JP2011098090A - Shunt murmur monitoring system and shunt murmur monitoring method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a shunt murmur monitoring system, when a dialysis patient undergoes a dialysis treatment, constantly measuring the shunt murmur of the dialysis patient and, when the blood pressure decreases, abnormality in a shunt portion is found or abnormal physical conditions occurs, allowing an abnormal state transmission section to issue various types of alarms; and to provide a shunt murmur monitoring method. <P>SOLUTION: This shunt murmur monitoring system 100 for the dialysis patient is constituted by sequentially connecting a sensor 2, a sensor amplifier 2, an electric signal integrator 3 and a shunt murmur intensity monitor 4. In this shunt murmur monitoring system, the sensor 1 is retained to an arm position of the dialysis patient, and the shunt murmur intensity monitor 4 includes a data computing section 41, a data storage section 42, a data display section 45, a data determination section 43 and the abnormal state transmission section 44. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a shunt sound monitoring system in which when a dialysis patient performs artificial dialysis, the blood pressure is constantly monitored, and when the blood pressure is lowered and abnormal, the abnormal state transmission unit can generate various alarms. The present invention relates to a shunt sound monitoring method.

  A conventional shunt sound monitoring system is disclosed in Patent Document 1. Patent Document 1 describes that a signal is obtained from a microphone arranged close to a shunt formation site, and an alarm is generated by a determination circuit of a detector.

Japanese Patent Laid-Open No. 5-115547

The shunt sound monitoring system described in Patent Document 1 has the following problems.
Regarding the blood pressure reduction of a dialysis patient, an alarm is generated from the microphone signal by the detector judgment circuit, but the alarm type is only a buzzer, and the alarm is not necessarily transmitted accurately. Moreover, although the microfin is attached to the patient's arm, it has been difficult to stably hold the microfin for a long time.

The problem of the present invention is that when a dialysis patient receives treatment for artificial dialysis, the dialysis patient always measures the shunt sound, and detects an abnormality in blood pressure decrease, an abnormality in the shunt region, or an abnormality in physical condition,
It is an object of the present invention to provide a shunt sound monitoring system and a shunt sound monitoring method in which an abnormal condition transmission unit in a shunt sound monitoring system can generate various alarms.

The shunt sound monitoring system of the present invention is a shunt sound monitoring system for a dialysis patient configured by sequentially connecting a sensor, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter. The sensor is held on the dialysis patient's arm, and the shunt sound intensity monitor is composed of a data calculation unit, a data storage unit, a data display unit, a data determination unit, and an abnormal state transmission unit. It is characterized by being.
The shunt sound monitoring system of the present invention is a shunt sound monitoring system for a dialysis patient configured by sequentially connecting a sensor, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter. The sensor is held on the dialysis patient's arm,
The shunt sound intensity monitor meter includes a data operation unit, a data storage unit, a data determination unit, and an abnormal state transmission unit.

The shunt sound monitoring system of the present invention includes a sensor, a dialysis patient probe gauze, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter that are sequentially connected to each other. In the sound monitoring system, the probe gauze for a dialysis patient is formed by laminating a biocontact gauze and a double-sided adhesive tape for sensor bonding, and penetrates the biocontact gauze and the double-sided adhesive tape for sensor to pass through a central portion. The sensor is held at the site of the dialysis patient's arm through the hollow hole of the dialysis patient probe gauze, and the shunt sound intensity monitor is a data calculation unit. A data storage unit, a data display unit, a data determination unit, and an abnormal state transmission unit.
Further, the shunt sound monitoring system of the present invention is for a dialysis patient comprising a sensor, a probe gauze for dialysis patient, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter sequentially connected. The probe gauze for dialysis patients is laminated with a biocontact gauze and a double-sided tape for sensor adhesion, and penetrates the biocontact gauze and the double-sided tape for sensor adhesion, A hollow hole is formed in the central part, and the sensor is held at the site of the dialysis patient's arm through the hollow hole of the probe gauze for dialysis patient. It is comprised by the calculating part, the data storage part, the data determination part, and the abnormal condition transmission part.

Here, in the shunt sound monitoring system, the abnormal state transmission unit generates sound, generates light, generates vibration, or transmits to a portable terminal.
In the shunt sound monitoring system, the electric signal integrator and the data display unit are integrated.
In the shunt sound monitoring system, the shunt sound sampled at intervals of 0.1 seconds or less is input to the electric signal integrator.

