JP2019146534A - Cell culture method using gelatin supporting medium - Google Patents

Abstract

SOLUTION: A plurality of cell aggregation masses 2 are supported on a crosslinked gelatin sheet 14 (gelatin supporting medium), and the cell aggregation masses 2 are immersed in a culture fluid for culturing together with the gelatin sheet 14. A space is formed on the crosslinked gelatin sheet 14 and the culture fluid is taken into the space. Thus, the culture fluid is supplied through the space to the cell aggregation masses supported on the gelatin sheet 14, thereby fusing adjacent cell aggregation masses 2 to produce a fusion pad 4.EFFECT: Aggregation masses can be supported efficiently without being held by a pin.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a cell culture method using a gelatin support, and in particular, a gelatin support for culturing a plurality of cell aggregates while supporting them by a gelatin support to produce an aggregate structure of cells fused together. The present invention relates to a cell culture method using

Conventionally, a method of creating a three-dimensional structure of a cell having a required shape by culturing by contacting cell aggregates (spheroids) in which cells are cultured in a substantially spherical shape in advance, and fusing the cell aggregates together Is known (Patent Documents 1 and 2).
In Patent Document 1, cell aggregates are passed through a large number of pins erected, and in Patent Document 2, the cell aggregates are inserted into a plurality of pins erected, so that each cell aggregate is shaped into a required shape. Cell aggregates are fused by aligning and culturing in that state.

Japanese Patent No. 4517125 JP 2017-79719 A

However, in the above Patent Documents 1 and 2, the work for penetrating the cell aggregate into the pin and the work for inserting the cell aggregate between the pin and the pin require high precision and take a lot of time. There was a problem.
Further, in the above method, since the pins holding the cell aggregates are dense, the circulation of the culture solution between the pins is stagnant, and among the aligned cell aggregates, the cell aggregates arranged in the central part There was a problem that culture failure was likely to occur.
Furthermore, the three-dimensional structure of the cells obtained by the above method has a problem that a through hole is formed by a pin that holds the above-mentioned cell aggregate, so that an operation for processing this through hole is required separately. there were.
In view of such a problem, the present invention provides a cell culture method using a gelatin support capable of easily fusing cell aggregates without being held by the pins.

  That is, in the cell culture method using the gelatin support according to the invention of claim 1, a plurality of cell aggregates are supported on a crosslinked gelatin support, and the cell aggregates are immersed in a culture solution together with the gelatin support. Then, adjacent cell aggregates are fused together by culturing.

According to the above invention, since the cell aggregates may be supported by the gelatin support without being held by the pins, high-precision operations are not required, and the cell aggregates can be aligned more quickly. Moreover, a through-hole is not formed in the obtained three-dimensional structure of a cell.
Furthermore, since a space is formed in the cross-linked gelatin support and the culture solution can be taken into the space, the culture solution is passed through the space with respect to the cell aggregates supported by the gelatin support. Thus, it is possible to supply the culture solution satisfactorily to all the supported cell aggregates.

Configuration diagram of the creation device in this embodiment Diagram showing the inside of the isolator Enlarged view of the container Diagram explaining the inside of the culture vessel Perspective view of gelatin sheet and cell aggregate Cross section of mold for making gelatin sheet Diagram showing the inside of the incubator The figure explaining the supply process in 2nd Example The figure explaining the supply process in 3rd Example

