KR20230032431A - Dry eye diagnostic method using quantitative immunoassay analysis - Google Patents

Abstract

The present invention relates to a dry eye diagnosis method using quantitative immunoassay analysis, more specifically, wherein an amount of a test subject's tears and an amount of target ingredient (matrix metallo-proteinase (MMP) 9 proteins) contained in the tears are quantified and at the same time, a protein content per unit tear volume is considered to allow quick and accurate determination of dry eye. In particular, in the present invention, a tear volume is quantified using a Schirmer strip or strip meniscometry (SM) tube, and the target ingredient is analyzed through fluorescence immunology-based lateral flow analysis to allow accurate analysis and diagnosis. In addition, in the present invention, quick and easy diagnosis at the level of a diagnostic kit is possible, and at the same time, even mild patients with low sensitivity can be accurately diagnosed through numerical quantitative results to improve sensitivity. Therefore, reliability and competitiveness can be improved in fields of dry eye diseases, especially a field of dry eye diagnosis, and similar or related fields such as fields related to lesions such as glaucoma, Sjögren's syndrome, rheumatoid arthritis, Parkinson's disease, and autoimmune diseases.

Description

Dry eye diagnostic method using quantitative immunoassay analysis}

The present invention relates to a method for diagnosing dry eye using quantitative immunoassay, and more particularly, to the amount of tears of a test subject and the target component (Matrix Metallo-Proteinase (MMP, matrix metalloproteinase) 9 protein) contained in tears. By quantifying the amount and simultaneously considering the protein content per unit tear volume, it is possible to quickly and accurately determine dry eye.

In particular, the present invention quantifies the tear amount using a Schirmer strip or SM (Strip Meniscometry) tube, and analyzes the target component through fluorescence immunological-based lateral flow analysis, thereby providing accurate analysis. and a method for diagnosing dry eye using quantitative immunoassay enabling diagnosis.

In the inner skin of the human eyelid, there are meibomian glands that drain the fat layer for the tear film and lacrimal glands that drain water-containing tears.

The tear film formed from the fat and tears secreted by the meibomian and lacrimal glands is formed as a continuous and complex multi-layered structure composed of water, inorganic salts, carbohydrates, lipids and proteins, covering the entire exposed ocular surface to protect the eyeball and act as a lubricant. It performs nutritional and antibacterial action.

At this time, if the quality and quantity of the tear film change, Dry Eye Syndrome (DES) may occur, causing discomfort and, in severe cases, eye inflammation. can be induced

In general, dry eye syndrome has a high incidence mainly in women over the age of 50, but recently, as the use of smartphones and the like increases, it has occurred in men and women of all ages.

Most dry eye symptoms are caused by meibomian gland dysfunction (Meibomian Gland Dysfunction), and when the meibomian gland is blocked or thickened to produce or release lipids, it affects the formation of the tear film.

Examples of such meibomian gland dysfunction include low fat transfer and obstructive meibomian gland dysfunction and high transfer rate, seborrheic type meibomian gland dysfunction.

Among them, in the case of low fat transfer and obstructive meibomian gland dysfunction, moisture in the tear film evaporates easily due to fat deficiency, resulting in dry eyes.

In the case of high transmission rate, seborrheic type meibomian gland dysfunction, the meibomian gland secretes excessive fat to induce an inflammatory reaction on the ocular surface, which causes inflammation in the eye.

MMP 9 is a protein produced by stimulation of epithelial cells on the ocular surface by this inflammatory response. It is a typical indicator material used.

Since dry eye syndrome can cause complications if it is not treated for a long time, it has become necessary to promptly diagnose and treat dry eye syndrome.

As one of these technologies, the following prior art document, Republic of Korea Patent Registration No. 10-2193937, 'Semi-quantitative immunoassay diagnosis kit for diagnosing inflammatory dry eye syndrome' (hereinafter referred to as 'prior art') overcomes the disadvantages of conventional qualitative analysis. It is a technology that diagnoses in a semi-quantitative way to solve it.

However, in the case of the prior art, the target to be measured in a semi-quantitative amount is MMP 9, and dry eye syndrome is diagnosed only with the amount of MMP 9. There is a problem that errors in diagnosis may occur.

