JP2020147315A - Cryopreservation tube - Google Patents

Abstract

To provide a cryopreservation tube in which leakage of contents due to tube breakage is unlikely to occur when internal pressure of the cryopreservation tube has increased due to a refrigerant that has entered the cryopreservation tube.SOLUTION: A cryopreservation tube for encapsulating and cryopreserving contents with a refrigerant includes a tube body having an opening at one end, and a cap screwed onto the tube body to close the opening. A gas exhaust part that cleaves due to internal pressure increase in the cryopreservation tube and exhausts the gas inside the cryopreservation tube is provided on at least a part of the cryopreservation tube on the side where the cap is mounted.SELECTED DRAWING: Figure 1

Description

The present invention relates to a cryopreservation tube used as a container for cryopreservation of a sample in a biochemical test or the like.

The cryopreservation tube has conventionally been widely used as a storage container for cryopreserving biological samples such as cells and fertilized eggs in a refrigerant in biochemical tests and the like. Its basic structure includes a tube body filled with a biological sample or the like as a content, and a cap that closes an opening of the tube body to prevent leakage of the content.

For example, Patent Document 1 includes a container (tube) body having an opening at one end and a lid (cap) for closing the opening, and the lid and the container body can be detached from each other by a screw lid mechanism. The lid has a portion where the distance from the center of rotation to the outer periphery of the lid is long and a portion where the distance is short when viewed from the direction of the central axis of rotation of the screw lid mechanism, and a portion where the distance is short. A test container provided with a finger hook having a surface connected to a portion having a long distance is disclosed, and it is also disclosed that this test container is used as a cryopreservation tube.

Japanese Unexamined Patent Publication No. 2015-029945

However, in the cryopreservation tube of Patent Document 1, the tube body and cap shrink when cryopreserved in the refrigerant, and the liquid refrigerant and vaporized refrigerant freeze from the gap between the tube body and the cap caused by this shrinkage. It may get inside the storage tube. Then, when the internal pressure of the cryopreservation tube increases due to the vaporization of the refrigerant that has entered the inside of the cryopreservation tube due to the temperature rise after the cryopreservation tube is taken out from the refrigerant, the tube body is damaged in an unspecified region. It may occur, and if damage occurs near the closed bottom of the tube body, there is a problem that the contents leak to the outside.

The present invention has been made in view of the above problems, and when the internal pressure of the cryopreservation tube is increased by the refrigerant that has entered the inside of the cryopreservation tube, the contents are less likely to leak due to tube breakage. The purpose is to provide.

The cryopreservation tube according to the present invention is a cryopreservation tube for encapsulating the contents and cryopreserving in a refrigerant, and has a tube body having an opening at one end and an opening screwed into the tube body. It is provided with a cap for closing the cryopreservation tube, and at least a part of the cryopreservation tube on the side where the cap is attached is provided with a gas exhaust part which is cleaved by an increase in the internal pressure of the cryopreservation tube to exhaust the gas inside the cryopreservation tube. It is characterized by that.

In the cryopreservation tube according to the present invention, when the internal pressure of the cryopreservation tube increases due to the refrigerant that has entered the inside of the cryopreservation tube, the gas exhaust section is cleaved and the gas inside the cryopreservation tube is discharged from the gas exhaust section. Can be exhausted to. Therefore, even if the internal pressure of the cryopreservation tube rises, damage is unlikely to occur in a portion other than the gas exhaust portion, and leakage of the contents is unlikely to occur.

It is a front view / sectional view which shows the whole (tube body and cap) of the cryopreservation tube which concerns on this embodiment. It is a schematic diagram which showed the tube main body of the cryopreservation tube which concerns on this embodiment from right above the opening. It is an enlarged cross-sectional view of the screwed portion between a tube body and a cap of the cryopreservation tube which concerns on this embodiment. It is a schematic diagram which showed the tube main body in the modification of the cryopreservation tube which concerns on this embodiment from right above the opening.

Hereinafter, embodiments of the cryopreservation tube according to the present invention will be described with reference to the drawings.
It should be noted that the embodiments described below are merely examples for facilitating the understanding of the present invention, and do not limit the present invention. That is, the shapes, dimensions, arrangements, etc. of the members described below can be changed and improved without departing from the gist of the present invention, and it goes without saying that the present invention includes equivalents thereof.
Further, in all the drawings, similar components are designated by the same reference numerals, and duplicate description will be omitted as appropriate. For convenience, some of the drawings are not marked (omitted).

