JPWO2020208672A1 - Sampling device - Google Patents

Abstract

The sampling device (1) has a suction port (3) for sucking a sample at the tip, and a sample having a flow path (4) for holding a sample sucked from the suction port (3) inside. A sampling device (1) provided with a sampling chip (2), wherein the sampling chip (2) is predetermined in order to separate a part of the flow path (4) from another part and take it out. A sample from the divided section (26) of the flow path (4) exposed to the fracture surface of the sampling chip (2), which is configured to be broken by bending at the breaking position and divided into a plurality of pieces. A protective layer (24) for preventing scattering of the sample is provided so as to cover the break position of the sampling chip (2).

Description

The present invention relates to a sampling device.

As a device capable of accurately collecting a very small amount of sample, a sampling chip having a suction port at the tip and an internal fine flow path for holding a sample sucked from the suction port has been proposed. (See Patent Document 1). The proposed sampling chip can be centrifugally separated by collecting a sample in a flow path provided inside and then holding the sample in a predetermined holder as it is. Further, this sampling chip is provided with a notch on the outer surface so that an analyst can fold it by hand to cut out a necessary part of the flow path, and can be divided into a plurality of pieces. This makes it possible to easily take out a required fixed amount of the sample separated in the internal flow path.

International Publication No. 2016/09720

When the above-mentioned sampling chip is divided into a plurality of pieces, the sample in the flow path may be scattered from the fracture surface to the outside due to the impact when the sampling chip is broken. Especially when handling biological samples, it is necessary to be careful about scattered substances because there is a possibility of biohazard.

Therefore, an object of the present invention is to prevent scattering of the sample inside when the sampling chip is divided.

The sampling device according to the present invention is provided with a sampling chip having a suction port for sucking a sample at the tip and a flow path inside for holding a sample sucked from the suction port. .. The sampling chip is configured to be divided into a plurality of pieces by refracting at a predetermined breaking position in order to separate a part of the flow path from the other part and take it out. A protective layer for preventing the sample from scattering from the divided section of the flow path exposed on the fracture surface of the sample is provided so as to cover the fractured position of the sampling chip.

That is, the sampling device of the present invention includes a protective layer that remains unbroken at the fractured position when the sampling chip is bent and broken, and the protective layer provides an impact when the sampling chip is fractured. It is characterized in that the scattering of the sample from the divided cross section of the flow path due to the above is prevented.

In the sampling chip of the present invention, the protective layer that remains unbroken at the breaking position of the sampling chip can prevent the internal sample from scattering when the sampling chip is divided.

It is a plane which shows one Example of a sampling device. It is sectional drawing which shows the cross-sectional structure at the breaking position of the sampling device. It is sectional drawing which shows the state when the sampling chip is broken at the breaking position. It is sectional drawing which shows the Example which provided the groove in the protective layer. It is a top view which shows the Example of the sampling device provided with the protective cover. It is a side view of the sampling device.

Hereinafter, embodiments of the sampling chip will be described with reference to the drawings.

As shown in FIG. 1, the sampling device 1 of this embodiment comprises a sampling chip 2 and a protective layer 24. The sampling chip 1 has a suction port 3 at the tip thereof, and has a flow path 4 inside for holding the sample sucked from the suction port 3. The flow path 4 is a U-shaped flow path having one end leading to the suction port 3, extending linearly from the suction port 3 toward the base end side, being folded back in the middle, and extending linearly from the folded portion toward the tip end side. .. The other end of the flow path 4 leads to an air hole 6 provided on the surface of the tip portion 8 of the sampling chip 1.

A plurality of notches 16 in a direction (horizontal direction in FIG. 1) intersecting the longitudinal direction (vertical direction in FIG. 1) of the sampling chip 2 are provided on the upper surface and the lower surface of the sampling chip 2. The notch 16 is for breaking the sampling chip 2 at a predetermined breaking position when it is refracted and dividing it into a plurality of pieces. By refracting the sampling tip 2 at the break position where the notch 16 is provided, the tip 8, the first extraction section 10, the second extraction section 12, and the third extraction section 14 are cut off from the sampling tip 2, respectively. be able to.

Each of the first extraction unit 10, the second extraction unit 12, and the third extraction unit 14 contains a part of the flow path 4 inside, and the first extraction is performed with the sample sucked into the flow path 4. By cutting out the part 10, the second extraction part 12 and the third extraction part 14, a part of the sample sucked into the flow path 4 can be quantitatively extracted.

