CN114121196A - Visual electronic medical record query system and visual electronic medical record query method - Google Patents

Abstract

The invention provides a visual electronic medical record query system and a visual electronic medical record query method, which comprise an EMR system and a database, wherein the EMR system comprises a control unit, a storage unit, a display unit and a communication unit; the control unit stores clinical data created by the healthcare worker through the EMR system in the storage unit; when a user of the EMR system wants to view the stored clinical data, the control unit receives the user's request and loads and displays one or more stored clinical data accordingly, the screen on which the clinical data is displayed being a first screen; when the user wants to search more related data, the control unit displays a search screen for searching clinical data on the first screen, wherein the search screen is a second screen; a second screen configured to be capable of inputting a data search request; with the EMR system of the present invention, images representing each disease identified from the patient's medical record are sequentially visualized on the human body image according to the occurrence time of the disease, and it is easier to grasp disease information.

Description

Visual electronic medical record query system and visual electronic medical record query method

Technical Field

The invention relates to the technical field of medical record query systems, in particular to a visual electronic medical record query system and a visual electronic medical record query method.

Background

Generally, when a patient goes to a hospital, the patient's personal information, the name of a previously affected disease, medical history, and the like are written and submitted in written form according to the requirements of the hospital. After filling and receiving the document, the hospital will make a chart according to the written content, and if the person is a person who receives treatment at the hospital, the hospital will prepare for the treatment, for example, search the past chart.

However, with regard to the written medical records as described above, it has taken a lot of time in the past to search for charts or create new charts by referring to information of patients, which has a problem that cannot be effectively solved. In particular, these files must be retained for a certain time, and there is a problem in that a place where the files need to be stored and storage costs.

To solve this problem, techniques and contents for sharing various types of information about patients through various types of networks (such as the internet, LAN, and Intranet) as a network have been developed. Electronic medical record processing performed in this manner is called Electronic Medical Record (EMR). However, the existing electronic medical records record data in a free-form presentation form, which is difficult for a computer to understand, and therefore, even if other medical staff are treating a patient, it is difficult to grasp the condition of the patient even if they see the data recorded on the medical record. Therefore, a technique that enables a patient to quickly and accurately grasp the relationship between the progression of various diseases occurring in the past and the disease is required.

Disclosure of Invention

The invention aims to provide a query system and a query method of an EMR system, and can show the state of a patient in a visual form. The display of disease records within a patient's body visualized over time on the medical personnel's EMR treatment screen enables the patient's past medical history and current status to be easily grasped in the form of images rather than complex textual descriptions.

In order to achieve the above object, the present invention provides a visual electronic medical record query system, which includes: it includes an EMR system 100 and a database 200;

wherein the EMR system 100 may create, display and store clinical documents generated during treatment for any patient, link and store medical records created during each medical procedure and media files related to each medical record;

the EMR system 100 includes a control unit 101, a storage unit 102, a display unit 103, and a communication unit 104;

the control unit 101 stores clinical data created by medical workers through the EMR system 100 in the storage unit 102; when a user of the EMR system 100 wants to view the stored clinical data, the control unit 101 receives the user's request and loads and displays one or more stored clinical data accordingly, the screen of the clinical data display being the first screen; when the user wants to find more relevant data, the control unit 101 displays a search screen for searching clinical data on the first screen, the search screen being a second screen; a second screen configured to be capable of inputting a data search request;

the storage unit 102 extracts data according to the request and transmits it to the control unit 101, and the control unit 101 displays clinical data through the display unit 103;

the display unit 103 provides a first screen for creating and querying clinical data and a second screen for searching clinical data;

the communication unit 104 includes a circuit for receiving and transmitting data and/or signals and processing wired or wireless signals under the control of the control unit 101; the control unit 101 controls the communication unit 104 to transmit and receive clinical documents and/or clinical data with the database 200.

Further, the control unit 101 is further configured to visualize a disease image representing a disease on the human body image according to a time point at which the disease occurs, and display in the first screen; the control unit 101 changes the color of the occurrence position of the disease in the human body image or adjusts transparency according to the development of the disease, which is advantageous for observing the change of organs related to the disease and the treatment process.

