KR20190140414A - Apparatus and method for performing hematological estimation using saliva - Google Patents

Abstract

Disclosed are an apparatus and a method for measuring the concentration of components in blood by using saliva. The method measuring the concentration of components in blood by using saliva comprises the steps of: calculating a correlation between components in blood of a subject and components in saliva of the subject; measuring the concentration of the components in saliva of the subject; and calculating the concentration of the components in blood of the subject by using the measured concentration of the components in saliva of the subject and the correlation between the components in blood of the subject and the components in saliva of the subject.

Description

Apparatus and method for measuring the concentration of components in the blood using saliva {APPARATUS AND METHOD FOR PERFORMING HEMATOLOGICAL ESTIMATION USING SALIVA}

The present invention relates to an apparatus and method for measuring the concentration of components in blood using saliva.

Self-diagnosis products that can diagnose various diseases such as diabetes, AIDS and colon diseases are appearing on the market. These products look for biomarkers in the blood that can determine if a disease is present and diagnose their condition. In general, a blood sample is taken and then reagents that can cause a chemical reaction are added to determine whether the reaction is performed electronically or optically.

In the case of a portable blood glucose meter used by diabetics to manage blood glucose, blood is collected and D-glucose in the blood is reacted with Glucose oxidase in the strip to make hydrogen peroxide, and the method of measuring the hydrogen peroxide concentration in an electrical manner is used. do. On the other hand, the blood glucose measurement method used in the hospital is a technique using fluorescence coloration, which uses an optical method of measuring the degree of reaction using a specific reagent that generates resorufin in response to hydrogen peroxide.

Checking and managing your own health is a necessary skill, but the process of collecting blood is inconvenient and painful. For this reason, efforts are being made to develop a technique for diagnosing a medical condition through other types of body fluids such as saliva, sweat, and tears, or by using far-infrared and near-infrared rays.

However, there is a problem that it is difficult to obtain accurate measurement results for each individual because the correlation between the concentration of blood and saliva components is different for each individual.

The present invention is to provide an apparatus and method for measuring the concentration of the components in the blood using saliva to calculate the correlation characteristics of blood and saliva for each subject to know the accurate measurement results of the concentration of components in the blood do.

According to one aspect of the present invention, there is provided a method for measuring a concentration, the method for measuring the concentration of a component in blood using saliva, comprising: calculating a correlation between a component in blood of a subject and a component in saliva; Measuring the concentration of components in the subject's saliva; And calculating the concentration of the component in the blood of the subject using the correlation between the measured concentration of the component in the subject's saliva and the component in the subject's blood and the component in the saliva.

The calculating of the correlation may include measuring a concentration of a component in saliva of the subject in advance; Measuring the concentration of a component in blood of the subject in advance; And calculating the correlation between the components in the blood and the components in the saliva for the subject using a pair of pre-measured concentration measurement results of the components in the saliva and previously measured concentration measurements of the components in the blood. Include.

In addition, the ordered pair of the result of the concentration measurement of the components in the saliva and the concentration measurement result of the concentration of the components in the blood measured in advance is an ordered pair of the concentration of the components in the blood and the concentration of the components in the saliva for the subject measured over a plurality of times. .

In addition, the concentration of the components in the blood or the concentration of the components in the saliva is a measuring body for measuring the concentration of the components of the blood sample or saliva sample collected in the strip using the optical measuring device of the strip from which the blood sample or saliva sample is taken Measured when inserted into and mounted in the strip, and the strip is taken from a blood sample or saliva sample through capillary action, and when the strip is inserted into and mounted in the measuring body, the strip is stored in a reagent storage vinyl inside the strip. The aqueous reagent solution is discharged and mixed with the blood sample or saliva sample and the aqueous catalyst solution stored inside the strip.

In addition, the measuring body includes a cover, a mixture of a blood sample or saliva sample and the reagent aqueous solution and the catalyst aqueous solution mixed in the strip when the cover is opened and the cover is closed after the strip is inserted and mounted. Drive the strip to impinge on the lid to further mix.

