CN112037898A - Digital medical hyperbaric oxygen chamber system based on 5G - Google Patents

Abstract

Based on the 5G digital medical hyperbaric oxygen chamber system, the mobile chamber-checking unit adopts a service server and a data server to expand a preset number of mobile chamber-checking terminal devices; the cloud side coordination unit adopts mobile capsule inspection terminal equipment to make diagnosis and treatment decisions and make room inspection; the in-cabin remote monitoring and diagnosing unit is used for receiving the services of a remote monitor of an expert in real time by a critical patient in a primary hospital beside a sickbed arranged in the hyperbaric oxygen cabin; the hyperbaric oxygen medical remote education unit adopts a VR virtual classroom with 5G communication to perform VR teaching on primary workers or students in medical colleges; the remote robot operation unit in the cabin performs operation control on the remote robot adopting 5G communication, and the 5G communication is adopted to perform AR or VR video transmission from a site to a remote doctor end in the operation control process. The invention solves the problems of unbalanced medical resource allocation, large graded diagnosis and treatment pushing resistance, complicated patient medical treatment, imperfect medical supervision mechanism and the like in the traditional oxygen chamber operation process.

Description

Digital medical hyperbaric oxygen chamber system based on 5G

Technical Field

The invention belongs to the technical field of hyperbaric oxygen chambers, and particularly relates to a digital medical hyperbaric oxygen chamber system based on 5G.

Background

The medical high-pressure oxygen technology is an important medical technology at home and abroad, the development of the industry has the history of fifty years and sixty years, and the product can obtain good curative effect on treating anoxia and ischemic diseases or a series of diseases caused by anoxia and ischemia; can also obtain better curative effect on certain infectious diseases and autoimmune diseases; especially in the treatment of harmful gas poisoning, there is no alternative effect.

Because of the particularity of the hyperbaric oxygen chamber, a doctor needs to spend a large amount of time on pressurizing and depressurizing the oxygen chamber every time when getting in and out of the oxygen chamber, the time and energy of the doctor are wasted, the doctor repeatedly moves around in a ward and an office, the working strength is high, the medical quality is low, the patient's condition cannot be mastered anytime and anywhere, and a nurse cannot timely master the patient's condition. The traditional remote specialist diagnosis system has the characteristics of high concurrent routing congestion, slow transmission of large-capacity data, poor interaction of medical information and the like, lacks of unified management on severe patients, and the life safety of severe patients in a cabin is difficult to guarantee. The traditional continuous medical education has the problems that the training opportunities of basic medical workers are few, the workload of clinical services of medical experts is large, the scientific research tasks are heavy, the purchase cost of medical specimens is high, the synchronization of the learning and practice courses of medical colleges and universities is difficult, the education quality is difficult to guarantee, and the like. In addition, because of the unbalanced regional medical resources, many patients lose the "golden time" for emergency treatment.

In summary, the existing hyperbaric oxygen chambers no longer meet the requirements of the increasing development, and a systematic technical scheme of the hyperbaric oxygen chamber is urgently needed.

Disclosure of Invention

Therefore, the invention provides a 5G-based digital medical hyperbaric oxygen chamber system, which solves the problems of unbalanced medical resource allocation, large staged diagnosis and treatment pushing resistance, complicated patient medical treatment, incomplete medical supervision mechanism and the like in the traditional oxygen chamber operation process.

In order to achieve the above purpose, the invention provides the following technical scheme: digital medical hyperbaric oxygen chamber system based on 5G includes:

the system comprises a mobile ward-round unit, a hospital information system and a service server, wherein the mobile ward-round unit is used for expanding a preset number of mobile ward-round terminal devices by adopting the service server and a data server, and the service server and the data server implement interactive data with the hospital information system;

the cloud side coordination unit is used for carrying out diagnosis and treatment decision making and ward round by adopting the mobile ward round terminal equipment, wherein the diagnosis and treatment decision making comprises doctor advice issuing and examination application;

the in-cabin remote monitoring and diagnosing unit is used for receiving the services of a remote monitor of an expert in real time by a critical patient in a primary hospital beside a sickbed arranged in the hyperbaric oxygen cabin;

the hyperbaric oxygen medical remote education unit is used for performing VR teaching on primary workers or students in medical colleges by adopting a VR virtual classroom with 5G communication, and performing intra-cabin operation image acquisition, operation relay or operation guidance in the VR teaching process;

and the intra-cabin remote robot operation unit is used for performing operation control on a remote robot adopting 5G communication, and the 5G communication is adopted to perform AR or VR video transmission from a scene to a remote doctor end in the operation control process.