<Overview>
First, the outline of the cryopreservation tube according to the present embodiment will be described with reference to the reference numerals of FIGS. 1 to 4.
In addition, FIG. 1 is a schematic front view / cross-sectional view (right half is a front view, left half is a front view) showing the whole cryopreservation tube (state before the tube body and the cap are screwed) according to the present embodiment. Sectional view). 2 and 4 are schematic views showing the tube body of the cryopreservation tube according to the present embodiment from directly above the opening, and FIG. 3 is a tube main body of the cryopreservation tube according to the present embodiment. It is a schematic enlarged sectional view of the screwed portion in the state where the cap and the cap are screwed.

The cryopreservation tube according to the present embodiment is a cryopreservation tube for enclosing the contents (filling a biological sample or the like as the contents and then closing the opening) and cryopreserving in the refrigerant, that is, cryopreservation. Tube container for.
A tube body 1 having an opening 11 at one end and a cap 3 screwed into the tube body 1 to close the opening 11 are provided, and at least on the side where the cap 3 of the cryopreservation tube is attached. A gas exhaust section 15 is provided in a part thereof, which is cleaved by an increase in the internal pressure of the cryopreservation tube and exhausts the gas inside the cryopreservation tube.

Here, in the present embodiment, the "refrigerant" means a substance having a temperature below the freezing point and having a function of absorbing heat from the object to be cooled and freezing the object to be cooled, for example, liquid nitrogen or liquefaction. Argon, liquefied helium, dry ice, etc. are shown. Then, in the cryopreservation tube according to the present embodiment, after the contents are sealed, the contents are cryopreserved by immersing the contents in a liquid refrigerant liquid phase or surrounding the contents with a solid refrigerant. In the present embodiment, the effect of the present invention is more exerted especially when liquid nitrogen is used as a refrigerant.
Further, in the present embodiment, "cleavage" means that in the cryopreservation tube according to the present embodiment, at least a part of the side on which the cap 3 is attached is torn and opened due to an increase in the internal pressure of the cryopreservation tube. .. Therefore, opening the tube body 1 and the cap 3 without tearing, such as opening the opening 11 of the tube body 1 which has been closed by loosening the screw between the cap 3 and the tube body 1, is a result of this opening. Is not included.
Further, in the present embodiment, "exhausting" means releasing gas from the inside of the cryopreservation tube to the outside.

The contents to be enclosed in the cryopreservation tube according to the present embodiment include biological samples used in biochemical tests of fertilized eggs, unfertilized eggs, cells, serum, microorganisms, viruses, etc., DNA, RNA, and antibodies. , Enzyme proteins, low molecular weight compounds and the like. In particular, when a sample such as a fertilized egg that requires freeze storage or quick thawing by quick freezing is used as the content, liquid nitrogen is likely to be used as a refrigerant, so that the effect of the present invention tends to be more exhibited. It is in.

<About the overall configuration>
The overall configuration of the cryopreservation tube according to this embodiment will be described in detail with reference to FIG.

FIG. 1 is a schematic front view / cross-sectional view showing the entire cryopreservation tube according to the present embodiment, and is a tube body 1 having an opening 11 at one end and a closed bottom at the other end (lower view of FIG. 1). ) And a cap 3 (upper view of FIG. 1) that can be screwed into the tube body 1 to close the opening 11. The tube body 1 is provided with a screwing portion 13 for screwing with the cap 3 on the outer peripheral surface on the side where the cap 3 is mounted, and is similarly screwed with the tube body 1 on the inner peripheral surface of the cap 3. A screw portion 13 for the purpose is provided. Then, the opening 11 of the tube body 1 is closed by screwing the screwed portion 13 of the cap 3 shown in the upper part of FIG. 1 into the screwed portion 13 of the tube body 1 shown in the lower figure of FIG. Can be done. Further, in FIG. 1, the screwed portion 13 of the tube main body 1 is provided with a gas exhaust portion 15 which is a mechanism for cleaving due to an increase in the internal pressure of the cryopreservation tube and exhausting the gas inside the cryopreservation tube to the outside.