Korean Patent Registration No. 10-2193937 'Semi-quantitative immunoassay diagnostic kit for diagnosing inflammatory dry eye syndrome'

In order to solve the above problems, the present invention quantifies the amount of tears of the test subject and the amount of the target component (MMP 9 protein) contained in the tears, and simultaneously considers the protein content per unit tear amount, quickly and accurately. An object of the present invention is to provide a method for diagnosing dry eye using a quantitative immunoassay capable of discriminating dry eye.

In particular, the present invention quantifies the amount of tears using Schirmer test strips or SM tubes, and analyzes target components through fluorescence immunological-based lateral flow analysis, enabling accurate analysis and diagnosis. An object of the present invention is to provide a method for diagnosing dry eye using quantitative immunoassay.

In addition, the present invention enables rapid and simple diagnosis at the level of a diagnostic kit, and at the same time, quantitative immunology that can improve sensitivity so that diagnosis of mild patients with low sensitivity can be accurately performed through quantified quantitative results. An object of the present invention is to provide a method for diagnosing dry eye using analysis.

In order to achieve the above object, the method for diagnosing dry eye using a quantitative immunoassay according to the present invention includes a tear amount quantification step of measuring a tear amount by collecting tears of a test subject; Target component quantification step of quantifying the target component contained in the collected tears; and a dry eye determination step of determining dry eye based on the amount of tears collected and the amount of the target component.

In addition, the target component may include MMP 9 protein.

In addition, the tear amount quantification step, a tear collection process of collecting tears using any one of a Schirmer strip and a SM tube (Strip Meniscometry tube); An indirect calculation process of calculating the amount of tears by measuring the length permeated into the Schirmer test strip when the Schirmer test strip is collected; and a direct confirmation process of confirming the amount of tears collected by the SM tube when collected by the SM tube.

In addition, in the step of quantifying the target component, a sample solution prepared by eluting the target component contained in tears collected using any one of a Schirmer strip and a strip meniscometry tube (SM tube) as an elution solution solution preparation process; and a target component quantification step of analyzing and quantifying the target component included in the sample solution.

In addition, the elution solution can recognize the epitope of the target component and may include a buffer-based solution containing an antibody to which a fluorescent substance is attached.

In addition, the elution solution may further include at least one of 'Stabilizer', 'Detergent' and 'Preservative' based on 'Buffer'.

In addition, the 'Buffer' may include at least one of 'Tris-HCl', 'PBS', 'HEPES', 'MES', 'CAPSO', 'MOPS' and 'Borate buffer'.

In addition, the 'Stabilizer' may include at least one of 'Sucrose', 'BSA' and 'StabilGuard'.

Also, the 'Detergent' may include at least one of 'Triton X-100', 'Tween 20', 'IGEPAL CA630', 'CHAPS', 'TTAB' and 'Anzergent'.

Also, the 'Preservative' may include at least one of 'NaN3' and 'ProClin'.

In addition, the elution solution is 'Phosphate buffer saline', 'Sodium phosphate buffer', 'MES (2-(N-morpholino)ethanesulfonic acid) buffer', 'MOPS (3-(N-morpholino)propanesulfonic acid) buffer' , 'Tris buffer', 'HEPES (4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid', 'Borate buffer'-based solutions may include at least one.

In addition, the elution solution may further include at least one of 'Preservative' and 'Stabilizer'.

In addition, the 'Preservative' may include at least one of 'NaN3' and 'ProClin 300'.

In addition, the 'Stabilizer' may include at least one of 'Bovine serum albumin (BSA)', 'Polysorbate 20 (Tween 20)', 'Triton x100', 'Sucrose', and 'BHT (Butylated hydroxytoluene)' .

In addition, in the process of quantifying the target component, the target component may be quantified using fluorescence immunological-based lateral flow analysis.

In addition, the process of quantifying the target component may include an antibody immobilization process of immobilizing the antibody to the bottom of the lateral flow membrane; a target component binding step of binding the target component to the antibody by lateral flow of the sample solution through the membrane; and a fluorescent substance identification process of quantifying a target component by confirming the fluorescent substance attached to the antibody.

In addition, the step of determining whether or not the dry skin is dry may include a target component concentration check process of dividing the amount of the target component quantified through the confirmation of the fluorescent material by the quantified amount of tears to determine the concentration of the target component included in the unit tear amount; and a dry eye diagnosis process of comparing the confirmed concentration of the target component with a reference value for determining dry eye to determine whether or not there is dry eye.

