JPH10295695A - Apnea detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apnea detector in sleeping which is a portable one, is eliminated any necessity for a testee to wear electrodes, etc., and is safety and easy to be handled, by providing a pressure sensing type respiration and body movement sensor and a sound sensor and recording data obtained from the respiration and body movement sensor and the sound sensor in a recorder. SOLUTION: A pressure sensing type respiration and body movement sensor 1 which detests the respiratory movement and the body movement caused by change in pressure applied on the sensor is generally arranged under the breast of a testee in bed. The sound sensor 2 detects the respiration sound such as a snore and is constituted for example, a microphone and a sound conditioner. The recorder 3 which records data obtained from the respiration and body movement sensor 1 and the sound sensor 2 prints or displays the data recorded in a magnetic storage medium or an electric record medium on a display, etc., by a data processing device 4 during or after recording so as to enable the confirmation.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an apnea detector and, more particularly, to a portable sleep apnea detector.

[0002]

2. Description of the Related Art Polysomnography (polysomnogr) is required for detecting apnea necessary for diagnosis of sleep apnea syndrome and the like.
aph) (hereinafter also referred to as PSG). PS
In G, basically, electroencephalogram, electromyogram, electro-oculogram, respiratory movement of the diaphragm and abdominal muscle (measured by a strain gauge attached to the chest), ventilation state (measured by a thermistor attached to the nostril) ), And biological information such as arterial blood oxygen concentration (measured by an ear oximeter attached to one earlobe) must be simultaneously and continuously recorded in the laboratory overnight, and the subject and examiner's The burden is not small. For example, since a subject wears many electrodes and measures in an examination room, it may be difficult to keep a record of natural sleep, and psychological and physical burdens on the subject may occur. Not a few. In addition, PSG recording requires an inspection room, various types of inspection equipment, and a technician with a certain level of skill or more in handling the equipment, and the technician may be forced to monitor all night. The cost of recording is quite high, and there is a limit to the number of subjects that can be recorded within a certain period of time.

[0003] Therefore, before performing PSG, it is simpler,
Home recording is also possible, and there is a great benefit from a reliable screening method. Such simple methods have been reported based on recordings with only an ear oximeter, those based on electrocardiograms and breath sounds from a macrophone attached to the pharynx, and those based on pulse oximetry and clinical evaluation. . However, most of these methods require some kind of electrodes to be worn on the body, and some methods allow recording at home, while others require recording in the laboratory, In addition, there is a method that requires time for data analysis after recording, and a method that can be satisfied as a simple type has not been defined at present. Furthermore, apnea is classified into three types: obstruction type, central type and peripheral type. However, most of the simple devices aim at detecting the obstruction type, and the discrimination from the central type is insufficient.

[0004]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems in the prior art, and is portable, has no electrodes to be attached to a subject, and is safe and easy to handle. It is an object to provide an easy sleep apnea detector.

[0005]

SUMMARY OF THE INVENTION The present invention provides an apnea detector employing a specific sensor to solve the above-mentioned problems.

That is, the apnea detector of the present invention comprises a pressure-sensitive respiration / body motion sensor, a sound sensor, and the respiration / body motion sensor.
It is characterized by comprising a body movement sensor and a recorder for recording data obtained from the sound sensor.

The apnea detector of the present invention preferably further comprises a data processing device for calculating an index effective for diagnosing sleep apnea from the data recorded in the recorder. The adoption of a pressure-sensitive respiratory / body movement sensor and a sound sensor eliminates the need to attach electrodes to the subject at all, making it easy to record at home, making it portable, and a closed type. It is possible to discriminate a certain type from a central type. In addition, if a data processing device is used, it is possible to arrange materials after recording in a short time.

[0008]

Embodiments of the present invention will be described below. FIG. 1 is a block diagram showing the configuration of an embodiment of the apnea detector of the present invention. A pressure-sensitive respiration / body movement sensor 1 and a sound sensor 2 are connected to a recorder 3. Further, the data processing device 4 is optionally connected to the recorder 3.
FIG. 2 shows a pressure-sensitive respiration / body motion sensor 1 and a sound sensor 2
And an example of the arrangement of the recording device 3.

