JP2016036637A - Bowel sound measuring apparatus and bowel sound measuring method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bowel sound measuring apparatus and a bowel sound measuring method capable of grasping the change of bowel movement influenced by stress or the like.SOLUTION: Bowel sound measuring means 10 for measuring a subject's bowel sound and analysis means 20 for performing spectrum analysis of the sound signals measured by the bowel sound measuring means 10 are included. The analysis means 20 includes: a function to extract bowel peristaltic movement sound from the sound signals measured by the bowel sound measuring means 10; and a function to execute the spectrum analysis of the extracted bowel peristaltic movement sound. Since the bowel peristaltic movement sound is extracted from the sound measured by the bowel sound measuring means 10 and the spectrum analysis is executed, the condition of the bowel peristaltic movement can be grasped if the energy of the extracted bowel peristaltic movement sound is calculated. Therefore, the bowel condition and the change of it can be understood according to the bowel peristaltic movement.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a bowel sound measuring apparatus and a bowel sound measuring method. More particularly, the present invention relates to an intestinal sound measuring apparatus and an intestinal sound measuring method for measuring and analyzing sounds generated during intestinal movement such as irritable bowel syndrome.

  When the intestine moves, sound is generated as the contents of the intestine move. This sound varies depending on the state of the intestinal contents (amount, fluidity, degree of gas mixing). Even if there is an abnormality such as stenosis or inflammation in the intestine, or when the intestinal motility function is abnormal and the intestinal motility is increased or decreased, the normal nature of the sound (sound quality or sound quality) The frequency of occurrence is different. For this reason, a doctor or a nurse can grasp the state of the intestine by listening to the sound of the intestine through a stethoscope. For example, when intestinal obstruction (ileus) has occurred, a specific metallic sound (sound like a metal called Keen) is produced, so that the occurrence of intestinal obstruction can be grasped by listening to intestinal sounds.

  In recent years, a technique for measuring gastrointestinal sounds and evaluating gastrointestinal motility characteristics and the like has been developed instead of a doctor's examination using a stethoscope (Patent Document 1 and the like).

  Patent Document 1 discloses a sensor that can be disposed in the vicinity of a body region of a subject, configured to detect acoustic energy and generate at least one acoustic energy signal that represents the acoustic energy, and to process the acoustic energy signal. And a processing unit configured to determine the occurrence of at least one gastrointestinal parameter from the processing result. And gastrointestinal mixing, gastrointestinal emptying, gastrointestinal contraction, gastrointestinal events including gastrointestinal propulsion and gastrointestinal transit time, or gastrointestinal system upset including reflux disease, irritable enteropathy, ulcerative colitis, constipation, diarrhea, strong contraction group upset It is described that it is effective to adopt for determining gastrointestinal parameters and events.

Special table 2011-519663 gazette

  The above-mentioned patent document 1 grasps an abnormality based on the acoustic energy of the intestine only when an abnormality of the intestine occurs, and it is difficult to grasp the abnormality unless there is an abnormality in the intestine.

  On the other hand, functional diseases that cause symptoms such as diarrhea and constipation, such as irritable bowel syndrome, that cause abnormalities in the motor function of the intestine due to the effects of stress, etc., are abnormal in the intestine itself. In many cases, abnormalities in intestinal motility do not always occur, and it is difficult to objectively evaluate abnormalities in intestinal motility function in a short period of time due to daily fluctuations and the influence of the environment to be evaluated. is there. For this reason, in the technique of Patent Document 1, if it can be measured in the situation where symptom such as diarrhea or constipation occurs, it can be grasped that it is irritable bowel syndrome, but it is actually grasped that it is irritable bowel syndrome. Difficult to do.

  At present, in cases of irritable bowel syndrome, etc., the patient is diagnosed by self-reporting symptoms, but since it is self-reported, objective diagnosis is difficult. In addition, it is necessary to confirm that the intestine has no abnormality such as inflammation or tumor by examination with an endoscope or X-ray, and to prove that the symptom is caused by an abnormality in the intestinal motility function. Although effective, performing these invasive tests places a heavy burden on the patient.

  If objective information that can determine irritable bowel syndrome or the like can be easily obtained, it is desirable because irritable bowel syndrome or the like can be accurately diagnosed.

  In view of such circumstances, an object of the present invention is to provide an intestinal sound measuring apparatus and an intestinal sound measuring method capable of grasping a change in intestinal movement due to an influence of stress or the like.

