JP2022046814A - Bedside monitor and display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bedside monitor and display method capable of displaying a series of biological information of a patient including biological information during a movement acquired by a transport monitor in an easily diagnosable manner.

SOLUTION: A bedside monitor allows an electrocardiographic wave acquired in a state where a transport monitor is connected and an electrocardiographic wave acquired by the transport monitor in a state where the transport monitor is not connected to be displayed by linkage on the same time base, and also displays marks 301, 302 indicating positions where an electrocardiographic wave acquired in a state where the transport monitor is connected and an electrocardiographic wave acquired by the transport monitor in a state where the transport monitor is not connected are linked.

SELECTED DRAWING: Figure 6

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to a display method used in a bedside monitor to which a portable transport monitor can be connected, and a biological information monitoring system having a bedside monitor and a portable transport monitor that can be connected to the bedside monitor. ..

In medical settings such as hospitals, it is necessary to collect, analyze, and display the biological information of each patient (for example, electrocardiogram, blood pressure, respiratory rate, pulse rate, etc.) at any time. In addition, since the patient will be transferred to a hospital room, a laboratory, an operating room, etc., it is necessary to collect the biological information of the patient together with the transfer of the patient. Small medical portable monitor systems (see, for example, Patent Documents 1 and 2) are widely used.

Some systems of this type allow a portable transport monitor to be connected (specifically dockable and removable) to a stationary bedside monitor. This kind of bedside monitor can also be called a host monitor as opposed to a transport monitor.

The transport monitor has a terminal to which electrodes for electrocardiogram measurement are connected, a small display, a data storage device, a battery, etc., and continuously acquires biometric information even while the patient is being transported, and displays and records it. be able to. The biometric information recorded on the transport monitor during patient transfer is transferred to the bedside monitor when the transport monitor is docked to the bedside monitor. The biometric information transferred to the bedside monitor is also sent to the central monitor connected to the bedside monitor.

By using a system having such a transport monitor, it is possible to easily acquire the biometric information of the patient in transit. In addition, by configuring the transport monitor to be docked to the bedside monitor, the transformer can be used without reconnecting the biometric information acquisition electrode attached to the patient between the bedside monitor and the transport monitor. You can continue measuring biometric information simply by inserting and removing the port monitor from the bedside monitor.

Special Table No. 8-504345 Gazette Special Table No. 8-504531 Gazette

By the way, the biometric information acquired by the transport monitor during the transfer of the patient is temporarily stored in the storage unit of the transport monitor, and when the transport monitor is connected to the bedside monitor, the bedside monitor and the bedside monitor It is sent to a higher-level server device via the central monitor. The server device can display both the biometric information acquired by the bedside monitor and the biometric information acquired by the transport monitor on the display unit (display).

Therefore, in the past, a series of biometric information including during transfer could be viewed on a higher-level server device, but it was inconvenient because it could not be viewed on the bedside monitor installed at the site where the patient was actually treated. there were. Insufficient consideration was given to displaying a series of biometric information acquired by a plurality of biometric information monitors including a bedside monitor and a transport monitor in a form that is easy to diagnose.

The present invention has been made in consideration of the above points, and is a bedside monitor capable of displaying a series of biometric information of a patient in an easy-to-diagnose form, including biometric information during transfer acquired by a transport monitor. Provides a display method.

One aspect of the bedside monitor of the present invention is
The bedside monitor used in a biological information monitoring system having a bedside monitor and a portable transport monitor that can be connected to the bedside monitor.
The connection part to which the transport monitor is connected and
The first biometric information acquired when the transport monitor is connected to the connection portion and the second biometric information acquired by the transport monitor when the transport monitor is not connected to the connection portion. A display unit that displays biometric information and
Equipped with
The display unit displays the first biological information and the second biological information by connecting them on the same time axis, and at the position where the first biological information and the second biological information are connected. Display a mark indicating.

One aspect of the display method of the present invention is
A display method used in a biological information monitoring system having a bedside monitor and a portable transport monitor that can be connected to the bedside monitor.
With the transport monitor connected to the bedside monitor, the first biometric information acquisition step of acquiring the first biometric information by the bedside monitor and the transport monitor, and
A second biometric information acquisition step of acquiring a second biometric information by the transport monitor in a state where the transport monitor is not connected,
The first biological information and the second biological information are connected and displayed on the same time axis, and a mark indicating the position where the first biological information and the second biological information are connected is displayed. Display steps and
including.