In addition, a data management step of converting the quantitative results of the target component into a database to be used as a database of related fields including at least one of diagnosis of related diseases and basic technologies of smart health care; may be further included.

By means of the above solution, the present invention quantifies the amount of tears of the test subject and the amount of the target component (MMP 9 protein) contained in the tears, and simultaneously considers the protein content per unit amount of tears, thereby quickly and accurately dry eye. It has the advantage of being able to discriminate.

In particular, the present invention has the advantage of enabling accurate analysis and diagnosis by quantifying the amount of tears using Schirmer test strips or SM tubes and analyzing target components through fluorescence immunological-based lateral flow analysis.

In addition, the present invention has the advantage of enabling rapid and simple diagnosis at the level of a diagnostic kit, and at the same time improving sensitivity so that diagnosis of mild patients with low sensitivity can be accurately performed through quantified quantitative results. there is.

In addition, the present invention has the advantage of supplementing the difficulty of collecting a small amount of tears through the biomarker ratio by adding a biomarker for target lesions associated with dry eye, and enabling expansion of the diagnostic subject.

Through this, the present invention has the advantage of enabling diagnosis by expanding related target lesions to glaucoma, Sjogren's syndrome, rheumatoid arthritis, Parkinson's disease, and the like.

In addition, the present invention has the advantage of numerically leveling the inflammation of the diagnostic kit and using it as a database of related fields including at least one of diagnosis of related diseases and basic technologies of smart health care.

In addition, the present invention has the advantage of enabling rapid and precise measurement by minimizing the diagnostic evaluation process by enabling integration or assembly of the sample collection unit and the diagnostic kit.

Therefore, reliability and competitiveness in similar or related fields such as the field of dry eye disease, especially the field of diagnosis of dry eye disease, as well as fields related to related target lesions such as glaucoma, Sjogren's syndrome, rheumatoid arthritis, Parkinson's disease, and autoimmune diseases Improve reliability and competitiveness can make it

1 is a flowchart showing an embodiment of a method for diagnosing dry eye using a quantitative immunoassay according to the present invention.
FIG. 2 is a flowchart illustrating a specific embodiment of FIG. 1 .
FIG. 3 is a flowchart illustrating a specific embodiment of step 'S100' shown in FIG. 1 .
FIG. 4 is a flowchart illustrating a specific embodiment of step 'S200' shown in FIG. 1 .
5 is a flowchart illustrating a specific embodiment of the process 'S220' shown in FIG. 4 .
6 is a flowchart illustrating a specific embodiment of step 'S300' shown in FIG. 1 .
7 is a flowchart illustrating another embodiment of FIG. 1 .
Figure 8 is a graph showing the quantification of the target component (MMP 9) by Figure 1, (a) is taken into account the sample amount, (b) is not taken into account the sample amount.
FIG. 9 is a standardized table of a plurality of specimens including tears and target components according to FIG. 1 .

Examples of the method for diagnosing dry eye using quantitative immunoassay according to the present invention can be applied in various ways, and hereinafter, the most preferred embodiment will be described with reference to the accompanying drawings.

1 is a flowchart showing an embodiment of a method for diagnosing dry eye using a quantitative immunoassay according to the present invention.

Referring to FIG. 1 , the method for diagnosing dry eye using quantitative immunoassay includes a step of quantifying a tear amount (S100), a step of quantifying a target component (S200), and a step of determining whether or not there is dry eye (S300).

The tear amount quantification step (S100) is a process of measuring the amount of tears by collecting the tears of the test subject, collecting tears from the eyes of the test subject for a specific time, and measuring the amount of collected tears.

For example, tears of test subjects are tested using a Schirmer strip, a strip meniscometry tube (SM tube), a capillary tube, and a cellulose rod as well as Merocel, a polyvinyl alcohol material. , ophthalmic sponges containing KeraCel, a high-density polyvinyl alcohol material, and Weck-cel, a cellulose material, etc., and sampling methods can be diversified in various ways.

The target component quantification step (S200) is to analyze and quantify the target component contained in the collected tears, and the target component may include Matrix Metallo-Proteinase (MMP, matrix metalloproteinase) 9 protein.

At this time, the target component can be analyzed using an 'all-in-one' type tube in which samples can be prepared at once using a tube equipped with a filter without separately removing the sampling tool.

