WO2018225881A1

WO2018225881A1 - Health information monitoring system

Info

Publication number: WO2018225881A1
Application number: PCT/KR2017/005887
Authority: WO
Inventors: 정문기
Original assignee: 주식회사 레드서브마린
Priority date: 2017-06-07
Filing date: 2017-06-07
Publication date: 2018-12-13

Abstract

Disclosed is a health information monitoring system. A server in a system of the present invention stores health information according to a predetermined parameter, determines a health condition of a pad wearer from an image relating to a visual change of a biosensor, and transmits the determined health condition to a mobile terminal.

Description

Health Information Monitoring System

The present invention relates to a health information monitoring system.

In the field of health care there is a need to remotely monitor any one of the patient's health conditions, for example, immature newborns need to constantly monitor the body function and the like. Such monitoring and inspection requires labor-intensive, highly trained staff, and a large burden on staff when there are many patients.

As such, in order to monitor the health information of individual patients, a remote monitoring device is used. Such devices include sensors that are wired to the portable receiver and the display unit and typically provide a visual reading of measured parameters and an alarm if an abnormal value is obtained. However, such a monitoring system has a problem that hardware is expensive, occupies a lot of space, and its configuration is very complicated.

The technical problem to be solved by the present invention is to provide a health information monitoring system that receives the health information of the individual from the personal hygiene products worn by the user, and provides the data to the mobile terminal of the user to enable continuous monitoring. It is.

In order to solve the above technical problem, the health information monitoring system according to an embodiment of the present invention, the biosensor disposed between the baffle and the liner of the pad, and functions as a visual indicator for a predetermined parameter; A predetermined mobile terminal for transmitting the image photographing the biosensor to a server; And store the health information according to the predetermined parameter, determine the health state of the wearer of the pad from the image of the visual change of the biosensor, and transmit it to the mobile terminal.

In one embodiment of the present invention, the biosensor may be configured to be visually identifiable through the baffle.

In one embodiment of the present invention, the biosensor may include a visual indicator for any one or more of amine, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, and bilirubin.

In addition, in order to solve the above technical problem, the health information monitoring system of an embodiment of the present invention, disposed between the baffle and the liner of the pad, the biosensor for determining the data relating to the health status of the wearer for a predetermined parameter ; A communication module for transmitting data relating to the health state; And a server for storing the health information according to the parameter, determining the health state of the wearer of the pad from the data related to the health state, and transmitting the health information to the mobile terminal.

In one embodiment of the present invention, the communication module may transmit data related to the health state to the server.

In one embodiment of the present invention, the communication module may transmit data related to the health state to the mobile terminal, and the mobile terminal may transmit it to the server.

In one embodiment of the present invention, the baffle may be a transparent or opaque material.

In one embodiment of the present invention, the biosensor can determine data for any one or more of amine, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, and bilirubin.

The present invention as described above, by using a variety of parameters contained in the secretion collected by the personal care products worn by the user, it is possible to easily monitor the health information.

In addition, the present invention has the effect of early diagnosis and prevention of simple gynecological diseases, including vaginitis, using a personal care products.

1A and 1B are examples of personal care products used in one embodiment of the present invention.

2 is a block diagram illustrating a health information monitoring system according to an embodiment of the present invention.

3 is an exemplary view for explaining the configuration of the mobile terminal of FIG.

Figure 4 is a block diagram for explaining a health information monitoring system of another embodiment of the present invention.

In order to fully understand the constitution and effects of the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be embodied in various forms and various changes may be made. However, the description of the present embodiment is provided to make the disclosure of the present invention complete, and to fully inform the person of ordinary skill in the art the scope of the present invention. In the accompanying drawings, for convenience of description, the size of the components is larger than the actual drawings, and the ratio of each component may be exaggerated or reduced.

Where a component is said to be 'on' or 'facing' another component, it may be directly in contact with or connected to another component, but it should be understood that there may be another component in between. something to do. On the other hand, if a component is said to be 'directly' or 'directly' to another component, it may be understood that there is no other component in between. Other expressions describing the relationship between the components, such as 'between' and 'directly between', may be interpreted as well.

