JP2010057616A - Biological information monitoring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To inform a user of the reliability of the displayed biological signal waveform. <P>SOLUTION: In a central monitor 100, a wireless receiver section 102 receives the biological signals wirelessly transmitted from a telemeter transmitter 110 by an antenna 101 and carries out predetermined signal processing. A control section 103 measures the intensity of the received biological signals. The control section 103 synchronously displays the waveform 121 showing the received biological signals and the waveform 122 showing the measured intensity of the received signals on a display screen or a recording sheet. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a biological information monitor device.

  The central monitor is a kind of biological information monitoring device, and receives a biological signal of a patient at a remote place from a medical telemeter transmitter (hereinafter also simply referred to as “telemeter transmitter”) and displays it on a display screen. (For example, see Patent Document 1). The telemeter transmitter is carried by a patient and transmits a patient's biological signal superimposed on a radio signal. Therefore, the patient's biological signal can be transmitted from the telemeter transmitter to the central monitor from anywhere within the range where the radio signal emitted from the telemeter transmitter reaches the receiver on the central monitor side.

In general, when receiving a biological signal, the central monitor determines whether the biological signal is a normal value or an abnormal value, and issues an alarm if the biological signal is an abnormal value. For example, in the case of an electrocardiogram, the central monitor displays the received electrocardiogram waveform on the screen, analyzes the electrocardiogram waveform by an analysis technique such as template matching, and issues an alarm when an arrhythmia is detected as a result of the analysis.
JP 2005-177342 A

  However, in the conventional central monitor described above, the reception sensitivity of the central monitor may decrease due to, for example, the influence of noise. In this case, the central monitor sometimes cannot distinguish the received noise, for example, in the electrocardiogram waveform from the arrhythmia, which causes a false alarm. The user cannot determine whether such an apparent waveform abnormality is caused by a change in the patient's own condition or a deterioration in the reception environment simply by looking at the display screen. That is, the user cannot recognize the reliability of the displayed biological signal waveform.

  The present invention has been made in view of this point, and an object of the present invention is to provide a biological information monitoring apparatus capable of notifying the user of the reliability of the displayed biological signal waveform.

  The biological information monitoring apparatus of the present invention includes a receiving means for receiving a wirelessly transmitted biological signal, a measuring means for measuring the reliability of the received biological signal, and the received biological signal and the measured reliability. And a display means for synchronous display.

  According to the present invention, it is possible to notify the user of the reliability of the displayed biological signal waveform.

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

  FIG. 1 is a block diagram showing a configuration of a biological information monitor system according to an embodiment of the present invention.

  The biological information monitoring system in FIG. 1 includes a central monitor 100 and a telemeter transmitter 110. A central monitor 100 as a biological information monitoring apparatus of the present invention includes an antenna 101, a wireless reception unit 102, a control unit 103, a display 104, a printer 105, and a display switching instruction unit 106. A telemeter transmitter 110 acquires a biological signal. Unit 111, control unit 112, wireless transmission unit 113, and antenna 114.

  In the telemeter transmitter 110, the biological signal acquisition unit 111 has a signal processing circuit including an amplifier, an analog / digital (A / D) converter, and the like. Signal processing such as amplification and A / D conversion is performed on the biological signals (electrocardiogram, SpO2 and the like) to be supplied to the control unit 112.

  The control unit 112 includes a storage device that stores a program for controlling various functions in the telemeter transmitter 110, and a CPU (Central Processing Unit) that executes the program. The control unit 112 supplies the biological signal supplied from the biological signal acquisition unit 111 to the wireless transmission unit 113. The storage device also stores channel information indicating a radio channel number uniquely assigned to the telemeter transmitter 110.

  The wireless transmission unit 113 includes a signal processing circuit including a digital analog (D / A) converter, an up-converter, and the like, and performs D / A conversion and frequency conversion to a radio frequency band on the biological signal supplied from the control unit 112. The signal processing is performed, and the biological signal after the signal processing is wirelessly transmitted from the antenna 114. Note that the frequency after frequency conversion is uniquely determined according to the radio channel number indicated in the channel information stored in the control unit 112.

  In this way, the biological signal measured from the patient is transmitted to the central monitor 100 in real time.

  On the other hand, in the central monitor 100, the wireless receiving unit 102 as a receiving means of the present invention has a signal processing circuit including a down converter, an A / D converter, and the like, and receives a biological signal wirelessly transmitted from the telemeter transmitter 110 as an antenna. The received signal is subjected to signal processing such as baseband frequency conversion and A / D conversion, and the biological signal after the signal processing is supplied to the control unit 103. In FIG. 1, the central monitor 100 is described as receiving a biological signal from one telemeter transmitter, but usually a radio channel is individually assigned to each telemeter transmitter. Biological signals from a plurality of telemeter transmitters can be received simultaneously.

  The control unit 103 as a measurement unit and a display unit of the present invention includes a storage device that stores a program for controlling various functions in the central monitor 100 and a CPU that executes the program. The control unit 103 stores the biological signal supplied from the wireless reception unit 102 in the storage device and analyzes the biological signal.