Hereinafter, each component will be described. (1) Pressure-sensitive respiration / body motion sensor The pressure-sensitive respiration / body motion sensor 1 detects respiratory motion and body motion based on a change in pressure applied to the sensor. As the pressure-sensitive respiration / body movement sensor 1, a known sensor can be used. For example, a sensor using a piezoelectric element as a means for detecting a change in pressure is used. Sensors using piezoelectric elements are lightweight and advantageous to carry,
In addition, since a small change in the capacitance is sensed, almost no current flows, and even if the subject touches a cord or the like, there is no risk of electric shock and the subject is safe.

The respiratory / body motion sensor 1 is usually arranged below the chest of the subject in a lying state. Therefore, breathing
The shape of the body motion sensor 1 is preferably a flat plate from the viewpoint that the body motion sensor 1 can be easily arranged under a sheet or a blanket and its presence does not give a sense of discomfort to the subject. Respiration / body motion sensor 1
The size and arrangement are such that a pressure change can be detected over a width sufficient to reliably detect the respiratory movement even when the body position of the subject changes due to turning over or the like. For example, it has a size of 10 cm × 80 to 90 cm and is arranged in a direction crossing the bed. For convenience in carrying, it is preferable to use a plurality (preferably three) of appropriate size (for example, 10 cm × 20 cm), and arrange them in the width direction (FIG. 2). The plurality of sensors may be foldably connected to each other.

Since the respiration / body motion sensor 1 used in the apnea detector of the present invention is of a pressure sensing type, respiration and body motion can be detected without mounting electrodes on the body of the subject.

(2) Sound Sensor The sound sensor 2 detects a breathing sound such as snoring. For example, it is constituted by a microphone and a sound conditioner. A known microphone can be used, but an omnidirectional microphone is preferable. For example, an omnidirectional condenser microphone is used. Preferably, the microphone has a characteristic of sensing sounds of 20 Hz to 20,000 Hz at substantially the same level.
The sound conditioner converts an analog signal output of sound from a microphone into a digital signal, and a known one can be used. The power supply to the microphone may be provided by a sound conditioner. If the output of the microphone matches the input to the recorder 3, the sound conditioner may be omitted. Further, the current flowing through the microphone and the sound conditioner is very small, so that even if the subject touches a cord or the like, there is no risk of electric shock and the subject is safe.

The microphone has sufficient strength (for example, about -55d).
It is installed so that the sound of B) can be reliably recorded regardless of the level of the frequency. For example, about 4
Although it can be installed 0 cm above, the distance between the microphone and the nose is appropriately adjusted according to the sensitivity of the microphone and the like. In addition, the microphone may be fixed to a support that supports the microphone, and it is preferable that the support has a shape like a bedside light because it does not give a subject a sense of discomfort.

Since a sound sensor is used in the apnea detector of the present invention, information on ventilation can be obtained without mounting electrodes on the body of the subject.

(3) Recorder The recorder 3 records data obtained from the respiration / body movement sensor 1 and the sound sensor 2. As the recording device 3, a known recording paper recording type recording device having a plurality of channels can be used, but a portable recording device is preferable. In the case of a recording paper recording type, it is preferable to use a thermal type having a quiet operation sound so as not to hinder sleep even if the recording device is placed near the subject. The paper feed speed of the recording paper is, for example, 2.5 cm
The speed should be such that breathing sounds and body movements of about / min can be confirmed. In this case, the length of the recording paper becomes 12 m in the continuous recording for 8 hours.

The recording device 3 may be a device for recording on a magnetic storage medium or an electric storage medium such as a disk or a memory card. The data recorded on the magnetic storage medium or the electric storage medium can be confirmed during printing or after printing, or displayed on a display or the like, by the data processing device 4 described later.

The output of the respiration / body motion sensor and the output of the sound sensor are input to the recorder 3. The recording sensitivity is finely adjusted for each subject and for each channel before recording is started so that signals from each sensor can be optimally recorded. If necessary, a smoothing circuit and a bandpass filter (for example, HCF (high cut filter)) may be provided between the respiratory / body motion sensor and the recorder. These smoothing circuit and bandpass filter may be integrated with the piezoelectric element to form a breathing / body motion sensor.

