JP7429629B2 - Cryopreservation management system - Google Patents

Description

The present invention relates to a cryopreservation management system .

For example, in medical fields such as infertility treatment and regenerative medicine, and research fields such as new drug development, deterioration of biological samples (hereinafter simply referred to as "specimens") such as sperm, eggs, embryos, blood, and cells is prevented. Therefore, it is common to store them frozen. For cryopreservation, cryopreservation containers containing liquid nitrogen (boiling point -196°C) are widely used because samples can be stored in a stable state for long periods of time.

Further, among cryopreservation containers, there are large-sized (for example, internal volume of 100 L or more) cryopreservation containers (see, for example, Patent Documents 1 and 2 below). Such a large cryopreservation container has an insulated container with an open top and an insulated lid that closes the upper opening of the insulated container. It has a structure that can accommodate multiple storage devices inside. On the other hand, the storage device has a rack structure in which holder sections for holding storage devices containing samples are provided in multiple stages (usually 7 to 11 stages) in the height direction.

Japanese Patent Application Publication No. 2005-143873 Japanese Patent Application Publication No. 2007-271279

By the way, samples stored frozen in the cryopreservation container mentioned above will be damaged if exposed to high temperatures (room temperature) when the storage equipment is taken out and put in the cryopreservation container, so it is necessary to properly manage the storage conditions. There is. For example, the management of samples that are frozen in a cryopreservation container includes the storage temperature in the cryopreservation container (-150°C or lower), the exposure time when the storage device is removed from the cryopreservation container, and the freezing of the storage device. This includes the number of exposures taken out of the storage container.

Among these, the storage temperature in the cryopreservation container can be managed using a temperature sensor or the like. On the other hand, the loading and unloading of samples from cryopreservation containers is performed visually and manually by an operator while referring to data recorded on a notebook, computer, or the like. At this time, the operator needs to record the exposure time, number of exposures, etc. of the storage device mentioned above while taking the sample in and out of the cryopreservation container.

However, since such work cannot be performed automatically, it is difficult to accurately manage the exposure time, number of exposures, etc. of the storage device. Further, the working time required to take the sample in and out of the storage device varies greatly depending on the skill level of the operator and in which stage of the holder section of the storage device the target sample is located. That is, between the upper holder part and the lower holder part of the storage device, there will be a difference in the time required for loading and unloading the sample and the time for exposure to room temperature.

However, in the past, the temperature increase that occurs when samples are taken out and taken out of cryopreservation containers causes great damage to the samples, but the current situation is that this cannot be properly managed. Therefore, there is a need to appropriately manage the storage conditions of samples frozen in cryopreservation containers, including information such as exposure time and number of exposures that have a large effect on damaging such samples.

The present invention was proposed in view of the above-mentioned conventional circumstances, and is a cryopreservation management system that makes it possible to appropriately manage the preservation state of biological samples frozen in cryopreservation containers. The purpose is to provide a

In order to achieve the above object, the present invention provides the following means.
[1] A storage device having a holder portion for holding a storage device containing a biological sample, and the holder portions are provided in multiple stages in the height direction;
It has an insulated container with an open top and an insulated lid that closes the upper opening of the insulated container, and the storage device is placed inside the insulated container while liquid nitrogen is stored in the insulated container. Using a cryopreservation container with a storage space for storing the
A cryopreservation management system that manages the preservation state of a biological sample cryopreserved in the cryopreservation container, comprising:
an identification tag attached to each of the holder parts or each of the storage devices;
an installation tool that is detachably attached around the upper opening of the heat insulating container and that is provided with a reader that reads the identification tag;
The cryopreservation management system is characterized in that the reading device reads the identification tag that passes through the upper opening of the heat-insulating container when the storage device is taken in and taken out from the upper opening of the heat-insulating container.
[2] An information processing device comprising: a storage unit that stores information on the identification tag read by the reading device; and a calculation unit that performs calculation processing based on the information stored in the storage unit;
[1], wherein the information processing device calculates the time or number of times the cryopreservation container is taken out of the cryopreservation container for each holder part or each storage device by the arithmetic processing. Preservation management system.
[3] The cryopreservation management system described in [2] above, wherein the information processing device stores the calculation result of the arithmetic processing in the storage unit or outputs it to the outside.
[4] The identification tag is attached to two diagonally located corners of the four corners of the holder part or the storage device, and
The reading device is located at two corners of the holder portion or the storage device on the opposite side of the periphery of the installation tool from the side where the operator who takes in and takes out the storage device is located across the upper opening of the heat insulating container. The cryopreservation management system according to any one of [1] to [3] above, characterized in that the cryopreservation management system is installed at a position facing the section.
[5] The identification tag is a non-contact IC tag,
The cryopreservation management according to any one of [1] to [4] above, wherein the reading device performs wireless communication with the non-contact IC tag when reading the identification tag. system.
[6] The installation tool according to any one of [1] to [5] above, wherein the installation tool is a protective member that protects the heat insulating container when the storage device is taken in and taken out from the upper opening of the heat insulating container. The cryopreservation management system described in any one of the above .

