JP7186957B2 - Cell thawing device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a cell thawing device capable of thawing cells (for example, cultured epidermal cells and cultured fibroblasts) cryopreserved in a cell freezing container.

(refractory skin ulcer)
Intractable skin ulcer refers to a skin condition in which the skin is extensively deficient and sometimes infected. It is said that about 10,000 patients a year have to have their lower limbs amputated due to intractable skin ulcers. necessary.

(Trials of regenerative medicine for intractable skin ulcers)
As an alternative to leg amputation, which has the drawbacks described above, there is also an attempt to apply regenerative medicine to the affected area of an intractable skin ulcer by transplanting cultured epidermal cells to promote self-regeneration. The cultured epidermal cells are placed in a cell-freezing container such as a cryotube and are usually cryopreserved at -80°C to -196°C. In terminal hospitals, these frozen cells are transported and stored in cell-freezing containers, so it is necessary to thaw the frozen cells in the cell-freezing containers during treatment.

(Conventional thawing technique for cryopreserved cultured epidermal cells: water bath)
As a conventional technique for thawing the frozen epidermal cells, there is a method using a water bath. In this method, the water in the bath is heated to lukewarm water of about 37.degree. However, the stirring and thawing operation in the water bath not only requires a high degree of skill, but also poses a risk of water entering the tube.

(Conventional frozen cell thawing device)
In addition to the water bath described above, a frozen cell thawing device as shown in Non-Patent Document 1 is already available. A plurality of bottomed open holes are provided on the upper surface of the thawing device, and the cell containers are placed in these holes and heated. However, the opening hole is made with a predetermined size, and cannot be applied to containers other than a dedicated cell container adapted to this size. There are many hospitals all over the country, and there are many vendors who deliver medical equipment to these hospitals. Perhaps because of this fact, cell containers vary widely in shape, structure, size, and the like, and there is a demand for a cell thawing apparatus that can handle all of these cell containers.

JP-A-58-225019 JP 2007-061245 A JP 2013-252204 A

Catalog No: YS-1 Frozen Cell Thawing Apparatus, BM Equipment Co., Ltd. website, [searched on January 13, 2019], Internet <https://www.bmbio.com/product/tabid73.html?pdid1=YS -1>

(Defrosting equipment in other fields)
Looking to fields other than frozen cells, devices for thawing frozen plasma bags have been proposed so far (see Patent Documents 1 to 3).

(Difference between freezing container for frozen plasma and freezing container for frozen cells)
Frozen plasma bags are limited to bag-shaped containers, but containers for frozen cells have various shapes such as plate-shaped and tube-shaped in addition to bag-shaped, and all of these container shapes There is a demand for a thawing device that can handle

(Difference between storage temperature of frozen plasma and storage temperature of frozen cells)
In addition, frozen plasma is usually stored at −20° C., whereas cells are stored at −80° C. to −196° C. Therefore, thawing frozen cells requires more heat than frozen plasma. In addition, since it contains cells, it is also necessary to thaw within a short time of 3 minutes.

(Defrosting device of Patent Document 1)
As described above, Patent Documents 1 to 3 all deal with thawing "frozen plasma". The thawing apparatus of Patent Document 1 presses a pair of movable heater plates close to each other to heat a bag-like container containing frozen blood, and at the same time heats the frozen blood by a driving mechanism including a motor. A heater plate is rotated to promote convection in the frozen blood.

(Clamping body of Patent Document 1)
The thawing object of Patent Document 1 is a bag-like container (specifically, a plastic bag) in which frozen blood or the like is stored. In other words, the object to be thawed is flexible, and the object itself to be thawed can be deformed when sandwiched between the pair of heaters. Therefore, the sandwiching part on the heater side may be a simple rigid body (plate-shaped copper sheet). It deforms according to the shape of the sheet.

(Problem when trying to apply the device of Patent Document 1 to the use of the present invention)
However, in the case of frozen cells, the cell freezing container has a wide variety of shapes. For example, in the case of a tube-shaped container, the container itself does not deform, so it is necessary to deform the holding part on the heater side to hold the container. be. Therefore, even if the device of Patent Document 1 were simply applied to the field of frozen cells as it is, it would not be possible to properly thaw containers in which these cells were stored (for example, the rigid cylindrical containers described above).

(Defrosting device of Patent Document 2)
Similarly, Patent Document 2 also discloses a thawing device in which a blood bag containing frozen plasma is sandwiched and heated by a pair of heaters and rocked by a rocking means. In Patent Document 2, it is the first and second heat medium bags in which the flowable heat medium is sealed that come into direct contact with the object to be thawed.

(Problem when trying to apply the device of Patent Document 2 to the use of the present invention)
Although the first and second heat medium bags are flexible, there is no problem if the object to be thawed (the object to be clamped) is a deformable blood bag. Or, if the cell freezing container is flat and has sharp edges, there remains a concern that the heat medium bag may burst during use or the high-temperature heat medium inside the bag may scatter.