Terms such as 'first' and 'second' may be used to describe various components, but the components should not be limited by the above terms. The term may only be used to distinguish one component from another. For example, a 'first component' may be referred to as a 'second component' without departing from the scope of the present invention, and similarly, a 'second component' may also be referred to as a 'first component'. Can be.

Singular expressions include plural expressions unless the context clearly indicates otherwise. The terms "comprises" or "having" are intended to indicate that there are features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, one or more other features or numbers, It may be interpreted that steps, actions, components, parts or combinations thereof may be added.

Unless otherwise defined, terms used in the embodiments of the present invention may be interpreted as meanings commonly known to those skilled in the art.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The personal care product used in the embodiment of the present invention may be, for example, any one of the pad 10 of FIG. 1A and the absorbent underpants 20 of FIG. 1B.

The pad 10 may be comprised of a liquid impermeable baffle 12 on its side and a bodyside liner 14 that is adsorbable liquid permeable as a layer closest to the wearer. An absorbent core (not shown) may be arranged between the baffle 12 and the liner 14 to hold the liquid secretion, and the biosensor 30 of the present invention is disposed between the core and the baffle 12 therein. Can be. The baffle 12 may be mainly formed of a polypropylene film or the like and may be transparent or translucent. In addition, a communication module may be disposed between the baffle 12 and the liner 14 or on one surface of the baffle 12 to transmit a signal measured from the biosensor 30 to a server (to be described later).

In addition, the personal care product used in one embodiment of the present invention may be an absorbent underpants 20, the absorbent underpants 20 may be composed of a baffle 22 and a liner 24. An absorbent core (not shown) may be disposed between the baffle 22 and the liner 24, and the biosensor 30 of the present invention may be disposed between the absorbent core and the baffle 22. . In addition, a communication module for transmitting a signal measured from the biosensor 30 to a server (described later) may be disposed between the baffle 22 and the liner 24 or on one surface of the baffle 22.

The configuration of the pad 10 and the underpants 20 described with reference to FIGS. 1A and 1B is described as a minimum configuration as an example, and it is obvious that many more configurations may be included.

Hereinafter, a personal hygiene product in the form of a pad 10 will be described as an example, but a personal hygiene product in the form of underpants 20 of FIG. 1B may be applied, or in another form, for example, a tampon. Personal hygiene products may be used.

As shown in the figure, the system of one embodiment of the present invention, the biosensor 30, the server 40 and the mobile terminal 50 in communication with the server 40 disposed in the pad 10 via a network. It can be configured to include.

The owner of the mobile terminal 50 may be a wearer of the pad 10, but may also be a protector of the wearer of the pad 10. In this case, the owner of the mobile terminal 50 may monitor the hygiene information of the wearer of the pad 10.

The owner of the mobile terminal 50 may register the unique number of the pad 10 through a web page provided by the server 40.

As shown in the figure, the mobile terminal 50 of the present invention includes a control unit 51, a communication unit 52, a camera unit 53, a user input unit 54, a display unit 55, and a storage unit 56. It may include.

The communication unit 52 may include a module that enables communication between the mobile terminal 50 and the server 40.

The camera unit 53 may process an image frame of a still image or a moving image obtained by the image sensor, and the processed image frame may be displayed on the display unit 55. In addition, the image frame processed by the camera unit 53 may be stored in the storage unit 56 or transmitted to the outside through the communication unit 52. That is, the owner of the mobile terminal 50 may photograph the discoloration of the biosensor 30 using the camera unit 53 through the baffle 12 of the pad 10, and transmit the corresponding image to the server 40. It may be transmitted through the communication unit 52 or stored in the storage unit 56.

The user input unit 54 may generate input data for the operation control of the mobile terminal 50 by the user, and may be configured, for example, as a touch pad.

The display unit 55 displays information processed by the mobile terminal 50. The display unit 55 displays an image captured by the user through the camera unit 52 in the form of a preview, or displays the captured image in the form of a still image or a video. Can be displayed.