The illustrated embodiment will be described below. FIGS. 1 to 7 illustrate the production apparatus 1 used for the cell culture method using the gelatin support according to the first embodiment. (Spheroid: see FIG. 3) are aligned inside the culture vessel 3, and the cell aggregate 2 is cultured to produce a fusion pad 4 (see FIG. 7) as an aggregate structure of cells joined together. It has become.
The cell aggregate 2 can be prepared by a method disclosed in Japanese Patent No. 4517125, for example. That is, when cells are seeded and cultured in a container having an inner surface that is non-adhesive, the cells aggregate to form a cell aggregate 2 by adhering to each other in search of a scaffold, and these are further fused to form a substantially spherical shape. Cell aggregates 2 are formed.
More efficiently, the cell aggregate 2 can be easily obtained by culturing in a non-adhesive well (substantially hemispherical accommodating portion) of the well plate. In addition, the preparation method of the cell aggregate 2 is not limited to this, and a swirl culture method in which the cell suspension is put into the swirling culture solution, or a method in which the cell suspension is put in a test tube and precipitated with a centrifuge Alternatively, it can be prepared by various known methods such as a culture method using alginate beads.
As described above, the cell aggregate 2 becomes a substantially spherical cell aggregate having an outer diameter of about 100 to 500 μm in which cells are aggregated and aggregated, and the cell aggregate 2 is planarly or three-dimensionally formed. When placed in contact or in close proximity, the cells of each cell aggregate 2 proliferate or combine to fuse with the adjacent cell aggregate 2 to obtain a planar or three-dimensional aggregate structure of cells. .
The fusion pad 4 produced in the present embodiment is obtained by arranging a plurality of cell aggregates 2 in a plane and fusing them. The thickness can be made about 100 to 500 μm depending on the size of the cell aggregate 2 to be used, and the planar size can be adjusted by the number of cell aggregates 2 to be aligned.
The fusion pad 4 thus produced is different from a cell sheet obtained by culturing a cell suspension in a planar form by culturing a cell suspension in a planar manner.

The cell assembly structure creating apparatus 1 of this embodiment is provided inside an isolator 5 whose interior is maintained in a sterile state and an incubator 6 provided so as to be connectable to the isolator 5 shown in FIG. Yes. In addition, the isolator 5 is provided with a pass box 5a for decontaminating the incoming material.
FIG. 2 shows a configuration provided inside the isolator 5, and a container supporting unit 8 that supports the container 7 that stores the cell aggregate 2 and a culture that supports the culture container 3 in which the fusion pad 4 is cultured. A container support 9; a plurality of suction nozzles 10 for holding the cell agglomerates 2; and nozzle moving means 11 for moving the suction nozzles 10 relative to the storage container 7 and the culture container 3. Yes.
On the other hand, FIG. 7 shows a configuration provided in the incubator 6 and includes a culture solution supply means 12 for supplying a culture solution to the cell aggregate 2 or the fusion pad 4 of the culture vessel 3.
In the following description, the horizontal direction shown in FIG. 2 is the X direction, the front-rear direction is the Y direction, and the vertical direction is the Z direction.

The interior of the isolator 5 is maintained in a sterile environment, and a one-way flow is generated by aseptic air from above to below by the sterile air supply means.
In addition, a glove 5b that can be worn by an operator is provided in front of the isolator 5, so that various operations can be performed. It is also possible to provide a robot or a transfer means having a required configuration inside the isolator 5 so that these operations are automatically performed.
Next, the inside of the incubator 6 is maintained in a sterile environment and is maintained at a predetermined temperature and humidity suitable for culturing the fusion pad 4, and the cell aggregate 2 is fused to form the fusion pad 4. During this time, the incubator 6 can be separated from the isolator 5 and placed at a location away from the isolator 5.
For this reason, the isolator 5 and the incubator 6 are connected by the connecting means 13, and for example, as described in Japanese Patent No. 4656485, a connecting means for contacting and separating the incubator 6 and the isolator 5 while maintaining sterility. 13 can be used.

FIG. 3 shows a cross-sectional view of the container 7, and the well plate described above can be used. The storage container 7 includes a plurality of storage recesses 7a vertically and horizontally in a plan view, and each of the storage recesses 7a stores a substantially spherical cell aggregate 2 together with a culture solution one by one.
The storage recesses 7a of the storage container 7 are arranged in a predetermined number in the X direction and the Y direction in plan view. In this embodiment, the X of the cell aggregate 2 constituting the fusion pad 4 produced in the culture container 3 is used. The number is the same as the number in the direction and the Y direction, that is, five in the X direction and five in the Y direction.

