CN111477319A - Hypertension management system and method for realizing up-down linkage - Google Patents

Abstract

The invention provides a hypertension management system and method for realizing up-down linkage, which comprises a management terminal subsystem, an information capturing subsystem and a mobile terminal subsystem, wherein the information capturing subsystem and the mobile terminal subsystem are respectively connected with the management terminal subsystem. The invention realizes the integration and up-down linkage of high-quality medical resource doctors, basic community doctors and patients for the first time, namely the high-quality medical resource doctors conduct the basic community doctors to participate in the whole course and fine management of the hypertension of the patients under the control of quality, the doctor-patient interaction, the remote uploading of medical data, the control of grade doctors and the like are realized, the high-quality medical resources are guided to sink, the hypertension control capability of basic medical health institutions is improved, the hypertension control current situations of common people in communities and residents in remote areas are improved, and finally the cardiovascular disease risk is expected to be reduced.

Description

Hypertension management system and method for realizing up-down linkage

Technical Field

The invention belongs to the technical field of medical treatment, and particularly relates to a hypertension management system and method for realizing up-down linkage.

Background

Hypertension is a major risk factor for cardiovascular disease. Recent surveys show that the prevalence rate of hypertension in China is 27.9%, but the current hypertension control rate is only 16.8%, which is at a low level, and especially in rural, western and minority regions, causes a huge disease burden. Research shows that active prevention and control of hypertension is a core strategy for inhibiting development of cardiovascular and cerebrovascular diseases, and nearly 90% of hypertension contracted patients in China are distributed in primary hospitals, namely urban community health centers and rural community health centers. Therefore, primary hospitals are the primary battlefield for hypertension control. At present, a community mainly takes a two-level management mode as a main mode, namely different treatment and follow-up measures are carried out according to whether the blood pressure of a signed patient reaches the standard or not, however, the management mode is still in a passive state, the treatment measures and life suggestions of a community health service center are not effectively carried out and insisted on by the signed patient to a great extent, the compliance of the signed patient is not high, the daily follow-up is not carried out in time, and the effect of blood pressure control is influenced. Therefore, improvement of the current state of the art in the management of hypertension in the basic health institution is urgently needed.

Based on the problems existing in the current hypertension community prevention and treatment mode, how to most effectively utilize and integrate resources for contracted patients, community doctors and level hospitals and construct a long-acting hypertension chronic disease prevention and treatment mechanism is worthy of discussion. With the development of the current information age, the traditional hypertension management mode cannot meet the management of hypertension contracted patients in the primary community and remote areas. In view of the above situation, a set of specialized internet-based hypertension contracted patient-community-level hospital integrated management platform, a Red Shine cognitive management system of a direct management terminal website, an intelligent information capture subsystem and a contracted patient mobile phone applet are designed and developed, and at present, no specialized hypertension special disease management platform designed by a specialized medical team and integrating contracted patient-community-level hospital integration exists in China. The platform is expected to ensure that signed patients can be effectively managed by community doctors under the guidance of specialist doctors, and the community management capacity is improved in actual combat, so that the management status of hypertension in areas with underdeveloped medical resources is improved, the medical resources are optimized, and the social and economic costs are saved.

Disclosure of Invention

Aiming at the defects in the prior art, the hypertension is taken as a breakthrough, the integrated and up-and-down linked hypertension management system of high-quality medical resource doctors, basic community doctors and contracted patients based on the Internet is established, high-quality medical resources are guided to sink, the hypertension control capability of basic medical health institutions is improved, the hypertension control current situations of common people in communities and residents in remote areas are improved, and finally the cardiovascular morbidity risk is expected to be reduced.

