JP2021023418A - Electrocardiograph and operation method for electrocardiograph - Google Patents

Abstract

To shorten an inspection time of an electrocardiograph capable of performing a plurality of inspections.SOLUTION: An electrocardiograph 10 includes: a reception unit (transmission/reception unit) for receiving order information from a higher rank system; an electrocardiogram data acquisition unit 11 for acquiring electrocardiographic waveform data on a patient; a data storage unit 17 for storing the electrocardiographic waveform data; and an analyzing unit 12 for analyzing the electrocardiographic waveform data. During at least a period in which the analyzing unit 12 is performing analyzing processing corresponding to a first-type electrocardiogram inspection (e.g., a 12 induction inspection) included in the order information, the data storage unit 17 collects and stores electrocardiographic waveform data in a section with respect to a second-type electrocardiogram inspection (e.g., an arhythmia inspection) included in the order information. The analyzing unit 12 performs the analyzing processing corresponding to the first-type electrocardiogram inspection and, after that, performs analyzing processing corresponding to the second-type electrocardiogram inspection using the electrocardiographic waveform data in the section with respect to the second-type electrocardiogram inspection stored in the data storage unit 17.SELECTED DRAWING: Figure 6

Description

The present invention relates to an electrocardiograph and a method of operating the electrocardiograph.

Conventionally, an electrocardiogram has been widely used as a diagnostic index for heart disease. The electrocardiogram detects the electrical activity of the heart on the surface of the body and represents it as an electrocardiographic waveform. By analyzing this electrocardiographic waveform (electrocardiogram), various information on the activity of the heart can be obtained.

In recent years, the development of a digital electrocardiograph that converts an electrocardiogram into data and records it has made it possible to automatically analyze the electrocardiogram using a computer, and various parameters obtained from the electrocardiogram have been studied (for example, patent documents). 1).

In addition, there are some that can perform a plurality of tests (for example, 12-lead test, arrhythmia test, rhythm measurement test, master test, etc.) with one electrocardiograph.

Japanese Unexamined Patent Publication No. 2006-116207

By the way, an electrocardiograph capable of performing a plurality of tests such as a 12-lead test, an arrhythmia test, a rhythm measurement test, and a master test is used in, for example, a hospital. In this case, the electrocardiograph sequentially executes an electrocardiogram according to order information from a higher-level system of a hospital such as HIS (Hospital Information System).

However, in the conventional electrocardiograph, an efficient processing procedure for performing the above-mentioned plurality of tests has not been sufficiently examined. Therefore, there is a drawback that the total time of the electrocardiogram examination becomes long. This is a burden for patients who must continue to wear electrocardiographic electrodes on their body during the examination. In addition, it can be a big disadvantage in a large hospital where a large number of patients are required to be examined.

The present invention has been made in consideration of the above points, and an object of the present invention is to shorten the examination time in an electrocardiograph capable of performing a plurality of examinations.

One aspect of the electrocardiograph of the present invention is
A receiver that receives order information from the host system and
The electrocardiogram data acquisition unit that acquires the patient's electrocardiogram data,
A data storage unit that stores the electrocardiogram data and
An analysis unit that analyzes the electrocardiogram data and
With
The data storage unit is a section related to a second type of electrocardiographic examination included in the order information, at least while the analysis unit is performing an analysis process corresponding to the first type of electrocardiographic examination included in the order information. Collect and save ECG data
After performing the analysis processing corresponding to the first type of electrocardiography, the analysis unit uses the electrocardiogram data of the section related to the second type of electrocardiography stored in the data storage unit to perform the first type of electrocardiography. The analysis process corresponding to the two types of electrocardiography is performed.

One aspect of the method of operating the electrocardiograph of the present invention is
Steps to receive order information from the host system,
Steps to get the patient's electrocardiogram data,
The step of saving the electrocardiogram data and
Steps to analyze the electrocardiogram data and
Including
In the step of storing the electrocardiogram data, at least while performing the analysis processing corresponding to the first type of electrocardiography included in the order information, the section relating to the second type of electrocardiography included in the order information is performed. Collect and save ECG data,
In the step of analyzing the electrocardiogram data, the second type is performed by using the electrocardiogram data of the section related to the second type of electrocardiography saved after performing the analysis processing corresponding to the first type of electrocardiography. Performs analysis processing corresponding to the electrocardiogram examination of.

According to the present invention, in an electrocardiograph capable of performing a plurality of tests, the test time can be shortened without complicating the operation by the user.