The sampling tip 2 sucks the sample into the flow path 4, and then swirls the tip toward the center of rotation to apply a centrifugal force to the flow path 4, so that the sample in the flow path 4 is subjected to centrifugal force. Centrifugation can be performed. Then, after centrifugation, the first extraction unit 10, the second extraction unit 12, and the third extraction unit 14 are cut out from the sampling chip 1, so that a certain amount of the centrifuged sample components can be extracted with high accuracy. can.

The protective layer 24 is for preventing the sample from scattering in the flow path 4 when the sampling chip 2 is divided into a plurality of pieces. In this embodiment, the protective layer 24 is a resin film attached to the upper surface and the lower surface of the sampling chip 2 so as to cover the region including the breaking position where the notch 16 of the sampling chip 2 is provided.

The protective layer 24 allows refraction of the sampling chip 2 at the position where the notch 16 is provided, and remains unbroken when the sampling chip 2 breaks at the position of the notch 16. It should be. Therefore, the protective layer 24 may be made of a stretchable material. In this case, examples of the material of the protective layer 24 include PP, PC, COP, PMMA, and a fluororesin. Further, it may be attached to the sampling chip 2 so that there is a margin in the length of the position corresponding to the notch 16 of the sampling chip 2 so as to allow the refraction of the sampling chip 2.

FIG. 2 shows the cross-sectional structure of the sampling device 1 of this embodiment at the breaking position. As shown in FIG. 2, the sampling chip 2 is configured by joining two substrates 20 and 22 to each other, and the flow path 4 is formed on the joining surface of the substrates 20 and 22 to each other. The protective layer 24 is provided on the upper surface and the lower surface of the sampling chip 2 so as to cover the notch 16 of the sampling chip 2.

When the sampling chip 2 is refracted at a predetermined breaking position, as shown in FIG. 3, the substrates 20 and 22 forming the sampling chip 2 are broken at the position where the notch 16 is provided. At this time, the protective layer 24 does not break and covers the broken portion of the sampling chip 2. Therefore, even if the sample pops out from the partial cross section 26 of the flow path 4 due to the impact at the time of breaking of the sampling chip 2, the sample only adheres to the inner surface of the protective layer 24 and is outward from the protective layer 24. It does not scatter.

After breaking the sampling chip 2, the protective layer 24 is cut by some means in order to separate the piece containing the sample to be extracted from the rest of the sampling chip 2. At that time, for example, the protective layer 24 may be cut using a cutter or the like. As shown in FIG. 4, by providing a cutting auxiliary structure 28 such as a groove or a sewing machine wire at a predetermined position of the protective layer 24, the protective layer 24 can be easily torn by hand at a predetermined position. Can be done.

In the above embodiment, the protective layer 24 is provided on one and the other main planes (upper surface and lower surface) of the sampling chip 2, but the present invention is not limited thereto. When the refraction direction of the sampling chip 2 when the sampling chip 2 is divided into a plurality of pieces is defined on one of the main plane sides, the portion of the flow path 4 when the sampling chip 2 breaks. The protective layer 24 may be provided only on the surface side where the cross section 26 is exposed.

Further, in the above embodiment, the protective layer 24 is attached to the sampling chip 2, but the present invention is not limited thereto. Since the protective layer is for preventing the sample from scattering when the sampling chip 2 is divided into a plurality of pieces, at least the sampling chip 2 is broken when the sampling chip 2 is divided into a plurality of pieces. It may be provided so as to cover the position. As shown in FIGS. 5A and 5B, a cover 30 that surrounds the outer periphery of the sampling chip 2 may be attached to the sampling chip 2 to serve as a protective layer. In this case, the cover 30 can be made of a material that allows refraction of the sampling tip 2. Examples of the material of the cover 30 include silicon rubber and PDMS.

The embodiment of the sampling device (1) according to the present invention has a suction port (3) for sucking a sample at the tip, and a flow path for holding a sample sucked from the suction port (3). A sampling device (1) provided with a sampling chip (2) having 4) inside, wherein the sampling chip (2) separates a part of the flow path (4) from another part. The part of the flow path (4) exposed to the fracture surface of the sampling chip (2), which is configured to be broken by bending at a predetermined breaking position and divided into a plurality of pieces. A protective layer (24) for preventing the scattering of the sample from the cross section (26) is provided so as to cover the break position of the sampling chip (2).

In the first aspect of the above embodiment, the protective layer (24) covers the outer surface of the sampling chip (2) at the breaking position while allowing refraction of the sampling chip (2) at the breaking position. It is a resin film that covers. If the protective layer (24) is a resin film, it is easy to cut the protective layer (24) after breaking the sampling chip (2) at the breaking position.

