WO2016121247A1 - Biological information measurement system - Google Patents

Abstract

Provided is a system that can be easily purchased by a general consumer and can prevent the occurrence of cancer and other serious diseases through the household measurement of defecation gas. A system according to the present invention includes a subject-side device 6 provided in a toilet room and a server 12 capable of communicating with the subject-side device 6. The subject-side device 6 includes a sulfur-containing gas sensor 26 that reacts to sulfur-containing gas and outputs detection data and a transceiver 56 that transmits measurement data including the detection data for the sulfur-containing gas detected by the sulfur-containing gas sensor 26 to the server 12. The server 12 includes a database in which measurement data including detection data for the sulfur-containing gas detected by the sulfur-containing gas sensor 26 is associated with subject identification information and accumulated and stored together with defecation dates and times and a server-side data analysis means for analyzing the physical condition of a subject on the basis of the trend of the variation over time of the measurement data accumulated and stored in the database.

Description

Biological information measurement system

The present invention relates to a biological information measurement system, and more particularly, to a biological information measurement system that measures the physical condition of a subject based on defecation gas discharged into a bowl of a toilet installed in a toilet room.

In recent years, with the advancement of medical technology, the mortality rate due to cancer has become extremely low due to the diagnosis technology for major diseases such as cancer and the advancement of technology for cancer treatment itself. However, it is a burden for patients to go to the hospital to receive regular diagnosis for cancer prevention. For this reason, in reality, there are many patients who come to the hospital after realizing a poor physical condition, and unfortunately, there are still many people who get cancer. In addition, a practical device for suppressing the occurrence of cancer has not been developed yet, and in reality, it cannot be said to be sufficient for realizing cancer prevention.

In view of such a situation, the present inventors have made a device that can more easily diagnose major illnesses such as cancer at home without going to the hospital, and can really prevent major illnesses or realize early treatment. He had a strong desire to manufacture the equipment required by the market, and he had been researching for a long time.

Until now, the applicant has collected the defecation gas that is mounted on the toilet seat of a Western-style toilet and is discharged into the bowl when the subject defecates, and based on the concentration of carbon dioxide contained in the defecation gas, A device for obtaining the amount of excreted stool (see Patent Document 1) and a deodorizing device incorporated in the toilet seat of the flush toilet are sucked with a deodorizing device that is combined with the subject's stool, and the carbon dioxide concentration of the sucked gas is determined by carbon dioxide. An apparatus (see Patent Document 2) that estimates the intestinal state of a subject based on a gas sensor and based on the measured carbon dioxide concentration has been developed. However, these devices only estimate the current state of the intestine, and have not achieved the inventor's purpose of easily diagnosing a major disease such as cancer and grasping the risk status thereof. Furthermore, a fart detection device (Patent Document 3) is also known in which a gas sensor is disposed so as to come into contact with the air in the vicinity of a human excretion portion, and a fart is detected based on the peak value of the gas sensor output. In this fart detection device, the fart of the patient is collected by pulling out the tube from the excretion part in the diaper or underwear of the patient sleeping on the bed and sucking air with a suction pump. Furthermore, this fart detection device distinguishes farting from urination based on the half-value width of the peak of the gas sensor output, and the doctor confirms whether a fart has come out after cecal surgery or detects when to change diapers However, it does not achieve the purpose of the inventor. On the other hand, in Japanese Patent Application Laid-Open No. 2014-160049 (Patent Document 4), a sensor for measuring methyl mercaptan gas from a component of soot released by a subject, a calculation unit for calculating the concentration of methyl mercaptan gas obtained from this sensor, and a display A portable colorectal cancer risk measuring device for estimating the risk of developing colorectal cancer is known.

Japanese Patent Laid-Open No. 9-43182 (Patent Document 5) describes a biological monitor device. In this living body monitor device, a gas sensor is attached to a T-band made of cloth so that the gas sensor is disposed in the vicinity of the anus, and a fart discharged from the anus is detected. The signal from the gas sensor is transmitted to the processing device and stored in the memory. It is also known that data stored in a memory is compared with past data, and a warning is displayed on a display device when there is an abnormality such as when the difference is large.
Japanese Patent No. 3525157 (Patent Document 6) describes an intestinal gas component measurement method. In this intestinal gas component measurement method, a sampling tube is arranged in the toilet seat portion of the toilet bowl. When the person to be measured turns on the main switch of the apparatus, the suction pump is operated and the gas near the anus is sucked. The indicator gas detector constantly measures the concentration of carbon dioxide in the sucked gas, and when the measured concentration rapidly increases, the control / arithmetic processing unit recognizes that intestinal gas has been diffused. When the intestinal gas is released, another suction pump begins to operate, and a portion of the sucked gas is taken into the sample metering tube. The taken sample is sent to the column to separate the gas components and to be ionized. It is also known that the ionization amount is converted into an electric signal and the concentration of the detection target gas component in the intestinal gas is measured.
Japanese Unexamined Patent Application Publication No. 2014-206945 (Patent Document 7) describes a health information utilization system. In this health information utilization system, personal health information related to health management input from a terminal device is stored separately in a plurality of data center databases, and the analysis server device reads and analyzes the personal health information. The big data creation server device searches for personal health information under specific conditions, and creates and stores big data. Health information utilization system allows health contents based on knowledge in specialized fields to be browsed on terminal devices, stores and manages personal health information in multiple data centers, and health judgment results obtained by automatically judging personal health information Or, the health determination result determined by the expert is browsed on the terminal. Such things are also known.

Here, in developing a device capable of diagnosing a major disease such as cancer, for example, as described in Patent Document 4 described above, in recent years, a colorectal cancer disease and gas components in the intestine contained in a fart or defecation are used. It has been known that there is a correlation. Specifically, colon cancer patients have more methyl mercaptan gas containing sulfur components in gas components in the intestine than healthy individuals.

Japanese Patent No. 5131646 Patent No. 5019267 JP 2003-90812 A JP 2014-160049 JP-A-9-43182 Japanese Patent No. 3525157 JP 2014-206945 A

The gas component in the intestine is discharged as a fart or defecation gas together with the stool during defecation. Therefore, as described in the Nihon Keizai Shimbun on January 5, 2015, the inventors identified a fart discharged at the time of defecation and methyl mercaptan gas in the defecation gas as in the case of the above-mentioned Patent Document 4 and the like. I was able to detect colorectal cancer in the intestine by measuring the amount of gas. However, a measuring apparatus that can accurately measure only a specific gas such as methyl mercaptan gas is very expensive and large. In addition, the amount of methyl mercaptan gas contained in the defecation gas is very small, and it is very difficult to measure because it becomes a very small amount at the stage before cancer. At least such a gas analyzer that can measure accurately is used at home. The inventors faced the problem that it was not very realistic to install it in a toilet device and spread it as a consumer product, both in terms of cost and size.

However, the inventors want to reduce the number of people who are seriously ill such as cancer. To that end, we continued research with the very strong desire that general consumers need to make a device that can be easily purchased and diagnosed easily at home, and finally found a technical solution for its realization. is there.

The object of the present invention is to prevent general consumers from easily purchasing and measuring serious illnesses such as cancer by measuring fecal gas at home, or going to a hospital in a mild condition for treatment. It is to provide a highly practical diagnostic system that can be urged to be received and is truly required by the market.

The present invention relates to a biological information measuring system for measuring the physical condition of a subject based on defecation gas discharged into a bowl of a flush toilet, and a subject-side apparatus provided in a space where the flush toilet is installed And a server communicable with the subject-side device. The subject-side device includes a suction device that sucks the gas in the bowl from which the defecation gas has been discharged during the subject's defecation, and the gas sucked by the suction device Detection device which reacts with odorous gas other than methyl mercaptan gas and methyl mercaptan gas, which is an odorous gas containing sulfur component, and gas detection device which outputs first detection data, and subject identification which receives input of subject identification information Measurement data including the first detection data of the odorous gas detected by the apparatus, the control device for controlling the suction device and the gas detection device, and the gas detection device. The server transmits the measurement data including the first detection data of the odorous gas detected by the gas detection device in association with the subject identification information received by the subject identification device. The database that is accumulated and recorded along with the date and time of the action, the server-side data analysis means that analyzes the physical condition of the subject based on the temporal variation tendency of the measurement data accumulated and recorded in the database, and the analysis result by the server-side data analysis means And a server-side output device for outputting.

Conventionally, there has been no actual device for confirming whether a major illness such as cancer or the prevention of major illness exists other than diagnosis at a hospital. On the other hand, according to the present invention, a general consumer can easily purchase a subject-side device and measure it at home. Furthermore, since the defecation gas emitted during defecation is measured, there is no need for the subject to bother to perform a new measurement act. Can be prevented in advance, or can be treated by visiting a hospital in a mild condition. As described above, according to the present invention, it is possible to realize an apparatus that is truly required from the market and to provide a highly practical diagnostic system.

Here, before specifically explaining the effects of the present invention, a technical concept that enables a system that can be spread as a consumer product in a general household will be described. The key points lie in the idea of reversal and the knowledge of effective divestiture using the characteristics of major diseases such as cancer.

Specifically, first, one of the key points of the system of the present invention is the reversal idea that a subject side device installed in each home does not diagnose a serious illness such as cancer. In other words, the subject who is a general consumer who purchases the subject-side device does not want to know that he / she has cancer, but the risk of cancer is increasing at the stage before becoming cancer (hereinafter this stage is referred to as non-disease). Really, I really want to improve my life so that I don't get cancer. In other words, the device required for general households is thought to be valuable only in that a healthy person can accurately grasp cancer risk and improve physical condition so as not to get cancer.

Next, one of the key points of the system of the present invention is a device for diagnosing a specific type of cancer such as a specific rectal cancer, or a device capable of diagnosing an increased risk of a specific type of cancer. It is in the dilemma that it is not. This is because the subject is not worried about a particular type of cancer, such as rectal cancer, but is worried about any cancer. Therefore, the inventors do not have a commercial value unless a specific type of cancer is diagnosed, and think that there is no need for accuracy to specify the type of cancer, and can specify the type of cancer. It was decided that such measurement accuracy was unnecessary.

Next, one of the key points of the system of the present invention is the divisor that the diagnosis accuracy for each defecation may be extremely low. This is based on the idea that cancer is a disease that progresses over a long period of several years, and we realize that the chance of diagnosis extends over a long period of years. Therefore, if it is positioned as a device for reducing the risk that healthy people will get cancer, it will be noticed that there is virtually no problem even if the diagnostic accuracy is low once, and it is effective based on this. One of the keys is the regular cleaving.

Hereinafter, the specific effect of the system based on this invention constructed | assembled based on these knowledge and effective crevice is demonstrated.
In the present invention, since the subject's physical condition is analyzed by measuring the defecation gas discharged into the bowl of the toilet bowl, there is no need for the subject to bother to perform a measurement act, and defecation performed simply every day is usually performed. Diagnosis can be made simply by doing. In addition, since there is no hassle at all, the subject is not burdened, and measurement can be continued for a long period of time, so that information on changes in health status and a situation in which cancer risk is increased can be obtained with certainty.

Further, in the present invention, a sensor that reacts widely with odorous gases other than methyl mercaptan gas in the defecation gas is used without using a sensor for measuring methyl mercaptan gas at a pinpoint. When a sensor that measures methyl mercaptan gas in a pinpoint manner is used, it can be reliably detected that there is a correlation between the amount of methyl mercaptan gas and colorectal cancer, and the risk of cancer has increased. Is definitely known from the amount. However, this increases the risk of cancer to some extent, and if the amount of methyl mercaptan gas does not increase, it cannot be determined that the risk of cancer is increased, and is not suitable for the present invention for the purpose of preventing cancer. I realized that.

On the other hand, in the case of a sensor that reacts widely with odorous gas, it can be detected not only from an increase in cancer risk but also from a poor physical condition. Specifically, in a state where the risk of cancer has increased, a very strong odorous gas containing a sulfur component such as methyl mercaptan gas or hydrogen sulfide increases. And if it is a sensor which reacts widely with odorous gas, such an increase in gas can be detected without fail. In addition, as will be described later, although the amount of odorous gas may temporarily increase due to daily physical condition changes, in the case of cancer, an emergency that contains sulfur components such as methyl mercaptan gas and hydrogen sulfide. The state where the strong odor gas became strong lasts for a long time. For this reason, even if a sensor that reacts widely with odorous gases other than methyl mercaptan gas in defecation gas is used, if the gas amount is high over a long period of time, the risk of cancer is high and the risk of cancer increases. It can be determined that Thus, a sensor that also reacts widely with odorous gases functions in this respect in the same manner as a sensor that measures methyl mercaptan gas pinpoint.

Further, in the present invention, not only methyl mercaptan gas, but also a gas detection device that reacts to odorous gas in stool gas other than methyl mercaptan gas, only the amount of odorous gas in stool gas is known, The amount of methyl mercaptan gas cannot be measured, and the cancer state cannot be accurately identified. However, the inventors use a gas detection device that reacts not only with methyl mercaptan gas but also with odorous gas in defecation gas other than methyl mercaptan gas, so that healthy people have an increased risk of cancer. It has been found that it functions effectively as a device for preventing the risk of cancer and the risk of developing cancer. Specifically, a healthy person has a low total amount of odorous gases other than methyl mercaptan gas and methyl mercaptan gas. On the other hand, the total amount of odorous gases other than methyl mercaptan gas and methyl mercaptan gas temporarily increases due to deterioration of the intestinal environment, as well as cancer. Specifically, the deterioration of the intestinal environment is a deterioration of the intestinal environment due to factors such as excessive constipation, types of meals, lack of sleep, excessive drinking and overeating, excessive drinking, and excessive stress. However, all these factors are bad lifestyle habits. Cancer develops after bad lifestyle habits, but until now, even if the risk of cancer has risen, there is no way to recognize it, and as a matter of fact, many people now have a bad life with a good belief that they are all right Continuing customs.

As described above, when bad lifestyle habits as described above are performed, all or any of the odorous gases in the defecation gas such as methyl mercaptan, hydrogen sulfide, acetic acid, trimethylamine and ammonia increases. In contrast, the present invention is based on detection data of a gas detection device that detects not only methyl mercaptan gas but also odorous gas in stool gas other than methyl mercaptan gas such as hydrogen sulfide, acetic acid, trimethylamine, and ammonia. Is being analyzed. For this reason, the analysis results based on the total amount of odorous gas in the defecation gas reflect the results of the subject's poor physical condition and bad lifestyle habits, and the analysis results are based on physical conditions and lifestyle habits that increase the risk of such cancer. It can be used as an index based on objective data for improving cancer, that is, as an effective index for maintaining health and reducing the risk of developing cancer. For the purpose of improving lifestyle and suppressing cancer risk It has been found that it is an excellent effect that works extremely effectively.

As described above, according to the present invention, methyl mercaptan gas and odorous gas other than methyl mercaptan gas are measured, so that the cancer risk is in an increased state, and such a state is continued for a long time. The measurement which can notify a test subject of the suitable alarm which will become cancer is attained. The inventors have found a suitable finding for the purpose of reducing the number of people who become cancerous by the so-called reversal idea.

Furthermore, according to the present invention, since a sensor that reacts widely with not only methyl mercaptan gas but also odorous gas other than methyl mercaptan gas is used, the apparatus can be manufactured at low cost and provided as a consumer product. It became possible. This makes it possible for the subject to easily diagnose at home, prevent a serious illness such as cancer from occurring, or to promptly go to the hospital and receive treatment in a mild condition. It was able to meet the requirements sufficiently.

In addition, according to the present invention, since the defecation gas is measured by the daily normal action of defecation, even if the measurement accuracy of each time is low, the measurement data accumulated and stored in the database is used to prevent cancer. The accuracy of the analysis that the risk of becoming increased or that it is becoming cancer can be secured sufficiently.

Furthermore, in the present invention, since it is not a device that analyzes physical condition based only on measurement data of a single defecation action, it is necessary to accumulate long-term measurement data, and further, based on long-term measurement data Analysis is required. Incorporation of such a measurement data accumulation and analysis system into a device for a subject installed in each home becomes a factor of cost increase, and hinders widespread use of the device for a subject as a consumer product. In contrast, in the present invention, the measurement data is transmitted to the server and managed in the database, and the physical condition analysis is performed on the server side, so that the apparatus for the subject purchased by the consumer can be provided at low cost. It was. In addition, the accuracy of the physical condition analysis was dramatically improved by using the server.

In the present invention, preferably, the subject side device further includes a subject side data analysis device that analyzes the physical condition of the subject based on a trend of temporal variation of the measurement data, and a subject that outputs an analysis result by the subject side data analysis device. A side output device.

According to the present invention having such a configuration, the physical condition of the subject can be analyzed and output to the subject even in the subject-side apparatus, so that the burden on the server can be reduced by reducing the frequency of analysis and notification in the server. At the same time, the subject can quickly and easily improve daily life based on the display on the subject-side output device.

In the present invention, it is preferable that the gas detection device further reacts with a health gas composed of at least one of hydrogen gas, carbon dioxide, or methane gas contained in the gas sucked by the suction device, and performs the second detection. The data is output, and the second detection data of the health gas is included in the measurement data, and the analysis by the subject side data analysis device is simpler than the analysis by the server side data analysis means.

Detailed analysis of cancer diseases and the like is not a problem even if the frequency of diagnosis is low because cancer progresses over a long period of time. However, a very high accuracy is required. On the other hand, in order to improve life in a non-morbid state before cancer, it is desirable that the subject can quickly obtain physical condition analysis results every day during defecation. However, it is not realistic to perform a detailed analysis on the server side every day or to make a diagnosis by a doctor or the like based on the analysis result even in consideration of the server analysis burden and the doctor burden. In addition, in a system that performs analysis with high frequency and high accuracy on the server side, the usage fee of the system becomes high, and this is not realistic from this point. On the other hand, according to the present invention having the above configuration, cancer is a disease that develops after a long period of time, and the server-side analysis device and the subject-side device can effectively share roles. Thus, detailed analysis can be performed on the server side while suppressing an increase in the price of the subject side device. That is, according to the present invention having the above-described configuration, it is possible to provide an excellent practical system for major diseases such as cancer that can satisfy both of the above requirements. Specifically, the server-side analysis device and the subject-side data analysis device are functionally separated, and the server-side analysis device is provided with a low-frequency but high-accuracy medical diagnosis function, while the subject-side data analysis device has a cancer diagnosis function. A simple health management function that reveals that the risk of major illness such as the above has been increased, so that high-frequency notifications can be made even though it is a simple analysis. As a result, subjects can obtain physical information frequently and in a timely manner to manage their physical condition. On the other hand, although the frequency of detailed analysis on the server side is low, there is no influence because cancer progresses over a long period of time. On the other hand, by reducing the frequency of analysis on the server side, it was possible to analyze the cancer risk situation accurately while reducing the burden of analysis, and to notify the analysis result correctly. By separating the roles in this way, the server side can accurately grasp the detailed status of cancer diseases and the increase in cancer risk, and the subject side data analysis device can accurately judge daily changes in physical condition due to bad lifestyles. It was possible to encourage efforts to improve it.

Furthermore, in the present invention configured as described above, the physical condition is analyzed based on the first detection data of the odorous gas containing the sulfur component and the second detection data of the health gas. This is because the analysis accuracy is dramatically improved by performing analysis based on odorous gas and health gas containing sulfur component, and the risk of intestinal changes and cancer is increased even if simple measurement is performed. This is based on the excellent technical knowledge by the inventors that the accuracy of the analysis can be ensured. Specifically, the amount of odorous gas may temporarily increase or decrease due to changes in physical condition, but in a state where the risk of cancer is increased due to environmental changes in the intestine, The amount increases. In addition, the amount of health gas is surely continuously reduced so as to be inversely proportional to the increase in the amount of odorous gas. Therefore, using these relationships between the amount of odorous gas and the amount of healthy gas, all the defecation gas of the subject is collected, and the total amount of odorous gas in the subject is not accurately grasped. However, by performing analysis based on the odorous gas containing the sulfur component and the health gas, accurate physical condition analysis can be performed even with simple analysis. This makes it possible to detect changes in physical condition by simple analysis based on the relationship between odorous gas and health gas in defecation gas collected in a short period of time, and to accurately analyze that cancer risk is increasing. It is. According to the present invention based on this knowledge, it becomes possible to perform a useful analysis even when using a subject-side apparatus that performs a simple analysis installed on the subject side, and performs a simple analysis at a high frequency, It became possible to notify the physical condition with high frequency.

On the other hand, since the amount of odorous gas is very small, there is a problem in the measurement system and measurement accuracy considering the measurement error when analyzing with only odorous gas. In order to sufficiently ensure the reliability of the measurement data, a highly sensitive and very expensive odorous gas sensor is required, and it has been difficult to suppress an increase in the price of the system on the consumer side. According to the present invention having the above-described configuration, by using an analysis method based on the above-described technical knowledge found by the inventors, a simple odorous gas sensor can be obtained without using an expensive sensor. It was possible to ensure sufficient analysis reliability simply by adding a sensor for healthy gas, and dramatically improved the accuracy of physical condition analysis.

Moreover, in order to analyze both odorous gas and healthy gas, it is conceivable that the analysis load increases. In the present invention configured as described above, the subject-side apparatus uses the relationship between the two gases. Since simple analysis is used, it is possible to suppress the analysis load on the subject-side device. In addition, analysis on the server side can be performed sufficiently accurately even using data collected by an inexpensive odor sensor. Furthermore, according to the present invention having the above-described configuration, the accuracy of server-side analysis is improved by performing analysis based on odorous gas and health gas containing sulfur components, and misdiagnosis and useless hospital instructions are also provided in diagnosis by a doctor. Therefore, it is possible to prevent an unnecessary psychological burden on the subject, and a great merit is born to the subject.

In the present invention, preferably, the analysis result output from the server-side output device includes a determination result related to the specific disease, the analysis result output from the subject-side output device includes a history of measurement data, and the specific disease Does not include the determination results for.

The notification of the analysis result regarding the disease imposes a psychological burden on the subject, and is preferably performed based on a more accurate analysis. However, as described above, the analysis in the subject side data analysis apparatus is simple. According to the present invention having the above-described configuration, the analysis result by the subject-side output device does not include the determination result regarding the specific disease, so that no psychological burden is imposed on the subject. History is output. For this reason, the subject can grasp the physical condition change by confirming the data change, and if the data change occurs on the next day after performing bad lifestyle habits such as violent drinking and eating, the change amount can be directly grasped as a bad result based on the bad lifestyle. . For this reason, the test subject can change his bad lifestyle and be sure to improve his physical condition. Further, according to the present invention having the above-described configuration, since a more accurate analysis is performed on the server side, misdiagnosis and the like can be prevented. As described above, according to the present invention having the above-described configuration, analysis that requires high accuracy, such as cancer diagnosis, is performed in detail on the server side, and the subject-side device has the role of suppressing the risk of a healthy person becoming cancerous. With this ingenuity, we were able to build a practically superior system that could achieve a high level of diagnostic accuracy for cancer, etc. while realizing the price as a consumer product.

In the present invention, preferably, the subject-side data analysis device analyzes the physical condition of the subject based on data of a part of the measurement data during the defecation action, and the server-side data analysis means includes the measurement data The physical condition of the subject is analyzed based on data of a period longer than a part of the period during defecation.

