JP6768371B2 - Biometric information display device, biometric information display method, program and storage medium - Google Patents

Description

The present invention relates to a biological information display device and a biological information display method. The present invention also relates to a program for executing the method and a computer-readable storage medium in which the program is stored.

The vital data acquired from the sensor includes noise data caused by changes in the patient's behavior or disturbance during measurement of the vital data, and it is difficult to identify the noise data from the acquired vital data.

In Patent Document 1, the reliability of the QT interval acquired from the electrocardiogram waveform is distinguished with high accuracy, and then the low-reliability QT interval and the highly reliable QT interval are distinguished by the type of plot point. A biometric information display device that displays a trend graph of QT intervals on a display screen is disclosed. As described above, Patent Document 1 discloses a technique for visualizing noise data included in vital data on a trend graph.

JP-A-2014-94239

By the way, conventionally, the medical staff has selected the worst value of vital data (for example, the highest value and the lowest value of average blood pressure) only from the list of vital data. For example, the worst value of vital data is used for a score that predicts patient mortality (eg, APACHE2 SCORE, etc.). However, since vital data contains noise data, it is difficult to determine the worst value of vital data by discriminating noise data only from the list of vital data displayed on the display screen, and it takes a lot of time. Was required. In particular, it is difficult to determine whether or not the data is noise data only from the list of vital data, and it takes a lot of time. Thus, determining the worst value of vital data has placed a heavy burden on healthcare professionals.

An object of the present invention is to provide a biometric information display device and a biometric information display method capable of easily determining the worst value of vital data including noise data.
A further object of the present invention is to provide a program for causing a computer to execute the biometric information display method and a computer-readable storage medium in which the program is stored.

The biological information display device according to one aspect of the present invention is
With the processor
It has a memory for storing computer-readable instructions.
When the computer-readable instruction is executed by the processor, the biometric information display device
Acquires vital data having a plurality of vital values and a plurality of measurement times at which the plurality of vital values are measured, and each of the plurality of vital values is associated with a corresponding one of the plurality of measurement times. ,
Generate a list of the acquired vital data and a trend graph,
Display the generated list and trend graph on the display screen of the display unit, and display them.
Identify the noise data contained in the vital data and
Based on the vital data excluding the specified noise data, a data upper limit line that defines the upper limit value of the vital data and a data lower limit line that defines the lower limit value of the vital data are generated.
The generated data upper limit line and data lower limit line are displayed on the trend graph, and the data is displayed.
The worst value of the vital data from the vital data included in the range between the upper limit value of the vital data defined by the data upper limit line and the lower limit value of the vital data defined by the data lower limit line. Decide,
The worst value of the determined vital data is specified on the display screen.

According to the present invention, it is possible to provide a biometric information display device and a biometric information display method capable of easily determining the worst value of vital data including noise data. Further, according to the present invention, it is possible to provide a program for causing a computer to execute the biometric information display method and a computer-readable storage medium in which the program is stored.

It is a hardware block diagram which shows the biological information display device which concerns on embodiment of this invention (hereinafter, simply referred to as this embodiment). It is a figure which shows an example of vital data. It is a flowchart for demonstrating the biological information display method which concerns on this embodiment. It is a figure (the 1) which shows the vital data display window. It is a figure (the 2) which shows the vital data display window. It is a figure which shows an example of the vital data setting window. It is a flowchart of the noise data identification process shown in FIG. It is a flowchart of noise data identification processing based on the increase / decrease rate shown in FIG. It is a flowchart of noise data identification processing based on the average blood pressure value before and after shown in FIG. 7. It is a flowchart of noise data identification processing based on the average blood pressure value permissible range shown in FIG.

Hereinafter, this embodiment will be described with reference to the drawings. For convenience of explanation, the description of the element having the same reference number as the element already described in the description of the present embodiment will be omitted.

FIG. 1 shows a hardware configuration diagram of the biological information display device 1 according to the present embodiment. As shown in FIG. 1, the biological information display device 1 (hereinafter, simply referred to as a display device 1) includes a control unit 2, a storage unit 3, a network interface 4, a display unit 5, and an input operation unit 6. Be prepared. These are communicably connected to each other via the bus 8.

The display device 1 may be a dedicated device (biological information monitor, etc.) for displaying a trend graph or list of vital data such as average blood pressure, and may be, for example, a personal computer, a workstation, a smartphone, a tablet, or an operator. It may be a wearable device (for example, Apple Watch, smart glasses, etc.) worn on the body (for example, arms, head, etc.) of (medical worker).

The control unit 2 includes a memory and a processor. The memory is configured to store computer-readable instructions (programs). For example, a ROM (Read Only Memory) in which various programs and the like are stored, and a plurality of work areas in which various programs executed by the processor are stored. It is composed of a RAM (Random Access Memory) or the like having the above. The processor is, for example, a CPU (Central Processing Unit), an MPU (Micro Processing Unit), and / or a GPU (Graphics Processing Unit), and expands a program specified from various programs embedded in the ROM onto the RAM and develops the RAM. It is configured to execute various processes in collaboration with.

In particular, the control unit 2 may control various operations of the display device 1 by developing the biometric information display program described later on the RAM by the processor and executing the program in cooperation with the RAM. The details of the control unit 2 and the biological information display program will be described later.