(Intestinal sound measuring device)
The intestinal sound measuring device of the first invention comprises an intestinal sound measuring means for measuring the intestinal sound of a subject, and an analyzing means for spectrally analyzing the sound signal measured by the intestinal sound measuring means. The means has a function of extracting an intestinal peristaltic sound from a sound signal measured by the intestinal sound measuring means, and a function of performing a spectrum analysis of the extracted intestinal peristaltic sound.
The intestinal sound measuring device of the second invention is characterized in that, in the first invention, the intestinal sound measuring means measures sound in a state of non-contact or non-direct contact with the body of the subject.
In the first or second invention, the intestinal sound measuring device of the third invention comprises stress loading means for applying stress to a subject who measures intestinal sound when measuring the intestinal sound by the intestinal sound measuring means. It is characterized by.
(Intestinal sound measurement method)
The method for measuring bowel sounds of the fourth invention is characterized in that the bowel sounds of the subject are measured in a state where stress is applied to the subject who measures the bowel sounds.
The method for measuring bowel sounds of the fifth invention is characterized in that, in the fourth invention, after measuring the bowel sounds of the subject in a resting state, the bowel sounds of the subject are measured in a stress load state.
The method for measuring bowel sounds of the sixth invention is characterized in that, in the fourth or fifth invention, the bowel sounds are measured with the device for measuring the bowel sounds in a non-contact or non-direct contact state with the body of the subject. .

(Intestinal sound measuring device)
According to the first invention, since the intestinal peristaltic sound is extracted from the sound measured by the intestinal sound measuring means and spectrum analysis is performed, if the energy of the extracted intestinal peristaltic sound is obtained, the state of peristaltic movement of the intestine can be grasped. . Therefore, the state of the intestine and its change can be grasped based on the peristaltic movement of the intestine.
According to the second invention, since the sound is measured in a non-contact or non-direct contact state with the body of the subject, the burden on the subject can be reduced and the measurement is also simplified.
According to the third aspect, since stress can be applied to the subject, objective information for determining irritable bowel syndrome or the like resulting from the stress can be obtained.
(Intestinal sound measurement method)
According to the fourth invention, since the bowel sound can be measured in a state where stress is applied to the subject, even in a case where no abnormality occurs in the bowel sound at the time of measurement due to circadian variation or the influence of the measurement environment, Objective information for determining irritable bowel syndrome can be obtained.
According to the fifth aspect of the invention, since the intestinal sounds at rest and stress loading can be grasped, more preferable information for determining irritable bowel syndrome or the like caused by stress can be obtained.
According to the sixth invention, since the sound is measured in a non-contact or non-direct contact state with the body of the subject, the burden on the subject can be reduced and the measurement is also simplified.

It is a block diagram of the bowel sound measuring device 1 of this embodiment. It is the figure which showed an example of the installation place of an electronic stethoscope when an electronic stethoscope is used as the sensor 11 of the intestine sound measuring means. It is the figure which showed an example of the schedule which measures an intestinal sound with the intestinal sound measuring apparatus 1 of this embodiment. It is the figure which showed the other schedule which measures an intestinal sound with the intestinal sound measuring apparatus 1 of this embodiment. It is a figure explaining the fingertip volume pulse wave analysis. FIG. 6 is a diagram showing experimental results of Example 1. FIG. 6 is a diagram showing experimental results of Example 1. FIG. 6 is a diagram showing experimental results of Example 2. FIG. 6 is a diagram showing experimental results of Example 2.

The intestinal sound measuring device of the present invention is a device for measuring the sound of the intestine of a subject, and can appropriately grasp the peristaltic movement of the intestine.
In particular, the intestinal sound measuring device of the present invention can measure changes in the state of the intestine (such as the state of peristaltic movement of the intestine) due to the influence of stress or the like, such as irritable bowel syndrome, as a sound signal. It has the feature in doing so.

(Intestinal sound measuring device 1 of this embodiment)
The intestinal sound measuring device 1 of this embodiment includes an intestinal sound measuring means 10, an analyzing means 20, and a stress loading means 30.

(Intestinal sound measuring means 10)
The intestinal sound measuring means 10 includes a sensor 11 for measuring the intestinal sound of the subject and a transmission unit 12 that transmits a signal of the sensor 11 to the analyzing means 20.

