JP7524866B2 - Testing apparatus, press-fitting method, and microchannel device - Google Patents

Description

This disclosure relates to a test apparatus, a pressure injection method, and a microchannel device that injects a test liquid into a microchannel for measurement.

In order to test the susceptibility of bacteria to antibacterial drugs, a method using a microchannel device is known, as in Patent Document 1. For example, in Patent Document 1, a microchannel device is provided with an inlet and an outlet that communicate with the outside, and a channel through which a test liquid supplied from the inlet flows to the outlet side, and air is forced from the inlet into the channel to push the previously introduced test liquid into the fine channel. The channel is provided with a reaction section in which the test liquid supplied from the inlet is stored, and an agent placed in the reaction section acts on the bacteria.

JP 2017-67620 A

When filling a microchannel with test liquid, methods that use capillary action or pressure are known, but the method of injecting air as described in Patent Document 1 is an effective method for reliably and quickly filling a microchannel with test liquid. However, when test liquid is injected into a microchannel device that branches into multiple channels from a single inlet, differences in the liquid level height (liquid head) may occur between each channel or in the section from the inlet to each channel, and these differences may cause the test liquid to flow within each channel. If a flow occurs in the test liquid within the reaction section, it may not be possible to observe correct results.

The present disclosure has been made to solve such problems, and aims to provide a test apparatus, a pressing method, and a microchannel device that can suppress the flow of test liquid that occurs within the channel and enable accurate results to be observed.

The test device of the present disclosure is a test device that uses a microchannel device to perform a test using a test liquid containing a specimen, the microchannel device having a first opening for receiving the test liquid, a plurality of branch channels communicating with the first opening, a plurality of microchannels communicating with each branch channel, a recovery section provided at the end of each branch channel opposite the side communicating with the first opening and recovering a portion of the test liquid, and a second opening provided in the recovery section, a pressure section connected to the first opening and applying air pressure to pressurize the test liquid into the microchannel, an opening/closing section that switches the open/closed state of the second opening, and a control section that controls the pressure section and the opening/closing section, the control section controls the second opening to a closed state by the opening/closing section, pressurizes the test liquid into the microchannel by the pressure section, and after pressing the test liquid into the microchannel, controls the second opening to an open state by the opening/closing section, and applies air pressure by the pressure section to cause the test liquid in the branch channel to be recovered by the recovery section.

The pressing method of the present disclosure is a pressing method for pressing a test liquid containing a specimen into a microchannel device, the microchannel device having a first opening for receiving the test liquid, a plurality of branch channels communicating with the first opening, a plurality of microchannels communicating with each of the branch channels, a recovery section provided at the end of each branch channel opposite the side communicating with the first opening and recovering a portion of the test liquid, and a second opening provided in the recovery section, and includes the steps of closing the second opening, connecting a pipette that has aspirated the test liquid to the first opening, pressing the test liquid into the microchannel by discharging the aspirated test liquid into the first opening, opening the second opening, and applying air pressure with the pipette to recover the test liquid in the branch channel in the recovery section.

The microchannel device of the present disclosure is a microchannel device used for testing using a test liquid containing a specimen, and includes a first opening for receiving the test liquid, a plurality of branched channels communicating with the first opening, a plurality of microchannels communicating with each of the branched channels, a recovery section provided at the end of each of the branched channels opposite the side communicating with the first opening for recovering a portion of the test liquid, and a second opening provided in the recovery section.

The above test apparatus, pressing method, and microchannel device can suppress the flow of test liquid within the channel, allowing accurate results to be observed.

1 is a diagram showing an example of the overall configuration of a test device according to an embodiment of the present invention; 1 is a diagram showing an example of a peripheral configuration of a pipette nozzle in a testing device according to an embodiment of the present invention; FIG. 2 is a block diagram for explaining control of the test apparatus according to the present embodiment. 1A to 1C are diagrams showing a configuration example of a microchannel device according to an embodiment of the present invention; FIG. 13 is a diagram showing a configuration example in which a test liquid is injected under pressure into a channel of the microchannel device according to the present embodiment. 13A and 13B are diagrams showing a state after a test liquid has been injected into a channel of the microchannel device according to the present embodiment. 13A and 13B are diagrams showing a state after a test liquid has been discharged from a branch channel of the microchannel device according to the present embodiment. 11A to 11C are diagrams illustrating a method for discharging a test liquid from a branch channel of the microchannel device according to the present embodiment. 13A and 13B are diagrams showing a state in which a sealant is applied to an opening of the microchannel device according to the present embodiment. 5 is a flowchart for explaining a press-fitting method for the testing device according to the present embodiment. 13A and 13B are diagrams showing configurations of a collection section and an opening according to a modified example.

The present embodiment will now be described in detail with reference to the drawings. Note that the same or corresponding parts in the drawings will be given the same reference numerals and their description will not be repeated.

[Device configuration]
FIG. 1 is a diagram showing an example of the overall configuration of a test device according to the present embodiment. FIG. 2 is a diagram showing an example of the peripheral configuration of a pipette nozzle in the test device according to the present embodiment. FIG. 3 is a block diagram for explaining the control of the test device according to the present embodiment. The test device of the present disclosure is an apparatus for measuring the test liquid by pressing a test liquid containing a specimen into a microchannel of a microchannel device, and an example of pressing a test liquid into a microchannel to measure the sensitivity of bacteria to an antibacterial drug (medicine) will be described below as an example. The test liquid includes a specimen. The specimen may be a bacterium (in a specific example, a pathogenic bacterium). In a specific example, the test liquid may be a suspension of bacteria. Of course, the test device of the present disclosure is not limited to the above-mentioned test liquid as long as the test liquid is pressed into the microchannel of the microchannel device.