Concentration measuring device according to another feature of the present invention,

A device for measuring the concentration of components in the blood using saliva, comprising a reagent aqueous solution and a catalyst solution therein, taking a blood sample or saliva sample through a capillary phenomenon, the collected blood sample and saliva sample is the reagent aqueous solution And a strip for storing the mixed solution with the aqueous catalyst solution; When the strip is inserted and mounted, the blood sample or saliva sample stored in the strip and the reagent aqueous solution and the catalyst aqueous solution are mixed with each other, and an optical measuring device is used for the mixture after the mixing of the components in the blood. And a measuring body for measuring the concentration or concentration of a component in saliva.

Here, the strip, the body; A capillary tube mounted on a portion of the body through a rubber band to collect the blood sample or saliva sample; A reagent storage vinyl fixed to the inner surface of the body to store the reagent aqueous solution; And a catalyst reservoir configured to store the aqueous solution of the catalyst at the distal end of the body inserted into the measuring body.

In addition, the capillary tube is formed with an air hole to allow a blood sample or saliva sample to be collected at a predetermined quantity.

In addition, when the capillary tube is pressurized from the outside, the distal end inserted into the main body tears the reagent storage vinyl so that the aqueous solution of the reagent is discharged from the reagent storage vinyl to the outside, and the blood sample or saliva inside the main body. It has a pointed shape to be mixed with the sample and the aqueous catalyst solution.

In addition, a vacuum is maintained between the reagent storage vinyl and the catalyst reservoir.

In addition, the reagent storage vinyl uses black vinyl to prevent the reaction of the internal reagent aqueous solution by the external light.

In addition, the measuring body, the cover for protecting the inside from the outside; An optical measuring device for performing concentration measurement; A strip support elastically coupled to the optical measuring device through a first spring to fix the position when the strip is inserted into the measuring body; And a strip fixing part elastically coupled to the inside of the measuring body through a second spring and driven to rotate about a rotation axis positioned at a side thereof to control the position of the strip support.

In addition, the strip fixing part presses the strip support to move to the fixed position so that the strip can be inserted into the measuring body and fixed on the strip support, or the strip support is moved out of the fixing position.

In addition, the cover includes a projection, when the cover is opened, the strip support is located in the fixed position by the rotational drive of the strip fixing portion by the second spring, the projection when the cover is closed, The strip support is driven to deviate from the fixed position by the rotational drive of the strip fixture by means of which the strip support is lifted by the first spring so that the strip collides with the lid and is mixed inside the strip. The blood sample or saliva sample, and the aqueous reagent solution and the aqueous catalyst solution are further mixed.

In addition, the measuring body is equipped with a saliva strip from which the saliva sample of the subject is collected to measure the concentration of the saliva component of the subject through the optical measuring device, and a blood strip from which the blood sample of the subject is collected is mounted. After measuring the concentration of the components in the blood of the subject through the optical measuring device, the concentration of the components of the subject's saliva and blood using the ordered pair of the concentration of the components of the subject's saliva and the blood components measured After calculating the correlation between the concentrations of the components of the subject, when the saliva strip from which the subject's saliva sample is taken is mounted and the concentration of the component in the subject's saliva is measured by the optical measuring device, Concentration of the component in the blood of the subject corresponding using the correlation between the concentration of the component and the concentration of the component in the blood. A controller for calculating a; And a display for displaying the information calculated by the controller to the outside.

According to the present invention, it is possible to reduce the cumbersome and painful blood sampling process by detecting the concentration of constituents in the blood with saliva and performing a self-diagnosis.

In addition, accurate results can be obtained by calculating correlation characteristics between blood and saliva for each subject.

In addition, blood or saliva can be quantitatively collected to obtain more accurate results.

1 is a graph showing a pair of sugar concentrations in four different blood and saliva.
FIG. 2 is a graph showing all four data shown in FIG.
3 is a view schematically showing a measuring device for measuring the concentration of the components in the blood using saliva according to an embodiment of the present invention.
4 is a diagram illustrating an example of taking a blood sample with the blood strip shown in FIG. 3.
FIG. 5 is a detailed configuration diagram of the blood strip shown in FIG. 3.
6 is a cross-sectional view of the blood strip when the capillary tube of the blood strip shown in FIG. 5 is pushed into the blood strip.
FIG. 7 is a schematic configuration diagram of the measuring body illustrated in FIG. 3 and illustrating a state in which a cover is opened.
FIG. 8 is a schematic configuration diagram of the measuring body shown in FIG. 3, illustrating a state where a cover is closed.
FIG. 9 is a view illustrating a process of inserting and inserting a strip into the measuring body illustrated in FIG. 3.
FIG. 10 is a view illustrating a process of covering a cover of the measuring body illustrated in FIG. 9.
11 is a flowchart of a method for measuring the concentration of components in blood using saliva according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise. In addition, the terms “… unit”, “… unit”, “module”, etc. described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. have.