  The sensor 11 can measure sound in a non-contact or non-direct contact state with the subject's body, such as a general microphone. The sensor 11 has a function of converting the detected sound into an electric signal (a sound signal referred to in the claims). In the present specification, non-contact with the subject's body means a state separated from the subject's body surface or clothes. The state of non-direct contact with the subject's body means a state where the subject's clothes are touched but not in contact with the subject's body surface.

  The transmission unit 12 has a function of transmitting an electrical signal detected by the sensor 11 to the outside. For example, in the case of a wired microphone or the like, a transmission device 12 corresponds to a cord and a device (circuit or the like) that supplies a signal from the sensor 11 to the cord. In the case of a wireless microphone or the like, a device (circuit or the like) that wirelessly transmits a signal from the sensor 11 to the outside corresponds to the transmission unit 12.

  The intestinal sound measuring means 10 is not particularly limited as long as it has a function of detecting sound, converting it into an electric signal, and transmitting the electric signal to the outside. In addition to the wired microphone and the wireless microphone described above, a mobile phone, a smart phone, and the like have the above functions, and therefore can be used as the intestinal sound measuring means 10.

  The position where the intestinal sound measuring means 10 is arranged is not particularly limited as long as it can measure the intestinal sound. If a mobile phone, a smart phone, or the like is used as the intestinal sound measuring means 10, it is possible to measure the intestinal sound even in a state of being placed in a breast pocket. Further, when the measurement is performed with the subject lying on his back, the sensor 11 of the intestinal sound measuring means 10 is disposed above the epigastric region or the umbilicus. Then, the intestinal sound can be efficiently detected by the sensor 11. When the sensor 11 of the intestinal sound measuring means 10 is disposed above the epigastric portion, an intestinal sound (intestinal peristalsis) equivalent to the intestinal sound (intestinal peristaltic sound) measured when a stethoscope is applied to the epigastric portion. Sound) can also be detected.

(Analyzing means 20)
The analyzing unit 20 analyzes the electrical signal transmitted from the intestinal sound measuring unit 10 and calculates the energy of the intestinal peristaltic sound included in the sound measured by the intestinal sound measuring unit 10. This analyzing means 20 has a function of extracting intestinal peristaltic sound (peristaltic sound extracting function) and a function of performing spectrum analysis of a sound signal (spectrum analyzing function).

(Peristaltic sound extraction function)
The peristaltic sound extraction function has a function of extracting intestinal sounds (intestinal peristaltic sounds) from the electrical signal transmitted from the intestinal sound measuring means 10. In other words, it has a function of removing a signal (noise) other than the enteric sound (enteric peristaltic sound) from the electrical signal transmitted from the intestinal sound measuring means 10. For example, the peristaltic sound extraction function has a function of removing low-frequency noise (for example, heart sounds and noises) included in the electrical signal with a filter (for example, a high-pass filter and a Butterworth filter). The method for removing noise by the peristaltic sound extraction function is not particularly limited, and various methods can be employed.

(Spectrum analysis function)
The spectrum analysis function has a function of performing spectrum analysis on the electrical signal from which noise has been removed by the peristaltic sound extraction function and calculating a power spectrum density. Specifically, it has a function of calculating the power spectral density during a certain period of the electric signal after noise removal. For example, a period during which intestinal sounds (intestinal peristaltic sounds) are considered to be measured is selected from the electrical signal. If the power spectrum density is calculated for the signal in that period, the power spectrum density including the energy of each frequency included in the intestinal sound (enteric peristaltic sound) can be grasped.

  The power spectrum density of the electric signal is calculated because the sound pressure of the intestinal sound (intestinal peristaltic sound) increases as the intestinal movement becomes active as compared with the normal time. That is, if the power spectrum density of intestinal sounds (intestinal peristaltic sounds) can be grasped, the state of intestinal movement can be grasped appropriately.

  In addition, in the electrical signal, when there are a plurality of periods during which intestinal sounds (intestinal peristaltic sounds) are considered to be measured, the function of summing the power spectrum density included in the intestinal sounds (intestinal peristaltic sounds) of all periods The spectrum analysis function may be included.

  Since the analyzing means 20 having the peristaltic sound extraction function and the spectrum analysis function is provided as described above, the state of peristaltic movement of the intestine can be grasped based on the energy of the extracted intestinal peristaltic sound. Therefore, the state of the intestine and its change can be grasped based on the peristaltic movement of the intestine.

