KR101756515B1 - cartridge and method for analytes detection using chemiluminescence - Google Patents

Abstract

An analyte detection cartridge using chemiluminescence and an analyte detection method using the same are disclosed. In one embodiment, the analyte detection cartridge may include a first storage chamber having one end open and a first liquid material accommodated therein, a first storage chamber connected to the first storage chamber and having one end and the other end open, A second reservoir chamber in which a first channel for connection is formed therein and in which a second liquid material is accommodated, a second reservoir chamber disposed between the one end of the first reservoir chamber and the other end of the second reservoir chamber, A first separation membrane for separating the second liquid material from each other, and a penetrating member moving along the first channel of the second storage chamber and passing through the first separation membrane. The first liquid material includes at least one selected from the group consisting of phenylglyoxal, phenylglyoxal derivative, and combinations thereof. The second liquid material includes guanine. The second liquid material is introduced into the first storage chamber through the first separator penetrated by the penetrating material and mixed with the first liquid material, and the mixed guanine and the first liquid material react with each other Generate light.
In another embodiment, an analyte detection cartridge utilizing chemiluminescence is disclosed. The analyte detection cartridge includes a first storage chamber having one end opened and a first liquid material accommodated therein, a second channel connected to the first storage chamber and having one end and the other end opened and connecting the one end and the other end opened, A third reservoir chamber formed inside the first reservoir chamber and accommodating a third liquid material therein; a second reservoir chamber disposed between the one end of the first reservoir chamber and the other end of the third reservoir chamber for separating the first liquid material and the third liquid material from each other A second storage chamber connected to the third storage chamber and having a first channel formed therein and having one end and the other end opened and connected to the one end and the other end opened, A third separation membrane disposed between the other end of the second storage chamber and the one end of the third storage chamber for separating the third liquid material and the second liquid material from each other, And a penetrating member penetrating the third separating membrane and moving along the second channel to penetrate the second separating membrane. The first liquid material includes at least one selected from phenylglyoxal, phenylglyoxal derivative, and combinations thereof. The second liquid material includes guanine. The third liquid material may be at least one selected from tetra-n-methyl ammonium phosphate, tetra-n-ethyl ammonium phosphate, tetra-n-propyl ammonium phosphate (TPA) . The second liquid material is introduced into the third storage chamber via the third separation membrane penetrated by the penetration and mixed with the third liquid material, and the mixed second liquid material and the third liquid material Is introduced into the first storage chamber via the second separator by the penetrating member and mixed with the first liquid material. The mixed guanine and the first liquid material react with each other to generate light, and the third liquid material changes a reaction rate or a reaction pattern of the guanine and the first liquid material.
In yet another embodiment, a method for detecting an analyte using chemiluminescence is disclosed. The method for detecting an analyte includes the steps of preparing a first liquid material containing at least one selected from phenylglyoxal, phenylglyoxal derivative and a combination thereof; preparing a second liquid material containing guanine; 1 separating the first liquid material and the second liquid material from each other using a separator, passing the first liquid material through the first separator using a penetrating material, and mixing the first liquid material and the second liquid material with each other 1 mixing process and measuring light generated in the first mixing process through a luminescence measuring device. The light is generated when the guanine reacts with the first liquid material.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cartridge for detecting an analyte using chemiluminescence,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention generally relates to an analyte detection cartridge and an analyte detection method, and more particularly, to an analyte detection cartridge using chemiluminescence and an analyte detection method using the same.

This research was supported by the Ministry of Commerce, Industry and Energy, the Ministry of Commerce, Industry and Energy, and the project for cooperation with the Ministry of Commerce, Industry and Energy (2013, development and commercialization of arrhythmia diagnosis / treatment equipment, Project No. R0002625).

Recently, there is an increasing demand for on-site diagnostics to directly measure the concentrations of the components to be detected at the site of use and to immediately reflect the results. Particularly, specific needs for diagnostic cartridges and biochips capable of quickly and easily diagnosing and analyzing human diseases are increasing in our everyday and medical fields.

Accordingly, development of a biochip or a diagnostic cartridge for quickly and easily diagnosing and analyzing a biological sample is being actively carried out. The biochip can be divided into two types. First, a method of injecting only a biological sample and a method of sequentially injecting various reaction solutions are used. However, it has a disadvantage that it is difficult to apply it to the necessary diagnostic analysis of a complex chemical reaction. The sequential introduction of various reaction solutions has the advantage that it is possible to use various kinds of analysis because complex chemical reactions are possible, but there is a disadvantage that an additional device for storing and supplying the reaction solution is needed. Therefore, it is required to develop a biochip or a diagnostic cartridge which can be used for various kinds of analysis and requires a minimum additional device for storing and supplying the reaction solution.

The analyte detection cartridge and the analyte detection method using the chemiluminescence disclosed in the present specification provide reagents necessary for sample analysis in advance in the cartridge. Therefore, since the user only needs to inject the sample to be diagnosed, the analyte detection cartridge disclosed in this specification can provide the user with an analyte detection method suitable for on-site diagnosis. Related prior arts are Korean Patent Laid-Open Nos. 10-2013-0080784 and 10-2009-0108428.