Here, in the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter, when the intensity of the average shunt sound calculated by the data calculation unit is in the range of 60 dB to 70 dB, the data determination unit However, the minimum blood pressure of the dialysis patient is lower than the lower limit, and it is determined that the blood pressure is abnormal, and the abnormal state transmitting unit is operated.
In the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter,
When the decrease per 10 minutes of the intensity of the average shunt sound calculated by the data calculation unit is in the range of 5 dB to 50 dB, the data determination unit has a tendency that the minimum blood pressure of the blood pressure of the dialysis patient tends to the lower limit. And determining that the abnormal state transmitter is in operation.
In the shunt sound monitoring system, when the average shunt sound calculated by the data calculation unit of the shunt sound intensity monitor is 10 dB or less, the data determination unit causes the shunt portion of the dialysis patient to stenosis. And determining that the abnormal state transmitting unit is activated.

In the shunt sound monitoring system, when the frequency spectrum of the shunt sound intensity calculated by the data calculation unit of the shunt sound intensity monitor meter has a peak of the shunt sound intensity in a frequency range of 800 Hz or more, The data determining unit determines that a stenosis is detected in the vicinity of the shunt portion coupling portion of the dialysis patient and the surrounding blood vessels, and activates the abnormal state transmitting portion.
Further, in the shunt sound monitoring system, when the intermittentness of 5 seconds or more is detected between the shunt sounds calculated by the data calculation unit of the shunt sound intensity monitor meter, the data determination unit displays the dialysis patient's In the shunt portion coupling portion and the vicinity of the surrounding blood vessels, it is determined as a precursor to stenosis, and the abnormal state transmitting portion is operated.

The shunt sound monitoring method of the present invention is a method for monitoring a shunt sound for a dialysis patient in which a sensor, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter are sequentially connected. The sensor is held on the dialysis patient's arm, and the shunt sound intensity monitor is composed of a data calculation unit, a data storage unit, a data display unit, a data determination unit, and an abnormal state transmission unit. To do.
The shunt sound monitoring method of the present invention is a method for monitoring a shunt sound for a dialysis patient in which a sensor, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter are sequentially connected. The sensor is held at a site of an arm of a dialysis patient, and the shunt sound intensity monitor is constituted by a data calculation unit, a data storage unit, a data determination unit, and an abnormal state transmission unit.

The shunt sound monitoring method of the present invention comprises a sensor, a dialysis patient probe gauze, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter that are sequentially connected to form a shunt sound for a dialysis patient. The probe gauze for dialysis patients is laminated with a biocontact gauze and a double-sided adhesive tape for sensor adhesion, and passes through the biocontact gauze and the double-sided adhesive tape for sensor adhesion to the central portion. The sensor is held in the dialysis patient's arm through the hollow hole of the dialysis patient probe gauze, and the shunt sound intensity monitor is connected to the data calculation unit and the data storage unit. A data display unit, a data determination unit, and an abnormal state transmission unit.
The shunt sound monitoring method of the present invention comprises a sensor, a dialysis patient probe gauze, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter that are sequentially connected to form a shunt sound for a dialysis patient. The probe gauze for dialysis patients is laminated with a biocontact gauze and a double-sided adhesive tape for sensor adhesion, and passes through the biocontact gauze and the double-sided adhesive tape for sensor adhesion to the central portion. The sensor is held in the dialysis patient's arm through the hollow hole of the dialysis patient probe gauze, and the shunt sound intensity monitor is connected to the data calculation unit and the data storage unit. And a data determination unit and an abnormal state transmission unit.

Here, in the shunt sound monitoring method, the abnormal state transmission unit generates sound, generates light, generates vibration, or transmits to a mobile terminal.
In the shunt sound monitoring method, the electrical signal integrator and the data display unit are integrated.
In the shunt sound monitoring method, a shunt sound sampled at intervals of 0.1 seconds or less is input to the electric signal integrator.

Here, in the shunt sound monitoring method, in the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter, the average shunt sound intensity calculated by the data calculation unit is in the range of 60 dB to 70 dB. The data determination unit determines that the dialysis patient's diastolic blood pressure is abnormal, and activates the abnormal state transmission unit.
Here, in the shunt sound monitoring method, in the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter, the average shunt sound intensity calculated by the data calculation unit is reduced per 10 minutes. Is within the range of 5 dB to 50 dB, the data determination unit determines that the blood pressure of the dialysis patient is in an abnormal tendency, and operates the abnormal state transmission unit.
Here, in the shunt sound monitoring method, when detecting the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter, the average shunt sound calculated by the data calculation unit of the shunt sound intensity monitor meter is 10 dB. In the following cases, the data determination unit determines that the shunt portion of the dialysis patient is stenotic and activates the abnormal state transmission unit.

