JP2017067637A - Coating tube - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coating tube that can suppress reduction in the amount of a usable sample and that can prevent blood from leaking out of a broken part of a closed-end tube into another sample and infections due to the blood.SOLUTION: A coating tube 1 stores collected samples. The coating tube 1 includes: a closed-end tube body 11 for containing collected samples; a coating film 12 tightly covering the side part of the tube body; and a plug member 3 sealing the tube body, the coating 12 having a glass transition point which is below zero and is also lower than that of the tube body 11.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a coated tube for storing a collected specimen.

  There is a blood collection tube as a container for storing the collected specimen, specifically, blood. In the blood collection tube, an additive is stored in advance in order to enable a predetermined analysis, and the inside of the blood collection tube is in a vacuum state by being decompressed. The collected blood may be frozen and stored for a long period of time for examination or the like, and a vacuum blood collection tube such as that disclosed in Patent Document 1 is known as a blood collection tube for cryopreservation. The vacuum blood collection tube of Patent Document 1 has a bottomed tube and a plug, and a plug is attached to the opening of the bottomed tube to maintain the decompressed state inside the bottomed tube. In the vacuum blood collection tube, a cap is attached to the bottomed tube during freezing to close the opening of the bottomed tube.

WO2008 / 078808 specification

  The collected blood is used for various purposes, and is used for examining blood components or used for examining genes. Moreover, there is frozen storage as a method for storing the collected blood, but red blood cells contained in blood are destroyed when stored frozen. When a component test or the like is performed, the test value may change if the red blood cells are destroyed, so that the whole blood cannot be stored frozen. On the other hand, since the gene is not destroyed by freezing, in the genetic test, whole blood is frozen at an ultra-low temperature of around -80 degrees and stored for a long time in order to preserve the blood for a long time.

  When freezing whole blood, the water in the blood begins to freeze when it is below 0 ° C., and the blood begins to expand by freezing. Generally, when blood is collected, the inside of the blood collection tube is not filled with blood, and a part of the blood collection tube, that is, the upper portion is vacated. The vacuum blood collection tube of Patent Document 1 is no exception, and a space can be made in the upper part of the bottomed tube even after blood is collected. Therefore, the blood that expands while icing proceeds in the bottomed tube upward in the axial direction. Eventually, the upper blood in the bottomed tube freezes first, and the expansion of the lower blood in the axial direction is suppressed. Then, the blood on the lower side starts to expand in the radial direction, and there is a possibility that the bottomed tube may be damaged without being able to withstand the expansion of the blood. In a vacuum blood collection tube for cryopreservation of a single tube as described in Patent Document 1, a cold-resistant material is used to prevent breakage of the bottomed tube due to cryogenic destruction or blood expansion under ultra-low temperatures. . Moreover, in the vacuum blood collection tube for cryopreservation of a single tube, since the side part of a bottomed tube is exposed, the technique of further damage prevention is calculated | required. If the bottomed tube is damaged due to blood expansion or some external factor, it is possible that blood will leak out from the damaged part when it is thawed for genetic testing. As a result, the amount of blood in the bottomed tube decreases, and the amount of blood that can be used as a specimen decreases. Further, it may cause a mistake in the test result due to the leaked blood mixed into other specimens, or cause an infection from the specimen blood.

  Therefore, the present invention provides a coated tube that suppresses a decrease in the amount of a sample that can be used and that can further prevent contamination of blood leaked from a damaged portion of the bottomed tube and infection by the blood. It is intended to provide.

  A coated tube for cryopreservation according to the present invention is a coated tube for cryopreservation in which a collected specimen is cryopreserved, and a bottomed cylindrical tube body into which the collected specimen is placed and a side surface portion of the tube body are in close contact with each other And a plug member that seals the tube body, the coating having a glass transition point below the freezing point and lower than the glass transition point of the tube body. .