First, it is explained that the correlation between the components in the blood and those in the saliva is not the same for each individual.

1 is a graph showing a pair of sugar concentrations in four different blood and saliva. Referring to FIG. 1, the blood and saliva concentration sequence pairs of the results measured for each of four A, B, C, and D persons are displayed, and the correlation equations simply calculated for each of them are also expressed.

Referring to FIG. 1, all of the equations represented in the four graphs are respectively different, and the slopes of the graphs are 15.565, 11.306, 69.195, and 81.677, respectively, showing a large difference from each other. That is, it can be seen that they are not identical or similar to each other.

FIG. 2 is a graph showing all four data shown in FIG. Similarly, the correlation equation is represented in FIG. Referring to FIG. 2, the slope of the graph is shown as 36.368 through the correlation equation, which is also a big difference from each of the four graphs shown in FIG. 1. In other words, even when all four data are combined, it can be seen that the graphs of four people are not identical or similar to each other.

As shown in FIG. 1, the data of four persons show that the relationship between the concentration of components in the blood and the concentration of components in the saliva varies greatly from person to person. If the above-described relationship of FIG. 2 is applied to everyone collectively, a large error will occur when measuring the concentration of components in the blood using the concentration of components in the saliva.

Hereinafter, the present invention will be described for accurately measuring blood components for each individual in consideration of differences in concentrations of components in blood and concentrations of saliva components.

3 is a view schematically showing a measuring device for measuring the concentration of the components in the blood using saliva according to an embodiment of the present invention.

Referring to FIG. 3, the measuring device 10 for measuring the concentration of a component in blood using saliva according to an embodiment of the present invention includes a measuring body 100, a blood strip 200, and a saliva strip 300. do. Here, the blood strip 200 and the saliva strip 300 have the same configuration, and to mark each of the strips with a mark corresponding to the outside, for example, "blood", "saliva", and / or color Can be displayed differently.

Each strip 200, 300 is disposable and serves for quantitation of blood or saliva samples, initiation of reaction with reagents, dilution of samples and preparation of quantitation. The detailed configuration of such strips 200 and 300 will be described later.

When the blood body 200 or the saliva strip 300 is mounted, the measuring body 100 performs mixing of a solution including a sample contained in the strips 200 and 300, and transmits light to the strips 200 and 300. The concentration of the components in the blood or saliva is measured by fluorescence. The measuring body 100 can be used semi-permanently by only replacing the battery that supplies power to the measuring body 100. The specific configuration of such a measurement main body 100 will also be described later.

FIG. 4 is a diagram illustrating an example of taking a blood sample with the blood strip 200 shown in FIG. 3.

Referring to FIG. 4, the blood sample is taken through a capillary tube 220 attached to the body 210 of the blood strip 200. Specifically, when the capillary tube 220 of the blood strip 200 touches the blood 400, the blood is taken up through the capillary tube 220 by capillary action and collected as a blood sample. At this time, the air hole 230 is drilled at a position corresponding to the quantification of the capillary tube 220 in order to take a quantitative measurement of the blood sample coming on the capillary tube 220. Therefore, the blood sample is adjusted to be raised to a position corresponding to the air hole 230 of the capillary tube 220 when the blood sample is collected, and as a result, the blood sample of the desired quantity can be collected. That is, by adjusting the position where the air hole 230 of the capillary tube 220 is formed, the amount of blood sample to be collected can be adjusted.

The operation of taking a blood sample with reference to FIG. 4 may be equally used to collect a saliva sample. That is, it means that the structure of the blood strip 200 can be equally applied to the structure of the saliva strip 200.

FIG. 5 is a detailed configuration diagram of the blood strip 200 shown in FIG. 3.

Referring to FIG. 5, a blood strip 200 according to an embodiment of the present invention includes a body 210, a capillary tube 220, a reagent storage vinyl 240, and a catalyst reservoir 250.