Schematic diagram showing the system configuration including the electrocardiograph and the data flow in the hospital A flowchart showing a first comparative example of the processing flow of the electrocardiograph, which has been conventionally performed. The figure which shows the example of the 12-lead waveform collected in the 1st comparative example. The figure which shows the analysis result of the 12-lead test in the 1st comparative example. The figure which shows the display example of the order list in the 1st comparative example The figure which shows the example of the arrhythmia waveform collected in the 1st comparative example. The figure which shows the analysis result of the arrhythmia examination in the 1st comparative example The figure which shows the display image example at the end of an order in the 1st comparative example A flowchart showing a second comparative example of the processing flow of the electrocardiograph, which has been conventionally performed. The figure which shows the example of the 12-lead waveform collected in the 2nd comparative example. The figure which shows the example of the freeze screen in the 2nd comparative example The figure which shows the example of the freeze screen in the 2nd comparative example The figure which shows the analysis result of the 12-lead test in the 2nd comparative example. The figure which shows the analysis result of the arrhythmia examination in the 2nd comparative example The figure which shows the display image example at the end of an order in the 2nd comparative example Block diagram showing the configuration of the electrocardiograph of the embodiment A flowchart for explaining the operation of the electrocardiograph of the embodiment. The figure which shows the example of the 12-lead waveform collected in an embodiment. The figure which shows the example of the freeze screen in embodiment The figure which shows the analysis result of the 12-lead test in an embodiment. The figure which shows the display example of the order list in embodiment The figure which shows the example of the arrhythmia waveform of the shortage collected in an embodiment. The figure which shows the example of the freeze screen in embodiment The figure which shows the analysis result of the arrhythmia examination in embodiment The figure which shows the example of the display image at the end of an order in embodiment

<1> Background to the present invention First, before explaining the embodiment, the background to the present invention will be described.

FIG. 1 is a schematic diagram showing a configuration of an in-hospital system including an electrocardiograph 1 and a data flow. The in-hospital system of FIG. 1 includes an electrocardiograph 1, a data management system 2, and a host system 3.

The electrocardiograph 1 has a configuration capable of performing a plurality of tests such as a 12-lead test, an arrhythmia test, a rhythm measurement test, and a master test. The data management system 2 has a function of storing measurement data of medical measuring instruments including an electrocardiograph 1 provided in a physiological laboratory and a function of converting data between a higher-level system 3 and each medical measuring instrument. Have. The host system 3 is, for example, HIS.

When the host system 3 issues the order information, the data management system 2 converts the order information into the order information for the electrocardiograph and sends it to the electrocardiograph 1. The electrocardiograph 1 executes an electrocardiogram examination according to the order information. The electrocardiograph 1 sends the test data obtained by the electrocardiogram test and the order completion notification to the data management system 2. The data management system 2 stores inspection data and sends an order completion notification to the host system 3.

FIG. 2 is a flowchart showing a first comparative example of the processing flow of the electrocardiograph 1 that has been conventionally performed. 3A-3F are diagrams showing an example of an image displayed on the electrocardiograph 1.

First, the order list is displayed in step S11. The order information in this example indicates that a 12-lead test and an arrhythmia test should be performed. The medical staff who is the user of the electrocardiograph 1 grasps the examination to be performed by looking at the order list, and confirms the instruction from the doctor based on the comment included in the order.

Next, in step S12, the electrocardiograph 1 switches the examination mode to the 12-lead examination and collects the waveform. Here, the electrocardiograph 1 collects a waveform for 10 seconds as a waveform required for a 12-lead test. FIG. 3A shows an example of 12-lead waveforms collected.

Next, in step S13, the electrocardiograph 1 executes an analysis process corresponding to the 12-lead test using the collected waveforms. The analysis result is displayed on the display unit of the electrocardiograph 1. FIG. 3B shows the analysis result of the 12-lead test. The user confirms the displayed analysis result. The electrocardiograph 1 sends the analysis result to the data management system 2 (data transmission).

Next, in step S14, the electrocardiograph 1 displays an order list. FIG. 3C is a display example of the order list. By looking at this order list, the user recognizes that the next test is an arrhythmia test. Also, confirm the instructions from the doctor based on the comments included in the order.

Next, in step S15, the electrocardiograph 1 switches the examination mode to the arrhythmia examination and collects the waveform. Here, the electrocardiograph 1 collects a waveform for 180 seconds as a waveform necessary for an arrhythmia test. FIG. 3D shows an example of the collected arrhythmia waveform.