Referring to Figures 1 to 3, the testing device 100 includes a test liquid setting unit 10, a pipette nozzle driving unit 12, a table driving unit 13, a pump 14, a pipette nozzle 15, a table 16, an opening/closing unit 30, an opening/closing driving unit 31, an application unit 32, a pump 33, an application driving unit 34, and a control unit 50.

The test liquid setting unit 10 is a rack that can arrange multiple test liquid containers 5 containing test liquid. The test liquid setting unit 10 can set multiple test liquid containers 5 on a rack-by-rack basis to the testing device 100.

The pipette nozzle 15 is fitted with a removable pipette tip 1, and aspirates or expels test liquid from the test liquid container 5 through the tip of the pipette tip 1. The pipette nozzle drive unit 12 moves the pump 14 connected to the pipette nozzle 15 horizontally and vertically. The pipette nozzle drive unit 12 can freely move the pipette nozzle 15 by, for example, a solenoid actuator or a stepping motor.

The table 16 is a support member on which the microfluidic device is placed. The table 16 is formed in a flat plate shape, and the microfluidic device is fixed to the upper surface. The table driving unit 13 can move the table 16 in the horizontal direction. The table driving unit 13 can freely move the table 16 by, for example, a solenoid actuator or a stepping motor. Of course, the table driving unit 13 may move the table 16 up and down, but not move the pipette nozzle 15 up and down. At least the pipette nozzle driving unit 12 and the table driving unit 13 are movement mechanisms for changing the relative positions of the pipette nozzle 15 and the microfluidic device.

Although not shown, the pump 14 includes, for example, a syringe, a plunger capable of reciprocating movement within the syringe, and a drive motor for driving the plunger. The pump 14 is connected to the pipette nozzle 15 via piping, and by reciprocating the plunger, the pump 14 can adjust the air pressure within the pipette tip 1 to suck the test liquid into the pipette tip 1 or discharge the test liquid within the pipette tip 1 to the outside. In addition, the pump 14 can pump air out of the pipette tip 1 by moving the plunger further in the direction of pushing it into the syringe when the test liquid within the pipette tip 1 has been discharged to the outside.

The opening/closing unit 30 is a mechanism for opening and closing the opening (second opening) of the microchannel device described later. Specifically, the opening/closing unit 30 is a mechanism for controlling the opening to be in a closed state by blocking the opening with an elastic member, and for example, a silicone resin 30a is provided at the end of a rod-shaped support. The opening/closing unit 30 is attached to a predetermined position with respect to the pipette nozzle 15, so that it moves to the position of the second opening by moving the pipette nozzle 15 to the opening (first opening) of the microchannel device. The opening/closing drive unit 31 drives the opening/closing unit 30 that has moved to the position of the second opening, moves the silicone resin 30a up and down, and presses the silicone resin 30a against the second opening to block it, thereby controlling the second opening to be in a closed state. Note that in Figures 1 and 2, only one opening/closing unit 30 is shown for the purpose of simplifying the illustration, but multiple opening/closing units 30 are provided according to the number of second openings that need to be opened and closed. In addition, the opening/closing drive unit 31 may not only raise and lower the silicone resin 30a, but also move the opening/closing unit 30 relative to the pipette nozzle 15.

The application unit 32 applies a sealant to the openings of the microchannel device in order to prevent the test liquid pressed through the openings from volatilizing. Specifically, the application unit 32 is a nozzle that discharges a sealant such as silicone oil to the openings, and the nozzle applies the sealant to the openings by the pump 33. The configuration of the application unit 32 is not limited to this, and may be a mechanism that applies the sealant to the openings by a brush or the like. The application drive unit 34 moves the application unit 32 to a position such as an opening of the microchannel device to which the sealant is applied, and drives the pump 33. In Figures 1 and 2, the application unit 32 is illustrated in a configuration in which it is provided on the same moving mechanism as the pipette nozzle 15, but the application unit 32 may be provided on a moving mechanism different from the pipette nozzle 15, and the application drive unit 34 may move the application unit 32. If the volatilization of the test liquid is not a problem, the application unit 32 may not be provided in the test device 100.

The control unit 50 controls the operation of the test device 100. The control unit 50 includes a processor such as a CPU (Central Processing Unit) and memory such as a ROM (Read Only Memory) and a RAM (Random Access Memory). The memory stores a control program. The processor executes the control program to control the operation of the test device 100. The memory of the control unit 50 may include a HDD (Hard Disk Drive).

The control unit 50 controls the motor of the table drive unit 13 to move the table 16 so that the microchannel device is at a predetermined position. After the control unit 50 moves the microchannel device to the predetermined position, it controls the motor of the pipette nozzle drive unit 12 to move the pipette nozzle 15 to discharge the test liquid into the opening of the microchannel of the microchannel device. Furthermore, the control unit 50 controls the opening/closing drive unit 31 to switch the opening (second opening) of the microchannel device between open and closed states. The control unit 50 also controls the application drive unit 34 to apply a sealant to the opening of the microchannel device, etc.

Specifically, the control unit 50 controls the motor of the pipette nozzle driving unit 12 to move the pipette nozzle 15 to the position of a specified test liquid container 5, and controls the pump 14 to aspirate the test liquid in the test liquid container 5 from the tip of the pipette tip 1. The control unit 50 then controls the motor of the pipette nozzle driving unit 12 to move the pipette nozzle 15 to the position of the opening of the microchannel device, and controls the pump 14 to discharge the test liquid from the tip of the pipette tip 1.