As described above, according to the present invention, it is possible to provide a cryopreservation management system that makes it possible to appropriately manage the preservation state of a biological sample that is cryopreserved in a cryopreservation container. .

1 is a block diagram showing the configuration of a cryopreservation management system according to an embodiment of the present invention. 2 is a perspective view showing an example of a storage device used in the cryopreservation management system shown in FIG. 1. FIG. 2 is a sectional view showing an example of a cryopreservation container used in the cryopreservation management system shown in FIG. 1. FIG. FIG. 2 is a schematic cross-sectional view for explaining an operation of reading an identification tag by a reading device provided on an installation tool included in the cryopreservation management system shown in FIG. 1. FIG. FIG. 2 is a schematic plan view for explaining an operation of reading an identification tag by a reading device provided on an installation tool included in the cryopreservation management system shown in FIG. 1. FIG. 2 is a process diagram for explaining a cryopreservation management method using the cryopreservation management system shown in FIG. 1. FIG. 2 is a schematic cross-sectional view showing another configuration of the installation tool included in the cryopreservation management system shown in FIG. 1. FIG.

Embodiments of the present invention will be described in detail below with reference to the drawings.
Note that the drawings used in the following explanation may schematically show characteristic parts for convenience in order to make the characteristics easier to understand, and the dimensional ratio of each component may not be the same as the actual one. do not have.

(cryopreservation management system)
First, the configuration of a cryopreservation management system according to an embodiment of the present invention will be described with reference to FIGS. 1 to 5.

Note that FIG. 1 is a block diagram showing the configuration of the cryopreservation management system. FIG. 2 is a perspective view showing an example of a storage device 20 used in the cryopreservation management system. FIG. 3 is a sectional view showing an example of a cryopreservation container 30 used in the cryopreservation management system. FIG. 4 is a schematic cross-sectional view for explaining the operation of reading an identification tag by a reading device provided on an installation tool included in the cryopreservation management system. FIG. 5 is a schematic plan view for explaining the operation of reading an identification tag by a reading device provided on an installation tool included in the cryopreservation management system.

The cryopreservation management system of this embodiment can be used, for example, in medical fields such as infertility treatment and regenerative medicine, and in research fields such as new drug development. In order to prevent deterioration of samples (referred to as "specimens"), the storage conditions of frozen samples are managed.

Specifically, as shown in FIG. 1, this cryopreservation management system uses a storage device 20 for storing samples and a cryopreservation container 30 for cryopreserving the samples.

As shown in FIG. 2, the storage device 20 has a holder portion 21 that holds the storage device 50 containing the sample, and the holder portion 21 has multiple stages (9 in this embodiment) in the vertical direction (height direction). It has a rack structure provided over several stages.

The storage device 50 is made of a metal with excellent thermal conductivity such as aluminum, a metal such as stainless steel with excellent low temperature resistance, or resin, and includes a case body 51 in the shape of a rectangular box with an open top, and a case body. It has a plurality of partition walls 52 that partition the inside of 51 into a grid pattern.

A plurality of storage sections 53 partitioned by a plurality of partition walls 52 are provided inside the case body 51. In the storage device 50, containers containing samples and the like can be stored in the plurality of storage sections 53.

