JP2006239084A - Monitoring method of condition measuring device by portable terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for monitoring a plurality of condition measuring devices efficiently with a portable terminal. <P>SOLUTION: The plurality of condition measuring devices are grouped to be a plurality of groups. Each group is expressed as an identifiable first symbol, and the condition measuring devices are expressed as second symbols which can be identified by each group. Then, a signal transmitted from the condition measuring devices is converted into a message, and the first symbol, the second symbol showing the condition measuring devices included in at least one group and the message are displayed simultaneously on the screen of the portable terminal. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention relates to a method for monitoring a plurality of state measuring devices connected by a portable terminal via a wired and / or wireless network. In particular, arterial oxygen saturation using as the monitoring item states of the plurality of patients a nurse is hospitalized in a hospital (hereinafter, S p _{O 2),} monitor the patient monitoring to measure the pulse rate or the like in real time on a mobile device On how to do.

  In production factories and service facilities, one person monitors a plurality of production devices and measuring devices, and handles abnormalities when they occur. For example, a nurse who works in a hospital performs the task of grasping the status of multiple patients alone, responding quickly to abnormalities in patients, and taking appropriate measures and processing .

  Here, the state measuring device for grasping the patient's state is generally called a biological information monitor or a vital sensor.

The data Medical Monitor to measure, S p _{O 2,} blood pressure, pulse, etc. are common. As a system for monitoring a biological information monitor, for example, there is a system using a PHS. In this system, the nurse listens to the patient's room number, the patient's name, the type of alarm, etc. notified by the PHS by voice. It is configured to grasp the patient's condition.

  Such a conventional system can only monitor about 16 biometric information monitors at the maximum because the screen size of the portable terminal is small. However, as the scale of the system increases in recent years, several tens to several hundreds of units can be monitored. There is a problem that the state measuring device must be monitored.

  In addition, since an alarm always occurs when the value falls below a preset value, it is impossible to know the details of the alarm that occurred on the biological information monitor. . For this reason, when simultaneous alarms are generated from a plurality of state measuring devices, there is a problem that it is impossible to accurately determine which alarm should be prioritized on the spot, and it is not possible to respond from the highest priority.

  Furthermore, various alarms such as temporary alarms due to poor contact are included in the alarms, and it is necessary to monitor the alarms caused by hardware and the alarms caused by the occurrence of an abnormality in the monitoring target. . However, the conventional method for monitoring a state measuring apparatus has a problem that such alarms cannot be distinguished.

  Conventional systems for monitoring biological information monitors in hospitals perform registration of patient information using a management computer connected to a LAN. However, input using a management computer has problems such as input errors and time-consuming computer startup, and multiple management devices can be used to enable multiple people to use the management computer at the same time. There is also the problem of having to install a computer.

  Therefore, an object of the present invention is to provide a method capable of efficiently monitoring a large number of state measuring devices even in a portable terminal having a restriction that a large amount of information cannot be displayed because the size of a display screen is small.

  In addition, another object of the present invention is to provide an input at a data generation source that allows patient information to be input while interacting with a patient at a bedside, for example, while checking a wristband attached to the patient, using a portable terminal. It is an object of the present invention to provide a monitoring method for a state measuring apparatus that enables the above.

  Another object of the present invention is to provide a method capable of easily determining the priority order of alarms transmitted from a plurality of state measuring devices.

The present invention provides a monitoring method for a state measuring apparatus that takes advantage of the characteristics of a portable terminal that the display screen size is small and the information that can be displayed is limited, but is small and thus convenient to carry.
JP2003-303239 Medical Try System Co., Ltd. “Product Information Monitor Alarm Paging System” [searched on March 1, 2005], Internet (URL: <http://www.medical-trys.com/product/pcmoaps/index.htm>

  The present invention is a monitoring method for a plurality of state measuring devices connected via a network including a server by a portable terminal having a wireless proximity communication function, wherein the plurality of state measuring devices are grouped into a plurality of groups, Each group is represented as a identifiable first symbol, the state measuring device is represented as a second symbol identifiable for each group, a signal transmitted from the state measuring device is converted into a message, and the first This is a monitoring method of a state measuring device by a portable terminal that simultaneously displays the symbol, the second symbol indicating the state measuring device included in at least one group, and the message on the screen of the portable terminal.

  A plurality of state measuring devices are grouped, state measuring devices in one group are displayed on the screen as a second symbol that can be identified, and an alarm signal, for example, a signal from the state measuring device is sent. If it is, the signal is displayed as a message on the screen of the portable terminal. Thereby, even if the monitor who monitors the state measuring device is a portable terminal having a limited screen size, the state of the state measuring device of the group monitored by himself can be easily grasped.

  At least the second symbol changes by color and / or blinking according to a signal transmitted from the state measurement device associated with the symbol. Thus, for example, when a signal indicating abnormality is transmitted from the state measurement device, the color of the second symbol is changed and / or blinked to ensure that the abnormality has occurred in the state measurement device. Can be notified.