The control unit 50 can be connected to a calculation processing device 200 realized by a personal computer (PC) or a dedicated computer. A user can manage the test device 100 via the calculation processing device 200. For example, the calculation processing device 200 can set the amount of movement of the table 16 by the table driving unit 13, the amount of movement of the pipette nozzle 15 by the pipette nozzle driving unit 12, and the amount of test liquid aspirated or discharged from the tip of the pipette tip 1 by the pump 14. The calculation processing device 200 may be electrically connected to other devices arranged adjacent to the test device 100 to form a test system.

[Configuration of microfluidic device]
4 is a diagram showing an example of the configuration of a microfluidic device according to the present embodiment. Fig. 4 shows a plan view of a microfluidic device 2. The microfluidic device 2 is placed on a table 16 of a testing apparatus 100.

As shown in FIG. 4, the microchannel device 2 includes a plate-like member 20 and a channel structure. The channel structure includes an opening 21, an opening 22 (first opening), a branch channel 23a, a microchannel 23b, a storage section 24, an opening 26 (third opening), a gas permeable membrane 27, a recovery section 28, and an opening 29 (second opening). Note that the microchannel device 2 may not have the opening 26 (third opening).

The opening 22 is provided in the opening 21, and is a portion that connects the opening 21 and the branch flow path 23a. In other words, the opening 22 is connected to one end of the branch flow path 23a. From the opening 22, the test liquid is forced into the branch flow path 23a using fluid pressure. The test liquid forced into the branch flow path 23a is further forced into the micro flow path 23b. In this embodiment, air pressure is used as the fluid pressure. The opening 22 is formed, for example, with a circular cross section. The diameter of the opening 22 is, for example, 5 μm to 5 mm. In this embodiment, four branch flow paths 23a are connected to the opening 22. The four branch flow paths 23a are arranged radially around the opening 22.

In this embodiment, four branch flow paths 23a are connected to the opening 22, but the content of the embodiment of the present invention is not limited to this. At least one branch flow path 23a may be connected to the opening 22. Also, two branch flow paths 23a may be connected to the opening 22, or three branch flow paths 23a may be connected to the opening 22. Furthermore, five or more branch flow paths 23a may be connected to the opening 22.

The branch flow channel 23a extending from the opening 22 further branches into multiple micro flow channels 23b. The branch flow channel 23a is connected to the multiple micro flow channels 23b so that the test liquid can flow through it. The test liquid flowing in from the opening 22 flows through the branch flow channel 23a into the multiple branched micro flow channels 23b. The cross sections of the branch flow channel 23a and the micro flow channel 23b are rectangular, and the widths of the branch flow channel 23a and the micro flow channel 23b are, for example, 1 μm to 1 mm. However, the depths (heights) of the branch flow channel 23a and the micro flow channel 23b are different. For example, the depth of the branch flow channel 23a is 0.5 mm, while the depth of the micro flow channel 23b is as small as 0.025 mm. Therefore, the flow channel resistance of the micro flow channel 23b is greater than that of the branch flow channel 23a. By making the flow resistance of the microchannel 23b larger than that of the branch channel 23a, the test liquid flowing in from the opening 22 can flow into the multiple microchannels 23b almost simultaneously after first filling the branch channel 23a, as described below. In this embodiment, one branch channel 23a branches into 14 microchannels 23b.

The branching flow path 23a is arranged along the X-axis direction until it branches into multiple micro-flow paths 23b, and after branching, each micro-flow path 23b is arranged along the Y-axis direction. A storage section 24 is provided midway through each micro-flow path 23b after branching. Each micro-flow path 23b causes the test liquid flowing in from the opening 22 to flow into the storage section 24.

The storage section 24, in which a drug is placed, is connected to the opening 22 via the branch flow path 23a and the micro flow path 23b, and stores the test liquid that flows in from the opening 22. In the storage section 24, the test liquid reacts with the drug. The drug is, for example, an antibacterial drug. The drug may be a solid or a liquid. The drug is placed in the storage section 24 in advance. That is, the drug is placed in the storage section 24 before the test liquid flows into the storage section 24. In this embodiment, the drug is applied to the entire storage section 24.

The storage section 24 is formed in a rectangular parallelepiped shape. The length of one side of the storage section 24 is, for example, 10 μm to 10 mm.

In FIG. 4, 56 (=14×4) storage sections 24 are formed on the plate-like member 20. The volumes of test liquid stored in the 56 storage sections 24 are the same. Meanwhile, the types and amounts of drug placed in the 56 storage sections 24 may be the same or different.

The microchannel 23b between the storage section 24 and the opening 26 is configured to allow the test liquid to flow. This microchannel 23b is arranged along the Y-axis direction. One end of the microchannel 23b is connected to the storage section 24, and the other end of the microchannel 23b is connected to the opening 26. The microchannel 23b allows the test liquid that has flowed in from the storage section 24 to flow to the opening 26.

The opening 26 is connected to the other end of the microchannel 23b. The opening 26 is formed, for example, with a circular cross section. The diameter of the opening 26 is, for example, 5 μm to 5 mm.

The openings 26 are covered with a gas permeable membrane 27. Specifically, in FIG. 4, 56 (=14×4) openings 26 are formed in the plate-shaped member 20. Of the 56 openings 26, 28 openings 26 formed at the positive end of the plate-shaped member 20 along the Y axis are covered with one gas permeable membrane 27, and 28 openings 26 formed at the negative end of the plate-shaped member 20 along the Y axis are covered with one gas permeable membrane 27. Each of the two gas permeable membranes 27 is arranged along the X axis direction.

The gas permeable membrane 27 has a function of allowing gas to pass through but not allowing liquid to pass through. Examples of materials for the gas permeable membrane 27 include polytetrafluoroethylene (PTFE). It is preferable that the gas permeable membrane 27 has water repellency. The thickness of the gas permeable membrane 27 is 1 mm or less.

