JP7444907B2 - Biological information monitor, biological information monitoring system and display method - Google Patents

Description

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

In medical settings such as hospitals, it is necessary to collect, analyze, and display biometric information (e.g., electrocardiogram, blood pressure, respiratory rate, pulse, etc.) of each patient at any time. Furthermore, since the patient will be transported to a hospital room, examination room, operating room, etc., it is necessary to collect the patient's biological information at the same time as the patient is transported. Small-sized medical portable monitor systems (see, for example, Patent Documents 1 and 2) are widely used.

As this type of system, there is a system in which a portable transport monitor can be connected to a stationary bedside monitor (specifically, it can be docked and detached). Note that this type of bedside monitor can also be called a host monitor as opposed to a transport monitor.

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

By using a system having such a transport monitor, biological information of a patient during transport can be easily obtained. In addition, by configuring the transport monitor to be docked to the bedside monitor, the transport monitor can be transferred without having to reconnect electrodes for acquiring biological information attached to the patient between the bedside monitor and the transport monitor. Measurement of biological information can be continued by simply connecting and disconnecting the port monitor to the bedside monitor.

Special Publication No. 8-504345 Special Publication No. 8-504531

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

Therefore, in the past, it was possible to view a series of biological information, including information during transportation, on a host server, but this was inconvenient because it could not be viewed on a bedside monitor placed at the site where the patient is actually treated. there were. Furthermore, insufficient consideration has been given to displaying a series of biological information acquired by multiple biological information monitors, including a bedside monitor and a transport monitor, in a format that is easy to diagnose.

The present invention has been made in consideration of the above points, and provides a bedside monitor and a bedside monitor that can display a series of patient's biological information in an easy-to-diagnose format, including the biological information acquired by the transport monitor during transportation. Provide a display method.

One embodiment of the bedside monitor of the present invention is
The bedside monitor used in a biological information monitoring system including a bedside monitor and a portable transport monitor connectable to the bedside monitor,
a connection part to which the transport monitor is connected;
first biometric information acquired when the transport monitor is connected to the connection unit; and second biological information acquired by the transport monitor when the transport monitor is not connected to the connection unit. a display section that displays biological information;
Equipped with
The display unit displays the first biological information and the second biological information connected on the same time axis, and displays the position where the first biological information and the second biological information are connected. Display a landmark indicating the

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 connectable to the bedside monitor,
a first biological information acquisition step of acquiring first biological information by the bedside monitor and the transport monitor in a state where the transport monitor is connected to the bedside monitor;
a second biological information acquisition step of acquiring second biological information by the transport monitor in a state where the transport monitor is not connected;
Displaying the first biological information and the second biological information connected on the same time axis, and displaying a mark indicating a position where the first biological information and the second biological information are connected. a display step;
including.

According to the present invention, a series of patient's biological information, including the biological information obtained by the transport monitor during transportation, can be displayed in a form that is easy to diagnose.

1B is a diagram showing how the bedside monitor and transport monitor are docked (connected) according to the embodiment; FIG. 1A is a diagram showing how the transport monitor is removed from the bedside monitor; FIG. 1B is a diagram showing how the transport monitor is docked with the patient Figure 1C shows how the port monitor is moved. Figure 1C is a diagram showing how the transport monitor is docked to the bedside monitor. A diagram showing a schematic configuration of an in-hospital system to which a bedside monitor and a transport monitor according to an embodiment are connected. Block diagram showing the configuration of a bedside monitor according to an 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 FIG. 6A is a diagram illustrating a method of displaying biological information performed by the bedside monitor of the embodiment, and FIG. 6A shows an electrocardiogram waveform acquired when the transport monitor is docked (connected) to the bedside monitor. Figure 6B is a diagram showing an electrocardiogram waveform acquired by the transport monitor when the transport monitor is removed from the bedside monitor, and Figure 6C is a diagram showing the electrocardiogram waveform acquired by the transport monitor when the transport monitor is re-docked (reconnected) to the bedside monitor. Diagram showing the electrocardiogram waveform displayed on the bedside monitor after Diagram showing a display example of another embodiment Diagram showing a display example of another embodiment

Embodiments of the present invention will be described below with reference to the drawings.

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

FIG. 1 is a diagram showing how the bedside monitors 11 and 12 and the transport monitor 20 are docked (connected). Although not shown, the transport monitor 20 is connected to a biological information detection section for acquiring biological information of the patient, such as an electrode for electrocardiogram measurement.

