JP2021026316A - Medical system and biological information inspection device - Google Patents

Abstract

To provide a medical system capable of appropriately executing examination according to order information, while reducing time and effort required for inputting setting information by a user and suppressing wrong operation in selection of the setting information.SOLUTION: In a system, a data management device 2 is configured to collect and store setting information of a plurality of electrocardiographs 1 under the control, and the electrocardiograph 1 is configured to acquire the setting information of the plurality of electrocardiographs 1 stored in the data management device 2 from the data management device, so that it is possible to appropriately execute an electrocardiogram examination according to order information while suppressing time and effort required for inputting the setting information by a user and suppressing wrong operation.SELECTED DRAWING: Figure 4

Description

The present invention relates to a medical system and a biometric information inspection device.

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 test, etc.) with one electrocardiograph.

In addition, as an operation mode of the electrocardiograph, for example, in the operation of a large hospital, an instruction of the subject information and the contents of the examination to be performed on that day is given from a higher system (which may be called a higher device) such as HIS (Hospital Information System). Is issued as order information. Then, the order information is received on the electrocardiograph side, the subject information is reflected, and the necessary examination is carried out.

The order information includes information that specifies a test type such as whether to perform a 12-lead test, an arrhythmia test, or a rhythm measurement test. The order information also includes more detailed designation information. For example, detailed designation information includes the analysis section length of the electrocardiographic waveform. As an example, for a 12-lead test, the order information specifies any analysis interval length between 8 and 24 seconds. This order information is created, for example, by a doctor.

Furthermore, in the operation of large hospitals, etc., the test data obtained by the electrocardiograph is transmitted to the host system so that the test implementation status can be confirmed on the host system side. In practice, the test data itself is stored in a data management device provided between the host system and the electrocardiograph.

Japanese Unexamined Patent Publication No. 2006-116207

By the way, whether the electrocardiograph performs a 12-lead test, an arrhythmia test, or a rhythm measurement test based on the information that specifies the test type included in the above-mentioned order information. It can be switched automatically. That is, the inspection type (which may be called the inspection mode) can be easily switched.

On the other hand, in order to set the electrocardiograph so as to match the detailed specified information included in the order information, manual operation by a user such as a medical technician is required, which is not easy. For example, as described above, for the 12-lead inspection, when any analysis section length between 8 seconds and 24 seconds is specified by the order information, the user displays a screen for setting the analysis section length. It is necessary to set the analysis section length to the specified length on this setting screen.

By the way, in the conventional electrocardiograph, in addition to the button to execute the inspection with the default set value (default inspection button), the button to execute the inspection with the set value set by the user is additionally registered in advance. There are things that can be prepared by. As a result, the user manually inputs the set value after the order information arrives by operating either the default inspection button or the inspection button additionally registered in advance according to the contents of the order information. It is possible to perform an inspection conforming to the order information by operating a button without doing so.

However, the number of inspection buttons that can be newly created by additional registration is limited (for example, the number of additionally registered inspection buttons is only a few), and as a result, the contents of the order information can be sufficiently supported. Absent. It is thought that increasing the number of additionally registered inspection buttons can correspond to the contents of the order information, but increasing the number of additionally registered inspection buttons increases the choices of the user and the probability that the user operates the wrong inspection button. To increase. This leads to new problems such as increased likelihood of incorrect testing being performed.

The present invention has been made in consideration of the above points, and is a medical system capable of appropriately performing an inspection according to order information while suppressing the trouble required for the user to input setting information and erroneous operation of setting information selection. And provide a biometric information testing device.

One aspect of the medical system of the present invention is
A higher-level device that issues order information and
A plurality of biometric information inspection devices that perform measurement using setting information according to the order information, and
A data storage device that collects and stores the setting information of the plurality of biometric information test devices, and
With
The biometric information inspection device acquires the setting information of the plurality of biometric information inspection devices stored in the data storage device from the data storage device.

One aspect of the biometric information testing apparatus of the present invention is
A receiver that receives order information from the host device and
The setting information acquisition unit that acquires setting information from the data storage device,
Using the setting information acquired by the setting information acquisition unit, a measurement unit that measures biological information conforming to the order information, and a measurement unit.
To be equipped.