The storage unit 3 is, for example, a storage device (storage) such as an HDD (Hard Disk Drive), an SSD (Solid State Drive), or a USB flash memory, and is configured to store programs and various data. A biological information display program may be incorporated in the storage unit 3. In addition, vital data such as the average blood pressure data shown in FIG. 2 may be stored in the storage unit 3. The average blood pressure data is acquired by the blood pressure sensor. The acquired average blood pressure data is stored in the storage unit 3 via a storage medium such as a communication network or a USB memory. As shown in FIG. 2, the average blood pressure includes a plurality of average blood pressure values ART (N) (where N is an integer of 1 or more) and a plurality of measurement times when a plurality of average blood pressure values ART (N) are measured. and a T _N, are associated with one each of the plurality of mean blood pressure ART (N) corresponding plurality of measurement time T _N. For example, when the average blood pressure value of a predetermined patient is obtained every minute, the total number of samples of the average blood pressure value measured during one day (24 hours) is 60 minutes × 24 hours = 1440. In this case, N = 1-1440. Further, the measurement time _TN of the average blood pressure value may be the start time when the blood pressure measurement is started or the end time when the blood pressure measurement is finished. Alternatively, the measurement time may be a time between the start time and the end time. In the average blood pressure shown in FIG. 2, the average blood pressure values ART (N) are arranged in order from the oldest measurement time _TN, but the average blood pressure value ART (N) is in order from the smaller or larger average blood pressure value. ) May be lined up.

Further, in addition to the average blood pressure data, vital data such as systolic blood pressure data, body temperature data, heart rate data and respiratory rate data may be stored in the storage unit 3. These vital data also have a plurality of vital values and a plurality of measurement times at which the plurality of vital values are measured, and each of the plurality of vital values is associated with a corresponding one of the plurality of measurement times. ..

The network interface 4 is configured to connect the display device 1 to a communication network. Specifically, the network interface 4 includes various wired connection terminals for communicating with an external device such as a server via a communication network, and various processing circuits for wireless connection, and communicates via the communication network. It is configured to comply with the communication standards for Here, the communication network is a LAN (Local Area Network), a WAN (Wide Area Network), the Internet, or the like. For example, vital data such as a biological information display program and average blood pressure may be acquired from a computer arranged on a communication network via a network interface 4.

The display unit 5 may be a display device such as a liquid crystal display or an organic EL display, or may be a display device such as a transmissive type or non-transmissive type head-mounted display worn on the operator's head. For example, as shown in FIGS. 4 and 5, the vital data display window 20 displaying the list of average blood pressure data and the trend graph is displayed on the display screen of the display unit 5.

The input operation unit 6 is configured to accept an input operation of an operator who operates the display device 1 and to generate an instruction signal corresponding to the input operation. The input operation unit 6 is, for example, a touch panel arranged on the display unit 5, an operation button attached to a housing, a mouse, a keyboard, or the like. The instruction signal generated by the input operation unit 6 is transmitted to the control unit 2 via the bus 8, and the control unit 2 executes a predetermined operation in response to the instruction signal.

Next, the biological information display method according to the present embodiment will be described with reference to FIGS. 3 to 5. FIG. 3 is a flowchart for explaining the biological information display method according to the present embodiment. 4 and 5 are views showing a vital data display window 20 displayed on the display screen of the display unit 5. In the vital data display window 20, a list 24 of average blood pressure data (highest value selection list 22 and lowest value selection list 23) and a trend graph 21 are displayed.

As shown in FIG. 3, when the display device 1 is first activated, in step S1, the control unit 2 acquires the average blood pressure data from the storage unit 3. The control unit 2 may acquire the average blood pressure data from a server arranged on the communication network via the network interface 4. Next, the control unit 2 generates the acquired average blood pressure data list 24 and the trend graph 21 (step S2), and then displays the generated list 24 and the trend graph 21 on the display screen of the display unit 5. Display (step S3). In other words, the control unit 2 displays the vital data display window 20 including the list 24 and the trend graph 21 on the display screen of the display unit 5. As shown in FIG. 4, the list 24 includes a maximum value selection list 22 for selecting the highest average blood pressure value and a minimum value selection list 23 for selecting the lowest average blood pressure value. In the maximum value selection list 22, the average blood pressure value is displayed in order from the one with the largest average blood pressure value so that the operator can relatively easily select the maximum value of the average blood pressure value. On the other hand, in the minimum value selection list 23, the average blood pressure value is displayed in order from the smallest average blood pressure value so that the operator can relatively easily select the minimum average blood pressure value. The trend graph 21 is a graph showing the relationship between the average blood pressure value and the measurement time thereof. The horizontal axis of the trend graph is the measurement time, while the vertical axis of the trend graph is the average blood pressure value.

Next, in step S4, the control unit 2 identifies the noise data included in the average blood pressure data. Generally, the average blood pressure data acquired from the blood pressure sensor includes noise data caused by changes in the patient's behavior, disturbance, etc. during the measurement of the average blood pressure data. In this step, the control unit 2 determines whether or not each average blood pressure value is noise data. This step will be described later.

