Patent Application
20220105506
The present invention relates to a fluid handling system and a cartridge.
In the related art, when testing or analyzing various fluids, it has been common practice to suction the required amount of sample from the container used to store the fluid (sample) using a pipette, etc., and inject it into a chip or device for analysis. In the related art, devices that can automatically suction samples by pipette and inject samples into chips have been proposed (e.g., PTL 1 and PTL 2).
However, the analyzing devices described in PTL 1 and PTL 2 require a means to suction a sample into a pipette and a means to move the pipette. In addition, a plurality of pipettes is needed to inject a plurality of samples and reagents into the chips, and a plurality of pipettes also needed to be controlled. As a result, the device tends to be large and costly.
In view of the above, an object of the present invention is to provide a fluid handling system that can reliably inject fluid to a desired channel chip without using large-scale devices. In addition, another object of the present invention is to provide a cartridge that can be used in the above-mentioned fluid handling system.
A fluid handling system according to an embodiment of the present invention includes: a reservoir including a housing part configured to house fluid, an opening disposed in a bottom of the housing part and configured to communicate between the housing part and outside, and a first engaging part; a channel chip including an inlet disposed opposite to the opening of the reservoir and configured to introduce fluid, and a second engaging part configured to engage with the first engaging part; and a cap made of elastomer with flexibility, the cap including a first end portion configured to be fit in the opening of the reservoir, a second end portion configured to be connected to the inlet of the channel chip, and a through hole configured to connect the first end portion and the second end portion. A closed state is set when the opening of the reservoir presses a part of the cap in such a manner as to close the through hole, the closed state being a state where fluid in the housing part does not move to the inlet of the channel chip through the through hole of the cap. An open state is set when the cap is moved to a side of the housing part relative to a position of the closed state and pressing of the opening against the cap is released, the open state being a state where the fluid in the housing part moves to the inlet of the channel chip through the through hole of the cap. In the closed state, the first engaging part of the reservoir and the second engaging part of the channel chip are in a first engaging state. In the open state, the first engaging part of the reservoir and the second engaging part of the channel chip are in a second engaging state. When at least one of the reservoir and the channel chip is moved in such a manner that the reservoir and the channel chip are brought closer to each other, an engaging state of the first engaging part and the second engaging part is switched from the first engaging state to the second engaging state.
A cartridge according to an embodiment of the present invention is configured to be used in combination with a channel chip including an inlet configured to introduce fluid and a second engaging part, the cartridge including: a reservoir including a housing part configured to house fluid, an opening disposed in a bottom of the housing part and configured to communicate between the housing part and outside, and a first engaging part configured to be engaged with the second engaging part; and a cap made of elastomer with flexibility, the cap including a first end portion configured to be fit in the opening of the reservoir, a second end portion configured to be connected to the inlet of the channel chip, and a through hole configured to connect the first end portion and the second end portion. A closed state is set when the opening of the reservoir presses a part of the cap in such a manner as to close the through hole, the closed state being a state where fluid in the housing part does not move to the inlet of the channel chip through the through hole of the cap. An open state is set when the cap is moved to a side of the housing part relative to a position of the closed state and pressing of the opening against the cap is released, the open state being a state where the fluid in the housing part moves to the inlet of the channel chip through the through hole of the cap. The first engaging part of the reservoir is configured such that in the closed state, the first engaging part and the second engaging part of the channel chip are in a first engaging state. The first engaging part of the reservoir is configured such that in the open state, the first engaging part and the second engaging part of the channel chip are in a second engaging state. The first engaging part is configured such that when at least one of the reservoir and the channel chip is moved in such a manner that the reservoir and the channel chip are brought closer to each other, an engaging state of the first engaging part and the second engaging part is switched from the first engaging state to the second engaging state.
According to the present invention, a fluid handling system that can inject fluid to a channel chip by a simple method without using a means that drives a pipette or a means that conveys a chip can be provided. In addition, according to the present invention, a cartridge that can be used in the above-mentioned fluid handling system can be provided.