Further, the control unit 101 visualizes the occurrence of diseases and the location and type of diseases by inserting an icon or an arrow for each disease into the human body image.

Further, the control unit 101 assigns serial numbers to a plurality of diseases occurring in the patient from the past to the present time according to the occurrence time of the diseases and recalls the assigned serial numbers to the position, and guides the occurrence, position and occurrence order of each disease by visualizing sequentially according to the occurrence time. .

Further, when a trigger GUI event occurs, which is an input event generated by a user clicking a mouse on the first screen, mouse hovering, mouse wheel, mouse off, GUI focusing, keyboard input, finger touch, voice recognition, human motion recognition, or the like, occurs at the disease occurrence position in the human body image, the control unit 101 displays a voice balloon in association with the disease occurrence position, and provides information on the disease name, the occurrence time, the severity, and the current.

Further, the control unit 101 outputs a voice balloon in association with an area touched by the user or an area in which a mouse cursor is located in the human body image, and by visually displaying detailed information of a disease occurring in the corresponding area in text form, the control unit 101 switches display information by providing a control on the first screen, and when the user places or clicks the mouse on the human body image on the first screen, the control unit 101 displays a context including at least one of information display, prescription, progress inquiry, and progress record.

The invention also provides a visual electronic medical record query method, which specifically comprises the following steps:

in step 210, the EMR system 100 checks whether a first screen is requested from the terminal of the doctor treating the patient;

in step 220, if the confirmation requests the first screen, the EMR system identifies the disease occurring in the patient from the patient's medical record;

in step 230, the EMR system 100 provides a first screen by visualizing a disease image representing a disease on the human body image according to the occurrence time of the disease, and searches for disease information based on the search operation;

in step 240, a point of time to be in the first screen is changed according to the movement of the GUI control, an image visualized on the human body image is changed according to the movement of the GUI control set on the first screen, and a trend representing a treatment state of the "stomach illness" by transparency, size, and the like.

Further, when the time point selected according to the operation of the GUI control is located at the reference point, that is, the patient is in a normal state without a disease, when the time point selected according to the operation of the GUI control moves in a direction away from the reference point, medical record information is provided at the time corresponding to the point, and a disease image is visualized in the human body image to indicate the occurrence of a disease.

Further, as the selected point in time moves in a direction approaching the current point in time according to the operation of the GUI controls, the EMR system provides data on the progress of the treatment of the disease including, but not limited to, medication management, surgery, hospitalization, blood examination result abnormality and treatment frequency, and changes the color and transparency, contrast, shape and size of the disease image, thereby displaying a process image from the occurrence of the disease to the treatment and cure.

Further, a search window for searching for a disease is provided on the first screen, the EMR system searches for a disease name and a disease occurrence location, searches for a disease matching the disease from a medical record of a patient, and an image of the disease can be visualized on a human body image, providing a function of searching for a disease image on the first screen in various ways.

Further, when a query is requested, sequentially querying the stored video or images for patient status, setting GUI controls so that the stored still image or images can be controlled to be played; the GUI controls may include a play button, a back button, and a quick button so that a search function may be implemented through the buttons.

Compared with the prior art, the invention has the advantages that: with the EMR system of the present invention, images representing each disease identified from a medical record of a patient can be visualized on a human body image in sequence according to the occurrence time of the disease, and it is possible to make it easier to grasp disease information.

Drawings

FIG. 1 is a schematic diagram of the structure of an EMR system in an embodiment of the present application.

FIG. 2 is a workflow of a query method of an EMR system according to an embodiment of the present disclosure

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be further described below.

Fig. 1 is a block diagram illustrating an EMR system according to embodiments of the present description, including an EMR system 100 and a database 200. The EMR system 100 according to the present description may create, display, and store clinical documents generated during treatment (e.g., examination, surgery, medication, etc.) for any patient. In addition, the EMR system 100 may link and store the medical records created during each medical procedure and the media files associated with each medical record. The EMR system 100 may include a control unit 101, a storage unit 102, a display unit 103, and a communication unit 104. The EMR system 100 may also include a user interface unit.