According to the present invention, it is possible to display a series of biometric information of a patient, including biometric information in transit acquired by a transport monitor, in a form that is easy to diagnose.

FIG. 1A is a diagram showing a state of docking (connection) of a bedside monitor and a transport monitor according to an embodiment, FIG. 1A is a diagram showing a state of removing the transport monitor from the bedside monitor, and FIG. 1B is a diagram showing a transformer together with a patient. A diagram showing how the port monitor is moved, FIG. 1C is a diagram showing how the transport monitor is docked to the bedside monitor. The figure which shows the schematic structure of the in-hospital system to which the bedside monitor and the transport monitor of an embodiment are connected. Block diagram showing the configuration of the bedside monitor of the embodiment Diagram showing the screen displayed on the touch panel when the transport monitor is removed from the bedside monitor. Diagram showing the patient selection screen displayed on the touch panel when the transport monitor is connected to the bedside monitor It is a figure which provides the explanation of the display method of the biological information performed by the bedside monitor of embodiment, and FIG. 6A shows the electrocardiographic waveform acquired in the state where the transport monitor is docked (connected) to the bedside monitor. FIG. 6B shows the electrocardiographic waveform acquired by the transport monitor with the transport monitor removed from the bedside monitor, and FIG. 6C shows the transport monitor redocked (reconnected) to the bedside monitor. The figure which shows the electrocardiographic waveform displayed on the bedside monitor after The figure which shows the display example of another embodiment The figure which shows the display example of another embodiment

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<1> Overall configuration First, the overall configuration and the premise configuration of the embodiment will be described.

FIG. 1 is a diagram showing a state of docking (connection) of the bedside monitors 11 and 12 and the transport monitor 20. Here, although not shown, the transport monitor 20 is connected to a biometric information detection unit for acquiring patient biometric information such as an electrocardiogram measurement electrode.

When the patient is transferred from the place where the bedside monitor 11 is placed to the place where the bedside monitor 12 is placed, medical personnel such as doctors and nurses remove the transport monitor 20 from the bedside monitor 11. (FIG. 1A), the transport monitor is moved with the patient (FIG. 1B), and then the transport monitor 20 is docked to the bedside monitor 12 (FIG. 1C). By doing so, the biometric information of the patient can be acquired by the transport monitor 20 even during the transfer of the patient.

Here, the bottom surface and side surfaces of the transport monitor 20 and the corresponding surfaces of the bedside monitors 11 and 12 are provided with connector portions that are electrically connected to each other when docked, whereby the transformer is provided. The port monitor 20 and the bedside monitors 11 and 12 can send and receive information such as biometric information and setting information to and from each other via the connector portion.

The features of each device when the bedside monitors 11 and 12 and the transport monitor 20 are compared with each other are as follows.

Bedside monitor:
-It is supposed to be installed stationary on the bedside and is heavier than the transport monitor.
-The number of biological information parameters that can be displayed is larger than that of the transport monitor.
-The number of external devices that can be connected is larger than that of the transport monitor.
-The display is larger than the transport monitor, and an extended display can also be connected.
-It is assumed that the central monitor is connected to the network.

Transport monitor:
-It is supposed to be carried around, and is smaller and lighter than a bedside monitor.
-The number of biological information parameters that can be displayed is smaller than that of the bedside monitor.
-The number of external devices that can be connected is less than that of a bedside monitor.
-The display is smaller than the bedside monitor.
-Has a memory that can record the patient's biological information while moving. This memory has a capacity for recording biometric information for, for example, 10 days.

The bedside monitor and the transport monitor do not necessarily have all of the above-mentioned features, but at least the transport monitor is smaller and lighter than the bedside monitor and is portable.

FIG. 2 is a diagram showing a schematic configuration of an in-hospital system (hereinafter referred to as “in-hospital system”) 10 to which the bedside monitor and the transport monitor of the present embodiment are connected. In the in-hospital system 10, one or more bedside monitors 11A to 11X are installed in the operating room, one or more bedside monitors 12A to 12X are installed in the ICU (Intensive Care Unit), and one or more bedside monitors 12A to 12X are installed in the ward. Bedside monitors 13A to 13X are installed. The "ward" described in the present specification is a so-called "general ward" excluding a special treatment room such as an operating room or an ICU.