In one embodiment, an analyte detection cartridge using chemiluminescence is disclosed. The analyte detection cartridge includes a first storage chamber having one end open and a first liquid material accommodated therein, a first channel connected to the first storage chamber and having one end and the other end opened and connecting the one end and the other end opened, A second reservoir chamber formed in the first reservoir chamber and accommodated in the second reservoir chamber, the second reservoir chamber being formed inside the first reservoir chamber and receiving the second liquid material, And a penetrating member moving along the first channel of the second storage chamber and passing through the first separating membrane. The first liquid material includes at least one selected from the group consisting of phenylglyoxal, phenylglyoxal derivative, and combinations thereof. The second liquid material includes guanine. The second liquid material is introduced into the first storage chamber via the first separator penetrated by the penetration and mixed with the first liquid material,

The mixed guanine and the first liquid material react with each other to generate light.

In another embodiment, an analyte detection cartridge utilizing chemiluminescence is disclosed. The analyte detection cartridge includes a first storage chamber having one end opened and a first liquid material accommodated therein, a second channel connected to the first storage chamber and having one end and the other end opened and connecting the one end and the other end opened, A third reservoir chamber formed inside the first reservoir chamber and accommodating a third liquid material therein; a second reservoir chamber disposed between the one end of the first reservoir chamber and the other end of the third reservoir chamber for separating the first liquid material and the third liquid material from each other A second storage chamber connected to the third storage chamber and having a first channel formed therein and having one end and the other end opened and connected to the one end and the other end opened, A third separation membrane disposed between the other end of the second storage chamber and the one end of the third storage chamber for separating the third liquid material and the second liquid material from each other, And a penetrating member penetrating the third separating membrane and moving along the second channel to penetrate the second separating membrane. The first liquid material includes at least one selected from phenylglyoxal, phenylglyoxal derivative, and combinations thereof. The second liquid material includes guanine. The third liquid material may be at least one selected from tetra-n-methyl ammonium phosphate, tetra-n-ethyl ammonium phosphate, tetra-n-propyl ammonium phosphate (TPA) . The second liquid material is introduced into the third storage chamber via the third separation membrane penetrated by the penetration and mixed with the third liquid material, and the mixed second liquid material and the third liquid material Is introduced into the first storage chamber via the second separator by the penetrating member and mixed with the first liquid material. The mixed guanine and the first liquid material react with each other to generate light, and the third liquid material changes a reaction rate or a reaction pattern of the guanine and the first liquid material.

In yet another embodiment, a method for detecting an analyte using chemiluminescence is disclosed. The method for detecting an analyte includes the steps of preparing a first liquid material containing at least one selected from phenylglyoxal, phenylglyoxal derivative and a combination thereof; preparing a second liquid material containing guanine; 1 separating the first liquid material and the second liquid material from each other using a separator, passing the first liquid material through the first separator using a penetrating material, and mixing the first liquid material and the second liquid material with each other 1 mixing process and measuring light generated in the first mixing process through a luminescence measuring device. The light is generated when the guanine reacts with the first liquid material.

The foregoing provides only a selective concept in a simplified form as to what is described in more detail hereinafter. The present disclosure is not intended to limit the scope of the claims or limit the scope of essential features or essential features of the claims.

1 is a view for explaining an analyte detection cartridge using chemiluminescence disclosed in this specification according to an embodiment.
2 is a view for explaining an analyte detection cartridge using chemiluminescence disclosed in this specification according to another embodiment.
FIGS. 3 to 7 are views for explaining the components and the coupling process of the analyte detection cartridge using the chemiluminescence disclosed in this specification according to another embodiment. FIG.
8 is a flow chart illustrating an analyte detection method using chemiluminescence disclosed herein in accordance with one embodiment.

Hereinafter, embodiments disclosed in this specification will be described in detail with reference to the drawings. Like reference numerals in the drawings denote like elements, unless the context clearly indicates otherwise. The exemplary embodiments described above in the detailed description, the drawings, and the claims are not intended to be limiting, and other embodiments may be utilized, and other variations are possible without departing from the spirit or scope of the disclosed technology. Those skilled in the art will appreciate that the components of the present disclosure, that is, the components generally described herein and illustrated in the figures, may be arranged, arranged, combined, or arranged in a variety of different configurations, all of which are expressly contemplated, As shown in FIG. In the drawings, the width, length, thickness or shape of an element, etc. may be exaggerated in order to clearly illustrate the various layers (or films), regions and shapes.

When a component is referred to as being " deployed "to another component, it may include the case where the component is directly disposed on the other component, as well as the case where additional components are interposed therebetween.

The description of the disclosed technique is merely an example for structural or functional explanation and the scope of the disclosed technology should not be construed as being limited by the embodiments described in the text. That is, the embodiments are to be construed as being variously embodied and having various forms, so that the scope of the rights of the disclosed technology should be understood to include equivalents capable of realizing the technical ideas.

When an element is referred to as being "connected" to another element, it may be directly connected to the other element, but it should be understood that other elements may be present in between. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions that describe the relationship between components, such as " between " and " between "

It is to be understood that the singular " include " or " have " are to be construed as including the stated feature, number, step, operation, It is to be understood that the combination is intended to specify that it is present and not to preclude the presence or addition of one or more other features, numbers, steps, operations, components, parts or combinations thereof.

In each process, the identification codes (e.g., 310, 320, 330, ...) are used for convenience of explanation, and the identification codes do not describe the order of each step, Unless the specific order is described, it may occur differently from the order specified. That is, steps may occur in the same order as described, may be performed substantially concurrently, or may be performed in reverse order.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the disclosed technology belongs, unless otherwise defined. Terms defined in commonly used dictionaries should be interpreted to be consistent with meaning in the context of the relevant art and can not be construed as having ideal or overly formal meaning unless expressly defined in the present application.