Wherein the control unit 101 controls the storage unit to store clinical documents created by medical workers through the EMR system in the storage unit (e.g., database). In this case, clinical documents may be classified and stored according to items constructed for each patient or department. For example, by defining a hierarchy between each item that makes up a clinical document and mapping each item to an associated medical term, the required data can be retrieved from the item name or term. When a user of the EMR system wants to view the stored clinical documents, the control unit 101 receives the user's request (or selection) and loads and displays one or more stored clinical documents accordingly. At this time, the clinical file display screen is referred to as a first screen. When a user who is searching for clinical documents all the time wants to find more relevant data, the control unit 101 displays a search screen for searching for clinical data on the first screen. At this time, the search screen is referred to as a second screen. In the second screen, the user selects at least one of patient information (identity information, sex, age), diagnosis name (code), operation name (code), prescription name, test result, department (series), and query time, which may be configured to be able to input a data search request. In addition, the user can previously specify and store the search terms and search conditions of the second screen and load them if necessary.

The storage unit 102 extracts data according to the request and transmits it to the control unit 101, and the control unit 101 displays clinical data through the display unit 103. In this case, when the user selects a display format of the search results, clinical data corresponding to the search query may be displayed in one of a flowchart format or a summary format. The control unit 101 may comprise an Application Specific Integrated Circuit (ASIC), another chipset, a logic circuit and/or a data processing device.

The storage unit 102 can store clinical documents, media files related to medical records, and the like under the control of the control unit 101. The memory unit 102 may include Read Only Memory (ROM), Random Access Memory (RAM), flash memory, memory cards, storage media and/or other storage devices. The storage unit 102 may exist outside the control unit 101 in the form of a database, and may be connected to the control unit 101 by various well-known means.

The EMR system 100 may further include a display unit 103, the display unit 103 providing a first screen for creating and querying clinical documents and a second screen for searching clinical data, and the display unit 103 is an LCD (liquid crystal display), an OLED (organic light emitting diode and other well-known elements may be used).

In addition, the EMR system 100 may further include a communication unit including a circuit for transmitting and receiving data and/or signals to and from the outside and processing wired or wireless signals under the control of the control unit 101. The control unit 101 may control the communication unit 104 to transmit and receive clinical documents and/or clinical data together with an external database.

According to one embodiment, the control unit 101 may also visualize a disease image representing a disease on the human body image according to a time point at which the disease occurs and display in the first screen. That is, the control unit 101 may sequentially visualize and express individual images representing diseases on the human body image by changing them according to the occurrence of diseases and the course of treatment. In addition, as another example of visualizing the occurrence of a disease in the human body image, the control unit 101 changes the color of the occurrence position (organ) of the disease in the human body image or adjusts transparency according to the occurrence, so that the change of the organ related to the disease and the treatment process can be more vividly observed.

In addition, the control unit 101 may visualize the occurrence of diseases and the location and type of diseases by inserting (visualizing) an icon or an arrow for each disease into the human body image.

In addition, the control unit 101 assigns serial numbers to a plurality of diseases occurring in the patient from the past to the present time according to the occurrence time of the diseases, and recalls the assigned serial numbers to the position. The occurrence, location and order of occurrence of each disease are guided by visualizing the occurrence sequentially according to the time of occurrence.

In addition, when a trigger GUI event occurs, when it occurs at a disease occurrence position in the human body image, the control unit 101 displays a voice balloon in association with the disease occurrence position, and provides information on the disease name, the occurrence time, the severity, and the current. The voice balloon status may also be displayed in text form. Here, the GUI event is an input event generated by a user clicking a mouse on the first screen, mouse hovering, a mouse wheel, mouse off, GUI focusing, keyboard input, finger touch, voice recognition, human motion recognition, and the like.

For example, the control unit 101 outputs a voice balloon in the human body image in association with an area touched by the user or an area where the mouse cursor is located in the human body image, and visually displays detailed information of a disease occurring in the corresponding area by text.