The dry eye determination step (S300) is a process of determining dry eye based on the amount of tears collected and the amount of the target component. The ratio of the target component among the total tears is calculated and based on this, the dry eye is not determined only by the target component. By discriminating dry eye, it is possible to make an accurate diagnosis of the test subject.

Hereinafter, the method shown in FIG. 1 will be examined in more detail.

FIG. 2 is a flowchart illustrating a specific embodiment of FIG. 1 .

First, tears are collected from the eyes of the test subject (S101) and the amount of collected tears is quantified (S102). For example, when tears are collected using Schirmer test strips, the length of tears soaked into the Schirmer test strip can be measured, and the corresponding length can be converted into the amount of tears.

Then, the MMP 9 protein contained in tears is eluted (S201), diluted with a certain amount of distilled water (S202), mixed with a detection antibody (S203), and reacted with the detection unit (S204). For example, the MMP 9 protein contained in tears may be eluted using an elution solution, and this may be prepared as a sample solution.

At this time, if the detection unit operates normally (S205), the ratio of MMP 9 to the amount of tears can be checked (S206), and if the detection unit does not operate normally (S205), tears are collected from the eyes of the test subject again. (S101), the previous process can be performed again.

Then, the ratio of MMP 9 to the amount of tears is compared with the clinical cut-off value, and if the ratio is greater than the cut-off value, the test subject's eye condition is determined as dry eye (S302), If the ratio is smaller than the cutoff value, the eye condition of the test subject may be determined to be normal (S303).

On the other hand, the processes 'S202' to 'S303' shown in FIG. 2 can be integrated and processed within one device, and the diagnostic evaluation process can be minimized and quickly and efficiently by integrating or assembling the sample collection unit and the diagnostic kit. It can make precise measurements possible.

FIG. 3 is a flowchart illustrating a specific embodiment of step 'S100' shown in FIG. 1 .

First, in the step of quantifying the amount of tears (S100), tears can be collected (S111) using either a Schirmer strip or a strip meniscometry tube (SM tube).

At this time, if the method of collecting tears is the Schirmer test strip (S112), the amount of tears can be calculated (S114) by measuring the length permeated into the Schirmer test strip (S113), and this method is an indirect confirmation method It is said. In other words, it is a method to check the amount of tears by collecting tears and then converting them.

If collected with the SM tube (S112), the amount of tears collected by the SM tube can be directly confirmed (S115), and this method is called a direct confirmation method. In other words, it is a method in which the amount of tears collected can be checked immediately by checking the scale of the kit from which the tears were collected.

FIG. 4 is a flowchart illustrating a specific embodiment of step 'S200' shown in FIG. 1 .

Referring to FIG. 4 , the target component quantification step (S200) may include a sample solution preparation step (S210) and a target component quantification step (S220).

The sample solution preparation process (S210) is a process of preparing a sample solution in which the target component contained in the collected tears is eluted using either a Schirmer strip or a SM tube (Strip Meniscometry tube) as an elution solution. In this case, an 'all-in-one' type of tube can be used to prepare a sample at once using a tube with a filter installed without removing the collection tool separately.

At this time, the elution solution uses a 'Phosphate buffer saline' buffer-based solution, and may include an antibody attached with a fluorescent substance capable of recognizing one epitope of the target component (MMP 9).

In one embodiment, the elution solution may further include at least one of 'Stabilizer', 'Detergent' and 'Preservative' based on 'Buffer'.

Here, 'Buffer' may include at least one of 'Tris-HCl', 'PBS', 'HEPES', 'MES', 'CAPSO', 'MOPS' and 'Borate buffer'.

In addition, 'Stabilizer' may include at least one of 'Sucrose', 'BSA' and 'StabilGuard', and 'Detergent' may include 'Triton X-100', 'Tween 20', 'IGEPAL CA630', ' It may include at least one of CHAPS', 'TTAB' and 'Anzergent', and 'Preservative' may include at least one of 'NaN3' and 'ProClin'.

In another embodiment, the elution solution is a solution based on 'Phosphate buffer saline', a solution based on 'Sodium phosphate buffer', a solution based on 'MES (2-(N-morpholino)ethanesulfonic acid) buffer', a solution based on 'MOPS (3- (N-morpholino)propanesulfonic acid) buffer' based solution, 'Tris buffer' based solution, 'HEPES (4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid' based solution, 'Borate buffer' based solution) may contain at least one.