Further, the rocking mechanism disclosed in Patent Document 2 moves one end of the clamping part up and down, that is, rocks the one end and the other end of the clamping part like a seesaw. Thawing is fine, but in the experience of the present inventors, when assuming the thawing of frozen cells that require the application of a high amount of heat in a very short time, this rocking method is insufficient, and the rocking mechanism should also be improved. There is a need. In other words, the apparatus of Patent Document 2 cannot be applied to thawing frozen cells simply with its configuration.

(Defrosting device of Patent Document 3)
Patent Document 3 is also a device for thawing frozen plasma contained in a deformable bag-like container, and a pair of thawing plates sandwiching this is a hard plate-like body made of an aluminum plate or a copper plate. It is the same as document 1. Further, the rocking mechanism is the same as that of Patent Document 2 in that it rocks the holding portion up and down like a seesaw. Therefore, even when the apparatus of Patent Document 3 is applied to thawing frozen cells, the above problems described in the columns of Patent Documents 1 and 2 are concerned.

(Problems common to Patent Documents 1 to 3)
In addition, as can be said for any of the thawing devices of Patent Documents 1 to 3, the clamping portion that clamps and heats the freezing container becomes dirty and unhygienic as the number of times of use increases. In particular, it is necessary not only to replace the contact part), but also to inspect and replace the heater and the like in the holding part. However, it cannot be said that the devices disclosed in Patent Documents 1 to 3 have a structure that facilitates such maintenance.

In addition, since any of the thawing devices of Patent Documents 1 to 3 is intended for a relatively large blood bag containing frozen plasma, it is usually intended to pinch and thaw one blood bag in one use. However, the cell freezing container containing frozen cells targeted by the present invention is usually much smaller than a blood bag, and it is desired that a large number of cell freezing containers can be thawed in one use. When clamping and thawing a large number of containers at once, it is desirable to be able to individually manage the thermal environment such as heating conditions for each cell freezing container. There is room for further improvement in these needs and applications.

(Object of the present invention)
The present invention has been made in view of such circumstances, so that anyone can easily obtain cells (more specifically, cultured epidermal cells) cryopreserved in a container even in terminal hospitals that are not specialized hospitals. An object of the present invention is to provide a cell thawing device capable of thawing.

Another object of the present invention is to provide a cell thawing apparatus that can be used with cell freezing containers of various shapes and that facilitates maintenance of the thawing section that frequently contacts the container.

Another object of the present invention is to provide a cell thawing apparatus capable of sandwiching a large number of cell freezing containers at once and individually managing the thermal environment of each cell freezing container.

After intensive studies, the present inventors have found that the above problems can be solved admirably by using a cell thawing apparatus having the following structure, and completed the present invention.

That is, the present invention has, for example, the following configurations and features.
(Aspect 1)
A cell thawing device for thawing frozen cells stored in a cell freezing container,
an upper housing, a lower housing, a hinge section connecting the upper housing and the lower housing so that they can be opened and closed, and the cell freezing provided inside the upper housing and the lower housing. a thawing section provided with a pair of thawing surfaces capable of sandwiching a container and a planar heater capable of heating the thawing surfaces;
a base portion provided with a top plate on which the thawing portion can be placed, and a swing means capable of swinging the top plate;
and
The thawing surface can wrap a plurality of the cell freezing containers while deforming, and can be thawed even if the cell freezing container has a different shape or size ,
Each of the upper housing and the lower housing accommodates a laminated member containing at least a heat conductive rubber layer or a heat storage gel layer and the planar heater in order of proximity to the thawing surface,
The heat conductive rubber layer or the heat storage gel layer has deformability,
The planar heater is a flexible film heater or a flexible rubber heater,
A frame capable of holding the laminated member is detachably attached to the upper housing and the lower housing.
A cell thawing device characterized by:
(Aspect 2)
The cell thawing device according to aspect 1, wherein the thawing surface is covered with a plastic film.
(Aspect 3)
The cell thawing device according to aspect 1 or 2, wherein the thawing unit is detachably attached to the top plate.
(Aspect 4)
The cell thawing device according to any one of aspects 1 to 3 , wherein a plurality of the planar heaters are arranged so as to divide the thawing surface.
(Aspect 5)
The cell thawing device according to any one of aspects 1 to 4 , wherein the rocking means rocks the top plate so as to draw a circle in a plan view of the top plate.
(Aspect 6)
Aspects 1 to 3, wherein the base further comprises a memory pre-stored with a plurality of thawing modes suitable for different types of frozen cells, and control means capable of selecting one of the thawing modes. 6. The cell thawing device according to any one of 5 .
(Aspect 7)
The cell thawing device according to any one of aspects 1 to 6 , wherein cultured epidermal cells or cultured fibroblasts are used as the frozen cells.
(Aspect 8)
The cell thawing device according to any one of aspects 1 to 7 , wherein the cell freezing container is a rigid container that does not have deformability.

