KR20230155124A - System for Monitoring of Health Using Urine Test and Bionic Sensors - Google Patents

Abstract

The present invention relates to a health monitoring system using a urine test and biometric sensor, which includes a first sensor included in a hygiene product that collects parameters about the user's urine as first sensing data, and a user's oxygen saturation as second sensing data. Obtain image data for the second sensor, the third sensor that collects the user's heart rate as third sensing data, and the first sensing data, and analyze the image data, second sensing data, and third sensing data, It includes an electronic device that checks and displays the user's health status, including dementia, based on the analysis results of sensing data, and can be applied to other embodiments.

Description

Health monitoring system using urine test and bionic sensors {System for Monitoring of Health Using Urine Test and Bionic Sensors}

The present invention relates to a health monitoring system using urine tests and biometric sensors.

A urinalysis is a test that examines the physical properties of urine, such as color and turbidity, and semi-quantitatively detects various types of waste products excreted through urine. This urine test can be used as a screening test for early diagnosis of kidney and urinary system diseases such as urinary tract infections, endocrine diseases, metabolic diseases, and electrolyte abnormalities, as well as kidney diseases and systemic diseases. In particular, urine is commonly used for early screening of chronic diseases, including dementia.

Dementia is a representative neuropsychiatric disease in which the normally mature brain is damaged by causes such as acquired trauma or disease, resulting in a decline in cognitive functions such as overall intelligence, learning, language, behavior, and mental functions. As aging progresses rapidly, the number of elderly people suffering from dementia is increasing day by day, and due to digital developments, the number of people suffering from dementia at a young age is also increasing day by day.

Dementia can be diagnosed from recoverable dementia through early diagnosis, and in the case of vascular dementia, the progression of the disease can be stopped through appropriate treatment. In the case of Alzheimer's disease, it is possible to alleviate symptoms or slow the progression through appropriate treatment. . In particular, unlike degenerative dementia, early screening and early treatment of vascular dementia are very important because the occurrence or progression of dementia can be prevented by preventing additional secondary cerebrovascular diseases that may occur.

Embodiments of the present invention to solve these conventional problems provide a health monitoring system using a urine test and biometric sensors that can check health conditions, including dementia, in real time using a urine test and various biometric sensors.

In addition, embodiments of the present invention use urine tests and biometric sensors to receive sensing data that can confirm the individual's health status from personal hygiene products worn by the user and provide this to the user's electronic device to enable continuous monitoring. To provide a health monitoring system.

A health monitoring system according to an embodiment of the present invention includes a first sensor included in a hygiene product and collecting parameters about the user's urine as first sensing data, and a second sensor collecting the user's oxygen saturation as second sensing data. Obtaining image data for a sensor, a third sensor that collects the user's heart rate as third sensing data, and the first sensing data, and analyzing the image data, the second sensing data, and the third sensing data, , Characterized by including an electronic device that checks and displays the user's health status, including dementia, based on the analysis results of the sensing data.

Additionally, the first sensor is characterized in that it includes a visual indicator for at least one of amines, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, urobilinogen, bilirubin, and albumin.

In addition, the hygiene product is characterized as a pad or absorbent underpants worn by the user.

Additionally, the hygiene product is characterized by comprising a liquid-impermeable baffle and an absorbent, liquid-permeable liner.

Additionally, the first sensor is disposed between the baffle and the liner.

Additionally, the electronic device is characterized in that it makes a reservation at at least one hospital based on the confirmed health condition.

Additionally, the electronic device is characterized in that the reservation is made at a hospital previously stored in the electronic device.

Additionally, the electronic device is characterized in that it searches for hospitals located within a critical radius based on the location of the electronic device and performs the reservation.

In addition, a health monitoring system according to another embodiment of the present invention includes a first sensor included in a hygiene product and collecting parameters about the user's urine as first sensing data, and collecting the user's oxygen saturation as second sensing data. A second sensor, a third sensor that collects the user's heart rate as third sensing data, receives and analyzes the first sensing data, the second sensing data, and the third sensing data, and based on the analysis results, It is characterized by comprising a server that checks the user's health status, including dementia, and an electronic device that receives the health status from the server and displays it.

In addition, the hygiene product is characterized by further including a communication module that transmits the first sensing data to the server.

As described above, the health monitoring system using a urine test and biometric sensors according to the present invention has the effect of more easily and conveniently checking health conditions, including dementia, in real time using a urine test and various biometric sensors.