  According to the present invention, since the glass transition point of the coating is lower than the glass transition point of the tube body, the viscosity of the coating can be kept lower than that of the tube body during freezing. Further, since the glass transition of the coating is below freezing point, the coating can be made sticky even during freezing storage. Therefore, even if the specimen expands by cryopreservation while the tube main body is solidified below the glass transition point and the tube main body expands, the coating can be extended according to the expansion. That is, it is possible to maintain the state where the coating is in close contact with and cover the side surface of the tube body, and even if the tube body breaks without being able to withstand expansion, the damaged portion is still covered with the coating. Can be maintained. This prevents the specimen from leaking from the damaged part between the tube body and the coating even after the sample has been thawed, and the amount of specimen that can be used for examinations, etc., between the tube body and the coating. It can be prevented from decreasing. Furthermore, it is possible to further prevent the blood leaking from the damaged portion of the bottomed tube from being mixed into the specimen and the blood infection.

  ADVANTAGE OF THE INVENTION According to this invention, it can suppress that the quantity of the test substance which can be used decreases, and can further prevent the contamination of the blood leaked from the broken part of the bottomed tube and the blood infection.

It is the front view which looked at the coated tube for freezing preservation which is an embodiment of the present invention from the front. It is sectional drawing which cut | disconnected the coating tube of FIG. 1 by the cutting line II-II. It is an expanded sectional view which expands and shows the area | region X1 of the coating tube of FIG.

  Hereinafter, a coated tube 1 for cryopreservation according to an embodiment of the present invention will be described with reference to the drawings described above. In addition, the concept of the direction used in the following description is used for convenience in description, and does not limit the direction of the configuration of the invention in that direction. Moreover, the coated tube 1 for cryopreservation described below is only one embodiment of the present invention. Therefore, the present invention is not limited to the embodiments, and additions, deletions, and changes can be made without departing from the spirit of the invention.

  A coated tube 1 for cryopreservation (hereinafter referred to as “coated tube 1”) shown in FIG. 1 is used when a collected specimen, for example, blood is stored frozen at a temperature of −15 degrees or less. Specifically, the coated tube 1 is stored at a medical freeze of −30 ° C. or less to stop the reaction of the enzyme contained in the sample, or −70 to store a sample used for genetic testing for a long period (deep freeze). It is used when storing below 1 degree. The coated tube 1 used in this way includes a tube body 2 and a plug member 3. 1 is a plane including the axis L1 of the coated tube 1.

  The tube body 2 is formed in a bottomed cylindrical shape that is long in the axial direction, and includes a tube body 11 and a coating 12 as shown in FIG. The tube body 11 is a bottomed cylindrical tube that is long in the axial direction, and blood (sample) collected from a blood vessel can be placed in the tube body 11. The tube body 11 is made of a material having a glass transition point higher than the cold resistance temperature when the coated tube 1 is used. Specifically, the glass transition point of the tube body 11 is set to be relatively high (specifically, 50 degrees or more), and the tube body 11 has a relatively high viscosity at a temperature of 40 ° C. or less. It is solidified. The tube body 11 is made of a light-transmitting thermoplastic resin such as polyethylene terephthalate (PET), and is manufactured by injection molding. The cylindrical portion 11a that forms the side surface of the tube body 11 is formed in an annular cross section. Further, the lower portion 11b of the tube body 11 is substantially spherical, and the portion around the axis L1 of the lower surface portion of the tube body 11 is recessed toward the inside of the tube body 11 as shown in FIG. Yes. Thereby, the lower surface 11c of the pipe body 11 is formed in an annular shape. The outer peripheral surface of the tube body 11 configured in this way is covered with the coating 12.

  The coating 12 is a thin film, and is formed on the outer peripheral surface of the tube body 11 with a thickness of, for example, 1.0 mm or less, preferably 0.1 mm or more and 0.5 mm or less. In the present embodiment, the coating 12 is substantially the entire outer peripheral surface of the tube body 11 (the outer surface of the cylindrical portion 11a and the outer surface of the lower portion 11b). 11 is formed in a portion excluding the vicinity of the opening end portion 11e.

