WO2015154245A1

WO2015154245A1 - Cardiovascular-cerebrovascular risk dynamic monitoring and management system and method therefor

Info

Publication number: WO2015154245A1
Application number: PCT/CN2014/074968
Authority: WO
Inventors: 吴冰
Original assignee: 时云医疗科技（上海）有限公司
Priority date: 2014-04-09
Filing date: 2014-04-09
Publication date: 2015-10-15

Abstract

Disclosed is a cardiovascular-cerebrovascular risk dynamic monitoring and management system and a method therefor, wherein the system comprises at least one physical sign measuring terminal (101), a user terminal (102), a firewall (104), an authentication unit (105) and a server (106 ), wherein the networks (103) between the physical sign measuring terminal (101) and the user terminal (102), and between the user terminal (102) and the server (106) are interconnected, wherein the physical sign measuring terminal (101) comprises a communication module (221) and a memory (222), wherein the memory (222) is used for storing user's physical sign data measured by the physical sign measuring terminal (101); this is transmitted through the communication module (221) to the user terminal (102), uploaded through the user terminal (102) to the server (106), and after authenticating the uploaded data, the server (106) returns the authenticated data to the corresponding user terminal (102); and the server (106) is used for storing the uploaded data, and doing analysis based on the data, sending the analysis results to the user terminal (102) to be presented to the user.

Description

System and method for dynamic monitoring and management of cardiovascular and cerebrovascular risks

The present invention generally relates to the field of network intelligent clinical or home medicine, and in particular to a method and system for dynamically monitoring and managing cardiovascular and cerebrovascular risk populations through the Internet. Background technique

At present, with the accelerated pace of human life and the increasing number of sub-healthy people, chronic diseases have seriously threatened people's lives. Taking hypertension as an example, according to statistics, there is one person with hypertension in every three people in China over 35 years old. However, in patients with hypertension, 70% of patients do not know about their illness, and there is no way to choose timely treatment to control the condition. If prevention and treatment are not appropriate, the next 30 years will be an era of chronic disease outbreaks, especially the acute onset of many chronic diseases, which will greatly threaten human health.

In many chronic diseases that affect human health, the irregularity of blood pressure is an external response to most cardiovascular diseases such as cardiovascular and cerebrovascular diseases and diabetes. Therefore, it has become an urgent need for medium- and long-term prediction and treatment of blood pressure. In particular, family self-test blood pressure and related disease warnings have become more and more important.

In today's society, network technology has been filled with all aspects of people's lives. People can easily use the network to upload, analyze and share information to any group or individual. The entire society and the various industries are also enjoying technological innovation while enjoying the convenience brought by the network. However, there are few web applications that can be used in clinical medicine, especially in the use of electronic blood pressure instruments to monitor user blood pressure to help users warn of high blood pressure risks. Traditional electronic blood pressure monitoring instruments require the user to manually record the data, or manually upload the data to the network, and then use the corresponding blood pressure monitoring software to push the data to the doctor, family or friends, and the doctors review and make corresponding conclusions. The conclusions are susceptible to environmental fluctuations and do not have the ability to manage a large number of clinical research examples and experimental data, nor do they include the ability to use statistical techniques to analyze large amounts of data to make early warning capabilities for cardiovascular and cerebrovascular risk assessment.

Therefore, there is a need for a system for effective and dynamic monitoring and research management of people with cardiovascular and cerebrovascular risks using network technology, which can detect abnormalities in time and change passive therapy into active prevention. Summary of the invention

It is an object of the present invention to provide a dynamic monitoring and management system for cardiovascular and cerebrovascular risk, the system comprising at least one vitality measuring terminal, a user terminal, a firewall, an authentication unit and a server, wherein the vital sign measuring terminal and the Interconnecting between the user terminals and the network between the user terminal and the server, wherein the firewall allows or restricts the passage of data transmitted by the user according to specific rules to ensure user information security; Authenticating each user's unique user code and associated user password to ensure that only authenticated users with access rights are granted access to the server; the sign measurement terminal includes a communication module and a memory, The memory is used for storing the vital sign data measured by the user through the sign measuring terminal, and transmitted to the user terminal through the communication module, and then uploaded to the server by the user terminal, where the server authenticates the uploaded data. After that, the number after the certification Returned to the corresponding user terminal; the server is configured to store the uploaded data, analysis based on the data, and transmits the analysis result to the user terminal to the user.

Preferably, the sign measuring terminal is selected from one or more of a sphygmomanometer, a blood glucose meter, a thermometer, a heart rate monitor, an electrocardiograph, an electroencephalogram device, and a pulmonary function meter.