In addition, the health monitoring system using a urine test and biometric sensor according to the present invention has the effect of easily monitoring health information using various parameters included in secretions collected by personal hygiene products worn by the user.

In addition, the health monitoring system using a urine test and biometric sensor according to the present invention is effective in diagnosing and preventing simple gynecological diseases, including vaginitis, at an early stage using personal hygiene products.

1 is a diagram showing an example of a personal hygiene product according to an embodiment of the present invention.
Figure 2 is a diagram showing a health monitoring system according to an embodiment of the present invention.
Figure 3 is a diagram showing an electronic device that performs health monitoring according to an embodiment of the present invention.
Figure 4 is a flowchart explaining a method of performing health monitoring according to an embodiment of the present invention.
Figure 5 is a detailed flow chart to explain a method of analyzing sensing data according to an embodiment of the present invention.
Figure 6 is a detailed flowchart illustrating a method of making a hospital reservation according to an embodiment of the present invention.
Figure 7 is a diagram showing an example of a personal hygiene product according to another embodiment of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the attached drawings. The detailed description set forth below in conjunction with the accompanying drawings is intended to illustrate exemplary embodiments of the invention and is not intended to represent the only embodiments in which the invention may be practiced. In order to clearly explain the present invention in the drawings, parts unrelated to the description may be omitted, and the same reference numerals may be used for identical or similar components throughout the specification.

1 is a diagram showing an example of a personal hygiene product according to an embodiment of the present invention.

Referring to Figure 1, the hygiene product according to the present invention may be formed in the form of a pad 10, as shown in (a) of Figure 1, and may be formed in the form of underpants 20, as shown in (b) of Figure 1. . The pad 10 may be composed of a liquid-impermeable baffle 12 on the side and an absorbent, liquid-permeable body-side liner 14 as the layer closest to the user wearing the pad 10. An absorbent core (not shown) designed to retain liquid secretions may be disposed between the baffle 12 and the liner 14, and the first sensor 210 of the present invention is disposed inside between the core and the baffle 12. It can be.

The baffle 12 may be transparent only in an area corresponding to the first sensor 210 and other areas may be opaque. The entire area of the baffle 12 is transparent, and a non-absorbent film made of an opaque material is disposed on the lower part of the liner 14 except for the area corresponding to the first sensor 210, so that the user can detect the color of the secretion except for the color of the secretion. It may be configured to check only the discoloration of the first sensor 210. In addition, the baffle 12 may be mainly formed of polypropylene film, etc., and the signal measured from the first sensor 210 is transmitted to the server ( A communication module that transmits data (explained later) may be deployed.

In addition, the underpants 20 used in one embodiment of the present invention may be composed of a baffle 12 and a liner 14 like the pad 10. An absorbent core (not shown) may be disposed between the baffle 12 and the liner 14, and the first sensor 210 may be disposed between the absorbent core and the baffle 12. Additionally, a communication module that transmits the signal measured by the first sensor 210 to a server (described later) may be placed between the baffle 12 and the liner 14 or on one side of the baffle 12.

The configuration of the pad 10 and the underpants 20 described in FIG. 1 is a minimum configuration as an example, and it is obvious that more configurations may be included. In the embodiment of the present invention, a personal hygiene product in the form of a pad (10) will be described as an example, but it is not necessarily limited thereto, and such as a personal hygiene product in the form of underpants (20) that can be used by both men and women, or a tampon (not shown), etc. We clarify that this can also be applied to other personal hygiene products.

Figure 2 is a diagram showing a health monitoring system according to an embodiment of the present invention.

Referring to FIG. 2, the health monitoring system 100 according to the present invention includes a sensor 200 including a first sensor 210, a second sensor 220, and a third sensor 230, and an electronic device 300. and server 400.

The first sensor 210 is a sensor included in a hygiene product as shown in FIG. 1 and may include an indicator or information that can be visually recognized by the user. That is, the first sensor 210 may be a visual indicator for at least one of amine, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, urobilinogen, bilirubin, and albumin. Data changed by the user's urine in the first sensor 210, which is a visual indicator, may be first sensing data. When a user is wearing a hygiene product and the hygiene product receives urine, the urine may pass through the liner 14 and contact the first sensor 210 disposed under the liner 14 of the hygiene product, and the urine Depending on the components contained in the first sensor 210, discoloration may occur. Such discoloration can be confirmed through the baffle 12 made of transparent material.

