JP6125909B2 - Biological monitor device - Google Patents

Description

  The present invention relates to a biological monitor device.

  2. Description of the Related Art Conventionally, a biological monitor device that measures a patient's heart rate, electrocardiogram, and the like and transmits measurement data to a central monitor or a network has been used. In order to reduce the restraint of a patient, a technique has been proposed in which a communication cable for connecting a biological monitor device and a central monitor is eliminated and measurement data is transmitted using a wireless communication network (see Patent Document 1). .

Special table 2011-515042 gazette

  When the network becomes unstable, a phenomenon in which a part of measurement data cannot be transmitted / received normally (hereinafter referred to as data loss) occurs. In this regard, Patent Document 1 describes that the amount of communication data is limited according to the network load.

  However, even when the amount of communication data is limited, measurement data that cannot be transmitted / received occurs. Depending on the contents of the measurement data that cannot be transmitted and received, it may be difficult to properly monitor the patient.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a biological monitor device that is robust against network instability and enables appropriate monitoring.

  The living body monitoring device of the present invention acquires the first data acquisition means for acquiring the first data related to the living body in the first period, and the second data related to the living body in the second period longer than the first period. Second data acquisition means, and data transmission means for transmitting data for each transmission unit including the first data and the second data, and the number of transmission units including the same second data is: It is larger than the number of transmission units including the same first data.

  Since the second data has a long acquisition cycle, if the second data cannot be normally transmitted / received, the influence is great. The biological monitor device of the present invention repeatedly transmits the same second data more times than in the case of the first data. As a result, data loss of the second data is less likely to occur. Therefore, patient monitoring can be performed appropriately.

  Further, in the biological monitor device of the present invention, the number of times that the same first data is repeatedly transmitted is smaller than that in the case of the second data, so that all the data is repeatedly transmitted in the same manner as the second data. The transmission load can be reduced. Since the first data is acquired in a short cycle, even if data loss occurs in the first data, the influence is small compared to the data loss of the second data.

  The frequency corresponding to the first period (for example, when the first period is N (sec), the corresponding frequency is 1 / N (Hz)) can be 40 Hz or more, for example. In this case, as the first data, for example, it is easy to provide information that intuitively captures a change in a biological signal such as an electrocardiogram waveform, a pulse waveform, and body motion.

  The frequency corresponding to the second period (for example, when the second period is N (sec), the corresponding frequency is 1 / N (Hz)) can be set to 1 Hz or more, for example. For example, when the second data is a biological signal typified by heart rate or blood pressure, the biological signal is unlikely to change abruptly. Therefore, even if the second data is measured at a cycle similar to the cycle in the first data. While it is difficult to obtain useful information, the load on the biological monitor apparatus body and the load on the network are increased. Therefore, by setting the frequency corresponding to the second period to 1 Hz or more, it becomes easy to reduce the load on the biological monitor main body and the network and obtain useful information.

  The frequency at which the data transmission unit transmits the transmission unit can be, for example, 1/10 or less of the frequency of the base timer in the CPU provided in the biological monitor device. In this case, the load of transmission processing is reduced, and stable transmission is facilitated.

  The frequency at which the data transmission unit transmits the transmission unit may be 1 to 10 Hz, for example. In this case, for example, it becomes easy to perform appropriate patient monitoring at a transmission destination such as a central monitor. Moreover, the transmission which reduced the load of the biological monitor apparatus main body and a network becomes easy by setting it as 10 Hz or less.

For example, the retransmission of the transmission unit may not be performed. In this case, the burden on the network is reduced, and robust data transmission is facilitated.
The data transmission unit can perform transmission by wireless communication, for example. In wireless communication, the communication environment may fluctuate greatly due to obstacles or the like, but according to the present invention, robust communication is facilitated even if the communication environment changes.

  The first data can be, for example, one or more selected from the group consisting of an electrocardiographic potential, a pulse wave, and acceleration information. In this case, by observing the first data at the transmission destination, the state of the patient, such as the state of arrhythmia by the electrocardiographic potential, the peripheral circulatory dynamics by the pulse wave, the presence / absence or posture of the movement by acceleration Can be grasped and appropriate monitoring becomes easy. On the other hand, since these pieces of information are mainly determined by observations of medical staff, even if data loss occurs, the medical staff can make judgments, so that it is difficult to lead to a fatal error.