The gas permeable membrane 27 is fixed to the plate-like member 20 by adhesive bonding, ultrasonic fusion, etc. Examples of adhesives include photocurable resins, thermosetting resins, and pressure-sensitive resins.

The recovery section 28 is connected to the end of the branch flow path 23a opposite to the end to which the opening 22 is connected, and is a section that recovers a portion of the test liquid. The recovery section 28 is formed in a rectangular parallelepiped shape. The length of one side of the recovery section 28 is, for example, 10 μm to 10 mm. The recovery section 28 may be provided with a member that absorbs moisture (water-absorbing member), such as a sponge. This makes it possible to prevent backflow from the recovery section 28 to the branch flow path 23a, and to prevent the test liquid from evaporating from the branch flow path 23a.

The opening 29 is connected to the end of the recovery section 28 opposite to the end to which the branch flow path 23a is connected. The branch flow path 23a and the recovery section 28 allow the test liquid to flow from the opening 22 to the opening 29. The opening 29 is closed by blocking it with the silicone resin 30a of the opening/closing section 30. By closing the opening 29, the test liquid that has flowed into the branch flow path 23a is controlled so that it is not discharged to the recovery section 28 and the opening 29, and by opening the opening 29, the test liquid remaining in the branch flow path 23a can be discharged to the recovery section 28 and recovered.

Figure 5 is a diagram showing an example of a configuration in which a test liquid is pressed into a channel of a microchannel device according to this embodiment. The plate member 20 comprises a first plate member 20a on the upper side of Figure 5 and a second plate member 20b on the lower side. The second plate member 20b is laminated on the first plate member 20a. The second plate member 20b is disposed in the negative direction (downward direction) of the Z axis shown in Figure 4 relative to the first plate member 20a.

The first plate-shaped member 20a and the second plate-shaped member 20b are formed in a rectangular plate shape from a transparent material. Examples of materials for the first plate-shaped member 20a and the second plate-shaped member 20b include acrylic resin such as polymethylmethacrylate resin, glass, and the like. A flow path structure is formed in the first plate-shaped member 20a. Specifically, the first plate-shaped member 20a is formed with an opening 22, a branch flow path 23a, a micro flow path 23b, a storage section 24, an opening 26, and a recovery section 28 (see FIG. 4). The second plate-shaped member 20b functions as the lower surface of the opening 22, the branch flow path 23a, the micro flow path 23b, the storage section 24, the opening 26, and the recovery section 28. The thickness of the first plate-shaped member 20a and the second plate-shaped member 20b is not particularly limited, but is set to, for example, 0.5 mm to 3 mm. The second plate-like member 20b is fixed directly to the first plate-like member 20a by ultrasonic melting, but may also be fixed via an adhesive.

In this embodiment, the test liquid sucked into the pipette tip 1 is discharged into the opening 21 of the microchannel device 2, and the discharged test liquid is pressurized with air pressure and forced into the microchannel 23b through the opening 22. In order to pressurize the test liquid and force it into the microchannel 23b, a press-in pad (not shown) that covers the opening 21 communicating with the microchannel 23b may be provided. However, if a press-in pad is provided, when the press-in pad is pressed against the opening 21 and air pressure is applied to the test liquid to force it into the microchannel 23b, the test liquid may adhere to the press-in pad and become contaminated. Since the press-in pad is repeatedly used for other microchannel devices, when a different test liquid is measured, the previously measured test liquid may be mixed in (contaminated) and affect the test results.

Therefore, a pressure pad that can be attached to the pipette tip 1 is prepared, and when pressurizing the test liquid to force it into the microchannel 23b, air pressure is sent from the pipette tip 1 while covering the opening 21 with the pressure pad. The pressure pad can then be discarded together with the pipette tip 1. This prevents contamination of the test liquid and allows for highly accurate test results to be obtained.

As shown in FIG. 5, the test liquid flowing in from the pipette tip 1 passes through the opening 22 and the branching flow path 23a to fill the microchannel 23b, the reservoir 24, and the opening 26. However, in the microchannel device 2, the multiple microchannels 23b are connected via the branching flow path 23a. Therefore, when the test liquid is injected into the microchannel device 2 that branches from one opening 22 through the branching flow path 23a to multiple microchannels 23b, if a difference in the liquid level (liquid head) occurs between each flow path or in the portion from the opening 22 to each flow path, this difference will cause the test liquid to flow in each flow path.

Figure 6 is a diagram showing the state after the test liquid is pressed into the flow channel of the microchannel device according to the present embodiment. The upper path shown in Figure 6 is path A, and the lower path is path B. The test liquid flowing in from the opening 22 branches into the microchannel 23b of path A and the microchannel 23b of path B via the branch flow channel 23a, and reaches each opening 26. As shown in Figure 6, path B is longer from the opening 22 than path A, so the liquid head of the opening 26 of path A is higher than the liquid head of the opening 26 of path B. Since a difference in the liquid head occurs between path A and path B, a flow of the test liquid occurs between path A and path B to eliminate the difference. If a flow of the test liquid occurs in the storage section 24 of path A and path B, it may not be possible to observe the correct result.

In this embodiment, the test liquid remaining in the branch flow path 23a is discharged to the recovery section 28 after the test liquid is injected into the multiple micro flow paths 23b. By discharging the test liquid remaining in the branch flow path 23a, the multiple micro flow paths 23b and the opening 26 are connected via the branch flow path 23a, and each flow path is made independent so that they cannot be regarded as a single flow path as a whole, and flow due to a liquid head difference is prevented.