Vaginal infections come in the form of bacterial vaginosis or trichomoniasis, both of which produce amines. Accordingly, in an embodiment of the present invention, the first sensor 210 may include an amine-sensitive dye. When a user is wearing a hygiene product and the hygiene product receives secretions, that is, urine, the fluid passes through the liner 14 and comes into contact with the first sensor 210 disposed below the liner 14 of the hygiene product. If amines are present in urine, the first sensor 210 containing the amine-sensitive dye may be discolored.

The first sensor 210 may be a visual indicator of the specific gravity in urine, and the specific gravity of urine is determined by the ion concentration of solutes dissolved in urine, and can estimate the concentration and dilution abilities of the kidney. The specific gravity of urine can determine whether the kidneys are concentrated or have impaired dilution capacity.

The first sensor 210 may be a visual indicator of urine pH, and in an embodiment of the present invention, the first sensor 210 may include methyl red and bromophenol blue. . In this case, if the urine is acidic, it turns scarlet, and if it is alkaline, it turns blue. Normal people's urine pH ranges widely from 4.5 to 8.0 depending on the food or amount of water consumed, but acid urine can be seen during respiration or metabolic acid, and contradictory acid urine can also be seen in alkalosis caused by hypokalemia. Acidic urine can also be seen in fever, diarrhea, uremia, and starvation.

The first sensor 210 may be a visual indicator of free hemoglobin in urine and may test for occult blood in urine. In an embodiment of the present invention, the first sensor 210 may include tetramethylbenzidine. If the first sensor 210 is oxidized to green or dark blue due to free hemoglobin in the urine, hematuria can be assumed, or hemochromatosis, myoglobinuria, and bacterial peroxidase can be determined by heme in hemoglobin.

The first sensor 210 may be a visual indicator for urine protein and, in an embodiment of the present invention, may include tetrabromophenol or tetrachlorophenol. When the yellow color of the first sensor 210 changes to green due to urine protein, the concentration of urine protein can be estimated according to the degree of discoloration.

The first sensor 210 may be a visual indicator for leukocyte esterase (LE) and, in an embodiment of the present invention, may include an ester compound. If the ester compound of the first sensor 210 is hydrolyzed by leukocyte esterase released from neutrophils in the urine and turns purple, the presence of leukocytes in the urine can be determined as positive.

The first sensor 210 may be a visual indicator of nitrite in urine and may include arsanilic acid (p-arsanilic acid) in an embodiment of the present invention. If nitrite is present in urine, the first sensor 210 turns pink. Nitrite is a substance formed when nitrate absorbed into the body through food is oxidized by urinary tract infection bacteria. A positive reaction indicates the presence of significant urinary tract infection bacteria in the urine.

The first sensor 210 may be a visual indicator for glucose in urine, and in an embodiment of the present invention, may be potassium uride. When glucose is present in urine, the blue first sensor 210 may change to brown.

The first sensor 210 may be a visual indicator for ketones in urine, and in an embodiment of the present invention, may be sodium nitroferricyanide. When the acetoacetic acid in urine is above a certain concentration (10 mg/dL), the first sensor turns brown. Acetoacetic acid is one of the ketone bodies and is produced as a product of incomplete metabolism when fat is used as an energy source and appears in urine.

The first sensor 210 may be a visual indicator for urobilinogen in urine, and may be p-demithylaminobenzaldehyde. The yellow color of the first sensor 210 changes to dark red due to urobilinogen in the urine.

The first sensor 210 may be a visual indicator for bilirubin in urine, and in an embodiment of the present invention, may be a diazo salt. The cream color of the first sensor 210 changes to yellow-brown due to bilirubin in the urine. Bilirubin in urine is useful in the differential diagnosis of liver disease, especially jaundice. If bilirubin is positive and urobilinogen is negative, it indicates biliary obstruction.

Additionally, dementia can be detected based on the detection of albumin in urine. Accordingly, in an embodiment of the present invention, the first sensor 210 may include an albumin-sensitive dye, so that when albumin is present in urine, the first sensor 210 including the albumin-sensitive dye causes discoloration.

The second sensor 220 is an oxygen saturation sensor and collects the user's oxygen saturation as second sensing data. The second sensor 220 is provided in a portable device and may be a device that can measure oxygen saturation by applying it to the user's finger, or a device such as a smart watch. The second sensor 220 transmits second sensing data about the user's measured oxygen saturation to the electronic device 300. To this end, the second sensor 220 uses the electronic device 300 and ^5th generation communication (5G), long term evolution (LTE), long term evolution-advanced (LTE-A), wireless fidelity (Wi-Fi), Wireless communication such as Bluetooth can be performed, and wired communication using a USB cable can be performed.