The analysis of specific diseases such as cancer in the server-side analyzer is related to cancer and the amount of methyl mercaptan gas, so it is accurate to accurately measure the amount of odorous gas over a long period during defecation. It is desirable in terms of securing. On the other hand, the analysis in the subject-side device is a physical condition management that does not include the determination of disease, and as described above, since a method for analyzing by the correlation between odorous gas and health gas is found, it is generated in the body. There is no need to accurately grasp the total amount of odorous gas produced. Therefore, since the subject side apparatus can perform analysis based on the correlation between the amount of odorous gas in the gas collected in a short time and the health gas, analysis can be performed accurately and quickly without burden of analysis. By this useful discovery, effective cleaving was realized, and the analysis accuracy in the subject-side apparatus could be secured.

In the analysis on the subject side device, it is desirable to receive the result immediately after defecation. In other words, when performing analysis using all data during the period of defecation, the analysis will start after the defecation is over and preparation for exit is started. Convenience is very bad because there is a need to wait in vain until the results are received. However, according to the present invention configured as described above, since the analysis in the subject-side apparatus is performed only with data of a short specific period of the defecation action period, the analysis can be started during the defecation action. As a result, it is possible to receive the result immediately after the defecation act or immediately after the defecation act, and it is possible to avoid the state of waiting for the result in the toilet space when there is no morning time such as before going to work. . This effect in the system of managing the physical condition in the toilet space is a very useful unique effect.

In the present invention, preferably, measurement data for the whole period of the defecation action is recorded in the database, and the server-side data analysis means analyzes the physical condition of the subject based on the measurement data for the whole period of the defecation action.

There is a knowledge that the amount of methyl mercaptan gas produced in the body by cancer cells increases when cancer occurs. Since the server for disease determination analyzes based on the total amount of odorous gas during defecation, cancer diagnosis correlated with the amount of methyl mercaptan gas produced can be made more accurate, and accurate disease analysis can be performed. It becomes possible.

In the present invention, preferably, the subject-side data analysis device further includes a reliability determination unit that determines the reliability of the first detection data output from the gas detection device, and the subject-side data analysis device The physical condition of the subject is analyzed based on the measurement data in the period with high reliability determined by the reliability determination means.

In the present invention using a sensor that reacts widely with odorous components, the first detection data includes odorous gas components such as sweat and urine adhering to the subject, perfume, odor remaining in the toilet or toilet space attached to the toilet bowl. It is affected by gas, fragrance and alcohol sanitizer. In particular, when the perfume or fragrance is strong, or the body or toilet space is unsanitary, the measurement accuracy may decrease. In addition, when using immediately after the defecation of another person, it is highly likely that off-flavor components such as defecation gas or adhering odor of the person who used before remain in the toilet bowl or toilet space. It is conceivable that measurement is affected even if it is not a space. On the other hand, according to the present invention configured as described above, the reliability of the first detection data is determined by the reliability determination means, and the physical condition is analyzed based on the measurement data in the period with high reliability. The analysis of the physical condition in the analysis device can be made accurate and stable. In addition, it is possible to suppress misdiagnosis due to the influence of noise in the server-side analysis, and it is possible to prevent an unnecessary psychological burden on the subject.

In the present invention, preferably, the subject-side data analysis device identifies an initial defecation gas detection period during the defecation action period in the measurement data, and is based on the identified first defecation gas detection period data in the measurement data. Perform analysis.

Until now, since methylcaptan gas was produced by cancer cells, it was thought that a lot of this gas was discharged at the timing corresponding to the position of the cancer cells during the defecation period. I found a tendency to exhaust a lot of gas in the early days. This is considered to be due to the characteristic that gas is more easily discharged than stool during defecation and that the generated gas gathers near the anus with time. In the present invention based on this knowledge, since the analysis is performed based on the defecation gas discharged at the first time of the defecation action in the subject-side device, the accuracy of the physical condition analysis necessary for health management is greatly improved even with simple measurement. It was an improvement. Moreover, since the analysis can be started reliably during the defecation action period by performing a simple analysis with the first defecation gas, the analysis result can be reliably provided during the defecation action or immediately after the defecation action. The subject may be reluctant to view the analysis result if he / she has a bad lifestyle habit. However, according to the present invention, since the analysis result is provided during the defecation action or immediately after the defecation action, the subject always browses the analysis result. For this reason, it is possible to promote physical condition improvement even for a subject who is reluctant to view the analysis result.

In the present invention, preferably, the subject-side data analysis apparatus further includes a reliability determination unit that determines the reliability of the first detection data output from the gas detection apparatus, and the database records the reliability together with the measurement data. Then, the reliability is output to the server side output device together with the analysis result.

According to the present invention having the above configuration, since the reliability is output to the server side output device together with the analysis result, whether the analysis result is bad is caused by poor physical condition or noise caused by unsanitary environment or the like. It is now possible to accurately determine whether it is caused by an unnecessarily psychological burden. In addition, the subject can take actions such as cleaning the toilet bowl and removing perfume so that the subject can correct the noise himself, making it possible to perform more accurate diagnosis.

In the present invention, preferably, the subject-side device further includes an input device, the input device accepts input of defecation history information related to the defecation history status of the subject, and the database records the defecation history information together with the measurement data. The defecation history information is output together with the analysis result to the server-side output device.

For example, in the case of constipation, the generation of odorous component gas takes a long time, and the accuracy of diagnosis decreases. When the date and time of the measurement data recorded in the database is far away, it can be determined that the patient is constipated, and the possibility of misdiagnosis such as an increased cancer risk can be prevented. In addition, the subject does not necessarily defecate in the toilet provided with the subject-side device. According to the present invention having the above-described configuration, even when the date and time of measurement data recorded in the database is far away, it can be determined whether or not constipation is present, so that more accurate diagnosis can be performed. it can. Conversely, when defecation is performed at different locations, the amount of odorous gas contained in the defecation gas may be reduced. On the other hand, according to the present invention having the above configuration, even if the amount of the odorous gas this time is small, it is possible to prevent erroneous diagnosis of health. In the present invention for managing physical condition from defecation gas or judging cancer risk, since the amount of odorous gas is related to the time of stool held in the body, obtaining defecation history information according to the present invention It can be said that this is a very useful means for improving the diagnostic accuracy.

In the present invention, preferably, the subject side device further includes a stool state determination sensor that determines at least one of the stool volume and the stool state of the stool that the subject defecates, and the database includes the stool volume and the stool volume together with the measurement data. The flight status information including at least one of the flight statuses is recorded, and the flight status information is output to the server side output device together with the analysis result.

As the amount of stool increases, the amount of defecation gas generally increases, so an accurate physical condition analysis can be performed. In addition, when the stool is in a diarrhea state, it has been found by many verifications that the frequency of defecation increases and the amount of odorous gas generated decreases because the amount of water in the stool increases. According to the present invention having the above-described configuration, diagnosis can be performed in consideration of at least one of the stool volume and the stool state, so that an accurate diagnosis can be performed.

In the present invention, preferably, the subject-side data analysis device further includes a reliability determination unit that determines the reliability of the first detection data output from the gas detection device, and the subject-side device includes the reliability determination unit. If the determined reliability is low, measurement data is not transmitted to the server.

According to the present invention configured as described above, since transmission of data with low reliability to the server can be omitted, useless data transmission / reception and load on the server can be reduced.

In the present invention, preferably, the subject-side data analysis device analyzes the physical condition of the subject based on the measurement data recorded in the database of the server.

According to the present invention configured as described above, it is not necessary to provide a storage device for storing measurement data in the subject-side device, and the subject-side device can be provided at a lower cost.

In the present invention, preferably, the server constitutes new reference data serving as a reference for analysis by the subject-side data analysis device based on the measurement data stored and recorded in the database, and the reference of the subject-side data analysis device The data is updated to new reference data configured by the server.

There are individual differences in the amount of odorous and health gas containing sulfur components contained in defecation gas, and there may also be individual differences depending on the type of meal, amount of meal, amount of exercise, age, sex, etc. It was found by many verifications. If the reference data is fixed, it is difficult to suppress the influence of individual differences, and in some cases, there is a risk that unnecessary anxiety or conversely false security may be given to the subject. On the other hand, a lot of information is gathered on the server side and a detailed analysis is performed, and a diagnosis result by a doctor is also obtained. According to the present invention configured as described above, since the reference data in the subject side data analysis apparatus is updated from the server result to the one that best fits the subject, the analysis in the subject side data analysis apparatus is suppressed from the influence of individual differences. Since the data can be easily updated to the reference data, the subject can manage his / her health safely.

According to the present invention, general consumers can easily purchase and prevent serious diseases such as cancer due to measurement of fecal gas at home, or go to a hospital in a mild state to treat A highly practical diagnostic system that is truly required by the market can be provided.

It is a figure which shows the state which attached the biological information measuring system by 1st Embodiment of this invention to the flush toilet installed in the toilet room. It is a block diagram which shows the structure of the biometric information measurement system of 1st Embodiment of this invention. It is a figure which shows the structure of the gas detection apparatus with which the biological information measurement system of 1st Embodiment of this invention is equipped. It is a figure explaining the flow of the physical condition measurement by the biometric information measurement system of 1st Embodiment of this invention. It is a figure which shows an example of the screen displayed on the display apparatus of the remote control with which the biometric information measurement system of 1st Embodiment of this invention is equipped. It is a figure which shows an example of the physical condition display table displayed on the display apparatus of the remote control with which the biometric information measurement system of 1st Embodiment of this invention is equipped. It is a figure which shows an example of the movement by correction | amendment of the plot point of the newest data. It is a figure which shows the limit process with respect to the moving amount | distance of a plot point. It is a figure which shows an example of the diagnostic table displayed on the server side in the biometric information measurement system of 1st Embodiment of this invention. It is the graph which showed typically the detection signal by each sensor with which living body information measurement system 1 was provided in one defecation action of a subject. It is a figure explaining discharge | emission amount estimation of odorous gas in case the reference value of residual gas is not constant. It is a graph which shows an example of the detection value by an odorous gas sensor in case a test subject uses the alcohol-type toilet seat sanitizer. It is a figure which shows an example of the update of a diagnostic table. It is a figure for demonstrating the method of determining a measurement reliability. It is a figure which shows the test subject adhesion odor gas noise correction table for determining the influence of the odor gas adhering to a test subject's body and clothes. It is a figure which shows the humidity correction table for determining the influence of humidity. It is a figure which shows the temperature correction table for determining the influence of temperature. It is a figure which shows the excretion number correction table for determining the influence of an excretion number. It is a figure which shows the correction table which shows the relationship between the reliability recorded on the data analyzer, and the correction factor of a measured value. It is a figure which shows an environmental noise correction table. It is a figure which shows a reference value stability correction table. It is a figure which shows the disinfection toilet seat washing | cleaning correction table. It is a figure which shows the defecation gas total amount correction value table. It is a figure which shows a fart correction value table. It is a figure which shows the stool amount correction value table. It is a figure which shows a flight type correction value table. It is a figure which shows the defecation space | interval correction value table. It is a figure which shows a data accumulation amount correction table. It is a figure which shows an airflow correction value table. It is a diagram showing a CO ₂ compensation table. It is a figure which shows a methane gas correction table. It is a figure which shows a sulfide gas correction table. It is a figure which shows the relationship between the discharge time and discharge amount of each conditions S1, S2, and S3 from which the gas discharge total amount of defecation gas is constant, but discharge time and discharge amount (discharge density) per time differ. It is a figure which shows the detection waveform of the gas sensor at the time of changing discharge time and the discharge amount per time. The gas amount calculated based on the detection waveform of the gas sensor is shown. It is a figure which expands the time axis and shows the initial part of the detection waveform of a gas sensor shown in FIG. It is a graph which shows the relationship between the discharge amount (discharge density) per time, and the inclination of the rising of the detection data waveform detected by the sensor. Gas estimated based on the product of the slope of the detection waveform of the semiconductor gas sensor and the arrival time to the peak (gas sensor waveform area) for each of the conditions S1, S2, and S3 with different discharge time and discharge amount (discharge concentration) per time It is a figure which shows quantity. It is a figure which shows the state which attached the test subject side apparatus of the biological information measuring system by another embodiment to the flush toilet installed in the toilet room. It is a perspective view which shows the measuring apparatus of the test subject side apparatus shown to FIG. 37A. It is a figure which shows the structure of the suction device of another embodiment of this invention. It is a figure which shows the structure of the gas detection apparatus comprised so that the influence of hydrogen gas might be isolate | separated by shifting the arrival time to the odorous gas sensor of hydrogen gas and odorous gas by another embodiment of this invention. It is a figure which shows the detection waveform detected by the semiconductor gas sensor of the gas detection apparatus shown in FIG. It is a figure which shows the result of having measured the quantity of the health system gas and the odorous gas which are contained in the defecation gas of the healthy person under 60s, the healthy person of 60-70 generations, the patient of early cancer, and the patient of advanced cancer . It is the figure which compared the amount of gas before conversion of the hydrogen sulfide contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the total gas amount of the hydrogen sulfide contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the amount of gas before conversion of the methyl mercaptan gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the total gas amount of the methyl mercaptan gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the amount of gas before conversion of the hydrogen gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the total gas amount of the hydrogen gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the amount of gas before conversion of the carbon dioxide gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the total gas amount of the carbon dioxide gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the amount of gas before conversion of the propionic acid gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the total gas amount of the propionic acid gas contained in a defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the amount of gas before conversion of the acetic acid gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the total gas amount of the acetic acid gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the amount of gas before conversion of butyric acid gas contained in defecation gas with a healthy subject and a colon cancer patient. It is the figure which compared the total gas amount of the butyric acid gas contained in defecation gas with a healthy subject and a colon cancer patient.

Hereinafter, an embodiment of a biological information measurement system of the present invention will be described in detail with reference to the drawings.
Moreover, FIG. 1 is a figure which shows the state which attached the biological information measuring system by 1st Embodiment of this invention to the flush toilet installed in the toilet room. FIG. 2 is a block diagram showing a configuration of the biological information measurement system of the present embodiment. FIG. 3 is a diagram illustrating a configuration of a gas detection device provided in the biological information measurement system of the present embodiment.

As shown in FIG. 1, the biological information measurement system 1 includes a measuring device 6 built in a toilet seat 4 placed on a flush toilet 2 installed in a toilet room R, and a wall surface of the toilet room R. It has a subject-side device 10 consisting of an attached remote control 8. Furthermore, as shown in FIG. 2, the biological information measuring system 1 includes a server 12, a subject terminal 14 incorporating dedicated software in a smartphone, a medical institution terminal 16 installed in a medical institution such as a hospital, These perform part of the functions of the biological information measurement system 1 by exchanging data with the subject-side device 10. The server 12 and the medical institution terminal 16 accumulate measurement data transmitted from a large number of subject-side devices 10 and perform data analysis.

In the biological information measurement system 1 of the present embodiment, the physical condition state including the determination of cancer based on odorous gas containing sulfur component in the defecation gas released by the subject during defecation, particularly methyl mercaptan (CH ₃ SH) gas. Analyze. Furthermore, in the biological information measuring system 1 of the present embodiment, in addition to the odorous gas, the health-related gas is also measured, and the analysis accuracy of the physical condition is improved based on these correlations. The health-related gas is a gas derived from intestinal fermentation and increasing as the intestinal health level increases, and specifically, is a gas such as carbon dioxide, hydrogen, methane, and short chain fatty acid. In the present embodiment, carbon dioxide gas and hydrogen gas that can maintain high reliability of the health index measurement are measured as the health gas because it is easy to measure and has a large amount. Here, each subject apparatus 10 is configured to display the analysis result during or immediately after the subject's stool. On the other hand, in the server 12, measurement results from a large number of subjects are accumulated, and a more detailed analysis is possible by comparison with other subjects. As described above, in the biological information measuring system 1 of the present embodiment, simple analysis is performed in the subject-side apparatus 10 installed in the toilet room R, and more detailed analysis is performed in the server 12.

Here, the measurement principle of the physical condition in the biological information measurement system 1 of the present embodiment will be described.
It is reported in the literature that odorous gas containing sulfur components such as methyl mercaptan and hydrogen sulfide is discharged simultaneously with defecation from affected areas when suffering from cancer of the digestive system, particularly colorectal cancer. The digestive organs are the esophagus, stomach, duodenum, small intestine, large intestine, liver, pancreas, and gallbladder. The large intestine can also be classified into the appendix, cecum, rectum, and colon. . Cancer has little change every day and progresses gradually. As cancer progresses, the amount of odorous gas containing sulfur components, particularly methyl mercaptan, increases. That is, when the amount of odorous gas containing a sulfur component increases, it can be determined that cancer is progressing. Furthermore, in recent years, the idea of “non-disease” has spread, and the idea of improving the physical condition and preventing the disease when the physical condition deteriorates before becoming a diseased condition has spread. For this reason, it is required to detect cancer, particularly advanced cancer such as colorectal cancer, and improve physical condition before becoming cancer.

Here, in addition to hydrogen sulfide and methyl mercaptan, defecation gas excreted during defecation includes nitrogen, oxygen, argon, water vapor, carbon dioxide, hydrogen, methane, acetic acid, trimethylamine, ammonia, propionic acid, methyl disulfide, three Contains methyl sulfide. Among these, in order to determine a cancer disease, it is necessary to measure an odorous gas containing a sulfur-based component, particularly methyl mercaptan. Propionic acid, methyl disulfide, and trifluidized methyl contained in the defecation gas are very small amounts compared to methyl mercaptan, and can be ignored because they do not pose any problem for analysis of physical condition such as cancer determination. However, other gas components are not so small as to be negligible. In order to accurately determine cancer, it is naturally conceivable to use a sensor that can detect only odorous gas containing a sulfur component. However, since a sensor that detects only odorous gas containing a sulfur component is large and very expensive, it is difficult to configure it as a household device.

In contrast, as a result of earnest research, the inventors have not only detected methyl mercaptan in the defecation gas, but by using a gas sensor that detects odorous gas including other odorous gas, it is cheaper. The idea was that it could be configured as a household device. Specifically, the inventors use a general-purpose semiconductor gas sensor or solid electrolyte sensor that reacts not only with a sulfur-containing gas containing a sulfur component but also with other odorous gases as a sensor for detecting gas. It was.

In a state where the risk of cancer has increased, a very strong odorous gas containing sulfur components such as methyl mercaptan gas increases. And if it is a sensor which reacts widely with odorous gas like a semiconductor gas sensor and a solid electrolyte sensor, such an increase in gas can be detected without fail. However, as will be described later, sensors that react widely with odorous gases such as semiconductor gas sensors and solid electrolyte sensors, such as hydrogen sulfide, methyl mercaptan, acetic acid, trimethylamine, and ammonia that increase when they become unwell due to bad lifestyles. Odor gas is also detected. However, cancer is a disease that progresses over a long period of several years, and in the case of cancer, a state in which a very strong odorous gas containing a sulfur component such as methyl mercaptan gas or hydrogen sulfide is strengthened. It will last for a long time. Therefore, even if a general-purpose semiconductor gas sensor or solid electrolyte sensor that reacts not only with sulfur-containing gases containing sulfur components but also with other odorous gases is used, Therefore, it can be determined that the risk of cancer is high and the risk of cancer is increasing.

Also, semiconductor sensors and solid electrolyte sensors using oxidation / reduction reactions detect not only methyl mercaptan gas but also odorous gases such as acetic acid, trimethylamine, and ammonia in the defecation gas. However, as a result of experiments, the inventors have found that the amount of mixed odorous gases such as hydrogen sulfide, methyl mercaptan, acetic acid, trimethylamine, and ammonia increases when the physical condition deteriorates due to bad lifestyle, and the physical condition is good. It was found to show a decreasing trend. Specifically, a healthy person has a small total amount of odorous gases other than methyl mercaptan gas and methyl mercaptan gas. In contrast, the total amount of methyl mercaptan gas and other odorous gases other than methyl mercaptan gas is the amount of intestinal environment due to excessive constipation, types of meals, lack of sleep, overdrinking, excessive drinking, excessive drinking, and excessive stress. Temporarily increases due to deterioration.

The acetic acid in the defecation gas tends to increase not only when the physical condition deteriorates due to diarrhea or the like but also when the physical condition is good. That is, it does not necessarily coincide with the tendency of the amount of other odorous gases such as methyl mercaptan accompanying the above-described physical condition change. However, the amount of acetic acid contained in the defecation gas is very small compared to methyl mercaptan, and even if the amount of acetic acid increases when the physical condition is good, the increase is the decrease in other odorous gases. Very small compared to Furthermore, the increase amount of acetic acid when the physical condition deteriorates due to diarrhea or the like is much larger than the increase amount when the physical condition is good. Therefore, as a whole, the amount of odorous gas contained in the defecation gas increases when the physical condition deteriorates due to bad lifestyle, and tends to decrease when the physical condition is good. And since the intestinal environment deteriorates due to such bad lifestyle habits, it becomes cancer, so the amount of odorous gas contained in the defecation gas improves the physical condition while the cancer is unaffected Therefore, it becomes a suitable index.
In this embodiment, not only methyl mercaptan gas but also physical condition based on detection data of semiconductor sensors and solid electrolyte sensors that react to odorous gas in defecation gas other than methyl mercaptan gas such as hydrogen sulfide, acetic acid, trimethylamine, and ammonia. Analyze. As a result, an analysis result reflecting the results of poor physical condition and bad lifestyle habits is obtained, and this analysis result should be used as an index based on objective data for improving physical condition and lifestyle habits that increase cancer risk. Can do.

The defecation gas contains not only odorous gases but also H ₂ and methane. When semiconductor gas sensors or solid electrolyte sensors are used as gas sensors, these sensors also react with H ₂ and methane. End up. Furthermore, when a measuring device using a semiconductor gas sensor or a solid electrolyte sensor is set in each household, these sensors may react with a fragrance or perfume.
On the other hand, as will be described in detail later, the inventors use a hydrogen sensor, a methane sensor and a column to separate the influence of hydrogen and methane from the detection data of the semiconductor gas sensor and the solid electrolyte sensor, and We established a method for removing the effects of fragrances and perfumes as noise by detecting defecation behavior. In this way, the effects of hydrogen and methane are separated from the data detected by semiconductor gas sensors and solid electrolyte sensors, and furthermore, the effects of fragrances and perfumes are removed, and only the amount of odorous gas in the defecation gas is estimated. Became possible.

Further, the amount of methyl mercaptan and other odorous gases contained in the defecation gas is very small compared to H ₂ and methane. For this reason, even if a semiconductor gas sensor or a solid electrolyte sensor is used, the mixed gas amount of these odorous gases may not be measured accurately.
On the other hand, the inventors have a healthy intestinal environment that is acidic, but when they become cancer patients, an odorous gas containing a sulfur component is generated and the amount of the gas increases. In addition, the intestinal environment becomes alkaline, and the amount of bifidobacteria and the like is reduced, so that the amount of healthy gas such as CO ₂ , H ₂ , and fatty acid is inversely proportional to the increase in the amount of odorous gas We paid attention to the fact that it will definitely decrease continuously.
For this reason, the inventors do not necessarily have high measurement accuracy in each measurement, but the correlation between the amount of odorous gas such as methyl mercaptan and the amount of healthy gas components such as CO ₂ and H ₂ is calculated daily. We thought that the occurrence of advanced cancer could be detected by monitoring during defecation.

Therefore, the inventors measured the amount of healthy gas and odorous gas contained in the defecation gas of healthy persons under 60s, healthy persons in their 60s to 70s, patients with early cancer, and patients with advanced cancer. As a result, the result shown in FIG. 41 was obtained. That is, the defecation gas of a healthy person has a large amount of healthy gas and a small amount of odorous gas. On the other hand, the defecation gas of cancer patients has a small amount of healthy gas and a large amount of odorous gas. And the amount of the health system gas contained in the defeased gas of advanced cancer is decreasing compared with early cancer. Furthermore, when the amount of healthy gas and the amount of odorous gas are intermediate amounts between a cancer patient and a healthy person, it is considered to be a gray zone, that is, a non-disease state. For this reason, the inventors measure the gas amount of the health system gas and the gas amount of the odorous gas of the subject based on the above-mentioned knowledge, and think that the determination accuracy of the health state can be improved based on these correlations. It was.