A fluid handling system according to an embodiment of the present invention is elaborated below with reference to the drawings. Note that the dimensions or proportions of dimensions shown in the drawings may differ from the actual dimensions or proportions of dimensions for clarity of explanation.
As illustrated in
In fluid handling system 100 according to the present embodiment, when fluid is housed in housing part 230 of reservoir 200 (closed state), opening 210 of reservoir 200 presses a part of cap 400, and closes through hole 430 of cap 400 (see
On the other hand, as illustrated in
As is clear from comparison between
Each member of fluid handling system 100 according to the present embodiment is elaborated below.
As illustrated in
In the present embodiment, housing part 230 is a bottomed recess with a substantially cuboid shape. It should be noted that the shape of housing part 230 is not limited as long as fluid of a desired amount can be contained, and may be, for example, a recess with a truncated pyramid shape, a columnar shape, a truncated cone shape and the like. In addition, in the present embodiment, the bottom surface of housing part 230 is set to be approximately parallel with the surface of the housed fluid, but the bottom surface may be tilted in part or in its entirety such that it becomes deeper toward opening 210.
Opening 210 is a hole that is formed in the bottom of housing part 230 and communicates between the inside of housing part 230 and the outside of reservoir 200. First end portion 410 of cap 400 is fit to opening 210.
Here, as illustrated in
Pressing region 211a is a region for housing first region 410 of cap 400 when setting fluid handling system 100 to a closed state, and is a region for pressing a part of cap 400 (first region 410) toward the central axis of cap 400. In the present embodiment, the shape of first region 410 of cap 400 is a columnar shape, and the opening shape of pressing region 211a is a substantially elliptical columnar shape. Therefore, when columnar first region 410 of cap 400 is housed in pressing region 211a, the exterior wall of pressing region 211a presses first region 410 of cap 400 toward central axis CA of cap 400. As a result, through hole 430 of first region 410 of cap 400 is closed, and outflow of fluid from through hole 430 of cap 400 is suppressed.
Note that it suffices that pressing region 211a has a shape with which through hole 430 is closed at least at a part of first region 410 of cap 400 when first region 410 of cap 400 is housed. For example, pressing region 211a may have a constant opening cross-sectional area from outside of reservoir 200 to open region 211b side. In the present embodiment, pressing region 211a has a tapered shape whose opening cross-sectional area decreases from the outside of reservoir 200 toward open region 211b side for the sake of the ease of fitting of cap 400.
On the other hand, when fluid handling system 100 is set to an open state, second region 420 of cap 400 is housed in pressing region 211a. For this reason, pressing region 211a has a shape with which through hole 430 is not closed at second region 420 when second region 420 of cap 400 is housed.
Open region 211b is a region for housing first region 410 of cap 400 when fluid handling system 100 is set to an open state, and is a region where the pressing force toward central axis CA of cap 400 when first region 410 of cap 400 is housed is smaller than that of the above-described pressing region 211a. In the present embodiment, open region 211b is provided as a region having an opening cross-sectional area wider than that of pressing region 211a, and thus the pressure toward the central axis of cap 400 is set to a small value. In addition, in the present embodiment, open region 211b is similar in shape to the external shape of first region 410 of cap 400 (columnar shape). When first region 410 of cap 400 is housed in open region 211b with such a columnar shape, first region 410 of cap 400 is reset to the original columnar shape with its flexibility. As a result, through hole 430 is opened, and the fluid can pass inside through hole 430 of cap 400.
It should be noted that when a gap is formed between open region 211b and first region 410 of cap 400, the fluid may outflow to the outside of housing part 230 through the gap. In view of this, in the present embodiment, the opening diameter (diameter) of open region 211b is set to be equal to or smaller than the diameter of columnar first region 410 of cap 400.
