CN111161863A

CN111161863A - Telemedicine data sharing platform

Info

Publication number: CN111161863A
Application number: CN201911422598.2A
Authority: CN
Inventors: 韩锦川; 罗旭; 游月梅; 王子洪; 郭宇峰
Original assignee: First Affiliated Hospital of PLA Military Medical University
Current assignee: Nanfang Hospital; First Affiliated Hospital of PLA Military Medical University
Priority date: 2019-12-31
Filing date: 2019-12-31
Publication date: 2020-05-15

Abstract

The invention relates to the technical field of medical treatment, in particular to a remote medical treatment data sharing platform, which comprises a data sharing center, an ambulance-mounted subsystem and an emergency command center subsystem, wherein the data sharing center is respectively connected and communicated with the ambulance-mounted subsystem and the emergency command center subsystem through a wireless network, and the remote medical treatment data sharing platform is characterized in that: ambulance car sub-system includes monitor module, orientation module and communication module, first aid command center subsystem includes resource scheduling module, data sharing module and route and formulates the module, and the route is formulated the module and can be based on ambulance present geographical position information and purpose hospital, formulates the driving route to carry out the adjustment of driving route according to the road conditions. The invention solves the problem that the optimal rescue time of the patient to be rescued is easy to delay.

Description

Telemedicine data sharing platform

Technical Field

The invention relates to the technical field of medical treatment, in particular to a remote medical data sharing platform.

Background

At present, the pre-hospital first aid is developed rapidly, and the interior of a modern ambulance is spacious, so that ambulance men have enough space to rescue patients on the way to a hospital. A large number of bandages and external application articles are also carried in modern ambulances, which can help to stop bleeding, clean wounds and prevent infection. The cart is also provided with a splint and a bracket for fixing the broken limbs of the patient and preventing the neck and the spine of the patient from being seriously injured. The vehicle is also provided with oxygen, a portable respirator, a cardiac pacing defibrillator and the like. Most ambulances also have patient monitors that monitor the patient's pulse and respiration on the way to the emergency room. Providing the necessary emergency rescue tools for the patient.

However, due to the limitations of knowledge, skills, equipment and the like, on-site rescue workers often cannot timely, accurately and effectively rescue patients, and emergency rescue work can be carried out on ambulances only according to clinical symptoms of patients and the clinical experience of the patients, so that the precious health and even the life of a large number of patients cannot be guaranteed. The doctor can only rescue the patient after the patient arrives at the hospital, and in the rescue or treatment, the time of winning the rescue in minutes and seconds is very important for the rescued patient.

Medical staff waiting for rescue in a hospital can only acquire a small amount of physical sign information and illness state information of a patient through a small amount of electronic equipment because the medical staff cannot know the illness state change of a critically ill patient in the way of rescue. The specific treatment can only be performed after the patient arrives at the hospital and the rescue scheme can be determined after the condition of the patient is fully known, so that the optimal rescue time is delayed seriously, and the bad influence is brought to the cure of the patient.

Disclosure of Invention

The invention mainly aims to provide a remote medical data sharing platform, which solves the problem that the optimal rescue time of a patient to be rescued is easy to delay.

In order to achieve the above purpose, the present invention provides a remote medical data sharing platform, which comprises a data sharing center, an ambulance-mounted subsystem and an emergency command center subsystem, wherein the data sharing center is respectively connected and communicated with an ambulance-mounted subsystem and the emergency command center subsystem through a wireless network, and the ambulance-mounted subsystem comprises the following modules:

a monitoring module: the system is used for collecting vital sign information and illness state information of a patient in real time;

a positioning module: the system is used for acquiring the current geographical position information of the ambulance in real time;

a communication module: the data sharing center is used for sending the vital sign information, the illness state information and the geographic position information to the data sharing center in real time; the first aid command center subsystem comprises the following modules:

a resource scheduling module: medical resources used for matching appropriate treatment for patients nearby according to the information collected by the data sharing center; the medical resources include hospitals and ambulances;

a data sharing module: a destination hospital for sending the information collected by the data sharing center to an ambulance;

a route making module: the method is used for formulating the driving route according to the current geographical position information of the ambulance and a target hospital and adjusting the driving route according to the road condition.

The working principle and the advantages of the invention are as follows:

1. the arrangement of the ambulance carrier subsystem is beneficial to the medical staff waiting for rescuing patients in a hospital to make rescue preparations in advance if the medical staff can know the change of vital sign data of the rescued critical patients on the way to the hospital in time, so that the hospital can determine the most effective rescue scheme as soon as possible, the rescued critical patients can arrive at the hospital to be rescued immediately, thereby winning valuable treatment time for the patients and greatly improving the cure probability of the patients.

2. The first-aid command center subsystem can match a hospital suitable for treatment nearby for a patient, and a driving route of the ambulance is formulated and adjusted, so that the ambulance transports the patient to the hospital from a discovery field in the shortest time, thereby winning valuable treatment time for the patient and greatly improving the cure probability of the patient.