Here, in the shunt sound monitoring method, when the frequency spectrum of the shunt sound intensity calculated by the data calculation unit of the shunt sound intensity monitor meter has a peak of the shunt sound intensity in a frequency range of 800 Hz or more, The data determination unit determines that a stenosis is detected in the vicinity of a dialysis patient's shunt unit coupling unit and the surrounding blood vessels, and activates the abnormal state transmission unit.
Further, in the method for monitoring shunt sound, when an intermittent of 5 seconds or more is detected during the shunt sound calculated by the data calculation unit of the shunt sound intensity monitor meter, the data determination unit is configured to detect the dialysis patient. In the shunt portion coupling portion and the vicinity of the surrounding blood vessels, it is determined as a precursor to stenosis, and the abnormal state transmitting portion is operated.

  According to the present invention, when a dialysis patient undergoes treatment for artificial dialysis, the dialysis patient's shunt sound is constantly measured to detect a blood pressure decrease abnormality, a shunt region abnormality, or a physical condition abnormality, and a shunt sound. The abnormal condition transmission unit in the monitoring system can provide a shunt sound monitoring system and a shunt sound monitoring method capable of generating various types of alarms.

  According to the shunt sound monitoring system according to any one of claims 1 to 5, the abnormal state transmission unit generates sound, generates light, or generates vibration, or transmits it to a mobile terminal. An alarm feature can be selected. The shunt sound monitoring system according to claim 1, wherein the shunt sound monitoring system is provided. Since the probe gauze for a dialysis patient is used, the sensor can be stably fixed to the arm of the dialysis patient, and the patient's shunt sound can be stably taken.

  According to the shunt sound monitoring system according to claims 8 to 11, the patient's abnormality is caused by the shunt sound intensity, the time lapse of the shunt sound intensity, the frequency characteristic of the shunt sound, or the intermittent characteristic of the shunt sound. It is now possible to monitor the patient's medical condition in detail.

1 is a block diagram of a shunt sound monitoring system according to a first embodiment of the present invention. It is a block diagram of the 1st example of the shunt sound intensity monitor meter in FIG. It is a block diagram of the 2nd example of the shunt sound intensity monitor meter in FIG. It is data which shows the relationship between the blood pressure of a dialysis patient, and shunt sound intensity. It is the data of the time passage of the shunt sound intensity of a dialysis patient. It is the spectrum analysis data of the shunt sound of a dialysis patient. It is an external view of the probe gauze for dialysis patients used in the present invention. Fig.7 (a) is a top view of the probe gauze for dialysis patients, FIG.7 (b) is AA sectional drawing in Fig.7 (a). It is explanatory drawing of the state which attached the front-end | tip part of the sensor 1 to the hollow hole 7 of the probe gauze 100 for dialysis patients used for this invention, and was fixed to the arm 9 of a dialysis patient. FIG. 8A is a view showing a state in which an antibacterial waterproof film 55 for preventing sensor rubber contamination is attached to the tip portion of the sensor 1, and FIG. 8B shows a state where the release paper portion 54 of the biological contact gauze 5 is peeled off. FIG. 6 is a diagram showing a state in which the probe gauze 200 for a dialysis patient is adhered to the arm 9 of the dialysis patient.

(Embodiment 1)
FIG. 1 is an explanatory diagram of a shunt sound monitoring system 100 according to Embodiment 1 of the present invention.
In FIG. 1, a shunt sound monitoring system 100 is configured by sequentially connecting a sensor 1, a sensor amplifier 2, an electric signal integrator 3, and a shunt sound intensity monitor meter 4.
Here, the sensor 1 is fixed in the vicinity of the shunt portion of the dialysis patient.
FIG. 2 is a block diagram of a first example of the shunt sound intensity monitor shown in FIG.
The shunt sound intensity monitor 4 includes a data calculation unit 41, a data storage unit 42, a data display unit 45, a data determination unit 43, and an abnormal state transmission unit 44.

The signal from the sensor 1 is amplified by the sensor amplifier 2 and the signal amplified by the electric signal integrator 3 is integrated.
The integrated signal from the electric signal integrator 3 enters the data calculation unit 41 of the shunt sound intensity monitor meter 4 and is calculated. The calculation result is stored in the data storage unit 42 and is also stored in the data determination unit 43. It is inputted and judged by a preset threshold condition.
If it is determined by the data determination unit 43 that the dialysis patient is in an abnormal state, the abnormal state transmission unit 44 generates sound, light, or vibration to the outside. Alternatively, transmission to a mobile terminal is performed.