  Further, the control unit 103 displays a biological signal waveform indicating the supplied biological signal and an analysis result of the biological signal on the screen of the display 104. In addition, the control unit 103 measures the received signal strength of the biological signal received by the wireless receiving unit 102, stores the measured received signal strength in the storage device, and the received signal strength is stored in the biological signal waveform. Display in sync with. The mode of synchronous display will be described in detail later. The control unit 103 can also display the biological signal waveform, the biological signal analysis result, and the received signal intensity by printing them on a recording sheet with the printer 105. At this time, the control unit 103 can synchronize the biological signal waveform and the received signal intensity with each other. In this way, the central monitor 100 can display the received signal strength in real time in synchronization with the biological signal waveform.

  Further, the control unit 103 can read out the biological signal and the received signal intensity from the storage device, and display the biological signal analysis result on the display screen or on the recording sheet together with them. Therefore, the central monitor 100 can synchronously display the past biological signal waveform and the received signal strength at that time.

  In addition, the control unit 103 may display the received signal intensity at all times when displaying the biological signal waveform, or on the screen or recording only when a switching instruction is given from the display switching instruction unit 106. The display mode on the paper may be switched to display the received signal strength. The display mode switching will be described later in detail.

  The display switching instruction unit 106 as an instruction unit of the present invention generates a display instruction which is a signal for instructing switching of the display mode, and supplies the display instruction to the control unit 103.

  Supply of a display instruction from the display switching instruction unit 106 to the control unit 103 can be performed under various conditions. For example, when a user operates an input unit (not shown) such as a mouse or a keyboard at an arbitrary timing, and a display signal strength display request is input to the display switching instruction unit 106, a display instruction is supplied. It can be carried out. Alternatively, the display switching instruction unit 106 compares the received signal strength with a predetermined threshold value, and when the received signal strength falls below this threshold value, the display instruction can be supplied. Alternatively, the display instruction can be supplied when the biological signal shows some abnormality such as an abnormal increase in heart rate as a result of the biological signal analysis in the control unit 103.

  Next, the synchronous display mode according to the present embodiment will be described.

  FIG. 2 shows an example of a synchronous display mode of the biological signal waveform and the received signal strength. In FIG. 2, an electrocardiogram waveform 121 and a received signal strength waveform 122 indicating received signal strength are drawn side by side. In the electrocardiogram waveform 121, a waveform like VF (Ventricular Tachycardia) appears in some sections 123. However, also in the received signal strength waveform 122, a change such as a decrease in received signal strength appears in the section 123. Therefore, the user can recognize that the waveform such as VF appearing in the electrocardiogram waveform 121 is low in reliability when viewing this synchronous display.

  In this way, by drawing the biological signal waveform and the received signal intensity waveform side by side, it is possible to easily notify the user of a portion with low reliability in the biological signal waveform.

  FIG. 3 shows another example of a synchronous display mode of the biological signal waveform and the received signal strength. In FIG. 3, the waveform to be drawn is only the electrocardiogram waveform 131, and the received signal strength is expressed by the thickness of the electrocardiogram waveform 131. In the partial section 132 of the electrocardiogram waveform 131, a waveform like VF appears apparently as in the example shown in FIG. However, in the section 132, the line of the electrocardiogram waveform 131 is thin, that is, a change that the received signal intensity is reduced appears. Therefore, the user can recognize that the waveform like VF appearing in the electrocardiogram waveform 131 is low in reliability when viewing this synchronous display.

  In this way, by changing the thickness of the line of the biological signal waveform according to the received signal intensity, it is possible to easily notify the user of a portion with low reliability in the biological signal waveform. In addition, since the received signal strength is not notified using a waveform, it is not necessary to secure a storage area for one waveform in the control unit 103 for the received signal strength. It is possible to avoid a situation that must be omitted.

  Note that, when the line color or shading is changed according to the received signal intensity, the same effect as when the line thickness is changed can be realized. In addition, when changing the line thickness, color, and shading according to the received signal strength, it is preferable to output another alarm as needed.

  Next, display mode switching according to the present embodiment will be described.

  FIG. 4A shows a 6-bed 2-waveform display mode as an example of a general display mode on the display 104 of the central monitor 100. On the display screen 140 in the 6-bed 2-waveform display mode, the electrocardiogram waveform and the impedance respiration waveform can be synchronously displayed for six patients, and the analysis results of these waveforms can be displayed. Here, paying attention to the electrocardiogram waveform 141 and the impedance respiration waveform 142 for one patient shown in the figure, the electrocardiogram waveform 141 has a waveform that looks like VF in a part of the section. Also in the impedance respiration waveform 142, a disturbance in which the level changes reciprocally between the maximum value and the minimum value appears in the same section. It can be recognized from this waveform disturbance that the reliability of the electrocardiogram waveform 141 is not necessarily high, but it cannot be objectively determined what the cause is. As for the waveform disturbance, as shown in FIG. 4B, there may be a disturbance such that the level of the impedance respiration waveform 143 is fixed to the minimum value. Also in this case, it can be recognized that the reliability of the electrocardiographic waveform 141 is not necessarily high, but it is not possible to objectively determine what the cause is.