The storage container support portion 8 that supports the storage container 7 is configured by a Y-direction table 8a that constitutes the nozzle moving means 11 while positioning the storage container 7 on its upper surface by a positioning piece 8b.
As will be described later, five suction nozzles 10 of the present embodiment are provided in the X direction, and are movable only in the X direction and the Z direction. Therefore, the Y direction table 8a moves the container 7 in the Y direction. The suction nozzle 10 and the container 7 can be relatively moved in each direction of XYZ.
Specifically, the Y-direction table 8a first positions the first row of storage recesses 7a of the storage container 7 below the suction nozzle 10, and the suction nozzle 10 aggregates cells from the first row of storage recesses 7a. When the lump 2 is sucked and held, the Y-direction table 8a moves the storage container 7 in the Y direction by one row, and the second row of storage recesses 7a is positioned below the suction nozzle 10.

As shown in FIG. 4, the culture vessel 3 has a bottomed box shape, and a culture solution is accommodated therein at a predetermined depth, and the gelatin support for supporting the cell aggregate 2 is contained in the culture solution. A gelatin sheet 14 as a body is accommodated, and the gelatin sheet 14 is supported in a state of being positioned on a support member 15 provided on the bottom surface of the culture vessel 3.
Further, the gelatin sheet 14 is formed in a substantially square plate shape as shown in FIG. 5, and is solidified in a dry state by crosslinking in the production process as described in detail later. Many fine spaces are formed.
The gelatin sheet 14 has a plurality of through holes 14a as holding portions. When the cell aggregate 2 is placed at the position of the through hole 14a, the lower part of the cell aggregate 2 is fitted into the through hole 14a. At the same time, movement is prevented.
The through-holes 14a are arranged according to the shape of the fusion pad 4 to be created, and the interval between the adjacent through-holes 14a is such that the cell aggregates 2 placed in the respective through-holes 14a are in contact with each other or as close as possible. The interval is set as follows.
The through hole 14a can have any shape and may be circular, but it is desirable to adopt a shape such as a quadrangle or a triangle. By adopting such a shape, a gap is formed between the placed cell aggregate 2 and the opening edge of the through hole 14a, and a fresh culture solution is supplied to the cell aggregate 2 through the gap. It becomes possible to do.
Further, in this embodiment, a second gelatin sheet 14 is placed on the upper part of the cell aggregate 2 placed and aligned on the gelatin sheet 14 so as to prevent the movement of the cell aggregate 2. The second gelatin sheet 14 is also formed with a through hole 14 a in accordance with the position of the cell aggregate 2.
In this embodiment, the gelatin sheet 14 on which the cell aggregate 2 is placed and the second gelatin sheet 14 placed on the top of the cell aggregate 2 have the same shape. Alternatively, a gelatin sheet 14 having different shapes on the upper and lower sides may be used.

The method for producing the gelatin sheet 14 will be described. A dissolving step in which raw gelatin is dissolved in a liquid to form a gelatin solution, a forming step in which the gelatin solution is formed as a gelatin formed product of a predetermined shape, and the gelatin formed product And a cross-linking step of preparing a gelatin cross-linked body, and these steps are performed in an aseptic environment.
In the above-described dissolution step, various types of gelatin that can be dissolved in a liquid, such as powder, granules, particles, solids, gels, and gels, can be used as raw material gelatin, and this can be used as pure water, physiological saline, water for injection, etc. Dissolve in the solvent.
In the forming step, first, the gelatin solution is poured into a mold 101 as shown in FIG. 6, and at this time, a holding portion forming portion 101a corresponding to the through hole 14a is formed inside the die 101. Thus, the through hole 14a can be formed in the resulting gelatin formed product.
Here, in order to form the through hole 14a in the gelatin sheet 14, the level of the gelatin solution is shown by the dotted line in FIG. 6, that is, the holding part forming portion 101a protrudes above the liquid level. You can do it.
Further, the holding portion does not need to be a through hole, and may be a recess or a recess that does not penetrate as long as the cell aggregate 2 can be held and its position can be regulated. In order to form a holding part composed of such depressions and depressions, the level of the gelatin solution may be made higher than that of the holding part forming part 101a.