In order to achieve the above purpose, the invention adopts the technical scheme that:

the scheme provides a hypertension management system for realizing up-down linkage, which comprises a management terminal subsystem, an information capture subsystem and a mobile terminal subsystem, wherein the information capture subsystem and the mobile terminal subsystem are respectively connected with the management terminal subsystem;

the management terminal subsystem is used for acquiring and analyzing identity information and medical information of the signed patient and family self-test blood pressure data of the signed patient, and realizing information interaction and doctor-patient communication between the level hospital and the community hospital;

the information capturing subsystem is used for identifying and acquiring the identity information and the medical information of the signed patient and transmitting the identity information and the medical information of the signed patient to the management terminal subsystem;

and the mobile terminal subsystem is used for acquiring the family self-testing blood pressure data of the signed patient and uploading the family self-testing blood pressure data to the management terminal subsystem.

Furthermore, the management terminal subsystem comprises an information input unit, an information processing unit, an information storage unit and a statistical analysis unit, wherein the information input unit is respectively connected with the information capture subsystem and the mobile terminal subsystem;

the information input unit is used for acquiring the identity information, medical information and family self-testing blood pressure data of the signed patient and sending the identity information, medical information and family self-testing blood pressure data to the information processing unit;

the information processing unit is used for evaluating cardiovascular risk and health management capability of the signed patient according to the identity information, medical information and family self-testing blood pressure data of the signed patient;

the information storage unit is used for storing identity information and medical information of signed patients and cardiovascular risk and health management capability evaluation information corresponding to the identity information and medical information, and the identity information and medical information are used for being consulted by a level hospital and a community hospital;

the statistical analysis unit is used for managing the number of the signed patients, analyzing the accuracy of the prescription and analyzing the medical information of the signed patients.

Still further, the management terminal subsystem is managed by community physicians and level hospital physicians.

Still further, the information capturing subsystem comprises a first microprocessor, and an identity recognition unit, an information conversion unit, an information processing unit and a docking unit which are respectively connected with the first microprocessor, wherein the first microprocessor is connected with the information input unit;

the identity recognition unit is used for recognizing the identity information of the contracted patient;

the information conversion unit is used for butting the remote dynamic blood pressure analysis platform and converting and displaying the medical information transmitted by the remote dynamic blood pressure analysis platform;

the docking unit is used for docking a community L is system and realizing interconnection and intercommunication with community medical data;

the first microprocessor is used for integrating the identity information of the signed patient, the medical information transmitted by the remote dynamic blood pressure analysis platform and the community medical data and transmitting the integrated information to the management terminal subsystem;

and the information processing unit is used for calculating and quantizing medical data in the hypertension management system and carrying out layering and classified management on contracted patients.

Still further, the first microprocessor comprises a singlechip chip U1, a display circuit and an A/D conversion circuit;

a P1.0 pin, a P1.1 pin, a P1.2 pin, a P1.3 pin, a P1.4 pin, a P1.5 pin, a P1.6 pin, a P3.6 pin and a P3.7 pin of the chip U1 are respectively connected to the a/D converter, a P2.4 pin, a P2.5 pin, a P2.6 pin, a P0.0 pin, a P0.1 pin, a P0.2 pin, a P0.3 pin, a P0.4 pin, a P0.5 pin, a P0.6 pin and a P0.7 pin of the chip U1 are respectively connected to the display circuit, an XTA 733 pin of the chip U6325 is respectively connected to one end of the crystal oscillator X1 and one end of the capacitor C1, an XTA L pin of the chip U1 is respectively connected to the other end of the crystal oscillator X1 and one end of the capacitor C2, an RST pin RST 34 of the chip U6337 is respectively connected to the capacitor EA 9634 and the capacitor EA 3C 3648 and the other end of the capacitor C3626 and the capacitor C3648 is respectively connected to the capacitor C3626;

the display circuit comprises a display chip U2, a VSS pin of the chip U2 is grounded, a VDD pin of the chip U2 is connected with a power supply, an RS pin of the chip U2 is connected with a P2.4 pin of the chip U1, a RW pin of the chip U2 is connected with a P2.5 pin of the chip U1, an E pin of the chip U2 is connected with a P2.6 pin of the chip U1, a D2 pin of the chip U2 is connected with a P0.0 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.1 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.2 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.3 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.4 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.6 pin of the chip U2, and a P0.3 pin of the chip U2 is connected with a chip U2 pin of the chip U2, and a chip U2 pin of the, the D7 pin of the chip U2 is connected with the P0.7 pin of the chip U1;