(Stress loading means 30)
The stress loading means 30 has a function of applying stress to the subject who measures bowel sounds. When stress is applied, in the case of a healthy subject, sympathetic nerve predominates and the parasympathetic nerve is suppressed. Therefore, intestinal motility governed by parasympathetic nerves is suppressed, and bowel sounds (intestinal peristaltic sounds) usually decrease. However, in the case of a subject having an intestinal functional abnormality such as irritable bowel syndrome, the peristaltic movement of the intestine is not suppressed and becomes more active than usual. That is, by applying stress, it is possible to intentionally suppress the intestinal peristalsis of a healthy person and to activate (excessively activate) the intestinal peristalsis of a subject such as irritable bowel syndrome.

  As described above, in the intestinal sound measuring device 1 according to the present embodiment, stress is applied to the subject by the stress load means 30, thereby intentionally suppressing the intestinal peristalsis movement of a healthy person, and hypersensitivity. It is possible to make the intestinal peristalsis movement of a subject such as bowel syndrome activated (overactive). If the intestinal sound in that state is measured by the intestinal sound measuring means 10 and analyzed by the analyzing means 20, suppression or activation of the peristaltic movement of the intestine can be expressed using an objective index such as a numerical value or a graph. . Then, using the numerical value, the doctor can determine whether or not the subject has an intestinal functional disease such as irritable bowel syndrome. That is, the state of peristaltic movement of the intestine in a state where stress is applied, in other words, a state close to a state where symptoms such as irritable bowel syndrome have occurred, can be expressed using an objective index. Then, the doctor can more accurately determine whether or not the subject has an intestinal functional disease such as irritable bowel syndrome.

  Moreover, the intestinal sound resulting from the peristaltic movement of the intestine is measured, and the intestinal sound is measured in a state of non-contact with the subject's body or non-direct contact with the subject's body. Therefore, when grasping the state of peristaltic movement of the intestine, the burden on the subject can be reduced and the measurement can be simplified.

(Other examples of intestinal sound measuring means 10)
In addition, as described above, the intestinal sound measurement by the intestinal sound measuring means 10 is preferably performed by the sensor 11 that measures the sound in a non-contact or non-direct contact state with the subject's body. However, a device that directly contacts the subject's body (for example, an electronic stethoscope) may be used.

  Moreover, the sensor 11 of the intestinal sound measuring means 10 may be one or a plurality of sensors. For example, if intestinal sounds are measured using an electronic stethoscope, electronic stethoscopes are installed at three locations on the abdomen (see FIG. 2). Then, the advantage that an intestinal sound can be measured more accurately is acquired.

(Example of stress load means 30)
The stress loading means 30 is not particularly limited as long as it can load stress on the subject who measures bowel sounds. For example, as the stress load means 30, if a test subject is made to calculate and stress is applied, an appropriate load can be applied to the test subject in a relatively short time.

(Intestinal sound measurement method)
A method for measuring bowel sounds using the bowel sound measuring apparatus 1 of the present embodiment will be described.
Hereinafter, a method for measuring intestinal sounds according to the schedule shown in FIG. 3 will be described. This schedule is a schedule suitable for measuring both the intestinal sound resulting from the peristaltic movement of the intestine at rest and the intestinal sound resulting from the peristaltic movement of the intestine when stress is applied.

As shown in FIG. 3, the subject whose intestinal sound is to be measured is laid on his / her back in a bed or the like.
In that state, the sensor 11 of the intestinal sound measuring means 10 is arranged at a position vertically above the navel of the subject (for example, 20 cm), and the measurement preparation is completed.

  When the preparation for measurement is completed, the intestinal sound is measured by the sensor 11 of the intestinal sound measuring means 10 while the subject is at rest for a certain time (for example, 5 minutes). Then, the intestinal sound resulting from the peristaltic movement of the intestine at rest can be measured. The measured intestinal sound is analyzed by the analyzing means 20, and the power spectrum density when the intestinal peristaltic motion occurs during the measurement period can be grasped.

  When the measurement at rest is completed, stress is applied to the subject, and the bowel sound is measured by the sensor 11 of the bowel sound measuring means 10 for a certain time (for example, 5 minutes). Then, the intestinal sound resulting from the peristaltic movement of the intestine at the time of stress load can be measured. The measured intestinal sound is analyzed by the analyzing means 20, and the power spectrum density when the intestinal peristaltic motion occurs during the measurement period can be grasped.

  When the stress measurement is completed, the first set of measurements is terminated and the subject is allowed to take a break. Then, when there is a break for a certain time (for example, 3 minutes), the second set of intestinal sound measurement is started.