As a preferred scheme of the 5G-based digital medical hyperbaric oxygen chamber system, the cloud side cooperation unit is used for retrieving medical records, checking assay reports and checking images at a preset place; the prescription information, the medication record, the body temperature, the blood pressure and the historical detection data of the patient are inquired through the mobile capsule inspection unit, and the medication record and the routine inspection condition of the patient are input in real time through the notice of the newly-entered patient.

As a preferable scheme of the 5G-based digital medical hyperbaric oxygen chamber system, the cloud side cooperation unit is used for carrying out mobile management on the electronic medical record, and the mobile ward inspection unit is used for viewing the electronic medical record at a preset place.

As an optimal scheme of the digital medical hyperbaric oxygen chamber system based on the 5G, the patients are identified by the cloud edge coordination unit through a face recognition algorithm, medical orders are modified, issued or stopped by the aid of the mobile capsule-checking terminal device, medical record information of the patients is updated in time, and a nurse receives the new medical orders at the first time.

As the optimal scheme of the digital medical hyperbaric oxygen chamber system based on 5G, the vital sign data of the patient are collected by adopting monitoring equipment through an in-chamber remote monitoring and diagnosis unit, and are transmitted in real time to continuously and dynamically observe the state of illness of the patient for 24 hours.

As a preferable scheme of the digital medical hyperbaric oxygen chamber system based on 5G, remote interactive high-definition communication between experts and applying doctors, between applying doctors and patients and between patients and family members is carried out through an in-chamber remote monitoring diagnosis unit, and monitoring videos, data, images and physical sign information of the patients in the oxygen chamber are remotely checked by consultation experts in real time.

As the optimal scheme of the digital medical hyperbaric oxygen chamber system based on 5G, the life characteristics and the monitoring information are intelligently monitored and calculated in real time through the monitoring platform by adopting an AI technology, and an alarm is given when abnormality occurs.

As a preferred scheme of the digital medical hyperbaric oxygen chamber system based on 5G, a pathological section is converted into a virtual digital section by adopting a pathological digital scanning technology through an in-chamber remote monitoring diagnosis unit, and the virtual digital section is zoomed, marked and stored by a key graph and written and issued by a pathological report.

As the optimal scheme of the digital medical hyperbaric oxygen chamber system based on 5G, the digital video, the medical image picture and the electronic medical record of the patient are downloaded and consulted in real time through the hyperbaric oxygen medical remote education unit, the patient's condition is comprehensively known, and the operation of the immersive visual observation operation is carried out by combining the operation site video and the explanation of the teacher with the education.

The invention realizes the data synchronization of the database of the mobile ward inspection terminal device and the management database of all wards in the whole hospital, is convenient for medical staff to quickly look up medication and treatment knowledge inside and outside the oxygen cabin, accurately look up all treatment schemes of patients in time, grasp the conditions of the patients at any time and any place, issue better medical treatment decisions under the assistance of intelligent reminding, shorten the running time of doctors in the wards and offices repeatedly, lighten the working strength and improve the medical quality;

the electronic medical record moving is realized, medical staff can check the electronic medical record of a patient at any point outside the cabin at any time and any place, the treatment information of the patient is recorded in time, and the completeness of the diagnosis and treatment information is ensured; doctors or nurses can accurately identify patients by means of the face recognition technology, and misoperation is avoided;

the doctor can directly modify, issue or stop medical advice on the handheld terminal remotely according to the real-time condition of the patient in the oxygen cabin, and the medical record information of the patient is updated in time, so that a nurse receives the new medical advice at the first time, and the treatment efficiency is improved;

the unified management level of the hospital for severe patients is improved, and the life safety of severe patients in the cabin is ensured to the greatest extent;

medical staff and students are allowed to have an opportunity to feel the real environment in the operation, the participation degree of the medical staff and students is improved, the clinical experience is increased, and the operation teaching quality and the audience area are improved;

the real-time human-computer interaction of touch and visual information is realized, so that a doctor feels personally on the scene during remote operation, the operation is faster, more stable and more accurate, and the method has important significance for saving more patient lives in the 'golden time' of first aid and solving the problem of unbalanced cross-regional medical resources.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

FIG. 1 is a schematic view of a 5G-based digital medical hyperbaric oxygen chamber system provided in an embodiment of the invention;

FIG. 2 is a schematic view of a digital medical hyperbaric oxygen chamber system intra-cabin remote monitoring and diagnosis unit based on 5G provided in the embodiment of the invention;

fig. 3 is a schematic view of a 5G-based digital medical hyperbaric oxygen chamber system intra-cabin remote robot operation unit provided in the embodiment of the invention.