First engaging part 220 is formed at a position corresponding to second engaging part 320 of channel chip 300, and is engaged by means of second engaging part 320 of channel chip 300. In the present embodiment, four first engaging parts 220 are formed in side walls that constitute the housing part of reservoir 200. In fluid handling system 100 according to the present embodiment, while first engaging part 220 of reservoir 200 and second engaging part 320 of channel chip 300 are engaged with each other in both the closed state and open state, the engaging state between first engaging part 220 of reservoir 200 and second engaging part 320 of channel chip 300 differs between the closed state and the open state. Specifically, in the closed state, the engaging state between first engaging part 220 of reservoir 200 and second engaging part 320 of channel chip 300 is the first engaging state illustrated in
The shape of first engaging part 220 is not limited the above-mentioned function can be ensured, and is set in accordance with the shape of second engaging part 320 of channel chip 300. In the present embodiment, first engaging part 220 includes guide groove 221, first recess 222, and second recess 223. Guide groove 221 is a groove extending along the gravity direction, to which guide protrusion 321 of second engaging part 320 of channel chip 300 is fit in a slidable manner. First recess 222 and second recess 223 are disposed in guide groove 221, and engaged by means of claw 322 of second engaging part 320 of channel chip 300. First recess 222 is a recess for setting the engaging state between first engaging part 220 and second engaging part 320 to the first engaging state, and second recess 223 is a recess for setting the engaging state between first engaging part 220 and second engaging part 320 to the second engaging state. In addition, at least first recess 222 has a shape that allows for disengagement of engaged claw 322. In the present embodiment, first recess 222 is disposed below second recess 223 (i.e., on channel chip 300 side) in the gravity direction.
The material of reservoir 200 is not limited as long as it is not eroded by fluid housed in housing part 230. Examples of the material of reservoir 200 include polyester such as polyethylene terephthalate; polycarbonate; acrylic resin such as polymethylmethacrylate; polyvinyl chloride; polyolefin such as polyethylene, polypropylene, and cycloolefin resin; polyether; polystyrene; silicone resin; and resin materials such as various elastomers. In addition, reservoir 200 may be molded by injection molding and the like, for example.
As illustrated in
Here, the diameter of first region 410 is appropriately set in accordance with the opening width and opening cross-sectional area of opening 210 (pressing region 211a and open region 211b) of reservoir 200. In addition, the shape of through hole 430 in a direction orthogonal to central axis CA in first region 410 is not limited as long as it is closed with no gap when first region 410 is housed in pressing region 211a of reservoir 200, and may be, for example, a slit shape. Note that “slit shape” as used herein means a gap elongated in one direction in a cross-section perpendicular to central axis CA of cap 400, and is a gap that is closed in a linear shape when pressed along the minor axis direction from both sides. In the present embodiment, as illustrated in
Here, the opening width and opening shape of through hole 430 in first region 410 in a direction orthogonal to central axis CA are appropriately selected in accordance with the type of fluid and the desired flow rate of fluid.
In addition, the height of first region 410 is not limited, and is appropriately selected in accordance with the shape of opening 210 of reservoir 200 (pressing region 211a and open region 211b). It should be noted that, from the view point of causing outflow of the fluid housed in housing part 230 with no residue, it is desirable to set a height with which the first end portion (the end portion on first region 410 side) of cap 400 does not protrude into housing part 230 when first region 410 is housed in open region 211b of reservoir 200. That is, preferably, the height of first region 410 is set to a value equal to or smaller than the height of open region 211b.
On the other hand, the diameter of second region 420 is appropriately set in accordance with the opening width and opening cross-sectional area of pressing region 211a of reservoir 200. In addition, the opening width and opening shape of through hole 430 of second region 420 in a direction orthogonal to central axis CA are appropriately selected in accordance with the type of fluid and the desired flow rate of fluid, and may be the same as or different from the shape of through hole 430 of first region 410. In the present embodiment, the cross-sectional shape of through hole 430 of second region 420 in a direction orthogonal to central axis CA is a circular shape.
In addition, the height of second region 420 is set to a height with which a part of second region 420 protrudes from opening 210 of reservoir 200 when first region 410 is housed in open region 211b of reservoir 200. As described above, fluid handling system 100 of the present embodiment is used in the state where the second end portion (the end portion on the second region side) of cap 400 is connected to inlet 310 of channel chip 300.
