CN112735582A - Quick and simple follow-up system and follow-up method for implantable medical equipment - Google Patents

Abstract

The invention discloses a quick and simple follow-up visit system of implanted medical equipment, which comprises external hardware, an implanted pulse generator, a patient terminal, a server, a doctor client, a patient and a family client; the Bluetooth communication function of the implanted pulse generator is started through external hardware, and when the implanted pulse generator detects that the external hardware starts the Bluetooth communication function, the implanted pulse generator actively establishes a Bluetooth communication link with a patient terminal carried by a patient; the implanted pulse generator actively transmits follow-up data which is equal to follow-up data when a program controller is used for follow-up to a patient terminal; the patient terminal transmits the follow-up data to the server through a 5G or WI-FI network; a doctor can check and diagnose detailed follow-up data of a patient through a doctor client; the patient and the family members can also check the basic information of the current follow-up visit through the client of the patient and the family members; the invention reduces the economic burden of patients and hospitals, reduces the working difficulty of medical staff and is beneficial to strengthening the postoperative management of patients.

Description

Quick and simple follow-up system and follow-up method for implantable medical equipment

Technical Field

The invention relates to the technical field of medical instruments, in particular to a quick and simple follow-up system and a follow-up method for implantable medical equipment.

Background

With the development of scientific technology and medical technology, implantable medical devices have been used for a longer time in the human body, and devices such as implantable cardiac pacemakers, defibrillators, and implantable neurostimulators, which are implanted once, can generally work in the human body for 15 to 20 years. In order to monitor the operational status of these devices and the physiological status of the patient in which the device is implanted, follow-up visits to the implanted device and the patient in which the device is implanted must be made on a regular basis. Therefore, the patient needs to visit the hospital regularly, and during the visit, the doctor generally reads the working parameters of the equipment and the physiological parameters of the patient through the program controller to judge whether the working conditions of the equipment and the physiological conditions of the patient are normal, and meanwhile, the doctor adjusts the working parameters of the implanted equipment according to the needs to achieve the best treatment effect on the patient.

In the conventional follow-up mode, a manufacturer of implant devices typically provides an in vitro programmer for a hospital in follow-up treatment to read and set parameters of the patient implant device. However, due to the problems of medical cost and resource allocation, it is impossible to equip all hospitals with program-controlled instruments, which brings inconvenience to follow-up visits of some patients. In some remote areas or cities, patients cannot receive the implant therapy of the implanted medical device in a local hospital due to the falling behind medical technology level, and need to go to a hospital in a developed city for the implant therapy. Meanwhile, the local hospital is lack of a program control instrument or experienced medical care personnel, and cannot get professional postoperative follow-up visits in the local hospital. Patients often spend a great deal of time and money going to hospitals in developed cities in order to get better postoperative follow-up.

With the more mature technology of the implanted equipment, the operation of the implanted equipment becomes more and more stable, and the requirement for modifying the parameters of the equipment in the follow-up process is less and less. Most patient follow-up is mainly to confirm that the patient and its equipment are in normal working condition. Currently, implant equipment manufacturers also introduce systems similar to remote follow-up and remote monitoring systems, but due to power consumption, existing systems can only transmit limited data, such as alarm notifications in case of emergency and daily vital physiological parameters. Therefore, a simple follow-up mode for the implanted device is urgently needed to reduce the cost of each link of manufacturers, doctors and patients and realize the maximum utilization of medical resources.

Disclosure of Invention

The invention aims to provide a quick, simple and convenient follow-up system of implantable medical equipment and a follow-up method thereof, which realize the quick, simple and convenient follow-up system of full-function data in a Bluetooth communication and mobile internet mode under the condition of not additionally consuming the power consumption of the implantable cardiac equipment and break through the traditional mode that the follow-up of the full-function data can be carried out only by using a program control instrument.