The main body 210 is equipped with a capillary tube 220 on a flat side. Specifically, a portion of the flat side surface of the main body 210, for example, the center portion is made of a rubber band 260, and the capillary tube 220 is formed in the form of passing through the center portion of the rubber band 260. 210 is mounted. At this time, the capillary tube 220 is fixed to the body 210 by a friction force with the rubber band 260 when no external force is applied, when the external force is applied in the direction of the rubber band 260 The capillary tube 220 is inserted into the body 210.

As described above, the blood or saliva sample may be collected and stored in the capillary tube 220 as described with reference to FIG. 4. Of course, the air cap 230 is formed in the capillary tube 220 to collect a predetermined amount of blood or saliva sample.

In addition, the distal end portion of the portion inserted into the main body 210 of the capillary tube 220 is sharply formed to tear the reagent storage vinyl 240 which will be described later when a force is applied from the outside. At this time, the pointed shape may be variously formed.

The reagent storage vinyl 240 stores the reagent 241 therein and is fixedly installed on a wall inside the body 210. In particular, the reagent storage vinyl 240 is fixedly installed on the body 210 so that the lower space 270 of the reagent storage vinyl 240 is sealed inside the body 210 to maintain a vacuum. In addition, the reagents may be stored in the reagent storage vinyl 240 in the form of an aqueous solution of reagents.

In addition, when the capillary tube 220 is inserted into the main body 210 by external pressure, the reagent storage vinyl 240 is torn off the center of the fixed reagent storage vinyl 240 by the distal end thereof. The reagent 241 stored therein is fixedly installed on the inner wall of the main body 210 so that the reagent 241 stored therein may be mixed with the blood or saliva sample discharged from the capillary tube 220.

In addition, the reagent storage vinyl 240 is made of black to prevent the reaction of the internal reagent by the external light.

Optionally, reagent storage vinyl 240 may store reagents, such as latex, and materials may be used that can be easily torn by capillary tube 220.

One side of the body 210, in particular the side opposite to the side into which the capillary tube 220 is inserted, forms the catalyst reservoir 250 in a shape that protrudes outwardly.

The catalyst reservoir 250 previously stores a catalyst 251 to be mixed with blood or saliva samples and reagents. At this time, the catalyst 251 stored in the catalyst reservoir 250 is stored in the form of an aqueous solution, and since the lower space of the main body 210 to which the aqueous catalyst solution contacts is maintained in a vacuum state, the reagent storage vinyl 240 is later added. The torn state may remain stored in the catalyst reservoir 250 until the vacuum is broken.

FIG. 6 is a cross-sectional view of the blood strip 200 when the capillary tube 220 of the blood strip 200 shown in FIG. 5 is pushed into the blood strip 200.

Referring to FIG. 6, the capillary tube 220 is pressed by an external force, and thus the capillary tube 220 is completely inserted into the main body 210.

As such, when the capillary tube 220 is pressurized (P1) into the main body 210 and inserted, the reagent storage vinyl 240 is torn by the distal end of the capillary tube 220, and thus the inside of the reagent storage vinyl 240 is broken. The reagent aqueous solution 241 stored in the solution is discharged from the reagent storage vinyl 240 to the catalyst reservoir 250, and the blood sample 221 collected and stored in the capillary tube 220 is also capillary. The li tube 220 meets the vacuum space 270 of the body 210 and is sucked out of the capillary tube 220 and lowered toward the catalyst reservoir 250. As a result, the capillary tube 220 is pressurized into the main body 210 so that the blood sample 221, the aqueous reagent solution 241 and the aqueous catalyst solution 251 are mixed with each other in the lower space of the main body 210. do. Meanwhile, the concentrations of the reagent aqueous solution 241 and the catalyst aqueous solution 251 may be adjusted by the amount of water.

The blood strip 200 has been described in detail above, and the configuration of the blood strip 200 depends on whether the sample to be taken is blood or saliva, and is the same as the configuration of the saliva strip 300, thus the saliva strip 300 ), A detailed description thereof will be omitted.

Next, a specific configuration of the measuring body 100 of the concentration measuring apparatus 10 according to the embodiment of the present invention will be described.