Preferably, the user terminal interacts with the server and the vital sign measuring terminal in the form of an interface application.

Preferably, the network is selected from the group consisting of a wired network, WiF i, Zigbee, WLAN, GPRS, cellular network, GSM network, 3G network, LTE network or CDMA network, Bluetooth, NFC; infrared, ultrasonic, Wi re es s at least one of USB and RFID.

Preferably, the user terminal is selected from at least one of a desktop computer, a laptop computer, a smart phone, a personal digital assistant, a tablet computer, a game machine, and a multifunctional mobile terminal.

Preferably, the memory of the sign measuring terminal is provided with a plurality of user storage bits, which match a plurality of different users.

Preferably, when the user connects to the vital sign measuring terminal for the first time, the sign measuring terminal creates a user bit for the user to create a user record.

Preferably, when the physical location measuring terminal is connected to the user terminal, the identity of the vital sign measuring terminal is transmitted to the server for authentication by the user terminal.

Preferably, the server comprises a database, a database communication module, an access control module, a data checking module, a data analysis module and a session control module, wherein the database is used for storing user information and data; and the database communication module controls all directions to the database. The access control module is configured to perform identity authentication verification of a user that issues a request to access the server; the data checking module is configured to check consistency and integrity of the data; and the data analysis module is configured to perform the data Analysis, and sending the analysis result to the user terminal; the session control module is configured to manage the access control module, the data inspection module, and the data analysis Modules to allow data to be exchanged between modules and the database communication module.

Preferably, the user terminal includes a data collection module and an analysis report module, wherein the data collection module is configured to obtain data from the physical measurement terminal collection; the analysis report module is configured to analyze data from the server. Presented in the user interface.

Preferably, the information of each user in the server is independent and is relatively isolated from other user information, and the user obtains the user concerned by sending a request to other users requesting attention, and when the request is accepted. The data.

Preferably, the data analysis module performs data analysis based on a time biology or time medical approach.

Preferably, the user terminal collects information of the user by using a questionnaire.

Preferably, the user terminal is configured to make a medication reminder for the user based on the medicine input by the user.

According to still another aspect of the present invention, a method for dynamic monitoring and management of cardiovascular and cerebrovascular risks is provided, the method running in a system including at least one of a physical measurement terminal, a user terminal, a firewall, an authentication unit, and a server, The network between the physical measurement terminal and the user terminal and the network between the user terminal and the server is interconnected, and the method includes the following steps: a) the user logs in through the user terminal; b) detects and prompts the user Whether it is a new user; if yes, proceed to step c; if not, proceed to step e; c) the user performs a new user registration; d) the user provides information, and creates a new information containing the new user's information in the server-side database Recording; e) the user logs in to the server; f) lists the physical measurement terminals available for the user to select, and the user selects the terminal and performs the physical sign measurement; g) when the user selects a specific physical measurement device, judges the physical measurement terminal Is there data that was last measured by the user but not uploaded, and if so, the data is uploaded to After the user terminal enters step h; h) the user measures and performs the physical sign data collection by the sign measuring device; i) judges whether the collected data is complete, and if the obtained data is incomplete, returns to step h to re-measure; when the data is confirmed to be complete Then, proceed to step j; j) uploading to the server according to the collected data for data analysis; k) displaying the analyzed result in the form of a report to the user through feedback of the user terminal.

The system according to the present invention can combine the practice of continuous continuum change law analysis, can make individual user data and the light sputum population to compare and then establish an individual reference law and can find abnormalities in time, and change passive therapy into active prevention.

It is to be understood that the foregoing general descriptions DRAWINGS Further objects, features, and advantages of the present invention will be made apparent by the following description of the embodiments of the invention.

Fig. 1 schematically shows a system block diagram of a dynamic monitoring and management system for cardiovascular and cerebrovascular risk in accordance with an embodiment of the present invention.

FIG. 2 is a schematic diagram showing the data interaction relationship between the physical measurement terminal and the user terminal. Figure 3 illustrates in a modular manner the process of data access and interaction between a server and a user terminal in accordance with the present invention.

Fig. 4 shows the manner in which user information is stored in the server and the information sharing mechanism between users in accordance with the present invention.

Figure 5 shows the user interface for mutual attention and information sharing between users presented in the user application (a pp ) interface of the user terminal.

Fig. 6 shows a basic flow chart for performing a health condition analysis independently when a user uses the server system according to the present invention.