The connection between the recorder 3 and the respiration / body movement sensor 1 and the sound sensor 2 may be a wired connection using a cable or a wireless connection using an electric wave or the like. In the case of a wired connection, it is advantageous to carry the cable when the cable is wound.

Next, a recording method using the apnea detector of the present invention will be described. The respiratory / body motion sensor 1 is installed beforehand under a sheet to lie down on the subject and adjust the distance between the nose of the subject and the sound sensor. The sensitivity of the recorder of the detector according to the invention is adjusted in the manner described above. The recording start time is adjusted to the bedtime of each subject, but is usually between 21:00 and 24:00. Recording is started by turning on the necessary equipment.

During recording, when leaving the examination room for urination, etc., an operation such as disconnecting the electroencephalograph from the electrode box is required for PSG, but no operation is required for the detector of the present invention. . The recording ends when the subject wakes up, usually between 5:00 and 9:00.

Sleep is a time period in which no body movement is continuously observed for 30 seconds or more. The total sleep time is obtained by adding the time determined as sleep. Guilleminault et al. (Ann. Rev. Me
According to the definition in d., 27: 465-484, 1976), apnea lasting more than 10 seconds during sleep is regarded as sleep apnea. Apnea index (apnea
index) is the number of sleep apnea per hour of sleep (number of sleep apnea / total sleep time). Of the apnea, the obstructive type is assumed to have respiratory movements but suppressed compared to previous and subsequent recordings, and the respiratory sounds are interrupted. In the central type, neither respiratory movement nor respiratory sound is observed. In the mixed type, there is no ventilation and the respiratory movement is completely stopped, but the respiratory movement is suppressed before and after that. In this way, as shown in the examples described later, a result substantially matching the result obtained by PSG is obtained. This degree of agreement is sufficient to use the test with the apnea detector of the present invention as a screening method. Further, the discrimination between the closed type and the central type can be performed in almost the same manner as the PSG.

Next, a data processing device 4 arbitrarily connected to the recorder 3 for processing data recorded in the recorder 3 and calculating an index effective for diagnosing sleep apnea will be described.

When the data processing device 4 is connected, a recorder that records data on a storage medium such as a disk or a memory card is used as the recorder 3. The storage medium may be a removable medium such as an MO disk or a PCMCIA memory card. The data processing device 4 processes the data recorded in the recording device 3 according to the above-described criteria, and calculates each index. The data processing device 4 includes an output unit, and outputs each index. The data processing device 4 may include input means such as a keyboard and printing means.

The connection between the recorder 3 and the data processing device 4 is as follows.
It may be after the recording is completed. The connection in this case also includes transferring a removable storage medium from the recorder 3 to the data processing device 4.

When the data processing device 4 is used, the recorder 3 and the data processing device 4 may be integrated. These are a CPU 5 for performing calculations, a storage device 6 such as a memory or a disk, an input device 7 such as a keyboard, an output device 8 such as a display, and I / O devices 9a, 9b, 9 9c. Here, the CPU 5, the storage device 6, and the I / O devices 9a and 9b correspond to the recorder 3, and
The U5, the storage device 6, and the output device 8 correspond to the data processing device 4.

The storage device 6 is an MO disk or PCMCI
It is preferable to provide a removable storage medium such as an A memory card. The I / O devices 9a, 9b, and 9c may perform necessary signal conversion such as analog-digital conversion, and all or a part of them may be configured as a PCMCIA standard card.

The I / O device 9a is connected to the respiration / body motion sensor 1, and the I / O device 9b is connected to the sound sensor 2.
Further, the printing device 10 may be connected to another I / O device 9c if necessary.

Hereinafter, an example of the operation will be described. Input device 7
Starts and ends recording. When recording is started, data input via the I / O devices 9a and 9b is stored in the storage device 6 under the control of the CPU 5. After the recording is completed, a program for processing the data according to the above criterion and calculating each index is read out from the storage device 6, and the CPU 5 executes the data processing. This program is stored in a portion of the storage device 6 that is different from the portion that stores data. The calculated indices are output by the output device 8 or output by the printing device via the I / O device 9c. Further, the data may be output as a graph recorded by a recording paper recording type recorder.