FIG. 7 is a schematic configuration diagram of the measurement body 100 illustrated in FIG. 3. The cover 110 is opened. FIG. 8 is a schematic configuration diagram of the measurement body 100 illustrated in FIG. 3. , Is a view showing a state in which the cover 110 is closed.

Referring to FIG. 7, for measuring the concentration in the strips 200 and 300 when the strips 200 and 300 are mounted on the measuring body 100, for example, a light emitting display (LED) and a photo deck (PD) The optical measuring device 120 including a is installed at the bottom, the two strip support 141, 142 is elastically coupled to the upper surface of the optical measuring device 120 via the spring (131, 132). . That is, the strip supports 141 and 142 can be moved up and down by the springs 131 and 132. At this time, the two strip support (141, 142), although not shown is connected to each other, the vertical movement is interlocked with each other. For example, while being elastically coupled to the side of the measuring body 100 by the spring 150, the strip fixing part 160 is installed on the measuring body 100 so as to be able to rotate about the rotating shaft 161. When one strip support 142 is pressed down and fixed using the other strip support 141 is also pressed down and fixed together. And, as shown in FIG. 8, when the strip fixing part 160 is operated to be out of a position for pressing and holding the strip support 142 downward, the two strip supports 141 and 142 are both springs 131, 132 may be moved upwards.

In addition, a strip insertion hole 121 through which the catalyst reservoir 250 of the strips 200 and 300 can be inserted is formed between the top and the optical strip device 141 and 142 of the optical measuring device 120.

The cover 110 is provided at an upper portion of the measurement main body 100, and the cover 110 is provided so that foreign matter such as dust does not enter from the outside when the measurement main body 100 is not used. It is used to cover the, when the strip (200, 300) is inserted into the measuring body 100 can be used by opening the cover 110, in which case the cover (110) is pushed to the side and lifted open, In the case of closing, the cover 110 is mounted on the measurement main body 100 in a form of closing by pulling the cover 110 laterally.

Specifically, as shown in FIG. 8, when the cover 110 is closed, the strip fixing part 160 is formed by the protrusions 111 formed on the lower surface of the cover 110. It acts so as not to pressurize it. This may be achieved by rotating the strip fixing portion 160 to press the spring 150 by the movement of the protrusion 111 when the cover 110 is pulled down after being lowered. In addition, in order to insert the strips 200 and 300, when the cover 110 is opened, the protrusion 111 acting on the strip fixing unit 160 is moved, so that the strip fixing unit 160 of the spring 150 is moved. Due to its elasticity, it is rotated and moved to a position to press the strip support 142.

Next, a process in which the blood strip 200 or the saliva strip 300 is inserted into the measuring body 100 and mounted in the measuring body 100 for measuring the components in the blood or the components in the saliva is described.

9 is a view illustrating a process in which strips 200 and 300 are inserted into and mounted in the measuring body 100 shown in FIG. 3, and FIG. 10 is a process of covering a cover of the measuring body 100 shown in FIG. 9. Figure is a diagram.

Referring to FIG. 9, after the cover 110 of the measurement body 100 is covered as shown in FIG. 8, the cover 110 is pushed to the side (S1), and then lifted (S2) as illustrated in FIG. 7. As described above, the cover 110 is in an open state.

Thereafter, in the process of inserting the blood strip 200 from which the blood sample is taken or the saliva strip 300 from which the saliva sample is taken, by the operator's finger H1, the blood strip 200 is inserted into the strip insertion hole 121. As shown, the capillary tube 220 of the strips (200, 300) is pressed is inserted into the body 210 (S3). By doing so, the strips 200 and 300 are mounted on the optical measuring device 120 with the sample, the reagent aqueous solution and the catalyst aqueous solution mixed therein. At this time, the strip feet (141, 142) is in the position where the spring (131, 132) is pressed by the strip fixing portion 160, the body of the strip (200, 300) on the strip supports (141, 142) 210) is placed. Here, the strip supports 141 and 142 inform the holes 121 into which the strips 200 and 300 are to be inserted and serve to fix the strips 200 and 300.

Next, referring to FIG. 10, as shown in FIG. 9, after the strips 200 and 300 are inserted into and mounted in the measurement main body 100, the cover 110 is covered with the cover 110 open ( S4), and pulled sideways (S5) so that the cover 110 is in a closed state as shown in FIG. 8.