When the display unit 55 and a sensor (touch sensor) for detecting a touch operation form a mutual layer structure (touch screen), the display unit 55 may be used as a user input unit 54 that is an input device in addition to the output device. . The touch sensor is configured to convert a pressure applied to a specific portion of the display unit 55 or a change in capacitance generated at a specific portion of the display unit 55 into an electrical input signal. It can be configured to detect up to the pressure of the hour. When there is an input to the touch sensor, a signal corresponding thereto is transmitted to the controller 51, and the controller 51 processes the corresponding signal to determine which part of the display unit 55 has been touched and how much area thereof has been touched. It is possible to know whether it has been touched and at what pressure. Various configurations related to the touch screen are not related to the description of the present invention, and thus a detailed description thereof will be omitted.

When the user photographs the change of the biosensor 30 through the camera unit 53, the controller 51 may transmit the change to the server 40 through the communication unit 52. In addition, by receiving the user hygiene information from the server 40 periodically or in real time through the communication unit 52, the user can provide the monitoring result through the display unit 55 to check. The monitoring result received in this way may be stored in the storage unit 56.

The biosensor 30 may be a visual indicator of vaginitis. Vaginal infections appear in the form of bacteriosis or trichomonas, all of which give rise to amines. Thus, in one embodiment of the invention, the biosensor 30 may comprise an amine sensitive dye. When the user is wearing the pad 10, when the pad 10 receives secretions, the fluid passes through the liner 14 to the biosensor 30 disposed below the liner 14 of the pad 10. If the amine is present in the secretion, the biosensor 30 including the amine-sensitive dye will cause discoloration. Such discoloration can be confirmed through the baffle 12 of the transparent material.

In one embodiment of the present invention, the baffle 12 may be transparent only in the region corresponding to the biosensor 30 and other regions may be opaque. Alternatively, the baffle 12 is transparent in the entire area, and a non-absorbent film of opaque material is disposed in the area except the area corresponding to the biosensor 30 at the bottom of the liner 14, except for the color of the secretion. The user may be configured to check only the discoloration of the biosensor 30. This will be the same in the following description.

The user photographs the discolored biosensor 30 through the camera unit 53 of the mobile terminal 50, and the controller 51 of the mobile terminal 50 transmits the corresponding image to the server through the communication unit 52. 40).

The server 40 may store the degree of vaginitis infection corresponding to the degree of discoloration of the biosensor 30, and store the degree of vaginal infection according to the degree of discoloration of the biosensor 30 of the image received from the mobile terminal 50. It may be determined and transmitted to the mobile terminal 50. The controller 51 of the mobile terminal 50 may display the degree of vaginitis infection through the display unit 55.

The biosensor 30 may be a visual indicator of urine pH, and in one embodiment of the present invention may include methyl red and bromophenol blue, in which case the urine is acidic in red If it is alkaline, it will turn blue. The urine pH of a normal person varies widely from 4.5 to 8.0 depending on the amount of food or water consumed, but it can show acidic urine in respiratory or metabolic acidosis and contradicted acidic urine in hypokalemia. Fever, diarrhea, uremia and starvation can also cause acidic urine. When the user is wearing the pad 10, when the pad 10 receives secretions, the fluid passes through the liner 14 to the biosensor 30 disposed below the liner 14 of the pad 10. The biosensor 30 will be discolored according to the pH concentration of the secretion. Such discoloration can be confirmed through the baffle 12 of the transparent material.

The user photographs the discolored biosensor 30 through the camera unit 53 of the mobile terminal 50, and the controller 51 of the mobile terminal 50 transmits the corresponding image to the server 40 through the communication unit 52. To be sent.

The server 40 may map and store the pH corresponding to the degree of discoloration of the biosensor 30, and the pH according to the degree of discoloration of the biosensor 30 of the image received from the mobile terminal 50 may be possible. The disease name may be determined and transmitted to the mobile terminal 50. The controller 51 of the mobile terminal 50 may display the pH and possible bottle names through the display unit 55.

Alternatively, the biosensor 30 may be a visual indicator for free hemoglobin in the urine, thereby testing for urine occult blood. In one embodiment of the invention, the biosensor 30 may comprise tetramethylbenzidin. When the biosensor 30 is oxidized to green or dark blue by free hemoglobin in the urine, hemoglobin may be estimated, or hemoglobinuria, myoglobinuria and bacterial peroxidase due to heme of hemoglobin may be determined.