the A/D conversion circuit comprises a conversion chip U3, a START pin of the chip U3 is connected with a P1.2 pin of the chip U1, an EOC pin of the chip U3 is connected with a P1.1 pin of the chip U1, an OUTPUTENAB L E pin of the chip U3 is connected with a P1.0 pin of the chip U1, a C L K pin of the chip U3 is connected with a P1.4 pin of the chip U1, an ADD A pin of the chip U3 is connected with a P1.4 pin of the chip U1, an ADD B pin of the chip U3 is connected with a P1.5 pin of the chip U1, and a C pin of the chip U2 is connected with a P1.6 pin of the chip U1.

Furthermore, the mobile terminal subsystem comprises a central processing unit, and a second microprocessor, a display unit, an information reading and writing unit, a wireless Bluetooth sensing unit and an information transceiving unit which are respectively connected with the central processing unit, wherein the central processing unit is connected with an information input unit;

the wireless Bluetooth sensing unit is used for connecting the electronic wearing equipment of the signed patient through a wireless network or Bluetooth, acquiring the family self-test blood pressure data of the signed patient and sending the family self-test blood pressure data to the second microprocessor;

the second microprocessor is used for sending out early warning information to the signed patient according to the received blood pressure information and sending out follow-up plan reminding to the signed patient;

the information reading and writing unit is used for sending the text information, the voice information and the video edited by the signed patient to the information receiving and sending unit;

the information receiving and sending unit is used for realizing information interaction between doctors and patients according to the family self-testing blood pressure data of the contracted patients and the received text information, voice information and video;

the display unit is used for displaying personal information and blood pressure information of the contracted patient and corresponding information of a managed doctor, follow-up visit information and a health lecture hall;

and the central processing unit is used for integrating the information sent by the signed patient and the family self-testing blood pressure data and sending the information to the management terminal subsystem.

Still further, the second microprocessor comprises an alarm subunit and a reminding subunit;

the alarm subunit is used for sending early warning information to the contracted patient according to the received blood pressure information;

and the reminding subunit is used for sending a follow-up visit plan reminder to the contracted patient.

Still further, the second microprocessor comprises a single chip U4 and a conversion circuit U5;

an XTA L1 pin of the chip U4 is respectively connected with one end of a crystal oscillator X2 and one end of a capacitor C4, an XTA L2 pin of the chip U4 is respectively connected with the other end of a crystal oscillator X2 and one end of a capacitor C5, a RST pin of the chip U4 is respectively connected with one end of a capacitor C6 and one end of a resistor R6, the other end of the capacitor C6 is respectively connected with an EA pin of the chip U4 and a power supply, the other end of the resistor R2 is respectively connected with the other end of the capacitor C4 and the other end of the capacitor C5 and grounded, a P3.7 pin of the chip U4 is connected with one end of a horn L S1, the other end of the horn L S1 is grounded, a P1.0 pin, a P1.1 pin, a P1.2 pin, a P1.3 pin, a P1.4 pin, a P1.5 pin, a P1.6 pin and a P1.7 pin of the chip U4 are respectively connected with the conversion circuit;

the conversion circuit comprises a conversion chip U5; the VREF-pin of the chip U5 is connected with the ADDC pin, the ADDB pin and the ADDA pin of the chip U5 respectively and grounded, the VREF + pin of the chip U5 is connected with a power supply, the IN0 pin of the chip U5 is connected with the sliding end of the sliding resistor RV1, the first fixed end of the sliding resistor RV1 is grounded, and the second fixed end of the sliding resistor RV1 is connected with the power supply.