The material of cap 400 is not limited as long as the material has flexibility, and may be selected from publicly known elastomer resins. While elastomer resins include thermoplastic resins and thermosetting resins, cap 400 may be composed of any of them. Examples of heat-curable elastomer resins that can be used for cap 400 include polyurethane resins, and poly silicone resins the like, and examples of thermoplastic elastomer resins include styrene resins, olefin resins, and polyester resins. Specific examples of olefin resins include polypropylene resin. In addition, first region 410 and second region 420 of cap 400 may be composed of the same material, or different materials. It should be noted that from a view point of the ease of manufacture and the like, it is preferable to they are composed of the same material. In addition, cap 400 may be molded by injection molding and the like, for example.
As illustrated in
In the present embodiment, channel chip 300 is composed of main body 330 and a film (not illustrated in the drawing) joined to one surface (hereinafter referred to as “bottom surface”) of main body 330.
In addition, main body 330 further includes, as bottomed recesses formed in the surface (bottom surface) of main body 330 to which the film (not illustrated in the drawing) is bonded, first groove part 334 with one end connected to first inlet 331, second groove part 335 with one end connected to second inlet 332, and third groove part 336 with one end connected to first groove part 334 and second groove part 335 and the other end connected to outlet 333. In channel chip 300, the region surrounded by the film and first groove part 334 serves as the first channel, the region surrounded by the film and second groove part 335 serves as the second channel, and the region surrounded by the film and third groove part 336 serves as the third channel of the fluid.
In channel chip 300, for example, first fluid (in the present embodiment, a sample) is introduced from first inlet 331, and second fluid (in the present embodiment, a reagent) is introduced from second inlet 332. The fluids are introduced into the third channel through the first channel and second channel so as to cause a reaction at the third channel Thereafter, for example, the reactant can be moved from outlet 333 to reservoir 200 side through cap 400.
Note that examples of the material of main body 330 include polyester such as polyethylene terephthalate; polycarbonate; acrylic resin such as polymethylmethacrylate; polyvinyl chloride; polyolefin such as polyethylene, polypropylene, and cycloolefin resin; polyether; polystyrene; silicone resin; and resin materials such as various elastomers. In addition, main body 330 including the above-mentioned components may be molded by injection molding and the like, for example.
Here, main body 330 may be or may not be optically transparent. For example, in the case where fluid is observed from the surface on the side opposite to the front surface of main body 330, the material is selected such that main body 330 is optically transparent.
On the other hand, the film (not illustrated in the drawing) may be a flat film that covers main body 330. It suffices that the film is composed of a material that is not eroded by the fluid introduced in channel chip 300, and its thickness and the like are appropriately selected. Examples of the material of the film include polyester such as polyethylene terephthalate; polycarbonate; acrylic resin such as polymethylmethacrylate; polyvinyl chloride; polyolefin such as polyethylene, polypropylene, and cycloolefin resin; polyether; polystyrene; silicone resin; and resin materials such as various elastomers.
In the case where fluid is observed and/or analyzed from the film side in the state where the fluid is housed in the third channel, the material of the film is selected such that the film is optically transparent. It should be noted that, for example, in the case where fluid is observed from the side opposite to the front surface of main body 330, and/or the case where the observation of fluid is not performed, the film may not be optically transparent.
In addition, main body 330 and the film may be joined by publicly known methods such as heat fusing, and bonding with adhesive agents.
As described above, channel chip 300 includes four second engaging parts 320. In the present embodiment, second engaging part 320 is formed in main body 330.
