence, propagation and recovery of cardiac excitation. The tissues and body fluids around the heart can conduct electricity, so the human body can be regarded as a volume conductor with three dimensions of length, width and thickness. The heart is like a power source. The sum of the action potential changes of countless cardiomyocytes can be conducted and reflected on the body surface. There are potential differences between many points on the body surface. Animal body tissues and body fluids can conduct electricity. Placing the recording electrodes of the electrocardiograph on any two non-isoelectric parts of the body surface can record the images of ECG changes. This measurement method is called bipolar lead. , the measured potential change is the algebraic sum of the potential changes of the two measured points on the body surface, and the analysis waveform is more complicated. If you try to make one of the two measurement electrodes, usually the electrode connected to the negative end of the tracer, the potential of which is always kept at zero potential, it becomes the so-called "irrelevant electrode", and the other measurement electrode is placed on the body surface for a measurement Points, as "probing electrodes", this measurement method is called unipolar lead. Since the irrelevant electrodes often keep the zero potential unchanged, the measured potential changes only represent the potential changes at the location where the probe electrode is located, so the interpretation of the waveform is relatively simple. At present, both unipolar and bipolar leads are used in clinical examination of ECG, but their measurement accuracy is poor and the operation is difficult. In this embodiment, 3-12 leads are used to collect data synchronously. The electrode connection method is: the first lead (abbreviated as I), the right arm (-), the left arm (+); the second lead (abbreviated as II), the right arm (-), the left foot (+); the third lead Joint (referred to as III), left arm (-), left foot (+). The limb leads of the ECG have diagnostic significance for cardiac rhythm disorders. The present invention adopts the above arrangement to obtain ECG signal parameters, and achieves the practical effect of effectively reducing clutter while simplifying the operation steps of ECG acquisition, and obtains an ECG waveform with high sensitivity, little interference and diagnostic significance. The ECG signal processing circuit includes an operational amplifier and a filter. The signal is first amplified and then filtered, and then output to the central processing unit.

A man-machine interaction module is integrated on the watch body, which mainly includes a capacitive screen input module and a display module, preferably a high-definition TFT display module. The pulse wave signal and ECG signal are collected and processed and then transmitted to the central processing unit, and then processed by digital filtering. The waveform display and index parameter display are performed synchronously on the display module, which has the advantage of: there is a conduction lag time difference from the contraction of the heart to the flow of blood along the arterial blood vessels to the end of the limb. The process is displayed synchronously in a coordinate system, which is accurate enough for doctors to diagnose and interpret, and helps to detect cardiovascular abnormalities as early as possible.

In this embodiment, the central processing unit adopts an ARM32-bit single-chip microcomputer, and the model is: STM32ZET6, which is mainly responsible for waveform, algorithm, data file storage management, data transmission control, man-machine interface dialogue management, and the like. The data transmission module realizes data communication with the remote monitoring center based on the 3G/4G module TCP/IP protocol, etc., and transmits the data information collected by the user server to the remote monitoring center. The power management module is mainly used to supply power to the device, and the existing conventional power supply is selected, which is not particularly limited here.

In this embodiment, the user server also has the following functions: diagnosis and treatment plan report/download, real-time monitoring data report, including electrocardiogram, pulse wave, other indicators/download, patient symptom self-statement record/upload. In addition to the above watch-type micro-monitoring device, the user server can also be used in combination with conventional smart terminals, such as mobile phones, computers, etc. After downloading the client software and registering in the remote monitoring, the corresponding functions can be realized.

In this embodiment, the remote monitoring center includes: a database server for providing data storage and calling services; a query management server for providing doctor services and user remote data query services; a data analysis call server for consulting services and notification assistance The user solves emergencies; the data communication server is used for data communication between the user server and the doctor server and the database server; the data processing server is used to process the received human body sign data from the user server. The remote monitoring also has the following functions: management of patient files, storage of patient medical record data, security authentication, group organization management, doctor registration management, service registration management, uploading and downloading web services (patient services).