Figure 7 shows the flow of the comparative analysis function that the system provides to a particular user.

Figure 8 illustrates an exemplary user interface display of a medical history survey performed by a user, preferably in the form of a questionnaire.

Figure 9 schematically illustrates an exemplary user interface of a user health assessment report. Figure 10 schematically illustrates an exemplary user interface for medication reminders and app additions. detailed description

The objects and functions of the present invention and methods for achieving the objects and functions will be clarified by reference to the exemplary embodiments. However, the invention is not limited to the exemplary embodiments disclosed below; it can be implemented in various forms. The essence of the description is merely to assist those skilled in the relevant art to understand the specific details of the invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the figures, the same reference numerals indicate the same or similar components, or the same or similar steps.

The cardiovascular and cerebrovascular risk dynamic monitoring and management system for, for example, cardiovascular and cerebrovascular risk diseases according to the present invention is based on a network, and is particularly suitable for clinically studying and managing dynamic blood pressure monitoring data of cardiovascular and cerebrovascular risks. The system in accordance with the present invention is created as an integrated online platform designed for cardiovascular and cerebrovascular risk research and management with multiple servers running. It includes security modules, backup and redundancy, and supports data encrypted with standard encryption protocols. The database can be used to store user profiles, protocols, data and results reports. The system according to the invention can well match users and electronics Blood pressure measurement equipment, and safety certification, to store and upload data to the system back-end database while ensuring user data security and privacy; system operation includes collecting, providing and analyzing user information, protocols, blood pressure monitoring records and data conclusions. Therefore, it can be combined with the practice of continuous physical sign change law analysis, so that the individual user data and the light-population group can be compared and then the individual reference law can be established and the abnormality can be found in time, and the passive therapy is taken as active prevention. System Overview

Fig. 1 schematically shows a dynamic monitoring and management system for cardiovascular and cerebrovascular risks in accordance with an embodiment of the present invention. The system 100 includes at least one vitality measurement terminal 101, a user terminal 102, a firewall 104, an authentication unit 105, and a server 106. The physical measurement terminal 101 and the user terminal 102, and between the user terminal 102 and the server 106 (through the firewall 104 and the authentication unit 105) are interconnected by a wired or wireless network 103. For illustrative purposes, Figure 1 shows, by way of example only, two individual measurement terminals 101a and 101b, four user terminals 102a, 102b, 102c and 102n. However, it will be appreciated that in other embodiments, system 100 can include more of the vital sign measuring terminal 101 and the user terminal 102. In an embodiment in accordance with the present invention, the different vital sign measuring terminals 101 may be terminals independent of each other, respectively manufactured or operated by different manufacturers, and can be incorporated into the present invention only by following the communication method designed by the present invention. In the system. The sign measuring terminal 101 is, for example, a sphygmomanometer, a blood glucose meter, a thermometer, a heart rate monitor, an electrocardiograph, an electroencephalogram device, a lung function meter, or the like.

User terminal 102 can be a desktop computer, laptop computer, smart phone, personal digital assistant (PDA), tablet, gaming machine, multi-function mobile terminal, or any other device that includes computing functionality and data communication capabilities. The user terminal 102 includes an interface application (app), such as a web browser or a custom application (app), for two-way communication with a web-enabled application, thereby enabling the user to interact with the server and the physical measurement terminal in the form of an interface application. A user who installs a system software application that implements the method of the present invention can log in to the server 106 via the network 103 for various interactive functions such as information uploading, downloading, querying, and analyzing. The user terminal 102 can receive input from the user and can present an output, so the user terminal 102 also includes an I/O interface (input/output interface) that can receive one or more inputs and present the output. For example, the input interface can include one or more of a keyboard, a mouse, a joystick, a trackball, a touchpad, a touchscreen, a stylus, and a microphone. In addition, an output can be presented through the output interface to output a user's control operation instruction or feedback information from other users. The output interface includes one or more of a display screen, one or more speakers, and a tactile interface. Two-way communication between the vital sign measuring terminal 101 and the user terminal 102, between the user terminal 102 and the server 106 via any type of network 130. The network 130 includes, for example, a local area network ("LAN") such as an intranet and a wide area network ("WAN") such as the Internet. Network 130 can be configured to support the transmission of information in a variety of protocol setting formats. Additionally, network 130 can be a public network, a private network, or a combination thereof. Network 130 may also be implemented using any one or more types of physical media, including wired communication paths and wireless communication paths associated with multiple service providers. Wireless communication methods such as Zigbee, WiFi or WLAN, GPRS, cellular network, GSM network, 3G network, LTE network or CDMA network, at least one of Bluetooth, NFC, infrared, ultrasonic, Wireless USB, RFID, and the like.