(1. Compatible with various cell freezing containers in shape and size)
According to the thawing device of the present invention, unlike the conventional thawing device, it has a soft heating surface (and a deformable heat conductive rubber layer, heat storage gel, film heater, etc.) that is close to this, so that the shape and shape can be changed. It can be heated in such a way as to envelop cell freezing containers of various sizes. This heating surface can be adapted to various types of cell freezing containers by changing the housing size of the thawing section, the type, size, number of layers, and combination of heat conductive rubber layers, heaters, and the like.

The thawing section is detachable from the base section, and the upper and lower housings of the thawing section are provided with frames for detachably holding the laminated members in these housings. This not only facilitates the maintenance of the thawing section, but also enables the replacement of the thawing section with a different thawing section having various wide and narrow thawing surfaces.

In addition, by applying shaking and vibration suitable for the shape and size of the cell freezing container during heating, cells (cells that progress from a frozen state to a solid-liquid state and then a liquid state) can be obtained regardless of the shape of the cell freezing container. can be uniformly stirred and the heat can be uniformly transferred to the cells.

(2. Capable of thawing various types of cells)
Moreover, since the thawing apparatus of the present invention has control means for controlling the heating conditions and the shaking conditions, the operator can freely change the setting of the thawing conditions each time so as to suit the thawing target.

(3. It is possible to unzip multiple files at once)
The heating surface provided in the thawing section is a wide and flexible flat surface due to the presence of a heat-conducting rubber layer and a film heater that include or are adjacent to this surface. can be placed in place. As a result, the apparatus of the present invention can uniformly thaw a large number of frozen cells at one time, and can be used for transplantation operations that require a large amount of cells over a wide area.

(4. Anyone can easily decompress)
The thawing method using the thawing apparatus of the present invention does not require the skilled operating skills required for conventional methods using water baths. The operator can simply use the operation panel or the like to select or input the thawing conditions suitable for the thawing target to operate the apparatus.

(5. Prevention of foreign matter contamination)
The thawing method using the thawing apparatus of the present invention does not require warm bathing of the cell freezing container, which is essential for the water bath method, and the possibility of contamination by foreign matter is remarkably reduced. All parts that touch the cell freezing container are replaceable (replaceable), so cells can be thawed in a clean environment at all times.

It is the perspective view and exploded perspective view which showed the cell thawing apparatus of this invention. It is the front view and side view which showed the cell thawing apparatus (separation state) of this invention. FIG. 3 is an exploded perspective view of the thawing section showing main constituent members of the thawing section; FIG. 3 shows a temperature sensor attached to one or more heaters and layers of insulation. It is the figure which showed the basic composition of the apparatus of a base part. 4A and 4B are a plan view and a bottom view showing the main part of the base part; FIG. FIG. 4 is a side view showing the main parts of the base; FIG. 10 is a diagram showing a modified example of the cell freezing container and the frame to be thawed. 4 is an image showing the appearance of the decompression unit of the operation panel of the decompression device.

Hereinafter, the present invention will be described based on the following specific embodiments with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

(Apparatus overview)
A cell thawing device (hereinafter also simply referred to as “thawing device” or “apparatus”) 100 of this embodiment mainly comprises a thawing section (clamping section) 200 and a base section 300 . The thawing section 200 can be detachably mounted on the upper portion of the base section 300, as will be described later. FIG. 1(b) shows a state in which the decompression unit 200 and the base unit 300 are separated, and FIG. plate), and a plurality of cell freezing containers 1 ( 1 A) are arranged on one thawing surface 250 of the thawing unit 200 .

(to be decompressed)
An object to be thawed by the device 100 of the present invention is a container 1 (hereinafter also referred to as "cell freezing container" or "container") for storing, transporting or preserving frozen cells. Although the frozen cells stored in the container 1 are assumed to be cultured skin cells such as fibroblasts and epidermal cells in this embodiment, they are not necessarily limited to these cells.

(Specific example of cell freezing container)
There are various types of containers 1 for frozen cells having various shapes and sizes. Specific examples of the cell freezing container 1 include, for example, a rigid hollow cylindrical container 1B such as a cryotube as shown in FIGS. There is 1A. As will be described later, the thawing apparatus 100 of the present invention can clamp and heat various containers 1 in various shapes and capacities. It can be said that it is suitable for the purpose of thawing of In the thawing device 100, as will be described later, the thawing surface 250 and the laminated members in the vicinity thereof are deformable. becomes possible.

(outline of decompression part)
As shown in FIGS. 1 to 3, the thawing section 200 has a pair of upper housing 210 and lower housing 220, and a hinge section 230 connecting these housings so that they can be opened and closed. In addition, the defrosting unit 200 is provided with a locking mechanism that keeps the upper housing 210 and the lower housing 220 in contact with each other and in a closed state. In an embodiment, two first locking members 241 are juxtaposed at the front edge of the upper housing 210 and correspondingly two second locking members 242 are juxtaposed at the front edge of the lower housing 220. ing. The first locking member 241 is provided with a wedge-shaped protrusion 243 extending downward, and the second locking member 242 is provided with a locking hole 244 facing upward, so that the upper housing 210 and the lower housing 220 are separated. When the wedge-shaped protrusion 243 enters the locking hole 244 during contact, the wedge-shaped protrusion 243 is engaged by an engaging member (not shown) to temporarily hold and fix the wedge-shaped protrusion 243 .