The server 40 may map and store the degree of occlusion or disease name corresponding to the degree of discoloration of the biosensor 30, and the degree of occlusion according to the degree of discoloration of the biosensor 30 of the image received from the mobile terminal 50 or The disease name may be determined and transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 may display the degree of occult blood or the disease name through the display unit 55.

Alternatively, the biosensor 30 may be a visual indicator for urine protein, and may include tetrabromophenol or tetrachlorophenol in one embodiment of the present invention. When the yellow color of the biosensor 30 changes to green due to the urine protein, the concentration of the urine protein may be estimated according to the degree of discoloration.

Accordingly, the user photographs the discolored biosensor 30 through the camera unit 53 of the mobile terminal 50, and the control unit 51 of the mobile terminal 50 transmits the corresponding image to the server through the communication unit 52. 40).

The server 40 may map and store the concentration of the urine protein corresponding to the degree of discoloration of the biosensor 30, and determine the concentration of the urine protein according to the degree of discoloration of the biosensor 30 of the image received from the mobile terminal 50. The concentration may be determined and transmitted to the mobile terminal 50. The controller 51 of the mobile terminal 50 may display the concentration of the urine protein through the display unit 55.

Alternatively, the biosensor 30 may be a visual indicator for a leukocyte esterase (LE), and may include an ester compound in one embodiment of the present invention. When the ester compound of the biosensor 30 is hydrolyzed and turned purple by the leukocyte esterase released from the neutrophils in the urine, the presence of leukocytes in the urine can be determined positively.

The server 40 may store the concentration of leukocytes in the urine corresponding to the degree of discoloration of the biosensor 30, and store the same in the urine according to the degree of discoloration of the biosensor 30 of the image received from the mobile terminal 50. The leukocyte concentration may be determined and transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 may display the concentration of the white blood cells in the urine through the display unit 55.

Alternatively, the biosensor 30 may be a visual indicator of nitrite in urine, and may include para-arsananilic acid (p-arsanilic acid) in one embodiment of the present invention. The presence of nitrite in the urine causes the biosensor 30 to turn pink. Nitrite is a substance formed by oxidizing nitrates into the body through food, and the positive reaction indicates the presence of meaningful urinary tract infections in urine.

The server 40 may map and store the concentration of nitrite in the urine corresponding to the degree of discoloration of the biosensor 30 and in the urine according to the degree of discoloration of the biosensor 30 in the image received from the mobile terminal 50. The concentration of nitrite may be determined and transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 may display the concentration of nitrite in the urine through the display unit 55.

Alternatively, the biosensor 30 may be a visual indicator of glucose in the urine, and may be potassium iodide in one embodiment of the present invention. If glucose is present in the urine, the blue biosensor 30 may turn brown.

The server 40 may map and store the concentration of glucose in the urine corresponding to the degree of discoloration of the biosensor 30 and in the urine according to the degree of discoloration of the biosensor 30 in the image received from the mobile terminal 50. The concentration of glucose may be determined and transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 may display the concentration of glucose in the urine through the display unit 55.

Alternatively, the biosensor 30 may be a visual indicator for urine ketones, and in one embodiment of the present invention may be sodium nitroferricyanide. When acetoacetic acid in urine is above a predetermined concentration (10 mg / dL), the biosensor 30 turns brown. Acetoacetic acid is a ketone body that is produced as a product of incomplete metabolism and appears in the urine when fat is used as an energy source.

The server 40 may map and store the concentration of acetoacetic acid in the urine corresponding to the degree of discoloration of the biosensor 30, and the urine according to the degree of discoloration of the biosensor 30 in the image received from the mobile terminal 50. The concentration of acetoacetic acid may be determined and transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 may display the concentration of acetoacetic acid in the urine on the display unit 55.

Alternatively, the biosensor 30 may be a visual indicator of urinary eurobilinogen and may be para-dimethylaminobenzaldehyde. The yellow of the biosensor 30 changes to a dark red color due to the eurobilinogen in the urine.