As the components constituting the apnea detector of the present invention, if it is lightweight and movable, it can be made portable, and if it operates at 100 V AC for home use, it becomes economical. In addition, if a recording paper recording type recording device is used, the operation can be easily confirmed. On the other hand, if a data processing device is used, each index can be easily calculated.

[0030]

EXAMPLES The present invention will be described more specifically with reference to the following examples. In addition, in an Example, the apnea detector of the Example of this invention is called "this invention detector" for convenience.

1. Subjects The subjects were examined at the Department of Psychiatry and Neurology at the University of the Ryukyus Hospital and the Sleep Disorders Center of the Urasoe General Hospital during the period from September 1992 to February 1994. Out of 400 people consulted for
Fifty persons were simultaneously tested by the apparatus of the present invention and subjected to PSG. 42 males, 8 females, 1 age
The age and mean deviation were 87.0-89 years, 47.0 ± 2.1 years. In addition, subjects were explained about this test, and those who gave consent were recorded.

2. Method (1) Inspection Using the Detector of the Present Invention As described below, the detector of the present invention was composed of a breath / body motion sensor, a sound sensor, and a recorder, and an inspection was performed.

As the respiratory / body motion sensors, three piezoelectric type respiratory / body motion sensors (SPR104 manufactured by NEC Corporation) were used. 1
Each piece is 9 cm long, 18 cm wide and 3 mm thick. As shown in FIG. 2, the respiration / body motion sensor was placed on a mat on a bed, a pad and sheets were put on the sensor, and the subject was laid on the bed. The three respiratory / body motion sensors were arranged side by side at a position where the center of the sensor approximately coincides with the line connecting the left and right nipples when the subject lies down. The subject hardly felt the presence of the respiratory / body motion sensor.

The sound sensor was composed of a microphone and a sound conditioner. The microphone used was an omnidirectional condenser microphone (SM90A manufactured by Schur). The size is 12.9 cm long,
It is 9.5 cm wide and 1.5 cm thick and weighs 600 g. This microphone has the characteristic of sensing sounds of 20 to 20,000 Hz at almost the same level. Further, a sound conditioner (manufactured by CELUX) was used to convert a sound analog signal into a digital signal. The size is 12.5 cm long, 8.0 cm wide, 3.2 cm thick
And the weight is 280 g. The output from the sound conditioner was directly input to the recorder. Power to the microphone was provided by the sound conditioner. At the time of recording, the microphone was placed about 40 cm above the head in the posture of lying on the floor. Under these conditions, a sound of about -55 dB or more could be reliably recorded regardless of the frequency.

The recorder is a four-channel general-purpose arc writing inkless recorder (Handy Recorder 8K manufactured by NEC Corporation).
32) was used. This recorder is 20cm long and 37c wide.
m, height 11.5cm, weight 7.5kg, easy to carry. The power source used was a household 100 V AC. The recording was of a thermal type, and the paper was fed by a motor, but the driving sound was quiet, and even if the recorder was placed near the subject's bed, it hardly affected sleep. The recording sensitivity was finely adjusted for each subject and for each channel before recording was started so that signals from each sensor could be optimally recorded. The paper feeding speed of the recording paper was 2.5 cm / min, and continuous recording was performed for 8 hours, and the length of the recording paper was 12 m.

The sleep was judged in a time period in which no body movement was continuously observed for 30 seconds or more. The total sleep time was obtained by adding the time determined as sleep. Guilleminault et al. (Ann. Re
v. Med., 27: 465-484, 1976).
Apnea lasting 0 seconds or longer was regarded as sleep apnea. Apnea index
(apnea index) was the number of sleep apnea per hour of sleep (number of sleep apnea / total sleep time). Of the apnea, the obstructive type was assumed to have respiratory movements but suppressed compared to the previous and subsequent recordings, and the respiratory sounds were interrupted. In the central type, neither respiratory movement nor respiratory sound was observed. In the mixed type, there was no ventilation and the respiratory movement was completely stopped, but there was suppression of the respiratory movement before and after that.