At this time, when the cover 110 is pulled, by rotating the strip fixing portion 160 in the form of pressing the spring 150 around the rotation shaft 161 by the protrusion 111 (S6), the strip support 141 , The fixing state of the strip fixing unit 160 for pressing the 142 is released so that the strip support 141, 142 is raised by the springs (131, 132) (S7). Therefore, the strips 200 and 300 fixed by the strip supports 141 and 142 rise together to form the upper part of the strips 200 and 300, that is, the surface into which the capillary tube 220 is inserted. While colliding with the cover 110 of 100), the reagent solution or sample drops attached to the inner walls of the strips 200 and 300 are collected and mixed once more. In addition, the strip receiving members 141 and 142 are pushed in the direction of the strips 200 and 300 by the springs 131 and 132 so that the strips 200 and 300 are pressed against the cover 110 of the main body. As a result, the mixture of the reagent aqueous solution, the catalyst aqueous solution, and the sample may be fixed to the main body 100 to be measured without shaking.

Thereafter, the optical measuring device 120 transmits light to the portions of the strips 200 and 300 inserted into the strip insertion hole 121 and detects the transmitted light to detect the components of the sample in the strips 200 and 300. For example, the concentration of blood or saliva can be measured. Here, since the optical measuring device 120 transmits light to the strips 200 and 300 and detects the transmitted light, the technique of measuring the concentration of a component of the sample inside the strips 200 and 300 is well known. The detailed description is omitted.

On the other hand, the measurement main body 100 further includes a measurement control unit (not shown) for performing a control for measuring the concentration of the components in the blood or saliva according to an embodiment of the present invention.

Hereinafter, a method of measuring the concentration of a component in blood using saliva according to an embodiment of the present invention by a measurement control unit (not shown) will be described.

11 is a flow chart of a method for measuring the concentration of components in the blood using saliva according to an embodiment of the present invention.

Before explanation, the saliva sample of the subject to be measured for concentration of components in blood is collected in saliva strip 300, and if necessary, the blood sample of the subject to be measured for concentration of components in blood is collected in blood strip 200. Assume that

First, the LED intensity adjustment of the optical measuring device 120 is performed (S100). Such LED intensity adjustment may be made by pulse width modulation (PWM). If the variable for adjusting the period of the PWM is d, d can be adjusted within the range of 1 to 255. The LEDs are adjusted in brightness by turning d on and off (255-d) within one cycle. Therefore, the larger d, the brighter the LED, and the smaller d, the darker the LED. When the desired LED intensity is specified via the control unit (not shown), d is automatically reduced if the measured value read through the photodetector (PD) (not shown) is greater than that, and d is automatically measured if the measurement value is smaller than that. By raising, you can adjust the LED intensity to the desired value.

Next, as shown in FIGS. 4 and 5, the saliva strip 300 from which the saliva sample is taken is inserted into the measuring body 100 as shown in FIGS. 9 and 10 (S110), and the optical measurement The concentration of the components in the saliva, for example, the sugar concentration, is measured by the apparatus 120 (S120). Here, the concentration measurement can be performed as follows, for example. From the beginning of the concentration measurement, the measured values are sampled at short intervals via the PD. When the amount of change in the value measured by the PD falls within a certain range (eg, 1% of the measured value), the measured value at that time is determined as the result value.

Thereafter, mode selection is performed (S130). Here, two modes are used, namely, a first mode and a second mode.

The first mode is a mode for calculating a correlation between the concentration of a component in saliva and the concentration of a component in blood. That is, since the correlation between the concentration of the components in the saliva and the concentration of the components in the blood is different for each individual, the concentration between the concentration of the components in the blood and the concentrations of the components in the saliva The correlation is calculated in advance.

The second mode is a mode in which the concentration of the component in the blood is calculated using the correlation calculated in the first mode when the concentration of the component in the saliva is measured. Therefore, the second mode can be performed only after the first mode is preceded.

First, a case in which the first mode is selected in the mode selection step S130 will be described.

Since the concentration of the components in the saliva has already been measured through the step (S130), in order to measure the concentration of the components in the blood corresponding thereto, the blood strip 300 from which the blood sample of the same user is taken is inserted into the measuring body 100. (S140), the concentration of the component in the blood, for example, the sugar concentration is measured by the optical measuring device 120 (S150).