  The second data may be, for example, one or more selected from the group consisting of heart rate, pulse rate, arterial oxygen saturation, body temperature, body position information, and activity amount information. In particular, the second data includes, for example, one or more selected from the group consisting of heart rate, pulse rate, and arterial oxygen saturation, and one or more selected from the group consisting of body position information and activity amount information. Can be included.

  In this case, for example, the second data can be a parameter used by the transmission destination device itself to issue an alarm according to a threshold value set inside, in addition to the observation of the medical staff at the transmission destination. . For example, when the transmission destination (central monitor) receives data with a heart rate of 30 or less, it can be determined that the patient is abnormal and an alarm can be issued using sound or LEDs. In the present invention, since the second data can be transmitted a plurality of times, the instability of communication is more robust than the first data, and appropriate patient monitoring is facilitated.

  In particular, when the second data includes one or more selected from the group consisting of heart rate, pulse rate, and arterial oxygen saturation, and one or more selected from the group consisting of body position information and activity amount information, communication Appropriate patient monitoring can be performed even with a small number of data transmissions in an unstable situation. For example, when the heart rate and activity amount information are transmitted simultaneously as the second data, when the heart rate suddenly fluctuates, the activity amount information is viewed to determine whether the cause is a patient abnormality. Therefore, more appropriate patient monitoring can be performed.

  At least a part of the second data can be calculated based on the first data, for example. In this case, patient monitoring that is more robust against communication instability is facilitated. For example, consider a case where the first data is a pulse wave. Since the pulse rate is obtained by counting the number of waves from the pulse wave signal, for example, the pulse rate can be calculated by transmitting the pulse wave signal to the transmission destination device. However, when communication instability occurs, an incorrect pulse rate may be calculated by such a method and appropriate monitoring may not be performed. Therefore, by calculating and transmitting the second data in the living body monitoring device of the present invention, the second data can be transmitted reliably, and patient monitoring that is robust against communication instability is easy. Become.

  The data size of the second data calculated based on the first data can be made smaller than one data of the first data, for example. In this case, the network load is further reduced, and more stable communication is facilitated. Here, one data means a value at a certain point of the first data before analysis. For example, when the pulse rate is calculated from the pulse wave signal as described above, the data size of one point of the pulse wave signal can be set to, for example, 12 bits in consideration of fluctuations of the pulse wave. Since the number is usually calculated from 30 bpm to 300 bpm, a data size of about 8 bits is sufficient.

  The transmission unit can include, for example, time information at the time of acquiring the second data or measurement condition information together with the second data. In this case, in the unlikely event that data is lost, it is possible to grasp how much data has been lost at the next reception and under what conditions the data was measured, and appropriate patient monitoring becomes possible.

1 is a block diagram illustrating a configuration of a biological monitor device 1. FIG. It is explanatory drawing showing the process which the biological monitor apparatus 1 performs. It is explanatory drawing showing the relationship between a transmission unit, 1st data, and 2nd data. 6 is an explanatory diagram illustrating a display example on the central monitor 101. FIG. It is explanatory drawing showing the content of the measurement packet P2. It is explanatory drawing showing the content of the measurement packet P1.

An embodiment of the present invention will be described with reference to the drawings.
1. Configuration of Biological Monitor Device 1 The configuration of the biological monitor device 1 will be described with reference to FIG. The biological monitor device 1 includes an electrocardiogram electrode 3, an oxygen saturation sensor 5, an acceleration sensor 7, a temperature sensor 9, and an ECU 11.

  The electrocardiogram electrode 3 is attached to the patient and detects the electrocardiogram potential. The oxygen saturation sensor 5 is a known pulse oximeter attached to a patient's fingertip, earlobe, or the like. The oxygen saturation sensor 5 includes a light emitting unit that emits red light and infrared light, and a light receiving unit that receives transmitted light that has passed through the fingertip of a patient, and the like. The arterial oxygen saturation is detected based on the result of comparison with the degree of absorption.