  The second set of bowel sounds is measured by the same method as the first set, and the measurement is completed when the measurement of the second set under stress load is completed.

  After performing the above measurements, comparing resting data with stress loading data, the doctor can objectively determine whether the subject is suspected of having irritable bowel syndrome based on the difference in bowel peristalsis. Judgment can be made based on actual data.

  In both cases of resting and stress loading, it can be considered that the influence before the start of measurement remains for a certain period immediately after the start of measurement. Therefore, in order to more accurately measure the bowel sound resulting from the peristaltic movement of the intestine at rest and during stress loading, as shown in the schedule shown in FIG. 4, the bowel sound is not measured for a certain period immediately after the start of measurement. It is desirable to use (or do not use it for analysis of bowel sounds even if measured).

  Moreover, the bowel sound measurement at rest is not necessarily performed. For example, when the bowel sound data in the resting state of the same subject has already been acquired, or when it can be compared with the bowel sound data of a general healthy person (person who does not have irritable bowel syndrome, etc.) Only the measurement at the time of stress load may be performed. Even in this case, the doctor can determine whether the patient has irritable bowel syndrome or the like by comparing the rest time and the stress load.

  In the above example, two sets of measurements are performed, but only one set of measurements may be performed. However, when a plurality of sets (two sets or three sets or more) are measured, average data can be obtained as compared with a case where only one set is measured. Then, when a doctor makes a diagnosis based on the obtained state of the bowel sound, it can be determined whether or not the irritable bowel syndrome is appropriate. In the case where a plurality of sets of measurements are performed, it is desirable to acquire the break time as described above between each set.

  Using the intestinal sound measuring apparatus 1 of the present embodiment, it was confirmed whether or not data capable of diagnosing irritable bowel syndrome can be measured by measuring and analyzing the intestinal sound according to the schedules of FIGS. 3 and 4. The schedules in FIGS. 3 and 4 are the same intestinal sound measurement method but different in analysis method. That is, in the method of FIG. 3, all intestinal sounds were analyzed for 5 minutes when the first and second sets were resting and for 5 minutes when stress was applied. On the other hand, in the method of FIG. 4, it is considered that the change in intestinal sound (that is, peristaltic movement of the intestine) becomes larger in the latter half part at rest and stress loading, and measurement is started within 5 minutes each. 2 minutes later, analysis of intestinal sounds for 3 minutes was performed.

In the experiment, the intestinal sounds of a plurality of subjects were measured with an electronic stethoscope, the intestinal sound measurement data was divided into a plurality of periods, and the power spectral density was calculated by the ARMA system from the data of each period. And based on the power spectrum density of each period, it was confirmed whether the change of the intestinal peristaltic movement resulting from stress had arisen.
In addition, several test subjects performed about 10 test subjects (SIBS) with a possibility of irritable bowel syndrome, and 10 test subjects (Non-SIBS) with no possibility of irritable bowel syndrome.

Whether a change in intestinal peristalsis caused by stress occurs, it is determined based on the value of the average rate C _B of total energy obtained by the following equation.
Note that Eb is the total energy for each period of the signal determined from the power spectrum density as the sound of the intestinal peristalsis. The total Eb at the first set rest is E _r1 , the total Eb at the first set stress is E _s1 , the total Eb at the second set rest is E _r2 , the second set stress the sum total of the load at the time of Eb was _{E s2.}

C _B = (C _B1 + C _B2 ) / 2
C _B1 = (E _s1 + E _r1 ) / E _r1 × 100
C _B2 = (E _s2 + E _r2 ) / E _r2 × 100

In addition to the measurement of intestinal peristaltic sound, fingertip volume pulse wave was measured, and fingertip volume pulse wave analysis was also performed. In the fingertip plethysmogram analysis, a minimum peak interval shorter than between the peaks of one pulse is set, peaks identified by a distance shorter than the minimum peak interval are ignored, and the relative pulse wavelength T _{rs in} FIG. If it is smaller, it is judged that the person feels stress.
Note that T _{e, r} is an average pulse wavelength at rest, and T _{e, s} is an average pulse wavelength at stress load.

The results are shown in FIG.
FIG. 6A shows data related to a subject who is determined to be stressed by fingertip volume pulse wave analysis. These subjects, when performing bowel sounds measured in schedule 3, and check the value of the average rate C _B of total energy. Then, as shown in FIG. 6 (B), the subject is no possibility of irritable bowel syndrome, reduces the average rate of change C _B, is considered to intestinal peristalsis is suppressed. In contrast, in the subject of the possibility of irritable bowel syndrome has increased the average rate of change C _B, is considered to intestinal peristalsis is in active by stress.

