CN113456040B

CN113456040B - Postoperative patient supervision system for nerve intervention treatment

Info

Publication number: CN113456040B
Application number: CN202110879732.2A
Authority: CN
Inventors: 孙喆; 朱琳; 马雨培; 王颖悕; 许钧杰
Original assignee: Yaoli Technology Beijing Co ltd
Current assignee: Yaoli Technology Beijing Co ltd
Priority date: 2021-08-02
Filing date: 2021-08-02
Publication date: 2022-02-11
Anticipated expiration: 2041-08-02
Also published as: CN113456040A

Abstract

The invention discloses a postoperative patient supervision system for nerve intervention treatment, which relates to the technical field of postoperative patient supervision and is used for solving the problems that the existing postoperative patient supervision for nerve intervention treatment cannot supervise and analyze physical characteristic data of a patient and adjust the infusion speed of the patient, and infusion reaction is easy to occur; the system comprises a supervision module and an adjusting module, wherein the supervision module sends body characteristic data into a server and analyzes the body characteristic data to obtain an adjusting signaling; the adjusting module receives the adjusting signaling and analyzes the adjusting signaling to obtain an adjusting interval, and triggers the adjusting module to adjust the infusion rate of the patient through the adjusting interval; the invention carries out data supervision and analysis on postoperative patients of the neural intervention treatment through the supervision module to obtain the adjustment distance; the infusion speed of the postoperative patient for the nerve interventional therapy is reasonably adjusted by adjusting the distance; the problems of blood pressure reduction, body temperature rise and the like caused by too fast transfusion are avoided.

Description

Postoperative patient supervision system for nerve intervention treatment

Technical Field

The invention relates to the technical field of postoperative patient supervision, in particular to an postoperative patient supervision system for neural intervention treatment.

Background

The nerve intervention treatment adopts a minimally invasive technology to open a small channel at a diseased part of a patient, blocks the nerves innervating the diseased part on the premise of targeted positioning of an imaging device, interrupts the conduction of pain, and simultaneously carries the drugs for repairing the nerves, activating blood and relieving pain to diseased trigeminal nerves and peripheral tissues, thereby effectively repairing the diseased nerve tissues and relieving the physical stimulation of peripheral blood vessels and tissues while relieving the pain, and achieving the purpose of completely curing trigeminal neuralgia.

The patient needs to be monitored by medical equipment after the nerve interventional therapy, and during infusion, the existing postoperative patient supervision of the nerve interventional therapy cannot supervise and analyze the physical characteristic data of the patient and adjust the infusion speed of the patient, so that the infusion reaction is easy to occur; including fever reaction, fever reaction caused by pyrogen, medicine, impurities, too low temperature of liquid medicine, too high concentration of liquid medicine, too high transfusion speed and other factors during intravenous transfusion, blood pressure reduction and the like.

Disclosure of Invention

The invention aims to provide a post-operation patient supervision system for neural intervention treatment, aiming at solving the problems that the existing post-operation patient supervision for neural intervention treatment cannot supervise and analyze physical characteristic data of a patient and adjust the infusion speed of the patient, and infusion reaction is easy to occur.

The purpose of the invention can be realized by the following technical scheme: a post-operative patient supervision system for neuro-interventional therapy, comprising:

the acquisition module is in communication connection with the medical monitoring equipment and is used for acquiring physical characteristic data of a patient after the monitoring of the medical monitoring equipment and transmitting the physical characteristic data to the supervision module;

the monitoring module is used for sending the body characteristic data into the server, analyzing the body characteristic data to obtain an adjusting signaling and sending the adjusting signaling to the adjusting module; the specific analysis process is as follows:

acquiring infusion information, blood pressure information and body temperature information in the body characteristic data, comparing the blood pressure in the blood pressure information with the blood pressure of the patient before corresponding infusion when the patient is in infusion, and simultaneously comparing the body temperature in the body temperature information with the body temperature of the patient before corresponding infusion; when the blood pressure in the blood pressure information is lower than the blood pressure before transfusion or the body temperature in the body temperature information is higher than the body temperature of the patient before corresponding transfusion or the two conditions occur simultaneously, respectively calculating the blood pressure difference or the temperature difference to obtain a depression value and a temperature rise value; normalizing the depression value and the temperature rise value and taking the values of the depression value and the temperature rise value; multiplying the numerical values of the medical care terminal and the medical care module by corresponding adjustment distance conversion coefficients respectively, summing to obtain an adjustment distance, generating an adjustment signaling corresponding to the adjustment distance, and feeding the adjustment signaling back to the medical care terminal and the adjustment module; the medical care end is an intelligent terminal or a computer terminal corresponding to a doctor or a nurse;

the adjusting module is used for analyzing the adjusting signaling after receiving the adjusting signaling to obtain an adjusting interval and triggering the adjusting module to adjust the infusion rate of the patient through the adjusting interval;

as a preferred embodiment of the present invention, the adjusting module includes a housing installed on the flow rate adjuster, wherein rectangular holes are symmetrically formed in side walls of two sides of the housing, a control box is installed on an upper end surface of each rectangular hole, an installation groove is formed in the housing, and a cross bar is installed in the installation groove; the cross rod is provided with a motor, an output shaft of the motor is provided with one end of a screw rod through a coupler, the screw rod is provided with a sliding block fixing component in a threaded manner, and the sliding block fixing component is used for fixing a pulley arranged in the flow velocity regulator; the control box is used for controlling the motor to drive the sliding block fixing component to move on the screw rod;

as a preferred embodiment of the present invention, the control box is provided with a communication unit, a processing unit, an input unit, a collecting unit and an early warning unit; the acquisition unit is used for acquiring the position of the sliding block fixing component and transmitting the position to the supervision module and the medical care end through the communication unit; the processing unit receives the adjusting signaling and analyzes the signaling to obtain an adjusting distance, and then controls the motor to drive the sliding block fixing assembly to move towards the direction of reducing the flow speed, wherein the moving distance is equal to the adjusting distance; the direction of the flow velocity reduction is the direction that the inner wall of the flow velocity regulator and the pulley inside the flow velocity regulator become smaller, namely the pulley extrudes the infusion tube to a greater degree, so that the infusion rate of the infusion tube is reduced; the early warning unit is used for acquiring the moving state of the pulley in the flow rate regulator when the regulating instruction is not received and the moving state of the shell; when the pulley moves or the shell moves when an adjusting instruction is not received; generating an early warning instruction, feeding the early warning instruction back to the medical care end, and playing a hard explosion prompt at the same time; the input unit is in communication connection with the medical care end, receives the adjusting direction and the adjusting distance sent by the medical care end and feeds the adjusting direction and the adjusting distance back to the processing unit; the processing unit receives the adjusting direction and the adjusting distance to control the motor to drive the sliding block fixing assembly to move towards the adjusting direction, and the moving distance is consistent with the adjusting distance;

as a preferred embodiment of the invention, a first threaded hole is installed on one side of the upper end surface of the shell close to the edge, a threaded column is installed on the internal thread of the first threaded hole, and a rotating cap is fixedly connected to the top end of the threaded column; a cross bar is arranged in the mounting groove through a rotating shaft; the bottom end of the threaded column is positioned in the shell and is in contact with the upper surface of the cross rod; a compression spring is fixedly arranged at one end of the upper surface of the cross rod and the inner wall of the top of the mounting groove;

as a preferred embodiment of the invention, the sliding block fixing component comprises a movable sliding block which is installed on the screw rod in a threaded manner, two supports are symmetrically installed on two sides of the movable sliding block, grooves are formed in the two supports, vertical rods are installed in the grooves through connecting shafts, and one end of each thin rod is installed on one side of the top of each vertical rod; one end of an arc-shaped elastic sheet is fixedly arranged on one side of the top of the vertical rod; the other end of the arc-shaped elastic sheet is fixedly arranged on the inner wall of the groove; the bottom end of the vertical rod is fixedly connected with one end of an arc-shaped rod; the other ends of the two symmetrical arc-shaped rods are clamped in a pulley arranged in the flow rate regulator;

