JP2002277478A - Liquid-liquid interface segment flow method and segment analysis method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a new technique for further integrating chemical reaction and substance migration, ion analysis, and the like in a micro channel for continuation by accurately controlling flow. SOLUTION: In two taminar flows for forming the interface between liquids in the micro channel (30) on a micro chip (10), at least one solution flow (40A) is composed of several solution segments (1), (2), (3), (4), and (5) having different compositions.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid-liquid interface segment flow method and a segment analysis method. More specifically, the invention of this application provides a liquid-liquid interface segment flow method as a new technology and a segment utilizing the same, which enables continuous analysis, selective extraction and separation of ions of each type on a microchip. The present invention relates to an analysis method and a segment flow system that enables these methods.

[0002]

2. Description of the Related Art It is worldwide to form a groove (microchannel) of about several hundred microns on a chip such as a glass plate or a silicon substrate and integrate chemical analysis and chemical reaction as a system. Attention has been focused on and vigorous studies are underway.

[0003] However, many attempts to integrate electrophoretic analysis on a chip have been made so far, and few attempts have been made to integrate general chemical reactions.

In such a situation, the inventors of the present application have focused on the size effect of a liquid-phase micro space such as a micro channel, and have made various chemical reactions possible in the micro channel. Have been considered. As a result, we have realized a liquid-liquid extraction method in a microchannel focusing on a large specific interface area and a short molecular diffusion distance, and confirmed that it is an extremely effective ion sensing means. By this method, for example, specifically, complex formation and solvent extraction of cobalt ions and the like, and integration of an ion pair detection system have been successful.

Therefore, the present inventors have further developed the results so far, and further integrated and continuous chemical reaction, mass transfer, ion analysis, and the like in the microchannel by controlling the flow at a higher level. It has been a challenge to realize new technical means that can be used.

[0006]

Means for Solving the Problems The present invention solves the above-mentioned problems. First, at least one of the two-layer flow forming a liquid-liquid interface in a microchannel on a microchip is provided. Is provided by a plurality of solution segments having different compositions.

Second, a liquid-liquid interface segment flow characterized by selectively extracting and separating components contained in the other solution stream into at least one of a plurality of solution segments having different compositions. Third, a method is provided.
Provided is a liquid-liquid interface segment flow method, wherein a selective liquid-liquid interface reaction is performed by at least one of a plurality of solution segments having different compositions and the other solution flow.

The invention of this application relates to the above method. Fourth, a liquid-liquid interface segment flow method characterized in that solution segments having different compositions contain different recognition substances. A liquid-liquid interface segment flow method characterized in that the solution segments having different compositions include those containing a recognition substance and those not containing the recognition substance. Is a liquid-liquid interface segment flow method characterized by containing different pigments. Seventh, solution segments having different compositions are composed of those containing pigments and those not containing them. A liquid-liquid interface segment flow method is provided.

Eighth, in the invention of this application, the two-layer flow constituting the liquid-liquid interface is formed as a horizontal parallel flow in a microchannel in a confluence area of one solution flow and the other solution flow. The liquid-liquid interface segment flow method according to any one of the above, wherein the two-layer flow constituting the liquid-liquid interface is a micro flow in a confluence area of one solution flow and the other solution flow. A liquid-liquid interface segment flow method characterized by being formed as a cross flow in a channel.

[0010] Further, a tenth aspect of the present invention is to detect a component contained in a solution segment for at least one of the liquid-liquid interface segment flows formed by any of the above methods. Eleventh, a segment analysis method characterized in that detection is performed in a non-contact manner.
A segment analysis method is provided, wherein different components contained in each of a plurality of solution segments are continuously detected for each solution segment.

A thirteenth aspect is a system for the above segment flow method, comprising at least a plurality of solution segments having different compositions together with a microchannel in which a two-layer flow liquid-liquid interface is formed. A segment flow system comprising one solution flow supply means and its supply channel and the other solution flow supply means and its supply channel.
4 provides a segment analysis system characterized in that the system is provided with a detection means.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION The invention of this application has the features as described above, and embodiments thereof will be described below.

FIG. 1 of the accompanying drawings explains the outline of the liquid-liquid interface segment flow method of the invention of this application. For example, the invention of this application is implemented in a microchip (10) as illustrated in FIG.