Next, the control unit 2 generates a data upper limit line 25 and a data lower limit line 26 based on the average blood pressure data excluding the specified noise data (step S5), and is generated as shown in FIG. The data upper limit line 25 and the data lower limit line 26 are displayed on the trend graph 21 (step S6). Here, the data upper limit line 25 defines the upper limit value of the average blood pressure value, while the data lower limit line 26 defines the lower limit value of the average blood pressure value.

Next, in step S7, the control unit 2 is included in the range between the upper limit value of the average blood pressure value defined by the data upper limit line 25 and the lower limit value of the average blood pressure value defined by the data lower limit line 26. The maximum and minimum average blood pressure values are determined from multiple average blood pressure values. Here, the maximum value and the minimum value of the average blood pressure value are defined as the worst values of the average blood pressure data. After that, the control unit 2 displays the maximum value specifying mark 27 for specifying the maximum value of the average blood pressure value on the trend graph 21, and also displays the minimum value specifying mark 28 for specifying the minimum value of the average blood pressure value. It is displayed on the trend graph 21. Further, the control unit 2 selects one of the plurality of radio buttons displayed on the maximum value selection list 22 in order to specify the maximum value of the average blood pressure value on the maximum value selection list 22, and the selected radio. Turn on the button. Further, the control unit 2 selects one of the plurality of radio buttons displayed in the minimum value selection list 23 in order to specify the minimum value of the average blood pressure value on the minimum value selection list 23, and selects the radio. Turn on the button. As shown in FIG. 4, 87 is selected as the maximum value of the average blood pressure value in the maximum value selection list 22. On the other hand, in the minimum value selection list 23, 75 is selected as the minimum value of the average blood pressure value.

In this way, since the minimum and maximum values of the average blood pressure data are specified on the trend graph 21 and the list 24, the operator can clearly see the minimum and maximum values of the average blood pressure data at a glance. Further, the operator can intuitively determine whether or not the minimum and maximum values are appropriate by looking at the minimum and maximum values of the average blood pressure data displayed on the trend graph 21.

Further, the control unit 2 specifies the average blood pressure value specified as noise data on the maximum value selection list 22 and the minimum value selection list 23. For example, the average blood pressure value specified as noise data may be displayed in a color different from the normal data on the maximum value selection list 22 and the minimum value selection list 23. As shown in FIG. 4, in the maximum value selection list 22, each of the average blood pressure values 178 and 201 is displayed in a color different from the other normal data so as to be identified as noise data. In the minimum value selection list 23, the average blood pressure values −5, 5, 33, 34, and 35 are displayed in a different color from the other normal data so that each of them is identified as noise data. On the other hand, the operator can also visually recognize the average blood pressure value specified as noise data by looking at the data upper limit line 25 and the data lower limit line 26. That is, from the trend graph 21, the operator can visually recognize the average blood pressure value larger than the data upper limit line 25 as noise data and the average blood pressure value smaller than the data lower limit line 26 as noise data. it can.

From the above, after the display device 1 is started, the control unit 2 executes various operations specified in steps S1 to S8. Next, when there is an input operation for the data upper limit line 25 and / or the data lower limit line 26 displayed on the trend graph 21 (YES in step S9), the control unit 2 performs an input operation from the operator. Correspondingly, the moved data upper limit line 25 and / or the data lower limit line 26 is redisplayed on the trend graph 21. In this way, the control unit 2 moves the data upper limit line 25 and / or the data lower limit line 26 according to the input operation from the operator. In FIG. 5, the data upper limit line 25 and the data lower limit line 26 after the movement are shown.

Specifically, when the operator performs a predetermined operation on the data upper limit line 25 through the input operation unit 6 in order to move the data upper limit line 25, the input operation unit 6 performs a predetermined operation from the operator. An operation signal corresponding to the above is generated, and the operation signal is transmitted to the control unit 2. The control unit 2 updates the data upper limit line 25 according to the transmitted operation signal, and then displays the updated data upper limit line 25 on the trend graph 21. For example, when the input operation unit 6 is a mouse, the operator can move the data upper limit line 25 to a desired position by a drag-and-drop operation with the cursor placed on the data upper limit line 25. Further, when the input operation unit 6 is a touch panel, the operator can move the data upper limit line 25 to a desired position by a drag-and-drop operation with the operator's finger overlapped with the data upper limit line 25. .. In this way, the data upper limit line 25 can be moved to a desired position by a relatively simple operation such as a drag-and-drop operation. The data lower limit line 26 can also be moved by the same method as the data upper limit line 25.

Further, the operator can move the data upper limit line 25 to a desired position by clicking or touching the upper limit line moving command button 32 for moving the data upper limit line 25. Similarly, the operator can move the data lower limit line 26 to a desired position by clicking or touching the lower limit line movement command button 33 for moving the data lower limit line 26.

As shown in FIG. 5, after the data upper limit line 25 and the data lower limit line 26 are moved through the input operation by the operator, the control unit 2 sets the upper limit value of the average blood pressure value defined by the moved data upper limit line 25 and the upper limit value of the average blood pressure value. The maximum and minimum values of the average blood pressure value are determined from a plurality of average blood pressure values included in the range between the lower limit value of the average blood pressure value defined by the moved data lower limit line 26 (step S7). .. After that, the control unit 2 displays the maximum value specifying mark 27 and the minimum value specifying mark 28 on the trend graph 21. Further, the control unit 2 turns on one of the plurality of radio buttons displayed in the highest value selection list 22 and turns on one of the plurality of radio buttons displayed in the lowest value selection list 23. (Step S8). As shown in FIG. 5, in the maximum value selection list 22, 178 is selected as the maximum value of the average blood pressure value, while in the minimum value selection list 23, 5 is selected as the minimum value of the average blood pressure value. Further, in the maximum value selection list 22, the average blood pressure value 201 is specified as noise data, while in the minimum value selection list 23, the average blood pressure value −5 is specified as noise data.