Based on the system, the invention also provides a hypertension management method for realizing up-down linkage, which comprises the following steps:

s1, identifying identity information of the contracted patient;

s2, medical information of contracted patients is obtained by docking a remote dynamic blood pressure analysis platform and a community L is system;

s3, acquiring family self-testing blood pressure data of contracted patients;

and S4, according to the identity information, medical information and family self-testing blood pressure information of the contracted patient, evaluating the cardiovascular risk and health management ability of the contracted patient by a community doctor and a grade hospital doctor, and realizing information interaction and doctor-patient communication between the grade hospital and the community hospital.

The invention has the beneficial effects that:

(1) the invention realizes the integration and up-down linkage of high-quality medical resource doctors, basic community doctors and patients for the first time, namely the high-quality medical resource doctors conduct the basic community doctors to participate in the whole course and fine management of the hypertension of the patients under the quality control, the doctor-patient interaction, the remote uploading of medical data, the quality control of grade doctors and the like are realized, the high-quality medical resources are guided to sink, the hypertension control capability of basic medical health institutions is improved, and the hypertension control current situations of common people in communities and residents in remote areas are improved;

(2) the intelligent information capture subsystem is integrated, real-time data, character data, picture data and voice data are converted into system data through data uploading or voice sending, the labor cost and time consumption of community doctors are greatly saved, the homogeneity of the examination of signed patients is guaranteed, and unnecessary time consumption and repeated work of the community doctors are reduced.

Drawings

FIG. 1 is a schematic diagram of the system of the present invention.

Fig. 2 is a schematic diagram of a circuit connection between the single chip of the first microprocessor and the display circuit in this embodiment.

FIG. 3 is a schematic diagram of a conversion circuit of the first microprocessor according to the present embodiment.

FIG. 4 is a circuit diagram of a second microprocessor according to the present embodiment.

FIG. 5 is a flow chart of the method of the present invention.

Detailed Description

The following description of the embodiments of the present invention is provided to facilitate the understanding of the present invention by those skilled in the art, but it should be understood that the present invention is not limited to the scope of the embodiments, and it will be apparent to those skilled in the art that various changes may be made without departing from the spirit and scope of the invention as defined and defined in the appended claims, and all matters produced by the invention using the inventive concept are protected.

Example 1

The system comprises a management terminal subsystem, an information capture subsystem and a mobile terminal subsystem, wherein the information capture subsystem and the mobile terminal subsystem are respectively connected with the management terminal subsystem, the management terminal subsystem is used for obtaining and analyzing identity information, medical information and family self-testing blood pressure data of a signed patient, realizing information interaction and doctor-patient communication between a grade hospital and a community hospital, the information capture subsystem is used for identifying and obtaining identity information and medical information of the signed patient and transmitting the identity information and demographic information of the signed patient to the management terminal subsystem, the mobile terminal subsystem is used for obtaining family self-testing blood pressure data of the signed patient and uploading the family self-testing blood pressure data to the management terminal subsystem, the management terminal subsystem comprises an information input unit, an information processing unit, an information storage unit and a statistical analysis unit, wherein the information input unit is respectively connected with the information capture subsystem and the community information capturing subsystem and the mobile terminal subsystem, the information processing unit is connected with the information input unit, the information processing unit, the information storage unit is connected with the information processing unit, the information storage unit and the management unit, the management unit is used for receiving the family self-testing information, displaying the family self-testing information, the information input unit, the management terminal subsystem is used for receiving the family self-testing information, the information input unit, the microprocessor, the information input unit, the remote management unit, the information input unit, the microprocessor, the remote management unit, the microprocessor.

As shown in fig. 2, the first microprocessor includes a single chip U, a display circuit and an a/D converter, a pin P1.0, a pin P1.1, a pin P1.2, a pin P1.3, a pin P1.4, a pin P1.5, a pin P1.6, a pin P3.6 and a pin P3.7 of the chip U are respectively connected to the a/D converter, a pin P2.4, a pin P2.5, a pin P2.6, a pin P0.0, a pin P0.1, a pin P0.2, a pin P0.3, a pin P0.4, a pin P0.5, a pin P0.6 and a pin P0.7 of the chip U are respectively connected to the display circuit, a pin XTA 1 of the chip U is respectively connected to one end of the crystal oscillator X and one end of the capacitor C, a pin XTA 2 of the chip U is respectively connected to the other end of the crystal oscillator X and one end of the pin C, a pin RST of the chip U0.5 is connected to the pin R, a pin R0, a pin R2, a pin of the chip U is connected to the chip C, a pin R2, a pin C, a pin.