When a patient is transferred from a place where the bedside monitor 11 is placed to a place where the bedside monitor 12 is placed, a medical worker such as a doctor or nurse removes the transport monitor 20 from the bedside monitor 11. After moving the transport monitor with the patient (FIG. 1A) and moving the transport monitor with the patient (FIG. 1B), the transport monitor 20 is docked to the bedside monitor 12 (FIG. 1C). By doing so, the transport monitor 20 can acquire the patient's biological information even while the patient is being transported.

Here, the bottom 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 electrically connect to each other when docked. The port monitor 20 and the bedside monitors 11 and 12 are capable of transmitting and receiving information such as biological information and setting information to and from each other via this connector section.

When the bedside monitors 11 and 12 and the transport monitor 20 are compared with each other, the characteristics of each device are as follows.

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

Transport monitor:
- Designed to be carried, it is smaller and lighter than a bedside monitor.
・The number of biological information parameters that can be displayed is smaller than that of a bedside monitor.
・The number of external devices that can be connected is smaller than that of a bedside monitor.
-The display is smaller than a bedside monitor.
- Equipped with memory that can record patient's biometric information while in transit. This memory has a capacity to record, for example, 10 days' worth of biological information.

Note that the bedside monitor and the transport monitor do not necessarily have all of the above-mentioned characteristics, 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 transport monitor of this embodiment are connected. In the 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. Note that the "ward" described in this specification refers to a so-called "general ward" excluding special treatment rooms such as operating rooms and ICUs.

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

Further, the central monitors 31, 32, and 33 are connected to a server device 40. As a result, the biological information acquired by the bedside monitors 11A to 11X is aggregated to the central monitor 31 for display and recording, and the biological information acquired by the bedside monitors 12A to 12X is aggregated to the central monitor 32. Display and recording are performed, and the biological information acquired by the bedside monitors 13A to 13X is aggregated on the central monitor 33 and displayed and recorded. Furthermore, the biometric information acquired by the central monitors 31, 32, and 33 is collected and recorded in the server device 40. The server device 40 transmits the recorded biological information to the central monitors 31, 32, 33 or the bedside monitors in response to a request from the central monitors 31, 32, 33 or the bedside monitors 11A to 11X, 12A to 12X, or 13A to 13X, for example. 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 of the bedside monitors 11A to 11X, 12A to 12X, and 13A to 13X, and moves with the patient to the bedside monitors 11A to 11X to which the patient is transferred. , 12A to 12X, and 13A to 13X.

Although FIG. 2 shows the in-hospital system 10, the transport monitor 20 can also 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 of this embodiment. The bedside monitor 100 is used as the bedside monitors 11A to 11X, 12A to 12X, and 13A to 13X in FIGS. 1 and 2.

Bedside monitor 100 has connector parts 101, 102, and 103.

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

A transport monitor 20 is connected to the connector section 102. A central monitor 30 is connected to the connector section 103.

The measurement processing unit 104 executes a predetermined measurement process to detect the biological information detection unit (electrocardiogram electrode 201, blood pressure measurement cuff 202, body temperature sensor 203, SpO ₂ sensor 204, and heart rate) connected to the connector unit 101. The patient's biological information is measured using the output sensor 205). Note that since conventionally known methods for measuring various biological information using the biological information detection section can be applied, a detailed explanation 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 biological 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 then stored in the connector unit when connected to the bedside monitor 100. The information is transferred and stored in the storage unit 105 of the bedside monitor 100 via the transmission/reception processing unit 102 and the transmission/reception processing unit 106 .

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

The control section 110 controls the measurement processing section 104 , the transmission/reception processing section 106 , the display control section 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. Furthermore, the touch panel 109 not only has a display function of displaying biological information, but also has a function as an operation input unit that receives input operations from an operator. Specifically, information indicating the 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, changes the mode of the bedside monitor 100, and changes 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 is configured to emit light in, for example, red when the control unit 110 determines that an abnormality has occurred in the biological information.

The bedside monitor 100 also includes a connection detection section 111 and an ID identification section 112. The connection detection unit 111 detects whether 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 uses this patient ID as the patient ID of the previously connected transport monitor 20. 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 screen shown in FIG. 4 is displayed on the touch panel 109. When the user (medical worker) touches the "monitor interrupt" button, the bedside monitor 100 enters a monitoring interrupt mode and interrupts monitoring of biological information. On the other hand, when the user touches the "leave bed" button, the bedside monitor 100 performs the bedside exit process.