Subsequently, the mold 101 into which the gelatin solution is injected is put into a freeze dryer, the gelatin solution is gelated by cooling, and further, the mold 101 is dried at a low temperature while reducing the pressure inside the freeze dryer. A plate-like gelatin formed product having the through holes 14a formed therein is formed.
Subsequently, in the cross-linking step, the plate-like gelatin formed product is placed in a vacuum oven and heated while reducing the pressure to cross-link the gelatin formed product by heat, and the gelatin sheet 14 as a gelatin cross-linked product is obtained. Can be obtained.
In this crosslinking step, the rate at which the gelatin sheet 14 dissolves in the culture solution can be controlled by changing the heating temperature and the heating time. For example, the speed at which the gelatin sheet 14 dissolves can be set in accordance with the timing at which the adjacent cell aggregate 2 and the cell aggregate 2 are fused.
In the above crosslinking step, instead of heating in a vacuum oven under reduced pressure, a method of heating in an inert gas may be used. In addition, radiation crosslinking with gamma rays or electron beams, or chemicals using a chemical agent may be used. Crosslinking may be employed.

The support member 15 provided in the culture vessel 3 supports, for example, the four corners of the gelatin sheet 14 from below, and the gelatin sheet 14 so that the suction nozzle 10 can place the cell aggregate 2 in the through hole 14a. Is held at a predetermined position.
By supporting the gelatin sheet 14 at a position above the bottom surface of the culture vessel 3 by the support member 15, a space through which the culture solution flows is secured below the gelatin sheet 14.
Further, the support member 15 may be configured so that the lower surface side of the gelatin sheet 14 can be brought into contact with the culture solution as much as possible. For example, a net-like net is provided on the upper part of the support member 15 provided at the four corners, and the net is formed on the net. The gelatin sheet 14 may be placed.

  As shown in FIG. 2, the culture vessel support 9 is constituted by a Y-direction table 9 a that constitutes the nozzle moving means 11, and is adsorbed by the suction nozzle 10 in the same manner as the Y-direction table 8 a that constitutes the storage vessel support 8. Each time the retained cell aggregate 2 is placed in the through hole 14a of the gelatin sheet 14, the through hole 14a is moved in a row in the Y direction along with the culture vessel 3.

Next, the suction nozzle 10 will be described. As shown in FIG. 3, a main body portion 10a connected to a negative pressure generating means (not shown) and a tubular suction portion 10b provided at the lower end portion of the main body portion 10a. I have.
Further, as shown in FIG. 2, five suction nozzles 10 according to the present embodiment are arranged in the X direction, and the intervals of these suction nozzles 10 can be changed by the interval changing means 16 in the X direction. Yes.
The inner diameter of the adsorbing portion 10b is smaller than that of the cell aggregate 2 and when the cell aggregate 2 is adsorbed and held at the tip of the adsorbing portion 10b in the accommodating recess 7a of the accommodating container 7, the cell aggregate 2 The suction portion 10b is not sucked into the interior.
In the culture vessel 3, the center position of the adsorption part 10b is positioned in the through hole 14a of the gelatin sheet 14, and the negative pressure by the negative pressure generating means is eliminated, so that the cell aggregate 2 is transferred to the gelatin sheet 14. It is supposed to be placed.
The interval changing means 16 changes the suction nozzle 10 to the same interval as the accommodating recess 7 a of the accommodating container 7 or the same interval as the through hole 14 a formed in the gelatin sheet 14.
In addition, it is sufficient that at least one suction nozzle 10 is provided, and as a means for supplying the cell aggregate 2, in addition to the configuration for transferring the cell aggregate 2 as in this embodiment, a number of cell aggregates are provided. The configuration may be such that one by one is delivered from the container containing the lump 2.
Further, instead of the suction nozzle 10 for adsorbing and holding the cell aggregate 2, the cell aggregate 2 may be held by using a configuration such as holding the cell aggregate 2 with a gripper or the like.