The acceleration sensor 7 is attached to a patient and detects a three-dimensional acceleration. The temperature sensor 9 is attached to the patient and detects its body temperature (including skin temperature).
The ECU 11 includes an input IF (interface) 13, a calculation unit 15, and an output IF (interface) 17. The input IF 13 receives detection signals from the electrocardiogram electrode 3, the oxygen saturation sensor 5, the acceleration sensor 7, and the temperature sensor 9, and outputs them to the calculation unit 15. The calculation unit 15 executes a process to be described later, creates a transmission unit of data to be transmitted, and outputs it to the output IF 17. The output IF 17 sequentially transmits data for each transmission unit. Data transmission is performed by wireless communication. The frequency of the base timer in the calculation unit 15 (one embodiment of the CPU) is 10 times or more the transmission frequency (2 Hz) of a transmission unit, which will be described later.

  The central monitor 101 receives the data transmitted by the output IF 17. The central monitor 101 includes an input IF 103 that receives data transmitted by the output IF 17, a display device 105 that displays the received data, and a notification device 107 that issues an alarm when the displayed data satisfies a predetermined condition. .

2. Processing Performed by Biological Monitor Device 1 The processing performed by the biological monitor device 1 (particularly the calculation unit 15) will be described with reference to FIGS. The process shown in the flowchart of FIG. 2 is executed when the user presses a measurement start button (not shown) of the biological monitor device 1.

  In step 1 of FIG. 2, the second data is acquired and put into the measurement packet P2. The second data includes body temperature, heart rate, pulse rate, arterial oxygen saturation, body position information, and activity information. Among the second data, the body temperature and the arterial oxygen saturation are measured and acquired using the temperature sensor 9 and the oxygen saturation sensor 5 in this step. Among the second data, the heart rate, the pulse rate, the body position information, and the activity amount information are acquired based on the measurement result when Step 6 described later is executed last time. Specific contents of the second data are as follows.

Body temperature: The temperature of the patient acquired using the temperature sensor 9.
Heart rate: A value calculated on the basis of 50 electrocardiographic potentials (electrocardiograms) obtained when the process of step 6 described later is executed last time. The data size of the heart rate is smaller than the data size of 50 electrocardiographic potentials.

  Pulse rate: A value calculated on the basis of 50 pulse waves (pulse wave waveforms) obtained when the process of step 6 described later was executed last time. The data size of the pulse rate is smaller than the data size of 50 pulse waves.

Arterial blood oxygen saturation: arterial blood oxygen saturation of a patient obtained using the oxygen saturation sensor 5.
Body position information: Patient's body position (any one of standing, sitting, supine, and prone positions) obtained based on 50 acceleration signals obtained when the process of step 6 described later is executed last time. The data size of the body position information is smaller than the data size of 50 acceleration signals.

  Activity amount information: The degree of activity of a patient obtained based on 50 acceleration signals obtained when the process of step 6 described later is executed last time. Note that the data size of the activity amount information is smaller than the data size of 50 acceleration signals.

  In step 2, the measurement and acquisition of the first data and the entry into the measurement packet P1 are repeated 50 times every 0.01 seconds (with a period corresponding to 100 Hz). The first data includes an electrocardiographic potential, a pulse wave, and an acceleration signal. Specific contents of the first data are as follows.

ECG potential: the patient's ECG potential obtained using the ECG electrode 3 when this step is executed.
Pulse wave: An output value when the oxygen saturation sensor 5 executes this step.

Acceleration signal: The patient's acceleration at the time of execution of this step, acquired using the acceleration sensor 7.
Through the process of this step, 50 measurement packets P1 are obtained. Each measurement packet P1 includes one electrocardiographic potential, one pulse wave, and one acceleration signal.

  In step 3, one measurement packet P2 obtained in step 1 and 50 measurement packets P1 obtained in step 2 are combined to form one transmission unit. Then, the one transmission unit is transmitted using the output IF 17 at a timing when 0.5 seconds have elapsed since the transmission unit was transmitted in the immediately preceding step 7 (described later).

In step 4, the content of the transmission unit is reset.
In step 5, the second data acquired in the immediately preceding step 1 is put in the measurement packet P2.

  In Step 6, as in Step 2, the first data is acquired and put in the measurement packet P1 50 times every 0.01 seconds (with a period corresponding to 100 Hz).

  In Step 7, the one measurement packet P2 obtained in Step 5 and the 50 measurement packets P1 obtained in Step 6 are combined to form one transmission unit. Then, the transmission unit is transmitted using the output IF 17 at a timing when 0.5 seconds have elapsed since the transmission unit was transmitted in the immediately preceding step 3.