Detailed Description

The present invention is described in terms of particular embodiments, other advantages and features of the invention will become apparent to those skilled in the art from the following disclosure, and it is to be understood that the described embodiments are merely exemplary of the invention and that it is not intended to limit the invention to the particular embodiments disclosed. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, 2 and 3, there is provided a 5G-based digital medical hyperbaric chamber system comprising:

the system comprises a mobile ward-round unit 1, a hospital information system and a service server, wherein the mobile ward-round unit is used for expanding a preset number of mobile ward-round terminal devices by adopting the service server and a data server, and the service server and the data server implement interactive data with the hospital information system;

the cloud side coordination unit 2 is used for making diagnosis and treatment decisions and ward rounds by adopting the mobile ward round terminal equipment, wherein the diagnosis and treatment decisions comprise doctor advice issuing and examination application;

the in-cabin remote monitoring and diagnosing unit 3 is used for receiving the services of a remote monitor of an expert in real time by a critical patient in a primary hospital beside a hospital bed arranged in the hyperbaric oxygen cabin;

the hyperbaric oxygen medical remote education unit 4 is used for performing VR teaching on primary workers or students in medical colleges by adopting a VR virtual classroom with 5G communication, and performing intra-cabin operation image acquisition, operation relay or operation guidance in the VR teaching process;

and the intra-cabin remote robot operation unit 5 is used for performing operation control on a remote robot adopting 5G communication, and the 5G communication is adopted to perform AR or VR video transmission from a scene to a remote doctor end in the operation control process.

Specifically, the mobile cabin inspection unit 1 is constructed by adopting a wireless communication technology, an intelligent identification technology and a data fusion technology. The mobile ward-round unit 1 adopts independent service server and data server to support any number and mobile terminal expansion, the service server and data server can access the existing wireless network of hospital and can implement interactive data with the existing hospital information system.

The cloud edge coordination unit 2 is used for retrieving medical records, checking assay reports and checking images at a preset place; the prescription information, the medication record, the body temperature, the blood pressure and the historical detection data of the patient are inquired through the mobile capsule inspection unit 1, and the medication record and the routine inspection condition of the patient are input in real time through the notice of the newly-entered patient. And the cloud side cooperation unit 2 is used for carrying out mobile management on the electronic medical record, and the mobile ward inspection unit 1 is used for checking the electronic medical record at a preset place. Through the cloud limit synergistic unit 2 adopts face recognition algorithm to discern the disease, adopts the mobile terminal equipment of looking into the cabin to modify, assign or stop the doctor's advice, in time updates patient's case history information and makes the nurse receive new doctor's advice the very first time.

The mobile ward-round unit 1 based on the 5G network is adopted, doctors do not need to be bound in a fixed area, medical records, examination reports and examination images can be conveniently and freely retrieved in any place, diagnosis and treatment decisions such as medical advice issuing, examination application and the like can be completed through the cloud side coordination unit 2 and the mobile ward-round unit 1 by utilizing various mobile terminals, and clinical decisions and ward-round can have higher efficiency and quality. The adoption of the movable ward-examination unit 1 moves the doctor to the bedside, reduces the times of entering and exiting the oxygen chamber for the doctor, solves the problem that a large amount of time is needed for the doctor to enter and exit the oxygen chamber each time, and further enables the doctor to benefit the patient more in time and wisdom. Meanwhile, the nurse can also inquire prescription information, medication records, body temperature, blood pressure and historical detection data of the patient in real time, enter a notice of the newly entered patient, enter the medication records and routine examination conditions of the patient in real time, improve the nursing quality and efficiency and relieve the relationship between doctors and patients.

Remove the cooperation of looking into cabin unit 1 and cloud limit synergistic unit 2, realize removing the database of looking into cabin terminal equipment and the data synchronization of all ward management databases of whole hospital, make things convenient for medical personnel to look up the medicine of using fast inside and outside the oxygen cabin, treatment knowledge, in time all treatment schemes of patient are looked up to the accuracy, the disease condition is mastered anytime and anywhere, and assign better medical treatment decision-making under the supplementary of reminding of intelligence, shorten the doctor and relapse the time of running at ward and office, lighten working strength, improve medical quality. The electronic medical record moving is realized, medical care personnel can check the electronic medical record of the patient at any place inside and outside the cabin anytime and anywhere, the treatment information of the patient is recorded in time, and the completeness of the diagnosis and treatment information is ensured. Doctors or nurses can accurately identify patients by means of the face recognition technology, and misoperation is avoided. The doctor can be long-range according to oxygen cabin interior patient's real-time situation, directly revise on handheld terminal, assign or stop the doctor's advice, and patient's case history information is in time updated, makes the nurse receive new doctor's advice the very first time, improves treatment effeciency.