In this way, the control unit 2 moves the data upper limit line 25 and the data lower limit line 26 displayed on the trend graph 21 according to the input operation from the operator. For example, the operator can fine-tune the positions of the data upper bound line 25 and the data lower bound line 26 to fine-tune the lower and highest values of the more optimal average blood pressure data (in other words, the more reliable minimum and highest values). Value) can be determined. In particular, when the operator is not satisfied with the maximum value 87 and the minimum value 75 of the average blood pressure value shown in FIG. 4, the data upper limit line 25 and the data lower limit line 26 are moved by a drag-and-drop operation. As shown in 5, the maximum value 178 and the minimum value 5 of the average blood pressure value can be obtained.

Further, when there is no input operation for the data upper limit line 25 and / or the data lower limit line 26 displayed on the trend graph 21 (NO in step S9), the control unit 2 touches the automatic adjustment button 29 by the operator. Alternatively, it is determined whether or not the click operation has been performed (step S10). When the automatic adjustment button 29 is operated (YES in step S10), the control unit 2 executes each operation specified in steps S4 to S8. For example, when the automatic adjustment button 29 is operated from the state shown in FIG. 5, the noise data included in the average blood pressure data is specified by the control unit 2, and the data upper limit line 25 and the data lower limit line 26 are the trend graph 21. Displayed above. That is, the control unit 2 moves the data upper limit line 25 and the data lower limit line 26 so that the data upper limit line 25 and the data lower limit line 26 are in the state shown in FIG.

On the other hand, when the automatic adjustment button 29 is not operated (NO in step S10), the control unit 2 determines whether or not to end the operation of the display device 1 (step S11). For example, when the operator continues the input operation on the display screen (YES in step S11), the control unit 2 ends the operation of the display device 1. On the other hand, if the operation of the display device 1 is not completed, the process returns to step S9.

According to the present embodiment, the noise data included in the average blood pressure data is specified, and the data upper limit line 25 and the data lower limit line 26 are generated and on the trend graph 21 based on the average blood pressure data excluding the specified noise data. Is displayed in. Then, from a plurality of average blood pressure values included in the range between the upper limit value of the average blood pressure value defined by the data upper limit line 25 and the lower limit value of the average blood pressure value defined by the data lower limit line 26, the average blood pressure is obtained. The minimum and maximum values of the values are determined, and the determined minimum and maximum values are specified on the display screen.

As described above, it is possible to provide the display device 1 capable of relatively easily determining the minimum value and the maximum value of the average blood pressure data including the noise data. In particular, the operator can visually and intuitively determine the minimum and maximum values of the average blood pressure data by using the display device 1.

Further, according to the present embodiment, the noise data included in the average blood pressure data is specified by clicking or touching the automatic adjustment button 29. Therefore, the operator can display the data upper limit line 25 and the data lower limit line 26 on the trend graph 21 at an appropriate timing based on the average blood pressure data excluding the specified noise data (FIG. 4). reference). Therefore, the operability of the display device 1 can be improved.

Next, the noise data identification process S4 shown in FIG. 3 will be described with reference to FIGS. 7 to 10. FIG. 7 is a flowchart of the noise data identification process S4. FIG. 8 is a flowchart of the noise data specifying process S41 based on the increase / decrease rate shown in FIG. 7. FIG. 9 is a flowchart of the noise data identification process S42 based on the average blood pressure values before and after shown in FIG. 7. FIG. 10 is a flowchart of the noise data identification process S43 based on the average blood pressure value allowable range shown in FIG.

As shown in FIG. 7, first, the control unit 2 executes the noise data identification process based on the increase / decrease rate (step S41). The noise data identification process (step S41) based on the increase / decrease rate will be described with reference to FIG. As shown in FIG. 8, in step S410, the control unit 2 sets the sequence number N of the average blood pressure data to 1. Here, as shown in FIG. 2, the average blood pressure data includes a plurality of mean blood pressure ART (N) and a plurality of measurement time T _N, the average in order from the measurement time T _N it is old blood pressure ART ( N) are arranged. That is, as the SEQ ID NO: N increases, the measurement time of the average blood pressure value becomes newer, while as the SEQ ID NO: N decreases, the measurement time of the average blood pressure value becomes older. Further, for convenience of explanation, the average blood pressure data shall be acquired under the following conditions. Therefore, the total number of samples of the average blood pressure value is 2 hours and 15 minutes (= 135 minutes), and N = 1 to 135 (N _LAST = 135).

-The average blood pressure value of a predetermined patient is acquired every minute (measurement time interval is 1 minute).
-The average blood pressure value of a predetermined patient is acquired between 17:00 and 19:15.

Since the subsequent steps S411 to S417 are repeatedly executed from N = 1 to 135 (= N _LAST ), these steps will be described without specifying the sequence number N.