The nozzle moving means 11 for moving the suction nozzle 10 includes an X-direction rail 21 provided in the X direction over the storage container support 8 and the culture container support 9, and the suction nozzle 10 along the X-direction rail 21. X-direction moving means 22 for moving the suction nozzle 10 in the X-direction, Z-direction moving means 23 provided in the X-direction moving means 22 for raising and lowering the suction nozzle 10 in the Z-direction, the storage container support 8 and the culture container support 9 and the Y direction tables 8a and 9a.
The nozzle moving means 11 may be configured to move the X-direction rail 21 in the Y direction instead of the Y-direction tables 8a and 9a. By setting it as such a structure, the said suction nozzle 10 and the camera 24 mentioned later can be moved to a XY direction.
The X-direction rail 21 is provided with a camera 24 that moves in the X direction. When the cell aggregate 2 is placed on the gelatin sheet 14 by the suction nozzle 10, the camera 24 supports the culture vessel support 9. The gelatin sheet 14 in the culture container 3 is photographed.
It is confirmed from the photographed image whether or not the cell aggregate 2 is placed in all the through holes 14a, and if necessary, cells are inserted into the through holes 14a where the cell aggregate 2 is not placed. It can be instructed to supply the agglomerate 2.
When the nozzle moving means 11 positions the suction nozzle 10 above the culture vessel support 9, the camera 24 is configured to retract from above the culture vessel support 9 in order to avoid contact with the suction nozzle 10. It has become.

FIG. 7 shows a culture solution supply means 12 that is provided inside the incubator 6 and supplies the culture solution to the fusion pad 4 in the middle of culture. When a plurality of culture vessels 3 are accommodated inside the incubator 6, The culture solution supply means 12 can be provided for each of the culture vessels 3.
The culture medium supply means 12 is composed of a liquid supply pump 31 for supplying a culture liquid and pipes 31 a and 31 b connected to the liquid supply pump 31.
The liquid feeding pump 31 sucks the culture solution from the upper side in the culture vessel 3 through the pipe 31 a and causes the culture solution to flow into the culture vessel 3 through the pipe 31 b to circulate the culture solution in the culture vessel 3. It has become.
In addition, as a pretreatment for the supply operation of these culture solutions, supplementation of nutrients of the culture solution, supply of oxygen or carbon dioxide, and pH adjustment may be performed as necessary.

Hereinafter, a method for creating the fusion pad 4 using the cell assembly structure creating apparatus 1 having the above-described configuration will be described.
First, the container 7, the culture container 3, and the gelatin sheet 14 in which the cell clumps 2 are accommodated through the pass box 5 a are carried into the isolator 5 and other preparations necessary for the culture operation are made. A preparatory process is performed.
In the preparation step, a predetermined amount of the culture solution is stored in the culture vessel 3 and the gelatin sheet 14 is installed on the support member 15. At this time, the culture solution stored in the culture vessel 3 is the culture solution. It is desirable that the depth from the liquid surface to the upper surface of the gelatin sheet 14 is as shallow as possible, for example, about one cell aggregate 2.
Further, in the preparation step, if a plurality of the storage containers 7 and the culture containers 3 are carried into the isolator 5, a plurality of fusion pads 4 can be continuously formed using the plurality of culture containers 3.