Next, in step S16, the electrocardiograph 1 executes an analysis process corresponding to the arrhythmia test using the collected waveform. The analysis result is displayed on the display unit of the electrocardiograph 1. FIG. 3E shows the analysis result of the arrhythmia test. The user confirms the displayed analysis result. The electrocardiograph 1 sends the analysis result to the data management system 2 (data transmission).

Next, in step S17, the electrocardiograph 1 sends an order completion notification and ends the order. FIG. 3F shows an example of a display image of the electrocardiograph 1 at the end of the order.

FIG. 4 is a flowchart showing a second example of the processing flow of the electrocardiograph 1 that has been conventionally performed. 5A-5F are diagrams showing an example of an image displayed on the electrocardiograph 1.

First, the order list is displayed in step S21. The order information in this example indicates that a 12-lead test and an arrhythmia test should be performed. The medical staff who is the user of the electrocardiograph 1 grasps the examination to be performed by looking at the order list, and confirms the instruction from the doctor based on the comment included in the order.

Next, in step S22, the electrocardiograph 1 switches the mode to the examination mode and collects the waveform. In this second comparative example, the electrocardiograph 1 collects the waveforms required for the 12-lead test and the arrhythmia test at once. That is, since the waveform required for the 12-lead test is a waveform for 10 seconds, while the waveform required for the arrhythmia test is a waveform for 180 seconds, it takes at least 180 seconds to collect in step S22. .. Incidentally, although it depends on the order from the upper system 3, the waveform required for the 12-lead test is generally in the range of 8 seconds to 24 seconds, and the waveform required for the arrhythmia test is in the range of 40 seconds to 180 seconds. The waveform required for the rhythm measurement test is in the range of 40 seconds to 10 minutes. FIG. 5A shows an example of the waveforms collected.

Next, in step S23, the electrocardiograph 1 transitions to the freeze screen. The transition to this freeze screen is triggered by a user operation. 5B and 5C show an example of a freeze screen for a 12-lead test. First, the user sets the analysis range of the 12-lead test and the analysis range of the arrhythmia test on the freeze screen shown in FIG. 5B. When the user sets the analysis range and operates the "analysis mode" (here, "analysis mode" means the inspection type to be analyzed) button, a check box as shown in FIG. 5C is displayed. Will be done. Next, when the user checks the inspections listed in the order list from the inspections of the check boxes, operates the return button, and operates the "analyze" button, the checked inspections are analyzed. In the case of this example, the user checks the items of the 12-lead test and the arrhythmia test, operates the return button, and operates the "analyze" button to analyze the 12-lead test and the arrhythmia test. Become.

The electrocardiograph 1 moves to step S24 and changes the mode from the freeze mode to the analysis mode (the "analysis mode" here means that the electrocardiograph 1 is a mode for performing analysis processing).

As described above, the electrocardiograph 1 proceeds to step S25 when the analysis range for each examination is set in step S23 and the mode shift to the analysis mode is instructed in step S24. In step S25, the electrocardiograph 1 executes an analysis process corresponding to the 12-lead test and the arrhythmia test using the waveform in the set analysis range. The analysis result is displayed on the display unit of the electrocardiograph 1. FIG. 5D shows the analysis result of the 12-lead test, and FIG. 5E shows the analysis result of the arrhythmia test. The user confirms the displayed analysis result. The electrocardiograph 1 sends the analysis result to the data management system 2 (data transmission). That is, in the first comparative example shown in FIG. 2, the analysis, confirmation, and data transmission of the 12-lead test and the analysis, confirmation, and data transmission of the arrhythmia test were performed separately in steps S13 and S15. In the second comparative example shown in 4, in step S25, the analysis, confirmation, and data transmission of the 12-lead test and the analysis, confirmation, and data transmission of the arrhythmia test are performed collectively.

Next, in step S26, the electrocardiograph 1 sends an order completion notification and ends the order. FIG. 5F shows an example of a display image of the electrocardiograph 1 at the end of the order.

Here, in the first comparative example shown in FIG. 2, since the waveform collection of the 12-lead test (step S12) and the waveform collection of the arrhythmia test (step S15) are performed separately, the time required for the waveform collection becomes long. .. For example, in the example of FIG. 2, it takes 10 seconds to collect the waveform of the 12-lead test and 180 seconds to collect the waveform of the arrhythmia test, so that the waveform collection time of 190 seconds is required as a whole. As described above, the time required for waveform collection of the 12-lead test is 24 seconds at the maximum depending on the order. In this case, the waveform collection time of 24 + 180 = 204 seconds is required as a whole.