(upper housing)
In the upper housing 210, layered members having substantially the same size (approximately A5 size in the embodiment) are housed inside in a stacked state. In the example shown in FIG. 3, in order from the upper housing 210, a heat insulating material layer 211, a heat conductive rubber layer 212, a planar heater (preferably a film heater as shown or a rubber heater not shown (for example, silicon rubber) A heater )) 213 and a heat-conducting rubber layer 214 are laminated, and these members 211 to 214 are integrally held inside the upper housing 210 by a frame 215 having an opening 216 . Therefore, most of the lower surface of the heat-conducting rubber layer 214, which is the bottom layer (that is, the upper thawing surface 250) is exposed through the opening 216, and contacts and presses the cell freezing container 1, which will be described later, from above.

Note that the heat-conducting rubber layer 212 is not essential and may be omitted. In other words, only the heat-conducting rubber layer 214 may be provided on the upper housing 210 . For convenience of explanation, FIG. 3 omits the above-described lock mechanism and hinge portion 230 .

(lower housing)
On the other hand, the lower housing 220 also accommodates layered members having substantially the same dimensions in a stacked state. In this embodiment, a heat insulating material layer 221 , a film heater 222 , a thermally conductive rubber layer 223 , a film heater 224 , and a thermally conductive rubber layer 225 are laminated in order from the lower housing 220 and have an opening 227 . It is integrally held inside the lower housing 220 by a frame 226 . Therefore, most of the upper surface of the heat-conducting rubber layer 225 as the uppermost layer (that is, the lower thawing surface 250) is exposed from the opening 227, and contacts and presses the cell freezing container 1 described below from below.

In this example, a plurality (two) of the film heaters 222 and 224 were prepared in order to increase the amount of heat applied to the cell freezing container 1 per unit time. The number of heaters can be increased or decreased according to the cell freezing container 1 . For example, like the upper housing 210, only one heater 224 may be provided.

(frame body detachable from housing)
The frame 215 and the frame 226 are preferably detachably attached to the upper housing 210 and the lower housing 220 by known connection means such as screws S (see FIG. 2(a)). . As a result, part or all of the laminated members such as the heaters 213, 222, 224 and the heat conductive rubber layers 212, 214, 223, 225 can be easily removed for replacement or cleaning.

(Modified example of frame)
Note that the opening 216 (227) of the frame 215 (226) shown in FIG. , but not limited to. For example, as shown in FIGS. 8(c) and (d), a frame 215A (226A) provided with a plurality of openings 216A (227A) corresponding to the outer shape of the cell freezing container 1A, or the outer shape of the cell freezing container 1B. A frame 215B (226B) having a plurality of corresponding openings 216B (227B) may be prepared and used.

In this way, by using the openings 216A (227A), 216B (227B) and the like that match the shape and dimensions of the object to be thawed (the cell freezing container 1), the cell freezing containers 1A, 1B can be , 215B (226B), the container 1A, 1B can be held in an appropriate place more reliably, and an unforeseen situation such as the container 1A, 1B accidentally falling from the defrosting section 200 during the opening/closing operation of the defrosting section 200 or the defrosting process can be prevented. can be reduced significantly. Also, there is no risk of the containers 1A (1B) coming into contact with each other during defrosting. In addition, since the cell freezing container 1A (1B) does not move when the thawing unit 200 is closed, each container 1A (1B) and the film heater (for example, each opening 216A (227A) of the split heater) , 216B (227B)), the temperature of the thawing surface 250 can be monitored and warmed more appropriately.

Even if the shape and dimensions of the container 1 are new, it is possible to quickly meet the customer's request by manufacturing the modified frames 215A (226A) and 215B (226B) with a 3D printer or the like. can.

(Thermal conductive rubber layer)
The heat-conducting rubber layers 212, 214, 223, and 225 provided on the upper housing 210 and the lower housing 220 are characterized by having deformability, and preferably have a slight shape memory property. As a result, no matter what kind of cell freezing container 1 is placed, these layers flexibly deform to conform to the shape of the container, envelop them, and keep the temperature in the layers more stable and constant. become. A part or all of the heat-conducting rubber layers 212, 214, 223, 225 may be replaced with a heat storage gel layer.

(Thawed surface)
The upper and lower thawing surfaces 250 with which the cell freezing container 1 contacts are the inner surfaces of the heat-conducting rubber layers 214 and 225 in the example shown in FIG. , which may be the thawing surface 250 (see FIG. 9(c)). As a result, when the thawing surface 250 becomes dirty after using the device 1 several times, it is sufficient to replace it with a new one, so it is possible to reduce the cost and time required for cleaning or replacing the thawing surface 250.例文帳に追加.