The firewall 104 is a protection device for ensuring the security of user information. The firewall 104 may include privacy data such as user's health data and identity information according to the number of transmissions and analysis, and the data analysis result may be used to guide the user's treatment or health care behavior. The security of data has become especially important. In addition, the user may access the server 106 through a public network or other unsecured network. To ensure data security, this can be achieved by providing a firewall that secures the network between the user terminal 102 and the server 106. Firewall 104 can be implemented by a combination of software and hardware devices. The firewall 104 can set up functional modules such as service access rules, authentication tools, packet filtering, and application gateways to monitor and filter data flowing between the server 106 and the user terminal 102.

The authentication unit 105 is used to ensure that only authenticated users with access rights are granted, while protecting each user's private data, that is, each user has a unique user code and a user password associated with it. Authentication unit 105 is used to ensure that only authorized users with access rights can access the server by authenticating each user's unique user code and associated user password. When the user enters his/her own username and password through the user terminal 102 and successfully logs into the system, he or she will see his/her personal information, analysis methods and test results. Only after the authentication of the authentication unit 104 is successful, all operations performed by the user can be recognized by the server 106. The various protected data will be received, stored, and analyzed and fed back on server 106. interactive mode

2 is a schematic diagram showing the data interaction relationship between the vital sign measuring terminal and the user terminal, and the module architecture of the physical sign measuring terminal. As shown in Figure 2, each user passes through the user terminal. After logging in to the server, the user may try to connect to any one or more of the physical measurement terminals 201 a, 2 01 b or 2 01 c within the coverage of the network to perform the physical sign measurement. Figure 2 shows, by way of example only, three individual measurement terminals 201a, 201b and 201c and a user terminal 202. Taking the sign measuring terminal 201 b as an example, the sign measuring terminal includes a communication module 221 and a memory 222. The communication module 221 is configured to perform data transmission with the user terminal, and the memory 222 is configured to store at least one user record.

When the user connects to the physical measurement terminal 201 for the first time to perform the physical measurement, the user is first logged in to the server and connected to the physical measurement terminal to establish a matching relationship with the physical measurement terminal 201. The memory on the sign measurement terminal is provided with multiple user storage bits that can be matched to multiple different users. When the user first connects to the vital sign measuring terminal 201, the sign measuring terminal 201 creates a user bit for the user to create a user record. After the user logs in to the server for the first measurement, the server will associate the user code with the ID number of the physical measurement terminal. When the user makes the next measurement, offline measurement without logging in to the server can be achieved. That is, the user can directly measure the matching relationship between the user code and the physical measurement terminal ID number without logging in to the server again. After the user measurement is completed, the vital sign measuring terminal 201 may be in the state where the valid communication link 204 exists (for example, the user or another user who has matched the physical measurement terminal 201 matches again with the user terminal 202 that can connect to the server 203. The physical measurement terminal 201 uploads the un-uploaded data to the server 203 through the user terminal 202. After the server 203 authenticates the uploaded data, the authenticated data is transmitted back to the corresponding user terminal 202. Preferably, the data after successful upload of the server is deleted on the vitality measuring terminal 201.

Authentication is also required between the physical measurement terminal 2 01 and the remote server 2 ϋ 3. Preferably, the vital sign measuring terminal 201 completes the connection and authentication with the server 203 through the user terminal 202. When the vital sign measuring terminal 201 is connected to the user terminal 202, the identity of the vital sign measuring terminal 101 (e.g., device hardware code) is transmitted to the server 203 for authentication by the user terminal 202.

The application app running on the user terminal 202 issues an instruction to the user terminal 202 to enable it to search for available sign measurement terminal functions via network communication. Specifically, the user terminal 202 sends a request signal to all the vitality measurement terminals in the signal coverage area, and then displays the names of all the successful feedback physical measurement terminals on the system for the user to select.

After the user selects the vital sign measuring terminal that he wants to connect, the user terminal 202 will inform the selected sign measuring terminal of the user's identity code, and the memory 222 of the sign measuring terminal will reserve an information storage slot for the user. , after the measurement is completed, the measurement data will It will be stored in this location as a user record. If the physical measurement terminal and the user terminal are still connected at this time, the user's measurement data can also be automatically uploaded to the user terminal; if the connection cannot be made, the data will be stored in the memory 222 of the physical measurement terminal until there is a matching user. After the terminal 202 is again connected to the vital sign measuring terminal, the data will be uploaded to the user terminal again.