On the other hand, in the second comparative example shown in FIG. 4, since the waveforms of the plurality of tests (12-lead test, arrhythmia test) are collectively collected in step S22, the waveforms are collected as compared with the first comparative example. The time required for this can be shortened. However, in the second comparative example shown in FIG. 4, in step S23 and step S24, the user sets the analysis range for a plurality of inspections while confirming the plurality of order information, and in step S25, the user sets the analysis range. It is necessary to make analysis settings for multiple inspections while confirming multiple orders. Therefore, in the second comparative example shown in FIG. 4, the time and effort of the user is increased as compared with the first comparative example shown in FIG. 2, and the user has some experience in order to perform an accurate operation. Is required.

The inventor of the present invention has arrived at the present invention based on the above considerations.

<2> Embodiments Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, "electrocardiogram" in the following description may be read as "electrocardiographic waveform".

FIG. 6 is a block diagram showing a basic configuration of an electrocardiograph according to an embodiment of the present invention. The electrocardiograph 10 of the present embodiment is used as the electrocardiograph 1 in the system of FIG.

The electrocardiograph 10 includes an electrocardiogram data acquisition unit 11, an analysis unit 12, a display unit 13, an operation input unit 14, a control unit 15, a transmission / reception unit 16, and a data storage unit 17.

The electrocardiogram data acquisition unit 11 includes an amplifier circuit and an analog digital circuit for amplifying an electrocardiographic signal from a plurality of electrocardiographic electrodes 21 attached to the patient, and outputs the electrocardiogram data of the patient.

The analysis unit 12 analyzes the electrocardiogram data. The analysis unit 12 performs different analysis depending on the type of examination such as 12-lead examination and arrhythmia examination. Since the analysis for each inspection of the analysis unit 12 is a known technique, detailed description here will be omitted. The analysis result obtained by the analysis unit 12 is displayed on the display unit 13. Further, the analysis result is sent to the data management system 2 (FIG. 1) via the transmission / reception unit 16.

The display unit 13 is, for example, a liquid crystal display. The operation input unit 14 accepts user operations. When the display unit 13 is a liquid crystal display with a touch panel, the operation input unit 14 accepts a touch operation of the touch panel by the user. When a keyboard or mouse is connected to the electrocardiograph 10, the operation input unit 14 accepts these device operations by the user.

The control unit 15 controls the operation of the electrocardiograph 10 based on the operation signal output from the operation input unit 14. Further, order information is input to the control unit 15 via the transmission / reception unit 16, and the control unit 15 controls the operation of the electrocardiograph 10 based on the order information. Specifically, the order information is displayed on the display unit 13, and the analysis unit 12, the data storage unit 17, and the like are controlled based on the order information. As described above, the order information is issued by the higher-level system 3 (FIG. 1) such as HIS.

The data storage unit 17 stores the electrocardiogram data acquired by the electrocardiogram data acquisition unit 11. The electrocardiogram data stored in the data storage unit 17 is used for analysis in the analysis unit 12.

FIG. 7 is a flowchart showing a processing flow of the electrocardiograph 10 of the present embodiment. 8A-8H are diagrams showing an example of an image displayed on the electrocardiograph 10.

First, in step S31, the order list is displayed on the display unit 13. The order information in this example indicates that a 12-lead test and an arrhythmia test should be performed. The medical worker who is a user of the electrocardiograph 10 grasps the examination to be performed by looking at the order list, and confirms the instruction from the doctor based on the comment included in the order.

Next, in step S32, the electrocardiograph 10 switches the examination mode to the 12-lead examination based on the order information, and collects the electrocardiogram data. Here, the electrocardiograph 10 collects electrocardiogram data for 10 seconds as a waveform required for the 12-lead test. This electrocardiogram data may be stored in the memory of the analysis unit 12 or may be recorded in the data storage unit 17. FIG. 8A shows an example of the 12-lead waveform collected.

Next, in step S33, the electrocardiograph 10 transitions to the freeze screen. The transition to this freeze screen is triggered by a user operation. FIG. 8B shows an example of a freeze screen. The user sets the analysis range of the 12-lead test on the freeze screen shown in FIG. 8B.