  The coating 12 is made of a material having a glass transition point lower than that of the tube body 11, and the glass transition point of the coating 12 is below freezing (that is, 0 ° C. or lower). Examples of the material (glass transition point) of the coating 12 include polyethylene (−80 ° C.), polyoxymethylene (−68 ° C.), aliphatic polyester (poly-ε-caprolactone) (−60 ° C.), butadiene rubber (−94). ° C), silicone rubber (-120 ° C), nitrile rubber (-85 ° C), butyl rubber (-70 ° C), natural rubber (-70 ° C), polyester elastomer (-69 ° C), polyolefin elastomer (-60 ° C) ) Or polyurethane elastomer (−60 ° C.). In addition, the glass transition point of each material mentioned above is a reference example, and even if it is the same material, it can be made to have a different glass transition point by rearranging a composition. As described above, a material having a glass transition point lower than that of the tube body 11 is used as the material of the film 12, and the viscosity of the film 12 can be suppressed lower than that of the tube body 11. Moreover, since the glass transition point of the film 12 is below freezing point, the film can be made sticky even during freezing storage. Thereby, the outer peripheral surface of the solidified tube body 11 can be covered with the sticky coating 12 (that is, the viscosity is low), and the coating 12 can be covered with the tube body 11 in close contact.

  The coating 12 thus coated is formed on the outer surface of the tube body 11 by a coating forming method such as dipping or two-color molding. In the case of dipping, the tube body 11 is immersed in a bath layer of the material of the coating 12 that is liquefied, and the material of the coating 12 is adhered to the outer peripheral surface of the tube body 11. Then, the pipe body 2 is manufactured by raising the pipe body 11 from the bathtub and drying it. In the case of two-color molding, the material of the tube body 11 previously liquefied is poured into a mold, and after it is solidified, the material of the coating 12 is poured into the mold to form the coating 12 on the outer peripheral surface of the tube body 11. .

  As described above, the coating film 12 formed in this way is formed with a thickness of, for example, 1.0 mm or less, preferably 0.1 mm or more and 0.5 mm or less. By forming the coating film 12 in such a thin range, it is possible to cause the coating film 12 to exhibit the functions described above while suppressing the generation of pinholes in the coating film 12. Furthermore, by reducing the thickness of the coating 12, the amount of material used can be suppressed. In addition, it is preferable that the film 12 is comprised with the material which has translucency, and comes to be able to visually confirm the state of the blood preserve | saved in the coat tube 1 by having translucency. Yes. Note that the coating 12 does not necessarily have translucency, and the coating 12 has a light-shielding property when a specimen that is altered by light is collected or an additive that is altered by light is contained. Also good.

  The tubular body 2 having such a configuration has a bottomed cylindrical shape and is open on one side in the axial direction. That is, the tube body 2 has an opening 2a on one side in the axial direction, and the plug member 3 is fitted to the opening end 2b of the tube body 2 so as to close the opening 2a.

  The plug member 3 is a so-called rubber plug, and is made of, for example, synthetic rubber. The plug member 3 is formed in a substantially columnar shape, and a tip side portion 3 a thereof is fitted to the open end 2 b of the tube body 2. Further, the base end side portion 3b of the plug member 3 projects outward from the opening end portion 2b of the tube body 2, and the base end side portion 3b of the plug member 3 is a flange 3c formed over the entire circumference in the circumferential direction. have. The outer diameter of the flange 3c is formed to be larger than the outer diameter of the tube body 2, and covers the open end 2b of the tube body 2 from one side in the axial direction as shown in FIG. The plug member 3 having such a shape seals the inside of the tube main body 11 and prevents the gas and liquid in the tube main body 11 from being released to the outside by being sealed.

  The coated tube 1 configured as described above is evacuated by the inside of the tube body 11 being decompressed, and blood can be collected by using a holder with a blood collection needle (not shown). That is, the blood collection needle is punctured at the tip of the blood collection needle of the holder with a blood collection needle, and then the base end of the blood collection needle is punctured into the plug member 3 and the coated tube 1 is attached to the holder with the blood collection needle, whereby the blood in the blood vessel is decompressed. It flows into the treated tube body 11. When the appropriate amount of blood is collected, the coated tube 1 is removed from the holder with a blood collection needle. Thereby, the blood collected in the tube body 11 can be stored in a sealed state. The above method is an example of a blood collection method, and the blood collection method is not limited to this method. The coated tube 1 is frozen together with the blood when the collected blood is stored frozen. For example, when the collected blood is used for genetic testing, the coated tube 1 is stored frozen at −70 ° C. or less with blood in consideration of long-term storage. In the coated tube 1, the material of the coated film 12 is selected according to the cold resistance temperature when the coated tube 1 is used. For example, when blood is stored frozen at a temperature of −15 ° C. or lower, when it is medically frozen, or when deeply frozen, the cold resistance temperature of the coated tube 1 so that it can withstand a temperature lower than the expected temperature at the time of storage. Is set, and the material of the coating 12 is selected according to the cold resistance temperature. That is, the cold resistance temperature is set according to the use application (freezing temperature), and a material having a glass transition point lower than the cold resistance temperature is selected as the material of the coating film 12. Thereby, it is suppressed that the viscosity of the film 12 is remarkably lowered (that is, the viscosity is remarkably increased) in the temperature range in which the film tube 1 is cooled.