Further, FIG. 42A to FIG. 48B show measurement data comparing various gas amounts contained in the defecation gas between healthy subjects and colon cancer patients (including advanced cancer and early cancer).
FIG. 42 is a diagram comparing the amount of hydrogen sulfide contained in the defecation gas between healthy subjects and colorectal cancer patients, FIG. 43 is methyl mercaptan gas, FIG. 44 is hydrogen gas, FIG. 45 is carbon dioxide gas, FIG. 46 is a graph comparing propionic acid gas, FIG. 47 is acetic acid gas, and FIG. 48 is a graph comparing the amount of butyric acid gas between a healthy person and a colon cancer patient. In each of these drawings, “A” indicates measurement data of each gas amount, a healthy person is indicated by a rounded plot, and a colon cancer patient is indicated by a triangular marked plot. In “B”, the average value of each measurement data is indicated by a bar graph, and the standard deviation of the measurement data is indicated by a line segment.

As is apparent from the measurement data of FIGS. 42A to 48B, the amount of various gases contained in the defecation gas varies greatly between healthy subjects and colorectal cancer patients, but odorous hydrogen sulfide gas and methyl mercaptan are present. Regarding gas, many data showing a large amount of gas are found in patients with colorectal cancer, and there is almost no data showing a large amount of gas in healthy individuals. On the other hand, with respect to hydrogen gas and carbon dioxide gas, many data showing a large amount of gas are found in healthy subjects, and almost no data showing a large amount of gas is seen in patients with colorectal cancer. In this way, the amount of odorous gas, which indicates the risk of colorectal cancer, contained in the defecation gas is large in colorectal cancer patients and small in healthy individuals, while hydrogen gas and carbon dioxide, which are healthy gases, are present. The amount of carbon gas is higher in healthy subjects and lower in colorectal cancer patients. Thus, the size relationship between the amount of odorous gas and the amount of healthy gas is reversed between healthy subjects and colorectal cancer patients. Although this measurement data shows that it is difficult to measure the physical condition of the subject sufficiently by measuring the amount of these odorous gases and health-related gases once, the relationship between the odorous gas and health-related gases can be measured within a predetermined period. It shows that the physical condition of the subject can be reliably measured by continuously measuring multiple times.

In addition, the inventors measured the defecation gas, and when performing a plurality of excretion actions (an act of discharging one fart or one stool) at the time of one defecation, the first excretion It was found that the amount of defecation gas discharged with the action was large and odorous gas was also included. Therefore, in the present embodiment, in order to accurately measure a trace amount of odorous gas, the health condition of the subject is analyzed based on the first stool gas. As a result, when measuring the amount of gas from the second and subsequent excretion actions, the effects of feces and farts excreted by the first excretion action may be affected.
The biological information measurement system 1 of the present embodiment is based on the measurement principle described above. The odorous gas in the following description includes methyl mercaptan gas, which is an odorous gas containing a sulfur component, and odorous gases such as hydrogen sulfide other than methyl mercaptan, methyl mercaptan, acetic acid, trimethylamine, and ammonia. It is a waste.

Next, a specific configuration of the biological information measurement system 1 of the present embodiment will be described in detail.
As shown in FIG. 1, the subject-side device 10 in the biological information measurement system 1 is attached to the flush toilet 2 in the toilet room R, and a part thereof is incorporated in the toilet seat 4 with a buttocks washing function. In the toilet seat 4 with a butt washing function, as a measuring device 6, there are a suction device 18 that sucks the gas in the bowl 2a of the flush toilet 2 and a gas detection device 20 that detects a specific component contained in the sucked gas. It has been incorporated. The suction device 18 also serves as a part of the function of a deodorizing device incorporated in the toilet seat 4 with a normal butt washing function. The gas sucked by the suction device 18 is deodorized by the deodorizing device, and then the bowl 2a. Returned in. Further, each device incorporated in the toilet seat 4 such as the suction device 18 and the gas detection device 20 is controlled by a control device 22 (FIG. 2) built in the toilet seat side.

As shown in FIG. 2, the subject-side device 10 includes a measurement device 6 incorporated in the toilet seat 4 and a data analysis device 60 built in the remote controller 8.
The measuring device 6 includes a control device 22 having a CPU 22a and a storage device 22b. The control device 22 includes a hydrogen gas sensor 24, an odorous gas sensor 26, a carbon dioxide sensor 28, a humidity sensor 30, a temperature sensor 32, an entrance detection sensor 34, a seating detection sensor 36, and a defecation / urination detection sensor. 38, toilet lid opening / closing device 40, nozzle driving device 42, nozzle cleaning device 44, toilet bowl cleaning device 46, toilet bowl sanitizing device 48, fragrance sprayer 50 as a fragrance injection device, and deodorized air The feeder 52, the suction device 18, the sensor heating heater 54, the transceiver 56, and the duct cleaner 58 are connected. As will be described later, the hydrogen gas sensor and the odorous gas sensor can be an integrated sensor.

The temperature sensor 32 measures the temperature of the catalyst such as the odorous gas sensor 26. The humidity sensor 30 measures the humidity of the gas sucked from the bowl 2a. The sensor sensitivity of these sensors varies slightly depending on the temperature of the catalyst. In addition, a change in humidity due to urination or the like similarly affects the sensitivity of the sensor. In the present embodiment, since the amount of odorous gas is very small, the toilet side is used in accordance with the temperature and humidity measured by these sensors 30 and 32 so that the minute amount of gas can be measured accurately and stably. The CPU 22a controls a sensor heating heater 54 and a humidity adjusting device 59 (FIG. 3), which will be described later, so as to accurately maintain the sensor temperature and suction humidity of the sensors 30 and 32 within a predetermined range, thereby determining the predetermined temperature and humidity environment. Adjust to. Note that these sensors and devices are not essential, and are desirably provided to improve accuracy.

The entrance detection sensor 34 is, for example, an infrared sensor, and detects entry / exit of the subject into the toilet room R.
The seating detection sensor 36 is, for example, an infrared sensor or a pressure sensor, and detects whether or not the subject is seated on the toilet seat 4.
In the present embodiment, the defecation / urine detection sensor 38 is constituted by a microwave sensor, and whether the stool or stool discharged by the subject is stool or whether the stool floats in the sealed water It is configured to detect the state of defecation such as whether it is sinking or whether the stool is diarrhea. Alternatively, the defecation / urination detection sensor 38 can be configured by a CCD, a water level sensor that measures the transition of the sealing water, or the like.

The toilet lid opening / closing device 40 is a device for opening / closing the toilet lid according to the situation based on a detection signal from the entrance detection sensor 34 or the like.
The nozzle drive device 42 is a device that is used for butt washing, and is a device that cleans the butt of the subject after defecation. The nozzle driving device 42 is configured to drive the nozzle to wash the flush toilet 2.
The nozzle cleaning device 44 is a device for cleaning the nozzles of the nozzle driving device 42. In this embodiment, hypochlorous acid is generated from tap water, and the nozzle is cleaned with the generated hypochlorous acid. It is configured.

The toilet flushing device 46 is a device for discharging water or tap water stored in a flush water tank (not shown) into the toilet bowl and washing the bowl 2a of the flush toilet 2. The toilet bowl cleaning device 46 is normally operated by the operation of the remote controller 8 by the subject and cleans the inside of the bowl 2a. However, as will be described later, the toilet cleaning device 46 is automatically operated by the control device 22 according to the situation.
The toilet sterilizer 48 generates, for example, sterilized water such as hypochlorous acid water from tap water, sprays the generated sterilized water onto the bowl 2a of the flush toilet 2, and sterilizes the bowl 2a. It is.

The fragrance sprayer 50 is a device for spraying a predetermined fragrance into the toilet room R. This is provided in order to prevent the subject from spraying an arbitrary fragrance into the toilet room R and spraying an odor component that would cause a measurement disturbance. By providing the fragrance sprayer 50, a fragrance that does not affect a predetermined measurement can be sprayed in a predetermined amount at a predetermined time according to the situation, and the biological information that the fragrance has been sprayed. The measurement system 1 can recognize it. Thereby, disturbance to the physical condition measurement is reduced and the analysis result is stabilized, so that the fragrance sprayer 50 functions as an output result stabilization unit.
The suction device 18 includes a fan for sucking the gas in the bowl 2a of the flush toilet 2, and the sucked gas flows through the detection unit such as the odorous gas sensor 26 and is then deodorized by the deodorizing filter. . The detailed configuration of the suction device 18 will be described later.

The deodorized air supply device 52 is a device that discharges air that has been sucked and deodorized by the suction device 18 into the bowl 2a.
The sensor warming heater 54 is for heating and activating a catalyst such as the odorous gas sensor 26. Each sensor can accurately detect a predetermined gas component by maintaining the catalyst at a predetermined temperature.
The duct cleaner 58 is a device for cleaning the inside of the duct 18a attached to the suction device 18 with, for example, hypochlorous acid obtained by electrolyzing tap water.

In the present embodiment shown in FIG. 1, the suction device 18, the deodorizing air supply device 52, and the duct cleaner 58 are integrally configured as a deodorizing device. That is, the gas in the bowl 2a is sucked into the duct 18a by the suction device 18, the sucked gas is deodorized by the deodorizing filter 78 (FIG. 3), and the deodorized gas is released into the bowl 2a again. Thereby, the gas reacting with the odor gas sensor 26 flows into the bowl 2a from the outside, and the gas component in the bowl 2a is prevented from changing due to factors other than the defecation gas discharged from the subject during the defecation period of the subject. Is done. Therefore, the deodorizing device and the deodorizing air supply device 52 provided with the deodorizing filter 78 function as output result stabilizing means. Alternatively, as a modified example, a measurement gas supply device (not shown) that allows gas that does not react with each gas sensor to flow into the bowl 2a is provided, and the measurement gas equivalent to the gas sucked by the suction device 18 is provided. The present invention can also be configured to flow into the bowl 2a. In this case, the measurement gas supply device (not shown) functions as an output result stabilization unit that stabilizes the analysis result.

Next, as shown in FIG. 2, the remote control 8 has a built-in data analysis device 60. The data analysis device 60 includes a subject identification device 62, an input device 64, a transceiver 66, and a display device. 68 and a speaker 70 are connected. In the present embodiment, the transceiver 66, the display device 68, and the speaker 70 function as an output device that outputs an analysis result by the data analysis device 60. The data analysis device 60 includes a CPU, a storage device, a program for operating these, and the like, and a database is constructed in the storage device.

In this embodiment, the input device 64 and the display device 68 are configured by a touch panel, and receive various inputs such as subject identification information such as the subject's name, and display various information such as physical condition measurement results. It has come to be.
The speaker 70 is configured to output various alarms, messages, etc. issued by the biological information measurement system 1.
In the subject specifying device 62, subject identification information such as the subject's name is registered in advance. When the subject uses the biological information measuring system 1, the registered subject is displayed on the touch panel, and the subject selects his / her name.

Furthermore, the transmitter / receiver 66 on the remote control 8 side is communicably connected to the server 12 via a network. For example, the subject terminal 14 includes a device capable of displaying received data, such as a smartphone, a tablet PC, or a PC.

The server 12 includes a defecation gas database. In the defecation gas database, measurement data including the amount of odorous gas and the amount of health gas in each defecation behavior in association with the subject identification information of each subject using the biological information measurement system 1, and reliability data And are recorded along with the measurement date. The server 12 stores a diagnostic table and has data analysis means. This server-side data analysis means is constituted by an electric circuit built in the server 12.
Furthermore, the server 12 is connected to a medical institution terminal 16 installed in a hospital, a health institution, or the like via a network. The medical institution terminal 16 is composed of a PC, for example, and can browse data recorded in the database of the server 12.

Next, the configuration of the gas detection device 20 built in the toilet seat 4 will be described with reference to FIG.
First, in the biological information measurement system 1 of the present embodiment, a semiconductor gas sensor is used as a gas sensor in the gas detection device 20 in order to detect odorous gas and hydrogen gas. Further, in order to detect carbon dioxide, the gas detection device 20 uses a solid electrolyte type sensor.
The semiconductor gas sensor has a catalyst made of a metal oxide film containing tin oxide or the like. When the catalyst is heated to several hundred degrees and the heated catalyst is exposed to a reducing gas, an oxidation / reduction reaction occurs between oxygen adsorbed on the surface and the reducing gas. The semiconductor gas sensor can detect the reducing gas by electrically detecting a change in the resistance value of the catalyst due to the oxidation / reduction reaction. The reducing gas that can be detected by the semiconductor gas sensor includes hydrogen gas and odorous gas. In this embodiment, the semiconductor gas sensor is used for both the sensor for detecting odorous gas and the sensor for detecting hydrogen gas. However, the catalyst used in the odorous gas sensor reacts strongly to the odorous gas. In addition, the components of the catalyst are adjusted so that the catalyst used in the hydrogen gas sensor reacts strongly with hydrogen gas.

As described above, in the present embodiment, the “semiconductor gas sensor” is used as the “odor gas sensor”. As described above, this “semiconductor gas sensor” is other than the methyl mercaptan gas to be detected. The general thing which reacts also widely with odorous gas is used. In addition, a solid electrolyte sensor can be used as an “odor gas sensor” as will be described later, but the solid electrolyte sensor also reacts widely with other odorous gases in addition to methyl mercaptan gas as with the semiconductor gas sensor. You can use a common one. In other words, a gas sensor that reacts only with methyl mercaptan gas is extremely difficult to manufacture, and even if manufactured, it becomes an extremely large and expensive gas sensor. If such a large and expensive gas sensor is adopted, a biological information measurement system is manufactured at a cost that can be sold as a consumer product, even if it can be realized as a medical device used in advanced clinical examinations. It becomes impossible. In the biological information measurement system of the present embodiment, a simple, general-purpose gas sensor that reacts to other odorous gases other than the methyl mercaptan gas to be detected is adopted as the “odorous gas sensor”. This makes it possible to realize a living body information measurement system as a consumer product. As described above, the gas sensor employed in the present embodiment is a sensor that also reacts with methyl mercaptan gas and odorous gas other than methyl mercaptan gas. It will be referred to as “odorous gas sensor”. Representative examples of the odorous gas to which the “odorous gas sensor” employed in this embodiment reacts include methyl mercaptan gas, hydrogen sulfide gas, ammonia gas, and alcohol-based gas.

In addition, the “odorous gas sensor” employed in the biological information measuring system 1 of the present embodiment is a sensor that reacts to other odorous gases in addition to the target methyl mercaptan gas, but will be described later. Due to various measures, even if such a gas sensor is used, it is possible to measure with sufficient accuracy as a consumer product. Specifically, in a toilet room where various odorous gases exist, data on defecation gas is extracted from the device for improving the measurement environment and detection signals from the gas sensor, assuming the defecation behavior of the subject. Ingenuity in data processing, even when detection data with a large error is obtained, ingenuity to prevent an excessive psychological burden on the subject can be mentioned. Details of each device point will be described later.

In the present embodiment, a case where a semiconductor gas sensor is used as a sensor for detecting odorous gas and hydrogen gas will be described. However, a solid electrolyte sensor may be used instead. The solid electrolyte sensor is a sensor that detects a gas based on an ion permeation amount that passes through the solid electrolyte by heating a solid electrolyte such as stable zirconia, for example. Gases that can be detected by the solid electrolyte sensor include hydrogen gas and odorous gas. In this embodiment, a solid electrolyte sensor is used as a sensor for detecting carbon dioxide. The carbon dioxide sensor is not limited to these, and an infrared method or the like may be used. A sensor for detecting carbon dioxide can be omitted.

As shown in FIG. 3, in the present embodiment, a gas detection device 20 is disposed inside the suction device 18.
The suction device 18 includes a duct 18a directed downward, an intake passage 18b oriented substantially in the horizontal direction, and a suction fan 18c disposed on the downstream side of the intake passage 18b. A duct cleaner 58 and a humidity adjusting device 59 are provided inside the duct 18a.
The gas detection device 20 includes a filter 72 disposed in the intake passage 18b, an odorous gas sensor 26, a hydrogen gas sensor 24, and a carbon dioxide sensor 28. As shown in FIG. 3, a filter 72 is disposed so as to cross the intake passage 18 b, and an odorous gas sensor 26, a hydrogen gas sensor 24, and a carbon dioxide sensor 28 are juxtaposed on the downstream side of the filter 72.

Further, a deodorizing filter 78 is provided on the downstream side of the odorous gas sensor 26, and the suction device 18 also functions as a deodorizing device by deodorizing the gas taken in by the deodorizing filter 78.
Further, a humidity adjusting device 59 is provided on the downstream side of the deodorizing filter 78. A moisture absorbent is enclosed in the humidity adjusting device 59, and when it is necessary to lower the humidity in the bowl 2a, the air that has passed through the deodorizing filter 78 passes through the enclosed moisture absorbent. Thus, the flow path is switched to remove moisture from the air circulating in the bowl 2a. Thereby, the humidity in the bowl 2a is maintained at an appropriate value, and the detection sensitivity of each gas sensor is maintained substantially constant. Accordingly, the humidity adjusting device 59 functions as an output result stabilizing unit that suppresses a humidity change in the bowl 2a.

The suction fan 18c sucks off the odorous gas containing the odorous gas etc. in the bowl 2a of the flush toilet 2 at a constant speed, deodorizes it, and returns it to the bowl 2a. The deodorizing duct 18a opens in the bowl 2a with the suction port directed downward so that droplets such as urine do not enter the interior. Odorous gases such as methyl mercaptan and hydrogen gas have a low molecular weight, so they rise immediately after defecation. In contrast, in the present embodiment, the exhausted odorous gas and hydrogen gas are reliably introduced into the gas detection device 20 by being sucked by the suction fan 18c from the inlet of the duct 18a opened in the bowl 2a. be able to. Thus, the suction device 18 is operated before the subject starts defecation, and makes the gas sensor contact a gas having a constant flow rate during the defecation period of the subject. Thereby, a stable measurement value can be obtained. Accordingly, the suction device 18 and the control device 22 that operates the suction device 18 function as output result stabilization means.

The filter 72 is a filter that does not have a deodorizing function, and is configured to pass odorous gas, hydrogen, and carbon dioxide and prevent passage of foreign matter such as urine and cleaning agents. As such a filter 72, a member that mechanically collects foreign matters, for example, a fine net-like member, without using a chemical reaction, can be used. Thereby, it is possible to prevent the odorous gas sensor 26, the hydrogen gas sensor 24, and the carbon dioxide sensor 28 from being contaminated by urine stones or the like.

Furthermore, for each gas sensor, a sensor heating heater 54 is provided upstream of each gas sensor and downstream of the filter 72. As described above, the odorous gas sensor 26 and the hydrogen gas sensor 24, which are semiconductor gas sensors, can detect hydrogen and odorous gas in a state where the catalyst is heated to a predetermined temperature. The sensor heating heater 54 is provided to heat the catalysts of the odorous gas sensor 26 and the hydrogen gas sensor 24. Also, the carbon dioxide sensor 28 needs to heat the solid electrolyte to a predetermined temperature, and a sensor heating heater 54 is provided. These sensor heating heaters 54 also function as an odor removing device for heating and removing odorous gas components adhering to the sensor. Even when a solid electrolyte sensor is used as an odorous gas sensor or a hydrogen gas sensor, it is necessary to provide a sensor heating heater for heating the catalyst.

Furthermore, the sensor heating heater 54 also functions as a means for removing deposits attached to each sensor. Although the gas that has passed through the filter 72 has foreign substances removed, the sucked gas contains various odorous gas components. Such off-flavor gas components adhere to each gas sensor and can cause noise when measuring a minute amount of odorous gas. On the other hand, by heating the catalyst of the sensor by the sensor heating heater 54, the off-flavor gas adhering to the sensor can be removed by heating without providing a new device. Moreover, the control apparatus 22 controls the sensor heating heater 54 so that the temperature of each gas sensor becomes constant before the subject's defecation behavior is started. That is, the control device 22 controls the sensor heating heater 54 so as to suppress the temperature of each gas sensor from being lowered due to the contact of the airflow. Thereby, during the test subject's defecation period, the sensitivity of each gas sensor is managed by predetermined value, and the measurement error by each gas sensor can be suppressed. Therefore, the control device 22 and the sensor heating heater 54 function as output result stabilization means for stabilizing the output analysis result.

Further, the deodorizing filter 78 is a catalytic filter that adsorbs an odorous gas such as an odorous gas. The air from which gas such as odorous gas is removed by the deodorizing filter 78 is returned to the bowl 2a. At this time, if the gas refluxed in the bowl 2a contains odorous gas or the like, the odorous gas or the like flowing into the bowl 2a is again sucked from the duct 18a, and the odorous gas sensor 26 detects again. There is a risk that. For this reason, in this embodiment, the deodorizing filter 78 is arrange | positioned in the downstream of the odorous gas sensor 26, and odor components, such as odorous gas, are reliably removed from the gas returned in the bowl 2a.

When the subject sits on the toilet seat 4, the upper part of the bowl 2a is closed by underwear or the like. When the inside of the bowl 2a becomes negative pressure, the off-flavor gas component adhering to the body of the subject or clothes is sucked into the bowl 2a. In the biological information measurement system 1 of the present embodiment, the odorous gas sensor 26 is set to have extremely high sensitivity in order to detect odorous gas that is contained in a small amount in the defecation gas. Even the off-flavor gas component adhering to etc. becomes a disturbance to the measurement. On the other hand, in this embodiment, since the gas after deodorization is returned into the bowl 2a, the inside of the bowl 2a does not become negative pressure, and the off-flavor gas component adhering to the body of the subject, clothes, etc. Can be prevented from being drawn into the bowl 2a.

Here, the semiconductor gas sensor used as the odorous gas sensor 26 detects not only odorous gas but also hydrogen. For this reason, it is necessary to separate the influence of hydrogen gas from the detection data detected by the semiconductor gas sensor. In this embodiment, as a hydrogen separation mechanism for separating the influence of such hydrogen gas, the hydrogen gas sensor 24 detects the odorous gas detected by the semiconductor gas sensor in the gas detection device 20. By subtracting the detection value of the hydrogen gas, the influence of the hydrogen gas is separated and output as the detection value of the odorous gas sensor 26. A configuration including such a hydrogen separation mechanism, a semiconductor gas sensor, and a hydrogen gas sensor 24 and outputting a detection value corresponding to the amount of odorous gas and the amount of hydrogen gas is referred to as a detection value output mechanism. The arithmetic processing for subtracting the detected value of the hydrogen gas detected by the hydrogen gas sensor 24 from the detected value of the odorous gas detected by the semiconductor gas sensor may be performed in the data analysis device 60 or the like. In this embodiment, a hydrogen separation mechanism for separating the influence of hydrogen gas from detection data detected by the semiconductor gas sensor will be described. By providing a methane sensor for detecting methane, detection data detected by the semiconductor gas sensor is provided. It is also possible to separate the effects of methane from As the methane gas sensor, a semiconductor gas sensor adjusted so that the components of the catalyst react strongly with methane may be used.