In step S411, the control unit 2 calculates the first increase / decrease rate ΔART1 (N) of the average blood pressure value ART (N). Specifically, the control unit 2 has an average blood pressure based on the average blood pressure value ART (N) and the average blood pressure value ART (N-1) acquired immediately before the average blood pressure value ART (N) is acquired. The first increase / decrease rate ΔART1 (N) of the value ART (N) is calculated. More specifically, the first rate of increase / decrease ΔART1 (N) is calculated based on the following equation (1). Note that in the case of N = 1, ART (0) is not defined, so the first increase / decrease rate ΔART1 (1) is not calculated.

ΔART1 (N) = ART (N) / ART (N-1) × 100% ... (1)

Next, in step S412, the control unit 2 calculates the second increase / decrease rate ΔART2 (N) of the average blood pressure value ART (N). Specifically, the control unit 2 receives the average blood pressure value ART (N) and the average blood pressure value ART (N + 1) immediately after the average blood pressure value ART (N) is acquired. The second increase / decrease rate ΔART2 (N) of (N) is calculated. More specifically, the second rate of increase / decrease ΔART2 (N) is calculated based on the following equation (2). Note that in the case of N = 135, ART (136) is not defined, so the second increase / decrease rate ΔART2 (135) is not calculated.

ΔART2 (N) = ART (N) / ART (N + 1) × 100% ... (2)

Next, the control unit 2 determines whether or not at least one of the first increase / decrease rate ΔART1 (N) and the second increase / decrease rate ΔART2 (N) is out of the increase / decrease rate allowable range (step S413). For example, the control unit 2 determines whether or not at least one of the first increase / decrease rate ΔART1 (N) and the second increase / decrease rate ΔART2 (N) is the increase / decrease rate X% or more. In this case, the permissible range of increase / decrease rate is larger than (100-X)% and smaller than (100 + X)%. That is, the control unit 2 determines whether the first increase / decrease rate ΔART1 (N) is (100-X)% <ΔART1 (N) <(100 + X)%, and the second increase / decrease rate ΔART2 (N) is It is determined whether (100-X)% <ΔART2 (N) <(100 + X)%.

For example, when X = 16, the control unit 2 determines whether at least one of the first increase / decrease rate ΔART1 (N) and the second increase / decrease rate ΔART2 (N) has an increase / decrease rate of 16% or more. In this case, the permissible range of increase / decrease rate is a range larger than 84% and smaller than 116%. That is, the control unit 2 determines whether or not the first increase / decrease rate ΔART1 (N) is 84% <ΔART1 (N) <116%, and the second increase / decrease rate ΔART2 (N) is 84% <ΔART2 (N). ) <116% is determined.

Further, the control unit 2 may change the permissible range of increase / decrease rate according to an input operation from the operator. For example, when the operator clicks or touches the setting change button 30 (see FIG. 4) displayed on the vital data display window 20, the control unit 2 displays the vital data setting window 35 shown in FIG. It is displayed on the display screen of the part 5. Next, the operator changes the value of the increase / decrease rate (16% in FIG. 6) displayed in the vital data setting window 35 through a predetermined operation (click operation on the increase / decrease button or numerical input through the keyboard). The control unit 2 changes the permissible range of increase / decrease rate according to the operation signal corresponding to the predetermined operation from the operator. For example, when the increase / decrease rate displayed in the vital data setting window 35 is set to 20%, the control unit 2 sets the increase / decrease rate allowable range to a range larger than 80% and smaller than 120%.

Next, in step S413 shown in FIG. 8, when the control unit 2 determines that at least one of the first increase / decrease rate ΔART1 (N) and the second increase / decrease rate ΔART2 (N) is out of the increase / decrease rate allowable range ( YES in step S413), the average blood pressure value ART (N) is specified as noise data (step S414). On the other hand, when the control unit 2 determines that both the first increase / decrease rate ΔART1 (N) and the second increase / decrease rate ΔART2 (N) are within the increase / decrease rate allowable range (NO in step S413), the sequence number of the average blood pressure data. Determine if N is N _Last (= 135). When the control unit 2 determines that the SEQ ID NO: N of the average blood pressure data is not N _Last (NO in step S415), the SEQ ID NO: N is increased by one (Step S416), and the process returns to step S411. On the other hand, when the control unit 2 determines that the sequence number N of the average blood pressure data is N _Last (YES in step S415), the control unit 2 executes the noise data identification process S42 based on the average blood pressure values before and after shown in FIG. ..

表１：平均血圧値ＡＲＴ（Ｎ）と第１増減率ΔＡＲＴ１（Ｎ）と第２増減率ΔＡＲＴ２（Ｎ）との関係を示す一例 Table 1 below shows a specific example of the relationship between the average blood pressure value ART (N), the first increase / decrease rate ART1 (N), and the second increase / decrease rate ART2 (N). The decimal point is rounded off to the values of the first and second rate of increase / decrease.

Table 1: An example showing the relationship between the average blood pressure value ART (N), the first increase / decrease rate ΔART1 (N), and the second increase / decrease rate ΔART2 (N).