One aspect of the biometric information testing apparatus of the present invention is
A measurement unit that measures biological information based on setting information,
A receiver that receives order information from the host device and
A determination unit that determines whether or not the user has setting information that matches the order information received by the reception unit.
With
Even if the determination unit obtains a determination result that the determination unit does not have the setting information that matches the order information, the measurement unit uses the setting information that it holds to obtain biometric information. Make a measurement.

According to the present invention, it is possible to realize a medical system and a biometric information inspection apparatus capable of appropriately performing an inspection according to order information while suppressing the trouble required for the user to input the setting information and the erroneous operation of selecting the setting information.

Schematic diagram showing the system configuration including the electrocardiograph and the data flow in the hospital The figure which shows how the examination selection button was displayed on the electrocardiograph A flowchart showing the operation of the electrocardiograph of the first embodiment when the order information is received. The figure which showed the relationship between the electrocardiograph and the data management apparatus in Embodiment 2. A flowchart showing the operation of the electrocardiograph of the second embodiment when the order information is received. A block diagram showing a configuration example of a main part of the electrocardiograph according to the second embodiment. Flow chart showing the operation of the electrocardiograph of the third embodiment

<1> Embodiment 1
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 device 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 test. The data management device 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 device 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 device 2. The data management device 2 stores the inspection data and sends an order completion notification to the host system 3.

FIG. 2 is a diagram showing a state in which the test selection button is displayed on the electrocardiograph 1. As default buttons, "12-lead test" button, "arrhythmia test" button, "rhythm measurement test" button, "master test test" button, "post-load test" button, "15-lead test" button, etc. are displayed. There is. On the other hand, as the buttons additionally registered by the user, the "additionally registered 12-lead" button and the "additionally registered arrhythmia" button are displayed. When the user operates the default button, the inspection with the default setting is performed. On the other hand, when the user operates the additionally registered button, the inspection with the set value preset by the user is executed.

FIG. 3 is a flowchart showing the operation of the electrocardiograph 1 when the order information is received. The electrocardiograph 1 of the present embodiment determines the inspection specified in the order information, automatically switches the set value of the electrocardiograph 1 according to the determination result, and performs the inspection using the switched set value. To do. That is, conventionally, the user has been configured to select and operate one of the inspection selection buttons shown in FIG. 2 while looking at the order information, whereas in the electrocardiograph 1 of the present embodiment, the user It is not necessary to operate the inspection selection button by.

When the electrocardiograph 1 of the present embodiment receives the order information in step S11, the electrocardiograph 1 proceeds to step S12. In step S12, the electrocardiograph 1 determines what test the test specified by the order information is. The electrocardiograph 1 moves to step S13a when it obtains a judgment result which is a default 12-lead test, and moves to step S14a when it obtains a judgment result which is an additionally registered 12-lead test, and performs an arrhythmia test. When a certain determination result is obtained, the process proceeds to step S15a, and when a determination result of the rhythm measurement test is obtained, the process proceeds to step S16a.

The electrocardiograph 1 switches the set value for the test to the one corresponding to the default 12-lead test in step S13a, and performs the default 12-lead test in the subsequent step S13b. Similarly, in step S14a, the electrocardiograph 1 switches the set value for the test to one corresponding to the additionally registered 12-lead test, and in the subsequent step S14b, the additionally registered 12-lead test is performed. In step S15a, the electrocardiograph 1 switches the set value for the examination to one corresponding to the arrhythmia examination, and in the subsequent step S15b, the arrhythmia examination is performed. In step S16a, the electrocardiograph 1 switches the set value for the test to one corresponding to the rhythm measurement test, and in the subsequent step S16b, the rhythm measurement test is performed.

In the determination process of step S12, the order information is classified into a plurality of patterns in the present embodiment so that it can be determined what kind of inspection the inspection specified by the order information is. For example, the order information for the 12-lead test is classified as pattern 1, the order information for the arrhythmia test is classified as pattern 2, and the order information for the rhythm test is classified as pattern 3. Further, the default 12-lead test is classified as pattern 1-1, and the additionally registered 12-lead test is classified as pattern 1-2. By doing so, the electrocardiograph 1 can move from step S12 to step S14a when, for example, information indicating pattern 1-2 is received as order information.