The third sensor 230 is a heart rate variability sensor and collects the user's heart rate variability as third sensing data. The third sensor 230 may be a patch attached to a part of the user's body or a device such as a smart watch. To this end, the third sensor 230 uses the electronic device 300 and ^5th generation communication (5G), long term evolution (LTE), long term evolution-advanced (LTE-A), wireless fidelity (Wi-Fi), Wireless communication such as Bluetooth can be performed, and wired communication using a USB cable can be performed. In addition, the second sensor 220 and the third sensor 230 may be implemented as separate sensors in the same smart watch, etc.

Meanwhile, although not shown in the drawing, the present invention may further include a fourth sensor that collects fourth sensing data by measuring at least one biological signal among pulse, blood pressure, core body temperature, stress, and maximum oxygen saturation. At this time, the electronic device 300 may check and display the user's health status, including dementia, based on the analysis result of the fourth sensing data.

The electronic device 300 is an electronic device capable of communication, such as a smartphone, a tablet PC (personal computer), etc. The owner of the electronic device 300 may be a user wearing a hygiene product, but the guardian of the user wearing a hygiene product It may be. In this case, the owner of the electronic device 300 can monitor the hygiene information of the person wearing the hygiene product. In addition, in the embodiment of the present invention, both the user wearing the hygiene product and the guardian of the user wearing the hygiene product will be collectively referred to as the user.

The electronic device 300 acquires image data for the first sensing data collected by the first sensor 210 and receives second sensing data and third sensing data. The electronic device 300 can analyze the image data, second sensing data, and third sensing data to check the user's health condition and make a medical appointment at a hospital that can provide treatment according to the health condition. The main operations of this electronic device 300 will be described in FIG. 3 below.

The server 400 is a server that can make a medical appointment for a user according to a request from the electronic device 300 through communication with the electronic device 300, and may be a server 400 operated by a hospital. At this time, the server 400 can conduct an interview with the patient who requested a medical appointment through remote communication, fingerprint response, etc.

In addition, the server 400 receives the first to third sensing data from each sensor through direct communication with the first sensor 210, the second sensor 220, and the third sensor 230 and analyzes the sensing data. performed, and the analysis results can be transmitted to the electronic device 300.

To this end, the server 400 includes an electronic device 300, first to third sensors 230, ^5th generation communication (5G), long term evolution (LTE), long term evolution-advanced (LTE-A), Wireless communication such as Wi-Fi (wireless fidelity) can be performed.

Figure 3 is a diagram showing an electronic device that performs health monitoring according to an embodiment of the present invention.

Referring to FIG. 3, the electronic device 300 according to the present invention may include a communication unit 310, an input unit 320, a camera unit 330, a display unit 340, a memory 350, and a control unit 360. there is.

The communication unit 310 may receive second sensing data and third sensing data from the second sensor 220 and the third sensor 230 and provide them to the control unit 360. Additionally, the communication unit 310 may perform communication with the server 400 under the control of the control unit 360. To this end, the communication unit 310 can perform wireless communication such as ^5th generation communication (5G), long term evolution (LTE), long term evolution-advanced (LTE-A), and wireless fidelity (Wi-Fi). , wired communication using a cable can be performed.

The input unit 320 generates input data in response to user input of the electronic device 300. To this end, the input unit 320 may include input devices such as a keyboard, mouse, keypad, dome switch, touch panel, touch keys, and buttons.

The camera unit 330 can process image frames on still images or videos acquired by an image sensor, and the processed image frames can be displayed on the display unit 340. Additionally, image frames processed by the camera unit 330 may be stored in the memory 350 or transmitted externally through the communication unit 310. That is, the user of the electronic device 300 can photograph the discoloration of the first sensor 210, that is, the first sensing data, through the baffle 12 of the hygiene product using the camera unit 330. The camera unit 330 may provide image data generated by a user's photography to the control unit 360.

The display unit 340 outputs output data according to the operation of the electronic device 300. To this end, the display unit 340 may include a display device such as a liquid crystal display (LCD), a light emitting diode (LED) display, or an organic light emitting diode (OLED) display. In addition, the display unit 340 may be combined with the input unit 320 and implemented in the form of a touch screen.