Here, the "screw portion 13" in the present embodiment is a screw mechanism for screwing the tube body 1 and the cap 3 of the cryopreservation tube, and is formed on the outer peripheral surface of the tube body 1 and the inner peripheral surface of the cap 3. A mechanism in which a screw portion 13 having a spiral protrusion (thread portion) and a groove (thread groove portion) is provided, and the opening 11 of the tube body 1 is closed by rotating the tube body 1 and the cap 3 in combination. Is. Since the tube body 1 and the cap 3 can be attached to and detached from each other by the screwed portion 13, the cryopreservation tube having the opening 11 closed can be easily opened.

The materials for forming the tube body 1 and the cap 3 include polyethylene (PE) resin, polypropylene (PP) resin, polystyrene (PS) resin, acrylic nitrile / butadiene / styrene copolymer (ABS) resin, and polycarbonate (). It is preferable to use a thermoplastic resin such as a PC) resin, a polymethyl terpen (TPX) resin, or a polyethylene terephthalate (PET) resin. This is because not only the strength and moldability of the tube body 1 and the cap 3 are excellent, but also the gas exhaust portion 15 can be easily formed into an arbitrary shape or the like by the same material.
However, in the cryopreservation tube according to the present embodiment, the gas exhaust portion 15 may be formed by using a material (different material) locally different from other portions. For example, the tube body 1 and the cap 3 may be made of PP resin, and the gas exhaust portion 15 may be made of PE resin. With such a configuration, when the internal pressure of the cryopreservation tube increases, the joint portion between the gas exhaust portion 15 formed of a different material and the tube body 1 or the cap 3 is more likely to be cleaved than other portions. Therefore, there is a high possibility that the joint portion will be cleaved and the gas exhaust portion 15 itself will come out toward the outside, so that it is difficult for debris at the time of cleft to enter the inside of the cryopreservation tube. When the gas exhaust unit 15 is locally formed using a material different from other parts, the gas exhaust unit 15 may use a material other than the thermoplastic resin (for example, metal).
Further, the tube body 1 and the cap 3 may be made of different materials.

Further, the shape of the tube body 1 is preferably tubular (preferably cylindrical) except for the closed bottom, and the closed bottom is conical (conical bottom) or hemispherical (round bottom). Is preferable. Then, in the closed bottom portion which is conical or hemispherical, a flat portion having a flat surface may be formed in a part thereof. Then, the tube body 1 may have a means for making the cryopreservation tube according to the present embodiment self-supporting. As a means for making the tube body self-supporting, a skirt portion 17 formed so as to extend the side wall of the tube body 1 and cover the closed bottom portion of the tube body 1 as shown in FIG. 1 is exemplified. As, a pedestal formed on the closed bottom of the tube body 1 is shown.
Further, the shape and size of the cap 3 need to have a shape and size that can be screwed with the opening 11 of the tube body 1 in order to be screwed into the tube body 1 to close the opening 11.
Here, the cryopreservation tube according to the present embodiment is a sterilized tube in which the tube body 1 and the cap 3 are sterilized by γ-rays, electron beams, etc. in order to be a storage container that can be widely used in biochemical tests and the like. May be good. Further, the capacity of the tube body 1 can be arbitrarily selected according to the purpose of use and the like, and is not particularly limited.

<Regarding the configuration of the gas exhaust section>
The configuration of the gas exhaust portion 15 of the cryopreservation tube according to the present embodiment will be described in detail with reference to FIGS. 1 to 4.

The cryopreservation tube according to the present embodiment is cleaved at least a part of the side to which the cap 3 is attached (for example, the screwed portion 13 of the tube body 1) due to an increase in the internal pressure of the cryopreservation tube, and is inside the cryopreservation tube. A gas exhaust unit 15 for exhausting gas is provided. That is, the gas exhaust unit 15 is a fragile portion in the cryopreservation tube according to the present embodiment, and when the internal pressure inside the cryopreservation tube increases, the gas exhaust portion 15 which is the fragile portion is preferentially cleaved. As a result, it is possible to suppress the occurrence of damage in the unspecified area of the cryopreservation tube and prevent leakage of the contents.