Specifically, the vital sign data of the patient is collected by adopting the monitoring equipment through the remote monitoring and diagnosing unit 3 in the cabin, and the vital sign data is transmitted in real time to continuously and dynamically observe the state of illness of the patient for 24 hours. The remote interactive high-definition communication between the specialist and the applying doctor, between the applying doctor and the patient and between the patient and the family members is carried out through the remote monitoring and diagnosing unit 3 in the oxygen cabin, and the consultation specialist remotely checks the monitoring video, data, images and sign information of the patient in the oxygen cabin in real time. And the AI technology is adopted to carry out real-time intelligent monitoring and measurement on the vital signs and the monitored information through the monitoring platform, and an alarm is given when an abnormality occurs. The pathological section is converted into a virtual digital section by the remote monitoring and diagnosing unit 3 in the cabin by adopting a pathological digital scanning technology, and the virtual digital section is zoomed, marked and stored by a key graph and written and issued by a pathological report.

The in-cabin remote monitoring and diagnosing unit 3 supports the critical patients of the primary hospitals to receive the services of the remote monitoring party of the experts in real time beside the sickbed arranged in the oxygen cabin by utilizing the modern communication technology. The 5G remote monitoring application supports monitoring equipment such as a bedside breathing machine, a monitor and the like to acquire vital sign data such as heart rate, blood oxygen and the like of a patient, and the vital sign data are transmitted in real time, so that 24-hour uninterrupted continuous and dynamic observation of the state of an illness is realized. The remote monitoring is combined with a video system covering the bedside, so that the remote interactive high-definition communication between experts and application doctors, between application doctors and patients and between patients and family members is realized, and the consultation experts are supported to remotely check various information such as monitoring videos, data, images, physical signs and the like of the patients in the oxygen cabin in real time. Meanwhile, the AI technology is combined, real-time intelligent monitoring and measurement are carried out on the vital signs and the monitoring information through the monitoring platform, and once abnormity occurs, timely alarming is carried out, so that efficient, convenient, safe and reliable remote medical monitoring service is provided for the patient. 5G under-deck telemonitoring has reduced doctor and nurse's working strength, has promoted the unified management level of hospital to severe patient, and maximum assurance in-deck severe patient's life safety.

The remote pathological diagnosis adopts a pathological digital scanning technology to convert pathological sections into virtual digital sections. The remote diagnosis supports the scaling operation of the virtual digital slice, the marking and the storage of the key graph, and the writing and the publishing of the pathological report. Pathological section scanning, patient information uploading, expert consultation and report downloading are all operated and managed in a remote pathological system. The traditional remote specialist diagnosis system has the characteristics of high concurrent routing congestion, slow transmission of large-capacity data, poor interaction of medical information and the like. The cabin remote monitoring and diagnosing unit 3 of the 5G high-speed network supports the special diagnosis data of electrocardio, image, pathology and the like of a remote medical networking hospital to realize error-free transmission through network slicing. Meanwhile, the hospital utilizes big data, artificial intelligence and cloud edge cooperation technology to realize intelligent analysis service on image data, electrocardiogram data and pathological data, and provides decision-making assistance service for clinicians.

Specifically, the high-pressure oxygen medical remote education unit 4 downloads and looks up the digital video of the human body of the patient, medical image pictures, electronic medical records and comprehensively knows the illness state of the patient in real time, combines the video of the operation site and the explanation of a teacher, and carries out the immersive observation operation.

At present, the traditional continuous medical education has the problems that the training opportunities of primary medical workers are few, the workload of clinical services of medical experts is large, the scientific research tasks are heavy, the purchase cost of medical specimens is high, the synchronization of the learning and practice courses of medical colleges and universities is difficult, the education quality is difficult to guarantee, and the like. The hyperbaric oxygen medical remote education unit 4 makes full use of the modernization means, can effectively enrich the continuous education resources, improve the accessibility of the continuous education and enlarge the coverage, but has the problems of single course form, few audiences and the like.