(2) Inspection by PSG The PSG was recorded in a hospital laboratory (semi-insulated) in accordance with the clinical electroencephalography test standard by the Japanese Electroencephalogram and Electromyography Society clinical electroencephalography test committee.

That is, in accordance with the International Electroencephalographic Society standard electrode arrangement method (10-20 method), both earlobes are used as reference electrodes with a time constant of 0.3 from the left central part (C ₃ ) and the right central part (C ₄ ). EEG was derived. An electrode attached to the upper eyelid and the outer edge of the orbit 2 cm,
Left and right eye movements were derived from the electrodes attached to the contralateral earlobes, and electromyograms were derived from the genital muscle. Electrocardiograms were recorded using a thermistor attached to the nostrils and mouth to check for ventilation, and to use a strain gauge on the thorax and abdomen to check for respiratory movement. In addition, the arterial blood oxygen saturation was recorded using a pulse oximeter for subjects who could measure it. Recorder paper feed speed is 15mm
/ Sec or 10 mm / sec. In principle, the speed was not changed during recording.

From the PSG records, Rechtshaffen and Kales (A
manual of standardized terminology, techniques and
scoring system stages of human subjects.Public H
ealth Service US Government Printing Office, Was
hington DC, 1967), one examiner with five years of experience in determining sleep stages was visually inspected every 20 seconds. Based on the result, the sleep stage for each minute was determined. The indices related to sleep were calculated based on the total sleep time and the presence or absence of sleep apnea (apnea lasting for 10 seconds or more during sleep), the number of times and the duration in one night for comparison with the test by the detector of the present invention in (1). And,
Sleep apnea can be classified as obstructive (no nostril and mouth ventilation, but not completely stopped with suppressed respiratory movement), central (no ventilation, complete respiratory movement) ) And mixed (no ventilation and completely stopped respiratory movement, but before and after that, there was suppression of respiratory movement), and the number and duration of each were calculated. . In addition, the number and duration of hypoventilation (repression of respiratory movement of 50% or more that lasted for more than 10 seconds during sleep) were determined. From these results, the number of times of sleep apnea combined with hypoventilation per hour of sleep (apnea,
The hypoventilation index (apnea-hypopnea index) was calculated.

(3) Practical Recording Method The subject entered the examination room about one hour before each individual's normal sleep onset time, and attached electrodes for PSG recording. The respiratory / body motion sensor of the detector of the present invention was previously set under a sheet, the subject was laid down, and the distance between the nose of the subject and the sound sensor was adjusted. The sensitivity of the recorder of the detector of the invention was adjusted in the manner described above. The recording start time was between 21:00 and 24:00, according to each subject's bedtime.

Recording by the PSG and the detector of the present invention was started at the same time. Regarding the recording by the detector of the present invention, the operation was simply to turn on the sound conditioner of the sound sensor and the power switch of the recorder. During recording, urination, etc.
When leaving the examination room, an operation such as disconnection of the electrode box and the electroencephalograph is required for PSG, but no operation was required for the detector of the present invention. The recording was terminated when the subject was awake, between 5:00 and 9:00.

(4) Statistical processing In order to examine the correlation between the results obtained by both the PSG and the recording of the detector of the present invention, a correlation table between two variables corresponding to each index was prepared, and the Pearson correlation coefficient was calculated. I asked. Furthermore, in order to examine the usefulness of the detector according to the present invention as a screening method, the sensitivity and specificity were determined as follows. That is, the apnea / hypoventilation index is taken for PSG, and the apnea index is taken for the detector of the present invention.
For each of the subjects, the subject was divided into less than 5 and 5 or more for 2 minutes, and the numbers of the subjects were determined as true positive, true negative, false positive, and false negative, respectively. From the respective numbers, the sleep apnea with the detector of the present invention was used. The sensitivity and specificity related to the diagnosis of the syndrome were determined by the following equations.