Thereafter, the ordered pairs of the concentrations of the components in the saliva measured in the step (S130) and the concentration of the components in the blood measured in the step (S150) are stored (S160), and the concentration of the components in the blood and the concentration of the components in the saliva It is determined whether all of the ordered pairs to be used to calculate the correlation between the prepared (S170). As described above with reference to FIGS. 1 and 2, in general, the correlation between the concentration of components in blood and the concentration of components in saliva is calculated using a plurality of ordered pairs. The preparation process is repeated. The number of such ordered pairs may be set in advance. Of course, if there is one ordered pair to be used to calculate the correlation between the concentration of the components in the blood and the concentration of the components in the saliva, the following operation can be performed immediately without determination (S170).

Therefore, if it is determined in step S170 that all of the ordered pairs to be used for calculating the correlation between the concentration of the components in the blood and the concentration of the components in the saliva are not prepared, the concentration between the concentration of the components in the blood and the concentration of the components in the saliva is determined. Steps S110 and S120 of preparing an ordered pair to be used for calculating correlation are repeatedly performed.

On the other hand, if it is determined in step S170 that all of the ordered pairs to be used to calculate the correlation between the concentration of the components in the blood and the concentration of the components in the saliva are prepared, the values of the components of the blood and the saliva in The correlation between the concentrations of the components is calculated (S180).

Then, the correlation between the calculated concentration of the components in the blood and the concentration of the components in the saliva is stored and displayed to the outside (S190). To this end, the measurement body 100 may further include a display (not shown) for displaying information to the outside.

As such, after the correlation between the concentration of the components in the blood and the concentration of the components in the saliva is calculated by performing the first mode, the second mode may be selected in the mode selection step 130.

When the second mode is selected in the mode selection step 130, the concentration of the components in the saliva measured in the step (S120) and the concentration of the components in the blood and the concentration of the components in the saliva calculated in the step (S180) Calculate the concentration of components in the blood using the correlation of (S200).

Then, the calculated concentration of the components in the blood is stored and displayed to the outside (S190).

On the other hand, storing the concentration value of the concentration of the components in the blood calculated in the step (S190), that is, the result of measuring the concentration of the components in the blood using saliva according to an embodiment of the present invention is the measured value date, time Store it with information, and if the storage space is full, delete the oldest first. In addition, the concentration of the components in the blood to be stored is stored along with the concentrations of the components in the saliva that underlie these measurements. This also deletes the oldest if the storage space is full.

According to an embodiment of the present invention, since the concentration of the components of the blood in the saliva can be self-diagnostic, it can reduce the cumbersome and painful blood collection process.

In addition, accurate results can be obtained by calculating correlation characteristics between blood and saliva for each subject.

In addition, blood or saliva can be quantitatively collected to obtain more accurate results.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (15)