Here, in the present embodiment, the "side on which the cap 3 is attached" refers to the portion of the tube body 1 that is covered by the cap 3 when the cap 3 is attached, and its vicinity, and the tube body 1 in the cap 3. It means a top surface portion facing the opening 11 of the tube body 1 when attached. The vicinity of the portion of the tube body 1 that is covered by the cap 3 when the cap 3 is attached is a region of the upper end side 1/2 of the total length from the opening 11 to the closed bottom of the tube body 1. is there. For example, in FIG. 1, the portion of the tube body 1 that is covered by the cap 3 when the cap 3 is attached, that is, the portion where the screwed portion 13 of the tube body 1 is formed is the total length of the tube body 1. The area from the upper end side (opening 11 side) to 1/5 of the length, and the vicinity thereof is 1/2 of the total length of the tube body 1 from the upper end side (opening 11 side). Of the regions up to the length, this is the region excluding the portion where the screwed portion 13 of the tube body 1 is formed (the region from the upper end side to the length of 1/5 described above).

In this way, the gas exhaust unit 15 is provided on the side where the cap 3 of the above-mentioned cryopreservation tube is attached, which means that the contents are in direct contact with the contents in the cryopreservation tube. It means that it is not provided in or near the part where it is. In particular, as shown in FIGS. 1 to 4, it is more preferable that the screwed portion 13 of the tube body 1 is provided with the gas exhaust portion 15, and the gas exhaust portion 15 is provided on the top surface of the cap 3. It may be a configuration provided with.
The size and shape of the gas exhaust unit 15 can be appropriately designed within the range in which the tube body 1 and the cap 3 maintain their functions, and a preferred embodiment is a window structure of several millimeters square. ..

Further, the gas exhaust unit 15 needs to have a structure that keeps the cryopreservation tube in a closed state before cleavage and a structure that easily cleaves when the internal pressure of the cryopreservation tube rises due to a temperature rise or the like. There is. As such a structure, the gas exhaust portion 15 as described above is locally formed by using a material of a type different from other portions, or the gas exhaust portion 15 is locally formed more than other portions. An example is a configuration in which the thickness is thin.
Since the gas exhaust unit 15 has such a structure, the liquid refrigerant does not enter the inside of the cryopreservation tube from the gas exhaust unit 15 during cryopreservation in the liquid refrigerant liquid phase, and a solid such as dry ice. Even in the refrigerant, the vaporized refrigerant does not enter the inside of the cryopreservation tube from the gas exhaust section 15.

In particular, as shown in FIGS. 1 to 4, the gas exhaust unit 15 has a thin structure in which the outside of the tube body 1 is cut off, which is provided in the tube body 1, and is a tube from another part of the tube body 1. It is more preferable that the thickness of the portion is thin. Such a thin portion is easily cleaved due to an increase in the internal pressure of the cryopreservation tube, and since its structure is simple, it can be easily provided on the tube body 1 or the cap 3.
In this case, the gas exhaust portion 15 which is a thin portion includes both the portion where the outside of the tube body 1 is cut off and the thin structure of the tube body 1.
Further, the “outside of the tube body 1” in the present embodiment means the surface side of the tube body 1 in contact with the refrigerant, and includes the outer peripheral surface side of the screwed portion 13 of the tube body 1 which is screwed with the cap 3. Will be done. Therefore, "the outside of the tube body 1 is missing" means that the tube body 1 is cut off from the surface side of the tube body 1 in contact with the refrigerant toward the inside of the tube, as in the examples shown in FIGS. 1 to 4. Represents the state of being.

Here, in the case where the gas exhaust portion 15 is a thin portion having a thin structure in which the outside of the tube body 1 is omitted as described above, and the thickness is thinner than other portions of the tube body 1. It is more preferable that the thin portion is provided with one notch serving as a cleavage start point. Examples of the notch serving as the cleavage start point include a fine notch formed on the surface of the thin portion.
Since one such notch is provided, when the internal pressure of the cryopreservation tube increases, the gas exhaust portion 15 starts to be cleaved from this one notch, so that a fragment is generated at the time of cleaving. It is difficult, and even if a fragment is generated, it is difficult for the fragment to enter the inside of the cryopreservation tube.