as a preferred embodiment of the present invention, an identification unit, a storage unit, and a sending unit are disposed inside the supervision module; the identification unit is used for identifying the data category of the body characteristic data and comparing the data category with the preset normal range of the corresponding category; when the normal range is pre-checked, the normal range is sent to a storage unit; if not, directly sending the data to a server; the transmitting unit is used for counting the capacity of the body characteristic data stored in the storage unit and performing transmitting analysis, and the specific process is as follows: setting all data categories to correspond to a preset category value, matching the data categories to which the body characteristic data stored in the storage unit corresponds with all the data categories to obtain corresponding preset category values, and summing the matched corresponding preset category values to obtain a total category value; carrying out normalization processing on the capacity and the total classification value of the body characteristic data, taking the numerical value of the capacity and the total classification value, and analyzing the numerical value to obtain a data sending value of the body characteristic data; when the data sending value is larger than the set threshold value, the sending unit generates a data sending instruction and sends the data sending instruction to the storage unit, and after the storage unit receives the data sending instruction, the body characteristic data stored in the storage unit is compressed and packaged to obtain a data packet, and the data packet is fed back to the server through the sending unit.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, a supervising module is used for supervising and analyzing data of a post-operation patient for nerve interventional therapy, when the blood pressure in blood pressure information is lower than the blood pressure before infusion or the body temperature in body temperature information is higher than the body temperature of the patient before corresponding infusion or the two conditions occur simultaneously, the adjustment distance is obtained by calculating according to the depression value and the temperature rise value, and the infusion speed of the post-operation patient for nerve interventional therapy is reasonably adjusted through the adjustment distance; the problems of blood pressure reduction, body temperature rise and the like caused by too fast transfusion are avoided;

2. the body characteristic data are identified through the supervision module, the data categories corresponding to the body characteristic data stored in the storage unit are matched with all the data categories to obtain corresponding preset category values, and the matched corresponding preset category values are summed to obtain a total category value; carrying out normalization processing on the capacity and the total classification value of the body characteristic data, taking the numerical value of the capacity and the total classification value, and analyzing the numerical value to obtain a data sending value of the body characteristic data; when the data transmission value is larger than a set threshold value, compressing and packaging the body characteristic data stored in the storage unit to obtain a data packet, and feeding the data packet back to the server through the transmission unit; thereby reasonably sending the data;

3. the adjusting module is fixed on the flow rate adjuster for the infusion apparatus, so that on one hand, a pulley on the upper part of the flow rate adjuster can be blocked, and other people are prevented from adjusting the flow rate adjuster; on the other hand, the flow rate regulator is regulated and controlled, so that when a postoperative patient for nerve intervention treatment is input, if poor infusion reaction occurs, the flow rate regulator can be regulated at the first time, the phenomenon that infusion is too fast and patient treatment is influenced is avoided, early warning reminding is carried out through the early warning unit, and the flow rate regulator for the infusion apparatus can be timely reminded and early warned when being regulated under abnormal conditions.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is an overall schematic block diagram of the present invention;

FIG. 2 is an internal functional block diagram of the control box of the present invention;

FIG. 3 is an overall block diagram of the conditioning module of the present invention;

FIG. 4 is a side view of the conditioning module construction of the present invention;

FIG. 5 is a schematic view of the overall structure of the slider fixing assembly of the present invention;

fig. 6 is a cross-sectional view of the structure a-a of fig. 4 in accordance with the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention;

it will be understood that the terms "comprises" and/or "comprising," when used in this specification and claims, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

It is also to be understood that the terminology used in the description of the disclosure herein is for the purpose of describing particular embodiments only, and is not intended to be limiting of the disclosure. As used in the specification and claims of this disclosure, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should be further understood that the term "and/or" as used in the specification and claims of this disclosure refers to any and all possible combinations of one or more of the associated listed items and includes such combinations.