[0043]

## EQU00001 ## Sensitivity (%) = true positive / (true positive + false negative) .times.100 Specificity (%) = true negative / (false positive + true negative) .times.100

3. Results The average value and standard deviation of each index obtained by PSG were determined for 50 subjects. Total sleep time is 455.8 ± 76.4
Min, number of sleep apnea is 63.9 ± 90.6 for closed type, central type
5.9 ± 10.9 times, mixed type 11.7 ± 34.1 times, number of hypoventilation 38.5 ± 44.8 times, apnea / hypoventilation index 15.9 ± 18.5 times /
It was night.

According to the test using the detector of the present invention, the total sleep time was 459.0 ± 76.9 minutes, and the number of sleep apnea was 97.1 ± 1 of the obstructive type.
03.2 times, central type 4.6 ± 7.5 times, mixed type 17.8 ± 42.3 times, apnea index was 15.6 ± 18.1 times / night.

The correlation between the PSG and the results obtained by the detector of the present invention was determined for each index. As for the total sleep time, a high correlation was found with a correlation coefficient r = 0.889 (p <0.001). Regarding the number of sleep apnea, the correlation coefficients were respectively: obstructive r = 0.929 (p <0.001) and central r = 0.880.
(P <0.001), mixed r = 0.952 (p <0.001), and a correlation was observed for all types, but the correlation was slightly lower in the central type and higher in the mixed type. A correlation was obtained between the number of times of sleep apnea obtained by PSG and the hypopnea state combined with the total number of sleep apnea obtained by the detector of the present invention. The correlation coefficient was r = 0.966 (p < The correlation was high at 0.001). Apnea and hypoventilation index determined by PSG,
When a correlation was obtained for the apnea index obtained by the detector of the present invention, the correlation coefficient was r = 0.966 (p <0.001), and a high correlation was obtained.

Next, the sensitivity and specificity of the recording by the detector of the present invention in the diagnosis of sleep apnea syndrome were examined. At that time, the apnea / hypoventilation index was used in PSG instead of the apnea index. The reason is that the diagnostic criteria for sleep apnea are those in which REA sleep and non-REM sleep have more than 30 seconds of apnea episodes lasting more than 30 seconds during a 7-hour sleep, or that apnea is 5 per hour of sleep. Although it is specified that it occurs more than once, in recent years, not only apnea but also apnea does not occur, but there are many cases where respiratory movements of the chest and abdomen are suppressed by 50% or more ( Daug
las, NJ, Sleep (Cooper, R.), Chapman & Hall Medic
alm, Staffordshire, 272-273, 1994).

All subjects were evaluated for apnea and hypoventilation index (AHI) for PSG and apnea index (AHI) for the detector of the present invention.
When each value of I) was less than 5 and 5 or more, the results shown in Table 1 were obtained.

[0049]

[Table 1] Sensitivity and specificity of inspection by the detector of the present invention ────────────────────────── Recording by PSG AHI <5 AHI ≧ 5 total {Inspection by the detector AI <5 16016 of the present invention AI ≧ 5 3 3 1 3 4 4}計 Total 19 31 50 ──────────────────────── ──

Therefore, from the above equation, the sensitivity is 100%,
The specificity was calculated to be 84.2%. These values were sufficient for the purpose of screening for sleep apnea syndrome.

[0051]

As described above, according to the present invention,
It is portable and has no electrodes attached to the subject at all, it is safe,
A sleep apnea detector that is easy to handle is provided.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of a detector of the present invention.

FIG. 2 is a schematic diagram showing an example of an arrangement of a pressure-sensitive respiration / body motion sensor, a sound sensor, and a recorder.

FIG. 3 is a block diagram illustrating a configuration of an example of a recording device and a data processing device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Respiration / body motion sensor 2 Sound sensor 3 Recorder 4 Data processing device

Claims (2)

[Claims] 1. An apnea detector comprising a pressure-sensitive respiration / body motion sensor, a sound sensor, and a recorder for recording data obtained from the respiration / body motion sensor and the sound sensor. 2. An apnea detector further comprising a data processing device for calculating an index effective for diagnosing sleep apnea from data recorded in the recorder.