5G + VR virtual classroom will accelerate the continuation of medical education revolution. The 5G millisecond delay can allow experts to teach VR teaching or surgery teaching for grassroots workers or students in medical colleges far beyond a thousand miles away, and supports one-time recording and timing. For example: the skill and the process of medical expert's operation in the oxygen cabin let medical staff watch the study through VR glasses "first visual angle", let medical staff have an opportunity to experience real environment in the operation, improve its degree of participation, increase clinical experience. Under the 5G network, the medical education system can realize functions of intra-cabin operation image acquisition, operation relay, operation guidance, mobile terminal application such as a mobile phone and the like. Doctor, student can download in real time and look up patient's human digital video, medical image picture, electronic medical record, all-round understanding patient's state of an illness, combine operation site video and the explanation of taking the teacher, and the operation is seen to the immersive observation, and the treatment scheme of feeling improves operation teaching quality and audience face.

In particular, telerobotic surgery is a surgery performed by a doctor in a telemedicine manner by means of a robot to remotely and real-timely perform a surgery on a patient in a remote oxygen cabin, and is the most important and difficult content in telemedicine. Unlike the procedures of private diagnosis and adjuvant therapy, the operation is an invasive one, and the wrong or delayed operation will have serious consequences and even endanger the life of the patient. The key to the success of telesurgery is the consistency and real-time performance of the operation of the master and slave systems in the surgical robot, and the technical problems of signal stability, interference resistance, high-flux signal transmission and the like are also included. The existing 4G commercial network and satellite transmission can not meet the basic requirements of remote operation, and the problems of narrow bandwidth, signal delay, data packet loss and the like seriously restrict the safe development of remote operation. With the maturity of the 5G communication technology, the delay of remote operation is obviously reduced by the three characteristics of the 5G communication technology, and the operation experience and the operation quality of doctors are greatly improved.

In the remote robot operation process, the cabin remote robot operation unit 5 realizes the instant and stable transmission of high-definition 3D images and sound, the robot arm of the operation robot is smoothly and flexibly operated, the tracking performance of a master system and a slave system is good, AR and VR videos from the site to the remote doctor end are transmitted, and the operation site needs to be completely covered with a 5G network. The remote robot operation based on the 5G technology realizes real-time man-machine interaction of touch and visual information, enables doctors to feel personally on the scene during remote operation, enables the operation to be faster, more stable and more accurate, and has important significance for saving more patient lives in the 'golden time' of emergency treatment and solving the problem of unbalanced cross-regional medical resources.

In the invention, a mobile cabin inspection unit 1 adopts a service server and a data server to expand a preset number of mobile cabin inspection terminal devices, and the service server and the data server implement interactive data with a hospital information system; the cloud side coordination unit 2 adopts the mobile capsule inspection terminal equipment to carry out diagnosis and treatment decision making and ward inspection, wherein the diagnosis and treatment decision making comprises medical advice issuing and inspection application; the in-cabin remote monitoring and diagnosing unit 3 is used for receiving the services of a remote monitoring party of an expert in real time by a critical patient in a primary hospital beside a sickbed arranged in the hyperbaric oxygen cabin; the hyperbaric oxygen medical remote education unit 4 adopts a VR virtual classroom with 5G communication to perform VR teaching on primary workers or students in medical colleges, and intra-cabin operation image acquisition, operation relay or operation guidance are performed in the VR teaching process; the intra-cabin remote robot operation unit 5 performs operation control on the remote robot adopting 5G communication, and the 5G communication is adopted to perform AR or VR video transmission from the scene to the remote doctor end in the operation control process. The invention realizes the data synchronization of the database of the mobile ward inspection terminal device and the management database of all wards in the whole hospital, is convenient for medical staff to quickly look up medication and treatment knowledge inside and outside the oxygen cabin, accurately look up all treatment schemes of patients in time, grasp the conditions of the patients at any time and any place, issue better medical treatment decisions under the assistance of intelligent reminding, shorten the running time of doctors in the wards and offices repeatedly, lighten the working strength and improve the medical quality; the electronic medical record moving is realized, medical staff can check the electronic medical record of a patient at any point outside the cabin at any time and any place, the treatment information of the patient is recorded in time, and the completeness of the diagnosis and treatment information is ensured; doctors or nurses can accurately identify patients by means of the face recognition technology, and misoperation is avoided; the doctor can directly modify, issue or stop medical advice on the handheld terminal remotely according to the real-time condition of the patient in the oxygen cabin, and the medical record information of the patient is updated in time, so that a nurse receives the new medical advice at the first time, and the treatment efficiency is improved; the unified management level of the hospital for severe patients is improved, and the life safety of severe patients in the cabin is ensured to the greatest extent; medical staff and students are allowed to have an opportunity to feel the real environment in the operation, the participation degree of the medical staff and students is improved, the clinical experience is increased, and the operation teaching quality and the audience area are improved; the real-time human-computer interaction of touch and visual information is realized, so that a doctor feels personally on the scene during remote operation, the operation is faster, more stable and more accurate, and the method has important significance for saving more patient lives in the 'golden time' of first aid and solving the problem of unbalanced cross-regional medical resources.