Example 1:

referring to fig. 1, a postoperative patient monitoring system for neuro-interventional therapy includes an acquisition module, a monitoring module, an adjustment module, a server and a medical care end;

the acquisition module is in communication connection with the medical monitoring equipment, acquires physical characteristic data of a patient after monitoring of the medical monitoring equipment and then transmits the physical characteristic data to the supervision module; wherein the body characteristic data comprises body temperature, blood pressure, heart rate, etc. of the patient

The monitoring module sends, identifies and analyzes the body characteristic data, and an identification unit, a storage unit and a sending unit are arranged in the monitoring module;

the identification unit identifies the data category of the body characteristic data and compares the data category with a preset normal range of the corresponding category; when the normal range is pre-checked, the normal range is sent to a storage unit; if the current time is not within the pre-examination normal range, directly sending the current time to a server;

the sending unit counts the capacity of the body characteristic data stored in the storage unit and carries out sending analysis, and the specific process is as follows: setting all data categories to correspond to a preset category value, matching the data categories to which the body characteristic data stored in the storage unit corresponds with all the data categories to obtain corresponding preset category values, and summing the matched corresponding preset category values to obtain a total category value; carrying out normalization processing on the capacity and the total category value of the body characteristic data, taking the values of the capacity and the total category value, and respectively marking the two values as QT1 and QT 2; setting the weight coefficients corresponding to the two numerical values as fs1 and fs2 respectively; obtaining a data value JF of the body characteristic data by using a formula JF = QT1 xfs 1+ QT2 xfs 2; when the data transmission value is larger than the set threshold value, the transmitting unit generates a data transmission instruction and transmits the data transmission instruction to the storage unit, and after the storage unit receives the data transmission instruction, the body characteristic data stored in the storage unit is compressed and packaged to obtain a data packet, and the data packet is fed back to the server through the transmitting unit;

the monitoring module analyzes the blood pressure information and the body temperature information at the same time, obtains the infusion information, the blood pressure information and the body temperature information in the body characteristic data, compares the blood pressure in the blood pressure information with the blood pressure of the patient before corresponding infusion when the patient is in infusion, and compares the body temperature in the body temperature information with the body temperature of the patient before corresponding infusion; when the blood pressure in the blood pressure information is lower than the blood pressure before transfusion or the body temperature in the body temperature information is higher than the body temperature of the patient before corresponding transfusion or the two conditions occur simultaneously, respectively calculating the blood pressure difference or the temperature difference to obtain a depression value and a temperature rise value; normalizing the depression value and the temperature rise value and taking the values of the depression value and the temperature rise value; multiplying the numerical values of the medical care terminal and the medical care module by corresponding adjustment distance conversion coefficients respectively, summing to obtain an adjustment distance, generating an adjustment signaling corresponding to the adjustment distance, and feeding the adjustment signaling back to the medical care terminal and the adjustment module; the method specifically comprises the following steps: values for the depression and temperature rise values are labeled YD, WS;

the corresponding adjustment distance conversion coefficients are ks1 and ks2 respectively; substituting the numerical values of the depression value and the temperature rise value into a formula TG = YD × ks1+ WS × ks2 to obtain an adjusting distance; if no depression value or temperature rise value exists, the corresponding numerical value is zero; the adjustment distance conversion coefficient is obtained by acquiring a large amount of data and performing software simulation by a person skilled in the art; such as: acquiring information of flow rate regulators adjusted by doctors when a plurality of groups of patients have infusion reaction, performing software simulation according to the information, pressure information and body temperature information when the infusion reaction occurs, and calculating a plurality of groups to obtain two adjustment distance conversion coefficients close to a true value;

the adjusting module analyzes the adjusting signaling after receiving the adjusting signaling to obtain an adjusting interval, and triggers the adjusting module to adjust the infusion rate of the patient through the adjusting interval;

referring to fig. 3-4, the adjusting module includes a housing 1 mounted on the flow rate adjuster 3, rectangular holes 11 are symmetrically formed in side walls of both sides of the housing 1, a control box 2 is mounted on an upper end surface of the rectangular holes 11, a mounting groove is formed in the housing 1, and a cross bar 17 is mounted in the mounting groove; the motor 15 is installed on the cross rod 17, one end of a screw rod 151 is installed on an output shaft of the motor 15 through a coupler, the slider fixing component 18 is installed on the screw rod 151 in a threaded mode, and the control box 2 is used for controlling the motor 15 to drive the slider fixing component 18 to move on the screw rod 151; the side walls of the two sides of the shell 1 are elastic pieces with certain elasticity, and the side walls of the two sides of the shell 1 are clamped on the flow rate regulator 3 through the inward elasticity of the side walls of the two sides of the shell 1;