1 is a view for explaining an analyte detection cartridge using chemiluminescence disclosed in this specification according to an embodiment. Referring to FIG. 1, the analyte detection cartridge 100 includes a first storage chamber 110, a second storage chamber 120, a first separation membrane 130, and a penetration member 140. In some other embodiments, the analyte detection cartridge 100 may further optionally include an elastomer 150. In some other embodiments, the analyte detection cartridge 100 may optionally further include a support 160. In some embodiments, In some other embodiments, the analyte detection cartridge 100 may optionally further comprise a sensor 170. [

The first storage chamber 110 is opened at one end, and the first liquid material 10 is accommodated. The first liquid material 10 comprises at least one selected from the group consisting of phenylglyoxal, phenylglyoxal derivative, and combinations thereof. For example, as the phenylglyoxal derivative, acetyl, oxy, methoxy, C1-C6 linear alkyl or C1-C6 branched alkyl may be bonded to a phenyl ring as a substituent. As another example, the phenylglyoxal derivative may be at least one selected from the group consisting of phenylglyoxal, 3-methoxyphenylglyoxal, 4-methoxyphenylglyoxal, 3,4-dimethoxyphenylglyoxal, 3,5-dimethoxyphenylglyoxal, 3,4,5-trimethoxyphenylglyoxal Either one may be used. The first storage chamber 110 serves as a place where mixing of the first liquid material 10 and the second liquid material 20 occurs. The first liquid material 10 may be supplied and stored in the first storage chamber 110 in a predetermined amount predetermined according to the type, method, or the like of the diagnostic analysis target. The analyte detection cartridge 100 disclosed herein diagnoses and analyzes an analyte using chemiluminescence. To this end, at least a portion of the first storage chamber 110 may be made of a light-transmitting material.

The second storage chamber 120 is connected to the first storage chamber 110 and has one end and the other end opened and a first channel connecting the one end and the other end opened, 20 are accommodated. On the other hand, if necessary, the second liquid material 20 may be previously contained in the analyte. The second liquid material 20 comprises guanine. In one example, the second liquid material 20 may be a DNA or RNA sequence comprising guanine. The second liquid material 20 may include an analyte. In this case, the DNA or RNA sequence containing the guanine may be an aptamer capable of binding with the analyte. Aptamers are the ligands of interest, ie, oligonucleotides designed to bind to an analyte. The analyte may be a protein, a microorganism, a virus, an organic substance, an inorganic substance, a chemical substance, or the like. The analyte detection cartridge disclosed herein is capable of selecting and analyzing a desired target among those exemplified as the analyte. In this case, you can select the appropriate app tamer to combine with the selected analyte. The second reservoir chamber 120 may be configured such that the second liquid material 20 is supplied to the first reservoir chamber 110 during the mixing of the second liquid material 20 and the first liquid material 10 through the through- The other end of the second storage chamber 120 may have a shape that the width of the other end of the second storage chamber 120 becomes narrower toward the first storage chamber 110.

The first separator 130 is disposed between the one end of the first reservoir chamber 110 and the other end of the second reservoir chamber 120 so that the first liquid material 10 and the second liquid material 20 Separate. The first liquid material 10 provided in the first storage chamber 110 in a predetermined amount for diagnosis can be safely isolated or separated from the outside. In other words, the user of the analyte detection cartridge disclosed herein may mix the first liquid material 10 and the second liquid material 20 through removal or destruction of the first separation membrane 130 at the time of diagnosis . The first liquid material 10 and the second liquid material 20 generate light in the mixing process. The light is generated during the reaction of guanine with phenylglyoxal or guanine with phenylglyoxal derivative. The sensor 170 may diagnose and analyze the analyte by measuring the light. In one embodiment, the first storage chamber 110 and the second storage chamber 120 may be connected to each other in a threaded manner. At this time, the other end of the second storage chamber 120 is in close contact with the first separation membrane 130 while being in close contact with the one end of the first storage chamber 110, So that the first storage chamber 110 can be hermetically accommodated.

The penetrator 140 moves along the first channel of the second storage chamber 120 and penetrates the first separator 130. In this process, the second liquid material 20 flows into the first storage chamber 110 via the first separation membrane 130 penetrated by the penetration body 140 and is mixed with the first liquid material 10 . For example, the penetrating member 140 may have a shape narrowing in width along the direction of movement along the first channel. In particular, the end of the penetrating member 140 may have a pointed shape, and the first separating film 130 can be effectively penetrated therethrough.