Alternatively, the control unit 101 may switch the EMR treatment screen by providing a context menu on the first screen. Specifically, when the user places or clicks a mouse on the human body image on the first screen, the control unit 101 displays a context including at least one of information display, prescription, progress inquiry, and progress record; and when the information selects the display menu in context, a part or all of the EMR treatment screen output to the doctor terminal may be switched to a screen displaying detailed information about the occurred disease.

By such screen change, the control unit 101 can cause the doctor to check, for example, a patient's current surgical record, blood examination result, nursing record, and the like created based on the time at the time of information display.

Further, when a confirmation window of medical history in the prescription menu is selected, the control unit 101 switches a part or all of the first screen to prescription of a corresponding disease, and when a progress inquiry menu is selected, switches to a screen displaying progress of the disease. The screen switching function may be performed by a shortcut key. For example, if the scroll bar indicates a certain point in time and the patient is receiving the corresponding injury treatment, the physician may further search the progress record by pressing the shortcut key "P" to display a second screen, or may use any other shortcut key.

In addition, by clicking on an organ in the human body image, the doctor can request a query or create medical information for the disease at a point of time currently indicated by the scroll bar.

The human body image is displayed on the upper or lower body, front, rear or side in accordance with an operation of a GUI control (for example, a setting button or a shortcut key provided on the first screen). By three-dimensional visualization of the disease image representing the disease, it can be converted to facilitate viewing of the lesion.

The control unit 101 visualizes a disease image representing each disease recognized from a medical record of a patient on a human body image in turn according to the occurrence time of the disease, thereby occurrence and change of a medical history at each time point of the patient. With the lapse of time, you can easily grasp the information of the disease.

In addition, the control unit 101 may visualize all disease images representing each disease identified from the patient's medical record on the human body image to create and provide a disease map showing all diseases suffered by the patient at once.

In addition, the control unit 101 can identify the association between diseases by visualizing the human body images in conjunction with diseases occurring in similar time or similar regions in the diseases identified from the medical records of the patient.

For example, the control unit 101 displays a human body image and a GUI control on the first screen, and the recognized a disease image ("stomach" is a disease occurrence site (e.g., upper body center) in the human body image, and visually represents a disease indicative of a disease (e.g., "gastrointestinal disease") in the operation of the GUI control, movement of a scroll bar). The disease image visualized by reflecting the treatment status of the disease may change.

In another example, the recognition unit 110 determines a time point newly selected by the operation of the GUI control to move in a direction away from the reference point by the time point selected by the operation of the GUI control set on the first screen. After confirmation, a first disease that occurred at the time point and a second disease that occurred prior to the time point and did not cure may be identified. In this way, medical staff (doctor) can clearly check the occurrence and progress of disease, treatment, cure, and the like at a glance over time based on images only by operating GUI controls.

Here, the control unit 101 may be configured to include a viewpoint switching unit 124 and a direction switching unit 125. The viewpoint switching unit 124 switches the viewpoint implemented on the first screen according to the movement of the GUI control (e.g., "scroll bar"). That is, as the time point selected by the operation of the GUI control moves in a direction away from the reference point, the time point changing unit 124 determines the time point achieved on the first screen, the occurrence time of the disease first. From this point in time, the first screen may be switched to the currently requested point in time. Thus, the generated image of the disease can be sequentially visualized on the human body image.

As another example, when a play button on the screen providing the inquiry of the patient state is selected, the control unit 101 sequentially visualizes an image of a disease on the human body image, which may be saved or displayed, occurring from the time when the first disease occurs to the present time.

For example, the control unit 101 stores some or all of the disease occurrence time as one or more still images or videos, and sequentially inquires the stored video or images to acquire the patient state when the first screen is requested. The first screen may be configured by being displayed on a screen.

According to one embodiment, a part or all of the patient state inquiry screens stored by the control unit 101 include disease images as one or more still images or videos, and when the play button is selected, the stored one or more still images or videos may be sequentially displayed.

Further, whenever the return button on the screen providing the patient-state inquiry is selected, the control unit 101 skips transmitting a past disease to a set of previous time points (for example, occurrence time of an immediately previous disease) and can visualize it on the human body image.