  By specifying the second symbol, detailed information transmitted by the state measurement device associated with the symbol and / or detailed information associated with the state measurement device is displayed on the screen of the portable terminal. The symbol of the state measuring device displayed on the screen of the mobile terminal changes due to the color and / or blinking due to an alarm, so that the supervisor can know the state measuring device in which an abnormality has occurred. Also, by clicking on the symbol whose color or the like has changed, the supervisor can grasp the detailed contents of the alarm.

  The screen of the portable terminal that displays the detailed information associated with the state measurement device includes a third symbol for displaying the history. By clicking on the third symbol, the history information transmitted so far by the state measuring device associated with the symbol can be displayed, for example, in a graph, and the monitor can thereby display detailed contents sent from the state measuring device. Can be found on a mobile device.

  A fourth symbol for displaying a screen for receiving data input from the portable terminal is displayed on the screen for displaying the detailed information associated with the state measuring device.

  The state measuring device is a biological information monitor for monitoring arterial oxygen saturation and pulse rate.

  At least a patient ID, a patient name, and a patient sex can be input from the information input reception screen displayed by specifying the fourth symbol. Thereby, for example, when the state measurement device is a biological information monitor, the ID, address, name, etc. of the patient connected to the biological information monitor can be reliably input from the portable terminal.

  According to the monitoring method of the state measuring device by the portable terminal of the present invention, a large number of state measuring devices can be efficiently monitored even by a portable terminal having a small display screen size. In addition, since data can be directly input from the mobile terminal at the data generation source, data input mistakes and the like can be prevented. Furthermore, there is a specific effect that the supervisor can easily determine the priority of the information transmitted to the mobile terminal.

  FIG. 1 is a system configuration diagram of a monitoring system for a state measuring device using a portable terminal. In this embodiment, a PDA (Personal Digital Assistant) is used as the portable terminal, and a biological information monitor is used as the state measuring device. However, the present invention is not limited to this.

The biological information monitor 20 in this embodiment can monitor S _p O ₂ , pulse rate, and blood pressure. The biological information monitor 20 is attached to a patient's finger or the like by a cable. Data measured by the biological information monitor 20 is accumulated in the server 40 by the access point 30 via the network. The access point is a wireless base station and can accommodate a wired LAN, and the biological information monitor 20 and the access point 30 are connected by wire or wirelessly.

  A server 40 is connected to the network and stores data transmitted by the biological information monitor 20. The patient data input from the management personal computer 50 is also stored in the server 40 in association with the biological information monitor.

  The biological information monitor 20 is grouped into several groups. In this embodiment, they are grouped into East 3 and West 3. The grouping may be performed in units that are easy to monitor, such as by area where one nurse must monitor or by ward.

The mobile terminal 10 and the access point 30 are connected by radio. The server 40 S _p O ₂ level of the patient at regular intervals from the Medical Monitor 20, pulse rate, blood pressure is transmitted. The server 40 stores the transmitted data and transmits the information on the biological information monitor monitored by the nurse carrying the mobile terminal to the predetermined mobile terminal 10 at predetermined intervals.

  FIG. 2 is a configuration example of a screen normally displayed on the mobile terminal 10. In the configuration example of this screen, the biological information monitors 20 are grouped into three groups of “East 3”, “West 3”, and “North 3”. These three groups are displayed in the group display area 120 with these symbols.

  By clicking “East 3” in the group display area 120, all state measuring devices installed in the “East 3” group are displayed in the group display area 110 by symbols. Here, No. 1 of the biological information monitor “East 3” is displayed as E301.

  When an abnormality occurs in the biological information monitor corresponding to E301, E301 notifies the nurse that the abnormality has occurred due to a color change or the like. By selecting “ALL”, it is possible to display all the symbols of the biological information monitor on the screen of the mobile terminal 10.

  The content of the abnormality that has occurred is displayed as a simple message in the message display area 130 in real time. In FIG. 2, the abnormality that has occurred in E301 is displayed together with the time of occurrence, the content of the abnormality, and the upper limit value or lower limit value of the alarm occurrence. In order to know the details of the abnormality that occurred in E301, click E301.

FIG. 3 is a configuration example of a screen that displays detailed information of a patient transmitted by E301. The detailed information display area 160 displays that the biological information monitor being displayed is E301, the patient ID, the date of entry, the patient name, the patient's doctor, and the contact information of the doctor. In addition, the S _p O ₂ value, the blood pressure value, and the PI are displayed. In addition, patient contact information is displayed.

  Alarm in the detailed information display area 160 is an area for displaying whether an alarm has occurred from E301. “Exception” indicates whether there is an abnormality in hardware such as whether the cable connecting E301, which is a biological information monitor, and the patient is normally connected. In FIG. 3, the hardware is operating normally.