Note that the storage device 50 may have any configuration as long as it can be held in the holder portion 21, and is not limited to the configuration described above, and can be modified as appropriate.

The storage device 20 includes a rack body 22 that constitutes a plurality of holder parts 21. The rack body 22 is made of a metal with excellent thermal conductivity such as aluminum, or a metal with excellent low temperature resistance such as stainless steel, and includes a bottom plate 22a forming the bottom surface thereof, and a top plate 22b forming the top surface thereof. and four pillars 22c forming the side surfaces thereof. The rack body 22 has a generally rectangular parallelepiped shape extending in the vertical direction by joining the bottom plate 22a, the top plate 22b, and the four pillars 22c by welding or the like.

Further, the rack body 22 has a plurality of floor plates 22d joined to four pillars 22c by welding or the like, and divides the inside of the rack body 22 in the vertical direction. As a result, a plurality of holder parts 21 are provided inside the rack main body 22 in a line in the vertical direction. In the storage device 20, the storage device 50 can be held slidably in the front and rear directions with respect to the plurality of holder parts 21.

Further, the rack body 22 is provided with a rod-shaped slide stopper 23 that vertically passes through each holder portion 21 . In the storage device 20, the slide stopper 23 vertically penetrates the storage device 50 held by each holder portion 21, thereby preventing the storage device 50 from falling off from each holder portion 21. On the other hand, in the storage device 20, by pulling out the slide stopper 23 upward, it is possible to slide the storage device 50 held by each holder portion 21 in the front-rear direction.

A handle portion 24 is provided on the top plate 22b. Thereby, the storage device 20 can be taken in and out of the cryopreservation container 30 while grasping the handle portion 24.

Note that the storage device 20 may have a configuration in which the storage device 20 has a holder portion 21 that holds the storage device 50 and the holder portion 21 is provided in multiple stages in the height direction, and is not limited to the above-mentioned configuration. It is possible to make appropriate changes to the configuration without being changed.

As shown in FIG. 3, the cryopreservation container 30 includes a heat insulating container 31 with an open top and a heat insulating lid 32 that closes the top opening 31a of the heat insulating container 31.

The heat insulating container 31 is a double container having a vacuum heat insulating structure in which a heat insulating material 35 is filled between a bottomed cylindrical outer container 33 made of a metal with excellent low temperature resistance such as stainless steel, and an inner container 34. Become.

The upper opening portion 31a is provided with a substantially cylindrical neck portion 36 attached to the upper portion of the heat insulating container 31 so as to penetrate therethrough, and has a circular opening in a plan view. Further, the upper opening 31a (neck portion 36) is provided at a position shifted to one side with the central axis of the heat insulating container 31 interposed therebetween.

Furthermore, a plurality of casters 37 are attached to the lower part of the heat insulating container 31. This allows the cryopreservation container 30 to be moved.

The heat insulating lid 32 has a structure in which a heat insulating material 32b is filled inside a lid body 32a made of a metal with excellent low temperature resistance, such as stainless steel. The heat insulating lid 32 has a substantially cylindrical shape corresponding to the inside of the neck portion 36. Thereby, the heat insulating lid 32 can close the upper opening 31a of the heat insulating container 31 while being fitted into the neck portion 36.

Further, the heat insulating lid 32 is provided with an exhaust port 38 passing through the heat insulating lid 32. An exhaust pipe 38a can be connected to the exhaust port 38 if necessary.

The cryopreservation container 30 includes a mounting tray 39 on which a plurality of storage devices 20 are placed, a rotation support mechanism 40 that supports the mounting tray 39 rotatably around the center line of the heat insulating container 31, and a mounting tray 39. It is provided with a rotation operation mechanism 41 that rotates the.

The loading tray 39 includes a disc-shaped rotary table 39a and a plurality of partition plates 39b rising from the surface of the rotary table 39a. In the mounting tray 39, a plurality of storage devices 20 can be placed on a surface of a rotary table 39a partitioned by a plurality of partition plates 39b.