referring to fig. 5, the slider fixing assembly 18 includes a movable slider 181 which is installed on the screw 151 in a threaded manner, two brackets 183 are symmetrically installed on two sides of the movable slider 181, a groove 184 is formed in each of the two brackets 183, a vertical rod 186 is installed in each of the grooves 184 through a connecting shaft 185, and one end of a thin rod 189 is installed on one side of the top of each vertical rod 186; one end of an arc-shaped elastic sheet 187 is fixedly arranged on one side of the top of the vertical rod 186; the other end of the arc-shaped elastic sheet 187 is fixedly arranged on the inner wall of the groove 184; the bottom end of the vertical rod 186 is fixedly connected with one end of an arc-shaped rod 188; the other ends of the two symmetrical arc-shaped rods 188 are clamped in pulleys arranged in the flow rate regulator 3; the slide block fixing component 18 fixes the pulley arranged in the flow rate regulator 3; in the using process, the thin rods 189 on the two sides of the shell 1 are pressed by hands, so that the vertical rod 186 drives the arc-shaped rods 188 to rotate around the connecting shaft 185, the arc-shaped rods 188 on the two sides are opened, the position of a pulley arranged in the flow regulator 3 is adjusted, then the arc-shaped rods 188 are loosened, and the vertical rod 186 is reset through the arc-shaped elastic sheet 187; thereby fixing the pulley provided inside the flow rate regulator 3; a limiting groove is formed in the cross bar 17 and used for limiting the movable sliding block 181, so that the movable sliding block 181 can make linear motion on the screw 151 while the screw 151 rotates;

referring to fig. 2, the control box 2 is provided with a communication unit, a processing unit, an input unit, a collecting unit and an early warning unit; the acquisition unit is used for acquiring the position of the sliding block fixing component 18 and sending the position to the supervision module and the medical care end through the communication unit; the processing unit receives the adjusting signaling and analyzes the signaling to obtain an adjusting distance, and then controls the motor 15 to drive the sliding block fixing component 18 to move towards the direction of reducing the flow speed, wherein the moving distance is equal to the adjusting distance; the direction of the flow velocity reduction is the direction that the inner wall of the flow velocity regulator 3 and the pulley inside the flow velocity regulator become smaller, namely the pulley extrudes the infusion tube to a greater degree, so that the infusion rate of the infusion tube is reduced;

the early warning unit acquires the moving state of the pulley in the flow rate regulator 3 when the pulley does not receive the regulating instruction and the moving state of the shell 1; when the pulley moves or the shell 1 moves when an adjusting instruction is not received; generating an early warning instruction, feeding the early warning instruction back to the medical care end, and playing a hard explosion prompt at the same time; the input unit is in communication connection with the medical care end, receives the adjusting direction and the adjusting distance sent by the medical care end and feeds the adjusting direction and the adjusting distance back to the processing unit; the processing unit receives the adjusting direction and the adjusting distance to control the motor 15 to drive the sliding block fixing component 18 to move towards the adjusting direction, and the moving distance is consistent with the adjusting distance;

example two:

referring to fig. 6, a first threaded hole 12 is installed on one side of the upper end surface of the housing 1 near the edge, a threaded column 13 is installed on the inner thread of the first threaded hole 12, and a rotating cap 14 is fixedly connected to the top end of the threaded column 13; a cross bar 17 is arranged in the mounting groove through a rotating shaft 16; the bottom end of the threaded column 13 is positioned inside the shell 1 and is in contact with the upper surface of the cross rod 17; a compression spring 19 is fixedly arranged at one end of the upper surface of the cross rod 17 and the inner wall of the top of the mounting groove; through wrench movement rotating cap 14, and then adjust threaded post 13 and promote horizontal pole 17 and rotate around rotation axis 16 to adjust the direction between horizontal pole 17 and the velocity of flow regulator 3, so that horizontal pole 17 is parallel with the direction that the interior pulley of velocity of flow regulator 3 removed, makes the better promotion pulley of the fixed subassembly 18 of slider remove in velocity of flow regulator 3 then.