The invention is realized by the following technical scheme:

a quick and simple follow-up visit system of an implanted medical device comprises external hardware, an implanted pulse generator, a patient terminal, a server, a doctor client, a patient and a family client;

the external hardware is used for starting the Bluetooth communication function of the implanted pulse generator and triggering the implanted pulse generator to transmit complete follow-up data;

an implantable pulse generator implanted within a human body; after detecting that the external hardware starts the Bluetooth function, the implanted pulse generator actively establishes a Bluetooth communication link with the patient terminal and transmits follow-up data to the patient terminal;

the patient terminal receives and verifies the follow-up visit data and then transmits the follow-up visit data to the server through a 5G or WI-FI network;

the server receives the follow-up data transmitted by the patient terminal, diagnoses and analyzes the follow-up data according to various parameter thresholds set by doctors, and informs the corresponding doctors, patients and family members of the patients of the diagnosis and analysis results; the server stores follow-up data of the patient for the doctor and the patient to check through the doctor client and the patient and the family client;

a doctor client for acquiring and displaying follow-up visit data of a patient;

the system comprises a patient and family client, wherein the patient and family client acquires and displays follow-up visit data of the patient.

Further, the patient terminal comprises a Bluetooth communication module, a first network communication module, a first authorization and authentication module and a local storage module; the Bluetooth communication module is used for self broadcasting and follow-up data receiving, after the implantable pulse generator establishes a Bluetooth link with the patient terminal, the implantable pulse generator firstly needs to send a self equipment serial number to the patient terminal, and the patient terminal verifies the equipment serial number through the first authorization authentication module and receives data after the verification is passed; the first network communication module is used for transmitting follow-up data to the server; the first authorization authentication module is used for verifying a user name and a password of a patient, data transmission between the patient terminal and the server and whether the implanted pulse generator in the patient body is bound with a current user or not, and data transmission between the patient terminal and the implanted pulse generator; the local storage module is used for storing and recording part of the transmission log and part of the follow-up data.

Further, the server comprises a second network communication module, a data processing module, a second authorization and authentication module, a database module, a diagnosis and analysis module and a local log recording module; the second network communication module is used for receiving and transmitting data and sending alarm data; the data processing module is used for threshold setting and data storage; the second authorization and authentication module is mainly used for user management and data access authority management; the user management is used for verifying a user name and a password of the user, and the data access authority management is used for managing the data type accessed by the user; the database module is used for storing user information, implanted equipment information and follow-up visit data; the diagnosis and analysis module is used for diagnosing and analyzing follow-up data, analyzing the follow-up data according to various parameter thresholds set by a doctor and sending the follow-up data to the corresponding doctor and patient by the second network communication module after the follow-up data is analyzed; the local log recording module is used for storing part of user access records and follow-up data transmission records.

Further, the doctor client comprises a third network communication module, a first follow-up visit data display module, a third authorization authentication module and a configuration module; the third network communication module is used for receiving data requests and alarm information; the first follow-up data display module is used for displaying follow-up data of a patient; the third authorization authentication module verifies a user name and a password of a doctor for data transmission between the doctor client and the server; the configuration module is used for configuring a follow-up data alarm threshold value and an alarm information notification mode.

Further, the patient and family client comprises a fourth network communication module, a second follow-up data display module and a fourth authorization authentication module; the fourth network communication module is used for receiving a follow-up visit data request and alarm information; the second follow-up data display module is used for displaying follow-up data of the patient; and the fourth authorization authentication module verifies user names and passwords of patients and family members for data transmission between the patient and family member clients and the server.

Further, the external hardware is a magnet, and the Bluetooth function and the complete follow-up data transmission function of the implanted pulse generator can be started by controlling the magnitude of magnetic flux and the effective contact time of the magnet and the implanted pulse generator.

Further, the server is provided with a public network interface.

Further, the doctor client device is a personal computer and a mobile phone with 5G or WI-FI functions

Further, the patient and family client devices are mobile phones with 5G or WI-FI functionality.

Further, a quick and simple follow-up method for implantable medical equipment comprises the following steps:

s1, preparing before follow-up visit of patient terminal equipment; opening the Bluetooth and network functions of the patient terminal equipment to ensure that the Bluetooth and network communication are normal; running patient terminal software, and inputting a patient user name and a password to ensure that a patient user logs in successfully;

s2, preparing before follow-up visit of the doctor client equipment; opening the network function of the doctor client equipment to ensure that the network communication is normal; running doctor client software, and inputting a doctor user name and a password to ensure that a doctor user logs in successfully;

s3, transmitting follow-up data by the implanted pulse generator; placing external hardware near the position of the implanted pulse generator by a doctor, wherein the distance between the external hardware and the implanted pulse generator is 5-10 cm; the implanted pulse generator starts the Bluetooth function and starts to transmit the follow-up data;

and S4, after the follow-up data transmission is completed, the doctor views and diagnoses the follow-up report data of the patient at the doctor client or the doctor seeking help at the remote end views and diagnoses the follow-up report data at the doctor client.