In many people's intestines, there are no methanogens that produce methane, or even if they exist, the amount of methane is very small. Few. For this reason, in this embodiment, the hydrogen sensor 24 and the carbon dioxide sensor 26 are provided as health system gas sensors. However, rarely, there are people who have very many methanogens in their intestines. As described above, the defecation gas of a person having a very large number of methanogenic bacteria in the intestine has a large amount of methane produced but a small amount of hydrogen produced. For this reason, when only the hydrogen sensor 24 and the carbon dioxide sensor 26 are provided, the fecal gas of a person who has a very large amount of methanogenic bacteria in the intestine is judged to be less preferable because the amount of discharged health gas is small. In this embodiment, the hydrogen sensor 24 and the carbon dioxide sensor 26 are provided as health gas sensors in order to suit many people, but a methane gas sensor is provided instead of the hydrogen sensor 24 according to people with a large amount of methane gas. May be. Furthermore, by providing a methane gas sensor in addition to the hydrogen sensor 24 and the carbon dioxide sensor 26 in advance, any subject can be handled, which is more preferable.

As described above, the defecation gas contains a large amount of hydrogen, but the semiconductor gas sensor detects not only odorous gas but also hydrogen. On the other hand, since the influence of hydrogen can be separated by subtracting the amount of hydrogen gas detected by the hydrogen gas sensor 24 from the amount of gas detected by the odorous gas sensor 26 which is a semiconductor gas sensor, it is possible to accurately The amount of odorous gas can be measured.
Further, the hydrogen gas contained in the defecation gas has a very small molecular weight as compared with air, and easily escapes from the bowl 2a. On the other hand, in this embodiment, since the defecation gas is sucked by the fan 18c of the suction device 18, the defecation gas containing hydrogen gas can be reliably collected.

Moreover, if the sucked defecation gas is returned to the bowl 2a as it is, the measurement accuracy by the odorous gas sensor 26 is lowered. On the other hand, in this embodiment, since the sucked defecation gas is deodorized by the deodorizing filter 78 and returned to the bowl, the amount of odorous gas and the amount of hydrogen can be accurately measured. Further, such a deodorizing filter 78 needs to be disposed on the downstream side of each sensor. However, if such a deodorizing filter 78 is provided on the downstream side of each sensor, the sensor may be directly contaminated with foreign substances. . On the other hand, in this embodiment, since the filter 72 that does not have the deodorizing function is provided on the upstream side of the sensor, the contamination of the sensor with foreign substances can be reduced without affecting the odor component measurement.

In addition, when the gas in the bowl 2a is sucked, the pressure in the bowl 2a is lowered, and there is a possibility that the off-flavor gas component adhering to the body and clothes of the subject flows into the bowl 2a. On the other hand, in this embodiment, since the air from which the odor components after deodorization are removed is returned into the bowl 2a, the flow of off-flavor gas components adhering to the body or clothes of the subject into the bowl 2a is prevented. Accurate measurement became possible.

However, it is not essential to return the air from which the odor components after deodorization are removed to the bowl 2a. Thus, when the structure which returns the air which removed the odor component after deodorizing in the bowl 2a is not employ | adopted, there exists a possibility that the off-flavor gas component adhering to a test subject's body and clothes may flow in into the bowl 2a. However, as will be described later with reference to FIG. 9, when setting the reference value of the residual gas, the influence of the off-flavor gas component adhering to the body and clothes of the subject is included, and the reference of the residual gas Value is set. For this reason, it is possible to estimate the gas amount without returning the air from which the odor components after deodorization are removed to the bowl 2a.

Next, with reference to FIG.4 and FIG.5, the flow which measures a physical condition with the biological information measuring system 1 by 1st Embodiment of this invention is demonstrated.
FIG. 4 is a diagram for explaining the flow of physical condition measurement. The upper part shows each process in the physical condition measurement, and the lower part shows an example of a screen displayed on the display device of the remote controller in each process. FIG. 5 is a diagram illustrating an example of a screen displayed on the display device of the remote controller.

In the biological information measurement system 1 of the present embodiment, based on the correlation between the odorous gas in the defecation gas released by the subject at the time of defecation and the health system gas, the physical condition including the determination of cancer is analyzed. Here, it is preferable that each subject-side apparatus displays the analysis result during the defecation period or in a short period of time after the end of a single defecation period until it exits. However, if the analysis is performed in a short time, the analysis accuracy may be lowered. In addition, it is difficult to suck all of the defecation gas discharged by the subject with the suction device 18, and these are disturbances in a measurement environment where the toilet bowl or toilet is very unsanitary or the fragrance is strong. May affect the measurement accuracy. Therefore, in each subject-side device, when the physical condition including the presence / absence of illness is transmitted to the subject, the time-lapse results of measurement during many defecation behaviors over a long period of time are taken into account. Based on this, instead of strongly transmitting only the absolute amount of odorous gas highly relevant to cancer, the change in the physical condition of the subject, that is, the change in the intestinal state is transmitted strongly. Also, taking into account measurement errors at the time of each bowel movement, in the present embodiment, the subject is notified based on the measurement result at the time of one bowel movement so that the physical condition notified to the subject does not change significantly. It is devised to be notified. This utilizes the characteristic that the disease of cancer is a disease that progresses over a long period of time. The amount of odorous gas that is strongly related to cancer in a short period of time is greatly related to cancer. This is because it is not strong, but is often caused by bad lifestyle habits or the influence of noise, and if the physical condition changes greatly, it causes unnecessary psychological anxiety to the subject.

In view of the above points, in the present embodiment, first, in the subject-side device 10, the first defecation gas measurement result of one defecation action, that is, based on the defecation gas discharged during the first excretion action. , Simply analyze the health condition, and display the analysis result of the health condition. On the other hand, the server 12 can perform more detailed analysis by comparing with other subjects based on the total amount of gas discharged during a single defecation action. Therefore, in the biological information measurement system 1 of the present embodiment, simple analysis is performed in the subject-side device 10 installed in the toilet room R, and more detailed analysis is performed in the server 12.

As shown in FIG. 4, in the measurement at the time of one defecation action by the biological information measurement system 1 of the present embodiment, the pre-measurement environment preparation step S1, the measurement start preparation step S2, the measurement reference value setting step S3, The measurement process S4, the examination process S5, the communication process S6, and the post-measurement environment maintenance process S7 are executed.

The pre-measurement environment maintenance step S1 is a step performed before the subject enters the toilet room R. Whether or not the subject has entered the toilet room R is detected by the entrance detection sensor 34 (FIG. 2).
In the pre-measurement environment maintenance step S1, the control device 22 on the toilet seat side changes and controls the sensor warming heater 54, the suction device 18, and the toilet lid opening / closing device 40 to the measurement standby mode. In the measurement standby mode, the sensor warming heater 54 is based on the temperature measured by the temperature sensor 32 and the temperature of the catalyst of the odorous gas sensor 26 is lower than the temperature at the time of measurement (for example, 370 ° C.). To be controlled. In the measurement standby mode, the suction device 18 is controlled so that the suction air volume is minimized. The toilet lid opening / closing device 40 is controlled so that the toilet lid is closed in the measurement standby mode.

In addition, in the pre-measurement environment maintenance process S1, the catalyst of the odorous gas sensor 26 is lower than the optimum temperature because the sensor heating heater 54 is in the measurement standby mode, but the gas concentration of the odorous gas is measured. Is possible. When there is a source of off-flavor gas in the bowl 2a, such as when there is attached stool in the flush toilet 2, the gas concentration measured by the odorous gas sensor 26 becomes a predetermined value or more. When the gas concentration value measured by the odorous gas sensor 26 exceeds a predetermined value in the pre-measurement environment maintenance step S1, the control device 22 performs toilet cleaning. Specifically, the control device 22 discharges the cleaning water from the nozzle by the nozzle driving device 42 to clean the bowl 2a, and discharges the water stored in the cleaning water tank by the toilet cleaning device 46 into the bowl 2a. The bowl 2a is washed, or the sterilizer 48 generates sterilized water such as hypochlorous acid water from tap water, and sprays the generated sterilized water onto the bowl 2a to sterilize the bowl 2a. Do.

In addition, when the gas concentration measured by the odorous gas sensor 26 is equal to or higher than a predetermined value, the control device 22 can operate the suction device 18 to discharge the gas in the bowl 2a to reduce the gas concentration. Since the gas sucked by the suction device 18 is deodorized by the deodorization filter 78, the suction device 18 and the deodorization filter 78 function as a deodorization device. Further, by sucking the gas with the suction device 18 with the toilet lid open, not only the inside of the bowl 2a but also the toilet room R can be deodorized, so the suction device 18 and the deodorizing filter 78 are provided in the toilet room. It can also function as a deodorizing device. Preferably, when the suction device 18 and the deodorization filter 78 are functioned as a deodorization device, the amount of gas sucked by the suction device 18 is set larger than when the physical condition is measured during the defecation period of the subject.

Alternatively, a ventilation device (not shown) provided in the toilet room R may be configured to be controlled by the control device 22, and the gas concentration may be lowered by operating the ventilation device. In this way, the concentration of the odorous gas remaining in the bowl 2a is reduced, and the influence of residual gas noise caused by the remaining gas is reduced. Therefore, the cleaning or sterilization of the bowl 2a by the nozzle drive device 42, the toilet bowl cleaning device 46 or the toilet bowl sterilization device 48, and the exhaust / deodorization in the bowl 2a or the toilet room R performed in the pre-measurement environment maintenance step S1 are as follows. It functions as noise countermeasure means for reducing the influence of residual gas noise and residual gas removal means for reducing the concentration of residual odorous gas. Further, the noise countermeasure means executed when the subject is not in the toilet room R and is outside the subject's defecation period functions as the first noise countermeasure means and also as the residual gas removing means.

Furthermore, if the amount of gas measured by the odorous gas sensor 26 does not become less than a predetermined value even after the toilet bowl cleaning described above is performed in the pre-measurement environment maintenance step S <b> 1, the control device 22 causes the transceiver 56 to perform a cleaning warning. Send command signal. When the transmitter / receiver 66 on the remote control 8 side receives the cleaning warning command signal, the display device 68 or the speaker 70 notifies the subject to clean the toilet.

In addition, in the pre-measurement environment maintenance step S1, the control device 22 periodically performs suction environment cleaning. Specifically, the control device 22 drives the duct cleaner 58 and sprays cleaning water into the duct 18a of the suction device 18 to clean the duct 18a and the like. Further, the hydrogen heater 24, the odorous gas sensor 26, and the carbon dioxide sensor 28 are heated to a high temperature by the sensor heating heater 54, and the off-flavor gas components adhering to the surfaces of the gas sensors 24, 26, 28 are burned out.

Next, when the entrance of the subject is detected by the entrance detection sensor 34, the control device 22 transmits a signal to start the measurement start preparation step S <b> 2 to the transmitter / receiver 66 on the remote control 8 side via the transmitter / receiver 56. The measurement start preparation step S2 is performed in synchronization with the remote control side.

In the measurement start preparation step S2, first, the subject specifying device 62 built in the remote controller 8 specifies a subject. Specifically, the resident of the house where the system is installed is registered in the biological information measurement system 1, and the registered resident is displayed as a candidate for the subject. That is, as shown in FIG. 5, "subject A", "subject B", "subject C",. . The candidate's button is displayed, and when the subject entering the toilet room R presses the button corresponding to himself / herself, the subject is identified. Further, the data analysis device 60 built in the remote controller 8 refers to the storage device, and displays the physical measurement display table as the reference measurement data and the past measurement data of the personal identification information received by the subject identification device 62 and the analysis reference. get.

Further, in the measurement start preparation step S2, as shown in FIG. 5, the data analysis device 60 performs the previous defecation such as “Did you defecate in another place?” On the second stage of the display device. Questions about whether or not this was done in the toilet where this device was installed, and the answer options “Yes (this morning)”, “Yes (yesterday afternoon)”, “Yes (yesterday morning)”, “before yesterday” “No” is displayed. When the subject answers this question, the defecation history information of the subject is input to the input device 64 of the data analysis device 60. The defecation history information regarding the elapsed time from the previous defecation behavior of the subject is stored in a storage device (subject information storage device) built in the remote controller 8, and the subjects registered in advance in the subject information storage device The subject information regarding the body weight, age, sex, etc. of the child is also stored. The defecation history information is transmitted to the server 12 and recorded in the database of the server 12.

In the measurement start preparation step S2, the toilet-side control device 22 controls the sensor warming heater 54, the suction device 18, and the toilet lid opening / closing device 40 to the measurement mode. In the measurement mode, the sensor heating heater 54 is controlled based on the temperature measured by the temperature sensor 32 so that the temperature of the catalyst of the odorous gas sensor 26 becomes a temperature suitable for measurement (400 ° C.). Further, in the measurement mode, the suction device 18 is controlled to be constant so that the suction air volume is increased to an air volume that prevents the defecation gas from leaking outside from the bowl 2a and does not fluctuate from such air volume. Further, the toilet lid opening / closing device 40 is controlled to open the toilet lid in the measurement mode.

In the measurement start preparation step S <b> 2, when the odorous gas concentration detected by the odorous gas sensor 26 is high, the control device 22 performs sterilization in the bowl 2 a by the toilet sterilization device 48.
Further, in the measurement start preparation step S2, when the humidity measured by the humidity sensor 30 is a value that is not suitable for the measurement of the defecation gas by the odorous gas sensor 26, the control device 22 sends a signal to the humidity adjustment device 59. To control the humidity in the bowl to an appropriate value.

In the measurement start preparation step, when the toilet seat 4 is cleaned by a sheet using an alcohol-based disinfectant or by spraying, the odorous gas sensor 26 reacts with alcohol and the gas concentration value increases rapidly. Thus, when the gas concentration measured by the odorous gas sensor 26 increases rapidly, the data analysis device 60 displays a warning on the display device 68.

In addition, the data analysis device 60 stores the measurement value obtained by the odorous gas sensor 26 as an environmental reference value that is a noise level that is a base for defecation gas measurement. Based on this environmental reference value, the data analysis device 60 determines whether or not measurement is possible. If the data analysis device 60 determines that the noise level is being measured or cannot be measured, the display device 68 causes the display device 68 to read “Preparing for measurement! ”Is displayed to prompt the subject to wait for defecation.

Next, when the seating detection sensor 36 detects that the subject is seated, the control device 22 transmits a signal indicating that the measurement reference value setting step S3 is started to the data analysis device 60 via the transceiver 56. The measurement reference value setting step S3 is performed in synchronization with the data analysis device 60. In addition, when the seating detection sensor 36 repeats detection and non-detection a predetermined number of times, it is an effect of cleaning of the toilet seat by the subject, and in such a case, it is desirable to return to S1.
In the measurement reference value setting step S <b> 3, the data analysis device 60 performs subject adhering odor noise determination, which is determination of a noise level caused by the subject, based on the measurement value measured by the odorous gas sensor 26. That is, when the measured value measured by the odorous gas sensor 26 is sufficiently lowered and not stable, it is determined that there is a possibility that sterilization with an alcohol-based disinfectant or the like has been performed, and FIG. Continue to display “Preparing for measurement! Please wait if you can” as shown below. Alternatively, when the noise level caused by the subject is equal to or higher than a predetermined value, the data analysis device 60 sends a signal to the nozzle driving device 42 which is a local cleaning device to activate it, and performs the subject's tail washing. Alternatively, the data analysis device 60 notifies the subject by the display device 68 so that the subject performs the butt washing. As described above, the execution of the buttocks cleaning by the data analysis device 60, the notification for prompting the notification, and the notification that the noise to the subject is large, the second noise correspondence that reduces the subject noise by a measure different from the first noise handling means. Functions as a means. Further, the first noise countermeasure means described above is executed when the subject does not enter the toilet room R, whereas the second noise countermeasure means is executed when the subject enters the toilet room R. The On the other hand, when the measured value measured by the odorous gas sensor 26 is sufficiently lowered, this display is deleted. If the measured value measured by the odorous gas sensor 26 does not decrease sufficiently even after a predetermined time has elapsed, the data analysis device 60 stops measuring the physical condition and displays the fact on the display device 68 to indicate the subject. To inform. As described above, the data analysis device 60 stops the physical condition measurement of the subject when it is determined that the gas component in the bowl 2a before the defecation period of the subject is not suitable for measurement. Function.

In the measurement reference value setting step S3, the data analysis device 60 sets a reference value for gas amount estimation based on the gas concentration measured by the odorous gas sensor 26, as will be described in detail later.
Next, as will be described in detail later, when the measured value by the odorous gas sensor 26 greatly rises from the reference value, the data analysis device 60 determines that the subject has performed excretion. The data analysis device 60 performs the measurement step S4 until it is detected by the seating detection sensor 36 that the subject has left the seat after it is determined that the subject has excreted.

In the measurement step S4, the control device 22 includes a hydrogen gas sensor 24, an odorous gas sensor 26, a carbon dioxide sensor 28, a humidity sensor 30, a temperature sensor 32, an entrance detection sensor 34, a seating detection sensor 36, and defecation / urination. The detection data measured by the detection sensor 38 is stored in the storage device for each subject specified by the subject specifying device 62. The control device 22 transmits these measurement values stored in the storage device to the data analysis device 60 via the transceiver 56 after the measurement step S4 ends. In the present embodiment, the measurement value is transmitted from the control device 22 to the data analysis device 60 after the measurement step S4 ends. However, the measurement value is not limited to this, and may be transmitted in real time in parallel with the measurement.
Further, the control device 22 starts the measurement of the defecation gas even when the subject does not input the information for identifying the subject to the subject identifying device 62. The detection data detected before the information is input is stored in the storage device in association with the input subject information when the subject inputs the subject information during one stool. This is a practical device tailored to the characteristics of defecation so that various inputs can be made after calming down in a tight situation such as defecation. Further, if the subject does not input subject information even after a predetermined time has elapsed after the start of measurement, a message prompting the subject to input is output from the display device 68 and the speaker 70 to notify the subject. Thereby, a test subject's forgetting input can be prevented.

At the same time, as in the measurement reference value setting step S3, the data analysis device 60 determines whether or not measurement is possible. If it is determined by the data analysis device 60 that measurement is possible, the data analysis device 60 uses the display device 68 as shown in the lower row of FIG. “OK! Measuring” is displayed to the subject indicating that the measurement is being performed.

Next, when it is detected by the seating detection sensor 36 that the subject has left the seat, the control device 22 transmits a signal indicating that the examination process S5 is started to the data analysis device 60 via the transceiver 56. When receiving this signal, the data analysis device 60 starts the medical examination step S5.
First, the data analysis device 60 calculates the measurement reliability, which will be described in detail later, based on the measurement values measured by the sensors.
On the other hand, the control device 22 prohibits the flush toilet 2 from being washed when information for identifying the subject is not input even after the subject has left the seat. That is, when the subject specifying information is not input, even if the subject operates a cleaning button (not shown) of the remote controller 8, the control device 22 does not discharge the cleaning water of the flush toilet 2 and prompts input. Is displayed. Thereby, it is possible to strongly urge the subject to input subject identification information.

Further, as will be described in detail later, the data analysis device 60 estimates the gas amounts of odorous gas and hydrogen gas (health gas).
Further, in the screening process S5, the data analysis device 60 analyzes the physical condition of the subject based on the temporal changes of the plurality of detection data detected in a plurality of stool performed within a predetermined period and stored in the storage device. A medical examination result is calculated and a time-lapse diagnosis based on the stored value is performed. Then, the advice content based on the diagnosis over time is selected. As shown in the third row of FIG. 5, the data analysis device 60 displays the selected advice content on the display device 68 as a message related to health management. In the example shown in FIG. 5, the current physical condition of the subject falls under “physical illness” as a result of the screening, and advice is “The intestinal environment seems to be bad. Try to live a healthy life.” It is displayed.

Furthermore, below the screening result, the amount of healthy gas such as hydrogen gas and carbon dioxide gas, and the amount of poorly conditioned gas such as odorous gas in this measurement are displayed. Under the advice, measurement results for the past four times are also displayed. Further, when the subject presses the “detail screen” button on the display screen, a table showing the physical condition change of the subject for the past month is displayed. This display will be described later. As described above, the analysis result displayed on the display device 68 of the remote controller 8 includes only the physical condition, advice, and physical condition change (history of measurement data), and cancer that is displayed on the medical institution terminal 16. Notifications regarding disease determination results are not included. These analysis results may be notified to the subject terminal 14.

Also, as shown at the bottom of FIG. 5, the reliability of the current measurement data is displayed at the bottom of the display device 68. In the example shown in FIG. 5, the reliability is displayed as “4”, which is relatively high. When the reliability is low, the reason why the reliability has decreased and advice for improving the reliability are displayed under the reliability display. For example, if the residual gas noise caused by the gas remaining in the bowl or the subject noise caused by the subject is large, the reliability is lowered and the subject is notified that the noise affects the measurement result. . Therefore, the display of reliability by the display device 68 functions as noise countermeasure means. The calculation of reliability will be described later.

Next, when the control unit 22 detects that the subject has left the room by the entrance detection sensor 34, the control unit 22 transmits a signal indicating that data transmission is performed to the data analysis device 60 via the transceiver 56. When receiving this signal, the data analysis device 60 performs a communication step S6.
In the communication step S6, the data analysis device 60 obtains the information for identifying the subject specified by the subject specifying device 62, the data measured by various sensors, the calculated reliability, the measurement date / time information, and the defecation / urination detection sensor 38. The notification data including the flight status information regarding at least one of the flight volume and the flight status and the bowel movement history information are transmitted to the server 12 via the network. The server 12 records the received information in a database.

In addition, after the subject leaves the room by the entrance detection sensor 34, the control device 22 performs a post-measurement environment maintenance step S7.
The control device 22 measures the gas concentration by the odorous gas sensor 26 in the post-measurement environment maintenance step S7. When the gas concentration measured by the odorous gas sensor 26 is larger than a predetermined value even after a predetermined time has elapsed after the end of the defecation period, the control device 22 has stool adhesion on the bowl 2a of the flush toilet 2 And the wash water stored in the wash water tank by the toilet flushing device 46 is discharged into the bowl 2a to wash the inside of the bowl 2a, or the hypochlorine from tap water by the toilet flushing device 48 Disinfecting water such as acid water is generated, and the generated disinfecting water is sprayed on the bowl 2a to sterilize the bowl 2a.

The additional toilet cleaning by the toilet cleaning device 46 and the sterilization of the bowl 2a by the toilet sanitizing device 48 function as a residual gas removing means for reducing the concentration of the remaining odorous gas. Preferably, the toilet cleaning performed automatically by the residual gas removing means is set to have a higher cleaning power than the normal toilet cleaning performed by the subject operating a cleaning switch (not shown) of the remote controller 8. Keep it. Specifically, in the toilet bowl cleaning performed by the residual gas removing means, it is preferable to set a large number of times of discharge of the cleaning water to the bowl 2a or to set a high flow rate of the cleaning water. Further, the sterilization of the bowl 2a performed by the residual gas removing means is performed by setting the sterilization power stronger than the normal bowl sterilization performed by the subject operating the sterilization switch (not shown) of the remote controller 8. deep. Specifically, in the bowl sterilization performed by the residual gas removing means, the sterilization water having a higher concentration than that of the normal sterilization is sprayed or a large amount of the sterilization water is sprayed.

Furthermore, if the gas concentration measured by the odorous gas sensor 26 is greater than a predetermined value even after a predetermined time has elapsed after the end of the defecation period, the residual gas removing means determines that the duct 18a is dirty. The duct cleaner 58 is activated. The duct cleaner 58 cleans the inside of the duct 18a attached to the suction device 18 with hypochlorous acid or the like obtained by electrolyzing tap water.
In addition, the residual gas removing means is a flush toilet when the gas concentration measured by the odorous gas sensor 26 is not sufficiently lowered even when the above washing and sterilization processes are executed and is larger than a predetermined value. 2 is displayed on the display device 68.

In the post-measurement environment maintenance step S7, the control device 22 changes the sensor heating heater 54, the suction device 18, and the toilet lid opening / closing device 40 to the measurement standby mode, and ends one measurement.