Figure 3 illustrates in a modular manner the process of data access and interaction between a server and a user terminal in accordance with the present invention. As shown in FIG. 3, in the system according to the present invention, each user through his user interface 310 presented in a user interface manner performs session and data interaction with the server 320. The server 320 includes a database 321 for storing user information and data, a database communication module 322, an access control module 323, a data checking module 324, a data analysis module 325, and a session control module 326. The user terminal 310 includes a data collection module 311 and an analysis report module 312, and preferably further includes other information modules 313 for recording user basic information, questionnaires, and the like.

Specifically, the session control module 326 manages the user interface and other modules of the access control module 323, the data checking module 324, the data analyzing module 325, and the user terminal 310 for performing user identity authentication verification of the request for accessing the server (as shown in FIG. 3 All of the modules shown in block 300 include whether data is allowed to be exchanged between the modules and database communication module 322. The database communication module 322 controls all requests directed to the database 321 . The user interface of the user terminal 310 includes at least a data collection module 311, an analysis report module 312, and other information modules 313 for displaying non-interactive information (such as system settings, etc.). All data acquired from the physical measurement terminal by the data acquisition module 311 of the user terminal 310 will be checked for consistency and integrity by the data checking module 324. For example, a normal-blood user will not receive information about the way the buck is pressed. When all of the required information is collected, the session control module 326 issues an instruction to perform the analysis process in the data analysis module 325 in the server 320, and sends the analysis results to the user terminal's analysis report module 312 for presentation at the user interface.

The analytical method employed by data analysis module 325 is preferably a time-based or time-based approach. For example, the collected user data can be compared with people of the same type, etc., to more accurately predict, diagnose, and diagnose chronic diseases including stroke, hypertension, diabetes, senile dementia, sudden myocardial infarction, and cancer. treatment.

FIG. 4 shows a manner of storing user information in a server and an information sharing mechanism between users according to the present invention. In the server system according to the present invention, the information of each user (e.g., user 1, user 2 user n) is independent and relatively isolated from other users. Each user's information is stored in the server, and the user can successfully access the server only after determining the authentic and valid identity through the authentication of the authentication mechanism 402. After the user successfully logs into the server system, various personal information 404 is obtained, which includes personal records (ie, records measured by the vital sign measuring terminal 201), personal background survey data (for example, the physical condition of the user collected through questionnaires). , other information (such as the user's basic information, user name, password, birthday, language, etc.).

Preferably, different permissions and levels can also be designed for different users, such as general users, system administrators, physicians, medical institutions, and the like. The results of the above analysis can be transmitted to care facilities, doctors (regional medical facilities), patient-authorized caregivers, etc., according to different user rights or on demand.

The system according to the present invention also provides a function of sharing information between users. The user can obtain the health data information of the user concerned or its health assessment report through the server by sending the request to the attention object requesting attention. Each user can follow at least one other user. The user of interest, such as the family, friends, etc. of the user. Similarly, medical staff using the system can obtain any user reports with cardiovascular risk, and system administrators can also obtain relevant information via the network according to their authority.

Figure 5 shows the user interface for mutual attention and information sharing between users presented in the user application (a pp ) interface of the user terminal. As shown in Figure 5, users can follow the health information of family and friends through the server system. When the user enters the Follow Family page, they can see all the users who have followed. The user can add the attention user by inputting the invitation code or the user name of the object of interest, the E-ma i l, the mobile terminal device number, and the like, and waiting for the system and the object of interest to be reviewed. Users can get all the health analysis reports of the target and can cancel the attention at any time. In addition, the system according to the present invention supports a single contact between the user and the object of interest, for example, information can be sent to the object of interest and a call can be made. The user can also manually enter the vital sign data of the object of interest. In addition, all of the objects of interest can also be presented on top of the current concern object health analysis report, and the user can choose to view other users' health assessment reports.

Fig. 6 shows a basic flow chart for performing a health analysis independently by a user using a server system according to the present invention through a user terminal. As shown in Figure 6,

In step 600, the user logs in to the system through the user terminal to present an initial interface; in step 602, the server system detects and prompts the user whether it is a new user. If it is a new user, proceed to step 603 for registration and basic information background investigation; if it is not a new user, proceed to step 605 to prompt the user to log in.

In step 603, the user performs a new user registration, for example, by using a mobile phone number or an email number. To register, you can also customize your new username to register. Proceed to step 604 to provide supplemental information.