The elastic body 150 may be disposed on the outer peripheral surface of the penetrating member 140. The elastic body 150 moves along the first channel while closely contacting the inner surface of the first channel in the process of moving the penetrator 140 along the first channel so that the second liquid material 20 is separated from the first separator The first reservoir chamber 110 and the second reservoir chamber 110, respectively. It may be considered that it plays a substantially same role as that provided by the rubber of the elastic material disposed at the end of the piston of the generally used syringe. Accordingly, the second liquid material 20 accommodated in the second reservoir chamber 120 can be stably supplied to the first reservoir chamber 110. 5 shows an example of an elastic body 150 disposed on the outer circumferential surface of the penetrating member 140. [

The first storage chamber 110 and the second storage chamber 120 may be coupled to the support portion 160. That is, the first storage chamber 110 and the second storage chamber 120 may be connected to each other via the support portion 160. In other words, the support portion 160 includes the through-hole 162, and the one end of the first storage chamber 110 and the other end of the second storage chamber 120 are opposed to each other with the through- Lt; / RTI > In this case, the first separator 130 may be disposed on one side of the support 160 where the through-holes 162 are formed to separate the first liquid material 10 and the second liquid material 20 from each other. In addition, the support portion 160 may include a ventilation hole 164, as shown in Fig. The ventilation hole 164 is formed in such a manner that the penetration body 140 in which the elastic body 150 is disposed moves along the first channel of the second storage chamber 120 and passes through the first separation membrane 130, It is possible to perform the function of the discharge passage of the pressure to be provided. That is, when the pressure is provided from the penetration body 140 in which the elastic body 150 is disposed in the first storage chamber 110 which is opened only once, a large amount of force is required by the repulsive force. By forming the vent hole (164) in the support base (160), the pressure can be effectively provided even with a small force. The sensor 170 can detect and analyze the second liquid material 20 by sensing light generated in the mixing process of the first liquid material 10 and the second liquid material 20. In this case, in order to accurately measure the light isolated from the outside, the support may be made of a light-diffusing material.

The sensor 170 may be disposed on the support 160 so as to face the first storage chamber 110. As an example, the sensor 170 may be disposed in the sensor seating portion 170a represented in the analyte detection cartridge 200 shown in Fig. 3 (a). The first liquid material 10 and the second liquid material 20 generate light in the mixing process. The sensor 170 may sense this. A signal sensed by the sensor 170 can be compared with a preset reference value stored in a storage device (not shown) such as a memory. Whereby the analyte can be diagnosed. In other words, the guanine contained in the second liquid material 20 reacts with the phenylglyoxal or phenylglyoxal derivative contained in the first liquid material 10 to generate light. Depending on the amount of guanine and phenylglyoxal or guanine and phenylglyoxal derivative used in the reaction, the intensity of the light, the pattern of the emitted light, and the lifetime of the light are different. Data including the intensity of light, the pattern of light, the lifetime of light, and the like measured in advance from the sensor 170 according to the type of the reaction object, the concentration of the reaction object at the time of reaction, the temperature and the like are stored in the storage device, Can be utilized. For example, the user of the analyte detection cartridge 100 disclosed in the present specification can collect an appropriate amount of human needles, blood, secretions, etc. containing the analyte, and then measure the amount of the liquid substance including guanine And the second liquid material 20 can be prepared by mixing. In this case, guanine is assumed to be guanine contained in a DNA or RNA sequence capable of binding to the analyte. That is, guanine is assumed to be guanine contained in aptamer. The prepared second liquid material 20 can then be mixed with the first liquid material 10 using the penetrator 140. In this case, light is generated by the reaction of the first liquid material 10 and the second liquid material 20. When the analyte is included in the second liquid material 20, the analyte is associated with at least a portion of the aptamer. At least a portion of the guanine in the aptamer combined with the analyte may not react with or react with the first liquid material 10, but may generate light of weak intensity in the course of the reaction. Accordingly, the analyte is diagnosed by comparing the reference value measured in the absence of the analyte and the stored reference value with the intensity of the light measured in the state including the analyte, the pattern of the emitted light, and the lifetime of the light .

On the other hand, the user of the analyte detection cartridge 100 disclosed herein may prepare a second liquid material 20 by mixing an appropriate amount of the prepared catalyst material therewith. The catalyst may be at least one selected from tetra-n-methyl ammonium phosphate, tetra-n-ethyl ammonium phosphate, tetra-n-propyl ammonium phosphate (TPA) . The catalyst functions to change the reaction rate or the reaction pattern of the at least one selected from the group consisting of guanine and the first liquid material (10), that is, guanine, phenylglyoxal, phenylglyoxal derivative, and combinations thereof can do.

In addition, the user of the analyte detection cartridge 100 disclosed herein may bind a fluorescent label to the DNA or RNA array. By a chemiluminescent resonance energy transfer (CRET) generated between the energy intermediate generated in the course of the reaction between guanine and phenylglyoxal or a guanine and a phenylglyoxal derivative and the fluorescent label bound to the DNA or RNA sequence, The intensity of light generated during the reaction between the liquid material 10 and the second liquid material 20, the pattern of the emitted light, and the lifetime of the light can be changed. It is possible to adjust the intensity of the light, the pattern of the emitted light, the lifetime of the light, etc., which are generated through the selection of the fluorescent markers. These fluorescent labels include, for example, pacific blue, fluorescein, 6-FAM, Cy3, Cy3.5, Cy5, Cy5.5, HEX, TET, VIC, NED, JOE, ROX, Texas Red, Phodamine Green, Rhodamine Red, And a combination of these may be used.

Accordingly, the analyte detection cartridge 100 disclosed in this specification can measure the light intensity, the light pattern, the light lifetime, etc., which are generated differently depending on the presence or absence of the analyte, can do.

2 is a view for explaining an analyte detection cartridge using chemiluminescence disclosed in this specification according to another embodiment. FIGS. 3 to 7 are views for explaining the components and the combining process of the analyte detection cartridge disclosed in this specification according to another embodiment.