  Here, the generation of sound, generation of light, generation of vibration may be generation of sound, generation of light, generation of vibration in a ward, or a nurse's station or a hospital monitoring room. Sound generation, light generation, and vibration generation may be used. As for the transmission to the mobile terminal, the patient's abnormal state is notified to the dedicated doctor in charge or the mobile terminal of the nurse.

Items that the data determination unit 43 determines are the absolute value of the shunt sound intensity, the temporal change of the shunt sound intensity, the shape of the frequency spectrum of the shunt sound intensity, or the intermittentness of the shunt sound.
Specifically, in the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter, when the average shunt sound intensity calculated in the data calculation unit is in the range of 60 dB to 70 dB, the data The determination unit determines that the minimum blood pressure of the dialysis patient is abnormal, and activates the abnormal state transmission unit.

Moreover, when the reduction | decrease per 10 minutes of the intensity | strength of the average shunt sound calculated in the said data calculating part exists in the range of 5 dB-50 dB, the said data determination part judges that the blood pressure of a dialysis patient has an abnormal tendency. Then, the abnormal state transmission unit is activated.
Alternatively, when the average shunt sound calculated by the data calculation unit is 10 dB or less, the data determination unit determines that the shunt portion of the dialysis patient is stenotic and activates the abnormal state transmission unit.
Alternatively, when the frequency spectrum of the shunt sound intensity calculated by the data calculation unit of the shunt sound intensity monitor meter has a peak of the shunt sound intensity in a frequency range of 800 Hz or more, the data determination unit is In the vicinity of the shunt portion coupling portion and the surrounding blood vessels, it is determined as a precursor to stenosis, and the abnormal state transmitting portion is activated.
In addition, when an interruption of 5 seconds or more is detected during the shunt sound calculated by the data calculation unit, the data determination unit causes a stenosis in the shunt connection part of the dialysis patient and in the vicinity of the surrounding blood vessels. Judgment is made as a precursor to occur, and the abnormal state transmitter is activated.

Thus, by detecting the absolute value of the shunt sound intensity, it is possible to detect that the minimum blood pressure in the blood pressure of the dialysis patient is lower than the normal range. Further, by detecting the time change of the shunt sound intensity, it can be predicted that the blood pressure of the dialysis patient is moving in the lower direction.
Furthermore, the abnormality of the shunt site | part of a dialysis patient can be detected by the detection of the frequency range which shows the peak in the frequency spectrum form of the calculated shunt sound intensity.

The data display unit 45 of the shunt sound intensity monitor meter 4 is usually integrated with the shunt sound intensity monitor meter 4 and can display the time change of the shunt sound intensity in particular, or other data such as shunt sound The frequency spectrum form of sound intensity can also be displayed.
In other cases, the data display unit 45 may be arranged independently of the shunt sound intensity monitor 4, and in particular, the data display unit 45 may be arranged integrally with the electric signal integrator 3. In this case, if the electric signal integrator 3 is attached to the dialysis patient's arm, the patient himself / herself can view the contents of the data display unit 45.

Regarding sampling of the signal of the electric signal integrator, in the present invention, sampling can be performed at intervals of 0.1 seconds or less. When sampling is performed at intervals of 0.1 seconds or less in this way, the waveform of the shunt sound on the data display unit 45 is clearly displayed.
(Embodiment 2)

A shunt sound monitoring system according to Embodiment 2 of the present invention will be described.
The monitoring system 100 is the same as FIG. 1 of the first embodiment.
However, the shunt sound intensity monitor meter is different from the first embodiment. FIG. 3 is a block diagram of a second example of the shunt sound intensity monitor in FIG. In the second embodiment, the shunt sound intensity monitor 4 includes a data calculation unit 41, a data storage unit 42, a data determination unit 43, and an abnormal state transmission unit 44. In the feature 2 of the present embodiment, the data display unit is not held.

  The signal from the sensor 1 is amplified by the sensor amplifier 2 and the signal amplified by the electric signal integrator 3 is integrated. The integrated signal from the electric signal integrator 3 enters the data calculation unit 41 of the shunt sound intensity monitor meter 4 and is calculated. The calculation result is stored in the data storage unit 42 and is also stored in the data determination unit 43. It is inputted and judged by a preset threshold condition. If it is determined by the data determination unit 43 that the dialysis patient is in an abnormal state, the abnormal state transmission unit 44 generates sound, light, or vibration to the outside. Alternatively, transmission to a mobile terminal is performed.