The doctor server can use existing smart terminals such as mobile phones, computers, and tablet computers. It performs registration after downloading the corresponding software on the intelligent terminal. It can realize the following functions: query of patient identity, file query, monitoring data and graph query, analysis of data collected by patients for several weeks, months/appointed time, obtaining early symptoms of some sudden diseases from users, health intervention guidance and suggestions given to the symptoms, Telephone guidance service records, intervention effect records, diagnosis and treatment plan reports, etc.

In this embodiment, the implementation method of the remote medical monitoring and rescue platform system includes:

(1) Create a user file in the remote monitoring center; the doctor server matches the corresponding user file;

(2) Collect the monitoring data of the user's body through the user server, and upload the data to the remote monitoring center through the data transmission module;

(3) After the remote monitoring center processes the received data, it stores the data for inquiries by doctors and user servers;

(4) The doctor server retrieves user data through the remote monitoring center and gives guidance and suggestions to the remote monitoring center;

(5) The remote monitoring center transmits the doctor's guidance and suggestions to the user server, or the remote monitoring center stores the doctor's guidance and suggestions for the user server to consult.

Example 2

On the basis of Embodiment 1, the remote medical monitoring and rescue platform system provided in this embodiment also includes a positioning device. Specifically, a positioning module is integrated on the wristwatch body in the wristwatch-type micro-monitoring device. Preferably, the positioning module The AGPS positioning system is adopted, which utilizes GPS and the AGPS (Assisted Positioning) of the communication operator, the location information of the base station, and uses the principle of multi-point intersection to realize the indoor positioning of the user. The user's plane geographic location can be determined through the positioning module, which is conducive to timely rescue after the user's body is abnormal and loses self-rescue ability. The work of the positioning module can be real-time work, and the user's positioning position is transmitted to the remote monitoring center in real time. This method consumes a lot of power. Those skilled in the art can also choose the wake-up positioning method, that is, under normal conditions, the positioning module is in Sleep state, low-power operation, when the user monitoring data is abnormal (the data abnormality judgment is realized by setting the parameter index reference value), the central processing unit wakes up the positioning module, the positioning module starts to work to realize the user's position positioning, and then transmits it to Remote monitoring center.

Example 3

On the basis of Embodiment 1 or Embodiment 2, the remote medical monitoring and rescue platform system provided in this embodiment further includes a local alarm module. Specifically, the wristwatch body in the wristwatch-type micro-monitoring device is integrated with a local alarm module. , It is preferable to use an audible and visual alarm device. When obtaining the abnormal signal of the user's body, the audible and visual alarm can remind the user or his relatives and friends to save himself. At the same time, the central processor sends the alarm signal to the remote control center, and the remote physician expert team provides timely professional services The rescue of patients can win precious "golden rescue time" for the rescue of patients.

Example 4

On the basis of Embodiment 1, this embodiment provides a further implementation method of the remote medical monitoring and rescue platform system: after receiving the uploaded data, the remote monitoring center compares the uploaded data with user profile data or with normal human body data For comparison, when the data is abnormal, the following processing is performed: (a) the remote monitoring center actively feeds back the abnormal data to the doctor server; (b) the doctor server establishes real-time communication with the user server; (c) the user server performs local sound and light alarm. Among them, the user profile data comes from the previous data collection, and the normal human body data comes from the medical reference indicators corresponding to the user's age, gender, height, weight and other basic conditions.

Example 5

On the basis of Embodiment 1, the remote medical monitoring and rescue platform system provided in this embodiment further includes a number of external interfaces for connecting external detection equipment, and a signal processing circuit for signal processing is arranged therein, wherein the signal processing The circuit is mainly used for signal amplification and filtering. Preferably, the external connection interface includes one or more of a blood oxygen saturation probe interface, a blood glucose test strip interface, a temperature sensor interface, and an attitude sensor interface. The external equipment corresponding to each interface is as follows: the blood oxygen saturation probe interface is connected to the blood oxygen saturation probe, which is used to monitor the data information of human blood oxygen saturation; the blood glucose test strip interface is connected to the blood glucose test strip, which is used to monitor the human blood glucose data information; The temperature sensor interface is connected to a temperature sensor, which is used for monitoring human body temperature data; the attitude sensor interface is connected to an attitude sensor, which is used to monitor the attitude information data of the human body.