2 through 7, the analyte detection cartridge 200 includes a first storage chamber 210, a second storage chamber 220, a third storage chamber 230, a second separation membrane 240, A separator 250 and a penetrator 140. In some other embodiments, the analyte detection cartridge 200 may further optionally include an elastomer 150. In some other embodiments, the analyte detection cartridge 200 may optionally further include a support 160. In some other embodiments, the analyte detection cartridge 200 may optionally further comprise a sensor 170. In some embodiments,

The first storage chamber 210 is opened at one end, and the first liquid material 10 is accommodated. The first liquid material 10 comprises at least one selected from the group consisting of phenylglyoxal, phenylglyoxal derivative, and combinations thereof. The first storage chamber 210 may be formed on the support 160 as shown in FIGS. 3 and 4 by way of example. The first storage chamber 210 serves as a place where mixing of the first liquid material 10, the second liquid material 20, and the third liquid material 30 occurs. The first liquid material 10 may be supplied and accommodated in the first storage chamber 210 in a predetermined amount predetermined according to the type, method, or the like of the diagnostic analysis target. The analyte detection cartridge 100 disclosed herein diagnoses and analyzes an analyte using chemiluminescence. To this end, at least a portion of the first storage chamber 110 may be made of a light-transmitting material.

The second liquid material 20 comprises guanine. In one example, the second liquid material 20 may be a DNA or RNA sequence comprising guanine. The second liquid material 20 may include an analyte. In this case, the DNA or RNA sequence containing the guanine may be an aptamer capable of binding with the analyte. Aptamers are the ligands of interest, ie, oligonucleotides designed to bind to an analyte. The analyte may be a protein, a microorganism, a virus, an organic substance, an inorganic substance, a chemical substance, or the like. The analyte detection cartridge disclosed herein is capable of selecting and analyzing a desired target among those exemplified as the analyte. In this case, you can select the appropriate app tamer to combine with the selected analyte. On the other hand, if necessary, the second liquid material 20 may be previously contained in the analyte.

The third liquid material 30 may include a reaction promoter such as a catalyst. The reaction promoter may perform a function of promoting the reaction of the first liquid material 10 and the second liquid material 20. The reaction mediator may act as a mediator when a direct reaction between the first liquid material 10 and the second liquid material 20 is difficult in the course of producing the liquid mixture material. That is, the second liquid material 20 may first function to bind the reaction mediator and to help the reaction mediator associated with the second liquid material 20 react with the first liquid material 10 have. The catalyst may be at least one selected from, for example, tetra-n-methyl ammonium phosphate, tetra-n-ethyl ammonium phosphate, tetra-n-propyl ammonium phosphate (TPA) have. The catalyst functions to change the reaction rate or the reaction pattern of the at least one selected from the group consisting of guanine and the first liquid material (10), that is, guanine, phenylglyoxal, phenylglyoxal derivative, and combinations thereof can do.

The first liquid material 10 and the second liquid material 20 generate light in the mixing process. The light is generated during the reaction of guanine with phenylglyoxal or guanine with phenylglyoxal derivative. The sensor 170 may diagnose and analyze the analyte by measuring the light. The sensor 170 disposed adjacent to the first storage chamber 210 can sense this. A signal sensed by the sensor 170 can be compared with a preset reference value stored in a storage device (not shown) such as a memory. Whereby the analyte detection cartridge disclosed herein can diagnose and analyze the second liquid material 20. For example, the sensor 170 senses the light generated in the mixing process of the first liquid material 10, the second liquid material 20, and the third liquid material 30 to diagnose the second liquid material 20 . In this case, the first storage chamber 210 may be made of a light-transmitting material.

The third storage chamber 230 is connected to the first storage chamber 210 and has one end and the other end opened. A second channel connecting the one end and the other end is formed in the third storage chamber 230. 30 are accommodated. On the other hand, the third reservoir chamber 230 may include a second liquid material 20, a third liquid material 30, and a second liquid material 30 through the penetrator 140, as shown by way of example in FIG. 4 (b) In order to allow the mixed second liquid material 20 and the third liquid material 30 to be easily injected into the first storage chamber 210 in the mixing process of the material 10, The first reservoir chamber 210 and the second reservoir chamber 210 may have different shapes.

The second separation membrane 240 is disposed between the one end of the first reservoir chamber 210 and the other end of the third reservoir chamber 230 so that the first liquid material 10 and the third liquid material 30 Separate. The first liquid material 10 provided in advance in the first storage chamber 210 for diagnosis can be safely isolated or separated from the outside. In other words, the user of the analyte detection cartridge disclosed herein is able to detect the presence or absence of the first liquid material 10 and the second liquid material 20 mixed with the first liquid material 10 and the second liquid material 20 through removal or destruction of the second separation membrane 240 The third liquid material 30 may be mixed to produce a liquid mixture. The second liquid material 20 can be diagnosed and analyzed by measuring the light generated in this process.

In one embodiment, the first reservoir chamber 210 and the third reservoir chamber 230 may be connected to each other in a threaded manner. At this time, the other end of the third storage chamber 230 may be in close contact with the second separation membrane 240 while being in close contact with the one end of the first storage chamber 210 to connect the first liquid material 10, So that the first storage chamber 210 can be hermetically accommodated.