Next, in step S34, the electrocardiograph 10 executes an analysis process corresponding to the 12-lead test using the electrocardiogram data in the set analysis range. The analysis result is displayed on the display unit 13. FIG. 8C shows the analysis result of the 12-lead test. The user confirms the displayed analysis result. Further, the electrocardiograph 10 sends the analysis result to the data management system 2 (FIG. 1) via the transmission / reception unit 16 (data transmission).

Next, in step S35, the electrocardiograph 10 displays an order list. FIG. 8D is a display example of the order list. By looking at this order list, the user recognizes that the next test is an arrhythmia test. Also, confirm the instructions from the doctor based on the comments included in the order.

The electrocardiograph 10 of the present embodiment stores the electrocardiogram data in the data storage unit 17 while performing the processing of steps S32-S35 by executing step S40 in parallel with steps S32-S35. (Waveform storage). That is, when the processing time in steps S32 to S35 is 150 seconds, the data storage unit 17 stores the electrocardiogram data for a period of 150 seconds. In other words, the electrocardiograph 10 stores the electrocardiogram data in the background during the processing of steps S32-S35.

Next, in step S36, the electrocardiograph 10 switches the examination mode to the arrhythmia examination and collects the electrocardiogram data. The collection of the electrocardiogram data is performed in order to make up for the shortage of the electrocardiogram data saved in step S40. That is, if the electrocardiogram data can be saved without any shortage in step S40, it is not necessary to collect the electrocardiogram data here. For example, if the electrocardiogram data required for the arrhythmia test specified in the order information is 180 seconds of data and 150 seconds of data can be saved in step S40, the shortage of 30 seconds of data is stored in step S36. collect. FIG. 8E shows an example of the deficient arrhythmia waveform collected.

Next, in step S37, the electrocardiograph 10 transitions to the freeze screen. The transition to this freeze screen is triggered by a user operation. FIG. 8F shows an example of a freeze screen. On this freeze screen, the electrocardiogram data saved in step S40 and the insufficient electrocardiogram data collected in step S36 are combined and displayed. The user sets the analysis range of the arrhythmia test on the freeze screen shown in FIG. 8F.

Next, in step S38, the electrocardiograph 10 executes an analysis process corresponding to the arrhythmia test using the electrocardiogram data in the set analysis range. The analysis result is displayed on the display unit 13. FIG. 8G shows the analysis result of the arrhythmia test. The user confirms the displayed analysis result. Further, the electrocardiograph 10 sends the analysis result to the data management system 2 (FIG. 1) via the transmission / reception unit 16 (data transmission).

Next, in step S39, the electrocardiograph 10 sends an order completion notification from the transmission / reception unit 16 to the data management system 2 to end the order. FIG. 8H shows an example of a display image of the electrocardiograph 10 at the end of the order.

Here, comparing the processing of the electrocardiograph 10 of the present embodiment with the processing shown in FIG. 2, in the processing of FIG. 2, after waveform collection and analysis for 12-lead examination, for arrhythmia examination. It is necessary to newly collect the electrocardiogram data for 180 seconds, but the electrocardiograph 10 of the present embodiment stores the electrocardiogram data for the arrhythmia test during the collection and analysis of 12 leads. Therefore, the total inspection time can be shortened. That is, in the process of the present embodiment, the time of step S15 in FIG. 2 can be shortened.

Since there are many patients in large hospitals, there is a demand to shorten the time required for per capita examination as much as possible. For example, it may be required to test about 50 patients a day with one electrocardiograph. In such a case, the electrocardiograph 10 of the present embodiment is very effective because the examination time per person can be shortened. Moreover, since the examination time is shortened, the burden on the patient to which the electrocardiographic electrode 21 is attached can be reduced.

Further, comparing the processing of the electrocardiograph 10 of the present embodiment with the processing shown in FIG. 4, in the processing of FIG. 4, in step S23 and step S24, a plurality of users confirm a plurality of order information. It is necessary to set the analysis range for the inspection of the above, or in step S25, set the analysis for the plurality of inspections while the user confirms the plurality of orders. On the other hand, in the process of the electrocardiograph 10 of the present embodiment shown in FIG. 7, the user sets the analysis range and the analysis setting for each test while checking the order information for each test. In other words, after the setting and analysis of one inspection is completed, the setting and analysis of the next inspection may be performed, so that even a user who is unfamiliar with the inspection can perform the setting operation accurately. become able to.