The rotation support mechanism 40 includes a rotary tube 40a in the form of a cylindrical shaft that is attached to the mounting tray 39 (rotary table 39a) so as to penetrate through the center thereof, and a rotary tube 40a that rises from the center of the bottom surface of the heat insulating container 31. 40a, an upper bearing 40c interposed between the top of the rotating cylinder 40a and the top of the supporting shaft 40b, and a lower side of the rotating cylinder 40a and the supporting shaft 40b. The mounting tray 39 is supported rotatably around the center line of the heat insulating container 31. Note that the lower bearing 40d is provided as necessary as a steady rest bearing, and may be omitted.

The rotation operation mechanism 41 rotates the operation shaft 43, which is connected to the top of the rotary tube 40a and rotatably supported via a seal portion 42 that passes through the upper center of the heat insulating container 31. It has a rotating motor 44 to drive, and a drive transmission mechanism 45 that transmits the driving force from the rotating motor 44 to the operating shaft 43.

Further, the drive transmission mechanism 45 is wound around a drive pulley 45a attached to the rotation shaft 44a of the rotation motor 44, a driven pulley 45b attached to the operating shaft 43, and between the drive pulley 45a and the driven pulley 45b. It has an endless belt 45c.

The rotation operation mechanism 41 is capable of rotating the loading tray 39 while controlling the drive of the rotation motor 44. Note that the drive transmission mechanism 45 is not necessarily limited to the configuration described above, and may have any configuration as long as it can transmit the driving force from the rotary motor 44 to the operating shaft 43.

In the cryopreservation container 30, liquid nitrogen R is stored at the bottom of the insulated container 31. The liquid level (height of the liquid level) of the liquid nitrogen R can be confirmed from outside the heat insulating container 31 using a liquid level gauge (not shown), and is always maintained within a certain range.

In the cryopreservation container 30, an accommodation space K for accommodating a plurality of (60 in this embodiment) storage devices 20 is provided inside the heat insulating container 31. For this reason, in this embodiment, the cryopreservation container 30 in which the internal volume of the insulated container 31 is 1400 L is used.

Each storage device 20 is put in and taken out through the upper opening 31a of the heat insulating container 31, and is placed above the liquid level of the liquid nitrogen R in the heat insulating container 31 while being placed on the surface of the mounting tray 39. Encased in a cryogenic gas phase that forms.

Further, each storage device 20 is provided with a label such as a number on its upper surface (top plate 22b) to distinguish them from each other. On the other hand, in the cryopreservation container 30, each storage device 20 is placed in a designated area divided by the partition plate 39b of the storage tray 39 while rotating the mounting tray 39 according to the mark attached to each storage device 20. It is configured to be placed (accommodated).

The cryopreservation container 30 has an insulated container 31 with an open top and an insulated lid 32 that closes the upper opening 31a of the insulated container 31, so that liquid nitrogen R is stored in the insulated container 31. Any configuration may be used as long as the storage space K is provided inside the heat insulating container 31 to store the storage device 20 in the above-mentioned state, and the configuration is not limited to the above-mentioned configuration, and the configuration may be modified as appropriate. It is possible. Further, the internal volume of the heat insulating container 31 can also be arbitrarily changed depending on the number of storage devices 20 accommodated.

As shown in FIG. 1, FIG. 4, and FIG. It is provided with an installation tool 3 which is removably attached to the holder and is provided with a reader 2 for reading the identification tag 1.

The identification tag 1 is a non-contact IC tag (RFID tag), and the reading device 2 performs wireless communication with this non-contact IC tag when reading the identification tag 1.

The identification tags 1 are attached to the storage device 20 in line with each other in the vertical direction in accordance with the position of each holder portion 21 of the storage device 20. Further, the identification tags 1 are respectively attached to two diagonally located corners (posts 22c) of the four corners (posts 22c) of the holder portion 21.

The installation tool 3 is a protection member called a neck tube guard that protects the neck portion 36 of the heat insulating container 31 from contact with the storage tool 20 when the storage tool 20 is taken in and out from the upper opening 31a of the heat insulating container 31. .