The bedside monitors 11A to 11X in the operating room are connected to the central monitor 31, the bedside monitors 12A to 12X in the ICU are connected to the central monitor 32, and the bedside monitors 13A to 13X in the ward are connected to the central monitor 33. It is connected.

Further, the central monitors 31, 32, 33 are connected to the server device 40. As a result, the biometric information acquired by the bedside monitors 11A to 11X is aggregated in the central monitor 31 for display and recording, and the biometric information acquired by the bedside monitors 12A to 12X is aggregated in the central monitor 32. The display and recording are performed, and the biometric information acquired by the bedside monitors 13A to 13X is aggregated in the central monitor 33 and displayed and recorded. Further, the biometric information acquired by the central monitors 31, 32, and 33 is aggregated and recorded in the server device 40. The server device 40, for example, responds to the request of the central monitors 31, 32, 33 and the bedside monitors 11A to 11X, 12A to 12X, 13A to 13X, and records the recorded biological information on the central monitors 31, 32, 33 and the bedside monitor. It can be sent to 11A to 11X, 12A to 12X, and 13A to 13X.

The transport monitor 20 can be docked (connected) to each bedside monitor 11A to 11X, 12A to 12X, 13A to 13X, moves with the patient, and the bedside monitor 11A to 11X to which the patient is transferred. , 12A-12X, 13A-13X docked (connected).

Although the in-hospital system 10 is shown in FIG. 2, the transport monitor 20 can be docked (connected) to, for example, a bedside monitor provided in an ambulance.

<2> Configuration of Bedside Monitor FIG. 3 is a block diagram showing the configuration of the bedside monitor 100 according to the present embodiment. The bedside monitor 100 is used as the bedside monitors 11A to 11X, 12A to 12X, and 13A to 13X of FIGS. 1 and 2.

The bedside monitor 100 has connector portions 101, 102, 103.

The connector unit 101 is a connector for connecting the biological information detection unit attached to the patient to the bedside monitor 100. The connector portion 101 has an electrocardiogram measurement electrode 201 for detecting an electrocardiogram, a blood pressure measuring cuff 202 for detecting blood pressure, a body temperature sensor 203 for detecting body temperature, and a SpO ₂ sensor for detecting SpO ₂ . A biometric information detection unit such as 204 and a cardiac output sensor 205 for detecting the cardiac output is connected.

A transport monitor 20 is connected to the connector portion 102. The central monitor 30 is connected to the connector unit 103.

By executing a predetermined measurement process, the measurement processing unit 104 performs a biological information detection unit (electrocardiographic electrode 201, blood pressure measurement cuff 202, body temperature sensor 203, SpO ₂ sensor 204, and cardiac output) connected to the connector unit 101. The patient's biological information is measured using the output sensor 205). As for the method of measuring various biometric information using the biometric information detection unit, conventionally known methods can be applied, and therefore detailed description thereof will be omitted here. The biological information obtained by the measurement processing unit 104 is stored in the storage unit 105 and displayed on the touch panel 109.

On the other hand, the biometric information acquired by the transport monitor 20 is stored in the storage unit 105 via the connector unit 102 and the transmission / reception processing unit 106. Incidentally, the biometric information acquired by the transport monitor 20 while the transport monitor 20 is moving is temporarily stored in the storage unit (not shown) of the transport monitor, and when connected to the bedside monitor 100, the connector unit is used. It is transferred and stored in the storage unit 105 of the bedside monitor 100 via the transmission / reception processing unit 106.

The biometric information stored in the storage unit 105 is sent to the central monitor 30 via the transmission / reception processing unit 106 and the connector unit 103. As a result, the central monitor 30 can display and record the biometric information acquired by the bedside monitor 100 and the transport monitor 20.

The control unit 110 controls the measurement processing unit 104, the transmission / reception processing unit 106, the display control unit 107, and the alarm indicator 108.

The touch panel 109 is controlled by the display control unit 107 and displays biological information in the form of measured values or waveforms. Further, the touch panel 109 not only has a display function for displaying biological information, but also has a function as an operation input unit for receiving an input operation by an operator. Specifically, information indicating a user's touch operation on the touch panel 109 is sent from the touch panel 109 to the control unit 110, and the control unit 110 changes the display on the touch panel 109 and the mode of the bedside monitor 100 according to the touch operation. Performs various registration processes.