Although the invention has been described in detail above with reference to a general description and specific examples, it will be apparent to one skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (9)

1. Medical hyperbaric oxygen chamber system of digital based on 5G characterized in that includes:

the system comprises a mobile ward-round unit, a hospital information system and a service server, wherein the mobile ward-round unit is used for expanding a preset number of mobile ward-round terminal devices by adopting the service server and a data server, and the service server and the data server implement interactive data with the hospital information system;

the cloud side coordination unit is used for carrying out diagnosis and treatment decision making and ward round by adopting the mobile ward round terminal equipment, wherein the diagnosis and treatment decision making comprises doctor advice issuing and examination application;

the in-cabin remote monitoring and diagnosing unit is used for receiving the services of a remote monitor of an expert in real time by a critical patient in a primary hospital beside a sickbed arranged in the hyperbaric oxygen cabin;

the hyperbaric oxygen medical remote education unit is used for performing VR teaching on primary workers or students in medical colleges by adopting a VR virtual classroom with 5G communication, and performing intra-cabin operation image acquisition, operation relay or operation guidance in the VR teaching process;

and the intra-cabin remote robot operation unit is used for performing operation control on a remote robot adopting 5G communication, and the 5G communication is adopted to perform AR or VR video transmission from a scene to a remote doctor end in the operation control process.

2. The 5G-based digital medical hyperbaric chamber system according to claim 1, wherein medical records, examination reports and examination images are retrieved at preset places through the cloud-side cooperative unit; the prescription information, the medication record, the body temperature, the blood pressure and the historical detection data of the patient are inquired through the mobile capsule inspection unit, and the medication record and the routine inspection condition of the patient are input in real time through the notice of the newly-entered patient.

3. The 5G-based digital medical hyperbaric chamber system of claim 1, wherein the cloud-side coordination unit is used for performing mobile management of electronic medical records, and the mobile ward inspection unit is used for performing electronic medical record inspection at a preset place.

4. The 5G-based digital medical hyperbaric chamber system of claim 1, wherein the cloud-side cooperative unit is used for identifying patients by adopting a face recognition algorithm, and the mobile chamber-checking terminal equipment is used for modifying, issuing or stopping medical orders, updating medical record information of patients in time and enabling nurses to receive new medical orders at the first time.

5. The digital medical hyperbaric chamber system based on 5G according to claim 1, wherein the vital sign data of the patient is collected by a remote monitoring and diagnosing unit in the chamber by using a monitoring device, and the vital sign data is transmitted in real time to continuously and dynamically observe the state of illness of the patient for 24 hours.

6. The digital medical hyperbaric oxygen chamber system based on 5G according to claim 1, wherein the remote interactive high-definition communication between experts and applying doctors, between applying doctors and patients, between patients and family members is performed through the remote monitoring and diagnosing unit in the chamber, and the consultation experts remotely check the monitoring video, data, images and sign information of the patients in the oxygen chamber in real time.

7. The digital medical hyperbaric chamber system based on 5G according to claim 1, wherein the life signs and the monitoring information are intelligently monitored and calculated in real time through the monitoring platform by adopting AI technology, and an alarm is given when an abnormality occurs.

8. The digital medical hyperbaric chamber system based on 5G according to claim 1, wherein pathological sections are converted into virtual digital sections by an in-chamber remote monitoring and diagnosing unit by adopting a pathological digital scanning technology, and the virtual digital sections are zoomed, marked and stored in key maps, written and issued with pathological reports.

9. The 5G-based digital medical hyperbaric oxygen chamber system of claim 1, wherein the digital video of the human body, the medical image picture, the electronic medical record of the patient and the comprehensive understanding of the patient's condition are downloaded and consulted in real time through the hyperbaric oxygen medical remote education unit, and the immersive viewing operation is performed by combining the operation site video and the teaching of the teachers.

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