  In the coated tube 1, when the blood is frozen, the water contained in the blood begins to freeze at 0 ° C. or less, and the blood begins to expand accordingly. When blood is collected, blood is not filled in the entire tube main body 11, and a sufficient space is provided between the blood level and the plug member 3. Therefore, the blood that expands while freezing advances toward the plug member 3 in the tube body 11, that is, the upper side, and the blood on the upper side in the tube body 11 eventually freezes faster than the lower blood. If it does so, expansion | swelling to the upper side of the blood will be suppressed gradually, and the blood which exists in the lower side in the pipe | tube main body 11 will begin to expand | swell to radial direction, freezing.

  The expansion of blood is not uniform in the circumferential direction of the tube main body 11, but occurs around a fragile portion of the tube main body 11. Therefore, the blood expansion occurs locally in the tube body 11, and the tube body 11 is locally deformed in accordance with the blood expansion. As described above, the coating 12 is made of a material having a low glass transition point, that is, a material having a glass transition point below freezing point. Therefore, even when stored frozen, the viscosity does not significantly decrease (viscosity increases significantly), and the coating 12 can be extended in accordance with the deformation of the tube body 11. Accordingly, the expansion of the tube body 11 can be suppressed and the tube body 11 can be prevented from being damaged due to an excessive load. Moreover, since the coating film 12 has stickiness, it can suppress that the coating film 12 is torn with expansion of the tube main body 11. Thereby, after thawing | decompressing blood, it can suppress that the blood leaks outside from the pipe | tube main body 11. FIG. Therefore, the coated tube 1 can be suitably used also when blood is stored frozen.

  On the other hand, the coated tube 1 may not always prevent the tube body 11 from being damaged. That is, in the coated tube 1, blood may swell greatly in the radial direction depending on the method of freezing the blood and the tube body 11 may be locally damaged. Even in that case, the damaged portion of the tube main body 11 is closed while the coating 12 is in close contact with the periphery of the damaged portion of the tube main body 11. Therefore, the damaged portion does not pass to the outside of the coating 12, and even if the blood is thawed after the breakage, the blood can be prevented from leaking from the damaged portion. Therefore, not only blood leaks out from the coated tube 1 but also blood can be suppressed from entering between the tube main body 11 and the coating 12, and blood enters between the tube main body 11 and the coating 12. Therefore, it is possible to prevent the blood volume that can be examined from decreasing. In addition, by preventing blood from leaking from the damaged part, blood leaking from the damaged part of the tube main body 11 is mixed with other specimens, resulting in a mistake in the test result, or an infection caused by blood occurs. Can be further prevented.

  In addition, since the glass transition point of the coating 12 is low and the coating 12 is sticky before and after freezing, the impact transmitted to the tube main body 11 even if impact is applied to the coating 12 by dropping the coated tube 1 or the like. It can be softened by the coating 12. Thereby, it can suppress that the pipe | tube main body 11 is damaged by an impact. Further, since the coating 12 is formed so as to cover the entire lower portion 11b of the tube main body 11, even if blood leaks into the coating 12 from the damaged portion, the blood accumulates in the lower portion 11b. Therefore, even if blood leaks into the coating 12, it can be prevented from leaking outside.

  By the way, in the vacuum blood collection tube of Patent Document 1, it is also conceivable to close the opening of the bottomed tube with a cap before blood collection. However, in the case of a vacuum blood collection tube, it is necessary to puncture a blood collection needle through a needle piercing member, which is a stopper, and therefore it is necessary to remove the cap before blood collection. I can't block the part. That is, in the vacuum blood collection tube of Patent Document 1, it is necessary to close the opening of the bottomed tube with a cap after blood collection and before cryopreservation, and the step of attaching the cap during cryopreservation is an essential work process. Become.