In addition, the control unit 101 may perform the above-described function by recognizing a gesture (e.g., a "tap" operation of tapping the screen touching the finger touching the first screen) or by recognizing a change in the touched hand index. In addition, the control unit 101 can perform the above-described functions by recognizing voice commands such as "play", "double speed", and "reverse". In this way, the doctor can simply switch and search for the disease image visualized on the human body image on the first screen without manipulating GUI controls or buttons.

Hereinafter, in fig. 2, a workflow of a query method of the EMR system according to an embodiment of the present invention will be described in detail.

Referring to fig. 2, the EMR system 100 checks whether a first screen is requested from the terminal of the doctor treating the patient in step 210. For example, the EMR system selects a menu associated with a medical history query, prescription drug registration, hospitalization, surgery, examination, etc., or the corresponding patient is first used when the patient visits the hospital. The hospital needs past medical history information and can recognize that the first screen is requested.

If the confirmation requests the first screen, then in step 220 the EMR system identifies the disease occurring in the patient from the patient's medical record. For example, the EMR system is searched for medical records in all medical institutions, including other medical institutions of the patient, and based on the current point of request, the system 100 identifies all diseases. In addition, the EMR system identifies disease information from the patient's medical history, time of occurrence of the disease, time of healing, location, size and shape of occurrence, medications and surgery, hospitalization, severity, etc.

In step 230, the EMR system 100 provides a first screen by visualizing a disease image representing the disease on the human body image according to the occurrence time of the disease, and searches for disease information based on the search operation. For example, when an outpatient treatment is requested, the patient's medical record is retrieved from the EMR system. The ability of the patient to identify other diseases being treated by another physician (e.g., "gastrointestinal diseases"). Thereafter, the EMR system provides a first screen consisting of the human image 221 and controls so that the disease can be visualized in the disease occurrence area (e.g., the center of the upper body) in the human image.

When the point in time selected according to the operation of the GUI controls is at the reference point, the EMR system can visualize the normal state of the patient without the disease. Thereafter, when the time point selected according to the operation of the GUI control is moved in a direction away from the reference point, the first screen providing system provides a medical record (medical information) at the time corresponding to the point. And, if there is a disease, a disease image may be visualized in the human body image to indicate the occurrence of the disease. Thereafter, as the selected time point moves in a direction close to the current point according to the operation of the GUI control, the EMR system provides data on the progress of treatment of the disease (medication management, operation, hospitalization, abnormality of blood examination result, treatment frequency, etc.) and changes the color and transparency, contrast, shape and size of the disease image, thereby displaying a process image from the occurrence of the disease to the treatment and cure.

According to one embodiment, the EMR system may search for an image of a disease by designating an ROI on the image of the person on the first screen. Specifically, the first screen providing system detects a disease ("brain disease") occurring in human tissue ("brain", "face", "eyes", etc.) belonging to a user-designated region of interest. Disease images can also be searched and visualized from medical records according to movement of GUI controls ("scroll bars"). For example, the first screen providing system designates a region where the user drags the drawing on the human body image or a region where the user clicks as a region of interest, and appears in the region of interest to search for and visualize an image of the disease on the human body image 301.

In another embodiment, a search window for searching for a disease may be provided on the first screen, and the EMR system may include the disease name and the disease occurrence location in the search. When the user inputs a window, when text of the occurrence time of a disease is input, a disease matching the disease can be searched from a medical record of the patient, and an image of the disease can be visualized on the human body image. At this time, the first screen providing system combines the region of interest and the text entered in the search box according to the selected search condition (e.g., "and", "or", "not", etc.), and can search for a disease satisfying the combination from the medical history of the patient.

For example, in the EMR system, when a user specifies a region of interest and enters text ("tumor") in a search box, the region of interest is selected as a search condition. A search can be made from the patient's medical history and if the "OR" condition is selected as the search condition, all diseases occurring within the region of interest and all oncology medical records occurring within the patient can be searched from the patient's location. In addition, when the "not" condition is selected as the search condition, all other diseases than the tumor among the diseases occurring in the region of interest can be searched. As described above, the EMR system may provide a function of searching for a disease image on the first screen in various ways.