Here, the generation of sound, generation of light, generation of vibration may be generation of sound, generation of light, generation of vibration in a ward, or a nurse's station or a hospital monitoring room. Sound generation, light generation, and vibration generation may be used. As for the transmission to the mobile terminal, the patient's abnormal state is notified to the dedicated doctor in charge or the mobile terminal of the nurse.
The items to be determined by the data determination unit 43 are the absolute value of the shunt sound intensity, the change over time of the shunt sound intensity, the shape of the frequency spectrum of the shunt sound intensity, or the shunt sound intermittently. This is the same as the case of 1.
(Embodiment 3)

A shunt sound monitoring system according to Embodiment 3 of the present invention will be described.
FIG. 1 is an explanatory diagram of a shunt sound monitoring system 100 according to Embodiment 3 of the present invention.
In FIG. 1, a shunt sound monitoring system 100 is configured by sequentially connecting a sensor 1, a sensor amplifier 2, an electric signal integrator 3, and a shunt sound intensity monitor meter 4.
Here, the sensor 1 is fixed to the arm of the dialysis patient by a probe gauze for dialysis patient.
FIG. 7 is an external view of a dialysis patient probe gauze used in the third embodiment.
Fig.7 (a) is a top view of the probe gauze for dialysis patients, FIG.7 (b) is AA sectional drawing in Fig.7 (a).
The probe gauze 200 for a dialysis patient in FIG. 7 has a structure in which the double-sided tape 6 for sensor adhesion is bonded to the living body contact gauze 5 and the hollow hole 7 is opened in the central portion.
Here, the living body contact gauze 5 is configured by laminating an adhesive portion 51, a gauze portion 52, an aluminum foil portion 53, and a release paper portion 54.
Here, the gauze portion 52 is made of normal cotton. The double-sided adhesive tape 6 for sensor bonding is made of polyethylene resin.

  FIG. 8 is an explanatory diagram of a state in which the distal end portion of the sensor 1 is attached to the hollow hole 7 of the dialysis patient probe gauze 100 used in Embodiment 3 and fixed to the arm 9 of the dialysis patient. FIG. 8A is a view showing a state in which an antibacterial waterproof film 55 for preventing sensor rubber contamination is attached to the tip portion of the sensor 1, and FIG. 8B shows a state where the release paper portion 54 of the biological contact gauze 5 is peeled off. It is a figure of the state which adhered the probe gauze 200 for dialysis patients to the arm 10 of a dialysis patient. Thus, by using the probe gauze 200 for dialysis patients, the sensor 1 can be stably fixed to the arm 9 of the dialysis patient, and the shunt sound of the dialysis patient can be reliably measured.

  The shunt sound from the patient is converted into an electrical signal by the sensor 1 and connected to the sensor amplifier (shown in FIG. 1) via the signal line 9. In addition, the aluminum foil part 53 of the biocontact gauze 5 is in close contact with the skin of the arm 9 of the dialysis patient and has an action of making the skin potential around the sensor 1 uniform, so that the sensor 1 is stable, Contributes to collecting shunt sounds.

The signal from the sensor 1 is amplified by the sensor amplifier 2 and the signal amplified by the electric signal integrator 3 is integrated.
The integrated signal from the electric signal integrator 3 enters the data calculation unit 41 of the shunt sound intensity monitor meter 4 and is calculated. The calculation result is stored in the data storage unit 42 and is also stored in the data determination unit 43. It is inputted and judged by a preset threshold condition.
If it is determined by the data determination unit 43 that the dialysis patient is in an abnormal state, the abnormal state transmission unit 44 generates sound, light, or vibration to the outside. Alternatively, transmission to a mobile terminal is performed.

  Here, the generation of sound, generation of light, generation of vibration may be generation of sound, generation of light, generation of vibration in a ward, or a nurse's station or a hospital monitoring room. Sound generation, light generation, and vibration generation may be used. As for the transmission to the mobile terminal, the patient's abnormal state is notified to the dedicated doctor in charge or the mobile terminal of the nurse.

Items that the data determination unit 43 determines are the absolute value of the shunt sound intensity, the temporal change of the shunt sound intensity, the shape of the frequency spectrum of the shunt sound intensity, or the intermittentness of the shunt sound.
Specifically, in the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter, when the average shunt sound intensity calculated in the data calculation unit is in the range of 60 dB to 70 dB, the data The determination unit determines that the minimum blood pressure of the dialysis patient is abnormal, and activates the abnormal state transmission unit.