The server 40 may map and store the concentration of eurobilinogen in the urine corresponding to the degree of discoloration of the biosensor 30 and in the urine according to the degree of discoloration of the biosensor 30 in the image received from the mobile terminal 50. The concentration of eurobilinogen may be determined and transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 may display the concentration of eurobilinogen in the urine through the display unit 55.

Alternatively, the biosensor 30 may be a visual indicator for bilirubin in the urine, and may be a diazo salt in one embodiment of the present invention. Urinary bilirubin changes the cream color of the biosensor 30 to yellowish brown. Urinary bilirubin is useful for differential diagnosis of liver disease, especially jaundice, and bilirubin is positive if bilirubin is positive and eurobilinogen is negative.

The server 40 may map and store the concentration of bilirubin in the urine corresponding to the degree of discoloration of the biosensor 30 and in the urine according to the degree of discoloration of the biosensor 30 in the image received from the mobile terminal 50. The concentration of bilirubin may be determined and transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 may display the concentration of bilirubin in the urine through the display unit 55.

However, in the description of one embodiment of the present invention, the biosensor 30 is, for example, an amine, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, or an indicator for each of bilirubin, for example Although described, it may be an indicator of a plurality. That is, one region of the biosensor 30 may be one indicator and the other region may be another indicator. In this case, when the user photographs the discoloration in each area through the camera unit 53 of the mobile terminal 50, the control unit 51 of the mobile terminal 50 transmits the image through the communication unit 52 to the server ( 40, the server 40 may store a symptom corresponding to the discoloration degree of each area of the biosensor 30, and the discoloration degree of the biosensor 30 in the image received from the mobile terminal 50. Determining each symptom according to it may be transmitted to the mobile terminal (50). The controller 51 of the mobile terminal 50 may display the symptom on the discharge of the user through the display unit 55.

As shown in the figure, in another embodiment of the present invention, the health information monitoring system, the biosensor 30 disposed in the pad 10, the communication module 16 disposed in the pad 10, the communication module ( 16 and a server 40 connected through a network and a mobile terminal 50 communicating with the server 40 through a network.

In one embodiment of the present invention, the baffle 12 of the pad 10 may be a transparent material, or may be an opaque material. That is, in another embodiment of the present invention, it is not necessary to check the color change of the biosensor 30, and measure the concentration of a predetermined substance in the secretion of the user and transmit it to the server 40 through the communication module 16. Can be.

The communication module 16 may transmit data transmitted from the biosensor 30 to the server 40 through a predetermined communication method.

The user may remove the predetermined sticker adhered to the communication module 16 to start communication between the communication module 16 and the server 40 before the pad 10 is worn. Communication with the server 40 may be initiated. The communication module 16 may transmit the unique number of the pad 10 to the server 40 together with data transmitted from the biosensor 30. In this case, the user may pre-register the unique number of the pad 10 in the web page provided by the server 40. The unique number of the pad 10 registered in the server 40 may be previously displayed on the individual packaging of the pad, or may be previously displayed on the package accommodating the plurality of pads 10. The user may register this unique number in a web page provided by the server 40, and the server 40 may store the unique number of the pad 10 together with the user information.

In addition, although not shown, the communication module 16 may transmit data transmitted from the biosensor 30 to the mobile terminal 50 through a predetermined communication method. In this case, the mobile terminal 50 may store data transmitted from the communication module 16 directly in the storage unit 56 or may transfer data to the server 40. Thereafter, the health information of the wearer determined by the server 40 may be received by the mobile terminal 50 and displayed on the display unit 55.

Hereinafter, the data determined by the biosensor 30 is directly transmitted from the communication module 16 to the server 40, for example, but through the relay of the mobile terminal 50 in one embodiment of the present invention. The transmission of data from the communication module 16 to the server 40 is not excluded.

The biosensor 30 may be an indicator of vaginitis, determines the amine concentration of the secretion of the wearer's secretion of the pad 10 received through the liner 14, and transmits it to the server 40 through the communication module 16. Can be.

The server 40 may map and store the infection level corresponding to the amine concentration received from the communication module 16, and determine the degree of infection infection corresponding to the amine concentration received from the communication module 16, thereby determining the mobile terminal ( 50). The controller 51 of the mobile terminal 50 may display the degree of vaginitis infection through the display unit 55.