At step 604, the user is required to provide some necessary information (e.g., medical history surveys and life habit surveys, as will be described in more detail below). At the same time, the database on the server side creates a new record containing this information for the new user. Go to step 606.

In step 605, if the user has already registered, the system can be directly logged in. Go to step 606. At step 606, the user needs to make a new cadre measurement, such as measuring blood pressure, the system will list the available measurement devices, the user will select the device and prepare for the physiology measurement.

In step 607, after the user selects a specific measurement device, it is determined whether there is data on the measurement device that was last measured but not uploaded by the user. If yes, the process proceeds to step 608 to upload the data directly to the user terminal, and then proceeds to the step. 609 gathers new data; if there is no data not uploaded, it proceeds to step 609.

At step 609, the user begins measuring medical signs through the measurement device to perform a collection of vital data.

In step 610, it is judged whether the collected data is complete. If the obtained data is incomplete, return to step 609 to re-measure. After the system confirms that the data is complete, the system proceeds to step 611. Judging whether the collected data is complete, for example, whether the user serial number, the device number, the storage location on the device, and the vital sign data constitute a complete sequence of data can be determined.

In step 611, the collected data is uploaded to the server for data analysis process and a conclusion is drawn.

At step 612, the analyzed results are displayed to the user via feedback from the user terminal in the form of a report.

Figure 7 shows the flow of the comparative analysis function that the system provides to some users (such as doctors or health consultants, etc.). As shown in FIG. 7, after the special user logs in to the system in step 701, in step 702, data data of two or two periods of time (respectively in step 703 and step 704) of the individuals to be compared may be respectively selected. And at step 705, the analysis is performed and a conclusion is obtained, and the report is displayed at step 706. This function can be used to analyze, for example, changes in blood pressure before and after taking the drug, to determine the effects of the drug, and to analyze the effects of lowering blood pressure, uniformity, and duration. Alternatively, the analysis comparison function can also be provided to a normal user.

The user terminal according to the present invention provides a plurality of interaction functions with the user in addition to the function of connecting the measurement device for collecting the vital data and uploading the server for analysis. The interactive functions include, but are not limited to: body survey information, including medical history surveys and questionnaires; data collection, including manual input and device input measurement data, and user autonomous input Basic information, etc.; The health assessment report section includes the user's personal health assessment report and the health assessment report of the person concerned; and the system information section, including personal login information and system settings, system new message push, etc. Unrelated information, etc.

The information survey (such as medical history survey) made by the user is collected in a preferred manner, and the exemplary user interface display content is shown in FIG. These surveys help the system know if the user has previously been diagnosed with high blood pressure or if the user is a potential cardiovascular high risk patient to more accurately analyze user data. A large number of Yes/No in the questionnaire is used to avoid misuse and data obfuscation. If the user's answer to a question is not realistic or has changed, you can answer it again at any time. Table 1 below shows an exemplary questionnaire form.

Table 1 Questionnaire The data collection section allows the user to set up personal information such as gender, height, weight, body temperature, blood sugar and blood pressure, and basic health information. In addition to the user sign data automatically acquired by the sign measuring terminal described above, the user can also input the vital sign data by manual input. When the user data input is completed, the data is automatically uploaded to the server side of the system.

The big data analysis based health assessment report portion according to the present invention is a personal analysis report interface displayed by the user application. Before getting this report, the system needs to obtain data such as blood pressure, blood sugar, body temperature, weight and height of the user before analyzing. The manner in which the user's blood pressure measurement data is obtained has been described above and will not be described here.

Figure 9 schematically illustrates an exemplary interface of a user health assessment report. Because different ages have different fluctuation ranges at different times, beyond this range, there is a risk of cardiovascular disease. After obtaining the user data, the system will make a corresponding comparative analysis according to the user's gender, age, and test time. After the system analyzes the data, the user can get the icon analysis and data list of the individual's high pressure, low pressure and heart rate, and whether they have the heart. Risk of vascular disease. At the same time, the system also uses the big data platform that has accumulated a large number of known users and known cases to provide the percentage of health of users and peers; and according to the user's blood pressure awake/sleep cycle, the most timely sleep, exercise and meals Good time range. At the same time, users can view the history of their recent tests at any time, and click on the calendar icon to query the history of a certain day. The present invention is preferably presented to the user evaluation report in an intuitive form such as scoring, charting, etc., so that the user can more clearly find that his or her physical condition is abnormal, making the interaction effect more friendly.