Next, the physical condition display table will be described with reference to FIG. This physical condition display table is a table displayed by pressing the “detail screen” button on the display screen shown in FIG. 5.
In the storage device on the remote control 8 side, the physical condition display table, the date and time of defecation of each subject in association with the subject identification information, and past measurement data are recorded for each subject. The past measurement data stored in the storage device on the remote control 8 side may be data for the entire period during the defecation period, but due to the relationship with the capacity of the storage device, it is discharged by the first excretion action during the defecation period. The measurement data of the defecation gas (measurement data of the first excretion action period) is preferable.

As shown in FIG. 6, the physical condition display table is a table determined based on the experiment conducted by the above-described inventors, and the vertical axis represents the odorous gas that is the first index (the poorly related gas on the display). Is a graph showing an index related to the amount of gas and a horizontal axis indicating the index related to the gas amount of health-related gas as the second index. The first index is related to the amount of odorous gas based on the first detection data detected by the gas detection device 20, and the second index is the second detection data detected by the gas detection device 20. Based on the amount of hydrogen gas, which is a health gas. On the display device 68 of the remote controller 8, the measurement results of the defecation gas of the subject are displayed as plot points over time on such a physical condition display table having a vertical axis and a horizontal axis. That is, as shown in FIG. 6, the plot point representing the latest measurement result of the same subject is “1”, the previous result is “2”, and the previous result is “3”. . . As a result, the past 30 plot points are displayed together with numbers. Thereby, the test subject can recognize the temporal change of his / her physical condition. In this embodiment, the number is 30 times, but it may be several weeks or months, and may be a year by considering that the progression of cancer is a year. It is more desirable for the subject to be able to change the display range according to the situation. Furthermore, when the display range is large, the display method is easy to see, such as one year or two years on a monthly average. It goes without saying that it is even better to change in consideration of the above.

Further, in the physical condition display table, “disease suspicion level 2”, “disease suspicion level 1”, “physical illness level 2”, “physical dysfunction level” are set according to the relationship between the index related to health gas and the index related to odorous gas. A plurality of regions are set according to whether the physical condition is good, such as “1” and “good physical condition”. Here, as shown in FIG. 6, “disease suspicion level 2” corresponding to the state of the worst physical condition is that the amount of odorous gas is the largest and the amount of healthy gas is the smallest in the physical condition display table. It is set in the upper left area. On the other hand, “good physical condition” corresponding to the best physical condition is set in the lower right region of the physical condition display table where the amount of odorous gas is the smallest and the amount of healthy gas is the largest. The areas of “disease suspicion level 1”, “physical condition level 2”, and “physical condition level 1” indicating physical condition levels between these are set in order from the upper left as a band-like area that rises to the right on the physical condition display table. Has been. Such a physical condition display table is set in advance according to the weight, age, sex, etc. of the subject. By displaying plot points based on the first and second indices on this table, the detection data and the subject are displayed. Analysis based on information can be performed.

As described above, in the present embodiment, since the two indexes of the index regarding the gas amount of the odorous gas and the index regarding the gas amount of the health-related gas are used, the change in the physical condition and the physical condition of the subject can be described in more detail. Can be evaluated. For example, even if the amount of healthy gas that indicates good physical condition is large, if the amount of odorous gas is also large, the evaluation is not the most satisfactory level (in the physical condition display table). Upper right area). On the other hand, even if the amount of healthy gas that indicates good physical condition is very small, if the amount of odorous gas is small, the evaluation is not the most bad level (physical condition display table). Lower left area).
In addition, for example, the boundary line between “physical condition level 1” and “physical condition level 2” indicating a state of poorer physical condition indicates that the index for the amount of healthy gas on the horizontal axis increases and the odor characteristic on the vertical axis. The “physical condition level 2” representing a state of poor physical condition is distributed on the larger side of the index related to the odorous gas amount of the boundary line. Since the boundary line is set in this way, in this embodiment, even if the index related to the amount of healthy gas on the horizontal axis is the same value, the condition of the physical condition depends on the value of the index related to the amount of odorous gas on the vertical axis. The evaluation will be different. In order to obtain an equivalent evaluation, the value of the health gas amount on the horizontal axis needs to increase as the value of the odorous gas amount on the vertical axis increases.

Further, advice corresponding to the physical condition is recorded in the storage device on the remote control 8 side. Specifically, the advice “please go to the hospital” for the physical condition “suspected disease level 2”, the advice “recommend to the hospital” for the physical condition “suspected disease level 1”, the physical condition “physical condition” “Unsatisfactory level 2” suggests that “disease concerns will increase. Stress reduction and lifestyle improvement will be urgently improved”, but “physic condition level 1” indicates “intestinal environment seems to be bad. The advice “Let's keep life” is recorded in association with the advice “physical condition is good” in association with the physical condition “good physical condition”. On the physical condition display table, advice corresponding to the area where the latest plot point is located is displayed together with the plot points indicating the physical condition of the subject.

However, the plot points shown on the physical condition display table of the display device 68 of the remote controller 8 do not indicate the analysis results analyzed by the data analysis device 60 as they are, but are plotted at positions moved with predetermined corrections. A dot is shown. Here, the disease assumed to be detected by the biological information measurement system 1 of the present embodiment is colon cancer or the like, and such a disease does not progress rapidly within a few days. On the other hand, the living body information measurement system 1 of the present embodiment sucks the defecation gas from the bowl 2a of the flush toilet 2 installed in the toilet room R and analyzes the sucked gas. I can't do it. In addition, when the subject is wearing perfume, or when the gas reacting with the odorous gas sensor 26 such as odorous gas remains in the toilet room R, an error occurs in the physical condition measurement result due to various factors. There is a fear.

For this reason, if the displayed physical condition swings to the side with a bad physical condition based on one measurement result of a test subject, an unnecessary psychological burden is given to the test subject. In addition, if the physical condition measurement result fluctuates greatly for each measurement, the test subject's confidence in the physical condition measurement result is lost. For this reason, in the biological information measurement system 1 of the present embodiment, the analysis result obtained by the data analysis device 60 is corrected so that the displayed measurement result does not fluctuate greatly for each measurement. However, the detection data stored in the storage device of the remote controller 8 and the detection data transmitted and stored in the server 12 are stored together with the reliability of the detection data without correction. The storage device of the remote controller 8 may store the coordinates of the display that is corrected and displayed in consideration of the next display. Thus, the detection data obtained by the biological information measurement system 1 of the present embodiment are not all highly reliable. However, it is possible to detect changes in the physical condition of the subject over a long period of time by acquiring data on daily defecation behavior continuously for a long period and accumulating the data in the storage device of the remote control 8 or the server 12. Thus, before the subject's physical condition is greatly deteriorated, attention can be drawn so as not to cause a large disease such as colorectal cancer.
As described above, the correction applied to the detection data functions as an output result stabilization unit that suppresses the physical condition index of the subject output to the display device 68 from being shaken in the direction of poor physical condition due to a detection error or the like.
In the present embodiment, the detection data stored in the storage device of the remote controller 8 does not necessarily have to be corrected, and the corrected detection data may be recorded.

Next, correction of plot points will be described with reference to FIGS. 7A and 7B.
FIG. 7A is a diagram illustrating an example of movement of the plot points of the latest data by correction, and FIG. 7B is a diagram illustrating limit processing for the amount of movement of the plot points.
First, as shown in FIG. 7A, the plot point calculated by the data analysis device 60 based on the latest measurement is “1”, and this point is greatly deviated from the center G of the plot points of the past 30 measurement data. ing. Thus, if the plot point “1” that is significantly deviated from the distribution of the measurement data up to the previous time is displayed, an excessive psychological burden is given to the subject. Since cancer risk does not increase in a day, such a large change in measurement data may be the result of bad lifestyles the previous day or the effects of noise rather than an increased risk of cancer. high. Therefore, in this embodiment, the correction is performed in consideration of not giving an excessive psychological burden to the subject. For this reason, when the latest analysis result changes to the poor physical condition side (upper left direction), the data analysis device 60 determines the position where the plot point “1” is displayed on the physical condition display table in the current measurement data. Based on the reliability, the display is moved by a predetermined distance in the direction of the center of gravity G. That is, in the example shown in FIG. 7A, the latest measurement data is displayed at the position of the plot point “1 ′” corrected so that the plot point “1” is moved in the direction of the center of gravity G (good physical condition side). (The plot point “1” is not actually displayed). The movement distance of the plot point “1” in the direction of the center of gravity G is increased as the reliability of the latest measurement data is lower. In this way, the psychological burden on the subject can be reduced by moving the latest plot point to the side showing good physical condition. The calculation of the reliability of the measurement data will be described later. However, the data analysis device 60 decreases the correction amount (the movement amount due to the correction) when the latest plot point moves to the poor physical condition side for a predetermined number of times or more. Thereby, the test subject can recognize that his / her physical condition is deteriorating and can urge him to try to improve his / her physical condition.

In addition, when the latest physical condition measurement includes a very large noise and the latest plotted point is greatly deviated, even if the correction described in FIG. It can be considered to move largely to the side. For this reason, as shown in FIG. 7B, a predetermined limiter is applied to the moving distance of the latest data from the center of gravity G. That is, the movement of the latest data from the center of gravity G is limited to ± 40%, and even when the latest data is deviated by 40% or more from the coordinates of the center of gravity G, the latest data is plotted at a position deviated by 40%. . For example, when the coordinate value of the center of gravity G is (x, y), the range of coordinate values in which the latest data can be plotted is (0.6x to 1.4x, 0.6y to 1.4y), which is more than that. It is not plotted at the specified position.

Furthermore, when the movement of the latest data exceeding 40% continues twice, the range in which the latest data can be moved is reduced to 60%. Thereby, for example, when the coordinate value of the center of gravity G is (x, y), the range of coordinate values in which the latest data can be plotted is (0.4x to 1.6x, 0.4y to 1.6y). Be changed. This is because when such a large amount of latest data movement occurs frequently, it is considered that a change in the physical condition of the subject is reflected rather than a simple measurement error.

Next, the diagnosis table on the server side will be described with reference to FIG. The following processing in the server is performed by data analysis means provided in the server 12.
FIG. 8 is a diagram illustrating an example of a diagnostic table displayed on the server side. As described above, in the biological information measurement system 1 of the present embodiment, the measurement data for the entire defecation period analyzed by the data analysis device 60 is sequentially transmitted to the server 12 via the Internet and recorded in the database on the server side. Has been. The accumulated measurement data can be displayed on a medical institution terminal 16 installed in a medical institution registered by a subject or the like. For example, when the subject receives a message “Recommend Visit” displayed on the display device 68 of the remote controller 8 and the subject visits a medical institution, the medical institution terminal 16 can display a diagnostic table for the server. It is like that. In the diagnostic table, the vertical axis and the horizontal axis represent the same indices as the physical condition display table displayed on the display device 68 of the remote controller 8, but the physical condition assigned to each region is more specific. It has become. The doctor can refer to the physical condition of the subject over time by referring to the measurement data of the subject recorded in the database on the server 12 side at the medical institution terminal 16, which is useful for examination and treatment in the medical institution. Can do. Alternatively, when the measurement data transmitted to the server 12 indicates a significant physical condition, the subject's terminal 14 for the subject is notified so as to receive a medical examination from a medical institution in which the subject is registered. The present invention can also be configured.

The diagnostic table displayed on the medical institution terminal 16 is different from the physical condition display table displayed on the display device 68 of the subject as described above. As shown in FIG. 8, the diagnosis table on the server 12 side is a table determined based on the experiment conducted by the inventors described above, and the relationship between the amount of healthy gas and the amount of odorous gas. Corresponding to the disease state is associated. Specifically, in the diagnostic table, depending on the relationship between the amount of healthy gas and the amount of odorous gas, “large colorectal cancer concern”, “early colorectal cancer concern large”, “early colorectal cancer suspect” , “Physical dysfunction level 3”, “Physical dysfunction level 2”, “Physical dysfunction level 1”, “Health condition”, “Intestinal dysfunction (diarrhea)”, and “Suspected mismeasurement” are set. .

On the server-side diagnosis table set in this way, the past measurement data of the subject is plotted over time, and based on the position of the plotted point, “large colorectal cancer concern”, “early early colorectal cancer concern”, “early” Judgment regarding cancer diseases such as “suspected colorectal cancer” is performed. Note that the plot points displayed in the server-side diagnosis table are not corrected or limited, and the doctor comprehensively determines the displayed data together with the reliability. In addition, since the diagnosis table and the determination result displayed on the medical institution terminal 16 are set on the assumption that the doctor refers to the diagnosis table, the name of the disease and the degree of progression thereof are displayed more specifically. It has become. In addition, when the plot point is located in a region related to cancer diseases such as “large concern about colon cancer”, “great concern about early colorectal cancer”, “suspected early colorectal cancer” over a long period of time, It is displayed that there is a high possibility of The doctor can comprehensively judge the indicated plot points, the reliability of measurement, and the like, and can tell the subject of his / her physical condition. In addition to the diagnostic table in which the past measurement data is plotted over time, the medical institution terminal 16 also includes the reliability calculated with reference to the database, the data measured by various sensors, the stool volume, and the stool status. At least one of the flight status information and the bowel movement history information can be displayed.

In addition, a large number of subject-side devices 10 are connected to the server 12, and measurement data of a large number of subjects are accumulated. Further, the database on the server 12 side stores data on the medical condition of a subject who has visited a medical institution based on certain measurement data as a result of a precise examination at the medical institution. Yes. Therefore, the data measured by the biological information measuring system 1 of the present embodiment and the data relating the actual medical condition can be accumulated on the server 12 side. The diagnosis table on the server side is sequentially updated based on the measurement data of a large number of subjects accumulated in this manner, and more accurate diagnosis can be performed based on the updated diagnosis table. Also, the physical condition display table can be updated based on the data accumulated on the server side. The physical condition display table updated based on the data on the server side is downloaded to each subject apparatus 10 via the Internet and displayed on the display device 68 of the remote controller 8. However, even if the physical condition display table is updated, the physical condition display table that is directly presented to the subject has been corrected to an appropriate content to be shown to the subject.

Next, with reference to FIG. 9, the data detected by each sensor provided in the biological information measurement system 1 of the present embodiment and the estimation of the gas amount based thereon will be described.
FIG. 9 is a graph schematically showing detection signals from the sensors provided in the biological information measurement system 1 in one defecation of the subject. FIG. 9 shows waveforms of detection signals from the hydrogen gas sensor 24, the carbon dioxide sensor 28, the odorous gas sensor 26, the humidity sensor 30, the temperature sensor 32, the seating detection sensor 36, and the entrance detection sensor 34 in order from the top. .

The estimation of the gas amount based on the detection signal of each sensor is performed by the data analysis device 60 which is a physical condition determination unit for determining the physical condition, that is, the CPU and storage device built in the remote controller 8 or the CPU of the server 12 and This is done in the storage device. The data analysis device 60 reads from the storage means of the remote controller 8 and starts the excretion action start time point, and the gas amount change rate threshold value and the gas amount that enables stable measurement. A stability threshold is set in advance. In addition, fart is included in the excretion act here.

First, at time t ₁ in FIG. 9, the room entry detection sensor 34 detects the entrance of the subject. The data analysis device 60 measures the amount of odorous gas by the odorous gas sensor 26 even in a state before the subject enters and exits the toilet room R by the occupancy detection sensor 34 (time t ₀ to t ₁ ). . Even in this state, the odorous gas sensor 26 reacts and outputs a certain level of detection signal due to the influence of the fragrance and the residual stool adhering to the bowl 2a of the flush toilet 2. Thus, the measured value of the odorous gas sensor 26 before the subject enters the room is set as the environmental reference value of the gas amount that is residual gas noise. In the state before the entrance detection sensor 34 detects the entrance, the odorous gas sensor 26 and the suction device 18 are in a power saving state, and the temperature of the sensor heating heater 54 for heating the catalyst of the odorous gas sensor 26. Is set to be low, the rotational speed of the suction fan 18c is suppressed, and the passing flow rate is also low.

Next, when the entrance detection sensor 34 detects that the subject has entered the room at time t ₁ , the odorous gas sensor 26 and the suction device 18 are activated. As a result, the temperature of the sensor heating heater 54 of the odorous gas sensor 26 rises, and the rotational speed of the fan of the suction device 18 increases, so that a predetermined flow rate of gas is sucked. As a result, the value detected by the temperature sensor 32 rises once and then converges to an appropriate temperature (time t _1-in FIG. 9). In the present specification, the period (time t ₁ to t _{8 in} FIG. 9) during which the entry detection sensor 34 detects entry of the subject into the toilet room R is referred to as one “defecation action”. . When the subject enters the room, the detection signal detected by the odorous gas sensor 26 increases. This is because the odorous gas sensor 26 reacts to the body odor of the subject, the perfume used, the hairdressing agent, and the like. That is, the increase from the residual gas noise before the subject enters the toilet room R is subject noise caused by the subject. The noise measuring means built in the data analysis device detects residual gas noise caused by the gas remaining in the bowl 2a and subject noise caused by the subject. The odorous gas sensor 26 is set to extremely high sensitivity for the purpose of detecting an extremely small amount of odorous gas contained in the ppb order in the defecation gas discharged into the toilet bowl. It also reacts to odors that cannot be felt.

Next, at time t ₂ in FIG. 9, when the subject is seated on the toilet seat 4 is detected by the seating detection sensor 36, this point is set as the starting point of one bowel movement period of the subject. In the present specification, the period (time t ₂ to t _{7 in} FIG. 9) in which the seating detection sensor 36 detects the seating of the subject on the toilet seat 4 is called one “defecation period”. Then, the detected value by the odorous gas sensor 26 after the start time (time t ₂ ) of the defecation period and immediately before the start of the first excretion action (time t _{5 in} FIG. 9) is used as the reference value of the residual gas. Set as.

In the example shown in FIG. 9, the detected value of the humidity sensor 30 increases between time t ₃ and t ₄ after the subject is seated at time t ₂ . This is the detection of urination of the subject, and since the detection value of the odorous gas sensor 26 has hardly changed, the data analysis device 60 determines that no excretion is performed. Then, the detection value of the hydrogen gas sensor 24 and odorous gas sensor 26 is up abruptly at time t _5. As described above, when the detected value of the odorous gas sensor 26 suddenly rises during the defecation period after the subject is seated, the data analysis device 60 determines that the excretion action has been performed.

When the excretion action is performed, the data analysis device 60 makes the fluctuation range which is an increase from the reference value of the residual gas (the hatched portion of the graph of the detection value by the odorous gas sensor 26) of the detection value by the odorous gas sensor 26. Based on this, the amount of odorous gas discharged from the subject is estimated. That is, the data analysis device 60 uses the value of the detection data at the start of the defecation period by the subject as a reference value that is a noise level caused by the subject, and calculates the difference between the detection value detected by the odorous gas sensor and the reference value. By integrating the time from the start point to the end point, the amount of odorous gas associated with the first excretion is estimated. Thus, since the data analysis device 60 estimates the odorous gas amount based on the difference from the reference value, the influence of noise caused by the subject can be suppressed. Therefore, the circuit built in the data analysis device 60 that performs this calculation functions as noise suppression means and also functions as second noise countermeasure means that reduces the influence of subject noise. Further, when the noise level caused by the subject is equal to or higher than a predetermined value, the data analysis device 60 notifies the display device 68 of the fact. Details of the estimation of the odorous gas amount will be described later. Similarly, the data analysis device 60 estimates the amount of hydrogen gas discharged from the subject based on the increase in the detected value by the hydrogen gas sensor 24 from the reference value of the residual gas. After excretion by the subject (time t _{5 in} FIG. 9), the detection values by the odorous gas sensor 26 and the hydrogen gas sensor 24 return to the reference value of the residual gas. Next, when a second excretion action is performed by the subject at time t ₆ , the detection values by the odorous gas sensor 26, the carbon dioxide sensor 28, and the hydrogen gas sensor 24 rapidly rise again. As for the second excretion action, similarly to the first excretion action, the amount of odorous gas and hydrogen gas discharged from the subject is estimated based on the increase from the reference value of the residual gas. In addition, when estimating the amount of odorous gas and hydrogen gas in the second and subsequent excretion actions, the standard value is changed each time in consideration of the effects of floating stools floating in the sealed water in the bowl. May be.

In this way, when the subject has performed excretion multiple times after entering the room (that is, when a change in the gas amount equal to or greater than a predetermined threshold is detected multiple times), the stool associated with each excretion The gas amount is estimated in the same way. When calculating the amount of defecation gas for the second and subsequent excretion actions, the reference value may be changed every time in consideration of the effect of floating stool floating on the sealed water in the bowl.

Then, by the seating detection sensor 36 unseated subjects completed defecation period once detected at time t ₇ in FIG. 9, the entrance detecting sensor 34 at time t ₈ the exit of the subject is detected, defecation once The action ends. The data analysis device 60 estimates the amount of stool gas associated with each excretion until the entry detection sensor 34 detects that the subject has left the room.

The physical condition of the subject is determined by the remote controller 8 and the server 12 based on the defecation gas amount measured in this way. At this time, it is desirable that the remote controller 8 can display the measurement of the physical condition during the defecation period or immediately after the defecation period. And if excretion is performed several times, since the stool accumulates in the bowl 2a, the accuracy of the measurement of the gas amount by the odorous gas is lowered. On the other hand, during the first excretion action, the defecation gas that reaches the most downstream of the large intestine is discharged, so that the most useful information for physical condition measurement can be obtained, and the measurement reliability is high. Based on these, the remote control 8 side, when the amount of defecation gas (the amount of odorous gas and hydrogen gas) from the first excretion can be estimated, the subject is based only on the amount of defecation gas from the first excretion Is measured and displayed on the display device 68 of the remote controller 8. Or a physical condition can also be measured so that the weighting of the measured value based on the detection data regarding the initial excretion action in one defecation action becomes heavier than the weighting regarding the late excretion action.

In contrast, on the server 12 side, it is desirable to make a more accurate determination by using the total amount of defecation gas resulting from multiple excretion actions. For this reason, on the server 12 side, the total amount of defecation gas (total amount of odorous gas and hydrogen gas) due to multiple excretion actions, more preferably all included in one defecation period from sitting to sitting The physical condition of the subject is determined based on the total amount of defecation gas due to the excretion action. The determination of the physical condition of the subject on the server 12 side does not necessarily need to be the total amount of defecation gas due to all excretion actions included in one defecation period, but all excretion included in many defecation periods. It is preferably based on the total amount of defecation gas due to action.

Here, in the example shown in FIG. 9, the reference value of the residual gas is constant, but even when the reference value is not constant, the amount of odorous gas discharged can be estimated. For example, when the detection value detected by the odorous gas sensor 26 tends to increase, as shown in FIG. Suppose that the auxiliary line A drawn before and after the excretion action is the reference value. The amount of the odorous gas can be estimated by determining that the time when the inclination of the detection value by the odorous gas sensor 26 greatly changes from the auxiliary line A is the time when one excretion is started.

In addition, since estimation of the amount of odorous gas sets the residual gas before excretion as a reference value and estimates based on the difference from the reference value, it is desirable that the reference value does not vary greatly. For this reason, the data analysis device 60 has the first stable rate of change of the detected value detected by the odorous gas sensor 26 before the start of excretion (that is, the rate of change of the reference value = the slope of the auxiliary line A). If it is below the sex threshold value, the notification means comprising the display device 68 or the speaker 70 of the remote controller 8 displays that the defecation gas amount is estimated with high accuracy.