The microchip (1) illustrated in FIG.
No. 0) is made of a transparent cell substrate such as glass, silicon, plastic or the like, and the surface of the substrate is also covered with a transparent cover. The size of the chip has been reduced to a length and width of several centimeters.

On the surface of the substrate of the microchip (10), two minute liquid passages (20A) and (20B) are formed.
Is formed. The solutions introduced into the fine liquid passages (20A) and (20B) flow in the directions indicated by the arrows in the figure, and merge in the microchannel (30) to form a two-layer liquid-liquid interface. At this time, the solution flow (4
0A) and (40B) are incompatible or poorly compatible with each other. For example, one solution stream (40A) is composed of an organic solution, and the other solution stream (40B) is composed of an aqueous solution.

In such a two-layer flow forming a liquid-liquid interface, in the invention of this application, for example, a solution flow (40A) composed of an organic solution as one of the flows is converted into a solution segment (1) ( 2) (3) (4) (5)
As a continuous flow. As the composition, for example, segment (1): A ⁺ ionophore / solvent Segment (2): solvent only Segment (3): B ⁺ ionophore / solvent Segment (4): solvent only Segment (5): C ⁺ ionophore / solvent It can be configured as follows. Of course, it is needless to say that the present invention is not limited to the combination of the segments containing the specific ionophore and those not containing the specific ionophore. It may be configured as a combination of segments such as those containing an appropriate reactive active molecule, a dye or the like, and those not containing these.

The flow of the solution segment is supplied to the above-mentioned minute liquid passage (20A) from a micro syringe or the like as a supply means corresponding to each solution segment.
It can be formed by supplying each solution segment so as to be sequentially continuous. Various chemical reactions, extraction, analysis, and the like can be performed depending on what kind of solution segment constitutes the solution flow (40A).

For example, FIG. 2 shows that the specific ion species A ⁺ , B ⁺ , and C ⁺ are selected from the other solution stream (40B) by the configuration of the solution segment containing the specific ionophore as described above. An example is shown in which a segment of the solution flow (40A) is extracted and taken in, and its presence is continuously detected.

For the solution flow (40A) constituted by the solution segments, the other solution flow (40B)
As illustrated in FIGS. 1 and 2, a two-layer liquid-liquid interface may be formed in the microchannel (30) as a horizontal parallel flow, or, in the microchannel (30) in the confluence area, It may be formed as a downstream.
In the upstream and downstream, the flow velocity, flow rate, etc. may be adjusted so that the liquid-liquid interface is formed in a short time in consideration of the problem of specific gravity. It may be formed in a hierarchical structure, and the microchannels (30) in the confluence area may have a vertical cross flow.

For example, the liquid-liquid interface segment flow system as described above can be configured as an analysis system provided with various detection means. For example, as a suitable detection means, non-contact analysis by a thermal lens microscope realized by the inventors of the present application is enabled. Downstream of the confluent microchannel (30), for example, detecting each of a plurality of ionic species etc. contained in each solution segment of the solution stream (40A) associated with the extraction of the aqueous solution from the solution stream (40B) Becomes possible.

In the ion detection by a thermal lens microscope, it is effective to include, for example, a fat-soluble dye in the organic solution segment together with the ionophore. This is because, as shown in FIG. 3, the detection of ions for analysis can be performed with higher accuracy by the emission of protons from the dye molecules.

In fact, the discrimination of the thermal lens signal by the introduction of the dye solution is extremely remarkable. FIG. 4 shows the dye solution and 1-
FIG. 9 illustrates an example of a change in the intensity of a thermal lens signal when only butanol is alternately introduced as a segment. It is understood from this that the discrimination is high.

Of course, the inventors have already proposed the liquid-liquid interface segment flow method of the invention of this application, the analysis method using the same, and specific means for a system for realizing these methods. Various aspects may be employed. Also, the composition of the actual solution segment,
It goes without saying that the flow rate and flow rate in the microchannel, as well as the detection site and detection means, are appropriately determined.

The present invention will be described in more detail with reference to the following examples. Obviously, the invention is not limited by the following examples.

[0025]

EXAMPLE In the example of FIG. 2, extraction and analysis of ions were carried out using an organic phase composed of a solution segment containing each of the ionophores A ⁺ and B ⁺ and a solution segment containing only a solvent as a solution flow (40A). .