(Film heater)
For the film heaters 213, 222, 224 described above, for example, an etched metal foil (for example, stainless steel foil) sandwiched between polyimide or polyester films can be used. Since the film heater is extremely thin (usually about 0.1 mm to 0.3 mm in thickness), it can be deformed according to the deformation of the adjacent heat-conducting rubber layer. A flexible rubber heater (not shown) may be used.

(temperature sensor)
Temperature sensors such as thermistors 241 (15 in the illustrated example) and thermocouples 242 are provided on the upper and lower surfaces of the heaters 213 and 224 as shown in FIG. Such temperature sensors 241 and 242 transmit signals to the control means 320 in the base portion 300 through electric wires. For more accurate temperature monitoring, a plurality of (for example, 8 to 20) temperature sensors are used to measure the temperature of each film heater, the average temperature is calculated by the control means 320, and the average temperature is calculated. You may use it as a representative temperature of the heater.

In addition to the temperature sensor 241, a temperature sensor for preventing overheating and a safety device may be provided separately. For example, as shown in FIG. 4A, the heaters 213 and 224 are provided with thermocouples 242 (two in the illustrated example) and thermal fuses 243 as temperature sensors and safety devices for overheating prevention. On the other hand, as shown in FIG. 4B, a thermocouple 242 is provided on the heat insulating material layer 211 (221).

(Split heating of thawing surface by attaching multiple heaters)
Also, the film heaters 213, 222, 224 may be attached so as to cover all the thawing surfaces 250 with one heater, but as shown in FIG. A plurality of relatively small heaters (that is, divided heaters) 260 (16 in the illustrated example) and temperature sensors (in the illustrated example, thermoelectric 242) may be juxtaposed. Although it is not necessary to limit the number of divisions of the divided heater 260, if the defrosting surface 250 is of A5 size as described above, up to about 16 divisions (the number of heaters is 16) would be realistic.

Also in this case, a thermocouple 242 may be provided in the heat insulating material layer 211 (221) as a temperature sensor for preventing overheating. Note that the thermal fuse 243, which is difficult to mount on the surface including the split heater 260, may be installed on the heat insulating material layer 211 (221).

(Merit 1 of split heating)
By using a plurality of small film-like heaters (hereinafter also referred to as “split heaters”) 260 attached so as to divide the thawing surface 250 and the temperature sensor 242, a plurality of cell freezing containers 1 can be used to thaw cells. When the device 100 simultaneously pinches and defrosts, the heat quantity can be applied while pinpointing the temperature of each container 1, so that the temperature of each container 1 can be controlled.

(Merit 2 of split heating)
In addition, when a plurality of divided heaters 260 and temperature sensors 242 are installed, it is possible to uniformly heat the entire thawing surface 250 compared to when a single heater is installed. It is also possible to thaw under substantially the same temperature conditions no matter where the object to be thawed (the cell freezing container 1) is placed.

(Merit 3 of split heating)
In addition, when the number of cell freezing containers 1 to be thawed at one time by this thawing apparatus 100 is small, there may be areas where heating is unnecessary on any thawing surface 250 . For example, the left and right sides of thawing surface 250 may not be needed, and only the central region may require heating. In this embodiment of divided heating, power consumption and energy can be saved by suppressing the power supply only to the divided heaters 260 placed in areas where heating is not required (for example, left and right areas).

(Advantage 4 of split heating)
In addition, by dividing the surface including the heater as shown in FIG. As a result, packaging of these containers 1 becomes easier.

Since the deformable thermal conductive rubber layers 212, 214, 223, 225 and the film heaters 213, 222, 224 include the thawing surface 250 or are provided in the vicinity of the thawing surface 250, for example, they are different from each other. Even when a plurality of shaped cell freezing containers 1 are sandwiched at the same time, it is possible to heat (thaw) them by sandwiching them without gaps.

(base part)
Next, the base portion 300 will be described in detail. The base portion 300 includes a base portion housing 301 , legs 302 supporting the base portion housing 301 , and a top plate 340 , as shown in FIG. 1 and the like. A vibration isolation pad is preferably installed on the leg portion 302 to suppress transmission of vibration generated in the base portion 300 to an external structure (not shown). In addition, FIG. 1B shows the internal structure of the base portion 300 with broken lines for reference.

(Basic composition of the base part)
FIG. 5 is a diagram conceptually explaining the basic configuration of the base section 300. As shown in FIG. The base housing 301 includes a swinging means 310 capable of driving the defrosting section 200, a swinging means for controlling the swinging operation, acquiring and processing temperature signals from a temperature sensor, and setting, changing, and saving defrosting conditions. Control means 320 for and power supply means 330 capable of supplying power to these means 310, 320 are provided.

As shown in FIG. 1, a main power switch 350 and an operation panel 360 are provided on the outer surface of the base housing 301 to display/input the heating conditions and swing conditions of the heater. A buzzer 380 is also attached to emit a warning sound, a start sound, an end sound, and the like.