A method of measuring the concentration of components in the blood using saliva,
Calculating a correlation between a component in a subject's blood and a component in saliva;
Measuring the concentration of components in the subject's saliva; And
Calculating the concentration of the component in the subject's blood using the correlation between the measured concentration of the component in the subject's saliva and the component in the subject's blood and the component in the saliva
Concentration measurement method comprising a. The method of claim 1,
Computing the correlation,
Measuring the concentration of a component in the saliva of the subject in advance;
Measuring the concentration of a component in blood of the subject in advance; And
Calculating the correlation between the components in the blood and the components in the saliva for the subject using a pair of pre-measured concentration measurement results of the components in the saliva and previously measured concentration measurements of the components in the blood
Containing, concentration measurement method. The method of claim 2,
The ordered pair of the result of the concentration measurement of the components of the saliva and the measurement result of the concentration of the components of the blood measured in advance is an ordered pair of the concentration of the components of the blood and the concentration of the components in the saliva for the subject measured over a plurality of times,
Concentration Measurement Method. The method of claim 1,
The concentration of the component in the blood or the component in the saliva is inserted into the measuring body in which the strip from which the blood sample or saliva sample is taken measures the concentration of the component of the blood sample or saliva sample taken in the strip using an optical measuring device. Measured when mounted,
The strip collects a blood sample or saliva sample through a capillary phenomenon, and when the strip is inserted into the measuring body and mounted thereon, an aqueous solution of a reagent stored in a reagent storage vinyl inside the strip is discharged to the blood sample or saliva. Mixed with a sample and an aqueous catalyst solution stored inside the strip,
Concentration Measurement Method. The method of claim 3,
The measuring body includes a cover,
When the lid is opened so that the lid is closed after the strip is inserted and mounted, the strip may be further mixed to further mix a mixture of the blood sample or saliva sample and the aqueous solution of the reagent and the aqueous catalyst solution mixed in the strip. Driven to crash into,
Concentration Measurement Method. A device for measuring the concentration of components in the blood using saliva,
A strip including an aqueous reagent solution and an aqueous catalyst solution therein, collecting blood samples or saliva samples through capillary action, and storing the collected blood samples and saliva samples so as not to mix with the reagent aqueous solution and the aqueous catalyst solution;
When the strip is inserted and mounted, the blood sample or saliva sample stored in the strip and the reagent aqueous solution and the catalyst aqueous solution are mixed with each other, and an optical measuring device is used for the mixture after the mixing of the components in the blood. Measuring body for measuring the concentration or concentration of components in saliva
Concentration measuring device comprising a. The method of claim 6,
The strip,
main body;
A capillary tube mounted on a portion of the body through a rubber band to collect the blood sample or saliva sample;
A reagent storage vinyl fixed to the inner surface of the body to store the reagent aqueous solution; And
A catalyst reservoir configured to store the aqueous solution of the catalyst at a distal end of the body inserted into the measuring body;
Containing a concentration measuring device. The method of claim 7, wherein
The capillary tube is formed with an air hole for allowing a blood sample or saliva sample to be taken at a predetermined quantity,
Concentration measuring device. The method of claim 7, wherein
When the capillary tube is pressurized from the outside, the distal end inserted into the main body tears the reagent storage vinyl so that the aqueous solution of the reagent is discharged from the reagent storage vinyl to the outside, so that the blood sample or saliva sample is separated from the inside of the main body. Having a pointed shape to be mixed with the aqueous catalyst solution,
Concentration measuring device. The method of claim 7, wherein
Maintaining a vacuum between the reagent storage vinyl and the catalyst reservoir,
Concentration measuring device. The method of claim 7, wherein
The reagent storage vinyl uses a black vinyl to prevent the reaction of the reagent solution inside by the external light,
Concentration measuring device. The method of claim 6,
The measuring body,
A cover for protecting the interior from the outside;
An optical measuring device for performing concentration measurement;
A strip support elastically coupled to the optical measuring device through a first spring to fix a position when the strip is inserted into the measuring body; And
A strip fixing part elastically coupled to the inside of the measuring body through a second spring and driven to rotate about a rotation axis located at a side thereof to control the position of the strip support.
Containing a concentration measuring device. The method of claim 12,
Wherein the strip fixing portion presses the strip support to move to a fixed position so that the strip can be inserted into the measuring body and fixed on the strip support, or to move the strip support out of the fixing position,
Concentration measuring device. The method of claim 13,
The cover includes a projection,
When the cover is opened, the strip support is positioned in the fixed position by rotational driving of the strip fixing part by the second spring,
When the cover is closed, the strip support is driven to be out of the fixed position by the rotational drive of the strip fixing part by the projection, so that the strip support is lifted by the first spring so that the strip rests on the cover. The blood sample or saliva sample and the aqueous solution of the reagent and the aqueous catalyst solution are further mixed by the collision,
Concentration measuring device. The method of claim 12,
The measuring body,
A saliva strip from which a subject's saliva sample is collected is mounted to measure the concentration of a component in the saliva of the subject through the optical measuring device, and a blood strip from which the blood sample of the subject is collected is mounted to the After measuring the concentration of the component in the subject's blood, the correlation between the concentration of the component in the subject's saliva and the concentration of the component in the blood using the measured pairs of concentrations of the component in the subject's saliva and the concentration of the component in the blood After calculating the relationship,
Correlation between the concentration of components in the saliva of the subject and the concentration of components in the blood, when the saliva strip from which the saliva sample of the subject is taken and the concentration of the components in the saliva of the subject is measured by the optical measuring device A control unit for calculating a concentration of components in the blood of the subject corresponding thereto; And
Display for displaying the information calculated by the controller to the outside
Further comprising, the concentration measuring device.

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