Figure 7 is a diagram showing the state after the test liquid has been discharged from the branch flow path of the microchannel device according to this embodiment. The upper path shown in Figure 7 is path A, and the lower path is path B. By discharging the test liquid from the branch flow path 23a, the microchannel 23b of path A and the microchannel 23b of path B can no longer be considered as a single flow path via the branch flow path 23a. Therefore, even if the liquid head at the opening 26 of path A is higher than the liquid head at the opening 26 of path B, no flow of test liquid occurs between paths A and B to eliminate the difference.

Figure 8 is a diagram for explaining a method for discharging a test liquid from a branch channel of a microchannel device according to this embodiment. In Figure 8, a plurality of microchannels 23b are connected to a branch channel 23a, a recovery section 28 is connected to one end of the branch channel 23a, and an opening 29 is provided at the end of the recovery section 28 opposite the end to which the branch channel 23a is connected. Although not shown, the branch channel 23a is connected to an opening 22 at the end opposite the end to which the recovery section 28 is connected.

When the test liquid flows into the branch flow channel 23a, the flow resistance of each micro flow channel 23b is larger than that of the branch flow channel 23a, so the test liquid does not flow into each micro flow channel 23b until all of the branch flow channels 23a are filled with the test liquid. In order to make the flow resistance of each micro flow channel 23b larger than that of the branch flow channel 23a, the cross-sectional area of the branch flow channel 23a may be made larger than that of each micro flow channel 23b. If the width of the branch flow channel 23a and the width of each micro flow channel 23b are the same, the depth of the branch flow channel 23a is made deeper than that of each micro flow channel 23b. For example, if the depth of the branch flow channel 23a is 0.5 mm and the depth of each micro flow channel 23b is 0.001 mm, the cross-sectional area of the branch flow channel 23a can be made 500 times the cross-sectional area of each micro flow channel 23b.

When the test liquid is flowed into the branch flow path 23a, the opening 29 is blocked and closed by the silicone resin 30a of the opening/closing section 30. Therefore, the test liquid that has flowed into the branch flow path 23a is not discharged to the recovery section 28 at this stage. After the branch flow paths 23a are all filled with the test liquid, as shown in FIG. 8, the test liquid flows into each micro flow path 23b almost simultaneously. This causes the test liquid to flow into each micro flow path 23b and each storage section 24.

Then, the silicone resin 30a of the opening/closing section 30 that is blocking the opening 29 is removed, and air is sent through the opening 22 while the opening 29 is open, thereby discharging the test liquid remaining in the branch flow path 23a to the recovery section 28 as shown in FIG. 8. The air sent through the opening 22 can be the air discharged from the pipette tip 1 to pressurize the test liquid. The recovery section 28 has a space (buffer space) that holds the test liquid in the branch flow path 23a that is discharged, and this space is larger than the volume of the branch flow path 23a.

Whether or not the test liquid in the branch flow path 23a is discharged to the recovery section 28 can be controlled by opening and closing the opening 29. The test liquid remaining in the branch flow path 23a is discharged to the recovery section 28 from the opening 22 by air.

In this embodiment, the test liquid is injected into each microchannel 23b, and the test liquid remaining in the branch channel 23a is discharged to the recovery section 28, and then a sealant such as silicone oil is applied to the openings 22, 26, 29, etc. FIG. 9 is a diagram showing the state in which the sealant is applied to the openings of the microchannel device according to this embodiment. As shown in FIG. 9, silicone oil 33a is applied to the openings 22, 26, 29 (see FIG. 8), etc. by the application section 32. By applying silicone oil 33a to the openings 22, 26, 29, etc., it is possible to suppress the test liquid in each microchannel 23b from volatilizing from the openings 22, 26, 29, etc. Note that since the gas permeable film 27 is provided in the opening 26, silicone oil 33a is applied to at least the openings 22 and 29.

The sealant applied to the openings 22, 26, 29, etc. is not limited to silicone oil 33a, but may be any material that remains in the openings 22, 26, 29, etc. and suppresses the volatilization of the test liquid.

Next, a method for pressing the test device according to this embodiment will be described using a flowchart. FIG. 10 is a flowchart for explaining a method for pressing the test device according to this embodiment. First, the control unit 50 of the test device 100 controls the motor of the pipette nozzle drive unit 12 to move the pipette nozzle 15 to the position of a specified test liquid container 5, and controls the pump 14 to aspirate the test liquid in the test liquid container 5 from the tip of the pipette tip 1 (step S11). The control unit 50 controls the motor of the pipette nozzle drive unit 12 to move the pipette nozzle 15 to the position of the opening 22 of the microchannel device 2 (step S12).

The position of the opening/closing unit 30 relative to the pipette nozzle 15 is determined in advance according to the position of the opening 29 relative to the opening 22 of the microchannel device 2. Therefore, when the pipette nozzle 15 is aligned with the position of the opening 22 of the microchannel device 2 in step S12, the opening/closing unit 30 moves to a position directly above the opening 29. The control unit 50 causes the opening/closing drive unit 31 to move the elastic member (silicone resin 30a) to a position that blocks the opening 29 (step S13). The control unit 50 determines whether the openings 29 are closed based on whether the elastic member (silicone resin 30a) has been moved to a position that blocks all of the openings 29 (step S14). If it is determined that all of the openings 29 are not closed (NO in step S14), the control unit 50 returns the process to step S13.

If it is determined that all openings 29 are closed (YES in step S14), the control unit 50 controls the pump 14 to discharge the test liquid from the tip of the pipette tip 1 and pressurize the test liquid into the flow paths (branch flow path 23a, micro flow path 23b) of the micro flow path device 2 (step S15).