The alarm indicator 108 is provided on the upper part of the housing of the bedside monitor 100, and emits light, for example, red when the control unit 110 determines that an abnormality has occurred in the biological information.

Further, the bedside monitor 100 has a connection detection unit 111 and an ID identification unit 112. The connection detection unit 111 detects whether or not the transport monitor 20 is connected to the connector unit 102, and sends the detection result to the control unit 110. The ID identification unit 112 inputs the patient ID set in the transport monitor 20 connected to the connector unit 102 via the connector unit 102, and the patient ID of the transport monitor 20 to which this patient ID is previously connected is input. It is identified whether or not it is the same as, and the identification result is sent to the control unit 110.

When the transport monitor 20 is removed from the bedside monitor 100, this is detected by the connection detection unit 111, and the touch panel 109 displays the screen shown in FIG. When the "monitor interruption" button is touched by the user (medical worker), the bedside monitor 100 enters the monitoring interruption mode and interrupts the monitoring of biometric information. On the other hand, when the user touches the "get out of bed" button, the bedside monitor 100 performs the out of bed process.

When the transport monitor 20 is connected to the bedside monitor 100, this is detected by the connection detection unit 111, and the touch panel 109 displays the patient selection screen shown in FIG. On this screen, the user can use the patient information associated with the patient ID set in the transport monitor 20 and the patient associated with the patient ID set in the device (bedside monitor 100). You can select either a mode that uses information or a mode that newly inputs patient information and starts monitoring.

<3> Display of biological information according to the embodiment FIG. 6 is a diagram provided for explaining a method of displaying biological information performed by the bedside monitor 100 of the present embodiment. In addition, in FIG. 6, in order to simplify the figure, the time direction is shown shorter than the actual time.

FIG. 6A is an electrocardiographic waveform acquired with the transport monitor 20 docked (connected) to the bedside monitor 100. This electrocardiographic waveform is stored in the storage unit 105 of the bedside monitor 100.

FIG. 6B is an electrocardiographic waveform acquired by the transport monitor 20 with the transport monitor 20 removed from the bedside monitor 100. This electrocardiographic waveform is stored in a storage unit (not shown) of the transport monitor 20.

FIG. 6C is an electrocardiographic waveform displayed on the bedside monitor 100 after the transport monitor 20 is redocked (reconnected) to the bedside monitor 100. As can be seen from FIG. 6C, the bedside monitor 100 has an electrocardiographic waveform (electrocardiographic waveform of FIG. 6A) acquired with the transport monitor 20 connected and a state in which the transport monitor 20 is not connected. The electrocardiographic waveform (electrocardiographic waveform in FIG. 6B) acquired by the transport monitor 20 is connected and displayed on the same time axis.

In addition, the bedside monitor 100 has an electrocardiographic waveform (electrocardiographic waveform in FIG. 6A) acquired with the transport monitor 20 connected and a transport monitor 20 with the transport monitor 20 not connected. The marks 301 and 302 indicating the positions connected to the electrocardiographic waveforms (electrocardiographic waveforms in FIG. 6B) acquired by the above are displayed. The position with the mark 301 is the position corresponding to t1 when the transport monitor 20 is removed from the bedside monitor 100, and the position with the mark 302 is the position where the transport monitor 20 is reattached to the bedside monitor 100. It is the position corresponding to the time point t2 when it is connected (reconnected). By displaying the markers 301 and 302, the medical staff can easily recognize from where to where the electrocardiographic waveform is the waveform acquired by the transport monitor 20 during the transfer of the patient. In particular, in the present embodiment, triangular figures are used as the marks 301 and 302, and their vertices face the direction of the waveform section acquired by the transport monitor 20 during the transfer of the patient, so that the marks are directed at a glance. The waveform section acquired during movement can be recognized.

Further, in the present embodiment, as can be seen from FIG. 6C, instead of simply connecting the electrocardiographic waveform of FIG. 6A and the electrocardiographic waveform of FIG. 6B, mask sections 401 and 402 are provided at the joint to provide the core of FIG. 6A. The radio wave type and the electrocardiographic waveform shown in FIG. 6B are connected. By doing so, there was a difference between the machine time of the bedside monitor 100 and the machine time of the transport monitor 20, and the two electrocardiographic waveforms to be connected were relatively shifted in the time direction. However, in the electrocardiographic waveform in which the two electrocardiographic waveforms are connected, the inconvenience caused by this difference in machine time can be suppressed.