The memory 350 stores operation programs of the electronic device 300. In particular, the memory 350 can store an application that can monitor the user's health status and can store personal information of the user that the application wants to monitor. Additionally, the memory 350 may store answers to the dementia diagnosis questionnaire entered by the user.

When an execution signal for executing an application is received from the input unit 320, the control unit 360 checks whether the dementia diagnosis questionnaire has been completed and the answers to the questionnaire are stored in the memory 350. If the questionnaire has not been completed, the control unit 360 displays a questionnaire for the user, for example, a patient's preliminary examination, on the display unit 340. When answers to the questionnaire are received, the control unit 360 stores them in the memory 350. At this time, the dementia diagnosis questionnaire refers to the mini mental state examination for dementia screening (MMSE-DS) designated by the country, and the control unit 360 receives answers to the questionnaire from the user and stores them in the memory 350. The control unit 360 calculates the answers to the questionnaire into a dementia index ( ) can be calculated.

The control unit 360 performs analysis of the first sensing data, second sensing data, and third sensing data. First, the control unit 360 acquires image data for the first sensing data collected from the first sensor 210 included in the hygiene product worn by the user and performs analysis of the image data. The control unit 360 checks the reference data stored in the memory 350.

At this time, the reference data includes the degree of vaginitis infection corresponding to the degree of discoloration of the first sensor 210, the specific gravity in urine corresponding to the degree of discoloration of the first sensor 210, and the degree of discoloration of the first sensor 210. pH concentration, degree of occult blood or disease name corresponding to the degree of discoloration of the first sensor 210, concentration of urine protein corresponding to the degree of discoloration of the first sensor 210, urine corresponding to the degree of discoloration of the first sensor 210 Concentration of white blood cells, concentration of nitrite in urine corresponding to the degree of discoloration of the first sensor 210, concentration of glucose in urine corresponding to the degree of discoloration of the first sensor 210, degree of discoloration of the first sensor 210 It may be the concentration of acetoacetic acid in urine corresponding to the concentration of urobilinogen in urine corresponding to the degree of discoloration of the first sensor 210, and the concentration of bilirubin in urine corresponding to the degree of discoloration of the first sensor 210. The control unit 360 can check the user's health status by comparing the analysis results of the image data with the reference data stored in the memory 350.

Second, the control unit 360 analyzes the color of the first sensor 210 after the urine test and checks the RGB (red, green, blue) value of the pixel where the first sensor 210 is located. The control unit 360 checks the degree of color change according to the difference between the color of the first sensor 210 before the urine test and the color of the first sensor 210 after the urine test stored in the memory 350 and performs a standard test. Through color mapping, the risk of dementia can be confirmed in three levels: low, high, and risk. That is, the control unit 360 checks whether the first sensor 210 reacts positively to albumin as a result of the urine test and determines the dementia index ( ) can be confirmed. Additionally, the control unit 360 may check the presence or absence of frequent urination and polyuria by checking the cycle in which image data for the first sensing data is acquired.

Third, the control unit 360 analyzes the second sensing data collected from the second sensor 220. At this time, the second sensor 220 is an oxygen saturation sensor and provides data measuring the user's oxygen saturation. The second sensor 220 is provided in a portable device and may be a device that can measure oxygen saturation by applying it to the user's finger, or a device such as a smart watch. When high-concentration oxygen is supplied, the blood oxygen saturation of young people appears to be greater than that of the elderly, and at the same time, when performing cognitive functions, there is a positive correlation between the absolute value of blood oxygen saturation and cognitive performance ability. Therefore, abnormalities in cognitive ability and the early stages of dementia can be easily measured using the second sensing data, which is oxygen saturation. That is, the control unit 360 uses the second sensing data obtained from the second sensor 220 to calculate the dementia index ( ) is calculated.

Fourth, the control unit 360 analyzes the third sensing data collected from the third sensor 230. The third sensor 230 is a heart rate variability sensor and provides data measuring the user's heart rate variability. The third sensor 230 may be a patch attached to a part of the user's body or a device such as a smart watch. Blood flow disorders caused by high blood pressure and increased head blood pressure cause chronic headaches, fatigue, adult diseases, and even stroke and dementia. Therefore, since the risk of cerebral blood flow disorder can be predicted by measuring blood pressure, cerebral blood flow disorder can be simply measured using the third sensing data. That is, the control unit 360 uses the third sensing data obtained from the third sensor 230 to calculate the dementia index ( ) can be calculated.