The method comprises the steps that data supervision and analysis are carried out on a post-operation patient subjected to nerve intervention treatment through a supervision module, when the blood pressure in blood pressure information is lower than the blood pressure before infusion or the body temperature in body temperature information is higher than the body temperature of the patient before corresponding infusion or when the blood pressure in the blood pressure information is lower than the blood pressure before infusion or the body temperature in the body temperature information is higher than the body temperature of the patient before corresponding infusion or the blood pressure information and the body temperature are in the same state, the depression value and the temperature rise value are combined to calculate to obtain an adjusting interval, and the infusion speed of the post-operation patient subjected to nerve intervention treatment is reasonably adjusted through the adjusting interval; the problems of blood pressure reduction, body temperature rise and the like caused by too fast transfusion are avoided;

the body characteristic data are identified through the supervision module, the data categories corresponding to the body characteristic data stored in the storage unit are matched with all the data categories to obtain corresponding preset category values, and the matched corresponding preset category values are summed to obtain a total category value; carrying out normalization processing on the capacity and the total classification value of the body characteristic data, taking the numerical value of the capacity and the total classification value, and analyzing the numerical value to obtain a data sending value of the body characteristic data; when the data transmission value is larger than a set threshold value, compressing and packaging the body characteristic data stored in the storage unit to obtain a data packet, and feeding the data packet back to the server through the transmission unit; thereby reasonably sending the data;

the adjusting module is fixed on the flow rate adjuster 3 for the infusion apparatus, so that on one hand, a pulley on the upper part of the flow rate adjuster 3 can be blocked, and other people are prevented from adjusting the flow rate adjuster 3; on the other hand, the flow rate regulator 3 is regulated and controlled, so that when a postoperative patient for nerve intervention treatment is input, if an infusion adverse reaction occurs, the flow rate regulator can be regulated at the first time, the phenomenon that the infusion is too fast and the treatment of the patient is influenced is avoided, and early warning reminding is performed through an early warning unit, so that the flow rate regulator 3 for the infusion apparatus can be regulated and timely reminded and early warned under abnormal conditions.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. A post-operative patient supervision system for neuro-interventional therapy, comprising:

acquiring infusion information, blood pressure information and body temperature information in the body characteristic data, comparing the blood pressure in the blood pressure information with the blood pressure of the patient before corresponding infusion when the patient is in infusion, and simultaneously comparing the body temperature in the body temperature information with the body temperature of the patient before corresponding infusion; when the blood pressure in the blood pressure information is lower than the blood pressure before transfusion or the body temperature in the body temperature information is higher than the body temperature of the patient before corresponding transfusion or the two conditions occur simultaneously, respectively calculating the blood pressure difference or the temperature difference to obtain a depression value and a temperature rise value; normalizing the depression value and the temperature rise value and taking the values of the depression value and the temperature rise value; multiplying the numerical values of the medical care terminal and the medical care module by corresponding adjustment distance conversion coefficients respectively, summing to obtain an adjustment distance, generating an adjustment signaling corresponding to the adjustment distance, and feeding the adjustment signaling back to the medical care terminal and the adjustment module;

the monitoring module is internally provided with an identification unit, a storage unit and a sending unit; the identification unit is used for identifying the data category of the body characteristic data and comparing the data category with the preset normal range of the corresponding category; when the normal range is pre-checked, the normal range is sent to a storage unit; if not, directly sending the data to a server; the transmitting unit is used for counting the capacity of the body characteristic data stored in the storage unit and performing transmitting analysis, and the specific process is as follows: setting all data categories to correspond to a preset category value, matching the data categories to which the body characteristic data stored in the storage unit corresponds with all the data categories to obtain corresponding preset category values, and summing the matched corresponding preset category values to obtain a total category value; carrying out normalization processing on the capacity and the total category value of the body characteristic data, taking the values after normalization processing of the capacity and the total category value, and respectively marking the two values as QT1 and QT 2; setting the weight coefficients corresponding to the two numerical values as fs1 and fs2 respectively; obtaining a data value JF of the body characteristic data by using a formula JF = QT1 xfs 1+ QT2 xfs 2; when the data transmission value is larger than the set threshold value, the transmitting unit generates a data transmission instruction and transmits the data transmission instruction to the storage unit, and after the storage unit receives the data transmission instruction, the body characteristic data stored in the storage unit is compressed and packaged to obtain a data packet, and the data packet is fed back to the server through the transmitting unit;