Further, as shown in FIGS. 1 to 4, the gas exhaust portion 15 is at least a part of the screw groove portion 13-3 which is a part of the screw portion 13 provided on the side where the cap 3 of the tube body 1 is mounted. It is more preferable that it is provided in.
This part is a part covered by the cap 3 when the cap 3 is attached to the tube body 1 and is closed. By providing the gas exhaust part 15 in this part, the gas exhaust part due to the increase in the internal pressure of the cryopreservation tube When the 15 is cleaved, the gas inside the cryopreservation tube passes through the gap formed between the cleaved gas exhaust portion 15 and the screw portion 13 of the tube body 1 and the screw portion 13 of the cap 3. Although the gas is exhausted to the outside, since the cleaved gas exhaust portion 15 is covered with the cap 3, the contents are less likely to leak from the cleaved gas exhaust portion 15. Further, in this configuration, it is possible to prevent substances existing outside the cryopreservation tube from entering the inside of the cryopreservation tube through the cleaved gas exhaust unit 15, so that the contents are less likely to be contaminated.

In the present embodiment, as a further modification, the gas exhaust portion 15 is at least one of the screw thread portions 13-1 which is a part of the screw portion 13 provided on the side where the cap 3 of the tube body 1 is mounted. Although the configuration may be provided in the portion, the gas exhaust portion 15 is provided in at least a part of the screw groove portions 13-3 described above in that the cryopreservation tube is more easily cleaved due to an increase in the internal pressure. It is very suitable to have.

Further, in the configuration in which the gas exhaust portion 15 is provided in the screw groove portion 13-3 of the tube body 1 described above, as shown in FIG. 3, the cap 3 is attached to the tube body 1 and the opening 11 of the tube body 1 is capped. In the state of being closed by 3 (the state in which the tube body 1 and the cap 3 are screwed and rotated until they stop), they are engaged (engaged) with the threaded portion 13-1 provided on the inner peripheral surface of the cap 3. ) A gas exhaust portion 15 is provided in the thread groove portion 13-3 of the tube body 1, and a gap is provided between the thread portion 13-1 and the gas exhaust portion 15 provided in the screw groove portion 13-3. It is more preferable to have (the tip of the thread portion 13-1 is not in contact with the gas exhaust portion 15). For example, in the cross-sectional view shown in FIG. 3, of the four-stage threaded portion 13-1 provided on the inner peripheral surface of the cap 3, the second-stage threaded portion 13-1 counted from the top surface of the cap 3. Of the three threaded grooves 13-3 of the tube body 1 to be engaged, that is, the three threaded grooves 13-3 provided in the tube body 1, gas is supplied to the first threaded groove 13-3 counted from the opening 11 of the tube body 1. An exhaust portion 15 is formed, and a gap is provided between the cap 3 and the second-stage thread portion 13-1 of the cap 3 to be engaged with the exhaust portion 15. It should be noted that this gap is formed to such an extent that the threaded groove portion 13-3 of the tube body 1 and the threaded portion 13-1 of the cap 3 are not disengaged, and gas can be exhausted to some extent. Just do it. Then, in the cross-sectional view shown in FIG. 3, for convenience, the threaded portion 13 of the tube body 1 and the threaded portion 13 of the cap 3 are described with a gap as a whole. The lower slope 14-1 of the threaded portion 13-1 of the screw thread portion 13-1 and the upper slope 14-2 of the threaded portion of the threaded portion 13-1 of the cap 3 may be in close contact with each other. In such an embodiment, the lower slope 14-1 of the thread portion 13-1 of the thread portion 13 of the tube body 1 and the upper slope 14-2 of the thread portion of the thread portion 13-1 of the cap 3 are in close contact with each other. The gas is exhausted by a spiral void formed at the screwed portion 13 that communicates with the outside.
With the above configuration, when the gas exhaust unit 15 is cleaved, the gas exhaust from the tube body 1 becomes relatively slow, so that the contents can be suppressed from leaking together with the gas, and the gas exhaust due to the presence of voids. Since the flow path is secured, the gas inside the cryopreservation tube can be reliably exhausted to the outside.