Moreover, when the reduction | decrease per 10 minutes of the intensity | strength of the average shunt sound calculated in the said data calculating part exists in the range of 5 dB-50 dB, the said data determination part judges that the blood pressure of a dialysis patient has an abnormal tendency. Then, the abnormal state transmission unit is activated.
Alternatively, when the average shunt sound calculated by the data calculation unit is 10 dB or less, the data determination unit determines that the shunt portion of the dialysis patient is stenotic and activates the abnormal state transmission unit.
Alternatively, when the frequency spectrum of the shunt sound intensity calculated by the data calculation unit of the shunt sound intensity monitor meter has a peak of the shunt sound intensity in a frequency range of 800 Hz or more, the data determination unit is In the vicinity of the shunt portion coupling portion and the surrounding blood vessels, it is determined as a precursor to stenosis, and the abnormal state transmitting portion is activated.
In addition, when an interruption of 5 seconds or more is detected during the shunt sound calculated by the data calculation unit, the data determination unit causes a stenosis in the shunt connection part of the dialysis patient and in the vicinity of the surrounding blood vessels. Judgment is made as a precursor to occur, and the abnormal state transmitter is activated.

Thus, by detecting the absolute value of the shunt sound intensity, it is possible to detect that the minimum blood pressure in the blood pressure of the dialysis patient is lower than the normal range. Further, by detecting the time change of the shunt sound intensity, it can be predicted that the blood pressure of the dialysis patient is moving in the lower direction.
Furthermore, the abnormality of the shunt site | part of a dialysis patient can be detected by the detection of the frequency range which shows the peak in the frequency spectrum form of the calculated shunt sound intensity.

The data display unit 45 of the shunt sound intensity monitor meter 4 is usually integrated with the shunt sound intensity monitor meter 4 and can display the time change of the shunt sound intensity in particular, or other data such as shunt sound The frequency spectrum form of sound intensity can also be displayed.
In other cases, the data display unit 45 may be arranged independently of the shunt sound intensity monitor 4, and in particular, the data display unit 45 may be arranged integrally with the electric signal integrator 3. In this case, if the electric signal integrator 3 is attached to the dialysis patient's arm, the patient himself / herself can view the contents of the data display unit 45.

Regarding sampling of the signal of the electric signal integrator, in the present invention, sampling can be performed at intervals of 0.1 seconds or less. When sampling is performed at intervals of 0.1 seconds or less in this way, the waveform of the shunt sound on the data display unit 45 is clearly displayed.
Example 1

FIG. 4 is data showing the relationship between the blood pressure of a dialysis patient and the shunt sound intensity measured by the shunt sound monitoring system of the present invention. The patient A may have a blood pressure of 50 or less. In this case, the intensity of the shunt sound is about 65 dB, and the shunt sound intensity is in an abnormal range. On the other hand, patient B has normal blood pressure. The data determination unit of the shunt sound intensity monitor meter detects that the patient A is abnormal and activates the abnormal state transmission unit. The abnormal state transmission unit generates sound, generates light, or generates vibration. Alternatively, transmission to the mobile terminal is performed.
(Example 2)

FIG. 5 is data of time course of shunt sound intensity of a dialysis patient. For patient D, a sharp drop in shunt sound intensity was observed after 60 minutes, and after 120 minutes, it was within the abnormal range of 60 dB to 70 dB. Thus, a decrease in blood pressure of a dialysis patient can be predicted by detecting the degree of decrease in shunt sound. On the other hand, patient C is normal.
The data determination unit of the shunt sound intensity monitor predicts an abnormality with respect to the patient D and operates the abnormal state transmission unit, and the abnormal state transmission unit generates sound, generates light, or generates vibration. Alternatively, transmission to the mobile terminal is performed.
(Example 3)

FIG. 6 is spectrum analysis data of a shunt sound of a dialysis patient. For patient F, the peak of the shunt sound intensity is in the region of 800 Hz or higher, which indicates that the blood vessel at the shunt site is narrow, and the data judgment unit of the shunt sound intensity monitor meter Regarding the patient D, an abnormality is predicted and the abnormal state transmission unit is activated, and the abnormal state transmission unit generates sound, generates light, generates vibration, or transmits it to the mobile terminal.
On the other hand, regarding the patient E, the peak of the shunt sound is in the region of 200 Hz to 500 Hz and is normal.