Finally, the control unit 360 calculates a plurality of dementia indices ( ) to determine the final dementia index (DI). As shown in the first example, the control unit 360 can check the user's health status, including whether the user is infected with vaginitis, using the analysis result of the first sensing data. In addition, the control unit 360 can check the user's health status for dementia using the analysis results of the first to third sensing data and the questionnaire results of the dementia diagnosis questionnaire as in the second to fourth.

Next, the control unit 360 checks the user's health status, including whether the user is infected with vaginitis and whether there is dementia, and if it is determined that a detailed examination by an expert is necessary, the control unit 360 determines the critical radius based on the hospital pre-designated by the user or the user's current location. Make an appointment at a hospital located within your area. To this end, the control unit 360 may communicate with the server 400 operated by the hospital.

Figure 4 is a flowchart explaining a method of performing health monitoring according to an embodiment of the present invention.

Referring to FIG. 4, in step 401, the control unit 360 checks whether an execution signal for executing an application is received from the input unit 320. As a result of confirmation in step 401, if the execution signal is received, the control unit 360 performs step 403. If the execution signal is not received, the control unit 360 waits for reception of the execution signal.

In step 403, the control unit 360 checks whether the dementia diagnosis questionnaire has been completed and the answers to the questionnaire are stored in the memory 350. As a result of the confirmation in step 403, if the questionnaire has been completed, the control unit 360 performs step 407. If the questionnaire has not been completed, the control unit 360 performs step 405. In step 405, the control unit 360 displays a questionnaire for the user, for example, a patient's preliminary examination, on the display unit 340. When an answer to the questionnaire is received, the control unit 360 stores it in the memory 350 and performs step 407.

At this time, the dementia diagnosis questionnaire refers to the mini mental state examination for dementia screening (MMSE-DS) designated by the country, and the control unit 360 receives answers to the questionnaire from the user and stores them in the memory 350. The control unit 360 calculates the answers to the questionnaire into a dementia index ( ) can be calculated.

In step 407, the control unit 360 analyzes the sensing data. At this time, the analysis of the sensing data will be explained in more detail using FIG. 5 below. Figure 5 is a detailed flow chart to explain a method of analyzing sensing data according to an embodiment of the present invention.

Referring to FIG. 5, in step 501, the control unit 360 acquires image data for the first sensing data collected by the first sensor 210 included in the hygiene product worn by the user and performs step 503. In step 503, the control unit 360 analyzes the acquired image data. More specifically, the first sensor 210 includes a visual indicator for at least one of amines, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, urobilinogen, bilirubin, and albumin, so that the control unit 360 ) controls the camera unit 330 to obtain image data about the discoloration of the first sensor 210.

When a user is wearing a hygiene product and the hygiene product receives secretions, that is, urine, the fluid passes through the liner 14 and comes into contact with the first sensor 210 disposed below the liner 14 of the hygiene product. The first sensor 210 may change color depending on the components present in the urine.

Additionally, dementia can be detected based on the detection of albumin in urine. Accordingly, in an embodiment of the present invention, the first sensor 210 may include an albumin-sensitive dye, so that when albumin is present in urine, the first sensor 210 including the albumin-sensitive dye causes discoloration. In order to measure the color of the first sensor 210 before and after a urine test, the control unit 360 checks the RGB value of the pixel where the first sensor 210 is located using Equation 1 below.

The control unit 360 uses Equation 1 to determine the RGB value ( ) and subsequent RGB values ( ) is measured, the degree of color change is confirmed according to the difference between the value before and after the urine test, and the risk of dementia can be divided into three levels: low, high, and risk through mapping with the standard test color. . The control unit 360 checks whether the first sensor 210 reacts positively to albumin as a result of the urine test and determines the dementia index ( ) can be calculated as shown in Table 1 below. Through this, the control unit 360 lowers the degree of risk through the result values measured for each of the plurality of first sensors 210 ( ), high( ), danger( ) can be judged in three stages.

In step 505, the control unit 360 analyzes the second sensing data collected from the second sensor 220. At this time, the second sensor 220 is an oxygen saturation sensor, and the user's oxygen saturation ( ) is measured data. The second sensor 220 is provided in a portable device and may be a device that can measure oxygen saturation by applying it to the user's finger, or a device such as a smart watch. When high-concentration oxygen is supplied, the blood oxygen saturation of young people appears to be greater than that of the elderly, and at the same time, when performing cognitive functions, there is a positive correlation between the absolute value of blood oxygen saturation and cognitive performance ability. Therefore, abnormalities in cognitive ability and the early stages of dementia can be easily measured using the second sensing data, which is oxygen saturation. More specifically, the control unit 360 applies the second sensing data obtained from the second sensor 220 to Equation 2 below to calculate the dementia index ( ) is calculated. The maximum value of oxygen saturation, which is the second sensing data, is 99%, which is a very healthy state, and if it falls below 85%, it is a dangerous value. Therefore, the control unit 360 uses Equation 2 to calculate the dementia index ( ) can be calculated.