On the other hand, when a spray-type fragrance is sprayed just before the excretion action, or when a disinfecting sheet or disinfection spray of an alcohol-based toilet seat disinfectant is used, it is detected by the odorous gas sensor 26 before the excretion action. The detection value fluctuates greatly. If such a state is set as a reference value, the amount of odorous gas cannot be estimated accurately. For this reason, the data analysis device 60 displays the display device of the remote controller 8 when the reference value, which is the noise level caused by the subject, is greater than or equal to a predetermined value, or when the change rate of the reference value is greater than or equal to the second stability threshold. A notification that the estimation accuracy of the amount of the defecation gas is low is provided by a notification means including 68 or a speaker 70. When excretion is performed despite such notification, measurement for physical condition analysis is not performed or the measurement reliability is set low.

Next, with reference to FIG. 10B, use detection of the alcohol-based toilet seat disinfectant will be described. FIG. 10B is a graph showing an example of a detected value by the odorous gas sensor 26 when the subject uses an alcohol-based toilet seat disinfectant.
At time t ₁₀ in FIG. 10B, after the entrance detecting sensor 34 is entry of the subject is detected, the detection value of the odorous gas sensor 26 gradually rises in response to body odor or the like of the subject. Next, when the subject takes out the toilet seat disinfecting sheet using the alcohol-based disinfectant at time t ₁₁ , the odorous gas sensor 26 reacts with the alcohol odor, and the detected value rises rapidly. At time t _12, subjects completed the eradication of the toilet seat 4, and to discard the eradication seat in the bowl 2a, alcohol-based detection value of the odor of gas sensor 26 immediately due to the high volatility starts to decline. Since this characteristic is different from the remaining off-flavor gas component, the inventors have found that the rapid increase in the detection value due to alcohol-based sterilization decreases after a while and measurement is possible. However, in the case of sterilization using an alcohol-based sterilization sheet, it may float in the sealed water when discarded. In this case, since the volatilization of the alcohol continues, the decrease tends to be delayed. Therefore, it is desirable to discharge the sheet as follows.

Then, after the seating detection sensor 36 detects the seating of a subject at time t _13, when the subject to perform a cleaning switch of washing by operating the (not shown) flush toilet second washing of the remote controller 8, distilled water bowl 2a Since the sterilization sheet floating on the odor gas sensor 26 is discharged, the detection value of the odorous gas sensor 26 rapidly decreases. When an alcohol-based disinfectant is used, the odorous gas sensor 26 generally changes in this way.

For this reason, the toilet seat disinfection detection means built in the data analysis device 60 has the odorous gas sensor 26 before the seating detection sensor 36 detects the subject's sitting after the entrance detection sensor 34 detects the entrance of the subject. When the detected value rises rapidly over a predetermined value, it is determined that the subject has sterilized the toilet seat 4 and the like using an alcohol-based sterilizing agent. The present inventor can thus detect the sterilization action of the toilet seat 4, which is a specific action performed by the subject in the toilet room R, from the detection signals of the entrance detection sensor 34, the seating detection sensor 36, and the odorous gas sensor 26. Was found.

In addition, when the toilet sterilization detection means detects the use of the alcohol-based sterilization agent and the flush toilet 2 is not washed for a predetermined time after the subject is seated, the sterilization built in the data analysis device 60 is performed. The noise countermeasure means sends a signal to the toilet cleaning device 46 to automatically execute toilet cleaning. Further, when the toilet seat sterilization detection means detects the use of the alcohol-based sterilization agent, the sterilization noise countermeasure means increases the rotational speed of the suction fan 18c. As a result, the amount of gas sucked by the suction device 18 is increased, and the alcohol component volatilized by toilet seat sterilization is positively deodorized by the deodorizing filter 78, thereby reducing the detection value of the odorous gas sensor 26. it can. That is, when the toilet seat sterilization detection unit detects sterilization, the sterilization noise countermeasure unit reduces the influence of noise caused by the alcohol-based sterilizing agent by operating the deodorizing device. These toilet seat sterilization detection means and sterilization noise countermeasure means are configured by an electric circuit built in the data analysis device 60.

Further, when the toilet seat disinfection detection means detects the use of the alcohol-based disinfectant and the detection value of the odorous gas sensor 26 is rising, the disinfection noise countermeasure means stops the physical condition measurement and waits for defecation. A message is displayed on the display device 68 to notify the subject. The sterilization noise countermeasure means displays a message on the display device 68 to inform the subject that he / she waits for defecation until physical condition measurement is possible. Thereby, the influence of the noise resulting from an alcoholic disinfectant is reduced. On the other hand, the detection value of the odorous gas sensor 26 that has risen rapidly due to the use of the alcohol-based disinfectant begins to decrease when the subject finishes disinfecting.

When the noise level detected by the odorous gas sensor 26 starts to decrease, the sterilization noise countermeasure means erases the message waiting for the defecation displayed on the display device 68 and notifies that measurement is possible. To do. That is, in a situation where the noise level caused by the alcohol-based disinfectant tends to decrease, it is possible to detect the rising of the detection value of the odorous gas sensor 26 that tends to decrease. The data analysis device 60 detects the time point when the detection value of the odorous gas sensor 26 that tends to decrease rises as the release of defecation gas by the subject. However, in a state where the noise level detected by the odorous gas sensor 26 is not less than a predetermined rate of change, the sterilization noise response means stops displaying physical condition and continues displaying a message to wait for defecation. . That is, in a state where the noise level is drastically reduced, an increase in the detection value due to the release of the defecation gas is masked, and the release of the defecation gas cannot be accurately detected. In addition, it is desirable to stop the calculation while the reference value is greatly decreased because the error also increases.

Also, the sterilization noise countermeasure means stops the measurement for physical condition measurement or sets the measurement reliability to be low when the noise level is a predetermined value or more due to the use of the alcohol sterilizing agent. As described above, when the measurement reliability is set low, the plot points on the physical condition display table described with reference to FIG. 7A are corrected to a greater degree on the side showing good physical condition. That is, when the sterilization noise countermeasure is detected, the sterilization noise countermeasure unit corrects the physical condition output by the display device 68 to the side indicating a good physical condition.

On the other hand, when there are many attached stools in the flush toilet 2 or when a large amount of fragrance is used, the absolute value of the gas amount detected by the odorous gas sensor 26 becomes large, and in some cases the detected value by the sensor In such a situation, it is difficult to accurately estimate the amount of odorous gas, which is a minute amount, because it saturates or falls out of a band with high measurement accuracy. For this reason, the data analysis device 60 does not perform measurement for physical condition measurement or sets the measurement reliability low even when the absolute amount of the reference value is equal to or greater than the third stability threshold.

Further, as described above, the measurement data of the gas amount of the odorous gas and the gas amount of the health gas of the new subject are sequentially accumulated in the database of the server 12. In the database of the server 12, the medical checkup result of cancer that the subject has received at the medical institution from the medical institution terminal 16 is recorded in association with the identification information of the subject. The server 12 updates the recorded diagnostic table based on the change in the history of the change in the gas amount of the odorous gas and the health-related gas, as well as the results of such a medical checkup for cancer.

FIG. 11 is a diagram illustrating an example of updating the diagnosis table. For example, as a result of plotting and analyzing the measurement data A of the odorous gas and healthy gas of the subject in the old diagnostic table, even if it is determined as "suspected early colorectal cancer", Suppose this patient is diagnosed with early colorectal cancer. In such a case, as shown in FIG. 11, “large colorectal cancer concern” and “early large bowel cancer concern” are included so as to include a portion corresponding to measurement data A of a subject diagnosed with early colorectal cancer. , Expand the area of "suspected early colorectal cancer", and narrow the area of "physical dysfunction level". On the contrary, for example, in the old diagnostic table, even if it is determined that “early colorectal cancer is suspected” from the correlation between the gas amounts of odorous gas and healthy gas, the result of the medical examination is suspected of cancer. If there are a large number of subjects diagnosed as having none, expand the “disease level” area, and narrow the “large colorectal cancer concern”, “early colorectal cancer concern”, and “early colorectal cancer suspect” areas . When the diagnostic table is updated, the areas of the display table are changed in the same manner.

In addition, the server 12 stores a plurality of physical condition display tables that are conditionally classified with respect to attribute information such as a subject's weight, age, and sex, and a history of changes in measurement data of odorous gas and healthy gas. .

When the subject-side device 10 wishes to perform a more detailed physical condition analysis, the server 12 registers the subject's identification information and attribute information such as the subject's weight, age, and sex. Then, when the measurement data of the subject who desires this more detailed analysis is accumulated in the server 12, the server 12 selects a physical condition display table with conditions close to the history of changes in the attribute information and measurement data of the subject. . The server 12 transmits the selected physical condition display table to the subject apparatus 10 via the network. When the test subject side apparatus 10 receives a new physical condition display table from the server 12, the subject side apparatus 10 changes the already stored physical condition display table to the received physical condition display table. Thereby, in the subject side apparatus 10, the more accurate physical condition analysis according to a test subject's attribute and the log | history of measurement data can be performed.

In the above-described embodiment, the subject-side device 10 is configured to store the history of measurement data. However, the measurement data is not limited to this, and the measurement data is stored only in the database of the server 12, and the subject side The apparatus 10 may read the history of past measurement data from the database of the server 12 and perform the examination result calculation and the successive diagnosis in the examination step S5.

Here, the calculation method of the reliability in the screening process S5 of FIG. 4 will be described in detail below. As a characteristic of the semiconductor gas sensor used as the odorous gas sensor 26, not only the odorous gas but also the odorous gas around the fragrance, the sanitizing sheet, etc., and the odorous gas adhering to the body and clothes of the subject are detected. Sometimes. Furthermore, the detected value of the odorous gas detected by the semiconductor gas sensor varies depending on the state of the stool (for example, whether or not it is a diarrhea state) and the amount of stool. For this reason, when determining the disease regarding cancer, it is calculated | required that the magnitude | size of the influence of these off-flavor gas noises and the state of a stool can be evaluated. In the present embodiment, the reliability determination means provided in the data analysis device 60 of the subject apparatus 10 installed in the toilet room is used to measure the influence of the odor gas noise of the defecation gas, the state of the stool, and the like. An event that affects the accuracy is evaluated, and the measurement reliability is determined as an index indicating the accuracy of gas detection by the gas detection device 20. This reliability determination means is constituted by an electric circuit built in the data analysis device 60.

FIG. 12 is a diagram for explaining a method of determining the measurement reliability. In the following description, a case where correction is performed by the influence of the off-flavor gas adhering to the subject's body or clothes, the influence of humidity, the influence of temperature, and the influence of the number of defecation gases will be described as an example. The following determination of the measurement reliability is performed using a reliability determination unit that determines the reliability of detection of odorous gas in the data analysis device 60 of the remote controller 8.

The outputs from the hydrogen gas sensor 24, odorous gas sensor 26, carbon dioxide sensor 28, humidity sensor 30, temperature sensor 32, entrance detection sensor 34, seating detection sensor 36, and defecation / urine detection sensor 38 of the measuring device 6 are transmitted from the remote control 8. Are sent to the data analysis device 60. FIG. 12 shows an example of outputs from these sensors.

In addition, a plurality of reliability correction tables for calculating reliability are recorded in the data analysis device 60 of the remote controller 8 in advance.

FIGS. 13 to 16 respectively show a subject-adherent off-flavor gas noise correction table for determining the influence of off-flavor gas adhering to the body and clothes of the subject, a humidity correction table for determining the influence of humidity, and the influence of temperature. It is a figure which shows the temperature correction table for performing, and the excretion count correction table for determining the influence by the frequency | count of excretion.

The semiconductor gas sensor used as the odorous gas sensor 26 detects a strange odor noise (environmental noise) other than the defecation gas adhering to the subject. It can be said that the reliability of measurement is low when the amount of off-flavor gas components (noise amount) attached to the subject is large. For this reason, as shown in FIG. 13, in the test subject attached odor gas noise correction table, a correction value is determined for the amount of attached odor gas noise. Specifically, when the amount of the off-flavor gas component adhering to the subject is less than a predetermined value, the correction value is set to 1 as a value that is not corrected. When the amount of noise of the off-flavor gas component adhering to the subject is too much larger than the predetermined amount, the negative correction amount from 1 is increased in order to gradually decrease the reliability value as the amount of off-flavor gas component increases. Is not measurable (correction value 0). The amount of attached odor gas noise is determined based on the detection data detected by the odorous gas sensor 26 during the non-defecation period before the seating detection sensor 36 detects that the subject has been seated. In addition, since the off-flavor gas component adhering to the subject affects the entire defecation period, not a part during the defecation period, the reliability is corrected over the entire defecation period. Hereinafter, this correction of reliability over the entire defecation period is referred to as “overall correction”.

Further, when the subject urinates, the humidity in the bowl 2a increases, and the humidity of the gas reaching the catalyst of the odorous gas sensor 26 increases. When the humidity of the gas that reaches the odorous gas sensor 26 increases, the resistance of the odorous gas sensor 26 changes and the sensor sensitivity decreases. Moreover, when urine is applied to the attached stool in the bowl 2a, the attached stool becomes soft from the dry state, and a large amount of defecation gas is temporarily released from the attached stool while the urine is applied again in the bowl 2a. There is. The defecation gas released from the attached stool may be detected by the odor gas sensor as noise when measuring the defecation gas released from the subject. For this reason, as shown in FIG. 14, in the humidity correction table, 1 is set when the humidity measured by the humidity sensor 30 is lower than a predetermined value, and when the humidity is higher than the predetermined value, the reliability increases as the humidity increases. Decreases and is not measurable (correction value 0) when the value exceeds the measurement limit value. Since the urination action is a temporary action, the humidity correction table is “partial correction” for correcting only the period during which the change in humidity measured by the humidity sensor 30 is observed. Note that, hereinafter, the correction of the reliability only in a specific period of the defecation period, or the correction of the whole defecation period, but the correction different in each period of the defecation period is referred to as “partial correction”.

The semiconductor gas sensor used as the odorous gas sensor 26 detects the odorous gas based on the oxidation / reduction reaction between oxygen adsorbed on the surface and the reducing gas in the state where the catalyst made of tin oxide is heated. is doing. For this reason, when the temperature of the catalyst is higher or lower than a predetermined temperature range, the sensor sensitivity is lowered. For this reason, as shown in FIG. 15, in the temperature correction table, a correction value is determined according to the temperature detected by the temperature sensor 32. Specifically, when the temperature detected by the temperature sensor 32 is within an appropriate temperature range suitable for the measurement of the catalyst of the odorous gas sensor 26, the correction value is set to a value larger than 1 so as to increase the reliability. When the temperature detected by the temperature sensor 32 is slightly higher or lower than the appropriate temperature range, the correction value is set to a value less than 1 so as to decrease the reliability value, and further, the temperature sensor detects the temperature. When the temperature is larger than the upper limit value of the measurable temperature or smaller than the lower limit value of the measurable temperature, measurement is impossible (correction value 0). The temperature correction does not vary greatly during the defecation period, and is therefore an overall correction for correcting the entire defecation period.

In addition, as described above, when performing the excretion action a plurality of times during a single defecation period, the amount of defecation gas itself is large (the amount of odorous gas is also large) in the first defecation period. The initial excretion action is more accurate than the later excretion action. For this reason, as shown in FIG. 16, in the excretion action frequency correction table, the first defecation gas correction value is set to a value larger than 1 so as to increase the reliability value, the second time is set to 1, and the third time and thereafter. The value was less than 1 and gradually decreased as the number of times increased. Thus, the first defecation gas is devised so as to be preferentially diagnosed. The excretion action frequency correction table corrects only the period during which defecation gas is detected, and is a partial correction.

As shown in FIG. 12, when the entrance detection sensor 34 detects the entrance of the subject at time t ₁ , the control device 22 of the measurement device 6 shifts from the pre-measurement environment maintenance process in the standby state to the measurement start preparation process. Then, the sensor heating heater 54 and the suction device 18 are driven. Thereby, the temperature detected by the temperature sensor 32 rises and converges to an appropriate temperature. Then, the data analysis device 60 of the remote controller 8 refers to the temperature correction table and refers to the correction value corresponding to the convergence temperature measured by the temperature sensor 32 during the non-defecation period before the seating detection sensor 36 detects the seating. To get. In the example shown in FIG. 12, the temperature correction value is 0.9.

Further, when the subject enters the room at time t ₁ , detection data detected by the odorous gas sensor 26 increases due to the off-flavor noise attached to the subject, and then converges to a certain value. Then, the seating by the seating detection sensor 36 at time t ₂ is detected. The data analysis device 60 of the remote controller 8 obtains a correction value corresponding to the detection data measured by the odorous gas sensor 26 in the non-defecation period before the seating detection sensor 36 detects the seating. In the present embodiment, the test subject adhesion odor gas noise correction value is 0.7.

Next, at time t ₃ , when the subject urinates during the defecation period after the seating detection sensor 36 detects the seating, the detection value by the humidity sensor 30 increases. The humidity increase detected by the humidity sensor 30 may be measured, for example, based on the humidity before the defecation period, that is, before the seating detection sensor 36 detects the seating. As described above, when an increase in the detection data is detected by the humidity sensor 30, the data analysis device 60 refers to the humidity correction table for the period during which the detection data is increasing, and corresponds to the increased detection data. Find the correction value. In the present embodiment, the partial correction value during the period in which the detection data from the humidity sensor 30 rises (that is, times t ₃ to t ₄ ) is 0.6.

Next, when the subject performs an excretion action at times t ₅ and t ₆ , the change rate of the difference between the detection data detected by the odorous gas sensor 26 and the reference value is equal to or greater than a predetermined value. The analysis device 60 calculates the amount of gas accompanying this excretion action. At the same time, the data analysis device 60 refers to the frequency correction table according to the number of excretion actions during the defecation period, and the period corresponding to the first excretion action (that is, times t ₅ to t ₅ ′) The correction value becomes 1.5, and the period corresponding to the second excretion action (that is, times t ₆ to t ₆ ′) becomes the correction value 1.0.

The data analysis device 60 calculates the measurement reliability of gas detection associated with each excretion based on the overall correction value and the partial correction value estimated in this way. In the present embodiment, the reliability is based on 3, and the reliability for each excretion is calculated as 3 × the product of all the total correction values × the product of all the corresponding partial correction values. Specifically, the reliability of the first excretion is 3 (reference) × 0.9 (temperature correction value) × 0.7 (subject adhesion noise correction value × 1.5 (number of times correction value) = 2.84. The reliability of the second excretion action is 3 (reference) × 0.9 (temperature correction value) × 0.7 (subject adhesion noise correction value × 1.0 (number of times correction value) = 1. 89.

Then, the reliability calculated in this way is displayed on the display device 68 of the remote controller 8 as described with reference to FIG. Further, the calculated reliability is transmitted from the subject apparatus to the server 12 together with the detection data of the odorous gas sensor 26 and the detection data of the hydrogen gas sensor 24, and is recorded in the defecation gas database of the server 12. At this time, raw data that is not corrected by reliability described later is recorded in the stool gas database of the server 12 as the detection data of the odor gas sensor and the detection data of the hydrogen gas sensor. When the measurement data is browsed by the medical institution terminal 16 connected to the server 12, the measurement reliability is displayed together with the detection data of the odorous gas sensor 26 and the detection data of the hydrogen gas sensor 24. The doctor of the medical institution makes a diagnosis with reference to the measurement reliability displayed together with the odorous gas and hydrogen gas displayed on the medical institution terminal 16. Thereby, when a doctor etc. diagnoses a test subject's physical condition based on measurement data, a more exact diagnosis can be performed using data with high measurement reliability. In addition, the doctor may make a diagnosis without using or placing importance on data with low measurement reliability. Note that when the reliability of a part or all of the measurement data is 1 or less, the measurement accuracy is very low. Therefore, the measurement data is not transmitted to the server 12 because measurement is impossible.

It is also possible to correct the detection data of the odorous gas sensor 26 and the hydrogen gas sensor 24 based on the measurement reliability calculated in this way. Specifically, when the measurement reliability is high, an actual detection value is used, but when the measurement reliability is low, the detection value is corrected to be a value close to a past detection value. As an example, when analyzing the physical condition based on the defecation gas detection data associated with the first excretion action in the subject-side device 10, a new detection is performed so as to approach the past measurement data recorded in the storage device of the remote controller 8. A case where the detected value is corrected will be described. As described above, the reliability associated with the first excretion was calculated as 2.84.

The data analysis device 60 determines the correction amount of the measurement value based on the reliability calculated in this way. FIG. 17 is a diagram showing a correction table showing the relationship between the reliability recorded in the data analysis device and the correction rate of the measured value. As shown in the figure, for example, in this embodiment, when the reliability is 1 or less, the reliability of the detection data is too low, and thus the measurement value is not usable. That is, the physical condition is not analyzed based on the detection data during the period when the reliability is equal to or less than the predetermined value, and the analysis is performed based only on the detection data having the reliability higher than the predetermined value, and the analysis result is displayed on the display device 68. When the reliability is greater than 1 and less than or equal to 2, correction is performed so that the measured value approaches 20% toward the past history side. Further, when the reliability of the measurement value is greater than 2 and less than or equal to 3, correction is performed so that the measurement value approaches 15% toward the past history side. When the reliability is greater than 3 and less than or equal to 4, correction is performed so that the measured value approaches 10% toward the past history side. When the reliability is greater than 4 and less than or equal to 5, correction is performed to bring the measured value closer to the past history side by 5%. If the measured value is greater than 5, the measured value is used without correction.

In the above example, the reliability associated with the first excretion is 2.84. For this reason, as described with reference to FIG. 7A, correction is performed so that the plot point of the latest data approaches 15% of the past measurement value, and the past data is displayed together with the past data.

Note that such correction based on reliability may be performed on the server 12 side. In addition, when analyzing the physical condition on the server 12 side, for example, the detection value of the odorous gas and the detection value of the hydrogen gas of the excretion action whose reliability is equal to or higher than a predetermined value in one defecation period are totaled. The physical condition may be analyzed based on the totaled data. In addition, the detection data stored in the storage device of the remote controller 8 does not necessarily have to be corrected based on the measurement reliability, and the corrected detection data may be recorded.

The correction table is not limited to the above-described subject-adherent odor gas noise correction table, temperature correction table, and humidity correction table. 18 to 29 are diagrams illustrating examples of the correction table.

For example, when there is a strange odor noise (environmental noise) other than the defecation gas such as a fragrance in the toilet room, the odorous gas sensor 26 may detect this strange odor noise and the measurement accuracy may be lowered. Therefore, the data analysis device 60 corrects the reliability in order to evaluate the influence of environmental noise. In addition, about the noise amount of such environmental noise, it can evaluate based on the detection data by the odorous gas sensor 26 before a test subject's entrance is detected by the entrance detection sensor 34, for example. FIG. 18 is a diagram showing an environmental noise correction table. As shown in the figure, the environmental noise correction value is 1 when the environmental noise amount is smaller than a predetermined value, and is corrected to lower the reliability value as the environmental noise amount becomes larger than the predetermined value. Decrease the coefficient. When the amount of environmental noise is equal to or higher than the measurable upper limit, measurement is impossible. The environmental noise correction value affects the entire defecation period, and therefore may be a total correction.

In addition, for example, when the reference value is set, such as when a spray-type fragrance is used, the detection data of the odorous gas sensor 26 greatly fluctuates, or the reference value set when the gas amount is estimated. When the inclination is large, the accuracy of the estimated gas amount is lowered. Therefore, the data analysis device 60 refers to the reference value stability correction table, and corrects the reliability in order to evaluate the influence of such a reference value stability failure state (referred to as a reference value stability failure). The reference value stability can be evaluated based on, for example, the inclination of the reference value with respect to the time axis during the non-defecation period and the magnitude of fluctuation in the detection value of the odorous gas sensor 26 when setting the reference value. FIG. 19 is a diagram illustrating a reference value stability correction table. As shown in the figure, the reference value stability noise correction value is 1 when the reference value stability failure is small, and decreases as the reference value stability failure increases. When the reference value stability failure is equal to or greater than a predetermined value, measurement is impossible. In addition, since estimation of the gas amount sets a reference value for each excretion action, it is a correction value only for a period corresponding to each excretion action, that is, a partial correction.