Next, the noise data identification process S42 based on the average blood pressure values before and after shown in FIG. 7 will be described with reference to FIG. As shown in FIG. 9, in step S420, the control unit 2 sets the sequence number N of the average blood pressure data to 1. Next, in step S421, the control unit 2 determines whether or not the average blood pressure value ART (N) is specified as noise data in the noise data identification process S41 (step S421). When the control unit 2 determines that the average blood pressure value ART (N) is specified as noise data in the noise data identification process S41 (YES in step S421), the process proceeds to step S424. On the other hand, when the control unit 2 determines that the average blood pressure value ART (N) is not specified as noise data in the noise data identification process S41 (NO in step S421), the control unit 2 performs the average blood pressure value ART (N) in the noise data identification process S41. It is determined whether both N-1) and the mean blood pressure value ART (N + 1) are identified as noise data (step S422). When the control unit 2 determines in the noise data identification process S41 that both the average blood pressure value ART (N-1) and the average blood pressure value ART (N + 1) are specified as noise data (YES in step S422), the control unit 2 determines the average blood pressure. The value ART (N) is specified as noise data (step S423). After that, the process proceeds to step S424.

In step S424, the control unit 2 determines whether or not the sequence number N of the average blood pressure data is N _Last (= 135). When the control unit 2 determines that the sequence number N of the average blood pressure data is not N _Last (NO in step S424), the sequence number N is increased by one (step S425), and the process returns to step S421. On the other hand, when the control unit 2 determines that the sequence number N of the average blood pressure data is N _Last (YES in step S424), the control unit 2 executes the noise data identification process S43 based on the average blood pressure value allowable range shown in FIG. ..

According to the present embodiment, in the noise data identification process S41, the first increase / decrease rate ΔART1 (N) and the second increase / decrease rate ART2 (N) of the average blood pressure value ART (N) are within the allowable increase / decrease rate. The average blood pressure value ART (N) is not specified as noise data. On the other hand, in this noise data identification process S42, immediately after the average blood pressure value ART (N-1) and the average blood pressure value ART (N) acquired immediately before the average blood pressure value ART (N) is acquired. When the acquired average blood pressure value ART (N + 1) is specified as noise data, the average blood pressure value ART (N) is specified as noise data. The noise data identification process S42 is not executed for the average blood pressure values ART (1) and ART (135).

Next, the noise data identification process S43 based on the average blood pressure value allowable range (an example of the vital value allowable range) shown in FIG. 7 will be described with reference to FIG. As shown in FIG. 10, in step S430, the control unit 2 sets the sequence number N of the average blood pressure data to 1. Next, in step S431, the control unit 2 determines whether or not the average blood pressure value ART (N) is specified as noise data in the noise data identification processes S41 and S42 (step S431). When the control unit 2 determines in the noise data identification processes S41 and S42 that the average blood pressure value ART (N) is specified as noise data (YES in step S431), the process proceeds to step S434. On the other hand, when the control unit 2 determines that the average blood pressure value ART (N) is not specified as noise data in the noise data identification processes S41 and S42 (NO in step S431), the average blood pressure value ART (N) is the average blood pressure. It is determined whether or not the value is within the permissible range (an example of the permissible vital value range) (step S432). For example, when the permissible range of the average blood pressure value is larger than 0 and smaller than 200, the control unit 2 determines whether or not the average blood pressure value ART (N) is 0 <ART (N) <200.

Further, the control unit 2 may change the average blood pressure value allowable range according to an input operation from the operator. For example, the operator performs a predetermined operation (click operation on the increase / decrease button or keyboard) for the automatic adjustment threshold value (upper limit threshold value: 200, lower limit threshold value: 0 in FIG. 6) displayed in the vital data setting window 35 shown in FIG. When the change is made through (numerical input through), the control unit 2 changes the average blood pressure value allowable range according to the operation signal corresponding to the predetermined operation from the operator. For example, when the upper limit threshold value displayed in the vital data setting window 35 is 180 and the lower limit threshold value is 30, the control unit 2 sets the average blood pressure value allowable range to a range larger than 30 and smaller than 180. Then, it is determined whether or not the average blood pressure value ART (N) is 30 <ART (N) <180.

Next, in step S432 shown in FIG. 10, when the control unit 2 determines that the average blood pressure value ART (N) is not within the allowable range of the average blood pressure value (NO in step S432), the average blood pressure value ART (N) Is specified as noise data (step S433). On the other hand, when the control unit 2 determines that the average blood pressure value ART (N) is within the permissible range of the average blood pressure value (YES in step S432), the sequence number N of the average blood pressure data is N _Last (= 135). Determine if it is. When the control unit 2 determines that the sequence number N of the average blood pressure data is not N _Last (NO in step S434), the sequence number N is increased by one (step S435), and the process returns to step S431. On the other hand, when the control unit 2 determines that the sequence number N of the average blood pressure data is N _Last (YES in step S434), the noise data identification process S4 ends.

As described above, the noise data identification process S4 of the present embodiment is based on the noise data identification process S41 based on the increase / decrease rate, the noise data identification process S42 based on the average blood pressure values before and after, and the average blood pressure value allowable range. It is composed of three processes of noise data identification process S43. The average blood pressure value ART (N), which has not been identified as noise data through these three processes, is identified as normal data. The control unit 2 generates a data upper limit line 25 and a data lower limit line 26 based on the average blood pressure value ART (N) specified as normal data.