In step 507, the control unit 360 analyzes the third sensing data collected from the third sensor 230. The third sensor 230 is a heart rate variability sensor and provides data measuring the user's heart rate variability. The third sensor 230 may be a patch attached to a part of the user's body or a device such as a smart watch. Blood flow disorders caused by high blood pressure and increased head blood pressure cause chronic headaches, fatigue, adult diseases, and even stroke and dementia. Therefore, since the risk of cerebral blood flow disorder can be predicted by measuring blood pressure, cerebral blood flow disorder can be simply measured using the third sensing data.

More specifically, the control unit 360 substitutes the third sensing data into Table 2 below to calculate the dementia index ( ) can be calculated.

Subsequently, in step 509, the control unit 360 calculates a plurality of dementia indices ( ) is considered, the final dementia index (DI) is confirmed, and the process returns to step 409 in FIG. 4. At this time, the dementia index (DI) can use Equation 3 below.

At this time, = 0.3; = 0.3; = 0.2; = 0.2, and in determining dementia, the weight of the urine test may be 30%, the weight of the dementia diagnosis questionnaire may be 30%, the weight of the second sensing data may be 20%, and the weight of the third sensing data may be 20%.

Next, in step 409, the control unit 360 checks the user's health status based on the sensing data analysis result in step 407. More specifically, the control unit 360 determines the degree of vaginitis infection corresponding to the degree of discoloration of the first sensor 210, specific gravity in urine, degree of occult blood or disease name, concentration of urine protein, concentration of white blood cells in urine, and meaningful urinary tract in urine. The user's health status can be checked based on the presence of infectious bacteria, the concentration of glucose in the urine, the presence of ketones in the urine, the concentration of acetoacetic acid in the urine, the concentration of urobilinogen in the urine, and the concentration of bilirubin in the urine. Additionally, the control unit 360 can confirm the user's health status by comparing the dementia index (DI) determined in step 509 with a clinically based threshold and classifying the stage of dementia into normal and early stages of dementia.

In step 411, if the control unit 360 determines that a detailed inspection by the user is necessary, it performs step 415, and if it determines that a detailed inspection is not necessary, it performs step 413. In step 413, the control unit 360 may generate a message indicating that the user's health condition is normal and output the message to the display unit 340. For example, if the dementia index is greater than the threshold and the dementia index is the same as the threshold or is similar to the threshold by more than the threshold, it may be determined that a detailed examination is necessary.

In step 415, the control unit 360 performs hospital reservation. This will be explained in more detail using Figure 6 below. Figure 6 is a detailed flow chart to explain a method of making a hospital reservation according to an embodiment of the present invention.

Referring to FIG. 6, in step 601, the control unit 360 checks whether the designated hospital set by the user exists in the electronic device 300. As a result of the confirmation in step 601, if the designated hospital set by the user exists, the control unit 360 performs step 605. If the designated hospital does not exist, the control unit 360 performs step 603.

In step 603, the control unit 360 checks the current location of the electronic device 300 or the location of the user's home address set by the user, and searches for a hospital located within the critical radius based on the confirmed location. At this time, the control unit 360 may search for a specialized hospital related to the disease for which a detailed examination identified in the electronic device 300 must be performed. For example, if it is confirmed that the user has vaginitis, the user can search for a women's hospital, and if it is determined that a detailed examination related to dementia is necessary, the user can search for a hospital specializing in neurology.

If a request signal for medical appointment reservation is received from the input unit 320 in step 605, the control unit 360 performs step 607. If the request signal is not received, the control unit 360 returns to step 417 of FIG. 4. In step 607, the control unit 360 makes a reservation for treatment at the hospital corresponding to the request signal through communication with the server 400 managed by the hospital and returns to step 417 of FIG. 4.

In step 417, the control unit 360 can terminate the process when an application termination signal is received from the input unit 320. If the termination signal is not received, the control unit 360 can wait to receive the termination signal.

Figure 7 is a diagram showing an example of a personal hygiene product according to another embodiment of the present invention.