Also, although not shown, instead of the function of the buzzer 380 or together with the function of the buzzer 380, the control means 320 sends a signal regarding the end of defrosting or an abnormal stop to the mobile terminal of the operator (medical worker such as a nurse). Functions may be added.

(Connection between base part and thawing part)
As shown in FIGS. 1B and 2, the upper surface 341 of the top plate 340 is provided with a connection hole 342 capable of accommodating the protrusion 220p provided on the lower surface 220b of the lower housing 220. As shown in FIG. As a result, the thawing section 200 including the lower housing 220 can be attached to and detached from the top plate 340 positioned above the base section 300 . In addition, if thawing units having different sizes (not shown, for example, having a thawing surface of A4 or B5 size) are prepared, an appropriate size suitable for the size and number of containers 1 to be thawed can be used. It can be replaced with a thawing portion of the appropriate size and placed on the base portion 300 . In the drawings such as FIG. 224, etc.) are omitted.

The internal structure of the base housing 301 will be described with reference to FIGS. 6 and 7. FIG. For convenience of explanation, FIG. 7 shows a side surface of the base portion 300 after removing the base portion housing 301 and the top plate 340 .

(Power supply means)
A power supply inlet 331 and a control/motor power supply 332 are provided in the base housing 301 as constituent members of the power supply means 330 . The control/motor power supply 332 converts the voltage of AC 100V obtained at the power inlet 331 into a voltage of DC 24V and supplies power to the motor 311 .

(Specific configuration of rocking means)
Further, as constituent members of the rocking means 310, a motor 311, a speed increasing gear group 312, an eccentric shaft 313, a top plate 340 and the like are provided. In addition to the motor driver 321, an operation monitor board 322, a control board 323, and the like are provided as components of the control means 320. FIG. The operation monitor board 322 and the control board 323 also play a role of setting, monitoring and controlling the thawing temperature.

In addition to the above components, a control board relay 324, a heater relay 325, a power fuse 326, and the like are also installed to form an electric circuit.

(Oscillation of thawing section by oscillation means)
The motor 311 is powered by a control/motor power supply 332 and becomes operable, and the rotational operation such as the number of revolutions is controlled by a motor driver 321 and a control board 323 . The motor 311 meshes with the gears (312a) of the speed increasing gear group 312 provided on the lower side of the base housing 301, and the power of the motor 311 is applied to the gears 312a, 312b, 312c, 312d sequentially. A gear 312 d that is farthest from the motor 311 in terms of gear transmission is connected to the eccentric shaft 313 . An upper portion of the eccentric shaft 313 is connected to the top plate 340 .

With the above configuration, when the motor 311 rotates, the gears 312a to 312d of the speed increasing gear group 312 also rotate while increasing the rotational speed. Since the center of rotation of the final gear 312d of the speed increasing gear group 312 and the eccentric shaft 313 are deviated from each other by several millimeters (1 to 10 mm, for example 5 mm), when the speed increasing gear group 312 rotates, the eccentric shaft 313 and the top plate 340 are driven, that is, rocked while being eccentric by 5 mm. In other words, in a plan view, the top plate 340 moves so as to draw a circle whose radius of rotation is the distance (deviation) caused by the eccentricity. Alternatively, as shown in FIG. 6A, the eccentric shaft 313 may be connected to the top plate 340 via a connecting plate 343. As shown in FIG.

In addition, as shown in FIGS. 6 and 7, the swing means 310 may be provided with a plurality of eccentric shafts 313 and 314 . Specifically, a second eccentric shaft (following side) 314 is also provided parallel to and separated from the first eccentric shaft (driving side) 313 , and the first eccentric shaft 313 and the second eccentric shaft 314 are separated from each other. are connected by transmission belts and gears (not shown). By providing a plurality of eccentric shafts 313 and 314 in this way, even if the weight of the defrosting section 200 is increased, the defrosting section 200 can be reliably swung without any trouble.

In addition to the swinging means 310 described above, a second swinging means (for example, a vibration motor (not shown)) may be installed on the top plate 340 or the like. As a result, not only the rotational movement (100 to 1,000 rpm) in the plane direction by the oscillating means 310, but also the microscopic vibration (for example, about 2,000 to 3,000 rpm) in the vertical direction by the second oscillating means vibration) can also be applied to the top plate 340 and the defrosting section 200 .

The control means 320 can set optimum parameters for realizing the rocking motion according to the shape and quantity (capacity) of the cell freezing container 1 . In addition to the number of oscillations, the control means 320 controls the heating temperature (eg, room temperature to 70° C.), the standby temperature (eg, room temperature to 70° C.), the rate of temperature rise from the lowest temperature (eg, 0 to 100 %), temperature upper limit from the lowest temperature (e.g. room temperature to 70°C), temperature raising program parameters such as thawing time (e.g. 1 to 10 minutes), and other safety related parameters (e.g. overheating prevention temperature) can.