DESCRIPTION OF SYMBOLS 1 Sensor 2 Sensor amplifier 3 Electrical signal integrator 4 Shunt sound intensity monitor meter 41 Data operation part 42 Data storage part 43 Data determination part 44 Abnormal state transmission part 45 Display part 200 Dialysis patient probe gauze 5 Biological contact gauze 51 Adhesive tape Part 52 Gauze part 53 Aluminum foil part 54 Release paper part 55 Antibacterial waterproof film for sensor rubber contamination prevention 6 Double-sided tape for sensor adhesion 7 Hollow hole for sensor installation 8 Release paper for double-sided tape 9 Signal line 10 Arm of dialysis patient

Claims (24)

A shunt sound monitoring system for dialysis patients comprising a sensor, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter connected in sequence,
The sensor is held at the site of the dialysis patient's arm,
The shunt sound intensity monitor meter includes a data calculation unit, a data storage unit, a data display unit, a data determination unit, and an abnormal state transmission unit. A shunt sound monitoring system for dialysis patients comprising a sensor, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter connected in sequence,
The sensor is held at the site of the dialysis patient's arm,
The shunt sound intensity monitor meter includes a data calculation unit, a data storage unit, a data determination unit, and an abnormal state transmission unit. A dialysis patient shunt sound monitoring system comprising a sensor, a dialysis patient probe gauze, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter connected in sequence,
The probe gauze for a dialysis patient has a structure in which a biocontact gauze and a double-sided tape for sensor adhesion are laminated, and a hollow hole is formed in a central portion through the biocontact gauze and the double-sided tape for sensor adhesion And
The sensor is held on the dialysis patient's arm through the hollow hole of the dialysis patient probe gauze,
The shunt sound intensity monitor meter includes a data calculation unit, a data storage unit, a data display unit, a data determination unit, and an abnormal state transmission unit. A dialysis patient shunt sound monitoring system comprising a sensor, a dialysis patient probe gauze, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter connected in sequence,
The probe gauze for a dialysis patient has a structure in which a biocontact gauze and a double-sided tape for sensor adhesion are laminated, and a hollow hole is formed in a central portion through the biocontact gauze and the double-sided tape for sensor adhesion And
The sensor is held on the dialysis patient's arm through the hollow hole of the dialysis patient probe gauze,
The shunt sound intensity monitor meter includes a data calculation unit, a data storage unit, a data determination unit, and an abnormal state transmission unit. 5. The shunt sound according to claim 1, wherein the abnormal state transmission unit generates sound, generates light, generates vibration, or transmits the vibration to a mobile terminal. Monitoring system. The shunt sound monitoring system according to claim 1 or 3, wherein the electric signal integrator and the data display unit are integrated. 5. The shunt sound monitoring system according to claim 1, wherein a shunt sound sampled at intervals of 0.1 seconds or less is input to the electric signal integrator. In the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter,
When the intensity of the average shunt sound calculated by the data calculation unit is in the range of 60 dB to 70 dB,
5. The shunt sound monitoring system according to claim 1, wherein the data determination unit determines that the minimum blood pressure of the dialysis patient is abnormal and activates the abnormal state transmission unit. . In the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter,
When the decrease per 10 minutes of the intensity of the average shunt sound calculated by the data calculation unit is in the range of 5 dB to 50 dB,
5. The shunt sound monitoring system according to claim 1, wherein the data determination unit determines that the blood pressure of the dialysis patient is abnormal and activates the abnormal state transmission unit. . In the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter,
When the average shunt sound calculated by the data calculation unit of the shunt sound intensity monitor is 10 dB or less, the data determination unit determines that the shunt portion of the dialysis patient is stenotic and activates the abnormal state transmission unit. The shunt sound monitoring system according to any one of claims 1 to 4, wherein the shunt sound monitoring system is provided.   In the shunt sound monitoring system, when the frequency spectrum of the shunt sound intensity calculated by the data calculation unit of the shunt sound intensity monitor meter has a peak of the shunt sound intensity in a frequency range of 800 Hz or more, the data determination 5. The operation of the abnormal state transmitting unit according to claim 1, wherein the unit determines that the stenosis occurs as a sign of occurrence of stenosis in the shunt coupling part of the dialysis patient and in the vicinity of the surrounding blood vessels. Shunt sound monitoring system.   In the shunt sound monitoring system, when an intermittent of 5 seconds or more is detected between the shunt sounds calculated by the data calculation unit of the shunt sound intensity monitor meter, the data determination unit displays the shunt unit of the dialysis patient. The shunt sound monitoring system according to any one of claims 1 to 4, wherein the abnormal state transmitting unit is activated by determining that it is a sign of stenosis in the vicinity of the joint and its surrounding blood vessels. A method for monitoring a shunt sound for a dialysis patient comprising a sensor, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter connected in sequence,