Alternatively, the biosensor 30 may be an indicator of the specific gravity in the urine. Urinary weight is determined by the concentration of ions in the solute dissolved in the urine, and the concentration and dilution capacity of the kidney can be estimated. The biosensor 30 may determine the urine secretion in the secretion received through the liner 14 and transmit the urine secretion to the server 40 through the communication module 16.

The server 40 may map and store the enrichment and dilution ability of the kidney corresponding to the specific gravity concentration received from the communication module 16, and the enrichment of the kidney corresponding to the specific gravity concentration received from the communication module 16. The dilution capacity may be determined and transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 may display the enrichment and dilution ability of the kidney with respect to the specific gravity through the display unit 55.

Alternatively, the biosensor 30 may be an indicator for the urine pH, and the biosensor 30 determines the pH in the secretion received through the liner 14, which is the server 40 through the communication module 16. Can be sent to.

The server 40 may map and store the bottle name corresponding to the pH received from the communication module 16, determine the bottle name corresponding to the pH received from the communication module 16, and transmit the same to the mobile terminal 50. will be. The controller 51 of the mobile terminal 50 may display the bottle name for the corresponding pH through the display unit 55.

Alternatively, the biosensor 30 may be an indicator for free hemoglobin in the urine, thereby testing for urine occult blood. The concentration of free hemoglobin in the secretion received through the liner 14 may be determined and transmitted to the server 40 through the communication module 16.

The server 40 may map and store a bottle name corresponding to the concentration of free hemoglobin received from the communication module 16, and determine a bottle name corresponding to the concentration of free hemoglobin received from the communication module 16 to determine the mobile terminal ( 50). The controller 51 of the mobile terminal 50 may display the bottle name for the concentration of the free hemoglobin on the display unit 55.

Alternatively, the biosensor 30 may be an indicator for the urine protein, determine the concentration of the urine protein in the secretion received through the liner 14, and transmit it to the server 40 through the communication module 16. have.

The server 40 may map and store a bottle name corresponding to the concentration of the urine protein received from the communication module 16, and determine a bottle name corresponding to the concentration of the urine protein received from the communication module 16 to determine the mobile terminal ( 50). The controller 51 of the mobile terminal 50 may display the bottle name for the concentration of the urine protein through the display unit 55.

Alternatively, the biosensor 30 may be an indicator for the esterase, and determine the concentration of the esterase in the secretion received through the liner 14, and then to the server 40 through the communication module 16. Can transmit

The server 40 may map and store a bottle name corresponding to the concentration of the esterase received from the communication module 16, and determine and move the bottle name corresponding to the concentration of the esterase received from the communication module 16. It may be transmitted to the terminal 50. The controller 51 of the mobile terminal 50 may display the bottle name for the concentration of the corresponding esterase through the display unit 55.

Alternatively, the biosensor 30 may be an indicator for nitrite, determine the concentration of nitrite in the secretion received through the liner 14, and transmit it to the server 40 through the communication module 16.

The server 40 may map and store a bottle name corresponding to the concentration of nitrite received from the communication module 16, and determine the bottle name corresponding to the concentration of nitrite received from the communication module 16. Will be able to send to. The control unit 51 of the mobile terminal 50 may display the bottle name for the concentration of the corresponding nitrite through the display unit 55.

Alternatively, the biosensor 30 may be an indicator of urine glucose, determine the concentration of glucose in the secretion received through the liner 14, and transmit it to the server 40 through the communication module 16. have.

The server 40 may map and store a bottle name corresponding to the concentration of glucose received from the communication module 16, determine the bottle name corresponding to the concentration of glucose received from the communication module 16, and then execute the mobile terminal 50. Will be able to send to. The controller 51 of the mobile terminal 50 may display the bottle name for the concentration of the corresponding glucose through the display unit 55.

Alternatively, the biosensor 30 may be an indicator for the ketone in the urine, determines the concentration of acetoacetic acid in the secretion received through the liner 14, and transmits it to the server 40 through the communication module 16. Can be.