  Therefore, in an example of switching the display mode, as shown in FIG. 5, when the electrocardiogram waveform 151 and the impedance respiration waveform 152 are displayed synchronously and the received signal intensity falls below a predetermined threshold, the impedance respiration waveform 152 A reception signal strength waveform 153 is drawn instead of the portion where the reception signal strength is reduced. Thereby, a user can be easily notified of a part with low reliability in a biological signal waveform. In addition, the display of waveforms that do not substantially make sense such as the waveform disturbance shown in FIGS. 4A and 4B is omitted, and instead, important information such as waveform reliability is placed on the displayed waveforms. Can do.

  As shown in FIG. 5, when a part of the biological signal waveform is replaced with the received signal intensity waveform, it is preferable to change the line color or thickness so that these waveforms can be easily distinguished.

  In another example of display mode switching, when the received signal strength falls below a predetermined threshold, the display mode of the display screen is the display screen 140 in the 6-bed 2-waveform display mode, as shown in FIG. As shown in FIG. 6, the display screen 160 in the 6-bed / two-waveform display mode and the display screen 161 in the mode for displaying the waveform and the like of the patient whose received signal intensity has decreased are displayed. Can be switched.

  On the display screen 160, a shape that looks like VF appears in the electrocardiogram waveform 162 for one patient. Also in the impedance respiration waveform 163, waveform disturbance appears in the same section. On the other hand, on the display screen 161, an electrocardiogram waveform 164, a received signal strength waveform 165, an impedance respiration waveform 166, and the like for the same patient are drawn side by side. Since the electrocardiogram waveform 164 and the impedance respiration waveform 166 are generated based on the same biological signal as the electrocardiogram waveform 162 and the impedance respiration waveform 163 on the display screen 160, they have the same shape. On the display screen 161, in addition to these waveforms, a received signal strength waveform 165 is drawn. In the received signal strength waveform 165, the received signal strength is shown in a section where an abnormal shape appears in another waveform. Since a decrease appears, it can be recognized that the waveform in this section has low reliability.

  As described above, according to the present embodiment, since the received signal intensity of the biological signal is displayed in synchronization with the biological signal waveform, the user receives the abnormality when any abnormality appears in the biological signal waveform. It can be easily recognized simply by looking at the display screen that it is caused by a decrease in signal strength.

  In the present embodiment, the received signal strength is cited as an example of the reliability of the biological signal. However, when other measured values related to the reception quality of the signal can be obtained from the received biological signal, the measurement is performed. Values may be substituted or used together. Further, when the reception sensitivity of the wireless reception unit 102 in the central monitor 100 can be measured, the measured value may be used instead or in combination.

  The embodiment of the present invention has been described above. The above description is an illustration of a preferred embodiment of the present invention, and the scope of the present invention is not limited to this. That is, the description of the configuration of the apparatus, the contents displayed on the screen, and the mode thereof is merely an example, and it is apparent that various modifications and additions to these examples are possible within the scope of the present invention.

The block diagram which shows the structure of the biometric information monitor system which concerns on one embodiment of this invention The figure which shows an example of the synchronous display aspect which concerns on one embodiment of this invention The figure which shows the other example of the synchronous display aspect which concerns on one embodiment of this invention. Diagram showing 6-bed 2-waveform display mode of central monitor The figure which shows an example of the switching of the display mode which concerns on one embodiment of this invention The figure which shows the other example of switching of the display mode which concerns on one embodiment of this invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Central monitor 101 Antenna 102 Radio | wireless receiving part 103 Control part 104 Display 105 Printer 106 Display switching instruction | indication part

Claims (6)

Receiving means for receiving a wirelessly transmitted biological signal;
Measuring means for measuring the reliability of the received biological signal;
Display means for synchronously displaying the received biological signal and the measured reliability;
A biological information monitor device characterized by comprising: The display means draws a biological signal waveform indicating the received biological signal, and draws a reliability waveform indicating the measured reliability side by side on the biological signal waveform,
The biological information monitoring apparatus according to claim 1. The biological signal includes different types of biological signals,
An instruction means for giving the display instruction of the reliability to the display means;
When the display instruction is received from the instruction unit while the plurality of biological signal waveforms respectively indicating the different types of biological signals are arranged and drawn, the display unit includes the plurality of biological signal waveforms. In place of one biological signal waveform, the reliability waveform is drawn.
The biological information monitoring apparatus according to claim 2. The display means draws a biological signal waveform indicating the received biological signal, and changes the thickness of the drawn biological signal waveform line according to the measured reliability.
The biological information monitoring apparatus according to claim 1. The display means draws a biological signal waveform indicating the received biological signal, and changes the shading of the drawn biological signal waveform line according to the measured reliability.
The biological information monitoring apparatus according to claim 1. The display means draws a biological signal waveform indicating the received biological signal, and changes the color of the drawn biological signal waveform line according to the measured reliability.
The biological information monitoring apparatus according to claim 1.

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