and the adjusting module is used for analyzing the adjusting signaling after receiving the adjusting signaling to obtain an adjusting interval, and triggering the adjusting module to adjust the infusion rate of the patient through the adjusting interval.

2. The postoperative patient supervision system for the neuro-intervention treatment as claimed in claim 1, wherein the adjusting module comprises a housing installed on the flow rate adjuster, rectangular holes are symmetrically formed in side walls of two sides of the housing, a control box is installed on an upper end face of each rectangular hole, an installation groove is formed in the housing, and a cross bar is installed in the installation groove; a motor is installed at one end of the cross rod, an output shaft of the motor is provided with one end of a screw rod through a coupler, a sliding block fixing component is installed on the screw rod in a threaded mode, and the sliding block fixing component is used for fixing a pulley arranged inside the flow speed regulator; the control box is used for controlling the motor to drive the sliding block fixing component to move on the screw rod.

3. The post-operative patient supervision system for neuro-interventional therapy according to claim 2, characterized in that the control box is provided with a communication unit, a processing unit, an input unit, a collecting unit and an early warning unit; the acquisition unit is used for acquiring the position of the sliding block fixing component and transmitting the position to the supervision module and the medical care end through the communication unit; the processing unit receives the adjusting signaling and analyzes the signaling to obtain an adjusting distance, and then controls the motor to drive the sliding block fixing assembly to move towards the direction of reducing the flow speed, wherein the moving distance is equal to the adjusting distance; the early warning unit is used for acquiring the moving state of the pulley in the flow rate regulator when the regulating instruction is not received and the moving state of the shell; when the pulley moves or the shell moves when an adjusting instruction is not received; generating an early warning instruction, feeding the early warning instruction back to the medical care end, and playing a hard explosion prompt at the same time; the input unit is in communication connection with the medical care end, receives the adjusting direction and the adjusting distance sent by the medical care end and feeds the adjusting direction and the adjusting distance back to the processing unit; the processing unit receives the adjusting direction and the adjusting distance to control the motor to drive the sliding block fixing assembly to move towards the adjusting direction, and the moving distance is consistent with the adjusting distance.

4. The postoperative patient supervision system for the neuro-intervention treatment as claimed in claim 2, wherein a first threaded hole is installed on one side of the upper end surface of the shell near the edge, a threaded column is installed on the inner thread of the first threaded hole, and a rotating cap is fixedly connected to the top end of the threaded column; a cross bar is arranged in the mounting groove through a rotating shaft; the bottom end of the threaded column is positioned in the shell and is in contact with the upper surface of the cross rod; and a compression spring is fixedly arranged at one end of the upper surface of the cross rod and the inner wall of the top of the mounting groove.

5. The postoperative patient supervision system for the neurointervention according to claim 2, wherein the slider fixing component comprises a movable slider which is installed on the screw in a threaded manner, two brackets are symmetrically installed on two sides of the movable slider, a groove is formed in each of the two brackets, a vertical rod is installed in each groove through a connecting shaft, and one end of a thin rod is installed on one side of the top of each vertical rod; one end of an arc-shaped elastic sheet is fixedly arranged on one side of the top of the vertical rod; the other end of the arc-shaped elastic sheet is fixedly arranged on the inner wall of the groove; the bottom end of the vertical rod is fixedly connected with one end of an arc-shaped rod; the other ends of the two symmetrical arc-shaped rods are clamped in a pulley arranged inside the flow rate regulator.