When the preparation step is completed, a supply step of placing and aligning the cell aggregate 2 on the gelatin sheet 14 accommodated in the culture vessel 3 is performed using the suction nozzle 10.
First, the nozzle moving means 11 moves the suction nozzle 10, and the interval changing means 16 changes the interval of the suction nozzle 10, so that the suction nozzle 10 is moved from the accommodating recess 7 a of the accommodating container 7 in the accommodating container support 8. The cell aggregate 2 is adsorbed and held.
Subsequently, the nozzle moving means 11 moves the suction nozzle 10 to the culture vessel support 9, and the interval changing means 16 changes the interval of the suction nozzle 10 according to the interval of the through holes 14 a of the gelatin sheet 14, and suction The nozzle 10 is lowered.
Then, each cell aggregate 2 held by the suction nozzle 10 is placed in the through hole 14a of the gelatin sheet 14, and the movement of the cell aggregate 2 is regulated by the through hole 14a. It will be aligned in the required shape.
In the drawings, for the sake of explanation, the cell aggregates 2 are arranged in squares of 5 in the vertical and horizontal directions. For example, when a gelatin sheet 14 having dimensions of 2 cm in length and width is used, the cell aggregates 2 are several tens in length and width. It is possible to arrange ˜100 and tens of each.

Here, as shown in FIG. 4, the depth from the liquid level of the culture solution to the upper surface of the gelatin sheet 14 is about one cell aggregate lump 2 so that the cell aggregate placed on the gelatin sheet 14 is The entire lump 2 is immediately immersed in the culture solution to prevent the cell aggregate lump 2 from being dried.
In addition, by reducing the depth to the liquid surface as much as possible, when the cell aggregate 2 is placed on the upper surface of the gelatin sheet 14, the movement of the cell aggregate 2 already placed on the gelatin sheet 14 is prevented as much as possible. can do.
When the cell aggregate 2 is placed in all the through holes 14a in this way, the camera 24 then moves above the culture vessel support 9 to photograph the cell aggregate 2 in the culture vessel 3, It is confirmed whether the cell aggregate 2 is accommodated in all the through holes 14a.

Further, in the supplying step, after the cell aggregate 2 is aligned on the gelatin sheet 14, the second gelatin sheet 14 is placed on the aligned cell aggregate 2 to prevent the movement of the cell aggregate 2. It is supposed to be.
Since the gelatin sheet 14 is also provided with a through hole 14a in accordance with the position of the cell aggregate 2, the gelatin sheet 14 is placed on top of the aligned cell aggregate 2 so that the through hole is formed. 14a fits in the upper part of the cell aggregate 2 so that the movement of the cell aggregate 2 is prevented.
After the gelatin sheet 14 is placed on top of the cell aggregate 2, the culture solution is then added to the culture vessel 3, and the culture solution is filled above the aligned cell aggregate 2. A sufficient amount of culture solution is accommodated.

When the cell aggregate 2 is placed in the culture vessel 3 by the supplying step, the culture vessel 3 is transferred to the incubator 6 by a robot or an operator's manual operation, and the cell aggregate 2 in the culture vessel 3 is removed. A culture process for culturing is performed.
First, when the culture vessel 3 is transferred to the incubator 6, pipings 31a and 31b of the culture solution supply means 12 are installed inside the culture vessel 3 as shown in FIG. 7, and the circulation of the culture solution is started.
Thereafter, the incubator 6 is separated from the isolator 5 and placed at a position separated from the isolator 5 to maintain the inside at a predetermined temperature and humidity, and maintain a predetermined concentration of carbon dioxide and oxygen.
As a result, the cell aggregate 2 is cultured in the culture container 3, and the cell aggregate 2 is fused with each other while maintaining the shape in which the cell aggregate 2 is arranged in a plane, thereby obtaining the fusion pad 4 as a cell aggregate structure. Can do.
That is, it is possible to create a fusion pad 4 having an arbitrary shape as the cell aggregate 2 is arranged, and the cell aggregate 2 is aligned without gaps by the through holes 14 a formed in the gelatin sheet 14. Therefore, the thickness of the fusion pad 4 is substantially uniform.