Further, for example, when the toilet seat is washed with a sterilization sheet, the odorous gas sensor 26 detects components such as alcohol contained in the sterilization sheet. As for the influence of components such as alcohol contained in the sterilization sheet, a large value is detected in the odor gas sensor 26 immediately after the use of the sterilization sheet. However, since alcohol is highly volatile, it is odorous in a short period of time. The value detected by the gas sensor 26 is lowered. Therefore, the data analysis device 60 refers to the sanitized toilet seat cleaning correction table and corrects the reliability according to the influence of toilet seat sanitization. The use of the sterilization sheet is, for example, detected by the odorous gas sensor 26 after detecting that the subject has entered the room by the room detection sensor 34 and before detecting that the subject has been seated by the seating detection sensor 36. It can be detected by detecting that the data fluctuates more than a predetermined value. FIG. 20 is a diagram showing a sanitized toilet seat cleaning correction table. When it is detected that the sterilization sheet has been used in this way, the measurement is impossible (correction value 0) for a predetermined period from the detection of the sterilization sheet, and the correction value for the subsequent period is a value less than 1. Ascends to 1 over time. In addition, since the influence of a disinfection sheet changes with time as above-mentioned, it is set as partial correction | amendment.

Moreover, since the odorous gas contained in the defecation gas is very small, the more odorous gas discharged during the defecation period, the more accurate physical condition analysis can be performed. Therefore, the data analysis device 60 refers to the defecation gas total amount correction value table and corrects the reliability based on the total amount of odorous gas. The total amount of defecation gas can be evaluated by the total amount of gas estimated based on the detection data of the odorous gas sensor within the defecation period. FIG. 21 is a diagram showing a defecation gas total amount correction value table. As shown in the figure, the defecation total amount correction value is determined to be unmeasurable (correction value 0) if any problem occurs such as spraying a fragrance spray during measurement when the defecation gas total amount is a predetermined value or more, Further, when the total amount of the defecation gas is equal to or less than the predetermined value, the measurement is impossible (correction value 0) because the defecation gas is too small to perform accurate measurement. Then, within a range where it is not determined that measurement is impossible (correction value 0), if the defecation gas total amount is large, the correction value is set to 1, and the correction value decreases as the defecation gas total amount decreases. Note that the total defecation gas amount correction is a total correction because a correction value is set based on the total defecation gas amount for the entire defecation period.

In addition, since a large amount of defecation gas is released into the bowl at farting times than during defecation, defecation gas by farting is suitable for physical condition analysis. For this reason, when the fart by the subject is detected, the data analysis device 60 refers to the fart correction value table and corrects the reliability in the fart period based on the amount of defecation gas included in the fart. To do. As for fart action, when the seat detection is detected by the seat detection sensor 36, it is detected that the difference between the detected value of the odorous gas sensor 26 and the reference value has rapidly increased at a change rate of a predetermined value or more. In addition, it can be determined that a fart act has been performed. Further, the period from when the above-mentioned difference suddenly increases until the detection value of the gas sensor 26 returns to the reference value may be a fart period. In order to detect that a fart action has been performed more accurately, the detection data of the odorous gas sensor 26 rises rapidly at a rate of change of a predetermined value or more, and the stool is placed in the bowl by a sealed water amount sensor or the like. What is necessary is just to detect that it is not discharged | emitted. FIG. 22 is a diagram illustrating a fart correction value table. As shown in the figure, in the fart correction value table, when the fart gas amount (the amount of stool gas detected by the odorous gas sensor) is small, the correction value is 1, and the fart gas amount increases as the fart gas amount increases. The correction value may be set to increase.

In addition, when there is a large amount of stool in each excretion act, the amount of defecation gas increases and a more accurate physical condition analysis can be performed. The amount is reduced and the accuracy of physical condition analysis is reduced. Therefore, the data analysis device 60 refers to the stool volume correction value table and corrects the reliability based on the stool volume during each excretion action. The stool volume can be evaluated by, for example, a sealed water volume sensor (stool volume measuring device) that detects a change in the sealed water volume of the defecation / urine detection sensor 38. FIG. 23 is a diagram illustrating a stool amount correction value table. As shown in the figure, when the stool volume is equal to or less than a predetermined value, the amount of stool gas is very small as well as the stool volume, and the measurement is impossible because accurate analysis cannot be performed. When the stool volume exceeds a predetermined value, the correction value gradually increases from a value less than 1 to a value greater than 1 as the stool volume increases. Since the stool volume is determined for each excretion action, the stool volume correction value is a partial correction.

Also, for example, when the stool is in a diarrhea state, since the release time is short, the sensor cannot sufficiently detect defecation gas. Moreover, when the stool after defecation floats in the sealing water, the defecation gas is released from the stool that floats in the sealing water, and the detection accuracy of the defecation gas decreases. Therefore, the data analysis device 60 refers to the flight type correction table and corrects the reliability according to the flight type of each excretion action. Note that the stool type can be detected based on the detection results using a CCD of a defecation / urine detection sensor 38 as a stool state detection device, a microwave sensor, or the like. In addition, feces floating can be detected by installing a CCD, a microwave sensor or the like in the bowl as a floating detector. FIG. 24 is a diagram illustrating a flight type correction value table. As shown in the figure, in the case of diarrheal stool, measurement is not possible (correction value 0). Is detected, the correction value is set to 1. In addition, since a flight type is determined for every excretion action, the flight type correction value is a partial correction.

Also, a healthy person usually defecates about once a day. On the other hand, if the gastrointestinal condition worsens due to food poisoning or the like, defecation may occur several times a day. In such a case, even if defecation is performed, the amount of defecation gas released during defecation is reduced. In addition, when the frequency of defecation decreases due to constipation or the like, the amount of defecation gas increases because the generation time of the odor component becomes longer or the amount of stool increases. If the defecation interval becomes too large, the analysis accuracy of the physical condition is lowered. Therefore, the data analysis device 60 refers to the defecation interval correction table and corrects the reliability based on the defecation interval. The defecation interval can be determined based on the date and time of the previous defecation stored by the data analysis device 60 and the defecation history information input in the measurement start preparation step S2. FIG. 25 is a diagram illustrating a defecation interval correction value table. As shown in the figure, when the defecation interval is extremely short, the correction value is very lower than 1, and when the defecation interval is about one day, the correction value is 1, and the defecation interval is 2. When it is about days, the correction value is set to a value lower than 1, and when the defecation interval is 4 days or more, the correction value is set to a value much lower than 1. The defecation interval correction value is the overall correction.

In the determination of the physical condition based on the defecation gas, for example, when the gastrointestinal condition deteriorates due to the cause of eating and drinking edible the day before, the physical condition is determined worse than the original physical condition. For this reason, the daily life results in variations in the physical condition analysis results. For this reason, for example, at the time when the analysis of physical condition by the biological information measurement system of the present embodiment is started, if a day with a bad physical condition happens to overlap due to overdrinking and eating, etc., an analysis result with a poor physical condition even if the history is displayed Only the message is displayed, and there is a possibility that accurate determination of the disease cannot be performed in a medical institution or the like. Therefore, the data analysis device 60 corrects the reliability in accordance with the number of past measurement data stored in the subject-side device with reference to the data accumulation amount correction table. FIG. 26 is a diagram illustrating a data accumulation amount correction table. As shown in the figure, when the number of accumulated data is less than 5, diagnosis is impossible (correction value 0), and when the number of accumulated data is 5 times or more and less than 10, the correction value is 1 If the number of stored data is 10 times or more and less than 30 times, the correction value is set to a low value of less than 1, and if the number of stored data is 30 times or more, the correction value is corrected. The value is 1. The subject-side device in the present embodiment is not a device for diagnosing cancer, but is a device intended to make the subject recognize that the risk of cancer has increased with changes in physical condition and to improve life. For this reason, since the accuracy of one measurement is not high, and the change history is the value of this apparatus, it is desirable to take such measures to prevent unnecessary psychological burden.

If the filter 72 installed in the duct 18a is clogged, the amount of air sucked into the duct 18a is reduced. On the other hand, if the air volume of the gas sent to the odorous gas sensor 26 or the hydrogen gas sensor 24 changes, the detection data of the odorous gas sensor 26 or the hydrogen gas sensor 24 changes according to the air volume. Further, if the wind speed of the gas sent to the odorous gas sensor 26 or the hydrogen gas sensor 24 is high, the time for the gas to contact the sensor is short, and the catalyst of the sensor does not react sufficiently. For this reason, it is desirable that the amount of air sent to the odorous gas sensor 26 and the hydrogen gas sensor 24 is constant. For this reason, the data analysis device 60 refers to the air volume correction value table and corrects the reliability according to the air volume (wind speed) of the gas sent to the odorous gas sensor 26 or the hydrogen gas sensor 24. In addition, the gas | air volume can be estimated based on the electric current and voltage of the suction fan 18c provided in the deodorizing apparatus, for example. FIG. 27 is a diagram showing an air volume correction value table. As shown in the figure, in the air volume correction table, when the air volume is less than the measurable lower limit value and greater than or equal to the measurable upper limit value, measurement is impossible (correction value 0), and the correction value is 1 within the optimum air volume range. It is set to a value close to 1 within a measurable range other than that. In the present embodiment, since the influence of the decrease in the air volume due to clogging has a greater influence on the sensor detection sensitivity than when the air volume is large, the correction value in the range higher than the optimum range within the measurable range is The correction value in the range lower than the optimum range is set low. Since the air volume during the measurement does not change greatly, the overall correction is made.

The defecation gas contains CO ₂ gas as a health gas, like hydrogen gas. For this reason, when a large amount of CO ₂ is detected by the CO ₂ gas sensor, the defecation gas is reliably detected by the sensor device. Therefore, the data analysis device 60 refers to the CO ₂ correction table and corrects the reliability based on the CO ₂ detection data detected by the carbon dioxide sensor 28. FIG. 28 is a diagram showing a CO ₂ correction table. As shown in the figure, in the CO ₂ correction table, when the detected amount of CO ₂ is less than a predetermined value, the correction value is set to 1, and when the detected amount of CO ₂ is greater than or equal to the predetermined value, it increases. The correction value is increased. Since the CO ₂ correction value can be calculated for each excretion action, it is a partial correction. Thus, in the present embodiment, since the detected hydrogen gas is corrected based on the amount of CO ₂ gas, the health system gas is evaluated using hydrogen gas and CO ₂ gas.
Further, when the physical condition analysis is performed using the detection data of the CO ₂ gas sensor as the detection data of the health gas, the correction value increases as the detection value detected by the hydrogen gas sensor 24 increases instead of the CO ₂ correction table. It is sufficient to use an H ₂ correction table that increases the value.

排 Defecation gas contains methane as a health gas, similar to hydrogen gas. For this reason, for example, a methane gas sensor that reacts strongly with methane gas is installed in the duct 18a of the deodorization device, and when a large amount of methane is detected by the methane gas sensor, a large amount of defecation gas is released. Therefore, the data analysis device 60 refers to the methane gas correction table and corrects the reliability based on the detected amount of methane gas detected by the methane gas sensor. FIG. 29 shows a methane gas correction table. As shown in the figure, in the methane gas correction table, when the detected amount of methane gas is less than a predetermined value, the correction value is 1, and when the detected amount of methane gas is greater than or equal to the predetermined value, the correction value increases as it increases. Has increased. Since the methane gas correction value can be calculated for each excretion action, it is a partial correction.

In this embodiment, when the detected values of CO ₂ and methane are high, the reliability is corrected to be high. However, the present invention is not limited to this, and when the detected values of CO ₂ and methane are high, the hydrogen gas It is also possible to perform correction so as to increase the detection value.

If there is cancer in the intestines, not only odorous gas but also hydrogen sulfide gas is included in the defecation gas. For this reason, for example, a hydrogen sulfide gas sensor that reacts strongly with hydrogen sulfide gas is installed in the duct 18a of the deodorization device, and the reliability is determined based on the detection data of the hydrogen sulfide gas detected by the hydrogen sulfide gas sensor. to correct. FIG. 30 is a diagram showing a hydrogen sulfide gas correction table. As shown in the figure, in the hydrogen sulfide gas correction table, the correction value is set to 1 when the detected amount of sulfide gas is less than a predetermined value, and increases when the detected amount of hydrogen sulfide gas is equal to or greater than the predetermined value. The correction value is increased as time goes on. Since the hydrogen sulfide gas correction value can be calculated for each excretion action, it is a partial correction. The reliability is calculated using a part or all of the correction table described above.

Next, in the example described with reference to FIG. 9, detailed description regarding the method of estimating the gas amount is omitted, and thus description will be given here.
As the odorous gas sensor 26 for measuring the odorous gas, a semiconductor gas sensor or a solid electrolyte sensor is used. Gas sensors such as semiconductor gas sensors, solid electrolyte sensors, and hydrogen gas sensors react not only to odorous gases but also to fragrances and alcohol contained in sanitizing sheets.

That is, even when the subject is absent, the detection data of the gas sensor includes environmental noise due to, for example, the effect of the fragrance or residual stool adhering to the bowl of the toilet bowl. In addition, the influence of such a fragrance | flavor and the residual stool adhering to the bowl of a toilet bowl does not change a lot with time.

When the subject enters the toilet space, the detection value detected by the gas sensor is slow due to the influence of the body odor of the subject and the off-flavor gas components adhering to the subject's body and clothes such as the perfume and hair styling used. However, when the subject is seated, the upper part of the bowl is covered with the subject and clothes, and therefore the data value detected by the gas sensor is stabilized or slowly increased.

In addition, if the subject cleans the toilet seat with the sanitization sheet, the amount of gas measured by the semiconductor gas sensor increases sharply at the moment when the sanitization sheet is used. After a while, the detection value measured by the gas sensor does not increase due to the influence of the sterilization sheet.

That is, after the subject is seated, the detection value of the gas sensor may slowly increase due to the influence of the off-flavor gas adhering to the subject's body, but it does not increase rapidly.

On the other hand, when the subject starts excretion, the gas sensor reacts to odorous gas or hydrogen gas contained in the defecation gas at the time when each excretion is performed, and the detected value of the gas sensor increases rapidly and peaks. Decreases after recognizing.

For this reason, the inventors do not rapidly increase the detection value by the gas sensor after the subject is seated on the toilet seat, and if this detection value is used as a reference value, the odorous gas or hydrogen gas contained in the defecation gas Thought that it could be detected as a sudden increase from this reference value.

Therefore, in the present embodiment, as described with reference to FIG. 9, the data analysis device 60 performs the excretion action after time t ₂ when the seating detection sensor 36 detects that the subject is seated on the toilet seat 4. the detection data of the gas sensor non-bodily functions period before the time t ₅ to start to set as the reference value. Next, the data analyzer 60 sets the time when the difference between the change rate becomes positive than a predetermined value between the detection value and the reference value of the gas sensor at the time t ₅ as the time of disclosure of bodily functions. Then, the data analysis device 60 integrates the difference between the detected value of the gas sensor during the excretion action and the reference value over time from the start point to the end point of the excretion action (that is, from the reference value of the gas amount during the excretion action). Is also estimated as the amount of defecation gas. The end point of the excretion action may be a time point when the detection value of the gas sensor returns to the reference value again, or a time point when the rate of change of the difference between the detection value of the gas sensor and the reference value changes from positive to negative after the start time point. .

Note that, similarly to the odorous gas sensor 26, the hydrogen gas sensor 24 and the carbon dioxide sensor 28 may be affected by strange odor noise other than the defecation gas. For this reason, when estimating the gas amount of hydrogen gas and carbon dioxide gas based on the detection data of the hydrogen gas sensor 24 and the carbon dioxide sensor 28, it is good to carry out similarly to defecation gas.

In addition, the estimation method of gas amount is not limited to said method. Hereinafter, a gas amount estimation method in the biological information measurement system of the second embodiment will be described. The second embodiment is different from the first embodiment only in the gas amount estimation method.
Also in the system of the present embodiment, as in the first embodiment, a semiconductor gas sensor or a solid electrolyte sensor is used as the odorous gas sensor 26 for measuring odorous gas. The semiconductor gas sensor or the solid electrolyte sensor has a low sensitivity because it measures the amount of gas by detecting a heated catalytic reaction. Also, the hydrogen gas sensor 24 has a low sensitivity like the semiconductor gas sensor. When using a gas sensor with such a low sensitivity, the following problems arise. The following problems are not unique to the semiconductor gas sensor, and the same applies to the solid electrolyte sensor and the hydrogen gas sensor.

For example, as shown in FIG. 31, the total gas discharge amount of the defecation gas is constant, but for each of the conditions S1, S2, and S3 having different discharge time and discharge amount per hour, a semiconductor gas sensor is used as the odorous gas sensor 26. Consider a case where odorous gas is detected. FIG. 32 is a diagram showing a detection waveform of the gas sensor when the discharge time and the discharge amount per time are changed, and FIG. 33 shows the gas amount calculated based on the detection waveform of the gas sensor. Note that S1 ′, S2 ′, and S3 ′ in FIGS. 32 and 33 correspond to S1, S2, and S3 in FIG. 31, respectively.

As shown in FIG. 32, even if the total gas discharge amount of the defecation gas is constant, if the discharge time is different, the gas discharge waveform does not converge unless the same amount of time is taken due to the time constant of the gas sensor. For this reason, the inventors paid attention to the inclination at the time of gas discharge. FIG. 34 is an enlarged view of the initial part of the detection waveform of the gas sensor shown in FIG. As shown in the figure, when the discharge amount (discharge density) per time is different, the slope from the start of discharge to the peak value and the time to reach the peak value are different. As the discharge amount per hour (discharge concentration) increases, the slope to the peak value increases, and as the gas discharge time increases, the arrival time to the peak value increases. Further, FIG. 35 is a graph showing the relationship between the discharge amount per time (discharge density) and the rising slope of the detection data waveform detected by the sensor. As shown in the figure, it can be said that the discharge amount per time (discharge concentration) and the slope of the rising edge of the waveform detected by the semiconductor gas sensor have a substantially proportional relationship.

The inventors have found that the slope of the detection waveform by the semiconductor gas sensor described above corresponds to the discharge amount (discharge concentration) of the discharge gas per hour, and the arrival time to the peak of the detection waveform by the semiconductor gas sensor corresponds to the discharge time. Based on the product of the slope of the detection waveform of the semiconductor gas sensor and the arrival time to the peak (gas sensor waveform area), the gas amount was estimated. Note that FIG. 36 shows the product of the slope of the detection waveform of the semiconductor gas sensor and the arrival time to the peak for each of the conditions S1, S2, and S3 having different discharge times and discharge amounts (discharge concentrations) per time as described above. The gas amount estimated based on the gas sensor waveform area is shown. As shown in the figure, the gas amounts S1 ″, S2 ″, and S3 ″ estimated based on the product of the slope of the gas amount waveform and the arrival time until the peak are the same amount, and the waveform of the gas amount It can be seen that the gas amount can be accurately estimated based on the slope of the gas and the arrival time to the peak.

Therefore, in the present embodiment, as in the first embodiment described above, the detection data of the odorous gas sensor 26 after the time when the sitting of the subject is detected by the seating detection sensor 36 and before the excretion action is started are used. A reference value is set based on this. Then, as shown in FIG. 10A, when the change rate of the difference between the detected value measured by the odorous gas sensor 26 and the reference value exceeds a preset start threshold, the start time of the defecation gas amount estimation It is set as (that is, the start point of excretion). Next, as shown in FIG. 10A, when the rate of change of the difference between the detection data detected by the odorous gas sensor 26 and the reference value becomes negative (that is, the peak time of the detection data of the odorous gas sensor 26). Is set as the end point of the estimation of the defecation gas amount (that is, the end point of the excretion action).

Next, the data analysis device 60 calculates the change rate of the difference between the detection data from the start point to the end point of the excretion action and the reference value. In addition, the data analysis device 60 calculates the defecation gas discharge time from the start time to the end time of the excretion action. Then, the data analysis device 60 integrates the change rate of the difference between the detection data from the start point to the end point of the excretion action and the reference value and the defecation gas discharge time, and estimates this integrated value as the gas amount. The estimation of the hydrogen gas amount based on the detection data of the hydrogen gas sensor 24 and the estimation of the carbon dioxide gas amount based on the detection data of the carbon dioxide sensor 28 can be performed in the same manner. According to the gas amount estimation method described above, the influence of the time constant of the gas sensor can be eliminated, and the defecation gas amount can be estimated more accurately.

Furthermore, the inventors have examined the relationship between the discharge amount of the defecation gas per hour and the discharge time, and found that there is little individual difference in the relationship between the discharge amount and the discharge time. That is, when the discharge amount per hour of the defecation gas is large, the discharge time is a relatively short time regardless of the subject, and when the discharge amount per hour of the discharge gas of the defecation gas is small, The discharge time is a long and constant time regardless of the subject. For this reason, the inventors set the discharge time of the defecation gas (odorous gas) based on the discharge amount per hour of the odorous gas in the defecation gas (the change rate of the detected value detected by the odorous gas sensor 26). I thought it could be estimated. Similarly, the defecation gas (hydrogen gas and carbon dioxide) is based on the discharge amount of hydrogen gas and carbon dioxide per hour (the rate of change in the detected values detected by the hydrogen gas sensor 24 and the carbon dioxide sensor 28). ) Discharge time can be estimated. In the present embodiment, the area is estimated so as to obtain the correlation between the amount of the health gas and the amount of the odorous gas, but there is a similar correlation only with the concentration of the health gas and the odorous gas concentration. Therefore, the density may be obtained from the slope of the measured value of each sensor. In this case, since the area is not estimated, the measurement can be simplified.

Hereinafter, a gas amount estimation method in the biological information measurement system of the third embodiment based on the above knowledge will be described. The third embodiment differs from the first and second embodiments only in the gas amount estimation method. In the data analysis device 60, in addition to the difference change rate start threshold described in the above embodiment, change rate-discharge period data relating to the correspondence between the difference change rate and the gas discharge time is set. Yes.

A reference value is set based on the detection data of the odorous gas sensor 26 after the time when the subject's seating is detected by the seating detection sensor 36 and before the excretion action is started. The point in time when the rate of change of the difference between the detected value measured by the odorous gas sensor 26 and the reference value exceeds a preset start threshold is set as the start point of estimation of the defecation gas amount (that is, the start point of excretion). Set. Then, the data analysis device 60 refers to the change rate-discharge period data, and acquires discharge period data corresponding to the change rate of the difference between the detection value at the start time and the reference value. Then, the data analysis device 60 integrates the change rate of the difference between the detection data at the start of the excretion action and the reference value and the discharge time, and estimates this integrated value as the gas amount. The estimation of the hydrogen gas amount based on the detection data of the hydrogen gas sensor 24 and the estimation of the carbon dioxide gas amount based on the detection data of the carbon dioxide sensor 28 can be performed in the same manner. Also by the gas amount estimation method described above, it is possible to eliminate the influence of the time constant of the gas sensor and estimate the defecation gas amount more accurately. In the gas amount estimation method of each of the above embodiments, the case where the semiconductor gas sensor is used as the odorous gas sensor 26 has been described. However, the gas amount is estimated even when a solid electrolyte sensor is used instead. It can be carried out. In the above-described embodiment, the data analysis device 60 obtains the change rate of the difference, and refers to the change rate-discharge period data to obtain the discharge period data corresponding to the change rate of the difference between the detected value at the start time and the reference value. Although the gas amount was estimated based on the rate of change and the discharge period, the present invention is not limited to this. For example, the change rate-gas amount data in which the change rate of the difference and the gas amount are associated in advance is stored, the change rate of the difference is obtained, and the gas amount is calculated by referring to the change rate-gas amount data. It may be estimated directly.