The control unit 50 determines whether the test liquid has been pressed into the flow paths of all the micro-channel devices 2 (step S16). The control unit 50 determines whether the test liquid has been pressed into the flow paths of all the micro-channel devices 2 based on, for example, the time it takes to press the test liquid into the flow paths of the micro-channel devices 2 and the amount of test liquid remaining in the pipette tip 1. If the test liquid has not been pressed into the flow paths of all the micro-channel devices 2 (NO in step S16), the control unit 50 returns the process to step S15.

When the test liquid has been injected into all of the flow paths of the microchannel device 2 (YES in step S16), the control unit 50 uses the opening/closing drive unit 31 to move the elastic member (silicone resin 30a) from the position blocking the opening 29 to open the opening 29 (step S17). The control unit 50 controls the pump 14 to expel air from the tip of the pipette tip 1, and expels the test liquid remaining in the branch flow path 23a to the recovery unit 28 (step S18).

The control unit 50 controls the motor of the pipette nozzle driving unit 12 to move the application unit 32 to the positions of the openings 22, 26, and 29, and applies the sealant to the openings 22, 26, and 29 (step S19).

[Modification]
(1) In the testing apparatus 100 according to the present embodiment, the opening 29 is closed by blocking the opening 29 with the silicone resin 30a of the opening/closing unit 30, but the present invention is not limited to this and may be configured in any manner as long as it is configured to switch the open/closed state of the opening 29. For example, in the case where an opening 29 of the microchannel device 2 is provided with an opening/closing mechanism (such as a shutter) in advance, the opening/closing unit 30 may be configured to switch the state of the opening/closing mechanism.

(2) In the test device 100 according to the present embodiment, a sealant is applied to the openings 22, 26, and 29, but this is not limited thereto, and any configuration may be used as long as it can suppress the evaporation of the test liquid. For example, the evaporation of the test liquid may be suppressed by attaching a cover prepared in advance to the openings 22, 26, and 29.

(3) In the test device 100 according to this embodiment, for example, the cross section of the opening 29 is formed in a circular shape and communicates with the recovery section 28. Therefore, when air is sent from the opening 22 with the opening 29 open to discharge the test liquid remaining in the branch flow path 23a to the recovery section 28, depending on the pressure of the air sent in, the test liquid may not only be discharged to the recovery section 28 but may also overflow from the opening 29. Therefore, the opening 29 is covered with a gas permeable membrane. Figure 11 is a diagram showing the configuration of the recovery section and opening according to a modified example. Figure 11(a) is a plan view of a portion where the recovery section 28 is provided at the end of the branch flow path 23a to which multiple microflow paths 23b are connected. Figure 11(b) is a cross-sectional view of the recovery section 28 shown in Figure 11(a) at the cutting line I.

FIG. 11(b) shows the gas permeable membrane 27a covering the opening 29. The gas permeable membrane 27a may be made of the same material as the gas permeable membrane 27 covering the opening 26, or a different material, as long as it has the function of allowing gas to pass through and not allowing liquid to pass through. Examples of materials for the gas permeable membrane 27a include polytetrafluoroethylene (PTFE). It is preferable that the gas permeable membrane 27a has water repellency. The thickness of the gas permeable membrane 27a is 1 mm or less.

By covering the opening 29 with the gas permeable membrane 27a, it is possible to prevent the test liquid from overflowing from the opening 29 when the test liquid remaining in the branch flow path 23a is discharged to the recovery section 28. In order to close the opening 29, it is necessary to block the opening 29 from above the gas permeable membrane 27a with the silicone resin 30a of the opening/closing section 30.

In this way, by further providing a gas permeable membrane 27a covering the opening 29 (second opening), when the test liquid remaining in the branch flow path 23a is discharged to the collection section 28, the risk that the test liquid will not remain in the collection section 28 but will be discharged from the opening 29 can be reduced.

In FIG. 11(b), an opening 29 is provided at the end of the collection section 28 opposite the end to which the branch flow path 23a is connected, but a configuration without an opening 29 can be realized by providing an opening in the collection section 28 itself. Even in a configuration without an opening 29, it is necessary to send air from the opening 22 while the opening in the collection section 28 is open, and to discharge the test liquid remaining in the branch flow path 23a into the collection section 28. Therefore, depending on the pressure of the air sent in, not only will the test liquid be discharged into the collection section 28, but it may also overflow from the opening in the collection section 28.

Figure 11 (c) is a modified example of the collection section 28 shown in Figure 11 (b). Figure 11 (c) shows an opening 28a provided by removing all of the first plate-like member 20a on the upper surface of the collection section 28. Furthermore, the opening 28a provided in the collection section 28 is covered with a gas permeable membrane 27b. By providing the opening 28a on the entire upper surface of the collection section 28, there is no possibility that the entire surface of the gas permeable membrane 27b will come into contact with the test liquid, and air is always released from the gas permeable membrane 27b, making it easier to discharge all the test liquid remaining in the branch flow path 23a. Note that the opening 28a does not need to be provided on the entire upper surface of the collection section 28, and it may be provided only on at least a part of the upper surface of the collection section 28 as long as it is large enough for the amount of test liquid discharged to the collection section 28.

The gas permeable membrane 27b may be made of the same material as the gas permeable membrane 27 covering the opening 26, or a different material, as long as it has the function of allowing gas to pass through and not allowing liquid to pass through. Examples of materials for the gas permeable membrane 27b include polytetrafluoroethylene (PTFE). It is preferable that the gas permeable membrane 27b has water repellency. The thickness of the gas permeable membrane 27b is 1 mm or less.

By covering the opening 28a provided in the recovery section 28 with the gas permeable membrane 27b, it is possible to prevent the test liquid from overflowing from the opening 28a when the test liquid remaining in the branch flow path 23a is discharged to the recovery section 28. In order to close the opening 28a, it is necessary to block the entire opening 28a from above the gas permeable membrane 27b with the silicone resin 30a of the opening/closing section 30.