Specifically, if two electrocardiographic waveforms are connected without providing mask sections 401 and 402, the waveforms will be displayed as if they are fluctuating due to the difference in machine time at the joint position. It ends up. Although this waveform fluctuation is not an actual disturbance of the electrocardiographic waveform, the doctor may mistake it for the disturbance of the electrocardiographic waveform and diagnose it as an abnormality such as an arrhythmia. By providing the mask sections 401 and 402 as in the present embodiment, such misdiagnosis can be prevented. Incidentally, in reality, it is assumed that a difference of about several msec occurs between the machine time of the bedside monitor 100 and the machine time of the transport monitor 20. In consideration of this, it is preferable that the mask sections 401 and 402 are each set to about several msec or more.

Practically, the process of connecting the two electrocardiographic waveforms on the same time axis, the process of adding the marks 301 and 302, and the process of providing the mask sections 401 and 402 as described above are performed by the display control unit 107. ..

Incidentally, in the present embodiment, when connecting the two electrocardiographic waveforms, the ID identification unit 112 identifies and displays the patient ID set in the bedside monitor 100 and the patient ID set in the transport monitor 20. The control unit 107 is adapted to connect the electrocardiographic waveforms of the monitors identified as having the same patient ID by the ID identification unit 112. This makes it possible to prevent the inconvenience of connecting the electrocardiographic waveforms of the bedside monitor 100 even if the transport monitor 20 of a patient different from the previous patient is connected to the bedside monitor 100, for example.

In the above-described embodiment, the electrocardiographic waveform (electrocardiographic waveform in FIG. 6A) acquired with the transport monitor 20 connected and the transport monitor 20 with the transport monitor 20 not connected are used. The case where the triangular figure is displayed as the marks 301 and 302 indicating the positions connected to the acquired electrocardiographic waveforms (electrocardiographic waveforms in FIG. 6B) has been described, but the marks are not limited to this. For example, as shown in FIG. 7, it may be used as a mark to clearly indicate that it is a moving period. Further, as shown in FIG. 8, the marks 301 and 302 may be omitted by using the mask sections 401 and 402 as marks.

<4> Effect of the Embodiment As described above, according to the present embodiment, the bedside monitor 100 has an electrocardiographic waveform (radio wave of FIG. 6A) acquired in a state where the transport monitor 20 is connected. Shape) and the electrocardiographic waveform (electrocardiographic waveform in FIG. 6B) acquired by the transport monitor 20 when the transport monitor 20 is not connected are connected and displayed on the same time axis, and the transport is displayed. The electrocardiographic waveform acquired by the transport monitor 20 when the monitor is connected (electrocardiographic waveform in FIG. 6A) and the electrocardiographic waveform acquired by the transport monitor 20 when the transport monitor 20 is not connected (cardiac in FIG. 6B). Markers 301 and 302 indicating the position where the radio wave type) is connected are displayed. This makes it possible to realize a bedside monitor 100 capable of displaying a series of patient biometric information including the moving biometric information acquired by the transport monitor 20 in an easy-to-diagnose form.

The above-described embodiment is merely an example of the 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.

The display of the electrocardiographic waveform of the above-described embodiment is not limited to the bedside monitor, and may be performed by a central monitor. That is, the display method of the present invention is a display method used in a biological information monitoring system having a bedside monitor and a portable transport monitor that can be connected to the bedside monitor, and transports to the bedside monitor. The step of acquiring the first biological information (FIG. 6A) by the bedside monitor and the transport monitor with the monitor connected, and the second biological information by the transport monitor with the transport monitor not connected. The step of acquiring information (FIG. 6B), the first biological information and the second biological information are connected and displayed on the same time axis (FIG. 6C), and the first biological information and the first biological information are displayed. It may include a step of displaying a mark (FIG. 6C) indicating a position where the biological information of 2 is connected.

Further, in the above-described embodiment, the electrocardiographic waveform is taken as an example of the connected and displayed biological information, but the connected and displayed biological information is not limited to the electrocardiographic waveform, and may be, for example, a waveform of oxygen saturation or a blood pressure.