In FIG. 3, a trend 140 is a symbol for displaying a trend of data that E301 (biological information monitor) has transmitted to the server 40 so far. FIG. 4 shows a screen displayed on the mobile terminal 10 when the trend 140 as the symbol is clicked. _PI patients as shown in FIG. _{4, S p O 2, PR} ( blood pressure) is displayed in the trend graph.

  In FIG. 3, an attribute 150 is a symbol that is clicked when information related to a patient, such as a patient ID, name, address, or the like is input from the mobile terminal 10.

Figure 4 is a _S P _O 2, PR, one configuration example of a trend display the screen of the PI of a patient of the biological information monitor (E301). As shown in FIG. 4, data such as S _P O ₂ of the patient Jiro of E301 is displayed in a trend. Based on the displayed trend, the nurse can grasp the condition of the patient before and after the alarm is generated, and can determine whether the alarm requires an urgent level.

  FIG. 5 shows an example of the configuration of the patient personal information input screen. When the attribute 150 is clicked on the screen shown in FIG. 3, a patient personal information input acceptance screen is displayed. At the bedside, the nurse inputs input items displayed on the screen, such as patient ID, patient name, sex, date of birth, and the like. When the input is completed, the data is stored in the server 40 by clicking “OK”. The nurse can input data while confirming the input data at the bedside of the patient.

  FIG. 6 shows an example of a configuration in which personal information of a patient is displayed on the screen. For example, by clicking E305 of East 3 on the screen shown in FIG. 2 and clicking the attribute 150 on the screen shown in FIG. 3, detailed information on the patient of E305 is displayed as shown in FIG. 6. .

  As described above, on the normal screen of the portable terminal 10 carried by the nurse, the biological information monitor that the nurse must monitor is displayed as a symbol on the screen of the portable terminal 10. Here, when an abnormality occurs in the biological information monitor, the nurse can surely know that the abnormality has occurred by changing the color of the symbol indicating the biological information monitor.

  The message area 130 displays the abnormal content as a simple message. As a result, the nurse can quickly grasp which biological information monitor has an abnormality and what the abnormality is.

  Furthermore, when it is determined that it is necessary to know more detailed contents from the message, the detailed screen shown in FIG. 3 can be displayed by clicking a symbol of the biological information monitor, for example, E301. As a result, it is possible to accurately determine whether the alarm requires an urgency level and is an alarm that needs to call the attending physician. Furthermore, by clicking on the trend 140, time-series information can be grasped, which is useful for determining the urgency level and priority level of an alarm.

  As described above, according to the present invention, a plurality of state measuring devices can be monitored by the mobile terminal, and the monitor can accurately monitor the plurality of state measuring devices by carrying the mobile terminal. The present invention can be applied to various monitoring systems such as manufacturing industry and service industry.

It is a system configuration | structure figure of the monitoring system of the state measurement apparatus by a portable terminal. 3 is a configuration example of a screen normally displayed on the mobile terminal 10. It is an example of 1 structure of the display screen of the detailed information which E301 transmits. S _P O _2, PR, which is one configuration example of a screen where the PI and trend display. It shows an example of the configuration of a patient personal information input screen. The example of a structure of the screen which displayed the detailed information of the patient is shown.

Explanation of symbols

1. Monitoring system for state measuring device using portable terminal
10 Mobile devices (PDA)
20 Biological information monitor
30 Access point 40 Server 50 Management PC

Claims (7)

A monitoring method for a plurality of state measuring devices connected via a network including a server by a portable terminal having a wireless proximity communication function,
Grouping the plurality of state measuring devices into a plurality of groups, and representing each group as a first identifiable symbol;
The state measuring device is represented as a second symbol that can be identified for each group,
The signal transmitted from the state measuring device is converted into a message,
A state measuring device using a portable terminal, wherein the first symbol, the second symbol indicating a state measuring device included in at least one group, and the message are simultaneously displayed on a screen of the portable terminal. Monitoring method. The state measurement device monitoring according to claim 1, wherein at least the second symbol changes by color and / or blinking according to a signal transmitted from the state measurement device associated with the symbol. Method. By specifying the second symbol, detailed information transmitted by the state measurement device associated with the symbol and / or detailed information associated with the state measurement device is displayed on the screen of the portable terminal. The monitoring method of the state measuring device according to claim 1 or 2.   The third symbol for displaying a history of data transmitted by the state measurement device is displayed on a screen of a portable terminal that displays detailed information associated with the state measurement device. The monitoring method of the state measuring apparatus as described in any one of 1-3. 5. The fourth symbol for displaying a screen for accepting data input from a mobile terminal is displayed on a screen for displaying detailed information associated with the state measuring device. 6. The state measuring device monitoring method according to one item. 6. The monitoring method for a state measuring device according to claim 1, wherein the state measuring device is a biological information monitor for monitoring arterial blood oxygen saturation and pulse rate. The state measuring apparatus monitoring method according to claim 6, wherein at least a patient ID, a patient name, and a patient sex can be input from the screen that receives the data input.

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