The invention has the beneficial effects that:

according to the invention, the Bluetooth communication function of the implanted pulse generator is started through external hardware, and when the implanted pulse generator detects that the external hardware starts the Bluetooth communication function, the implanted pulse generator actively establishes a Bluetooth communication link with a patient terminal carried by a patient; after the Bluetooth communication link is successfully established, the implanted pulse generator actively transmits follow-up data which is equal to the follow-up data when a program controller is used for follow-up to the patient terminal; after the patient terminal checks the follow-up data, the follow-up data is transmitted to the server through a 5G or WI-FI network; the relevant doctors can view and diagnose the detailed follow-up data of the patients through the doctor client; the patient and the family members can also check the basic information of the current follow-up visit through the client of the patient and the family members. The Bluetooth function and the mobile internet technology of the heart implantation equipment are started through external hardware, and a quick, simple and convenient follow-up system is realized. Compared with the traditional follow-up mode, doctors and patients can have complete follow-up without a program controller. For the postoperative follow-up visit of remote areas, the invention reduces the economic burden of patients and hospitals, reduces the working difficulty of medical staff, is beneficial to strengthening the postoperative management of patients, and solves the problem that local patients need to spend a large amount of time and money to developed cities for postoperative follow-up visit due to lack of program control instruments and experienced medical staff in hospitals of remote areas because of uneven medical cost and medical resource distribution.

Drawings

FIG. 1 is a schematic view of a quick and easy follow-up system for an implantable medical device according to the present invention;

FIG. 2 is a schematic diagram of a patient terminal function module of a quick and easy follow-up system of an implantable medical device according to the present invention;

FIG. 3 is a functional block diagram of a server of a quick and easy follow-up system of an implantable medical device according to the present invention;

FIG. 4 is a schematic diagram of a doctor client function module of the quick and easy follow-up system of the implantable medical device of the present invention;

fig. 5 is a schematic diagram of a patient and family function module of the quick and easy follow-up system of the implantable medical device of the invention.

Detailed Description

The invention will be described in detail with reference to the drawings and specific embodiments, which are illustrative of the invention and are not to be construed as limiting the invention.

It should be noted that all the directional indications (such as up, down, left, right, front, back, upper end, lower end, top, bottom … …) in the embodiments of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indication is changed accordingly.

In the present invention, unless expressly stated or limited otherwise, the term "coupled" is to be interpreted broadly, e.g., "coupled" may be fixedly coupled, detachably coupled, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature; in addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

Referring to fig. 1, the present invention relates to a system structure of a quick and easy follow-up system for an implantable medical device or a specific example of follow-up. As shown in FIG. 1, the quick and convenient follow-up system for the implanted medical device mainly comprises six parts, namely external hardware 11, an implanted pulse generator 12, a patient terminal 13, a server 14, a doctor client 15 and a patient and family client 16. The bluetooth function of the implanted pulse generator 12 cannot always be on, and cannot transmit a large amount of data when the bluetooth is turned on periodically (once a day) for data transmission, due to the influence of the battery and power consumption. The external hardware 11 is an external switch for turning on the bluetooth communication function of the implanted pulse generator 12 and triggering the implanted pulse generator to transmit the complete follow-up data. The external hardware is typically a magnet, and the bluetooth function and the full follow-up data transmission function of the implanted pulse generator 12 can be turned on by controlling the magnitude of the magnetic flux and the effective contact time of the magnet with the implanted pulse generator 12. After detecting that the external hardware 11 starts the bluetooth function, the implanted pulse generator 12 actively establishes a bluetooth communication link with the patient terminal 13 and transmits follow-up data to the patient terminal 13. After the patient terminal 13 receives and verifies the follow-up data, it is transmitted to the server 14 via a 5G or WI-FI network. The server 14 is provided with a public network interface, receives the follow-up data transmitted by the patient terminal, carries out diagnosis and analysis on the follow-up data according to various parameter thresholds set by a doctor, and informs the corresponding doctor, the patient and family members of the patient of the diagnosis and analysis result; at the same time, the server 14 stores the patient's follow-up data for review by the doctor and the patient via the doctor client 15 and the patient and family client 16. The physician client 15 obtains and displays the patient's follow-up data. The patient and family client 16 obtains and displays patient follow-up data.