INDUSTRIAL APPLICABILITY The present invention is widely applicable to a display method used in a bedside monitor to which a transport monitor can be connected and a biological information monitoring system having a bedside monitor and a portable transport monitor that can be connected to the bedside monitor. Is.

Further, the transport monitor of the above-described embodiment can be replaced with a telemeter. That is, the transport monitor of the present invention means a mobile biometric information measuring device that can be connected to a bedside monitor.

In the present invention, the first biological information acquired when the transport monitor is connected to the connection portion and the second biological information acquired by the transport monitor when the transport monitor is not connected to the connection portion are present. It is widely effective when displaying information by connecting it. The second biometric information in the above-described embodiment was stored in the memory of the transport monitor during movement and transferred to the bedside monitor when the transport monitor was connected to the bedside monitor. .. However, the second biometric information may be wirelessly transmitted to the central monitor while the telemeter is moving, for example, if the transport monitor is a telemeter. The second biometric information wirelessly transmitted to the central monitor is sent to the bedside monitor and is spliced by the bedside monitor on the same time axis as the first biometric information by the method described above.

11, 11A to 11X, 12, 12A to 12X, 13A to 13X, 100 Bedside monitor 20 Transport monitor 107 Display control unit 109 Touch panel 110 Control unit 111 Connection detection unit 112 ID identification unit 301, 302 Marks 401, 402 Mask section

Claims (9)

The bedside monitor used in a biological information monitoring system having a bedside monitor and a movable biological information measuring device that can be connected to the bedside monitor.
The connection part to which the movable biometric information measuring device is connected and
The first biometric information acquired when the movable biometric information measuring device is connected to the connection portion and the movable biometric information measuring device are not connected to the connecting portion. A display unit that displays the second biometric information acquired by the biometric information measuring device, and
Equipped with
The display unit displays the first biological information and the second biological information by connecting them on the same time axis, and at the position where the first biological information and the second biological information are connected. Display a mark indicating
Bedside monitor. The mobile biometric information measuring device is a telemeter.
The bedside monitor according to claim 1. The second biometric information is wirelessly transmitted to the central monitor while the telemeter is moving, and is transmitted to the bedside monitor via the central monitor.
The bedside monitor according to claim 2. The display unit masks the first and / or second biometric information in the vicinity of the position where the first biometric information and the second biometric information are connected.
The bedside monitor according to any one of claims 1 to 3. Further, an ID identification unit for identifying the patient ID set in the bedside monitor and the patient ID set in the movable biometric information measuring device is provided.
The display unit connects the first biological information and the second biological information identified as having the same patient ID by the ID identification unit on the same time axis.
The bedside monitor according to any one of claims 1 to 4. A living body having a first biological information monitor and a second biological information monitor that is smaller and more mobile than the first biological information monitor and can be connected to the first biological information monitor. It ’s an information monitoring system.
The first biological information monitor is
The connection part to which the second biometric information monitor is connected and
The first biometric information acquired with the second biometric information monitor connected to the connection portion, and the second biometric information with the second biometric information measuring device not connected to the connection portion. A display unit that displays the second biometric information acquired by the biometric information measuring device, and
Equipped with
The display unit displays the first biological information and the second biological information by connecting them on the same time axis, and at the position where the first biological information and the second biological information are connected. Display a mark indicating
Biometric information monitoring system. A living body having a first biological information monitor and a second biological information monitor that is smaller and more mobile than the first biological information monitor and can be connected to the first biological information monitor. A display method used in information monitoring systems.
A first living body that acquires first biological information by the first biological information monitor and the second biological information monitor in a state where the second biological information monitor is connected to the first biological information monitor. Information acquisition step and
The second biometric information acquisition step of acquiring the second biometric information by the second biometric information monitor in a state where the second biometric information monitor is not connected,
The first biological information and the second biological information are connected and displayed on the same time axis, and a mark indicating the position where the first biological information and the second biological information are connected is displayed. Display steps and
Display method including. The first biometric information monitor is a bedside monitor and the second biometric information monitor is a telemeter.
The display method according to claim 7. Further including a step of identifying the patient ID set in the bedside monitor and the patient ID set in the telemeter.
In the display step, the first biometric information and the second biometric information of the same patient ID are connected on the same time axis.
The display method according to claim 8.

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