In step 8, the content of the transmission unit is reset.
In step 9, it is determined whether or not the end flag is ON. If it is ON, this process ends. If it is OFF, the process proceeds to Step 1. The end flag is turned ON when a measurement end button (not shown) is pressed, and remains OFF when the measurement end button is not pressed.

The biological monitor device 1 does not retransmit the transmission unit that has already been transmitted.
Next, based on FIG. 3, the relationship between the transmission unit, the first data, and the second data will be described. The transmission unit is transmitted one by one in the step 3 and the step 7, and the transmission interval is 0.5 seconds. Therefore, the transmission unit is transmitted with a period of 0.5 seconds (a period corresponding to 2 Hz).

  Each transmission unit includes 50 measurement packets P1. Since each packet P1 contains one piece of first data of the same type, each transmission unit includes 50 pieces of first data of the same type. The 50 pieces of first data are repeatedly acquired with a period of 0.01 seconds (a period corresponding to 100 Hz) in 0.5 seconds. Note that 0.01 seconds is an embodiment of the first period.

  The arbitrary first data is included only in one transmission unit. That is, any first data is not included in two or more transmission units. For example, as shown in FIG. 3, the time periods of 0.5 seconds for acquiring 50 pieces of first data in step 2 or step 6 are T1, T2, T3,. When U1, U2, U3,..., Arbitrary first data acquired in the time zone T1 is included only in the transmission unit U1, and is not included in the transmission units U2, U3,. . Similarly, the arbitrary first data acquired in the time zone T2 is included only in the transmission unit U2, and is not included in the transmission units U1, U3,.

  Each transmission unit includes one measurement packet P2. Since one measurement packet P2 includes one second data of the same type, each transmission unit includes one second data of the same type. Arbitrary second data is included in each of two consecutive transmission units. That is, the second data acquired in step 1 is included in the transmission unit created in step 3 and transmitted, and the transmission unit created in step 7 is the next transmission unit. Is also included and transmitted.

  For example, as shown in FIG. 3, when the timing at which the second data is acquired in step 1 is V1, V2, V3..., The second data acquired at timing V1 is the transmission unit U1. It is included in both U2. Similarly, the second data acquired at timing V2 is included in both transmission units U3 and U4.

Therefore, the number of transmission units including the same second data is two. On the other hand, as described above, the number of transmission units including the same first data is one.
The period at which the second data is newly acquired (the period in which Step 1 is executed and the interval between Vi and Vi + 1 in FIG. 3 (i is a natural number)) is 1 second. One second is an embodiment of the second period.

  Next, a specific example of the measurement packet P2 is shown in FIG. The measurement packet P2 includes second data, time information, and measurement condition information. The time information is information representing the time when the second data is acquired. The measurement condition information is information related to the measurement of the second data, and specifically includes an electrocardiographic induction number and a light amount gain. A specific example of the measurement packet P1 is shown in FIG. The measurement packet P1 includes first data.

The central monitor 101 receives the data transmitted by the biological monitor device 1 and displays the image shown in FIG. 4 using the display device 105. In this display, HR (heart rate), SpO ₂ (arterial oxygen saturation), supine position (position information), electrocardiogram (created based on the electrocardiogram potential transmitted from the biological monitor device 1), and pulse wave waveform Is displayed.

  In addition, the central monitor 101 notifies the second data regarding the contents (body temperature, heart rate, pulse rate, arterial oxygen saturation, body position information, activity amount information) when a predetermined condition is satisfied. An alarm is issued using 107.

3. Effects of the living body monitor device 1 (1) Since the acquisition period of the second data is long, if the central monitor 101 cannot receive the second data (data omission), the influence is great. The biological monitor device 1 transmits the same second data twice in two transmission units. As a result, data loss of the second data is less likely to occur. Therefore, the biological monitor device 1 can appropriately perform patient monitoring.

  Moreover, since the same 1st data is transmitted only once in the biological monitor apparatus 1, the load of radio | wireless communication can be reduced compared with the case where all the data are transmitted in multiple times. Since the first data is acquired in a short cycle, even if data loss occurs in the first data, the influence is small compared to the data loss of the second data.