In addition, the elution solution may further include at least one of 'Preservative' and 'Stabilizer'.

Here, 'Preservative' may include at least one of 'NaN3' and 'ProClin 300', and 'Stabilizer' may include 'Bovine serum albumin (BSA)', 'Polysorbate 20 (Tween 20)', and 'Triton x100'. ', 'Sucrose', may include at least one of 'BHT (Butylated hydroxytoluene)'.

In addition, the elution solution can be easily used by diluting it with distilled water while making it easy to store by making it a dry formulation using freeze-drying as well as a liquid type.

The target component quantification process (S220) is a process of analyzing and quantifying the target component included in the sample solution, and the target component can be quantified using fluorescence immunological-based lateral flow analysis.

Hereinafter, this will be examined in more detail.

5 is a flowchart illustrating a specific embodiment of the process 'S220' shown in FIG. 4 .

First, an antibody that specifically binds to the target component, MMP 9 protein, is immobilized on the bottom of the lateral flow membrane (S221), and the sample solution is lateral flowed on the membrane to bind the target component in the tear sample to the antibody in the process of lateral flow. It can (S222).

In addition, by confirming the fluorescent substance-attached antibody bound to the epitope of the target component, the content of the target component can be precisely and sensitively analyzed (quantified) in a short time (eg, within 12 minutes) without a separate washing process. (S223).

Such a process can be performed by minimizing the inspection step while minimizing the user's intervention within a short time (eg, 12 minutes) using an automated machine.

Figure 6 is a flow chart showing a specific embodiment of step 'S300' shown in Figure 1, Figure 8 is a graph showing the quantification of the target component (MMP 9) by Figure 1, (a) is considering the sample amount and (b) does not consider the amount of sample.

In addition, FIG. 9 is a standardized table of a plurality of specimens including tears and target components according to FIG. 1.

Referring to FIG. 6 , the step of determining the presence of dry eye (S300) may include a step of confirming the concentration of a target component (S310) and a step of diagnosing dry eye (S320).

The process of confirming the concentration of the target component (S310) is a process of confirming the concentration of the target component included in the unit tear amount by dividing the amount of the target component quantified through the confirmation of the fluorescent material by the quantified amount of tears. It is possible to quantify the amount of the target component compared to the amount of tears by applying a simple formula dividing the amount of the target component measured using the measured amount of tears.

The dry eye diagnosis process (S320) is a process of determining dry eye by comparing the confirmed target component concentration with a reference value for determining dry eye, and dry eye can be determined by comparing with a clinical cut-off value.

As a result, as shown in FIG. 8 (a) and FIG. 9, the result of normalization with a sample solution containing tears matches well with the result using ELISA compared to other data, helping clinical diagnosis. It can be confirmed that this result can be obtained.

7 is a flowchart illustrating another embodiment of FIG. 1 .

Referring to FIG. 7 , the method for diagnosing dry eye using the quantitative immunoassay of the present invention may further include a data management step (S400).

In the data management step (S400), the information analyzed and diagnosed by steps 'S100' to 'S300' can be used as a database in various fields.

Specifically, the database of related fields including at least one of the diagnosis of related diseases (eg, ophthalmological diseases or neurodegenerative diseases) and smart health care based technologies using the quantitative results of the previously identified and analyzed target components. It can be made into a database for use as a

In the above, the method for diagnosing dry eye using quantitative immunoassay according to the present invention has been described. It will be understood that the technical configuration of the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention by those skilled in the art to which the present invention belongs.

Therefore, the embodiments described above are illustrative in all respects and should be understood as non-limiting ones.