The second storage chamber 220 is connected to the third storage chamber 230 and has one end and the other end opened. A first channel connecting the one end and the other end opened is formed in the second storage chamber 220, 20 are accommodated. For example, the second storage chamber 220 may be connected to the third storage chamber 230 as shown in FIG. In this process, the second storage chamber 220 may be connected to the third storage chamber 230 by a screw connection method.

The third separation membrane 250 is disposed between the other end of the second storage chamber 220 and the one end of the third storage chamber 230 and the third liquid material 30 and the second liquid material 20 are connected to each other Separate. The third liquid material 30 provided in advance in the third storage chamber 230 for diagnosis can be safely isolated or separated from the outside. In other words, the user of the analyte detection cartridge disclosed herein is capable of mixing the first liquid material 10 and the second liquid material 20 through removal or destruction of the third separation membrane 250 at the time of diagnosis, The third liquid material 30 may be mixed to produce a liquid mixture. The second liquid material 20 can be diagnosed and analyzed by measuring the light generated in this process.

In an embodiment, the second storage chamber 220 and the third storage chamber 230 may be connected to each other in a screw-coupled manner. At this time, the other end of the second storage chamber 220 is in close contact with the third separation membrane 250 while being in close contact with the one end of the third storage chamber 230 to be connected to the third liquid material 30, So that the third storage chamber 230 can be hermetically accommodated.

The penetrator 140 moves along the first channel of the second storage chamber 220 to pass through the third separation membrane 250 and to move along the second channel to penetrate the second separation membrane 240. The second liquid material 20 flows into the third storage chamber 230 via the third separation membrane 250 penetrated by the penetration body 140 and is mixed with the third liquid material 30, The mixed second liquid material 20 and the third liquid material 30 flow into the first storage chamber 210 via the second separation membrane 240 penetrated by the penetration body 140, (10), whereby the liquid mixture can be produced. For example, the penetrating member 140 may have a shape narrowing in width along the direction of movement along the first channel. In particular, the end of the penetrating member 140 may have a pointed shape, and the third separating film 250 and the second separating film 240 can be effectively penetrated therethrough. In FIG. 7 (a), the penetrating member 140 passing through the second storage chamber 220 is shown as an example. In FIG. 7 (b), the penetrating member 140 passing through the second storage chamber 220 and the third storage chamber 230 is shown as an example.

The first storage chamber 210 and the third storage chamber 230 may be coupled to the support portion 160. That is, the first storage chamber 210 and the third storage chamber 230 may be connected to each other via the support portion 160. In other words, the support portion 160 includes the through-hole 162, and the one end of the first reservoir chamber 210 and the other end of the third reservoir chamber 230 are opposed to each other with the through- Lt; / RTI > In this case, the second separation membrane 240 may be disposed on one side of the supporter 160 having the through-hole 162 to separate the first liquid material 10 and the third liquid material 30 from each other. In addition, the support portion 160 may include a ventilation hole 164, as shown in Fig. The ventilation hole 164 is formed in such a manner that the penetration body 140 in which the elastic body 150 is disposed moves along the second channel of the third storage chamber 230 and passes through the second separation membrane 240, It is possible to perform the function of the discharge passage of the pressure to be provided. That is, when the pressure is supplied from the penetration body 140 in which the elastic body 150 is disposed in the first storage chamber 210 which is opened only once, much force is required by the repulsive force. By forming the vent hole (164) in the support base (160), the pressure can be effectively provided even with a small force. For example, the sensor 170 senses the light generated in the mixing process of the first liquid material 10, the second liquid material 20, and the third liquid material 30 to diagnose the second liquid material 20 . In this case, the first storage chamber 210 may be made of a light-transmitting material. In addition, the support portion 160 may be formed with a guide portion 166 as shown in FIG. When the analyte detection cartridge 200 disclosed in the present specification contains a large number of second liquid substances 20 to be analyzed, it may be analyzed by a diagnostic machine. In this case, the analytical detection cartridge 200 disclosed in this specification according to the guidance of the guide portion 166 can be easily mounted on the diagnostic machine. In the figure, a guide portion 166 formed as a groove on the side surface of the support portion 160 is illustrated as an example. The shape of the guide portion 166 is not limited as long as the analyte detection cartridge 200 can be easily mounted on the diagnostic machine.

The sensor 170 may be disposed on the support 160 so as to face the first storage chamber 210. Depending on the types of the first liquid material 10, the second liquid material 20 and the third liquid material 30, light may be generated during the mixing of the liquid mixture material. The sensor 170 may sense this. A signal sensed by the sensor 170 can be compared with a preset reference value stored in a storage device (not shown) such as a memory. Whereby the analyte detection cartridge disclosed herein can diagnose and analyze the second liquid material 20. For example, the sensor 170 senses the light generated in the mixing process of the first liquid material 10, the second liquid material 20, and the third liquid material 30 to diagnose the second liquid material 20 . In this case, the supporting portion 160 can be made of a light-blocking material.

8 is a flow chart illustrating an analyte detection method using chemiluminescence disclosed herein in accordance with one embodiment. Referring to FIG. 8, the method 300 for detecting an analyte using chemiluminescence first comprises preparing a first liquid material containing at least one selected from phenylglyoxal, phenylglyoxal derivative, and combinations thereof (310 ). For example, the phenylglyoxal derivative includes those wherein acetyl, oxy, methoxy, C1-C6 linear alkyl or C1-C6 branched alkyl is bonded to the phenyl ring as a substituent. In another embodiment, the phenylglyoxal derivative is at least one selected from the group consisting of phenylglyoxal, 3-methoxyphenylglyoxal, 4-methoxyphenylglyoxal, 3,4-dimethoxyphenylglyoxal, 3,5-dimethoxyphenylglyoxal, 3,4,5-trimethoxyphenylglyoxal And may include any one of them.