In this way, the recovery section 28 has an opening 28a at least in a portion thereof, and further includes a gas permeable membrane 27b covering the opening 28a, which makes it easier to drain all of the test liquid remaining in the branch flow path 23a and reduces the risk that the test liquid will not remain in the recovery section 28 but will be discharged from the opening 28a.

[Aspects]
It will be understood by those skilled in the art that the above-described embodiments are illustrative of the following aspects.

(Section 1)
A test apparatus according to one embodiment is a test apparatus that uses a microchannel device to perform a test using a test liquid containing a specimen, the microchannel device having a first opening for receiving the test liquid, a plurality of branch channels communicating with the first opening, a plurality of microchannels communicating with each of the branch channels, a recovery section provided at an end of each branch channel opposite the side communicating with the first opening and recovering a portion of the test liquid, and a second opening provided in the recovery section, the test apparatus further comprising: a pressure section connected to the first opening and applying air pressure to pressurize the test liquid into the microchannel; an opening/closing section that switches the open/closed state of the second opening; and a control section that controls the pressure section and the opening/closing section, the control section controlling the opening/closing section to close the second opening, the pressure section to pressurize the test liquid into the microchannel, and after the test liquid has been pressed into the microchannel, the opening/closing section to open the second opening, and the pressure section to apply air pressure to cause the test liquid in the branch channel to be recovered in the recovery section.

According to the test device described in paragraph 1, the test liquid in the branch flow path can be discharged to the recovery section and recovered, so that the flow of the test liquid occurring in the flow path can be suppressed and accurate results can be observed.

(Section 2)
In the testing device described in paragraph 2, the opening/closing section has a mechanism for controlling the second opening to a closed state by blocking the second opening with an elastic member.

According to the test device described in paragraph 2, the second opening is blocked by an elastic member, so the device configuration can be simplified and the second opening can be easily closed.

(Section 3)
A test apparatus as described in paragraph 3, wherein the pressurizing unit has a pipette that aspirates or discharges test liquid, and a moving mechanism for changing the relative position of the pipette and the microchannel device, and connects the pipette to a first opening by the moving mechanism, and pressurizes the test liquid into the microchannel by discharging the aspirated test liquid into the first opening.

The test device described in paragraph 3 makes it easy to pressurize the test liquid into each microchannel of the microchannel device.

(Section 4)
The test apparatus described in paragraph 4 further includes an application section that applies a sealant that suppresses evaporation of the test liquid, and the microchannel device further has a third opening that is provided downstream as viewed from the side communicating with the branch channel, and the application section applies the sealant to at least the first opening and the third opening of the microchannel into which the test liquid has been injected.

According to the test device described in paragraph 4, a sealant is applied to the first and third openings, so that the test liquid can be prevented from evaporating from the openings.

(Section 5)
6. The testing device according to claim 5, wherein the sealing material is silicone oil.

According to the test device described in paragraph 5, the sealant is silicone oil, so it is easy to apply the sealant to the opening.

(Section 6)
One embodiment of the pressing method is a pressing method for pressing a test liquid containing a specimen into a microchannel device, the microchannel device having a first opening for receiving the test liquid, a plurality of branch channels communicating with the first opening, a plurality of microchannels communicating with each of the branch channels, a recovery section provided at an end of each branch channel opposite the side communicating with the first opening and for recovering a portion of the test liquid, and a second opening provided in the recovery section, the method including the steps of closing the second opening, connecting a pipette that has aspirated the test liquid to the first opening, pressing the test liquid into the microchannel by discharging the aspirated test liquid into the first opening, opening the second opening, and applying air pressure with the pipette to recover the test liquid in the branch channel in the recovery section.

According to the pressing method described in paragraph 6, the test liquid in the branch flow path can be discharged to the recovery section and recovered, so that the flow of the test liquid occurring in the flow path can be suppressed and accurate results can be observed.

(Section 7)
8. The pressing method according to claim 7, wherein the microchannel device further has a third opening provided downstream as viewed from the side communicating with the branch channel, and further includes a step of applying a sealant that suppresses volatilization of the test liquid to at least the first opening and the third opening of the microchannel into which the test liquid has been pressed.

According to the pressing method described in paragraph 7, a sealant is applied to the first and third openings, which prevents the test liquid from evaporating from the openings.

(Section 8)
9. The press-fitting method according to claim 8, wherein the sealing material is silicone oil.

According to the pressing method described in paragraph 8, the sealant is silicone oil, so it is easy to apply the sealant to the opening.

(Section 9)
A microchannel device according to one embodiment is a microchannel device used for a test that uses a test liquid containing a specimen, and includes a first opening for receiving the test liquid, a plurality of branch flow paths communicating with the first opening, a plurality of microchannels communicating with each of the branch flow paths, a recovery section provided at an end of each branch flow path opposite the side communicating with the first opening for recovering a portion of the test liquid, and a second opening provided in the recovery section.

According to the microchannel device described in paragraph 9, the test liquid in the branch channel can be discharged to the recovery section and recovered, so that the flow of the test liquid occurring in the channel can be suppressed and accurate results can be observed.

(Article 10)
11. A microchannel device according to item 10, wherein the recovery section is a buffer space that communicates with an end of the branch channel and has a volume larger than that of the branch channel.

According to the microchannel device described in paragraph 10, the recovery section is a buffer space larger than the volume of the branch channel, so that all of the test liquid remaining in the branch channel can be recovered.

(Article 11)
12. The microchannel device according to item 11, wherein a water-absorbing member is provided in the buffer space.

The microchannel device described in paragraph 11 can prevent backflow from the recovery section to the branch channel and can prevent the test liquid from volatilizing from the branch channel.