Specifically, in the embodiment, the quick and simple follow-up method for the implantable medical device includes the following steps:

s1, preparing before follow-up visit of patient terminal equipment; opening the Bluetooth and network functions of the patient terminal equipment to ensure that the Bluetooth and network communication are normal; running patient terminal software, and inputting a patient user name and a password to ensure that a patient user logs in successfully;

s2, preparing before follow-up visit of the doctor client equipment; opening the network function of the doctor client equipment to ensure that the network communication is normal; running doctor client software, and inputting a doctor user name and a password to ensure that a doctor user logs in successfully;

s3, transmitting follow-up data by the implanted pulse generator; placing external hardware near the implanted pulse generator for a certain time by a doctor, wherein the distance between the external hardware and the implanted pulse generator is 5-10 cm; the implanted pulse generator starts the Bluetooth function and starts to transmit the follow-up data;

and S4, after a certain time, after the follow-up data transmission is finished, the doctor views and diagnoses the follow-up report data of the patient at the doctor client or the doctor seeking help at the remote end views and diagnoses the follow-up report data at the doctor client.

Specifically, in this embodiment, fig. 2 is a functional module of a patient terminal according to the present invention. As shown in fig. 2, the patient terminal function module mainly comprises a bluetooth communication module 40, a network communication module 41, an authorization and authentication module 42 and a local storage module 43. The patient terminal device is typically a general purpose or custom mobile handset with bluetooth low energy, 5G or WI-FI functionality, which must have specific software installed or embedded. The bluetooth communication module 40 is used for self-broadcasting and follow-up data reception, and data is encrypted and transmitted between the implanted pulse generator 12 and the patient terminal 13. After the bluetooth link is established between the implanted pulse generator 12 and the patient terminal 13, the patient terminal 13 needs to send its own device serial number to the patient terminal 13, and the patient terminal 13 verifies the device serial number through the authorization and authentication module 42, and receives data after the verification is passed. The network communication module 41 is used for transmitting follow-up data to the server 14, and data between the patient terminal 13 and the server 14 are encrypted. The authorization authentication module 42 mainly verifies two parts of content: firstly, the user name and the password of the patient are verified, and the user name and the password are used for data transmission between the patient client 13 and the server 14; secondly, whether the implanted equipment in the patient body is bound with the current user is verified for data transmission between the patient terminal and the implanted equipment, the patient terminal 13 requests the equipment information of the current user from the server 14, and the equipment information contains an equipment serial number. The local storage module 43 is used for storing and recording part of the transmission log and part of the follow-up data. The patient terminal 13 will store the transmission log and follow-up data for the last period of time, such as the last 7 days.

Specifically, in this embodiment, fig. 3 is a functional module of a server according to the present invention. As shown in fig. 3, the server function module mainly comprises a network communication module 50, a data processing module 51, an authorization authentication module 52, a database module 53, a diagnostic analysis module 54 and a local log recording module 55. The network communication module 50 is used for data transceiving and alarm data transmission. The data processing module 51 is used for data processing, such as threshold setting, data storage, and the like. The authorization and authentication module 52 is mainly used for user management and data access authority management; the user management is used for verifying a user name and a password of the user; data access rights manage the types of data that a user has access to, such as a doctor client having access to almost all data and setting part of the data, while a patient and family client having access to only a small amount of data and being unable to set the data. The database module 53 is used for storing user information, implanted device information and follow-up data. The diagnosis and analysis module 54 is used for diagnosing and analyzing the follow-up visit data, the diagnosis and analysis module 54 analyzes the follow-up visit data according to various parameter thresholds set by the doctor, and the follow-up visit data is sent to the corresponding doctor and patient by the network communication module 50 after the analysis is completed, the sending mode can be mail, text short message, webpage notification, APP notification and the like, and the specific notification mode can be set by the doctor through the doctor client. The local logging module 55 is used to store part of the user access record and the follow-up data transmission record. The server 14 will store a record of the last period of user access and a record of the follow-up data transmission, such as the last 7 days of data.