As described above, according to the present embodiment, the inspection specified in the order information is determined, the set value of the electrocardiograph 1 is automatically switched according to the determination result, and the switched set value is used. By carrying out the examination, it becomes unnecessary for the user to operate the examination selection button, and it becomes possible to appropriately execute the electrocardiogram examination according to the order information while suppressing the trouble and erroneous operation by the user.

As shown in FIG. 3, in addition to the automatic inspection switching, the manual switching may be forcibly performed. That is, as shown in the example of FIG. 3, even if the inspection specified in the order information in step S12 is determined to be the default 12-lead inspection, it is added manually (that is, by a button operation by the user). You may switch to the registered 12-lead test.

<2> Embodiment 2
In the first embodiment, a case where the inspection specified by the order information is determined and the set value of the electrocardiograph 1 is automatically switched according to the determination result has been described. However, the electrocardiograph 1 does not always have a set value registered in advance that matches the test specified in the order information. That is, if the order information for specifying the inspection with the set value other than the default 12-lead inspection setting value and the additionally registered 12-lead inspection setting value is received, the inspection cannot be performed or the inspection cannot be performed. , The user needs to enter a new setting value included in the order information.

The configuration of the present embodiment takes this into consideration.

FIG. 4 shows the relationship between the electrocardiograph 1 and the data management device 2 in the present embodiment.

A plurality of electrocardiographs 1 and a data management device 2 are connected by, for example, a LAN (Local Area Network). The data management device 2 is embodied by a server and has a data storage unit 21. The data storage unit 21 has a shared folder 21a and a subject database (DB) 21b. The shared folder 21a stores an electrocardiograph setting file consisting of the setting information of the electrocardiograph 1, and the subject database 21b stores the doctor name, technician name, etc. in association with the subject's affiliation code. To.

The data management device 2 of the present embodiment collects and stores the setting information of a plurality of electrocardiographs 1 under it in the shared folder 21a.

This will be described in detail. Each electrocardiograph 1 holds a set value additionally registered by the user. Each electrocardiograph 1 sends the additionally registered set value to the data management device 2 via, for example, a LAN. As a result, the setting information of the plurality of electrocardiographs 1 under the control is collected and stored in the shared folder 21a of the data management device 2.

The electrocardiograph 1 of the present embodiment acquires the setting information of the plurality of electrocardiographs 1 stored in the shared folder 21a from the data management device 2. This acquisition may be performed, for example, when a dedicated button is operated by the user, or may be performed when the electrocardiograph 1 is activated, and the test setting information instructed by the order information may be obtained. If it is determined that the button is not held by itself, only the setting information may be acquired. That is, the electrocardiograph 1 does not necessarily have to acquire all the setting information stored in the shared folder 21a of the data management device 2, and may acquire only the necessary setting information.

Further, in the example of FIG. 4, the electrocardiograph 1 has a throttle for inserting the SD card 30, can store its own setting information in the SD card 30, and other hearts stored in the SD card 30. The setting information of the electric meter 1 can be read. That is, the setting information can be shared with the other electrocardiograph 1 via the SD card 30.

FIG. 5 is a flowchart showing the operation of the electrocardiograph 1 of the present embodiment when the order information is received.

When the electrocardiograph 1 of the present embodiment receives the order information in step S21, the electrocardiograph 1 proceeds to step S22. In step S22, the electrocardiograph 1 determines whether or not it holds the test setting information instructed by the order information. When the electrocardiograph 1 obtains a negative result in step S22, the electrocardiograph 1 proceeds to step S23 and reads setting information from the data management device 2 to acquire the setting information. The electrocardiograph 1 repeats the process of steps S22-S23-S22 until a positive result is obtained in step S22.

When the electrocardiograph 1 obtains a positive result in step S22, the electrocardiograph 1 proceeds to step S24. In step S24, the electrocardiograph 1 determines what kind of test the test specified by the order information is. The electrocardiograph 1 proceeds to step S25a when a determination result of the default 12-lead test is obtained, and proceeds to step S26a when a determination result of the additionally registered 12-lead test is obtained, and the data management device. When the determination result of the 12-lead test obtained from 2 is obtained, the process proceeds to step S27a. Incidentally, in FIG. 5, the arrhythmia test and the rhythm measurement test are not shown for the sake of simplification of the explanation, but of course, the arrhythmia test and the rhythm measurement test can also be included as shown in FIG.