When the transport monitor 20 is connected to the bedside monitor 100, this is detected by the connection detection unit 111, and the patient selection screen shown in FIG. 5 is displayed on the touch panel 109. On this screen, the user selects a mode that uses patient information linked to the patient ID set in the transport monitor 20, and a mode that uses patient information linked to the patient ID set in this device (bedside monitor 100). You can select either a mode that uses the information or a mode that starts monitoring by inputting new patient information.

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

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

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

FIG. 6C shows an electrocardiogram waveform displayed on the bedside monitor 100 after the transport monitor 20 is re-docked (reconnected) to the bedside monitor 100. As can be seen from FIG. 6C, the bedside monitor 100 displays an electrocardiogram waveform acquired with the transport monitor 20 connected (the electrocardiogram waveform in FIG. 6A) and a state where the transport monitor 20 is not connected. The electrocardiographic waveform acquired by the transport monitor 20 (the electrocardiographic waveform in FIG. 6B) is connected and displayed on the same time axis.

In addition, the bedside monitor 100 can display an electrocardiogram waveform obtained when the transport monitor 20 is connected (the electrocardiogram waveform in FIG. 6A) and an electrocardiogram waveform obtained when the transport monitor 20 is not connected. Marks 301 and 302 indicating the positions where the electrocardiographic waveform acquired by (the electrocardiographic waveform in FIG. 6B) is connected are displayed. The position marked with a mark 301 corresponds to time t1 when the transport monitor 20 is removed from the bedside monitor 100, and the position marked with a mark 302 is the position when the transport monitor 20 is reattached to the bedside monitor 100. This is the position corresponding to time t2 when the connection was made (reconnected). By displaying the marks 301 and 302, medical personnel can easily recognize from where to where the electrocardiographic waveform is acquired by the transport monitor 20 during patient transportation. In particular, in this embodiment, triangular shapes are used as the landmarks 301 and 302, and their vertices are directed toward the waveform section acquired by the transport monitor 20 during patient transportation, so that they can be easily seen at a glance. Waveform sections acquired while moving can be recognized.

Furthermore, as can be seen from FIG. 6C, in this embodiment, instead of simply connecting the electrocardiogram waveform in FIG. 6A and the electrocardiogram waveform in FIG. 6B, mask sections 401 and 402 are provided at the joint, and Connect the radio waveform and the electrocardiogram waveform in FIG. 6B. By doing this, there was a difference between the mechanical time of the bedside monitor 100 and the mechanical time of the transport monitor 20, and the two electrocardiogram waveforms that were to be connected were shifted relatively in the time direction. However, in an electrocardiographic waveform that connects two electrocardiographic waveforms, the inconvenience caused by the difference in mechanical time can be suppressed.

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

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

Incidentally, in this embodiment, when connecting two electrocardiographic waveforms, the ID identification unit 112 identifies and displays the patient ID set on the bedside monitor 100 and the patient ID set on the transport monitor 20. The control unit 107 connects the electrocardiographic waveforms of monitors identified by the ID identification unit 112 as having the same patient ID. Thereby, for example, even if the transport monitor 20 of a patient different from the previous patient is connected to the bedside monitor 100, it is possible to prevent the inconvenience that the electrocardiographic waveforms of these patients are connected.

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

<4> Effects of the Embodiment As explained above, according to the present embodiment, the bedside monitor 100 can perform an electrocardiogram waveform acquired with the transport monitor 20 connected (the electrocardiogram waveform in FIG. 6A). The electrocardiogram waveform acquired by the transport monitor 20 when the transport monitor 20 is not connected (the electrocardiogram waveform in FIG. 6B) are connected and displayed on the same time axis. An electrocardiogram waveform obtained with the monitor connected (the electrocardiogram waveform in FIG. 6A) and an electrocardiogram waveform obtained by the transport monitor 20 without the transport monitor 20 connected (the electrocardiogram waveform in FIG. 6B). Markers 301 and 302 indicating the position where the radio waveform) are connected are displayed. Thereby, it is possible to realize the bedside monitor 100 that can display a series of patient's biological information, including the biological information acquired by the transport monitor 20 during movement, in a form that is easy to diagnose.

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

The display of the electrocardiogram waveform in the embodiment described above is not limited to the bedside monitor, but may be performed on the central monitor. In other words, 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 connectable to the bedside monitor. acquiring first biological information (FIG. 6A) by the bedside monitor and transport monitor with the monitor connected; and acquiring the second biological information by the transport monitor with the transport monitor not connected. 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 second biological information are displayed on the same time axis. The step of displaying a mark (FIG. 6C) indicating the position where the biometric information of No. 2 is connected may be included.