As shown in FIG. 3, the conversion circuit comprises a conversion chip U3, the START pin of the chip U3 is connected with the P1.2 pin of the chip U1, the EOC pin of the chip U3 is connected with the P1.1 pin of the chip U1, the OUTPUTENAB L E pin of the chip U3 is connected with the P1.0 pin of the chip U1, the C L K pin of the chip U3 is connected with the P1.4 pin of the chip U1, the ADD A pin of the chip U3 is connected with the P1.4 pin of the chip U1, the ADD B pin of the chip U3 is connected with the P1.5 pin of the chip U1, and the ADD C pin of the chip U2 is connected with the P1.6 pin of the chip U1.

As shown IN FIG. 4, the second microprocessor includes a single chip U4 and a conversion circuit U4, the XTA 4 1 pin of the chip U4 is connected to one end of a crystal oscillator X4 and one end of a capacitor C4, the XTA 4 2 pin of the chip U4 is connected to the other end of the crystal oscillator X4 and one end of the capacitor C4, the RST pin of the chip U4 is connected to one end of the capacitor C4 and one end of a resistor R4, the other end of the capacitor C4 is connected to EA pin and power supply of the chip U4, the other end of the resistor R4 is connected to the other end of the capacitor C4 and grounded, the P3.7 pin of the chip U4 is connected to one end of a horn 4S 4, the other end of the horn 4S 4 is grounded, the P1.0 pin, P1.1.1 pin, P1.2 pin, P1.3, P1.4 pin, P1.5 pin, the chip U4 is connected to ground, the chip U4 is connected to the chip, the chip U4, the chip is connected to ground, the chip U4 is connected to the chip VREF + VREF pin, the chip is connected to the chip P1-VREF pin, the chip-VREF pin of the chip 100, the chip-VREF pin of the chip-VREF pin, the chip-.

In this embodiment, the management terminal subsystem is managed by community physicians and level hospital physicians, and is composed of an information entry unit, an information processing system subsystem, an information storage unit, a statistical analysis unit, and an information transceiving unit. The management terminal subsystem collects patient information through the data capture system and the mobile terminal subsystem, and is remotely connected with the mobile terminal subsystem through the information transceiving unit, the integrated system (Red shinechanic disease management) is a main medium for realizing integration and up-and-down linkage of high-quality medical resource doctors, basic community doctors and patients, and the main functions of the integrated system comprise a doctor end (level hospitals and community hospitals) information input unit, an information processing unit, an information storage unit, a statistical analysis unit and an information transceiving unit. The information entry unit comprises various demographic data, medical data and the like of the contracted patient. The information processing unit automatically evaluates 10-year cardiovascular risk, health management capability and the like of the patient according to various demographic data and medical data of the contracted patient, and is convenient for layering and classified management of the patient. The information storage unit realizes data storage and can be consulted by a grade hospital and a community hospital together, and the evaluation, quality control and the like of the grade hospital on the medical capability of the community hospital are realized. The statistical analysis unit mainly realizes the analysis of the number of the system management persons, the effective number of the system management persons, the correct proportion of the prescription and various medical data, and is convenient for the statistics of medical big data. The information receiving and sending unit mainly realizes communication between the level hospital and the community hospital to continue education in medicine, and realizes uploading of patient data, doctor-patient communication and the like through WeChat small program mediation.