In step S25a, the electrocardiograph 1 switches the set value for the test to one corresponding to the default 12-lead test, and in the subsequent step S25b, the default 12-lead test is performed. Similarly, in step S26a, the electrocardiograph 1 switches the set value for the test to one corresponding to the additionally registered 12-lead test, and in the subsequent step S26b, the additionally registered 12-lead test is performed. In step S27a, the electrocardiograph 1 switches the set value for the test to one corresponding to the 12-lead test acquired from the data management device 2, and in the subsequent step S27b, the 12-lead test acquired from the data management device 2 is performed. carry out.

As a result, even if the 12-lead test specified by the order information is neither the default 12-lead test nor the 12-lead test additionally registered by the own device, the 12-lead test acquired from the data management device 2 By using the set value, it is possible to increase the possibility that the 12-lead inspection specified by the order information can be performed.

That is, each of the N electrocardiographs 1 holds one pattern of the set value of the 12-lead test additionally registered, and if they are different, the data management device 2 has 12 patterns. The set value for the guidance inspection is stored for N patterns. Therefore, if the 12-lead inspection pattern specified by the order information is any of these N patterns, the specified 12-lead inspection can be performed without the user inputting a new set value. Will be.

Incidentally, when the 12-lead inspection pattern specified by the order information is not any of the above N patterns, a display instructing the user to input a new set value may be performed.

FIG. 6 is a block diagram showing a configuration example of a main part of the electrocardiograph 1 according to the present embodiment.

The electrocardiograph 1 of the present embodiment has a receiving unit 11 for receiving order information from a higher-level device (data management device 2), a setting information acquisition unit 12 for acquiring setting information from the data management device 2, and setting information. It has an analysis unit 13 that analyzes an electrocardiographic waveform that matches the order information by using the setting information acquired by the acquisition unit 12.

As described above, according to the system of the present embodiment, the data management device 2 collects and stores the setting information of the plurality of electrocardiographs 1 under the control, and the electrocardiograph 1 is the data management device 2. By acquiring the setting information of a plurality of electrocardiographs 1 stored in the data management device, it is possible to perform an electrocardiogram examination according to the order information while suppressing the trouble and erroneous operation required for the user to input the setting information. A system that can be executed properly can be realized.

Further, according to the configuration of the present embodiment, as compared with the case where the electrocardiograph holds all the setting information corresponding to all the orders, the electrocardiograph 1 has only the necessary setting information from the data management device 2. Since it can be acquired, it is not necessary to retain unnecessary setting information.

<3> Embodiment 3
FIG. 7 is a flowchart showing the operation of the electrocardiograph 1 according to the present embodiment, in which the parts corresponding to those in FIG. First, as a premise, the electrocardiograph 1 of the present embodiment has a configuration of acquiring setting information of a plurality of other electrocardiographs 1 from the data management device 2 like the electrocardiograph 1 of the second embodiment. Alternatively, the configuration may be such that only the default setting information and the setting information additionally registered by the own device are held as in the first embodiment.

When the electrocardiograph 1 of the present embodiment receives the order information in step S31, the electrocardiograph 1 proceeds to step S32. In step S32, the electrocardiograph 1 determines what test the test specified by the order information is. The electrocardiograph 1 proceeds to step S13a when it obtains a determination result of the default 12-lead test, and proceeds to step S33 when it obtains a determination result of a non-default 12-lead test, and performs an arrhythmia test. When a certain determination result is obtained, the process proceeds to step S15a, and when a determination result of the rhythm measurement test is obtained, the process proceeds to step S16a.

In step S33, the electrocardiograph 1 of the present embodiment includes 12-lead test setting information that matches the instructed 12-lead test among the 12-lead test setting information that it has other than the default. Determine if it exists.

When the electrocardiograph 1 of the present embodiment obtains a positive result in step S33, the electrocardiograph 1 moves to step S34a and switches the set value for the test to one corresponding to the 12-lead test conforming to the instructed test. In a subsequent step S34b, a 12-lead test conforming to the indicated test is performed.

On the other hand, when the electrocardiograph 1 of the present embodiment obtains a negative result in step S33, the process proceeds to step S13a, and the set value for the test is switched to the one corresponding to the default 12-lead test. In the following step S13b, a default 12-lead test is performed.