The installation tool 3 includes a cylindrical sleeve portion 3a corresponding to the inside of the neck portion 36, and a disk-shaped flange portion 3b protruding from the upper end of the sleeve portion 3a over the entire circumference in the radial direction. ing. When the storage device 20 is put in or taken out from the upper opening 31a of the heat insulating container 31, the installation tool 3 is configured such that the flange portion 3b comes into contact with the upper end of the upper opening 31a with the sleeve portion 3a inserted inside the neck portion 36. installed in contact with

Note that the installation tool 3 does not necessarily have the function of protecting the neck portion 36 of the heat insulating container 31 from contact with the storage tool 20, etc. It may also be configured to extend along the outside of the neck portion 36.

The reading device 2 is located around the installation tool 3 (the flange portion 3b) on the opposite side (rear side) from the side (front side) where the worker M who puts in and takes out the storage tool 20 is located across the upper opening 31a of the heat insulating container 31. They are respectively attached in positions facing the two corner portions (pillars 22c) of the holder portion 21 on the side).

The reading device 2 reads the identification tag 1 passing through the upper opening 31 a of the heat insulating container 31 when the storage device 20 is taken out or put in or taken out from the upper opening 31 a. As a result, when the storage device 20 is taken out or put in the cryopreservation container 30, it is possible to read the record of the insertion and removal from the cryopreservation container 30 for each holder portion 21 of each storage device 20 from the identification tag 1.

Furthermore, in this embodiment, as shown in FIGS. 5A and 5B, even if the orientation of the storage device 20 that is taken in and taken out from the upper opening 31a of the heat insulating container 31 changes, the One of the identification tags 1 and one of the reading devices 2 are always facing each other.

Thereby, it is possible to appropriately perform the reading operation of the identification tag 1 by the reading device 2 for each holder 21 of each storage device 20. Further, since the reading device 2 is located on the opposite side (back side) to the side (front side) where the worker M is present, it does not get in the way of the worker M when taking samples in and out of the cryopreservation container 30. Furthermore, since the reading device 2 is attached to the installation tool 3 that is detachable from the cryopreservation container 30, the installation tool 3 can be easily attached and detached from other cryopreservation containers 30 for use. It is.

As shown in FIG. 1, the cryopreservation management system of this embodiment includes an information processing device 10 that processes information on the identification tag 1 read by the reading device 2. The information processing device 10 includes a computer (CPU), etc., and includes a storage unit 11 that stores information on the identification tag 1 read by the reading device 2, and performs arithmetic processing based on the information stored in the storage unit 11. It has a calculation section 12.

The information processing device 10 calculates the exposure time and number of exposures taken out of the cryopreservation container 30 for each holder part 21 of each storage device 20 by arithmetic processing from the information of the identification tag 1 read by the reading device 2. Calculate.

Further, the information processing device 10 stores the calculation results (exposure time and number of exposures) by the arithmetic processing in the storage unit 11. Further, the information processing device 10 can output (display) calculation results (exposure time and number of exposures) by the arithmetic processing to the external monitor 13.

(cryopreservation management method)
Next, a cryopreservation management method using the cryopreservation management system shown in FIG. 1 will be described with reference to FIG. 6.
Note that FIG. 6 is a process diagram for explaining the cryopreservation management method.

The cryopreservation management method of this embodiment uses the cryopreservation management system shown in FIG. It is characterized by

Specifically, as shown in FIG. 6, when taking the storage device 20 in and out of the cryopreservation container 30, the reading device 2 first checks whether the storage device 20 is put in or taken out from the cryopreservation container 30 for each holder part 21 of each storage device 20. As a record, after reading the "warehousing time" and "leaving time" of each identification tag 1 from the identification tag 1, the information of the "warehousing time" and "leaving time" of each identification tag 1 is stored in the information processing device 10. The information is stored in the section 11.

Next, in the information processing device 10, the calculation unit 12 performs calculation processing based on the information stored in the storage unit 11, and the storage device 20 is removed from the cryopreservation container 30 for each holder part 21. Calculate "exposure time" and "exposure number".

The exposure time is calculated from the difference between the "warehousing time" and the "warehousing time" (warehousing time - warehousing time). The number of exposures is calculated from the count of "warehousing time" and "warehousing time".

Next, in the information processing device 10, the calculation results (exposure time and number of exposures) obtained by the arithmetic processing are stored in the storage unit 11.