In the embodiment, the data capture system establishes an integrated system based on an identity recognition unit, a basic community L is system docking unit and a remote dynamic blood pressure analysis platform docking through a first microprocessor, the first microprocessor transmits data into a management terminal subsystem through an information input unit, the homogeneity of checking of signed patients is guaranteed, unnecessary time consumption and repeated work of community doctors are reduced, the data capture system comprises the identity recognition unit, information conversion and capture are achieved through a conversion system based on real-time data, character data, picture data and voice data, related data information is displayed on a screen through the first microprocessor, fine processing and error correction of the data are completed through an information processing unit, and the management terminal subsystem is uploaded through the data docking unit to store, process and further analyze the data.

In this embodiment, the mobile terminal subsystem mainly reports the family self-test blood pressure data of the patient to the integrated system to realize doctor-patient communication, and includes a central processing module, a second microprocessor, a display unit, an information reading and writing unit, a wireless bluetooth transmission subsystem and an information transceiving unit module, wherein the second microprocessor, the display unit, the information reading and writing unit, the wireless bluetooth transmission subsystem and the information transceiving unit are all electrically connected with the central processing module. The second microprocessor comprises an alarm subunit system and a reminding subunit, and is used for reminding the patient when the blood pressure of the patient rises to exceed a safety range and carrying out alarm reminding on the management terminal subsystem. The display unit displays patient information, blood pressure data information, medical staff information corresponding to the patient, follow-up visit information and health lecture hall information. The information reading and writing unit is used for manually uploading blood pressure data to a patient, communicating doctors and patients with corresponding medical care and filling in questionnaire survey. The wireless Bluetooth transmission subsystem is used for automatically uploading blood pressure data. The information receiving and sending unit is used for carrying out doctor-patient communication and receiving health education and training with corresponding medical care, the second microprocessor is provided with an early warning value and a time reminding function for sending out early warning or follow-up visit reminding and the like to the patient, and the central processing unit realizes data integration and uploads the data to the Red Shine pharmaceutical discrete management system for storage, processing and further analysis.

Example 2

As shown in fig. 5, based on the above system, the present invention also discloses a hypertension management method for realizing up-down linkage, which comprises the following steps:

s1, identifying identity information of the contracted patient;

s2, medical information of contracted patients is obtained by docking a remote dynamic blood pressure analysis platform and a community L is system;

s3, acquiring family self-testing blood pressure data of contracted patients;

and S4, according to the identity information, medical information and family self-testing blood pressure information of the contracted patient, evaluating the cardiovascular risk and health management ability of the contracted patient by a community doctor and a grade hospital doctor, and realizing information interaction and doctor-patient communication between the grade hospital and the community hospital.

By the design, unnecessary repeated labor of community doctors is saved, an integrated and up-and-down linkage hypertension management system and method of high-quality medical resource doctors-basic community doctors-patients based on the Internet are established, high-quality medical resources are guided to sink, the hypertension control capability of basic medical health institutions is improved, and the hypertension control current situations of community people and residents in remote areas are improved.

Claims (9)

1. A hypertension management system for realizing up-down linkage is characterized by comprising a management terminal subsystem, an information capturing subsystem and a mobile terminal subsystem, wherein the information capturing subsystem and the mobile terminal subsystem are respectively connected with the management terminal subsystem;

the management terminal subsystem is used for acquiring and analyzing identity information and medical information of the signed patient and family self-test blood pressure data of the signed patient, and realizing information interaction and doctor-patient communication between the level hospital and the community hospital;

the information capturing subsystem is used for identifying and acquiring the identity information and the medical information of the signed patient and transmitting the identity information and the medical information of the signed patient to the management terminal subsystem;

and the mobile terminal subsystem is used for acquiring the family self-testing blood pressure data of the signed patient and uploading the family self-testing blood pressure data to the management terminal subsystem.