The noise data identification process S4 may be composed of only the noise data identification process S41 based on the increase / decrease rate, or the noise data identification process S41 based on the increase / decrease rate and noise data based on the average blood pressure values before and after. It may be composed of the specific process S42. Further, the noise data identification process S4 may be composed of only the noise data identification process S43 based on the average blood pressure value allowable range. In this case, step S431 is omitted in the noise data identification process S43.

According to the present embodiment, in the noise data identification process S41 based on the increase / decrease rate, the first increase / decrease rate ΔART1 (N) and the second increase / decrease rate ΔART2 (N) of the average blood pressure value ART (N) are calculated, and the first When at least one of the increase / decrease rate ΔART1 (N) and the second increase / decrease rate ΔART2 (N) is determined to be out of the allowable increase / decrease rate range, the average blood pressure value ART (N) is specified as noise data. In this way, by paying attention to the first increase / decrease rate and the second increase / decrease rate of each average blood pressure value, the noise data can be determined with relatively high accuracy.

Further, since the allowable increase / decrease rate range is changed according to the input operation from the operator, the optimum allowable increase / decrease rate range can be set for each hospital. In addition, by changing the permissible range of increase / decrease rate for each type of vital data such as average blood pressure, optimal noise determination can be performed for each type of vital data, and the noise determination accuracy of vital data can be determined for each type of vital data. It is possible to customize each time as appropriate.

Further, according to the present embodiment, when it is determined in the noise data identification process S43 based on the average blood pressure value allowable range that the average blood pressure value ART (N) is not within the average blood pressure value allowable range, the average blood pressure value ART ( N) is specified as noise data. As described above, since the noise data of the average blood pressure data is specified by a relatively simple method, the calculation load of the display device 1 can be reduced.

Further, since the average blood pressure value allowable range is changed according to the input operation from the operator, the optimum average blood pressure value allowable range can be set for each hospital. Further, by changing the average blood pressure value permissible range for each type of vital data such as the average blood pressure value, the optimum noise determination can be performed for each type of vital data, and the noise determination accuracy of the vital data can be determined as vital data. It is possible to customize each type as appropriate.

Further, in order to realize the display device 1 according to the present embodiment by software, the biometric information display program may be preliminarily incorporated in the storage unit 3 or the ROM. Alternatively, the biometric information display program includes a magnetic disk (HDD, floppy disk), an optical disk (CD-ROM, DVD-ROM, Blu-ray disk, etc.), a photomagnetic disk (MO, etc.), a flash memory (SD card, USB memory, etc.). , SSD, etc.) may be stored in a computer-readable storage medium. In this case, the biometric information display program stored in the storage medium is read by a disk drive or the like provided in the display device 1, and the biometric information display program is incorporated into the storage unit 3. Then, the program incorporated in the storage unit 3 is loaded on the RAM, and the processor executes the program loaded on the RAM. In this way, the biometric information display method shown in FIG. 3 is executed.

Further, the biometric information display program may be downloaded from a computer on the communication network via the network interface 4. In this case as well, the downloaded program is incorporated into the storage unit 3.

Although the embodiments of the present invention have been described above, the technical scope of the present invention should not be construed as being limited by the description of the present embodiments. This embodiment is an example, and it is understood by those skilled in the art that various embodiments can be changed within the scope of the invention described in the claims. The technical scope of the present invention should be determined based on the scope of the invention described in the claims and the equivalent scope thereof.

Further, in the present embodiment, as an example of the worst value of vital data, the display device 1 capable of easily determining the minimum value and the maximum value of the average blood pressure data has been described. However, in the present embodiment, the display device 1 may be configured to easily determine the worst value of other vital data. For example, the display device 1 may be configured so that the worst value of vital data such as systolic blood pressure data, body temperature data, heart rate data and respiratory rate data can be easily determined. These vital data have a plurality of vital values and a plurality of measurement times in which the plurality of vital values are measured, and each of the plurality of vital values is associated with a corresponding one of the plurality of measurement times.

1: Biological information display device (display device)
2: Control unit 3: Storage unit 4: Network interface 5: Display unit 6: Input operation unit 8: Bus 20: Vital data display window 21: Trend graph 22: Highest value selection list 23: Minimum value selection list 24: List 25 : Data upper limit line 26: Data lower limit line 27: Highest value specification mark 28: Minimum value specification mark 29: Automatic adjustment button 30: Setting change button 32: Upper limit line movement command button 33: Lower limit line movement command button 35: Vital data setting window

Claims (20)