Next, a second liquid material containing guanine is prepared (320). In one example, the second liquid material may comprise a DNA or RNA sequence comprising the guanine. In this case, the second liquid material comprises an analyte, and the DNA or RNA sequence can bind to the analyte. At this time, the intensity of the light generated in the reaction between the first liquid material and the second liquid material may be reduced according to the binding of the analyte and the DNA or RNA array. And the sensor senses it and diagnoses and analyzes the analyte. On the other hand, the DNA or RNA sequence may be combined with a fluorescent label. The fluorescent labels include pacific blue, fluorescein, 6-FAM, Cy3, Cy3.5, Cy5, Cy5.5, HEX, TET, VIC, NED, JOE, ROX, Texas Red, Phodamine Green, Rhodamine Red, , And a combination thereof. The function of the fluorescent labeling has been described above, and a detailed description thereof will be omitted for convenience of explanation.

Next, the first liquid material and the second liquid material are separated from each other using the first separation membrane (330). Next, a first mixing process of mixing the first liquid material and the second liquid material through the first separation membrane using a penetrator is performed (340). Next, a process of measuring light generated in the first mixing process is performed through a light emission measuring device (350). The light measured through the luminescence meter is generated during the reaction of the guanine with the first liquid material. The measured light is compared with a reference value as described above with reference to FIGS. 1 to 7 to diagnose the analyte.

In some other embodiments, the method 300 for detecting analytes using chemiluminescence is optionally performed prior to the first mixing step 340 and is performed prior to the first mixing step, The method may further include a step of preparing a third liquid material and a second mixing step of mixing the second liquid material and the third liquid material. The catalyst may include at least one selected from tetra-n-methyl ammonium phosphate, tetra-n-ethyl ammonium phosphate, tetra-n-propyl ammonium phosphate (TPA) . The catalyst may change the reaction rate or the reaction pattern of the first liquid material and the second liquid material. In one embodiment, the second mixing process includes separating the second liquid material and the third liquid material from each other using a second separation membrane, and separating the second liquid material and the third liquid material through the second separation membrane, And a second mixing process of mixing the two liquid materials and the third liquid material with each other. Through this, it is possible to sequentially react liquid substances, which are important in the order of the reaction among the liquid substances used for chemiluminescence, in accordance with the order of the reactions. A detailed description thereof has been given above, and will be omitted for the sake of simplicity.

The analyte detection cartridge 100, 200 disclosed in this specification can be used for various kinds of analysis as described above with reference to the drawings, and a diagnostic cartridge 100, 200, which requires a minimum additional device for storing and supplying the reaction liquid, . The analyte detection cartridge disclosed in this specification can provide a predetermined amount of the liquid material necessary for analysis in advance at least once. Further, the liquid material can be provided in a state separated from the outside. Accordingly, the analyte detection cartridges 100 and 200 disclosed in the present specification can be utilized not only in simple diagnostic analysis for inputting only a biological sample but also for diagnostic analysis requiring a reaction sequence and a complicated chemical reaction. In this specification, an analyte detection cartridge having two storage chambers and three storage chambers in association with the analyte detection cartridge is described as an example. The number of storage chambers can be increased depending on the type of the detection sample. In FIGS. 2 to 7, three storage chambers are exemplified. For example, an additional fourth storage chamber may be further introduced between the second storage chamber 220 and the third storage chamber 230. In this case, the liquid storage material containing guanine may be disposed in the fourth storage chamber, and the analyte may be disposed in the second storage chamber. Thereby allowing the chemiluminescence process to be sequentially performed through the analyte detection cartridge. The details of the introduction of additional chambers can be sufficiently deduced from the contents disclosed in the present specification, and will be omitted for convenience of explanation. It is clearly not intended to limit the scope of rights of the analyte detection cartridge disclosed in this description of this description.

From the foregoing it will be appreciated that various embodiments of the present disclosure have been described for purposes of illustration and that there are many possible variations without departing from the scope and spirit of this disclosure. And that the various embodiments disclosed are not to be construed as limiting the scope of the disclosed subject matter, but true ideas and scope will be set forth in the following claims.

Claims (17)