2. The hypertension management system achieving the up-down linkage according to claim 1, wherein the management terminal subsystem includes an information input unit connected to the information capturing subsystem and the mobile terminal subsystem, an information processing unit connected to the information input unit, an information storage unit connected to the information processing unit, and a statistical analysis unit connected to the information storage unit;

the information input unit is used for acquiring the identity information, medical information and family self-testing blood pressure data of the signed patient and sending the identity information, medical information and family self-testing blood pressure data to the information processing unit;

the information processing unit is used for evaluating cardiovascular risk and health management capability of the signed patient according to the identity information, medical information and family self-testing blood pressure data of the signed patient;

the information storage unit is used for storing identity information and medical information of signed patients and cardiovascular risk and health management capability evaluation information corresponding to the identity information and medical information, and the identity information and medical information are used for being consulted by a level hospital and a community hospital;

the statistical analysis unit is used for managing the number of the signed patients, analyzing the accuracy of the prescription and analyzing the medical information of the signed patients.

3. The system for managing hypertension according to claim 2, wherein the management terminal subsystem is managed by a community physician and a level hospital physician.

4. The hypertension management system achieving the up-down linkage according to claim 2, wherein the information capturing subsystem comprises a first microprocessor, and an identity recognition unit, an information conversion unit, an information processing unit and a docking unit which are respectively connected with the first microprocessor, wherein the first microprocessor is connected with the information entry unit;

the identity recognition unit is used for recognizing the identity information of the contracted patient;

the information conversion unit is used for butting the remote dynamic blood pressure analysis platform and converting and displaying the medical information transmitted by the remote dynamic blood pressure analysis platform;

the docking unit is used for docking a community L is system and realizing interconnection and intercommunication with community medical data;

the first microprocessor is used for integrating the identity information of the signed patient, the medical information transmitted by the remote dynamic blood pressure analysis platform and the community medical data and transmitting the integrated information to the management terminal subsystem;

and the information processing unit is used for calculating and quantizing medical data in the hypertension management system and carrying out layering and classified management on contracted patients.

5. The system for managing hypertension according to claim 4, wherein the first microprocessor comprises a single-chip microcomputer U1, a display circuit and an a/D conversion circuit;

a P1.0 pin, a P1.1 pin, a P1.2 pin, a P1.3 pin, a P1.4 pin, a P1.5 pin, a P1.6 pin, a P3.6 pin and a P3.7 pin of the chip U1 are respectively connected to the a/D converter, a P2.4 pin, a P2.5 pin, a P2.6 pin, a P0.0 pin, a P0.1 pin, a P0.2 pin, a P0.3 pin, a P0.4 pin, a P0.5 pin, a P0.6 pin and a P0.7 pin of the chip U1 are respectively connected to the display circuit, an XTA 733 pin of the chip U6325 is respectively connected to one end of the crystal oscillator X1 and one end of the capacitor C1, an XTA L pin of the chip U1 is respectively connected to the other end of the crystal oscillator X1 and one end of the capacitor C2, an RST pin RST 34 of the chip U6337 is respectively connected to the capacitor EA 9634 and the capacitor EA 3C 3648 and the other end of the capacitor C3626 and the capacitor C3648 is respectively connected to the capacitor C3626;

the display circuit comprises a display chip U2, a VSS pin of the chip U2 is grounded, a VDD pin of the chip U2 is connected with a power supply, an RS pin of the chip U2 is connected with a P2.4 pin of the chip U1, a RW pin of the chip U2 is connected with a P2.5 pin of the chip U1, an E pin of the chip U2 is connected with a P2.6 pin of the chip U1, a D2 pin of the chip U2 is connected with a P0.0 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.1 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.2 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.3 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.4 pin of the chip U2, a D2 pin of the chip U2 is connected with a P0.6 pin of the chip U2, and a P0.3 pin of the chip U2 is connected with a chip U2 pin of the chip U2, and a chip U2 pin of the, the D7 pin of the chip U2 is connected with the P0.7 pin of the chip U1;

the A/D conversion circuit comprises a conversion chip U3, a START pin of the chip U3 is connected with a P1.2 pin of the chip U1, an EOC pin of the chip U3 is connected with a P1.1 pin of the chip U1, an OUTPUT ENAB L E pin of the chip U3 is connected with a P1.0 pin of the chip U1, a C L K pin of the chip U3 is connected with a P1.4 pin of the chip U1, an ADD A pin of the chip U3 is connected with a P1.4 pin of the chip U1, an ADD B pin of the chip U3 is connected with a P1.5 pin of the chip U1, and a C pin of the chip U2 is connected with a P1.6 pin of the chip U1.