Other system information includes registration, login information, personal information, system settings, new messages, and more. When the user opens the system application app, they can register or log in to the system. In the personal information page, users can edit personal information, including password modification. In the settings page, users can change users, select follower mode (only focus on themselves, focus on family, follow yourself and family), language switching (multilingual support), bind measurement devices, set push information time and view development System settings such as information. The new message page displays information that the system pushes to the user, and so on.

In addition, the system according to the present invention can also cooperate with the user's treatment, prevention and the like to cooperate with the user's medication reminding function. The user terminal can make a medication reminder for the user based on the medicine input by the user. The user can see the personal medicine list on the user terminal application or the web application, and can also add the medicine to the medicine list according to the actual needs, the system will arrange to remind the user to take the best time for the medicine, and the user can not only see the medication reminder arranged in time. , you can also see each drug For details, the user's operation can be done by simply adding the name of the drug, for example, by scanning the barcode, QR code, and photo uploading through the user terminal. Figure 10 schematically illustrates the medication reminder and the app user interface for adding medication.

According to the method and system of the present invention, the user can conveniently combine the practice of continuous sign variation analysis by using the mobile terminal device, can compare the individual user data with the spectrum population, and then establish an individual reference rule and can find the abnormality in time, and change the passive treatment to active prevention. .

According to the method and system of the present invention, the user can conveniently combine the practice of continuous sign variation analysis by using the measuring device, can compare the individual user data with the spectral population and then establish an individual reference law and can timely adjust and optimize the detection of the collected physical data of the measuring device. Time point.

According to the method and system of the present invention, the user can conveniently combine the practice of continuous sign variation analysis with the measuring device, can compare the individual user data with the spectral population and then establish an individual reference rule and can timely adjust and optimize the time for the user to take medication or receive treatment. point.

The present invention describes a dynamic monitoring and management system for cardiovascular and cerebrovascular risk diseases only by taking blood pressure monitoring as an example. Those skilled in the art can understand that the system and method of the present invention can also be applied to monitoring and management of other chronic diseases. Prevention and control. The system can realize the exchangeable medical records in the control of the condition of patients with chronic diseases; real-time and life-time monitoring of personal health status; make corresponding health advice based on real-time monitoring data and assist medical institutions to make health status diagnosis; The treatment response is monitored in real time (auxiliary reminder of optimal medication or treatment time). For ordinary users, it can help users monitor their personal health in real time, proactively prevent cardiovascular disease, and combine adaptive system recommendations to adjust their physical condition, healthy life, and green future. The system uses a development-oriented architecture that supports Unicom's other healthcare systems and expands its dynamic monitoring of vital signs to improve health care and healthcare services in China.

Those skilled in the art will appreciate that many modifications and variations are possible in light of the above disclosure. Some portions of the specification describe embodiments of the invention in terms of algorithms and symbolic representations of operations on information. These algorithmic descriptions and representations are commonly used by those skilled in the data processing arts to effectively convey their work to those skilled in the art. The operations described functionally, computationally, or logically are understood to be implemented by computer programs or equivalent circuits, microcode, and the like. In addition, it has been proven many times that it is convenient to arrange these operations as modules without loss of generality. The described operations and their associated modules can be implemented in software, firmware, hardware, or any combination thereof.

Any of the steps, operations, or processes described herein may be performed or implemented using one or more hardware or software modules, alone or in combination with other devices. In one embodiment The software modules are implemented using a computer program product comprising a computer readable medium containing computer program code, which can be executed by a computer processor for performing any or all of the steps, operations or processes described.

Embodiments of the invention may also relate to apparatus for performing the operations herein. The apparatus may be specially constructed for the required purposes, and/or it may comprise a general purpose computing device that is selectively activated or reconfigured by a computer program stored in a computer. Such a computer program can be stored in a non-transitory tangible computer readable storage medium or any type of medium suitable for storing electronic instructions, which can be coupled to a computer system bus. Additionally, any of the computing systems referred to in this specification can include a single processor or can be an architecture involving multiple processors for increased computing power.

Embodiments of the invention may also relate to products produced by the computing processes described herein. Such products may include information derived from a computing process, wherein the information is stored in a non-transitory tangible computer readable storage medium and may include any implementation of a computer program product or other data combination as described herein.

Other embodiments of the invention will be apparent to those skilled in the <RTIgt; The description and the examples are to be considered as illustrative only, and the true scope and spirit of the invention are defined by the claims.