Further, the monitoring module specifically comprises the following sub-modules:

sign information acquisition submodule: the monitoring device is used for acquiring vital sign information of a patient in real time;

the illness state information acquisition submodule: the system is used for acquiring the video information of the illness state of the patient in real time through the visual sound acquisition equipment.

Through the collection of vital sign information and audio-visual information, can make the doctor master each item vital sign parameter of patient and change in real time, make the doctor prepare in advance in hospital's treatment, can greatly reduce first aid death rate and disability rate.

Further, the vital sign information comprises heart rate, respiratory rate, pulse rate and blood pressure, and the monitoring device comprises a multifunctional monitor.

The doctor can master various vital sign parameters and changes of the patient in time, know the degree of danger of the patient and prepare corresponding measures conveniently in advance.

Further, the video and audio information comprises video image information of the patient and audio information of the ambulance personnel describing the state of an illness, and the video and audio acquisition equipment comprises a camera and audio acquisition equipment.

The doctor can master the specific condition of the patient in time, and corresponding measures can be prepared in advance conveniently.

Further, the resource scheduling module specifically includes the following sub-modules:

hospital scheduling submodule: the system is used for searching hospitals with rescue capacity and idle rescue resources within a specified distance range according to the current geographical position of the ambulance as the circle center, and selecting the hospital closest to the ambulance from the hospitals as a proper hospital;

the ambulance dispatching submodule: the method is used for searching the ambulances which are not in rescue operation within the appointed distance range by taking the current geographical position of the ambulance at the position of the patient as the center of a circle, selecting the ambulances with proper quantity or types, and informing the ambulances to drive to the position of the patient.

The hospital scheduling sub-module is arranged, so that a patient can be matched with a hospital suitable for treatment nearby, and the ambulance can transport the patient to the hospital in a discovery field in the shortest time, thereby winning valuable treatment time for the patient and greatly improving the cure probability of the patient. The arrangement of the ambulance scheduling submodule can arrange the ambulance in time to rescue under the condition that the ambulance is not enough, thereby avoiding delaying the optimal rescue time and bringing bad influence on the cure of the patient.

Further, the route planning module specifically comprises the following sub-modules:

a route formulation sub-module: the system is used for making a plurality of driving routes according to the current geographical position information of the ambulance and a target hospital and screening the driving routes according to the set driving route selection parameters;

a route adjustment submodule: the mobile phone terminal is used for determining the starting point and the end point of the screened driving route, dividing a road range by taking the connecting line of the starting point and the end point as the diameter, and prompting all mobile phone users in the road range by short messages; the short message prompt comprises a prompt of each road name on the driving route, a prompt of avoiding the ambulance in advance and a prompt of the advancing direction of the ambulance.

The setting of the route formulation submodule can enable the ambulance to transport the patient from a discovery field to a hospital in the shortest time by formulating the driving route, thereby winning valuable treatment time for the patient and greatly improving the cure probability of the patient. And the route adjustment submodule is arranged to prompt all mobile phone users in a road range by short messages, so that vehicle owners on a driving route can make avoidance preparation in advance, and ambulances pass smoothly. Thereby winning valuable treatment time for the patient and greatly improving the cure rate of the patient.

Further, the driving route selection parameters comprise shortest distance, shortest travel time and non-congestion road conditions.

The driving route is selected the setting of parameter, conveniently in time carries out the pertinence and selects the driving video, and the ambulance is engaged in the discovery field in the shortest time and transports the patient to the hospital to win valuable treatment time for the patient, greatly improve patient's cure probability.

thank you prompt submodule: the short message credit prompting system is used for carrying out short message credit prompting on all mobile phone users in a road range after an ambulance arrives at a target hospital, wherein the short message credit prompting is used for prompting a road recovery prompt and an avoidance credit prompt.

The short message thank you prompt can carry forward positive energy and is beneficial to the road to be recovered to normal, so that the vehicle owner can normally pass.

Further, the positioning module is a Beidou positioning module. The acquisition is convenient, and the positioning effect is good.

Furthermore, the ambulance on-board subsystem also comprises a display module for medical staff to conduct remote emergency treatment guidance.

The medical staff can remotely guide the medical staff on the first-aid site to carry out appropriate rescue treatment, the state of an illness is relieved, and time is won for the rescue of doctors.

Drawings

Fig. 1 is a logical block diagram of a telemedicine data sharing platform according to an embodiment of the present invention.

Detailed Description

The following is further detailed by way of specific embodiments:

example one

A telemedicine data sharing platform is basically shown in figure 1 and comprises a data sharing center, an ambulance vehicle-mounted subsystem and an emergency command center subsystem, wherein the data sharing center is respectively connected and communicated with the ambulance vehicle-mounted subsystem and the emergency command center subsystem through a wireless network.

The ambulance on-board system comprises the following three modules:

the monitoring module specifically comprises the following two sub-modules:

sign information acquisition submodule: the monitoring device is used for acquiring vital sign information of a patient in real time; the vital sign information comprises heart rate, respiratory rate, pulse rate and blood pressure, and the monitoring device comprises a multifunctional monitor.