Specifically, in this embodiment, fig. 4 is a functional module of the doctor client according to the present invention, and as shown in fig. 4, the functional module of the doctor client mainly includes four parts, namely a network communication module 60, a follow-up data display module 61, an authorization authentication module 62, and a configuration module 63. The doctor client device may be a personal computer and a mobile handset with 5G or WI-FI functionality, requiring specific software to be installed. The network communication module 60 is used for data request and alarm information reception, and data is encrypted and transmitted between the doctor client 15 and the server 14. The follow-up data display module 61 is used for displaying the follow-up data of the patient and providing a friendly data viewing interface for the doctor. The authorization authentication module 62 verifies the doctor's username and password for data transfer between the doctor client 15 and the server 14. The configuration module 63 is configured to configure a follow-up data alarm threshold and an alarm information notification mode.

Specifically, in the embodiment, fig. 5 is a functional module of the patient and family client according to the present invention, and as shown in fig. 5, the functional module of the patient and family client is composed of three parts, namely a network communication module 70, a follow-up data display module 71 and an authorization and authentication module 72. The patient and family client devices are typically mobile phones with 5G or WI-FI capabilities, which require specific software to be installed. In special cases the functions of the patient and family client 16 may be integrated into the patient terminal 13. The network communication module 70 is used for follow-up data request and alarm information reception, and the family data of the patient and family client 16 and the server 14 are encrypted and transmitted. The follow-up data display module 71 is used for displaying the follow-up data of the patient, and the follow-up data requested by the patient and the family client 16 is less than the follow-up data requested by the doctor client 15. The authorization authentication module 72 verifies the patient and family's username and password for data transfer between the patient and family client 16 and the server 14.

According to the invention, the Bluetooth communication function of the implanted pulse generator is started through external hardware, and when the implanted pulse generator detects that the external hardware starts the Bluetooth communication function, the implanted pulse generator actively establishes a Bluetooth communication link with a patient terminal carried by a patient; after the Bluetooth communication link is successfully established, the implanted pulse generator actively transmits follow-up data which is equal to the follow-up data when a program controller is used for follow-up to the patient terminal; after the patient terminal checks the follow-up data, the follow-up data is transmitted to the server through a 5G or WI-FI network; the relevant doctors can view and diagnose the detailed follow-up data of the patients through the doctor client; the patient and the family members can also check the basic information of the current follow-up visit through the client of the patient and the family members. The Bluetooth function and the mobile internet technology of the heart implantation equipment are started through external hardware, and a quick, simple and convenient follow-up system is realized. Compared with the traditional follow-up mode, doctors and patients can have complete follow-up without a program controller. For the postoperative follow-up visit of remote areas, the invention reduces the economic burden of patients and hospitals, reduces the working difficulty of medical staff, is beneficial to strengthening the postoperative management of patients, and solves the problem that local patients need to spend a large amount of time and money to developed cities for postoperative follow-up visit due to lack of program control instruments and experienced medical staff in hospitals of remote areas because of uneven medical cost and medical resource distribution.

The technical solutions provided by the embodiments of the present invention are described in detail above, and the principles and embodiments of the present invention are explained herein by using specific examples, and the descriptions of the embodiments are only used to help understanding the principles of the embodiments of the present invention; meanwhile, for a person skilled in the art, according to the embodiments of the present invention, there may be variations in the specific implementation manners and application ranges, and in summary, the content of the present description should not be construed as a limitation to the present invention.

Claims (10)

1. A quick and simple follow-up system for implantable medical equipment is characterized in that: the system comprises external hardware, an implanted pulse generator, a patient terminal, a server, a doctor client, a patient and family clients; the external hardware is used for starting the Bluetooth communication function of the implanted pulse generator and triggering the implanted pulse generator to transmit complete follow-up data;

an implantable pulse generator implanted within a human body; after detecting that the external hardware starts the Bluetooth function, the implanted pulse generator actively establishes a Bluetooth communication link with the patient terminal and transmits follow-up data to the patient terminal;

the patient terminal receives and verifies the follow-up visit data and then transmits the follow-up visit data to the server through a 5G or WI-FI network;

the server receives the follow-up data transmitted by the patient terminal, diagnoses and analyzes the follow-up data according to various parameter thresholds set by doctors, and informs the corresponding doctors, patients and family members of the patients of the diagnosis and analysis results; the server stores follow-up data of the patient for the doctor and the patient to check through the doctor client and the patient and the family client;

a doctor client for acquiring and displaying follow-up visit data of a patient;

the system comprises a patient and family client, wherein the patient and family client acquires and displays follow-up visit data of the patient.