Claims

1. A dynamic monitoring and management system for cardiovascular and cerebrovascular risks, the system includes at least one physical sign measurement terminal, a user terminal, a firewall, an authentication unit and a server, wherein the physical sign measurement terminal and the user terminal are connected , and the network interconnection between the user terminal and the server, which ensures the security of user information; ' ^ ', the authentication unit authenticates each user's unique user code and the user password associated with it , used to ensure that only authenticated users with access rights are granted access to the server;

The physical sign measurement terminal includes a communication module and a memory. The memory is used to store the physical sign data measured by the user through the physical sign measurement terminal, and transmits it to the user terminal through the communication module, and then uploads it to the user terminal through the user terminal. The server: after authenticating the uploaded data, the server transmits the authenticated data back to the corresponding user terminal;

The server is used to store the uploaded data, perform analysis based on the data, and send the analysis results to the user terminal to present to the user.

2. The system according to claim 1, wherein the physical sign measurement terminal is selected from one or more of a sphygmomanometer, a blood glucose meter, a thermometer, a heart rate meter, an electrocardiographic device, an electroencephalographic device, and a pulmonary function meter.

3. The system according to claim 1, wherein the user terminal interacts with the server and the physical sign measurement terminal through an interface application.

4. The system of claim 1, wherein the network is selected from a wired network, WiFi, Zigbee, WLAN, GPRS, cellular network, GSM network, 3G network, LTE network or CDMA network, Bluetooth, NFC, At least one of infrared, ultrasonic, Wire l e s s USB, RFI D.

5. The system of claim 1, wherein the user terminal is selected from at least one of a desktop computer, a laptop computer, a smart phone, a personal digital assistant, a tablet computer, a game console, and a multi-function mobile terminal.

6. The system according to claim 1, wherein the memory of the physical sign measurement terminal is provided with multiple user storage bits to match multiple different users.

7. The system of claim 1, wherein when a user connects to the physical sign measurement terminal for the first time, the physical sign measurement terminal creates a user position for the user in order to create a user record.

8. The system according to claim 1, wherein when the physical sign measurement terminal is connected to the user terminal, the identity of the physical sign measurement terminal is transmitted to the server for authentication through the user terminal.

9. The system of claim 1, wherein the server includes a database, a database communication module, an access control module, a data inspection module, a data analysis module and a session control module,

The database is used to store user information and data;

The database communication module controls all requests directed to the database;

The access control module is used to perform identity authentication verification of users who issue access server requests;

The data checking module is used to check the consistency and integrity of data;

The data analysis module is used to analyze the data and send the analysis results to the user terminal;

The session control module is used to manage the access control module, data inspection module, and data analysis module to allow data exchange between each module and the database communication module.

10. The system of claim 1, wherein the user terminal includes a data collection module and an analysis reporting module, wherein

The data collection module is used to collect data from the physical sign measurement terminal;

The analysis report module is used to present the data analysis results from the server on the user interface.

11. The system of claim 1, wherein each user's information in the server is independent and relatively isolated from other user information, and the user requests attention by sending a request to other users, and when the request After being accepted, the data of the concerned user is obtained through the server.

12. The system of claim 9, wherein the data analysis module performs data analysis based on chronobiology or chronomedicine.

13. The system of claim 1, wherein the user terminal uses a questionnaire to collect the user's information.

14. The system of claim 1, wherein the user terminal is used to remind the user to take medicine based on the medicine input by the user.

15. A method for dynamic monitoring and management of cardiovascular and cerebrovascular risks, the method runs in a system including at least one physical sign measurement terminal, a user terminal, a firewall, an authentication unit and a server, wherein the physical sign measurement terminal and all The user terminals and the user terminals and the server are interconnected via a network. The method includes the following steps:

a) The user logs in through the user terminal;

b) Detect and prompt whether the user is a new user; if so, proceed to step c; if not, Then enter step e;

c) User registers as a new user;

d) The user provides information and a new record containing the information of the new user is created in the server-side database;

e) User logs in to the server;

f) List the physical sign measurement terminals available for users to choose, and the user selects the terminal and performs physical sign measurement;

g) When the user selects a specific physical sign measurement device, determine whether there is data on the physical sign measurement terminal that was last measured by the user but has not been uploaded. If so, the data is uploaded to the user terminal and then proceeds to step h;

h) The user measures and collects physical sign data through the physical sign measurement device;

i) Determine whether the collected data is complete. If the obtained data is incomplete, return to step h and re-measure; when it is confirmed that the obtained data is complete, enter step j;

j) Upload the collected data to the server for data analysis;

k) Display the analyzed results to the user in the form of a report through user terminal feedback.