Also, when performing bowel sounds measured in schedule 4, and check the value of the average rate C _B of total energy. Then, as shown in FIG. 7, the subject is no possibility of irritable bowel syndrome, the average rate of change C _B was decreased. In contrast, in the subject of the possibility of irritable bowel syndrome, the average rate of change C _B was increased. Moreover, the subject of the possibility of irritable bowel syndrome, a schedule with 3, subjects the average rate of change C _B is greater were seen.

  From the above results, if the bowel sound is measured according to the schedule as shown in FIGS. 3 and 4 using the bowel sound measuring device 1 of the present embodiment, there is a possibility that data capable of diagnosing irritable bowel syndrome can be measured. It was confirmed that there was.

  In the bowel sound measuring apparatus 1 of the present embodiment, it was confirmed whether or not the bowel sound can be measured with a non-contact sensor.

  In the experiment, using a recording microphone (RODE-NT55) and an electronic stethoscope (E-Scope 2), differences in intestinal sounds measured by both were confirmed.

The recording microphone was placed at a position 20 cm vertically above the umbilicus of the subject lying on his back, and intestinal sounds were measured.
Electronic stethoscopes were placed at the positions shown in FIG. 2 to measure intestinal sounds.

The results are shown in FIG. FIG. 8 shows the result of calculating the power spectral density by the ARMA system. In addition, a battery stethoscope is a measurement result of a right lower abdomen.
As shown in FIG. 8, the microphone has more back noise, but all of them show characteristic peaks in the vicinity of 400 Hz, and it was confirmed that similar results were obtained for both.

  Further, FIG. 9 shows the result of confirming what kind of sound is included in the intestinal peristaltic sound data (424 episodes) from the measured data. It is shown that the higher the HFrate, the more high frequency components are included in the episode.

  As shown in FIG. 9, it can be confirmed that the intestinal peristaltic sound recorded by the microphone contains a lot of high frequency components. On the other hand, in the electronic stethoscope, it can be confirmed that the intestinal peristaltic sound obtained in the epigastric region contains a lot of high frequency components. From this result, it is confirmed that when intestinal peristaltic sound is measured with a microphone, it is possible to measure data having characteristics similar to those of intestinal peristaltic sound obtained by a stethoscope placed in the epigastric region.

  From the above results, it was confirmed that even if intestinal sounds were measured in a non-contact manner using a microphone, data close to data measured by an electronic stethoscope was obtained. Moreover, it was confirmed that when the intestinal peristaltic sound was measured using a microphone, it was possible to measure a thing having characteristics similar to the intestinal peristaltic sound obtained by a stethoscope placed in the epigastric region.

  The intestinal sound measuring apparatus of the present invention is suitable for an apparatus for obtaining data for examining changes in the state of the intestine caused by the stress of a disease causing intestinal motor dysfunction such as irritable bowel syndrome.

DESCRIPTION OF SYMBOLS 1 Enteric sound measuring device 10 Intestinal sound measuring means 20 Analyzing means 30 Stress loading means

Claims (6)

Enteric sound measuring means for measuring the intestinal sound of the subject;
Analyzing means for spectral analysis of the sound signal measured by the intestinal sound measuring means,
The analysis means includes
A function of extracting the intestinal peristaltic sound from the sound signal measured by the intestinal sound measuring means;
And a function of performing spectrum analysis on the extracted intestinal peristaltic sound. The intestinal sound measuring means comprises
The intestinal sound measuring device according to claim 1, wherein the sound is measured in a state of non-contact or non-direct contact with the body of the subject. The intestinal sound measuring device according to claim 1 or 2, further comprising stress loading means for applying stress to a subject who measures intestinal sound when measuring the intestinal sound by the intestinal sound measuring means. A method for measuring an intestinal sound, comprising measuring the intestinal sound of a subject in a state where stress is applied to the subject who measures the intestinal sound. 5. The method for measuring bowel sounds according to claim 4, wherein the bowel sounds of the subject are measured in a stressed state after the bowel sounds of the subject are measured in a resting state. The intestinal sound measuring method according to claim 4 or 5, wherein the intestinal sound is measured with the device for measuring the intestinal sound being in a non-contact or non-direct contact state with the body of the subject.