With the processor
A biometric information display device equipped with a memory for storing computer-readable commands.
When the computer-readable instruction is executed by the processor, the biometric information display device
Acquires vital data having a plurality of vital values and a plurality of measurement times at which the plurality of vital values are measured, and each of the plurality of vital values is associated with a corresponding one of the plurality of measurement times. ,
Generate a list of the acquired vital data and a trend graph,
Display the generated list and trend graph on the display screen of the display unit, and display them.
Identify the noise data contained in the vital data and
Based on the vital data excluding the specified noise data, a data upper limit line that defines the upper limit value of the vital data and a data lower limit line that defines the lower limit value of the vital data are generated.
The generated data upper limit line and data lower limit line are displayed on the trend graph, and the data is displayed.
The worst value of the vital data from the vital data included in the range between the upper limit value of the vital data defined by the data upper limit line and the lower limit value of the vital data defined by the data lower limit line. Decide,
The worst value of the determined vital data is specified on the display screen.
Biological information display device. The biometric information display device according to claim 1, wherein the biometric information display device specifies the worst value of the vital data on the trend graph and the list. When the computer-readable instruction is executed by the processor, the biometric information display device moves the data upper limit line and the data lower limit line displayed on the trend graph according to an input operation from the operator. Item 3. The biological information display device according to Item 1 or 2. The biometric information display device is used to identify the noise data.
The first increase / decrease rate of the predetermined vital value is calculated based on the predetermined vital value and the vital value acquired immediately before the predetermined vital value is acquired.
The second increase / decrease rate of the predetermined vital value is calculated based on the predetermined vital value and the vital value acquired immediately after the predetermined vital value is acquired.
It is determined whether at least one of the first increase / decrease rate and the second increase / decrease rate is out of the allowable increase / decrease range.
Any one of claims 1 to 3, which specifies the predetermined vital value as noise data when it is determined that at least one of the first increase / decrease rate and the second increase / decrease rate is out of the allowable increase / decrease rate range. The biological information display device according to item 1. The biometric information display device is used to identify the noise data.
Vital value of Jo Tokoro is determined whether the vital value allowable range,
The biometric information display device according to any one of claims 1 to 4, wherein when it is determined that the predetermined vital value is not within the permissible range of the vital value, the predetermined vital value is specified as noise data. The biometric information display device according to claim 4, wherein when the computer-readable instruction is executed by the processor, the biometric information display device changes the permissible range of increase / decrease rate according to an input operation from the operator. The biometric information display device according to claim 5, wherein when the computer-readable instruction is executed by the processor, the biometric information display device changes the vital value allowable range according to an input operation from the operator. The biometric information display device according to any one of claims 1 to 7, wherein the biometric information display device identifies noise data included in the vital data according to an input operation from the operator. The vital data is average blood pressure data.
The average blood pressure data has a plurality of average blood pressure values and a plurality of measurement times at which the plurality of average blood pressure values are measured, and each of the plurality of average blood pressure values corresponds to one of the plurality of measurement times. Associated and
The biometric information display device according to any one of claims 1 to 8, wherein the worst value of the vital data is the lowest value and the highest value of the average blood pressure data. Acquires vital data having a plurality of vital values and a plurality of measurement times at which the plurality of vital values are measured, and each of the plurality of vital values is associated with a corresponding one of the plurality of measurement times. Steps and
Steps to generate the list of acquired vital data and trend graph, and
The step of displaying the generated list and trend graph on the display screen of the display device, and
The step of identifying the noise data included in the vital data and
A step of generating a data upper limit line that defines the upper limit value of the vital data and a data lower limit line that defines the lower limit value of the vital data based on the vital data excluding the specified noise data.
A step of displaying the generated data upper limit line and data lower limit line on the trend graph, and
The worst value of the vital data from the vital data included in the range between the upper limit value of the vital data defined by the data upper limit line and the lower limit value of the vital data defined by the data lower limit line. Steps to determine and
A step of specifying the worst value of the determined vital data on the display screen, and
Biometric information display method including. The biometric information display method according to claim 10, wherein in the step of specifying the worst value of the vital data, the worst value of the vital data is specified on the trend graph and the list. The biometric information display method according to claim 10 or 11, further comprising a step of moving the data upper limit line and the data lower limit line displayed on the trend graph according to an input operation from the operator. The step of identifying the noise data is
A step of calculating the first increase / decrease rate of the predetermined vital value based on the predetermined vital value and the vital value acquired immediately before the predetermined vital value is acquired, and
A step of calculating the second increase / decrease rate of the predetermined vital value based on the predetermined vital value and the vital value acquired immediately after the predetermined vital value is acquired, and
A step of determining whether at least one of the first increase / decrease rate and the second increase / decrease rate is out of the allowable increase / decrease range, and
According to claim 10, when it is determined that at least one of the first increase / decrease rate and the second increase / decrease rate is out of the allowable increase / decrease rate, the step of specifying the predetermined vital value as noise data is included. The biometric information display method according to any one of 12. The step of identifying the noise data is
Determining whether the vital value of Jo Tokoro is within the vital value allowable range,
The living body according to any one of claims 10 to 13, including a step of specifying the predetermined vital value as noise data when it is determined that the predetermined vital value is not within the allowable range of the vital value. Information display method. The biometric information display method according to claim 13, further comprising a step of changing the increase / decrease rate allowable range according to an input operation from the operator. The biometric information display method according to claim 14, further comprising a step of changing the vital value permissible range according to an input operation from the operator. The biometric information display method according to any one of claims 10 to 16, wherein the noise data included in the vital data is specified according to an input operation from the operator. The vital data is average blood pressure data.
The average blood pressure data has a plurality of average blood pressure values and a plurality of measurement times at which the plurality of average blood pressure values are measured, and each of the plurality of average blood pressure values corresponds to one of the plurality of measurement times. Associated and
The biometric information display method according to any one of claims 10 to 17, wherein the worst value of the vital data is the lowest value and the highest value of the average blood pressure data. A program for causing a computer to execute the biometric information display method according to any one of claims 10 to 18. A computer-readable storage medium in which the program according to claim 19 is stored.

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