  (2) Since the biological monitor device 1 transmits data by wireless communication, the restraint of the patient can be reduced as compared with the case where the biological monitor device 1 and the central monitor 101 are connected by a wired cable.

  (3) At least a part of the second data (heart rate, pulse rate, body position information, activity amount information) is calculated based on the first data. The biological monitor device 1 can reduce the data omission of the second data.

  (4) The transmission unit includes time information and measurement condition information at the time of acquiring the second data, together with the second data, in the measurement packet P2. As a result, the packet configuration can be simplified.

4). Other Embodiments (1) The first data may be data other than those described above. The first data may be any one or two of electrocardiographic potential, pulse wave, and acceleration information. The second data may be data other than those described above. Further, the second data may be any one to five of heart rate, pulse rate, arterial oxygen saturation, body temperature, body position information, and activity amount information.

(2) The biological monitor device 1 may transmit data to the central monitor 101 by wired communication.
(3) The same second data may be included in three or more transmission units and transmitted three or more times.

  (4) A part of the first data (for example, the first data acquired at the beginning or the end of the 0.5 second time slot) or all of the first data is included in two or more transmission units, and twice. You may transmit above. Also in this case, the number of transmission units including the same second data can be larger than the number of transmission units including the same first data.

  (5) In addition to the first data and the second data, the biological monitor device 1 acquires other biological data (hereinafter referred to as third data) and transmits it to the central monitor 101. Also good. The acquisition period of the third data can be set arbitrarily. Further, the number of transmission units including the same third data can be arbitrarily set, for example, 1, 2, 3,...

(6) The first period and the second period are not limited to 0.01 seconds and 1 second, and can be set as appropriate as long as the condition of the magnitude relationship between them is satisfied.
(7) The number of transmission units including the same second data may be different depending on the type of the second data. For example, for the heart rate, the number of transmission units including the same second data can be set to 2, and for the pulse rate, the number of transmission units including the same second data can be set to 3.

DESCRIPTION OF SYMBOLS 1 ... Living body monitor apparatus, 3 ... Electrocardiogram electrode, 5 ... Oxygen saturation sensor, 7 ... Acceleration sensor, 9 ... Temperature sensor, 11 ... ECU, 13 ... Input IF, 15 ... Calculation part, 17 ... Output IF, 101 ... Central monitor 103 ... Input IF 105 ... Display device 107 ... Notification device

Claims (12)

First data acquisition means for acquiring first data relating to a living body in a first cycle;
Second data acquisition means for acquiring second data relating to a living body in a second period longer than the first period;
Data transmission means for transmitting data for each transmission unit including the first data and the second data;
With
The number of the transmission units including the same second data is larger than the number of the transmission units including the same first data ,
The biological monitor device characterized in that at least a part of the second data is calculated based on the first data .   The biological monitor apparatus according to claim 1, wherein a frequency corresponding to the first period is 40 Hz or more.    The biological monitor apparatus according to claim 1 or 2, wherein a frequency corresponding to the second period is 1 Hz or more.   The frequency at which the data transmission unit transmits the transmission unit is 1/10 or less of the frequency of a base timer in a CPU included in the biological monitor device. The biological monitor device described.   The living body monitor apparatus according to claim 1, wherein a frequency at which the data transmission unit transmits the transmission unit is 1 to 10 Hz.   The living body monitoring apparatus according to claim 1, wherein retransmission of the transmission unit is not performed.   The living body monitor apparatus according to claim 1, wherein the data transmission unit performs transmission by wireless communication.   The biological monitor device according to claim 1, wherein the first data includes one or more selected from the group consisting of an electrocardiographic potential, a pulse wave, and acceleration information.   9. The second data according to claim 1, wherein the second data includes one or more selected from the group consisting of heart rate, pulse rate, arterial oxygen saturation, body temperature, body position information, and activity amount information. The biological monitor device according to Item 1.   The second data includes one or more selected from the group consisting of heart rate, pulse rate, and arterial oxygen saturation, and one or more selected from the group consisting of body position information and activity amount information. The biological monitor device according to claim 9. Biological monitor according to any one of claims 1 to 10, wherein the data size of the first of said second data calculated based on the data is less than 1 data of the first data apparatus. The transmission unit is the with second data, the second time information at the time of data acquisition, or biological monitoring device according to any one of claims 1 to 11, characterized in that it comprises a measurement condition information .