[0026] That is, in response to Figures 1 and 2, a width of about 150 [mu] m, the microchannel (30) a depth of approximately 50 [mu] m, from one inlet, as a solution stream (40B), the Na ⁺ and K ⁺ An aqueous solution containing 10 ^-2 M is introduced.
From the other inlet, a fat-soluble pH indicator (KD-A
3) a solution segment comprising an organic phase containing the Na ⁺ ionophore molecule (DD16C5) and an organic phase containing the KD-A3 and the K ⁺ ionophore molecule (Valinomycin) interposed between the organic phase not containing the ionophore and having a constant flow rate. And the segment was introduced at an introduction interval (1 μl / min, 2 min). The organic phase of the solution stream (40A) and the solution stream (40A)
The focus of the thermal lens microscope (excitation light wavelength: 514.5 mm, probe light wavelength: 633 nm) is focused on the organic phase side about 166 mm downstream from the confluence of the aqueous phase of B), and the ion concentration extracted into the organic phase segment Was measured.

When the organic phase segment containing the K ⁺ ionophore and the organic phase segment containing the Na ⁺ ionophore were alternately introduced, a response based on the selective extraction of a specific ion was obtained in each segment. Here, the amount of reagent required for one continuous measurement is about 6 μl for both the organic phase and the aqueous phase (about 150 pmol of reagent), and the amount of reagent can be further reduced when measuring transient response.
From the above results, for the first time, the merit of the continuous detection of many types of ions on one chip, which is not provided by the conventional sensor, was realized. Since such a system can measure different ions only by replacing the ionophore, it can be applied to fields requiring continuous analysis of a plurality of ions, such as environmental samples and serum samples.

[0028]

As described above in detail, the invention of this application further extends the achievements of the inventors to date, and by controlling the flow at a higher level, the chemical reaction in the microchannel is caused by mass transfer, ion A new technical means is realized in which analysis and the like can be further integrated and made continuous.

[Brief description of the drawings]

FIG. 1 is a diagram showing an outline of a segment flow.

FIG. 2 is a diagram showing an outline of a continuous analysis system for multiple types of ions.

FIG. 3 is a diagram showing usefulness of a dye molecule in ion detection.

FIG. 4 is a diagram illustrating a change in thermal lens signal intensity depending on the presence or absence of a dye.

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Claims (14)

[Claims] In a two-layer flow forming a liquid-liquid interface in a microchannel on a microchip, at least one of the solution flows is composed of a plurality of solution segments having different compositions. Interface segment flow method. 2. The liquid-liquid interface segment flow method according to claim 1, wherein components contained in the other solution stream are selectively extracted and separated into at least one of a plurality of solution segments having different compositions. . 3. The liquid / liquid interface segment flow method according to claim 1, wherein a selective liquid / liquid interface reaction is performed by at least one of the plurality of solution segments having different compositions and the other solution flow. 4. The liquid-liquid interface segment flow method according to claim 1, wherein the solution segments having different compositions contain different recognition substances. 5. The liquid-liquid interface segment flow method according to claim 1, wherein the solution segments having different compositions include those containing a recognition substance and those not containing the recognition substance. 6. A solution segment having a different composition containing different dyes.
Any one of the liquid-liquid interface segment flow methods. 7. The liquid-liquid interface segment flow method according to claim 1, wherein the solution segments having different compositions include those containing a dye and those not containing a dye. 8. The method according to claim 1, wherein the two-layer flow forming the liquid-liquid interface is formed as a horizontal parallel flow in a microchannel in a confluence region of one solution flow and the other solution flow. 7. The liquid-liquid interface segment flow method according to any of 7. 9. The method according to claim 1, wherein the two-layer flow forming the liquid-liquid interface is formed as a vertically crossing flow in a microchannel in a confluence area of one solution flow and the other solution flow. 7. The liquid-liquid interface segment flow method according to any of 7. 10. A segment characterized in that a component contained in a solution segment is detected for at least one of the liquid-liquid interface segment flows formed by the method according to any one of claims 1 to 9. Analysis method. 11. The segment analysis method according to claim 10, wherein the detection is performed in a non-contact manner. 12. The segment analysis method according to claim 10, wherein different components contained in each of the plurality of solution segments are continuously detected for each solution segment. 13. The system for a segment flow method according to claim 1, wherein at least one of a plurality of solution segments having different compositions is provided together with a microchannel in which a two-layer flow liquid-liquid interface is formed. And a supply channel for the other solution flow and a supply channel for the other solution flow, and a supply channel therefor. 14. The segment analysis system according to claim 13, further comprising detection means.