(Article 12)
13. A microchannel device according to item 12, wherein the flow resistance of the microchannel is greater than the flow resistance of the branch channel.

According to the microchannel device described in paragraph 12, the flow resistance of the microchannel is greater than the flow resistance of the branched flow channels, so that the test solution in the branched flow channels can be made to flow into each microchannel at almost the same time.

(Article 13)
14. The microchannel device according to item 13, further comprising a gas permeable membrane covering the second opening.

According to the microchannel device described in paragraph 13, when the test liquid remaining in the branch channel is discharged to the recovery section, the risk that the test liquid will not remain in the recovery section but will be discharged from the opening can be reduced.

(Section 14)
15. The microchannel device according to item 14, wherein the recovery section has an opening at least in a part thereof, and further comprises a gas-permeable membrane covering the opening.

The microchannel device described in paragraph 14 makes it easier to drain all test liquid remaining in the branch channel, and reduces the risk that the test liquid will not remain in the recovery section and will be drained from the opening.

The embodiments disclosed herein should be considered to be illustrative and not restrictive in all respects. The scope of the present invention is indicated by the claims, not by the description of the embodiments above, and is intended to include all modifications within the meaning and scope of the claims.

1 Pipette tip, 2 Microchannel device, 5 Test liquid container, 10 Test liquid placement section, 12 Pipette nozzle drive section, 13 Table drive section, 14, 33 Pump, 15 Pipette nozzle, 16 Table, 21, 28a Opening, 22, 26, 29 Opening, 23 Branch flow path, 23b Microchannel, 24 Storage section, 27, 27a, 27b Gas permeable membrane, 28 Recovery section, 30 Opening/closing section, 31 Opening/closing drive section, 32 Coating section, 34 Coating drive section, 50 Control section, 100 Test device, 200 Calculation processing device.

Claims (14)

A test apparatus for performing a test using a test liquid containing a specimen by using a microfluidic device,
The microchannel device includes:
a first opening for receiving the test liquid;
A plurality of branch flow paths communicating with the first opening;
a plurality of microchannels communicating with each of the branch channels;
a recovery section provided at an end of each of the branched flow paths opposite to the end communicating with the first opening, the recovery section recovering a portion of the test liquid;
A second opening is provided in the collection section,
a pressurizing unit connected to the first opening and applying air pressure to pressurize the test liquid into the microchannel;
an opening/closing unit that switches the open/closed state of the second opening;
A control unit that controls the pressurizing unit and the opening/closing unit,
The control unit is
The opening/closing unit controls the second opening to be in a closed state, and the pressurizing unit pressurizes the test liquid into the microchannel;
a test device for controlling the second opening to be open by the opening/closing unit after the test liquid is pressurized into the microchannel, and for recovering the test liquid in the branch channel in the recovery unit by applying air pressure by the pressurizing unit. The test device according to claim 1, wherein the opening/closing section has a mechanism for controlling the second opening to be in a closed state by blocking the second opening with an elastic member. The pressure applying unit is
A pipette for aspirating or discharging the test liquid;
a moving mechanism for changing a relative position between the pipette and the microfluidic device,
3. The test device according to claim 1, wherein the pipette is connected to the first opening by the moving mechanism, and the aspirated test liquid is discharged into the first opening, thereby forcing the test liquid into the microchannel. The test liquid further includes a coating unit that coats a sealant that suppresses volatilization of the test liquid,
the microchannel device further includes a third opening provided downstream as viewed from a side communicating with the branch channel,
4. The testing device according to claim 1, wherein the applicator applies the sealant to at least the first opening and the third opening of the microchannel into which the test liquid is pressurized. The test device according to claim 4, wherein the sealing material is silicone oil. 1. A method for pressurizing a test liquid containing a specimen into a microchannel device, comprising the steps of:
the microchannel device has a first opening for receiving the test liquid, a plurality of branch channels communicating with the first opening, a plurality of microchannels communicating with each of the branch channels, a recovery unit provided at an end of each of the branch channels opposite to the end communicating with the first opening and configured to recover a portion of the test liquid, and a second opening provided in the recovery unit;
closing the second opening;
connecting a pipette having aspirated the test liquid to the first opening;
discharging the aspirated test liquid into the first opening to pressurize the test liquid into the microchannel;
opening the second opening;
and applying air pressure with the pipette to recover the test liquid in the branch flow path in the recovery section. the microchannel device further includes a third opening provided downstream as viewed from a side communicating with the branch channel,
The pressing method according to claim 6 , further comprising the step of applying a sealant that suppresses volatilization of the test liquid to at least the first opening and the third opening of the microchannel into which the test liquid is pressed. The press-fitting method according to claim 7, wherein the sealing material is silicone oil. A microfluidic device for use in a test using a test liquid containing a specimen,
a first opening for receiving the test liquid;
A plurality of branch flow paths communicating with the first opening;
a plurality of microchannels communicating with each of the branch channels;
a recovery section provided at an end of each of the branched flow paths opposite to the end communicating with the first opening, the recovery section recovering a portion of the test liquid;
a second opening provided in the recovery section. The microchannel device according to claim 9, wherein the recovery section is a buffer space that is connected to an end of the branch channel and has a volume larger than that of the branch channel. The microchannel device according to claim 10, wherein a water-absorbing member is provided in the buffer space. The microchannel device according to any one of claims 9 to 11, wherein the flow resistance of the microchannel is greater than the flow resistance of the branch channel. The microchannel device according to any one of claims 9 to 12, further comprising a gas-permeable membrane covering the second opening. The collection section has an opening at least in a part thereof,
13. The microchannel device according to claim 9, further comprising a gas permeable membrane covering the opening.

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