The server 40 may map and store a bottle name corresponding to the concentration of acetoacetic acid received from the communication module 16, and determine a bottle name corresponding to the concentration of acetoacetic acid received from the communication module 16 to determine the mobile terminal ( 50). The controller 51 of the mobile terminal 50 may display the bottle name for the concentration of acetoacetic acid on the display unit 55.

Alternatively, the biosensor 30 may be an indicator for eurobilinogen, and may determine the concentration of eurobilinogen in secretions received through the liner 14 and transmit it to the server 40 through the communication module 16.

The server 40 may map and store a bottle name corresponding to the concentration of eurobilinogen received from the communication module 16, and determine the bottle name corresponding to the concentration of eurobilinogen received from the communication module 16 so as to determine the mobile terminal 50. Will be able to send to. The controller 51 of the mobile terminal 50 may display the bottle name for the concentration of the eurobilinogen through the display unit 55.

Alternatively, the biosensor 30 may be an indicator for bilirubin in the urine, determine the concentration of bilirubin in the secretion received through the liner 14, and transmit it to the server 40 through the communication module 16. have.

The server 40 may map and store a bottle name corresponding to the concentration of bilirubin received from the communication module 16, determine the bottle name corresponding to the concentration of bilirubin received from the communication module 16, and then execute the mobile terminal 50. Will be able to send to. The controller 51 of the mobile terminal 50 may display the bottle name for the concentration of the bilirubin through the display unit 55.

However, in the description of one embodiment of the present invention, the biosensor 30 is an example of the case of the amine, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, or bilirubin, respectively. Although described for example, it may be an indicator of a plurality. That is, the biosensor 30 determines the concentration of any one or more parameters of amine, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, or bilirubin, and this is determined by the communication module 16. Through the server 40 can be transmitted.

The server 40 is a disease name (health state) corresponding to the concentration of any one or more of amine, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, or bilirubin received from the communication module 16. May be stored and mapped to a concentration of any one or more of amine, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, or bilirubin, respectively, received from the communication module 16. Health state) may be transmitted to the mobile terminal 50. The control unit 51 of the mobile terminal 50 displays the disease name for the concentration of any one or more of the corresponding amine, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, or bilirubin. Will be displayed via

The user may identify a disease name corresponding to any one or more parameters of amine, specific gravity, pH, occult blood, protein, esterase, nitrite, sugar, ketone, eurobilinogen, or bilirubin, which are transmitted periodically or in real time through the mobile terminal 50. Through the mobile terminal 50 can be confirmed, it will be easy to monitor the health information using a variety of parameters included in the secretion.

Although embodiments according to the present invention have been described above, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments of the present invention are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the following claims.

Claims

A biosensor disposed between the baffle of the pad and the liner, the biosensor serving as a visual indicator for a predetermined parameter;

A predetermined mobile terminal for transmitting the image photographing the biosensor to a server; And

And a server configured to store health information according to the predetermined parameter, determine a health state of a wearer of the pad from an image of a visual change of the biosensor, and transmit the health state to the mobile terminal.
The health information monitoring system of claim 1, wherein the biosensor is configured to be visually identifiable through the baffle.
The method of claim 1, wherein the biosensor,

A health information monitoring system comprising visual indicators for any one or more of amines, pH, occult blood, protein, esterases, nitrites, sugars, ketones, eurobilinogen, and bilirubin.
A biosensor disposed between the baffle and the liner of the pad, the biosensor determining data relating to a wearer's health for a predetermined parameter;

A communication module for transmitting data relating to the health state; And

And a server for storing health information according to a corresponding parameter, determining a health state of the wearer of the pad from the data related to the health state, and transmitting the health state to a mobile terminal.
The health information monitoring system of claim 4, wherein the communication module transmits data related to the health state to the server.
The health information monitoring system of claim 4, wherein the communication module transmits data related to the health state to the mobile terminal, and the mobile terminal transmits the data to the server.
The health information monitoring system of claim 4, wherein the baffle is a transparent or opaque material.
The method of claim 4, wherein the biosensor,

A health information monitoring system that determines data for any one or more of amines, specific gravity, pH, occult blood, protein, esterases, nitrites, sugars, ketones, eurobilinogen, and bilirubin.