The processing unit 120 stores some or all of the disease occurrence time as one or more still images or videos, and sequentially inquires the stored video or images to acquire the patient status when requesting the patient status inquiry screen, sets GUI controls so that the stored still image or video or images can be controlled to be played. The GUI controls may include a play button, a back button, and a quick button so that images of diseases can be searched by pressing these.

When the play button is clicked, the first screen providing system may generate and display a pre-generated video or a video sequentially visualizing a disease image on a human body image from a first disease occurrence point to a current time. Alternatively, a part or all of the patient status query screens stored by the patient status query screen providing system may include a disease image as one or more still images or videos, and when the play button is selected, the stored one or more still images or videos may be displayed in order. At this time, the first screen providing system further outputs a progress bar, guides the progress of the video, and visualizes the video.

Each time the back button is clicked, the first screen providing system converts a time point 610 visualized on the first screen into a past time point (e.g., a time when an initial disease occurs), thereby providing past images, which can be searched in the reverse order.

For example, the EMR system may visualize images of diseases that occurred in the past on the human body image by jumping to a set previous point in time (e.g., "one week ago") on each return. In addition, the EMR system may change the time point visualized on the first screen to be closer to the current point each time the quick button is clicked, so that the latest image of the disease can be searched for. For example, the EMR system can increase the playing speed of the video by 2 times, 3 times, and n times at each click of the quick button, so that the latest image of the disease can be quickly searched. In this way, the EMR system provides a function for variously searching the disease image on the first screen, so that medical staff can simply search the disease image at a point of time and check it even without manipulating the scroll bar.

In step 240, a point in time to be implemented in the first screen is changed according to the movement of the GUI control. For example, the image visualized on the human body image is changed according to the movement of the GUI control provided on the first screen. Also, the tendency of the "stomach illness" treatment state can be represented by transparency, size, and the like.

In this way, the EMR system sequentially visualizes images representing each disease identified from the patient's medical record on the human body image according to the occurrence time of the disease, and can make it easier to grasp disease information.

The method according to the embodiment of the present invention may be implemented in the form of program instructions that can be executed by various computer apparatuses and recorded in computer-readable media. The computer readable medium may include program instructions, data files, data structures, etc., alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the embodiments, or may be known and available to those skilled in the computer software arts. Examples of the computer readable recording medium include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs, DVDs, and magnetic media such as floppy disks. Program instructions such as magneto-optical media, as well as ROM, RAM, flash memory, etc. Examples of program instructions include not only machine language code, such as those produced by a compiler, but also high-level language code that may be executed by the computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

As described above, although the embodiments have been described with limited embodiments and drawings, various modifications and changes may be made by those skilled in the art in light of the above description. For example, the described techniques may be performed in a different order and/or components such as systems, structures, devices, circuits, etc., described may be combined or grouped in a different manner than the described methods or otherwise. Component (b) can, optionally, achieve suitable results, even if substituted by or by equivalents. Accordingly, other embodiments, and equivalents of the claims fall within the scope of the claims.

The above description is only a preferred embodiment of the present invention, and does not limit the present invention in any way. It will be understood by those skilled in the art that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (11)

1. A visual electronic medical record query system, comprising: it includes an EMR system and a database;

wherein the EMR system may create, display and store clinical documents generated during treatment for any patient, link and store medical records created during each medical procedure and media files associated with each medical record;

the EMR system comprises a control unit, a storage unit, a display unit and a communication unit;

the control unit stores clinical data created by the healthcare worker through the EMR system in the storage unit; when a user of the EMR system wants to view the stored clinical data, the control unit receives the user's request and loads and displays one or more stored clinical data accordingly, the screen on which the clinical data is displayed being a first screen; when the user wants to search more related data, the control unit displays a search screen for searching clinical data on the first screen, wherein the search screen is a second screen; a second screen configured to be capable of inputting a data search request;

the storage unit extracts data according to the request and transmits the data to the control unit, and the control unit displays the clinical data through the display unit;

the display unit provides a first screen for creating and querying clinical data and a second screen for searching the clinical data;

the communication unit includes a circuit for receiving and transmitting data and/or signals and processing wired or wireless signals under the control of the control unit; the control unit controls the communication unit to send and receive clinical documents and/or clinical data with the database.