delete An analyte detection cartridge using chemiluminescence,
The detection cartridge
A first storage chamber which is opened at one end and in which the first liquid material is accommodated;
A third reservoir chamber connected to the first reservoir chamber and having one end and the other end opened, a second channel formed therein for connecting the one end and the other end opened, and a third liquid material being accommodated therein;
A second separator disposed between the one end of the first reservoir chamber and the other end of the third reservoir chamber for separating the first liquid material and the third liquid material from each other;
A second reservoir chamber connected to the third reservoir chamber and having one end and the other end opened, a first channel formed therein for connecting the one end and the other end opened, and the second liquid material being accommodated therein;
A third separator disposed between the other end of the second reservoir chamber and the one end of the third reservoir chamber for separating the third liquid material and the second liquid material from each other; And
And a penetrating member that moves along the first channel to penetrate through the third separating membrane and to move along the second channel to pass through the second separating membrane,
Wherein the first liquid material comprises at least one selected from phenylglyoxal, phenylglyoxal derivatives, and combinations thereof,
Wherein the second liquid material comprises an analyte and guanine,
The third liquid material may be at least one selected from tetra-n-methyl ammonium phosphate, tetra-n-ethyl ammonium phosphate, tetra-n-propyl ammonium phosphate (TPA) / RTI >
The second liquid material is introduced into the third storage chamber via the third separation membrane penetrated by the penetration and mixed with the third liquid material,
The mixed second liquid material and the third liquid material are introduced into the first storage chamber via the second separation membrane by the penetrating material and mixed with the first liquid material,
The at least one selected from the group consisting of guanine, phenylglyoxal, phenylglyoxal derivative, and combinations thereof reacts to generate light, and the third liquid material comprises the guanine, phenylglyoxal, phenylglyoxal derivative, A reaction rate or a reaction pattern of the at least one selected from the combinations thereof,
The first reservoir chamber, the third reservoir chamber, the second reservoir chamber, and the third reservoir chamber are connected to each other in a threaded manner,
And the other end of the third storage chamber is closely contacted with the one end of the first storage chamber while being in close contact with the second separation membrane in the process of being connected in the screw coupling manner so that the first liquid material is confined in the first storage chamber And,
The other end of the second reservoir chamber is in close contact with the third separator while being in close contact with the one end of the third reservoir chamber in the process of being connected by the screw connection method so that the third liquid material is confined in the third reservoir chamber An analyte detection cartridge using chemiluminescence that is adapted to be received. 3. The method of claim 2,
And an elastic body disposed on an outer circumferential surface of the penetration member,
Wherein the elastic body moves along the first channel while closely contacting the inner surface of the first channel in the process of moving the penetrating body along the first channel so that the second liquid material passes through the third separator, A pressure chamber for supplying pressure to be mixed with the third liquid material,
Wherein the elastic body is moved along the second channel while being in intimate contact with the inner surface of the second channel in the process of moving the penetrating body along the second channel so that the second liquid material and the third liquid material, Wherein the first liquid storage material is supplied into the first storage chamber via the second separation membrane passed through the sieve to provide a pressure to be mixed with the first liquid material. An analyte detection cartridge using chemiluminescence,
The detection cartridge
A first storage chamber which is opened at one end and in which the first liquid material is accommodated;
A third reservoir chamber connected to the first reservoir chamber and having one end and the other end opened, a second channel formed therein for connecting the one end and the other end opened, and a third liquid material being accommodated therein;
A second separator disposed between the one end of the first reservoir chamber and the other end of the third reservoir chamber for separating the first liquid material and the third liquid material from each other;
A second reservoir chamber connected to the third reservoir chamber and having one end and the other end opened, a first channel formed therein for connecting the one end and the other end opened, and the second liquid material being accommodated therein;
A third separator disposed between the other end of the second reservoir chamber and the one end of the third reservoir chamber for separating the third liquid material and the second liquid material from each other;
A penetrating member moving along the first channel to penetrate the third separating membrane and moving along the second channel to penetrate the second separating membrane; And
And a support to which the first storage chamber and the third storage chamber are coupled,
Wherein the first liquid material comprises at least one selected from phenylglyoxal, phenylglyoxal derivatives, and combinations thereof,
Wherein the second liquid material comprises an analyte and guanine,
The third liquid material may be at least one selected from tetra-n-methyl ammonium phosphate, tetra-n-ethyl ammonium phosphate, tetra-n-propyl ammonium phosphate (TPA) / RTI >
The second liquid material is introduced into the third storage chamber via the third separation membrane penetrated by the penetration and mixed with the third liquid material,
The mixed second liquid material and the third liquid material are introduced into the first storage chamber via the second separation membrane by the penetrating material and mixed with the first liquid material,
The at least one selected from the group consisting of guanine, phenylglyoxal, phenylglyoxal derivative, and combinations thereof reacts to generate light, and the third liquid material comprises the guanine, phenylglyoxal, phenylglyoxal derivative, A reaction rate or a reaction pattern of the at least one selected from the combinations thereof,
Wherein the support portion includes a vent connecting the outside to the first reservoir chamber,
The vent hole functions as a discharge passage for the pressure provided by the penetration member,
Wherein the supporting portion includes a through hole, the second separating film is disposed on one surface of the supporting portion having the through hole,
Wherein the one end of the first storage chamber and the other end of the third storage chamber are disposed opposite to each other with the through-hole and the second separation membrane interposed therebetween,
Wherein the first storage chamber and the third storage chamber are coupled to the support so that the first liquid material is received in the first storage chamber in an airtight manner by the second separation membrane, And the third liquid material,
The second storage chamber and the third storage chamber are connected to each other by a screw coupling manner so that the one end of the third storage chamber is in close contact with the third separation membrane in the process of being connected by the screw connection method, And the third liquid material is held in an air-tight manner in the third storage chamber. delete 5. The method of claim 4,
Further comprising a sensor disposed in the support to oppose the first reservoir chamber,
The portion of the first storage chamber facing the sensor is made of a light-transmitting material,
Wherein the sensor uses chemiluminescence to receive light generated during the mixing of the first liquid material and the second liquid material. The method according to claim 2, 3, 4, or 6,
Wherein the penetrating body has a shape that narrows in width along a direction of movement along the first channel. delete delete delete delete delete delete delete delete delete delete

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