Referring to FIG. 7, a hygiene product according to another embodiment of the present invention includes a first sensor 210 disposed within the pad 10, a communication module 16 disposed within the pad 10, and a server connected through a network. It may be configured to include an electronic device 300 that communicates with 400 and a server 400 through a network.

In order to initiate communication between the communication module 16 and the server 400 before wearing the pad 10, the user can use the communication module 16 in various ways, such as removing a predetermined sticker attached to the communication module 16. ) and the server 400 can be initiated. When transmitting the first sensing data transmitted from the first sensor 210, the communication module 16 may transmit the unique number of the pad 10 to the server 400 together.

At this time, the user can register the unique number of the pad 10 in the server 400 in advance. The unique number of the pad 10 registered in the server 400 may be displayed in advance on the individual packaging of the pad or may be displayed in advance on the package containing a plurality of pads 10. The user can register this unique number in the server 400, and the server 400 can store the unique number of the pad 10 along with the user information.

Additionally, although not shown, the communication module 16 may transmit the first sensing data transmitted from the first sensor 210 to the electronic device 300 through a predetermined communication method. In this case, the electronic device 300 can directly store the first sensing data transmitted from the communication module 16 in the memory 350 and transmit it to the server 400. Thereafter, the wearer's health information determined by the server 400 can be received again by the electronic device 300 and displayed on the display unit 340.

Hereinafter, data determined by the first sensor 210 is transmitted from the communication module 16 to the server 400 as an example, but in one embodiment of the present invention, the communication module 16 is transmitted through relay of the electronic device 300. Transmission of the first sensing data from (16) to the server 400 is not excluded.

In addition, since the pad 10 shown in FIG. 7 performs the same function as the pad 10 shown in (a) of FIG. 1 except for the communication module 16, detailed description will be omitted.

The embodiments of the present invention disclosed in this specification and drawings are merely provided as specific examples to easily explain the technical content of the present invention and to facilitate understanding of the present invention, and are not intended to limit the scope of the present invention. Therefore, the scope of the present invention should be construed as including all changes or modified forms derived based on the technical idea of the present invention in addition to the embodiments disclosed herein.

Claims (12)

A first sensor included in a hygiene product and collecting parameters about the user's urine as first sensing data;
a second sensor that collects the user's oxygen saturation as second sensing data;
A third sensor that collects the user's heart rate as third sensing data; and
Obtain image data for the first sensing data, analyze the image data, the second sensing data, and the third sensing data, and determine the user's health status, including dementia, based on the analysis results of the sensing data. Electronic device for checking and displaying;
A health monitoring system comprising: According to paragraph 1,
The first sensor is,
Containing indicators or information that can be visually recognized by the user
Health monitoring system. According to paragraph 1,
The first sensor is,
A health monitoring system comprising visual indicators for at least one of amines, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, urobilinogen, bilirubin and albumin. According to paragraph 1,
The hygiene products are:
A health monitoring system characterized by a pad or absorbent underpants worn by the user. According to paragraph 4,
The hygiene products are:
A health monitoring system comprising a liquid-impermeable baffle and an absorbent, liquid-permeable liner. According to clause 5,
The first sensor is,
A health monitoring system, characterized in that disposed between the baffle and the liner. According to paragraph 1,
The electronic device is,
A health monitoring system, characterized in that making an appointment at at least one hospital based on the confirmed health status. In clause 7,
The electronic device is,
A health monitoring system characterized in that the reservation is made at a hospital pre-stored in the electronic device. In clause 7,
The electronic device is,
A health monitoring system that searches for hospitals located within a critical radius based on the location of the electronic device and makes the reservation. A first sensor included in a hygiene product and collecting parameters about the user's urine as first sensing data;
a second sensor that collects the user's oxygen saturation as second sensing data;
A third sensor that collects the user's heart rate as third sensing data;
a server that receives and analyzes the first sensing data, the second sensing data, and the third sensing data, and confirms the user's health condition, including dementia, based on the analysis results; and
an electronic device that receives and displays the health status from the server;
A health monitoring system comprising: According to clause 10,
The hygiene products are:
a communication module that transmits the first sensing data to the server;
A health monitoring system further comprising: According to clause 10,
It further includes a fourth sensor that collects fourth sensing data of at least one of the user's pulse, blood pressure, core body temperature, stress, and maximum oxygen saturation,
The electronic device is
A health monitoring system, characterized in that it checks and displays the user's health status, including dementia, based on the analysis results of the fourth sensing data.

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