2. The system of claim 1, wherein the follow-up system further comprises: the patient terminal comprises a Bluetooth communication module, a first network communication module, a first authorization and authentication module and a local storage module; the Bluetooth communication module is used for self broadcasting and follow-up data receiving, after the implantable pulse generator establishes a Bluetooth link with the patient terminal, the implantable pulse generator firstly needs to send a self equipment serial number to the patient terminal, and the patient terminal verifies the equipment serial number through the first authorization authentication module and receives data after the verification is passed; the first network communication module is used for transmitting follow-up data to the server; the first authorization authentication module is used for verifying a user name and a password of a patient, data transmission between the patient terminal and the server and whether the implanted pulse generator in the patient body is bound with a current user or not, and data transmission between the patient terminal and the implanted pulse generator; the local storage module is used for storing and recording part of the transmission log and part of the follow-up data.

3. The system of claim 1, wherein the follow-up system further comprises: the server comprises a second network communication module, a data processing module, a second authorization and authentication module, a database module, a diagnosis and analysis module and a local log recording module; the second network communication module is used for receiving and transmitting data and sending alarm data; the data processing module is used for threshold setting and data storage; the second authorization and authentication module is mainly used for user management and data access authority management; the user management is used for verifying a user name and a password of the user, and the data access authority management is used for managing the data type accessed by the user; the database module is used for storing user information, implanted equipment information and follow-up visit data; the diagnosis and analysis module is used for diagnosing and analyzing follow-up data, analyzing the follow-up data according to various parameter thresholds set by a doctor and sending the follow-up data to the corresponding doctor and patient by the second network communication module after the follow-up data is analyzed; the local log recording module is used for storing part of user access records and follow-up data transmission records.

4. The system of claim 1, wherein the follow-up system further comprises: the doctor client comprises a third network communication module, a first follow-up visit data display module, a third authorization authentication module and a configuration module; the third network communication module is used for receiving data requests and alarm information; the first follow-up data display module is used for displaying follow-up data of a patient; the third authorization authentication module verifies a user name and a password of a doctor for data transmission between the doctor client and the server; the configuration module is used for configuring a follow-up data alarm threshold value and an alarm information notification mode.

5. The system of claim 1, wherein the follow-up system further comprises: the patient and family client comprises a fourth network communication module, a second follow-up data display module and a fourth authorization authentication module; the fourth network communication module is used for receiving a follow-up visit data request and alarm information; the second follow-up data display module is used for displaying follow-up data of the patient; and the fourth authorization authentication module verifies user names and passwords of patients and family members for data transmission between the patient and family member clients and the server.

6. The system of claim 1, wherein the follow-up system further comprises: the external hardware is a magnet, and the Bluetooth function and the complete follow-up data transmission function of the implanted pulse generator can be started by controlling the magnitude of magnetic flux and the effective contact time of the magnet and the implanted pulse generator.

7. The system of claim 1, wherein the follow-up system further comprises: the server is provided with a public network interface.

8. The system of claim 1, wherein the follow-up system further comprises: the doctor client equipment is a personal computer and a mobile phone with 5G or WI-FI functions.

9. The system of claim 1, wherein the follow-up system further comprises: the patient and family member client devices are mobile phones with 5G or WI-FI functions.

10. The method of any of claims 1-9, comprising the steps of:

s1, preparing before follow-up visit of patient terminal equipment; opening the Bluetooth and network functions of the patient terminal equipment to ensure that the Bluetooth and network communication are normal; running patient terminal software, and inputting a patient user name and a password to ensure that a patient user logs in successfully;

s2, preparing before follow-up visit of the doctor client equipment; opening the network function of the doctor client equipment to ensure that the network communication is normal; running doctor client software, and inputting a doctor user name and a password to ensure that a doctor user logs in successfully;

s3, transmitting follow-up data by the implanted pulse generator; placing external hardware near the position of the implanted pulse generator by a doctor, wherein the distance between the external hardware and the implanted pulse generator is 5-10 cm; the implanted pulse generator starts the Bluetooth function and starts to transmit the follow-up data;

and S4, after the follow-up data transmission is completed, the doctor views and diagnoses the follow-up report data of the patient at the doctor client or the doctor seeking help at the remote end views and diagnoses the follow-up report data at the doctor client.

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