In the case where the gas exhaust portion 15 is a thin portion provided in at least a part of the screw groove portion 13-3 of the tube body 1 and having a thickness thinner than that of other parts of the tube body 1, the gas exhaust portion 15 is provided. The wall thickness of the gas exhaust portion 15 (thickness of the thin structure) is preferably less than half of the wall thickness of the non-formed region of the gas exhaust portion in the thread groove portion 13-3 of the tube body 1. For example, in the case of a 2 mL cryopreservation tube made of polypropylene, the tube wall thickness of the gas exhaust portion non-forming region of the tube body 1 is 1 mm, and the tube wall thickness of the region where the gas exhaust portion 15 is formed is 0. An embodiment of 3 mm (that is, the missing portion in the gas exhaust portion 15 is 0.7 mm) is exemplified.
The gas exhaust portion 15 having a thin structure having such a thickness is likely to be stably maintained in a closed state during cryopreservation, and is more likely to be cleaved due to an increase in the internal pressure of the cryopreservation tube.

Further, when the gas exhaust unit 15 is provided in the tube body 1, two or more gas exhaust units 15 are provided at rotationally symmetric positions with respect to the central axis of the tube body 1 as shown in FIG. 2 or 4. It is preferable that it is. Here, the "central axis of the tube body 1" in this embodiment means an axis that becomes the center of rotation of the tube body 1 when the tube body 1 and the cap 3 are combined and rotated by a screw mechanism. ..
For example, in the thread groove portions 13-3 of the tube body 1 as shown in FIG. 2, a pair (two) are provided at 180-degree rotationally symmetric positions with the central axis of the tube body 1 as the base axis, and FIG. As shown, in the thread groove portions 13-3 of the tube body 1, a configuration in which one pair (three) is provided at a rotationally symmetric position of 120 degrees with the central axis of the tube body 1 as a base axis is shown as a preferable example.
With the above configuration, the strength balance of the tube body 1 and its screwed portion 13 is maintained even if the gas exhaust portion 15 is provided, and the gas exhaust portion 15 is unintentionally cleaved (frozen storage) when the cryopreservation tube is used. Cleavage due to factors other than the increase in the internal pressure of the tube) can be prevented.

As described above, the gas exhaust portion 15 is preferably provided in the screw portion 13 of the tube body 1, but the gas exhaust portion 15 is provided in a region other than the screw portion 13 of the tube body 1. The configuration is not excluded. For example, the gas is in the region from the upper end side (opening 11 side) to 1/2 of the total length of the tube body 1 and is closer to the closed bottom side than the screwed portion 13 of the tube body 1. The exhaust portion 15 may be formed.
Further, when the gas exhaust portion 15 is provided in the screw portion 13 of the tube body 1, a pair of gas exhaust portions 15 are provided in one thread groove portion 13-3 as shown in FIGS. 1 and 3. In addition to the above configuration, a plurality of pairs of gas exhaust portions 15 may be formed in connection with each stage of the screw thread portion 13-1 and the thread groove portion 13-3.

<About modification>
A further modification of the cryopreservation tube according to the present embodiment will be described.

In the cryopreservation tube according to the present embodiment, even when the gas exhaust portion 15 is provided on the top surface portion of the cap 3, the central axis of the cap 3 is used as a base axis as in the case where the gas exhaust portion 15 is provided on the tube main body 1. It is preferable that one or more pairs are provided at the rotationally symmetric positions. Here, the "central axis of the cap 3" in this modification means the axis that becomes the center of rotation of the cap 3 when the cap 3 and the tube body 1 are combined and rotated by the screw mechanism.

Further, the gas exhaust portion 15 provided on the top surface portion of the cap 3 has a thin structure in which the outside (the side in contact with the refrigerant) of the top surface portion of the cap 3 is omitted, as in the case of being provided on the tube body 1. It is preferably a thin portion having a thin portion, and the thickness of this thin structure is more preferably less than half the thickness of the region where the gas exhaust portion is not formed on the top surface portion of the cap 3.

In this embodiment, it is not preferable to provide the gas exhaust portion 15 on the side surface of the cap 3. The side surface of the cap 3 is a portion that covers the tube body 1 (overlaps the outside of the screwed portion 13 of the tube body 1) when the cap 3 and the tube body 1 are screwed, and gas is provided on the side surface of the cap 3. This is because even if the exhaust unit 15 is provided, it may not be able to be cleaved due to an increase in the internal pressure of the cryopreservation tube.