The resin film (24) of the first aspect may be attached to the sampling chip (2). If the resin film forming the protective layer (24) is attached to the sampling chip (2) and integrated, the sampling device (1) can be easily handled.

In the above case, the resin film (24) may be attached to one and the other main planes of the sampling chip (2). Then, even if the sampling chip (2) is bent toward either the main plane side of one main plane or the other main plane side and broken, the scattering of the sample is prevented.

Further, the resin film (24) may be provided with a cutting assist structure (28) for enabling cutting by tension at a position corresponding to the breaking position of the sampling chip (2). Then, it becomes easier to cut the protective layer (24) after breaking the sampling chip (2) at the breaking position.

In the second aspect of the embodiment, the protective layer (30) surrounds the outer periphery of the breaking position of the sampling chip (2) while allowing refraction of the sampling chip (2) at the breaking position. It is a cover (30) attached as described above. That is, in this second aspect, the cover (30) forming the protective layer is provided as a separate body from the sampling chip (2). The cover (30) may be attached to the sampling chip (2) at least when the sampling chip (2) is divided into a plurality of pieces. Therefore, when the sampling chip (2) is held in a predetermined holder for centrifugation, the cover (30) does not need to be attached to the sampling chip (2), as in the conventional case. The sampling chip (2) can be centrifuged using the device of.

In the third aspect of the above embodiment, the sampling chip (2) is composed of two resin substrates (20, 22) bonded to each other, and the flow path (4) is the two resin substrates (20). , 22) is formed on the joint surface. This third aspect can be combined with the first or second aspect described above.

In the third aspect, for breaking the sampling chip (2) at the breaking position when the outer surface of the resin substrate (20, 22) forming the sampling chip (2) is refracted. A notch (16) is provided, and the protective layer (24; 30) may be provided so as to cover the notch (16) of the resin substrate (20, 22).

Further, in the fourth aspect of the embodiment, one end of the flow path (4) leads to the suction port (3), and the other end is provided on the tip side by folding back toward the tip side of the sampling chip on the way. It is a U-shaped flow path leading to the air hole (6), and the sampling tip (2) has its tip directed toward the center of rotation so that centrifugal force acts in the flow path (4). This is for centrifuging the sample collected in the flow path (4). This fourth aspect can be freely combined with the first to third aspects described above.

1 Sampling device 2 Sampling chip 3 Suction port 4 Suction port 4 Flow path 6 Air hole 8 Tip part 10 1st extraction part 12 2nd extraction part 14 3rd extraction part 16 Notch 20, 22 Substrate 24 Protective layer 26 Channel segmentation 28 Cutting auxiliary structure 30 Cover

Claims (9)

A sampling device provided with a sampling chip having a suction port for sucking a sample at the tip and a flow path inside for holding a sample sucked from the suction port.
The sampling chip is configured to be broken and divided into a plurality of pieces by refracting at a predetermined breaking position in order to separate a part including a part of the flow path from the other part and take it out. ,
A sampling device provided with a protective layer for preventing scattering of a sample from a sectional section of the flow path exposed on the fracture surface of the sampling chip so as to cover the fractured position of the sampling chip. The sampling device according to claim 1, wherein the protective layer is a resin film that covers the outer surface of the sampling chip at the breaking position while allowing refraction of the sampling chip at the breaking position. The sampling device according to claim 2, wherein the resin film is attached to the sampling chip. The sampling device according to claim 3, wherein the resin film is attached to one and the other main planes of the sampling chip. The sampling device according to claim 3, wherein the resin film is provided with a cutting assist structure for enabling cutting by tension at a position corresponding to the breaking position of the sampling chip. The sampling device according to claim 1, wherein the protective layer is a cover attached so as to surround the outer periphery of the breaking position of the sampling chip while allowing refraction of the sampling chip at the breaking position. .. The sampling chip is composed of two resin substrates bonded to each other.
The sampling device according to claim 1, wherein the flow path is formed on a joint surface of the two resin substrates. The outer surface of the resin substrate forming the sampling chip is provided with a notch for breaking the sampling chip at the breaking position when it is refracted.
The sampling device according to claim 6, wherein the protective layer is provided so as to cover the notch in the resin substrate. The flow path is a U-shaped flow path having one end leading to the suction port, folding back toward the tip end side of the sampling chip, and the other end leading to an air hole provided on the tip end side.
The sampling chip is for centrifuging the sample collected in the flow path by swirling the tip toward the center of rotation so that a centrifugal force acts in the flow path. The sampling device according to claim 1.

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