In addition, the control means 320 can store in the memory 327 (see FIG. 5) in advance up to a plurality (for example, three types) of thawing conditions obtained by combining the above parameters according to the shape and type of the cell freezing container 1 . In addition, it is also possible to display the temperature information sequentially acquired from the temperature sensor on a display unit such as the display 366 (see FIG. 9A), compare it with safety parameters, or store it in the memory 327. .

(control panel)
The operation panel 360 shown in FIG. 9A is provided with switches such as a mode switch 361, a start switch 362, a set switch 363, an enter switch 364, and an up/down switch 365, as well as a display 366, a mode indicator lamp 367, An operating status indicator light 368 (standby indicator light, run indicator light, error indicator light, etc.) is provided.

(Various switches on the operation panel)
The mode switch 361 can select a desired mode from a plurality of preset thawing conditions (thawing modes). The defrosting mode that has been finally determined can be confirmed by the lighting state of any of the mode indicator lamps 367 . The start switch 362 can select, for example, starting or stopping operation. The set switch 363 can display/switch parameters, for example, to change the settings of various parameters that make up the thawing conditions. The enter switch 364, for example, confirms the setting change of the parameters described above. The up/down switch 365, for example, inputs/changes parameter setting values.

(Selection and setting of defrosting mode on the operation panel)
In the thawing device 100 of the embodiment, up to three types (three modes) of thawing conditions according to the type of cell freezing container 1 or cells can be stored in advance in the memory 327, but the number of modes is not limited to this example, and the number of modes can be increased or decreased. may Since the operator only has to select the defrosting mode suitable for the defrosting target from among these preset defrosting modes, it takes little time and effort to change the setting for each defrosting target. When thawing a thawing object that is not suitable for the preset mode (for example, a new type of cell or a cell freezing container with a new shape), set switch 363, enter switch 364, up/down switch 365, etc. are used to thaw a new You may change the setting to defrost mode.

(How to use the thawing device)
Next, an example of how to use the decompression device 100 described above will be described.
(1) Connect the power inlet 331 to a power outlet (100 V AC, not shown), and turn on the main power switch 350 .
(2) Depressing the mode switch 361 on the operation panel 360 selects the thawing conditions according to the thawing target from 3 types of thawing modes.
(3) Preheating is started, and when the set temperature is reached, the buzzer 380 and the operation status indicator lamp 368 announce that the thawing is possible.
(4) Clean the thawing surface 250 with ethanol or the like, and set the cell freezing container 1 on the thawing surface 250 .
(5) The upper housing 210 of the defrosting section 200 is brought closer to the lower housing 220 to close and lock the defrosting space.
(6) Depress the start switch 362;
(7) When defrosting is completed, buzzer 380 and operating status indicator light 368 notify the completion of defrosting.
(8) Unlock the thawing unit 200, lift the upper housing 210 to gently open the thawing space, and take out the cell freezing container 1.
(9) After taking out the cell freezing container 1, if the operation status indicator lamp 368 indicating the thawing possible state is lit, perform the above (4) to (8) for another (remaining) cell freezing container 1. Repeat process. If the light is off, the process starts from the above step (3).
(10) When all the cell freezing containers 1 have been thawed, be sure to turn off the main power switch 350 and unplug the power supply.

(Maintenance after use of thawing equipment)
After using the defrosting device 100, if the defrosting surface 250 is dirty, clean it with disinfecting ethanol or the like. If the thawing surface 250 is severely damaged, the vinyl sheet 251, the heat conductive rubber layers 212, 214, 223, 225 and the upper and lower frames 215, 226 constituting the thawing surface 250 are replaced with new ones. For safety, always turn off the main power switch 350 and unplug the power supply when performing this maintenance.

(Verification test)
Using the thawing apparatus 100 of the present invention, an experiment (demonstration test) was conducted in which frozen cells were actually thawed and the viability of the cells was measured. In addition, as a comparative example, the cells were thawed by a warm bath using a water bath, and the viability of the cells was also measured.

(Cell culture and measurement of cell viability during culture)
The test cells of this example were cultured according to the following method. That is, 3T3-J2 cells were cultured to 80% confluence according to a standard method, and after collecting the cells, they were suspended in a cell preservation medium (10% BS, 10% DMSO, 80% DME medium), and the viability was measured by automatic fluorescence. Measurement was performed using a cell counter LUNA-FL (Logos Bio).

(Cryopreservation of cells)
2 ml each of cells suspended in a cell preservation solution was placed in a cell freezing container (flat container) 1A (manufactured by JMS) or a cell freezing container (cylindrical container, cryotube) 1B (manufactured by Biologics #88). -3202) and cryopreserved in liquid nitrogen according to the standard method.

(Thawing of cells and measurement of viable cell rate)
Cells stored in liquid nitrogen for a certain period of time were thawed using a water bath at 37°C (comparative example) or using the thawing device 100 of the present invention, and the viability of the cells was measured using the automatic fluorescent cell counter. .