Claims (18)

Tear amount quantification step of measuring the amount of tears by collecting the tears of the test subject;
Target component quantification step of quantifying the target component contained in the collected tears; and
A method for diagnosing dry eye using quantitative immunoassay comprising: determining dry eye status based on the amount of collected tears and the amount of a target component.
According to claim 1,
The target component is
A method for diagnosing dry eye using a quantitative immunoassay comprising MMP 9 protein.
According to claim 1,
The step of quantifying the amount of tears,
A tear collection process of collecting tears using any one of Schirmer strip and SM tube (Strip Meniscometry tube);
An indirect calculation process of calculating the amount of tears by measuring the length permeated into the Schirmer test strip when the Schirmer test strip is collected; and
A method for diagnosing dry eye using quantitative immunoassay comprising a; direct confirmation process of confirming the amount of tears collected by the SM tube when collected by the SM tube.
According to claim 3,
The target component quantification step,
A sample solution preparation process of preparing a sample solution in which the target component contained in the collected tears is eluted as an elution solution using any one of Schirmer strip and SM tube (Strip Meniscometry tube); and
A method for diagnosing dry eye using quantitative immunoassay comprising a target component quantification step of analyzing and quantifying the target component contained in the sample solution.
According to claim 4,
The elution solution,
A method for diagnosing dry eye using quantitative immunoassay comprising a buffer-based solution capable of recognizing an epitope of a target component and containing an antibody to which a fluorescent substance is attached.
According to claim 5,
The elution solution,
A method for diagnosing dry eye using quantitative immunoassay, further comprising at least one of 'Stabilizer', 'Detergent' and 'Preservative' based on 'Buffer'.
According to claim 6,
The 'Buffer' is,
A method for diagnosing dry eye using a quantitative immunoassay comprising at least one of 'Tris-HCl', 'PBS', 'HEPES', 'MES', 'CAPSO', 'MOPS' and 'Borate buffer'.
According to claim 6,
The 'Stabilizer',
A method for diagnosing dry eye using quantitative immunoassay comprising at least one of 'Sucrose', 'BSA' and 'StabilGuard'.
According to claim 6,
The 'Detergent' is,
A method for diagnosing dry eye using quantitative immunoassay comprising at least one of 'Triton X-100', 'Tween 20', 'IGEPAL CA630', 'CHAPS', 'TTAB' and 'Anzergent'.
According to claim 6,
The 'Preservative' is,
A method for diagnosing dry eye using a quantitative immunoassay comprising at least one of 'NaN3' and 'ProClin'.
According to claim 5,
The elution solution,
'Phosphate buffer saline', 'Sodium phosphate buffer', 'MES (2-(N-morpholino)ethanesulfonic acid) buffer', 'MOPS (3-(N-morpholino)propanesulfonic acid) buffer', 'Tris buffer', ' A method for diagnosing dry eye using a quantitative immunoassay comprising at least one of solutions based on HEPES (4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid' and 'Borate buffer'.
According to claim 11,
The elution solution,
A method for diagnosing dry eye using quantitative immunoassay, further comprising at least one of 'Preservative' and 'Stabilizer'.
According to claim 12,
The 'Preservative' is,
A method for diagnosing dry eye using quantitative immunoassay comprising at least one of 'NaN3' and 'ProClin 300'.
According to claim 12,
The 'Stabilizer',
Dry eye using quantitative immunoassay characterized by containing at least one of 'Bovine serum albumin (BSA)', 'Polysorbate 20 (Tween 20)', 'Triton x100', 'Sucrose', and 'BHT (Butylated hydroxytoluene)' diagnostic method.
According to claim 5,
The target component quantification process,
A method for diagnosing dry eye using quantitative immunoassay, characterized in that a target component is quantified using fluorescence immunologically-based lateral flow analysis.
According to claim 5,
The target component quantification process,
an antibody immobilization process of immobilizing the antibody to the bottom of the lateral flow membrane;
a target component binding step of binding the target component to the antibody by lateral flow of the sample solution through the membrane; and
A method for diagnosing dry eye using quantitative immunoassay comprising a; fluorescent material identification process of quantifying a target component by identifying a fluorescent material attached to the antibody.
According to claim 16,
The step of determining whether or not the dry skin is dry,
A target component concentration confirmation step of dividing the target component amount quantified through the confirmation of the fluorescent material by the quantified tear amount to confirm the concentration of the target component included in the unit tear amount; and
A method for diagnosing dry eye using quantitative immunoassay comprising: a dry eye diagnosis process of comparing the concentration of the confirmed target component with a reference value for determining dry eye to determine whether or not there is dry eye.
The method of any one of claims 1 to 17,
Quantitative immunoassay further comprising; a data management step of converting the quantitative results of the target component into a database to be used as a database of related fields including at least one of diagnosis of related diseases and basic technologies of smart health care. Method for diagnosing dry eye using

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