In the cryopreservation tube according to the present invention including the above-described embodiment, when the internal pressure of the cryopreservation tube increases due to the refrigerant that has entered the inside of the cryopreservation tube, the gas exhaust portion is cleaved and the inside of the cryopreservation tube is cleaved. By exhausting the gas from the gas exhaust portion to the outside, it is possible to prevent damage to the cryopreservation tube in an unspecified region. Further, although the cryopreservation tube according to the present invention is provided with such a gas exhaust unit, the refrigerant can easily enter the inside of the cryopreservation tube when stored in the refrigerant as compared with the conventional cryopreservation tube. Not a structure.

When a thermoplastic resin or the like is used as a material, the cryopreservation tube according to the present invention can be manufactured by molding by a known molding method such as injection molding or vacuum forming.
In the cryopreservation tube according to the present embodiment, when the tube body 1 or cap 3 and the gas exhaust portion 15 are collectively molded using the same material, a mold including the shape of the gas exhaust portion 15 is included. It can be molded by injection molding or the like using. On the other hand, when the gas exhaust portion 15 is formed by using a material different from that of the tube body 1 and the cap 3, a method of joining the separately formed gas exhaust portion 15 and the tube body 1 and the cap 3 by heat fusion or the like, etc. Can be molded by

The above embodiment includes the following technical ideas.
(1) A cryopreservation tube for encapsulating the contents and cryopreserving in a refrigerant, a tube body having an opening at one end, and a cap that is screwed into the tube body to close the opening. , And at least a part of the cryopreservation tube on the side where the cap is attached is provided with a gas exhaust portion that is cleaved by an increase in the internal pressure of the cryopreservation tube to exhaust the gas inside the cryopreservation tube. tube.
(2) The cryopreservation tube according to (1), wherein the gas exhaust portion is a thin portion provided in the tube body and having a thin structure in which the outside of the tube body is omitted.
(3) The cryopreservation tube according to (1) or (2), wherein the gas exhaust portion is provided in at least a part of a screw groove portion provided on the side of the tube body to which the cap is mounted.
(4) The gas exhaust portion is provided at a portion of the screw groove portion that engages with a screw thread portion provided on the inner peripheral surface of the cap in a state where the opening of the tube body is closed by the cap. The cryopreservation tube according to (3), which has a gap between the gas exhaust portion and the thread portion.
(5) The cryopreservation tube according to (3) or (4), wherein the wall thickness of the gas exhaust portion is less than half the wall thickness of the gas exhaust portion non-forming region in the thread groove portion of the tube body.
(6) The cryopreservation tube according to any one of (1) to (5), wherein two or more gas exhaust units are provided at rotationally symmetrical positions with respect to the central axis of the tube body.

1 Tube body 3 Cap 11 Opening 13 Threaded part 13-1 Threaded part 13-3 Threaded groove part 14-1 Threaded part Lower slope 14-2 Threaded part Upper slope 15 Gas exhaust part 17 Skirt part

Claims (6)

A cryopreservation tube for encapsulating the contents and cryopreserving in a refrigerant.
A tube body having an opening at one end and a cap that is screwed into the tube body to close the opening are provided.
At least a part of the cryopreservation tube on the side where the cap is attached is provided with a gas exhaust portion that is cleaved by an increase in the internal pressure of the cryopreservation tube to exhaust the gas inside the cryopreservation tube.
Cryopreservation tube. The cryopreservation tube according to claim 1, wherein the gas exhaust portion is a thin portion provided in the tube body and having a thin structure in which the outside of the tube body is omitted. The cryopreservation tube according to claim 1 or 2, wherein the gas exhaust portion is provided in at least a part of a screw groove portion provided on the side of the tube body to which the cap is mounted. The gas exhaust portion is provided at a portion of the screw groove portion that engages with a thread portion provided on the inner peripheral surface of the cap in a state where the opening of the tube body is closed by the cap, and the gas is provided. The cryopreservation tube according to claim 3, which has a gap between the exhaust portion and the thread portion. The cryopreservation tube according to claim 3 or 4, wherein the wall thickness of the gas exhaust portion is less than half the wall thickness of the gas exhaust portion non-forming region in the thread groove portion of the tube body. The cryopreservation tube according to any one of claims 1 to 5, wherein two or more gas exhaust units are provided at rotationally symmetrical positions with respect to the central axis of the tube body.

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