6. The hypertension management system realizing up-down linkage according to claim 2, wherein the mobile terminal subsystem comprises a central processing unit, and a second microprocessor, a display unit, an information reading and writing unit, a wireless bluetooth sensing unit and an information transceiving unit which are respectively connected with the central processing unit, wherein the central processing unit is connected with an information input unit;

the wireless Bluetooth sensing unit is used for connecting the electronic wearing equipment of the signed patient through a wireless network or Bluetooth, acquiring the family self-test blood pressure data of the signed patient and sending the family self-test blood pressure data to the second microprocessor;

the second microprocessor is used for sending out early warning information to the signed patient according to the received blood pressure information and sending out follow-up plan reminding to the signed patient;

the information reading and writing unit is used for sending the text information, the voice information and the video edited by the signed patient to the information receiving and sending unit;

the information receiving and sending unit is used for realizing information interaction between doctors and patients according to the family self-testing blood pressure data of the contracted patients and the received text information, voice information and video;

the display unit is used for displaying personal information and blood pressure information of the contracted patient and corresponding information of a managed doctor, follow-up visit information and a health lecture hall;

and the central processing unit is used for integrating the information sent by the signed patient and the family self-testing blood pressure data and sending the information to the management terminal subsystem.

7. The system for managing hypertension according to claim 6, wherein the second microprocessor comprises an alarm subunit and a reminding subunit;

the alarm subunit is used for sending early warning information to the contracted patient according to the received blood pressure information;

and the reminding subunit is used for sending a follow-up visit plan reminder to the contracted patient.

8. The system for hypertension management according to claim 7, wherein the second microprocessor comprises a single-chip U4 and a conversion circuit U5;

an XTA L1 pin of the chip U4 is respectively connected with one end of a crystal oscillator X2 and one end of a capacitor C4, an XTA L2 pin of the chip U4 is respectively connected with the other end of a crystal oscillator X2 and one end of a capacitor C5, a RST pin of the chip U4 is respectively connected with one end of a capacitor C6 and one end of a resistor R6, the other end of the capacitor C6 is respectively connected with an EA pin of the chip U4 and a power supply, the other end of the resistor R2 is respectively connected with the other end of the capacitor C4 and the other end of the capacitor C5 and grounded, a P3.7 pin of the chip U4 is connected with one end of a horn L S1, the other end of the horn L S1 is grounded, a P1.0 pin, a P1.1 pin, a P1.2 pin, a P1.3 pin, a P1.4 pin, a P1.5 pin, a P1.6 pin and a P1.7 pin of the chip U4 are respectively connected with the conversion circuit;

the conversion circuit comprises a conversion chip U5; the VREF-pin of the chip U5 is connected with the ADDC pin, the ADDB pin and the ADDA pin of the chip U5 respectively and grounded, the VREF + pin of the chip U5 is connected with a power supply, the IN0 pin of the chip U5 is connected with the sliding end of the sliding resistor RV1, the first fixed end of the sliding resistor RV1 is grounded, and the second fixed end of the sliding resistor RV1 is connected with the power supply.

9. A hypertension management method for realizing up-down linkage is characterized by comprising the following steps:

s1, identifying identity information of the contracted patient;

s2, medical information of contracted patients is obtained by docking a remote dynamic blood pressure analysis platform and a community L is system;

s3, acquiring family self-testing blood pressure data of contracted patients;

and S4, according to the identity information, medical information and family self-testing blood pressure information of the contracted patient, evaluating the cardiovascular risk and health management ability of the contracted patient by a community doctor and a grade hospital doctor, and realizing information interaction and doctor-patient communication between the grade hospital and the community hospital.

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