Holding the sensor at the site of a dialysis patient's arm;
A shunt sound monitoring method comprising: the shunt sound intensity monitor meter including a data calculation unit, a data storage unit, a data display unit, a data determination unit, and an abnormal state transmission unit. A method for monitoring a shunt sound for a dialysis patient comprising a sensor, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter connected in sequence,
Holding the sensor at the site of a dialysis patient's arm;
A shunt sound monitoring method, wherein the shunt sound intensity monitor is composed of a data calculation unit, a data storage unit, a data determination unit, and an abnormal state transmission unit. A method for monitoring a shunt sound for a dialysis patient comprising a sensor, a probe gauze for a dialysis patient, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter in sequence,
The probe gauze for dialysis patients is configured by laminating a biocontact gauze and a double-sided adhesive tape for sensor adhesion, and penetrating through the biocontact gauze and the double-sided adhesive tape for sensor adhesion so that a hollow hole is opened in a central portion. age,
The sensor is held on the dialysis patient's arm through the hollow hole of the dialysis patient probe gauze,
A shunt sound monitoring method comprising: the shunt sound intensity monitor meter including a data calculation unit, a data storage unit, a data display unit, a data determination unit, and an abnormal state transmission unit. A method for monitoring a shunt sound for a dialysis patient comprising a sensor, a probe gauze for a dialysis patient, a sensor amplifier, an electric signal integrator, and a shunt sound intensity monitor meter in sequence,
The probe gauze for dialysis patients is configured by laminating a biocontact gauze and a double-sided adhesive tape for sensor adhesion, and penetrating through the biocontact gauze and the double-sided adhesive tape for sensor adhesion so that a hollow hole is opened in a central portion. age,
The sensor is held on the dialysis patient's arm through the hollow hole of the dialysis patient probe gauze,
A shunt sound monitoring method, wherein the shunt sound intensity monitor is composed of a data calculation unit, a data storage unit, a data determination unit, and an abnormal state transmission unit.   17. The abnormal state transmission unit performs generation of sound, generation of light, generation of vibration, generation of light, or transmission to a mobile terminal. How to monitor shunt sound.   The shunt sound monitoring method according to claim 13 or 16, wherein the electric signal integrator and the data display unit are integrated.   The shunt sound monitoring method according to any one of claims 13 to 17, wherein the electric signal integrator receives a shunt sound sampled at intervals of 0.1 seconds or less. In the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter,
When the intensity of the average shunt sound calculated by the data calculation unit is in the range of 60 dB to 70 dB,
18. The shunt sound monitoring method according to claim 13, wherein the data determination unit determines that the minimum blood pressure of the dialysis patient is abnormal and activates the abnormal state transmission unit. . In the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter,
When the decrease per 10 minutes of the intensity of the average shunt sound calculated by the data calculation unit is in the range of 5 dB to 50 dB,
The shunt sound monitoring method according to any one of claims 13 to 17, wherein the data determination unit determines that the blood pressure of the dialysis patient is in an abnormal tendency and activates the abnormal state transmission unit. . In the detection of the shunt sound intensity in the data calculation unit of the shunt sound intensity monitor meter,
When the average shunt sound calculated by the data calculation unit of the shunt sound intensity monitor is 10 dB or less, the data determination unit determines that the shunt portion of the dialysis patient is stenotic and activates the abnormal state transmission unit. The shunt sound monitoring method according to claim 13, wherein the shunt sound is monitored.   In the shunt sound monitoring system, when the frequency spectrum of the shunt sound intensity calculated by the data calculation unit of the shunt sound intensity monitor meter has a peak of the shunt sound intensity in a frequency range of 800 Hz or more, the data determination 18. The operation of the abnormal state transmitting unit according to claim 13, wherein the unit determines that the stenosis occurs as a sign of stenosis in the shunt portion coupling portion of the dialysis patient and the vicinity of the surrounding blood vessels, and activates the abnormal state transmission unit. To monitor the shunt sound of the camera.   In the shunt sound monitoring system, when an intermittent of 5 seconds or more is detected between the shunt sounds calculated by the data calculation unit of the shunt sound intensity monitor meter, the data determination unit displays the shunt unit of the dialysis patient. The shunt sound monitoring method according to any one of claims 13 to 17, wherein the abnormal state transmitting unit is operated by determining that it is a sign of stenosis in the vicinity of the joint and its surrounding blood vessels.

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