Example 6

On the basis of Embodiment 1, the remote medical monitoring and rescue platform system provided in this embodiment also includes a number of interfaces for externally transmitting data, that is, the wristwatch body of the wristwatch-type micro-monitoring device is provided with the above-mentioned interfaces, such as : RS232 interface, USB interface, etc., its function is to transmit data to personal computer and data server transmission system.

As described above, the present invention can be well implemented. The above descriptions are only preferred embodiments of the present invention, and are not intended to limit the present invention. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention shall be included in the scope of the present invention. within the scope of protection.

Claims (10)

1. A telemedicine monitoring rescue platform system, comprising:

the user server is used for monitoring the cardiovascular function of the user and feeding back monitoring data to the remote monitoring center; the method comprises the following steps of;

the doctor server is used for receiving the data transmitted by the remote monitoring center and feeding back suggestions to the user side through the remote monitoring center;

the remote monitoring center is used for connecting the user server and the doctor server to realize information interaction between the user server and the doctor server;

the user service end is a wristwatch type miniature monitoring device, which comprises: the wristwatch comprises a wristwatch body, a watchband, a central processing unit, a data storage management module, a man-machine interaction module, a positioning module, a local alarm module, a data transmission module, a pulse signal processing circuit, an electrocardiosignal monitoring module and a power management module, wherein the wristwatch body and the watchband are integrated on the wristwatch body; the wristwatch main body is also provided with a plurality of external connection ports for connecting external connection detection equipment, and a signal processing circuit for signal processing is arranged in the wristwatch main body; and the watchband is provided with a pulse wave sensor connected with the pulse signal processing circuit.

2. The telemedicine monitoring and rescue platform system of claim 1, wherein the remote monitoring center comprises:

the database server is used for providing data storage and calling service;

the query management server is used for providing doctor service and user remote data query service;

the data analysis calling server is used for consulting services and informing the assistant users to solve emergencies;

the data communication server is used for realizing data communication between the user server and the doctor server and the database server;

and the data processing server is used for processing the received human body sign data of the user server.

3. The telemedicine monitoring and rescue platform system according to claim 2, wherein the electrocardiosignal monitoring module comprises an electrocardiosignal collector interface lead and an electrocardiosignal processing circuit connected with the electrocardiosignal collector interface lead and used for processing collected signals, and the output of the electrocardiosignal processing circuit is connected with the central processing unit.

4. The telemedicine monitoring and rescue platform system of claim 3, wherein the pulse wave sensor comprises a piezoelectric material transducer piece with electrode leads, a shell and a silica gel filling layer; the shell is located piezoelectric material transduction piece downside and with piezoelectric material transduction piece combination constitutes sealed resonant cavity, the silica gel filling layer is located piezoelectric material transduction piece upside.

5. The telemedicine monitoring and rescue platform system of claim 4, wherein the human-computer interaction module comprises a capacitive screen input module and a display module.

6. The telemedicine monitoring and rescue platform system of claim 5, wherein the positioning module employs an AGPS positioning system.

7. The telemedicine monitoring and rescue platform system of claim 6, wherein the local alarm module is an audible and visual alarm.

8. The telemedicine monitoring rescue platform system of claim 7, wherein the external interface comprises one or more of a blood oxygen saturation probe interface, a blood glucose test strip interface, a temperature sensor interface, an attitude sensor interface.

9. The method of any one of claims 1 to 8, wherein the method comprises:

(1) establishing a user profile in a remote monitoring center; matching the corresponding user file by the doctor server;

(2) monitoring data of a user body are collected through a user server, and the data are uploaded to a remote monitoring center through a data transmission module;

(3) the remote monitoring center processes the received data and stores the data for the inquiry of doctors and user service terminals;

(4) the doctor server calls user data through the remote monitoring center and gives guidance suggestions to be fed back to the remote monitoring center;

(5) the remote monitoring center transmits the guidance suggestions of the doctor to the user server, or stores the guidance suggestions of the doctor for the user server to look up.

10. The method of claim 9, wherein the remote monitoring center compares the uploaded data with user profile data or with human body normal data after receiving the uploaded data, and when the data is abnormal, the method comprises the following steps:

(a) the remote monitoring center actively feeds back abnormal data to the doctor server; (b) the doctor server establishes real-time communication with the user server; (c) and the user server performs local sound-light alarm.

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