  In contrast, in the coated tube 1, only the outer peripheral surface of the tube main body 11 is covered with the coating 12, so that the blood collection needle can be punctured into the plug member 3 even when the tube main body 11 is coated with the coating 12. it can. In addition, since the coated tube 1 can be frozen and stored simply by coating the outer peripheral surface of the tube body 11 with the coating 12, the coated tube 1 is stored frozen as it is after the blood collection needle is removed from the stopper member 3. can do. Therefore, the step of attaching the cap can be omitted, and the cladding tube 1 can be stored frozen more easily.

  In addition, the cladding tube 1 of this embodiment can be used suitably so that the blood extract | collected as mentioned above may be preserve | saved below below freezing point. However, the cladding tube 1 is not usable only during frozen storage, and can appropriately store collected blood even if it is not below freezing.

<Other embodiments>
The coated tube 1 of the present embodiment is used as a blood collection tube for collecting blood, but the sample to be collected is not limited to blood. The collected sample may be, for example, digestive fluid such as saliva and gastric juice, or secretory fluid such as sweat.

  Further, in the coated tube 1 of the present embodiment, substantially the entire outer peripheral surface of the tube main body 11 is covered with the coating 12, but it is not always necessary to be entirely covered with the coating 12. For example, the portion easily damaged is mainly in the lower half of the tube body 11 in the axial direction, so at least the lower half (up to the bottom portion of the tube body 11 and the intermediate portion in the axial direction of the outer peripheral surface of the tube body 11). ) May be covered by the coating 12. The lower portion 11b of the tube body 11 is formed in a partial spherical shape. Therefore, the lower portion 11b of the tube main body 11 has higher rigidity than the cylindrical portion 11a of the tube main body 11, and is hardly damaged even if the blood freezes and expands. Therefore, the coating 12 does not necessarily need to cover substantially the entire outer peripheral surface of the tube main body 11, and may cover only the intermediate portion in the axial direction on the outer peripheral surface of the tube main body 11. Thereby, similarly to the coated tube 1 of the present embodiment, the expansion of the tube main body 11 due to the expansion of the sample is allowed, and even if the tube main body 11 is damaged, the sample can be prevented from leaking outside.

  Further, the coating 12 does not necessarily cover the tube main body 11 to the vicinity of the opening end portion 11e, and covers only a position lower than the opening end portion 11e of the tube main body 11, for example, the central portion of the cylindrical portion 11a. It may be in the form. Such a coated tube also has the same effects as the coated tube 1 of the present embodiment.

  Furthermore, the lower surface 11c of the tube body 11 does not necessarily have to be recessed around the axis L1, and may be flat or spherical. The method of covering the tube body 11 with the coating 12 is not necessarily limited to dipping or two-color molding. The tube body 11 is coated with the coating 12 manufactured separately from the tube body 11 and then thermally contracted to cover the tube body 11. You may make it closely_contact | adhere.

  Furthermore, the coated tube 1 is subjected to a decompression process and is not limited to a vacuum state, and may be atmospheric pressure.

DESCRIPTION OF SYMBOLS 1 Coated pipe 3 Plug member 11 Pipe body 11c Lower surface 12 Coating

Claims (8)

A coated tube for storing collected specimens,
A tubular body with a bottomed tube to hold the collected specimen;
A coating covering the outer peripheral side surface of the tube body in close contact;
A plug member for sealing the tube body;
The coated tube having a glass transition point below freezing point and lower than a glass transition point of the tube body. The tube body has a glass transition point higher than the cold resistance temperature of the coated tube,
The coated tube according to claim 1, wherein the coating has a glass transition point lower than the cold resistance temperature.   The coated tube according to claim 1 or 2, wherein the glass transition point of the coated film is -15 degrees or less.   The coated tube according to any one of claims 1 to 3, wherein the coated film has translucency. The coated tube according to any one of claims 1 to 3, wherein the coated film has a light shielding property.   The coated tube according to any one of claims 1 to 5, wherein the coating covers the entire bottom of the tube main body. The coated tube according to any one of claims 1 to 6, wherein the coated tube is used for frozen storage. The coated tube according to claim 6, wherein the coating covers at least the entire circumference of the lower half of the outer peripheral side surface portion.