In the biological information measuring system according to the first embodiment described with reference to FIG. 1, the measuring device 6 is incorporated in the toilet seat 4 placed on the flush toilet 2 installed in the toilet room R. However, in the biological information measuring system of the present invention, the measuring device does not necessarily need to be incorporated in the toilet seat.

FIG. 37A is a diagram illustrating a state in which the subject-side device in the biological information measurement system according to the fourth embodiment is attached to a flush toilet installed in a toilet room, and FIG. 37B is a measurement of the subject-side device illustrated in FIG. 37A. It is a perspective view which shows an apparatus. In addition, in 4th Embodiment, only the structure of a test subject side apparatus is different compared with 1st Embodiment. As shown in FIG. 37A, the biological information measurement system 101 of this embodiment has the same configuration as that of the first embodiment, but only the configuration of the measurement device 106 of the subject-side device 110 is different. The measuring device 106 of this embodiment is configured separately from the toilet seat 104.

As shown in FIG. 37B, the measuring apparatus 106 is attached to the apparatus main body 180, a duct 118a that is attached to the upper surface of the apparatus main body 180 so as to extend in the lateral direction, and whose tip is bent downward, and the apparatus main body 180. And a connected power cord 182. As shown in FIG. 37A, the measuring device 106 is fixed in a state where the end of the duct 118a is positioned in the bowl by hooking the end of the duct 118a on the side wall of the bowl of the flush toilet 2.

Similar to the first embodiment, the apparatus main body 180 includes a hydrogen gas sensor, an odorous gas sensor, a carbon dioxide sensor, a humidity sensor, a temperature sensor, an entrance detection sensor, a seating detection sensor, and a defecation / urination detection sensor. And a suction device, a sensor heating heater, and a transceiver. The gas sucked from the duct 118a is deodorized and discharged from a deodorized air outlet provided on the bottom surface of the apparatus main body 180. A hydrogen gas sensor, an odorous gas sensor, a carbon dioxide sensor, a humidity sensor, a temperature sensor, a sensor heating heater, and a fan are provided in the duct 118a. Since the arrangement of the sensors in the duct 118a is the same as in the first embodiment, the description thereof is omitted. With such a configuration, the measuring device 106 of the present embodiment also uses the odorous gas sensor, the hydrogen gas sensor, and the carbon dioxide sensor to adjust the amount of odorous gas, hydrogen gas, and carbon dioxide contained in the defecation gas. The corresponding detection data can be acquired.

The toilet seat 104 used together with the measurement device 106 of the present embodiment includes a toilet lid opening / closing device, a nozzle driving device, a nozzle cleaning device, a toilet cleaning device, and a toilet sterilization device. It is desirable to use a toilet seat with a washing function that can communicate with By using the measuring device 106 together with such a toilet seat, it is possible to perform various cleaning and sterilization operations when a strange odor gas is detected.

In the first embodiment, as shown in FIG. 3, in the gas detection device 20, the hydrogen gas sensor 24 is provided on the downstream side of the deodorizing filter 78, but such a configuration is not necessarily required. FIG. 38 is a diagram illustrating a configuration of a gas detection device in the biological information measurement system of the fifth embodiment. Note that the fifth embodiment differs from the first embodiment only in the configuration of the gas detection device. As shown in the figure, in the present embodiment, in the gas detection device 120, the arrangement of the hydrogen gas sensor 24 is different from the embodiment shown in FIG. In the present embodiment, the hydrogen gas sensor 24 is provided downstream of the deodorizing filter 78 in the intake passage 18b. According to such a configuration, even when a sensor that reacts not only to hydrogen gas but also to odorous gas is used as the hydrogen gas sensor 24, the influence of odorous gas is detected from data output by the hydrogen gas sensor 24. Can be removed.

In the first embodiment, the detection value detected by the hydrogen gas sensor 24 is subtracted from the detection value detected by the odorous gas sensor 26 to thereby separate the influence of the hydrogen gas and calculate the detection value of the odorous gas. However, the present invention is not limited to this. For example, the influence of hydrogen gas can be separated by shifting the arrival time of hydrogen gas and odorous gas to the odorous gas sensor 26 as described below. .

FIG. 39 is a diagram showing a configuration of a gas detection device according to a sixth embodiment configured to separate the influence of hydrogen gas by shifting the arrival times of hydrogen gas and odorous gas to the odorous gas sensor. . Note that the sixth embodiment differs from the first embodiment only in the configuration of the gas detection device. As shown in the figure, in the present embodiment, a branch path 283b that branches from the main path 283a of the intake passage 18b in the duct 18a is provided. In the first embodiment, the hydrogen gas sensor and the odorous gas sensor are separately provided. However, in this embodiment, both the hydrogen gas and the odorous gas are detected by a single semiconductor gas sensor.

As in the first embodiment, the intake passage 18 b is provided with a filter 72, a deodorizing filter 78 provided downstream of the filter 72, and a suction fan 18 c, and the branch path 283 b is downstream of the filter 72. Branches at The filter 72 is a filter that does not have a deodorizing function, and passes odorous gas and hydrogen, and prevents passage of foreign matters such as urine and cleaning agents. The deodorizing filter 78 is also a catalyst that adsorbs gas components such as odorous gas, as in the first embodiment.

The defecation gas in the bowl 2a of the toilet bowl is sucked into the intake passage 18b by the suction fan 18c at a constant flow rate. The defecation gas sucked into the intake passage 18b passes through the filter 72 to remove foreign substances such as urine and cleaning agents, and after the deodorizing filter 78 removes gas components such as odorous gas, Returned to the bowl 2a.

In the branch path 283b, a flow path switching valve 284, a column 286, a semiconductor gas sensor 288, and a pump 290 are sequentially provided from the upstream side toward the downstream side.

The flow path switching valve 284 is opened only for a part of the time during excretion (very short time), and a part of the defecation gas flowing through the intake passage 18b (for part of the time during the excretion of the subject) This is a valve for drawing into the branch path 283b. The flow path switching valve 284 is provided in the uppermost stream of the branch path 283b.

The column 286 is provided on the downstream side of the flow path switching valve 284, and is configured by, for example, filling a narrow fiber material with a thin fiber material. The column 286 is a mechanism that causes a difference in gas passage time depending on the molecular size (molecular weight) based on the principle of gas chromatography.

On the upstream side of the semiconductor gas sensor 288, a sensor heating heater 54 for heating the catalyst of the semiconductor gas sensor 288 to a predetermined temperature and removing an off-flavor gas component adhering to the semiconductor gas sensor 288 is provided.

By the flow path switching valve 284, a small amount of defecation gas that has passed through the filter 72 flowing through the intake passage 18b flows into the branch path 283b. Then, when the pump 290 is driven, hydrogen and odorous gas contained in the defecation gas pass through the column 286 and reach the semiconductor gas sensor 288 over a different time depending on the molecular weight according to the principle of gas chromatography. That is, hydrogen having a small molecular weight easily passes through the column 286 and reaches the semiconductor gas sensor 288 in a short time, and an odorous gas having a large molecular weight hardly passes through the column 286 and takes a longer time than hydrogen to reach the semiconductor gas sensor 288. To reach. The pump 290 is configured to suck the defecation gas at a constant flow rate.

FIG. 40 is a diagram showing a detection waveform detected by the semiconductor gas sensor of the gas detection device shown in FIG. As shown in the figure, according to the configuration of the gas detection device 220 of the present embodiment, the semiconductor gas sensor 288 reacts in a state of being temporally separated from the hydrogen gas and the odorous gas. In particular, excretion is performed in a short time, and defecation gas including hydrogen and odorous gas is released only for a short time. As described above, since the defecation gas is released in a short time, by providing the column 286 upstream of the semiconductor gas sensor 288, the time until the hydrogen gas and the odorous gas reach the semiconductor gas sensor can be shifted. The semiconductor gas sensor 288 can detect the amount of hydrogen gas and the amount of odorous gas. In this case, the inventors also adopted a method of determining the physical condition based on the correlation between healthy gas and odorous gas without measuring the total amount of methyl mercaptan gas correlated with cancer. This is based on the technical knowledge that it is only necessary to measure gas during a specific period. If a reduction sensor is used, it may be inexpensive, but it becomes difficult to separate a large amount of hydrogen contained in the defecation gas. On the other hand, according to the present embodiment, since the measurement is performed only for a small specific period, hydrogen separation is facilitated and practicality can be realized with an extremely inexpensive sensor.
In this embodiment, the arrival time of hydrogen and odorous gas to the semiconductor gas sensor 288 is shifted by the column 286, but it is also possible to shift the arrival time of methane contained in the defecation gas as a matter of course. . Thereby, it is also possible to separate not only hydrogen but also the influence of methane from detection data detected by the semiconductor gas sensor.

As described above, according to each of the above embodiments, the subject's physical condition is analyzed by the subject-side device 10 and the server 12 in the measurement of the defecation gas discharged into the bowl 2a of the flush toilet 2, There is no need for the subject to bother measuring, and diagnosis can be made by simply performing daily defecation. In addition, since there is no hassle at all, the subject is not burdened, and measurement can be continued for a long period of time, so that information on changes in health status and a situation in which cancer risk is increased can be obtained with certainty.

In each of the above embodiments, the gas detection device 20 does not use a pinpoint sensor for measuring methyl mercaptan gas, and is a semiconductor gas sensor or solid electrolyte that reacts widely with odorous gases other than methyl mercaptan gas in defecation gas. The sensor is used as the odor gas sensor 26. In a state where the risk of cancer has increased, a very strong odorous gas containing sulfur components such as methyl mercaptan gas and hydrogen sulfide increases. For this reason, according to each of the above embodiments, since a sensor that reacts widely with odorous gases such as a semiconductor gas sensor and a solid electrolyte sensor is used, an increase in cancer risk can be detected without fail.

Further, in each of the above embodiments, not only the methyl mercaptan gas but also the physical condition based on the detection data of the odor gas sensor 26 that detects the odor gas in the defecation gas other than the methyl mercaptan gas such as hydrogen sulfide, acetic acid, trimethylamine, and ammonia. Is being analyzed. For this reason, the analysis results based on the amount of odorous gas in the defecation gas reflect the results of the subject's poor physical condition and bad lifestyle, and the analysis results improve the physical condition and lifestyle that increase the risk of cancer. It can be used as an index based on objective data for making it happen, that is, as an effective index for maintaining health and reducing the risk of developing cancer.
Furthermore, according to each of the above embodiments, since a semiconductor gas sensor and a solid electrolyte sensor that reacts widely with not only methyl mercaptan gas but also odorous gas other than methyl mercaptan gas are used, an apparatus can be manufactured at low cost. It became possible to provide as a consumer product.

In addition, semiconductor gas sensors and solid electrolyte sensors that widely measure not only methyl mercaptan gas but also odorous gases other than methyl mercaptan gas, the measured values change depending on the physical condition and diet that change from day to day. There is no sex. On the other hand, according to each of the above-described embodiments, since the defecation gas is measured by a daily normal act of defecation, the measurement data accumulated and stored in the database is used even if the measurement accuracy of each time is low. As a result, it was possible to ensure the necessary and sufficient accuracy of the diagnosis that the risk of cancer is increasing or that the cancer is becoming cancerous.

Further, according to each of the above embodiments, the physical condition is analyzed every day based on not only methyl mercaptan gas but also odorous gas other than methyl mercaptan gas. For this reason, the test subject can use the analysis result as an index based on objective data values for improving bad lifestyle habits, that is, as an effective index for maintaining health and reducing the risk of developing cancer. .

Also, long-term measurement data needs to be accumulated in the analysis according to each of the above embodiments, and further, diagnostic analysis based on the measurement data is necessary. Incorporation of such a measurement data accumulation and analysis system into the subject-side device 10 installed in each home becomes a factor of cost increase, and hinders widespread use of the subject-side device 10 as a consumer product. On the other hand, according to each of the above embodiments, the measurement data is transmitted to the server 12 and managed in the database, and the physical condition analysis is performed on the server side. 10 could be provided at low cost. In addition, the accuracy of the physical condition analysis can be dramatically improved by the server 12.

Moreover, according to each said embodiment, in the test subject side apparatus 10, since a test subject's physical condition can be analyzed and output with respect to a test subject, the frequency of the analysis and notification in the server 12 is reduced, and a burden is reduced. In addition, the subject can quickly and easily improve daily life based on the display on the subject-side device 10.

Further, in each of the above embodiments, the analysis by the subject-side device 10 is simpler than the analysis by the server 12. As a result, the subject can obtain information frequently and in a timely manner by the subject-side device 10 and perform physical condition management, reduce the analysis burden by suppressing the frequency of analysis on the server side, and more accurately The cancer risk situation can now be analyzed.

Furthermore, in each said embodiment, the analysis in the test subject side apparatus 10 and the server 12 is performed based on the detection data of the odorous gas and health system gas containing a sulfur component. This makes it possible to ensure sufficient reliability by adding an inexpensive hydrogen gas sensor 24 to a simple odorous gas sensor 26 without using an expensive sensor, and to improve the accuracy of physical condition analysis. I was able to increase it dramatically.

Moreover, in each said embodiment, although the analysis result displayed on the medical institution terminal 16 contains the determination result regarding a specific disease, although the analysis result which the test subject side apparatus 10 displays includes the log | history of measurement data, a specific disease Does not include judgment results for For this reason, since the analysis result by the subject-side apparatus 10 does not include the determination result regarding cancer, no psychological burden is imposed on the subject. Moreover, since the analysis result displayed by the subject-side device 10 includes a history of measurement data, the change in physical condition can be grasped by confirming the data change, and the physical condition can be surely improved.

Moreover, in each said embodiment, the test subject side apparatus 10 analyzes a test subject's physical condition based on the data of the one part period during the defecation action among measurement data, and the server 12 has the defecation action among measurement data. The physical condition of the subject is analyzed based on data of a period longer than a part of the period, that is, the entire period. Thereby, in the test subject side apparatus 10, it became possible to receive a result during a defecation act or immediately after a defecation act.

Further, in each of the above embodiments, the measurement data for the whole period of the defecation action is recorded in the database, and the server 12 analyzes the physical condition of the subject based on the measurement data for the whole period of the defecation action. Thereby, an accurate disease analysis of cancer correlated with the amount of methyl mercaptan gas produced becomes possible.

Further, in each of the above embodiments, the subject-side device 10 includes the reliability determination unit, and analyzes the physical condition of the subject based on the measurement data in the period with high reliability among the measurement data. This makes it possible to analyze physical condition based on measurement data that is less affected by off-flavor gas components such as sweat and urine adhering to the subject, alcohol sanitizer, etc., and that the physical condition analysis is accurate and stable. can do.

In each of the above embodiments, the subject apparatus 10 performs analysis based on the first defecation gas detection period data in the measurement data. As a result, the analysis can be surely started during the defecation action period, so that the analysis result can be reliably provided during the defecation action or immediately after the defecation action. In addition, subjects may be reluctant to view the analysis results if they have a bad lifestyle habit, but the analysis results are in the process of defecation and immediately after defecation. Therefore, the subject always browses the analysis result, and the subject who is reluctant to view the analysis result can also promote physical condition improvement.

In each of the above embodiments, the reliability of the server 12 database is recorded together with the measurement data, and the reliability is output to the medical institution terminal 16 together with the analysis result. This makes it possible to accurately determine whether the poor analysis results are due to poor physical condition or due to noise from unsanitary environments, etc., and to reliably prevent unnecessary psychological burdens. became.

Moreover, in each said embodiment, the test subject side apparatus 10 receives the input of the defecation history information regarding a test subject's defecation history situation with the input device 64, and defecation history information is recorded with the measurement data in the database of the server 12, and medical institution. Defecation history information is output to the terminal 16 together with the analysis result. Thereby, even when the date and time of the measurement data recorded in the database is far away, it can be determined whether or not the patient is constipated, so that more accurate diagnosis can be performed.

Moreover, in each said embodiment, the test subject side apparatus 10 determines the stool volume and stool state of the stool which the test subject defecates, and information on the stool volume and the stool state is stored in the database of the server 12 together with the measurement data. The information is recorded and the information on the stool amount and the state of the stool is output to the medical institution terminal 16 together with the analysis result. Accordingly, doctors and the like can perform diagnosis after taking into account the amount of stool displayed on the medical institution terminal 16 and the state of the stool, so that accurate diagnosis can be performed.

Further, in each of the above embodiments, the subject-side device 10 can not transmit measurement data to the server when the reliability of the measurement data is low. According to such a configuration, transmission of data with low reliability to the server 12 can be omitted, so that unnecessary data transmission / reception and load on the server 12 can be reduced.

In each of the above embodiments, the subject apparatus 10 can analyze the physical condition of the subject based on the measurement data recorded in the database of the server 12. According to such a configuration, it is not necessary to provide a storage device for storing measurement data in the subject-side device 10, and the subject-side device 10 can be provided at a lower price.

Moreover, in each said embodiment, the server 12 comprises the new physical condition display table used as the reference | standard of the analysis by the test subject side apparatus 10 based on the measurement data accumulate | stored and recorded in the database, The physical condition display table is updated to a new physical condition display table configured by the server 12. Thereby, since the analysis in the subject side apparatus 10 can be easily updated to the physical condition display table in which the influence of individual differences is suppressed, the subject can perform health management with peace of mind.

R Toilet room 1 Biological information measuring system according to the first embodiment of the present invention 2 Flush toilet 2a Bowl 4 Toilet seat 6 Measuring device 8 Remote control 10 Subject side device 12 Server 14 Terminal for subject 16 Medical institution terminal 18 Suction device 18a Duct 18b Inhalation Passage 18c Suction fan 20 Gas detection device 22 Control device 22a CPU
22b Storage device 24 Hydrogen gas sensor 26 Odor gas sensor 28 Carbon dioxide sensor 30 Humidity sensor 32 Temperature sensor 34 Entrance detection sensor 36 Seat detection sensor 38 Defecation / urine detection sensor 40 Toilet lid opening / closing device 42 Nozzle driving device 44 Nozzle cleaning device 46 Toilet cleaning Device 48 Toilet sterilizer 50 Air freshener sprayer 52 Deodorizing air supply 54 Sensor heating heater 56 Transmitter / receiver 58 Duct cleaner 59 Humidity adjustment device 60 Data analysis device 62 Subject identification device 64 Input device 66 Transmitter / receiver 68 Display device 70 Speaker 72 Filter 78 Deodorizing filter 101 Biological information measuring system 104 of the fourth embodiment Toilet seat 106 Measuring device 118a Duct 180 Device body 182 Power cord 120 Gas detection device of the fifth embodiment 283a main path 283b branch path 284 flow channel switching valve 286 column 288 semiconductor gas sensor 290 pump

Claims (14)

1. A biological information measurement system for measuring the physical condition of a subject based on defecation gas discharged into a bowl of a flush toilet, the subject-side apparatus provided in a space where the flush toilet is installed, A server capable of communicating with the subject side device,
   The subject side device is:
   A suction device for sucking the gas in the bowl from which defecation gas was discharged during the defecation of the subject;
   A gas detection device that reacts with odorous gas other than methyl mercaptan gas and methyl mercaptan gas, which is contained in the gas sucked by the suction device and contains a sulfur component, and outputs first detection data;
   A subject identification device that accepts input of subject identification information;
   A control device for controlling the suction device and the gas detection device;
   A communication device that transmits measurement data including first detection data of odorous gas detected by the gas detection device to the server,
   The server
   A database in which measurement data including first detection data of odorous gas detected by the gas detection device is accumulated and recorded together with the date and time of the defecation action in association with the subject identification information received by the subject identification device When,
   Server-side data analysis means for analyzing the physical condition of the subject based on the temporal variation tendency of the measurement data accumulated and recorded in the database;
   And a server-side output device that outputs an analysis result by the server-side data analysis means.
2. The subject apparatus further includes:
   A subject-side data analysis device that analyzes the physical condition of the subject based on the temporal variation tendency of the measurement data;
   The biological information measurement system according to claim 1, further comprising: a subject side output device that outputs an analysis result by the subject side data analysis device.
3. The gas detection device further reacts with a health gas composed of at least one of hydrogen gas, carbon dioxide, or methane gas contained in the gas sucked by the suction device, and outputs second detection data,
   The measurement data includes second detection data of the health gas,
   The biological information measurement system according to claim 2, wherein the analysis by the subject-side data analysis device is simpler than the analysis by the server-side data analysis means.
4. The analysis result output by the server-side output device includes a determination result relating to a disease,
   The biological information measurement system according to claim 2, wherein the analysis result output by the subject-side output device includes a history of the measurement data and does not include a determination result regarding the disease.
5. The subject side data analysis device analyzes the physical condition of the subject based on some data during the defecation action of the measurement data,
   The server-side data analysis means analyzes the physical condition of the subject based on data of a longer period than the partial data during the defecation action in the measurement data. The biological information measurement system described in 1.
6. In the database, measurement data for the whole period of the defecation action is recorded,
   The biological information measurement system according to any one of claims 2 to 5, wherein the server-side data analysis means analyzes the physical condition of the subject based on measurement data of the whole period of the defecation action.
7. The subject-side data analysis apparatus further includes a reliability determination unit that determines the reliability of the first detection data output by the gas detection device,
   The subject data analysis apparatus analyzes the physical condition of the subject based on measurement data of a period with high reliability determined by the reliability determination means in the measurement data. The biological information measuring system according to item.
8. The subject-side data analysis device specifies an initial defecation gas detection period during a defecation action period in the measurement data, and performs analysis based on the specified first defecation gas detection period data in the measurement data.
   The biological information measurement system according to any one of claims 2 to 7.
9. The subject-side data analysis apparatus further includes a reliability determination unit that determines the reliability of the first detection data output by the gas detection device,
   In the database, the reliability is recorded together with the measurement data,
   The biological information measurement system according to claim 2, wherein the reliability is output together with an analysis result to the server-side output device.
10. The subject apparatus further includes an input device,
    The input device accepts input of defecation history information regarding the defecation history status of the subject,
    The database records the defecation history information together with the measurement data,
    The biological information measurement system according to claim 1, wherein the defecation history information is output together with the analysis result to the server-side output device.
11. The subject-side device further includes a stool state determination sensor that determines at least one of the stool volume and the stool state of the stool that the subject defecates,
    In the database, together with the measurement data, stool status information including at least one of the stool volume and stool status is recorded,
    The biological information measuring system according to claim 1, wherein the stool state information is output together with the analysis result to the server-side output device.
12. The subject-side data analysis device further includes a reliability determination unit that determines the reliability of the first detection data output by the gas detection device,
    The biological information measurement system according to any one of claims 2 to 11, wherein the subject-side apparatus does not transmit the measurement data to the server when the reliability determined by the reliability determination unit is low. .
13. The biological information measurement system according to any one of claims 2 to 12, wherein the subject-side data analysis device analyzes a physical condition of the subject based on the measurement data recorded in the database of the server.
14. The server constitutes new reference data serving as a reference for analysis by the subject-side data analyzer based on measurement data stored and recorded in the database,
    The biological information measurement system according to any one of claims 2 to 13, wherein the reference data of the subject-side data analyzer is updated to new reference data configured by the server.

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