In practice, the process shown in FIG. 4 takes less time to collect electrocardiogram data than the process shown in FIG. 2, but it is complicated because an arrhythmia test and a rhythm measurement test are also performed in the 12-lead test. Since operation and judgment are required, it was difficult to operate it except in specialized hospitals where there are familiar technicians. On the other hand, since the electrocardiograph 10 of the present embodiment is easy to operate, it can be operated in a medical institution without a familiar technician.

As described above, the electrocardiograph 10 of the present embodiment includes a receiving unit (transmission / reception unit 16) for receiving order information from the host system 3, an electrocardiogram data acquisition unit 11 for acquiring the patient's electrocardiogram data, and an electrocardiogram data acquisition unit 11. It has a data storage unit 17 for storing electrocardiogram data and an analysis unit 12 for analyzing electrocardiogram data, and the data storage unit 17 has at least the analysis unit 12 of the first type of electrocardiography examination (for example,) included in the order information. While performing the analysis process corresponding to the 12-lead test), the electrocardiogram data of the section related to the second type of electrocardiogram test (for example, arrhythmia test) included in the order information is collected and saved, and the analysis unit 12 collects and saves the second type of electrocardiogram test. After performing the analysis processing corresponding to the one type of electrocardiography, the second type of electrocardiography is supported by using the electrocardiogram data of the section related to the second type of electrocardiography stored in the data storage unit 17. Perform analysis processing.

As a result, in an electrocardiograph capable of performing a plurality of types of tests, the test time can be shortened without complicating the operation by the user.

The above-described embodiments are merely examples of embodiment of the present invention, and the technical scope of the present invention should not be construed in a limited manner by these. That is, the present invention can be implemented in various forms without departing from its gist or its main features.

In the above-described embodiment, as shown in FIG. 7, a case where the electrocardiogram data during the processing of steps S32-S35 is stored in the data storage unit 17 has been described. For example, the processing of steps S31-S35 has been described. The electrocardiogram data may be stored while the data is being performed. In short, the data storage unit 17 is performing analysis processing corresponding to the first type of electrocardiogram examination included in the order information by at least the analysis unit 12. During (that is, at least during step S34), the electrocardiogram data of the section related to the second type of electrocardiography included in the order information may be collected and stored.

Further, in the above-described embodiment, the case of performing the 12-lead test and the arrhythmia test is mainly described, but the above-mentioned practice is also performed when the order information includes the rhythm measurement test, the master test, and the load test. It can be carried out in the same manner as in the above form.

The present invention is widely applicable to an electrocardiograph that performs an electrocardiogram examination based on order information from a host system.

1, 10 Electrocardiograph 2 Data management system 3 Upper system 11 Electrocardiogram data acquisition unit 12 Analysis unit 13 Display unit 14 Operation input unit 15 Control unit 16 Transmission / reception unit 17 Data storage unit

Claims (4)

A receiver that receives order information from the host system and
The electrocardiogram data acquisition unit that acquires the patient's electrocardiogram data,
A data storage unit that stores the electrocardiogram data and
An analysis unit that analyzes the electrocardiogram data and
With
The data storage unit is a section related to a second type of electrocardiographic examination included in the order information, at least while the analysis unit is performing an analysis process corresponding to the first type of electrocardiographic examination included in the order information. Collect and save ECG data
After performing the analysis processing corresponding to the first type of electrocardiography, the analysis unit uses the electrocardiogram data of the section related to the second type of electrocardiography stored in the data storage unit to perform the first type of electrocardiography. Performs analysis processing corresponding to two types of electrocardiography,
Electrocardiograph. The second type of electrocardiographic examination is an electrocardiographic examination that requires a longer time to collect electrocardiographic data for analysis than the first type of electrocardiographic examination.
The electrocardiograph according to claim 1. The first type of electrocardiographic examination is a 12-lead examination.
The electrocardiograph according to claim 1 or 2. Steps to receive order information from the host system,
Steps to get the patient's electrocardiogram data,
The step of saving the electrocardiogram data and
Steps to analyze the electrocardiogram data and
Including
In the step of storing the electrocardiogram data, at least while performing the analysis processing corresponding to the first type of electrocardiography included in the order information, the section relating to the second type of electrocardiography included in the order information is performed. Collect and save ECG data,
In the step of analyzing the electrocardiogram data, the second type is performed by using the electrocardiogram data of the section related to the second type of electrocardiography saved after performing the analysis processing corresponding to the first type of electrocardiography. Performs analysis processing corresponding to the electrocardiogram examination of
How to operate the electrocardiograph.