(Measurement result)
Table 1 shows the measurement results of the cell viability under each test condition. In the thawing apparatus of the present invention, since an optimum heating program can be set for the frozen cells to be thawed, the cells can be thawed in an optimum state. As a result, the survival rate of the cells was remarkably increased compared to the conventional hot bath method (comparative example). In addition, although containers 1A and 1B having different shapes and sizes were used as cell freezing containers, the thawing device of the present invention has a higher cell viability after thawing regardless of which shape of container 1A or 1B is used. was found to be able to be maintained at a high level.

(Evaluation of cell culture and cell proliferation ability after thawing)
Next, the cells cryopreserved in the cylindrical cell freezing container 1B as described above are thawed using the thawing apparatus 100 of the present invention, and one-fifth of the thawed cells are thawed in a petri dish (10 cm diameter). The cells were cultured for a week, and the number of cell divisions was counted at the end of the culture to evaluate the proliferation ability.

(Evaluation results)
Table 1 shows the observation results of the number of cell divisions under each test condition. In the thawing apparatus of the present invention, since an optimum heating program can be set for the frozen cells to be thawed, the cells can be thawed in an optimum state. Therefore, compared with the conventional warm bath method (comparative example), it was found that the cells after thawing are allowed to survive while maintaining a higher cell proliferation ability.

As described above, if the cell thawing apparatus of the present invention is used, cells cryopreserved in a cell freezing container (more specifically, cultured fibroblasts and cultured epidermal cells) can be used even in terminal hospitals that are not specialized hospitals. ) can be easily decompressed by anyone.

In addition, the cell thawing apparatus of the present invention is compatible with cell freezing containers of various shapes, and maintenance of the constituent members (eg, thawing surface) of the thawing section that frequently come into contact with the cell freezing container is easy.

In addition, the cell thawing apparatus of the present invention can provide a cell thawing apparatus that can clamp a large number of cell freezing containers at once and can set and manage the thermal environment for each cell freezing container.

In this way, the present invention not only supports cooperation between hospitals using frozen cells in the field of regenerative medicine, but also contributes to the establishment and spread of cultured cell transplantation as a therapeutic method to replace conventional lower limb amputation. There is no doubt that the industrial utility value is very high.

Reference Signs List 1, 1A, 1B cell freezing container 100 cell thawing device 200 thawing unit 210 upper housing 211 heat insulating material layer 212, 214 heat conductive rubber layer 213 planar heater (film heater)
215 frame 220 lower housing 221 heat insulating material layer 222, 224 planar heater (film heater)
223, 225 Thermal conductive rubber layer 226 Frame body 230 Hinge part 241, 242, 243 Temperature sensor (thermistor, thermocouple, thermal fuse)
250 thawing surface 251 plastic film (vinyl sheet)
260 Split heater 300 Base part 301 Base part housing 302 Leg part of base part 310 Swing means 320 Control means 330 Power supply means 340 Top plate 350 Main power switch 360 Operation panel

Claims (8)

A cell thawing device for thawing frozen cells stored in a cell freezing container,
an upper housing, a lower housing, a hinge section connecting the upper housing and the lower housing so that they can be opened and closed, and the cell freezing provided inside the upper housing and the lower housing. a thawing unit provided with a pair of thawing surfaces capable of sandwiching a container and a planar heater capable of heating the thawing surfaces;
a base portion provided with a top plate on which the thawing portion can be placed, and a swing means capable of swinging the top plate;
and
The thawing surface can wrap a plurality of the cell freezing containers while deforming, and can be thawed even if the cell freezing container has a different shape or size.the law of nature,
The upper housing and the lower housing each accommodate a laminated member containing at least a heat conductive rubber layer or a heat storage gel layer and the planar heater in order of proximity to the thawing surface,
The heat conductive rubber layer or the heat storage gel layer has deformability,
The planar heater is a flexible film heater or a flexible rubber heater,
A frame capable of holding the laminated member is detachably attached to the upper housing and the lower housing.
A cell thawing device characterized by: The cell thawing device according to claim 1, wherein the thawing surface is covered with a plastic film. The cell thawing device according to claim 1 or 2, wherein the thawing unit is detachably attached to the top plate. The cell thawing device according to any one of claims 1 to 3 , wherein a plurality of said planar heaters are arranged so as to divide said thawing surface. The cell thawing device according to any one of claims 1 to 4 , wherein the rocking means rocks the top plate so as to draw a circle in a plan view of the top plate. 2. The base part further comprises a memory pre-stored with a plurality of thawing modes suitable for different types of frozen cells, and a control means capable of selecting one of the thawing modes. 6. The cell thawing device according to any one of 1 to 5 . The cell thawing device according to any one of claims 1 to 6, wherein cultured epidermal cells or cultured fibroblasts are used as the frozen cells. The cell thawing device according to any one of claims 1 to 7 , wherein the cell freezing container is a rigid container that does not have deformability.

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