The worker M can check the "exposure time" and "number of exposures" recorded for each holder part 21 of each storage device 20 on the monitor 13 as necessary.

In this embodiment, accurate "exposure" is performed between the upper holder part 21 and the lower holder part 21 of the storage tool 20, reflecting the time required to take the sample (storage tool 50) in and out and the time it is exposed to room temperature. It is possible to record "time" and "number of exposures" for each holder part 21 of each storage device 20.

Therefore, in the cryopreservation management method of the present embodiment, information such as the exposure time and the number of exposures that have a large effect of damaging the sample is appropriately collected for each holder part 21 of each storage device 20 using the cryopreservation management system described above. It is possible to manage.

Note that the present invention is not necessarily limited to the embodiments described above, and various changes can be made without departing from the spirit of the present invention.
For example, the installation tool 3 is not necessarily limited to the neck tube guard described above, and, for example, as in the jig shown in FIG. It is sufficient if it can be freely attached.

Further, in the above embodiment, the identification tag 1 is a non-contact IC tag, and the reading device 2 is configured to read the identification tag 1 by performing wireless communication with the non-contact IC tag. By wireless communication with this non-contact IC tag, the above-mentioned "warehousing time" and "leaving time" information, "exposure time" and "number of exposures" are stored in the storage section of the identification tag 1, It is also possible to read out the information.

Further, in the above embodiment, the identification tag 1 is attached to each holder portion 21 of each storage device 20, but the identification tag 1 may be attached to each storage device 50. In this case as well, it is possible to appropriately manage information such as exposure time and number of exposures that have a large effect of damaging the sample for each storage device 50 of each storage device 20.

Note that for the identification tag 1 and the reading device 2, in addition to the method of performing wireless communication with the non-contact IC tag described above, it is possible to adopt a method that allows the identification tag 1 to be read.

DESCRIPTION OF SYMBOLS 1...Identification tag 2...Reading device 3...Installation tool 10...Information processing device 11...Storage part 12...Calculation part 13...Monitor 20...Storage device 21...Holder part 30...Cryopreservation container 31...Insulating container 31a...Top opening 32...Insulating lid 50...Storage tool

Claims (6)

A storage device having a holder portion for holding a storage device containing a biological sample, the holder portion being provided in multiple stages in the height direction;
It has an insulated container with an open top and an insulated lid that closes the upper opening of the insulated container, and the storage device is placed inside the insulated container while liquid nitrogen is stored in the insulated container. Using a cryopreservation container with a storage space for storing the
A cryopreservation management system that manages the preservation state of a biological sample cryopreserved in the cryopreservation container, comprising:
an identification tag attached to each of the holder parts or each of the storage devices;
an installation tool that is detachably attached around the upper opening of the heat insulating container and that is provided with a reader that reads the identification tag;
The cryopreservation management system is characterized in that the reading device reads the identification tag that passes through the upper opening of the heat-insulating container when the storage device is taken in and taken out from the upper opening of the heat-insulating container. An information processing device comprising: a storage unit that stores information on the identification tag read by the reading device; and an arithmetic unit that performs arithmetic processing based on the information stored in the storage unit;
2. The information processing device calculates the time or number of times the cryopreservation is taken out of the cryopreservation container for each of the holder portions or for each of the storage devices by the arithmetic processing. management system. The cryopreservation management system according to claim 2, wherein the information processing device stores the calculation result of the calculation process in the storage unit or outputs it to the outside. The identification tags are attached to two diagonally located corners of the four corners of the holder part or the storage device, and
The reading device is located at two corners of the holder portion or the storage device on the opposite side of the periphery of the installation tool from the side where the operator who takes in and takes out the storage device is located across the upper opening of the heat insulating container. The cryopreservation management system according to any one of claims 1 to 3, wherein the cryopreservation management system is installed at a position facing the cryopreservation management system. The identification tag is a non-contact IC tag,
The cryopreservation management system according to any one of claims 1 to 4, wherein the reading device performs wireless communication with the non-contact IC tag when reading the identification tag. According to any one of claims 1 to 5, the installation tool is a protection member that protects the heat insulating container when the storage tool is taken in and taken out from an upper opening of the heat insulating container. cryopreservation management system.

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