2. The visualized electronic medical record query system as claimed in claim 1, wherein the control unit is further configured to visualize a disease image representing a disease on the human body image according to a time point of occurrence of the disease and to display it in the first screen; the control unit changes the color of the occurrence position of the disease in the human body image or adjusts the transparency according to the development condition of the disease, thereby being beneficial to observing the change of organs related to the disease and the treatment process.

3. The visualized electronic medical record query system as claimed in claim 1, wherein the control unit visualizes occurrence of diseases and location and type of diseases by inserting icons or arrows for each disease into the image of the human body.

4. The visualized electronic medical record query system as claimed in claim 1, wherein the control unit assigns serial numbers to a plurality of diseases occurring in the patient from the past to the present time according to the occurrence times of the diseases and recalls the assigned serial numbers to the positions, and guides the occurrence, position and order of occurrence of each disease by visualizing sequentially according to the occurrence times. .

5. The visual electronic medical record query system according to claim 1, wherein when a triggering GUI event occurs, occurring at a disease occurrence position in a human body image, the control unit displays a voice balloon in association with the disease occurrence position and provides information on a disease name, an occurrence time, a severity and a current, the GUI event being an input event generated by a user clicking a mouse on a first screen, mouse hovering, mouse wheel, mouse off, GUI focusing, keyboard input, finger touch, voice recognition, human body motion recognition and the like.

6. The visual electronic medical record query system as claimed in claim 1, wherein the control unit outputs a voice balloon in the human body image in association with an area touched by the user or an area where a mouse cursor is located in the human body image, and by visually displaying detailed information of diseases occurring in the corresponding area in text form, the control unit switches display information by providing a control on the first screen, and when the user places or clicks the human body image on the first screen, the control unit displays a context including at least one of information display, prescription, progress query and progress record.

7. The method for querying the visualized electronic medical record is applied to the system as claimed in claim 1, and specifically comprises the following steps:

in step 210, the EMR system checks whether a first screen is requested from the terminal of the doctor treating the patient;

in step 220, if the confirmation requests the first screen, the EMR system identifies the disease occurring in the patient from the patient's medical record;

in step 230, the EMR system provides a first screen by visualizing a disease image representing the disease on the human body image according to the occurrence time of the disease, and searches for disease information based on the search operation;

in step 240, a point of time to be in the first screen is changed according to the movement of the GUI control, an image visualized on the human body image is changed according to the movement of the GUI control set on the first screen, and a trend representing a treatment state of the "stomach illness" by transparency, size, and the like.

8. The method of claim 7, wherein when the time point selected according to the operation of the GUI control is located at a reference point, i.e., a normal state where the patient has no disease, and when the time point selected according to the operation of the GUI control is moved in a direction away from the reference point, the medical record information is provided at a time corresponding to the point, and the disease image is visualized in the human body image to indicate the occurrence of the disease.

9. The method of claim 7, wherein the EMR system provides data on the progress of the treatment of the disease including but not limited to medication management, surgery, hospitalization, abnormal blood examination results and treatment frequency as the selected time point moves in a direction approaching the current point according to the operation of the GUI controls, and changes the color and transparency, contrast, shape and size of the disease image to display the image of the procedure from disease occurrence to treatment and cure.

10. The method of claim 7, wherein a search window for searching for a disease is provided on the first screen, the EMR system searches for a disease name and a disease occurrence location, searches for a disease matching the disease from the patient's medical record, and can visualize an image of the disease on the human body image, providing a function of searching for an image of the disease on the first screen in various ways.

11. The method of claim 7, wherein when a query is requested, the stored video or images are sequentially queried to obtain the patient status, and the GUI controls are set so that the stored still image or images can be controlled to be played; the GUI controls may include a play button, a back button, and a quick button so that a search function may be implemented through the buttons.

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