The illness state information acquisition submodule: the system is used for acquiring the video information of the illness state of the patient in real time through the visual sound acquisition equipment; the video and audio information comprises video image information of a patient and audio information for describing the state of an illness of a rescuer, and the video and audio acquisition equipment comprises a camera and audio acquisition equipment.

A positioning module: the system is used for acquiring the current geographical position information of the ambulance in real time; the positioning module is a Beidou positioning module.

A communication module: the data sharing center is used for sending the vital sign information, the illness state information and the geographic position information to the data sharing center in real time; the communication module may be any one of a 3G module, a 4G module, and a 5G module, and the 4G module is selected in this embodiment.

A display module: the medical staff can conduct remote emergency treatment guidance. The display module is a display and is used for video communication between the rescue personnel and the medical personnel, so that the medical personnel can conveniently guide the rescue personnel

The first aid command center subsystem comprises the following three modules:

the resource scheduling module specifically comprises the following two sub-modules:

The route making module specifically comprises the following three sub-modules:

The specific implementation process is as follows:

when a patient, family members or other people call the ambulance to arrive at an accident site for rescuing the patient, the monitoring module in the ambulance subsystem collects the vital sign information and the illness state information of the patient and sends the information to the data sharing center, so that the subsystem of the emergency command center can be conveniently called.

The first aid command center subsystem matches the hospital suitable for treatment for the patient according to the information collected by the data sharing center, and makes and adjusts the driving route of the ambulance, so that the ambulance transports the patient to the hospital from the discovery field in the shortest time, thereby gaining valuable treatment time for the patient and greatly improving the cure probability of the patient. And the ambulance can be arranged in time to carry out rescue under the condition that the ambulance is not enough, so that the delay of the optimal rescue time is avoided, and the bad influence on the cure of the patient is avoided. The route adjusting submodule is arranged, and short message prompt is carried out on all mobile phone users in a road range, so that vehicle owners on a driving route can make avoidance preparation in advance, and ambulances can pass smoothly. Thereby winning valuable treatment time for the patient and greatly improving the cure rate of the patient.

Example two

The difference with the first embodiment is that the following modules are further included:

a data analysis module: the system is used for screening the vital sign information acquired by the monitoring equipment in real time according to a preset rule, carrying out comparison analysis on indexes of the screened data according to a preset comparison threshold value, and analyzing and judging the influence degree of the indexes of the screened data on the life health of the patient; the preset rule is the degree of influence of the data index on the life health of the patient;

an emergency report push module: and when the influence degree of the indexes of the data on the life health of the patient is analyzed and judged to be high, the screened data are imported into a preset emergency report template to generate an emergency report, and the emergency report is pushed to a relevant hospital.

The data analysis module and the emergency report pushing module are arranged, screening can be carried out from collected data according to preset rules, indexes of screened data are contrasted and analyzed according to preset contrast threshold values, the influence degree of the indexes of the screened data on the life health of a patient is conveniently judged, if the influence degree is high, the emergency report pushing module generates an emergency report and sends the emergency report to a related hospital, a doctor can know the condition in time, and corresponding preparation is made in advance to rescue the patient.

The foregoing is merely an example of the present invention, and common general knowledge in the field of known specific structures and characteristics is not described herein in any greater extent than that known in the art at the filing date or prior to the priority date of the application, so that those skilled in the art can now appreciate that all of the above-described techniques in this field and have the ability to apply routine experimentation before this date can be combined with one or more of the present teachings to complete and implement the present invention, and that certain typical known structures or known methods do not pose any impediments to the implementation of the present invention by those skilled in the art. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims

1. The remote medical data sharing platform comprises a data sharing center, an ambulance vehicle-mounted subsystem and an emergency command center subsystem, wherein the data sharing center is respectively communicated with the ambulance vehicle-mounted subsystem and the emergency command center subsystem through a wireless network connection, and the remote medical data sharing platform is characterized in that: the ambulance on-board system comprises the following modules:

2. The telemedicine data sharing platform of claim 1, wherein: the monitoring module specifically comprises the following sub-modules:

3. The telemedicine data sharing platform of claim 2, wherein: the vital sign information comprises heart rate, respiratory rate, pulse rate and blood pressure, and the monitoring equipment comprises a multifunctional monitor.

4. The telemedicine data sharing platform of claim 2, wherein: the video and audio information comprises video image information of a patient and audio information of a rescuer describing an illness state, and the video and audio acquisition equipment comprises a camera and audio acquisition equipment.

5. The telemedicine data sharing platform of claim 1, wherein: the resource scheduling module specifically comprises the following sub-modules:

6. The telemedicine data sharing platform of claim 1, wherein: the route making module specifically comprises the following sub-modules:

7. The telemedicine data sharing platform of claim 6, wherein: the driving route selection parameters comprise shortest distance, shortest travel time and non-congestion road conditions.

8. The telemedicine data sharing platform of claim 6, wherein: the route making module specifically comprises the following sub-modules:

9. The telemedicine data sharing platform of claim 1, wherein: the positioning module is a Beidou positioning module.

10. The telemedicine data sharing platform of claim 1, wherein: the ambulance on-vehicle subsystem further comprises a display module for medical staff to conduct remote emergency treatment guidance.