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

INDUSTRIAL APPLICATION This invention is widely applicable to the display method used for the biological information monitoring system which has a bedside monitor to which a transport monitor can be connected, and a bedside monitor and a portable transport monitor connectable to the bedside monitor. It is.

Further, the transport monitor in the above-described embodiment can also be implemented by being read as a telemeter. In other words, the transport monitor of the present invention means a movable biological information measuring device that can be connected to a bedside monitor.

The present invention provides first biological information acquired when the transport monitor is connected to the connection part, and second biological information acquired by the transport monitor when the transport monitor is not connected to the connection part. It is widely effective when connecting and displaying information. The second biological information in the embodiment described above is stored in the memory of the transport monitor during movement, and is transferred to the bedside monitor when the transport monitor is connected to the bedside monitor. . However, if the transport monitor is a telemeter, the second biological information may be wirelessly transmitted to the central monitor while the telemeter is moving. The second biological information wirelessly transmitted to the central monitor is sent to the bedside monitor, and is combined with the first biological information on the same time axis by the bedside monitor using the method described above.

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

Claims (13)

It has a connection part to which a biological information measuring device is connected,
First biological information acquired with the biological information measuring device connected to the connecting portion, and first biological information acquired by the biological information measuring device with the biological information measuring device not connected to the connecting portion. displaying the second biometric information in a connected manner with a mask section provided on the same time axis, and displaying a mark indicating the position where the first biometric information and the second biometric information are connected;
Biological information monitor. a connection part to which a biological information measurement device is connected;
First biological information acquired with the biological information measuring device connected to the connecting portion, and first biological information acquired by the biological information measuring device with the biological information measuring device not connected to the connecting portion. a display unit that displays second biological information;
Equipped with
The display unit displays the first biological information and the second biological information connected to each other with a mask section provided on the same time axis, and displays the first biological information and the second biological information connected to each other with a mask section provided on the same time axis. Displays a landmark indicating the location where biometric information is connected.
Biological information monitor. The biological information measuring device is a telemeter,
The biological information monitor according to claim 1 or 2. The second biometric information is received by the biometric information monitor from a central monitor.
The biological information monitor according to claim 3. The mask section is a section in which the first biometric information and/or the second biometric information near the position where the first biometric information and the second biometric information are connected are masked .
The biological information monitor according to any one of claims 1 to 4. The first living body is identified as having the same patient ID by an ID identification unit that identifies whether or not the patient ID set in the living body information monitor and the patient ID set in the living body information measuring device are the same. the information and the second biological information are connected on the same time axis;
The biological information monitor according to any one of claims 1 to 5. A biological information measuring device,
a biological information monitor having a connection part to which the biological information measuring device is connected;
A biological information monitoring system having
First biological information acquired with the biological information measuring device connected to the connecting portion, and first biological information acquired by the biological information measuring device with the biological information measuring device not connected to the connecting portion. a display unit that displays second biological information;
Equipped with
The display section connects and displays the first biological information and the second biological information by providing a mask section on the same time axis, and displays the first biological information and the second biological information. Display a mark indicating the location where the
Biological information monitoring system. A biological information measuring device,
a biological information monitor having a connection part to which the biological information measuring device is connected;
A display method used in a biological information monitoring system having
a first biological information acquisition step of acquiring first biological information with the biological information measuring device connected to the biological information monitor;
a second biological information acquisition step of acquiring second biological information by the biological information measuring device in a state where the biological information measuring device is not connected;
The first biological information and the second biological information are connected and displayed with a mask section provided on the same time axis, and the position where the first biological information and the second biological information are connected is displayed. a display step for displaying a landmark indicating the
Display method including. The biological information monitor is a bedside monitor, and the biological information measuring device is a telemeter.
The display method according to claim 8. further comprising the step of identifying whether the patient ID set on the bedside monitor and the patient ID set on the telemeter are the same;
In the displaying step, the first biological information and the second biological information, which were identified as the same patient ID in the identifying step, are connected and displayed on the same time axis.
The display method according to claim 9. The ID identification unit identifies whether a patient ID set in the connected biological information measuring device is the same as a patient ID of a previously connected biological information measuring device.
The biological information monitor according to claim 6. displaying "Monitor Interrupt" and "Leaving Bed" when the biological information measuring device is removed, and interrupting the biological information monitoring when "Monitor Interrupt" is selected;
The biological information monitor according to claim 1 or 2. When the biological information measuring device is connected, a mode in which patient information linked to the patient ID set in the biological information measuring device is used; You can select either a mode that uses patient information or a mode that starts monitoring by entering new patient information.
The biological information monitor according to claim 1 or 2.

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