As illustrated in
The shape of second engaging part 320 is not limited as long as the above-mentioned function can be ensured, and is set in accordance with the shape of first engaging part 220 of reservoir 200. In the present embodiment, second engaging part 320 includes guide protrusion 321 and claw 322. Guide protrusion 321 is a protrusion protruding toward reservoir 200 side, and is fit in guide groove 221 of first engaging part 220 of reservoir 200 in a slidable manner. Claw 322 is disposed at an end of guide protrusion 321, and is engaged with first recess 222 or second recess 223 of first engaging part 220 of reservoir 200. The shape of claw 322 is not limited as long as it be can engaged with first recess 222 and second recess 223 after being engaged with first recess 222. In the present embodiment, as illustrated in
First, as illustrated in
In this state, the engaging state between first engaging part 220 of reservoir 200 and second engaging part 320 of channel chip 300 is set to the first engaging state illustrated in
In the case where fluid handling system 100 is set to the closed state in the above-described manner, desired fluid is supplied in housing part 230 of reservoir 200. Note that in the case where the above-described channel chip 300 is used, one housing part 230 of three housing parts 230 of reservoir 200 is filled with the sample, another housing part 230 is filled with the reagent, and the remaining housing part 230 is set as a part for fluid collection, or in other words, set to an empty state. It should be noted that all housing parts may be filled with the fluid depending on the type of channel chip 300. In addition, various types of fluid (such as reagent and sample) may be supplied in reservoir 200 in advance.
The type of the fluid to be housed in housing part 230 of reservoir 200 is not limited as long as it can pass through through hole 430 of cap 400. The fluid may contain a single component or a plurality of components. In addition, the fluid is not limited to liquid, and may be, for example, a solvent in which a solid component is dispersed. In addition, the fluid may be a solvent in which droplets (liquid droplets) and the like incompatible with the solvent are dispersed, and the like.
When the fluid is moved from reservoir 200 into channel chip 300 in fluid handling system 100, at least one of reservoir 200 and channel chip 300 is moved such that reservoir 200 and channel chip 300 are brought closer to each other as illustrated in
Note that housing part 230 in which the fluid is housed may be pressurized or a specific housing part 230 may be suctioned as necessary for the purpose of facilitating the flow of the fluid in through hole 430 of cap 400. In addition, the fluid may be moved using capillarity.
With fluid handling system 100 according to the present embodiment, the closed state can be easily set by setting fluid handling system 100 to the first engaging state. In addition, the open state can be easily set by setting fluid handling system 100 to the second engaging state by moving at least one of reservoir 200 and channel chip 300. Thus, without using large-scale devices, the desired fluid can be supplied to channel chip 300.
In addition, in fluid handling system 100 according to the present embodiment, reservoir 200 and channel chip 300 can be moved relative to each other such that fluid handling system 100 is switched from the closed state to the open state by sliding guide protrusion 321 of second engaging part 320 of channel chip 300 in guide groove 221 of first engaging part 220 of reservoir 200. Thus, buckling of cap 400 due to a positional displacement of reservoir 200 and channel chip 300 in the horizontal direction can be suppressed. In addition, since first engaging part 220 of reservoir 200 and second engaging part 320 of channel chip 300 are engaged with each other, disassembling of reservoir 200, channel chip 300 and cap 400 can be suppressed.
In addition, with fluid handling system 100 according to the present embodiment, various types of fluid can be supplied into channel chip 300 by only pushing one of reservoir 200 and channel chip 300 toward the other. In addition, with fluid handling system 100, collection and the like of fluid at reservoir 200 can be achieved, and inspection and analysis of various types of fluid can be efficiently performed.
Note that while the example in which first engaging part 220 of reservoir 200 includes a recess, and second engaging part 320 of channel chip 300 includes the claw that engages with the recess is described in the embodiment, the present invention is not limited to this. For example, second engaging part 320 of channel chip 300 may include a recess, and first engaging part 220 of reservoir 200 may include a claw that engages with the recess.
This application is entitled to and claims the benefit of Japanese Patent
Application No. 2019-016903 filed on Feb. 1, 2019, the disclosure each of which including the specification, drawings and abstract is incorporated herein by reference in its entirety.
For example, the fluid handling system according to the present invention is applicable to inspection and analysis of various types of fluid and the like.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2019-016903 | Feb 2019 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2020/002919 | 1/28/2020 | WO | 00 |