As described above, in the electrocardiograph 1 of the present embodiment, even if the electrocardiograph 1 itself does not have the setting information matching the order information, the default setting information held by the self is used. Analyze the radio wave type. As a result, if the user does not have the setting information that matches the order information, the analysis operation does not stop or the user is not required to input new setting information, and the standard analysis using the default setting information is performed. Processing can be performed.

In the electrocardiograph 1, when the analysis result is obtained by such processing, the obtained analysis result is not obtained by using the setting information specified by the order information, but is a standard default. It may be notified that it is obtained by using the set value.

In practice, the electrocardiograph of the present embodiment has an analysis unit that analyzes an electrocardiographic waveform based on setting information, a reception unit that receives order information from a higher-level device, and order information received by the reception unit. It has a determination unit for determining whether or not it has setting information suitable for. Then, even if the analysis unit obtains a determination result that the determination unit does not have the setting information that matches the order information, the analysis unit uses the standard setting information that it holds. Analyze the radio wave type.

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 first and second embodiments, the case where the present invention is applied to a medical system having a plurality of electrocardiographs 1 has been described, but the present invention is not limited to this, and the setting information according to the order information is used. It can be widely applied to a medical system having a plurality of biometric information inspection devices for measuring. For example, the present invention can be applied to a medical system having an ultrasonic examination device, a lung function examination device, or the like instead of the electrocardiograph 1. In this case, instead of the analysis unit 13 of FIG. 6, a measurement unit that measures biological information that matches the order information may be provided by using the setting information acquired by the setting information acquisition unit 12.

That is, one aspect of the biometric information inspection apparatus of the present invention is
A receiver that receives order information from the host device and
The setting information acquisition unit that acquires setting information from the data storage device,
Using the setting information acquired by the setting information acquisition unit, a measurement unit that measures biological information conforming to the order information, and a measurement unit.
Is provided.

Moreover, one aspect of the biometric information inspection apparatus of the present invention is
A measurement unit that measures biological information based on setting information,
A receiver that receives order information from the host device and
A determination unit that determines whether or not the user has setting information that matches the order information received by the reception unit.
With
Even if the determination unit obtains a determination result that the determination unit does not have the setting information that matches the order information, the measurement unit uses the setting information that it holds to obtain biometric information. It is for measuring.

In the above-described embodiment, the case where the data management device 2 collects and stores the setting information of the plurality of electrocardiographs 1 has been described, but the present invention is not limited to this, in short, a plurality of biometric information test devices. It suffices to have a data storage device that collects and stores the setting information of (for example, electrocardiograph 1). That is, the above-described embodiment is an example in which the data management device 2 is used as the data storage device. If the data management device 2 is used as in the embodiment, it is not necessary to separately provide a data storage device, which is effective.

The present invention is widely applicable to medical systems and biometric information testing devices that are designed to perform tests based on order information.

1 Electrocardiograph 2 Data management device 3 Higher system 11 Receiver 12 Setting information acquisition unit 13 Analysis unit 21 Data storage unit 21a Shared folder 21b Subject database

Claims (5)

A higher-level device that issues order information and
A plurality of biometric information inspection devices that perform measurement using setting information according to the order information, and
A data storage device that collects and stores the setting information of the plurality of biometric information test devices, and
With
The biometric information inspection device acquires the setting information of the plurality of biometric information inspection devices stored in the data storage device from the data storage device.
Medical system. The data storage device collects setting information previously set by the plurality of biometric information inspection devices.
The medical system according to claim 1. A receiver that receives order information from the host device and
The setting information acquisition unit that acquires setting information from the data storage device,
Using the setting information acquired by the setting information acquisition unit, a measurement unit that measures biological information conforming to the order information, and a measurement unit.
A biometric information testing device. A measurement unit that measures biological information based on setting information,
A receiver that receives order information from the host device and
A determination unit that determines whether or not the user has setting information that matches the order information received by the reception unit.
With
Even if the determination unit obtains a determination result that the determination unit does not have the setting information that matches the order information, the measurement unit uses the setting information that it holds to obtain biometric information. Make measurements,
Biological information inspection device. When the determination unit obtains a determination result that the measurement unit does not have the setting information that matches the order information, the measurement unit sets a standard among a plurality of setting information that the measurement unit has. Measure biometric information using information,
The biometric information inspection apparatus according to claim 4.