In this culturing step, in the present embodiment, the cell aggregate 2 can be favorably cultured by placing the cell aggregate 2 on the upper surface of the gelatin sheet 14 and aligning them.
That is, in addition to the culture medium flowing through the formed through-holes 14a, the gelatin sheet 14 has a minute space formed therein by cross-linking, so that the culture solution flows into the space, and the space It is possible to supply the culture solution to the cell aggregate 2 in contact with the gelatin sheet 14 via
Here, when the thickness of the gelatin sheet 14 is reduced, the culture solution flowing through the culture vessel 3 by the culture solution supply means 12 passes through the space of the gelatin sheet 14 and the thickness of the gelatin sheet 14 is increased. For example, the culture solution can be supplied to the cell aggregate 2 by taking the culture solution into the space formed in the gelatin sheet 14.
Thus, by taking the culture solution into the space of the gelatin sheet 14, the culture solution can be supplied also to the cell aggregate 2 arranged in the central portion among the aligned cell aggregates 2, The fusion pad 4 can be obtained reliably.
And when the said culture process is started and the said cell aggregate 2 is cultured, as shown in FIG. 7, although the said gelatin sheet 14 will melt | dissolve gradually, the bridge | crosslinking process at the time of creating the said gelatin sheet 14 at this time By adjusting the degree of cross-linking in step 2, the gelatin sheet 14 can be extinguished in accordance with the timing at which the adjacent cell aggregate 2 and the cell aggregate 2 are joined.
Further, since the gelatin sheet 14 is manufactured under aseptic conditions, even if the components of the gelatin sheet 14 remain in the fusion pad 4 obtained, it can be safely used.

When the cell agglomerate 2 is cultured and the fusion pad 4 is created by the culture step, a recovery step of connecting the incubator 6 to the isolator 5 and collecting the fusion pad 4 from the culture vessel 3 is performed.
In the collection process, since the gelatin sheet 14 in the culture container 3 is dissolved and disappears, only the fusion pad 4 can be easily taken out from the culture container 3, and the required container can be obtained by a robot or an operator. It can be transferred to and collected.
In addition, between the culture | cultivation process and collection | recovery processes, the incubator 6 is connected to the isolator 5 for every predetermined period, the test | inspection process which test | inspects the culture | cultivation state of the fusion pad 4 in the middle of culture | cultivation, and culture medium exchange which replaces | exchanges a culture medium You may make it perform a process.

According to the said Example, when accommodating the cell aggregate 2 in the culture container 3, work can be efficiently performed by supporting the cell aggregate 2 with the gelatin sheet 14.
That is, since the culture is performed without using a pin as in Patent Documents 1 and 2, high-precision work such as inserting the cell aggregate 2 into the pin or inserting the cell aggregate 2 between the pins. Is unnecessary, and the operation of accommodating the cell aggregate 2 can be speeded up.
In the culturing step, since the culture solution can be supplied from the space formed in the gelatin sheet 14 in contact with the cell aggregate 2 in addition to the through hole 14a through which the culture fluid flows, the aligned cell aggregates The culture solution can be supplied satisfactorily with respect to the whole of 2.
Further, in Patent Documents 1 and 2, through holes are formed by the above pins in the obtained fusion pad 4 and it is necessary to carry out culture again until the through holes are blocked. However, the fusion pad 4 obtained in this example is used. In such a case, such a through hole is not formed, and the fusion pad 4 can be recovered immediately.

FIG. 8 is a diagram for explaining a supplying step of supplying the cell aggregate 3 to the culture vessel 3 in the cell culture method according to the second embodiment. In the first embodiment, a sheet-shaped fusion pad 4 is created. In contrast, in this embodiment, a method of creating a thicker three-dimensional structure of a cell will be described.
In addition, since the same thing as the said 1st Example can be used for the cell aggregate 2 and the gelatin sheet | seat 14 used in a present Example, detailed description is abbreviate | omitted.
Also in the accommodation step in the present embodiment, the cell aggregate 2 is first placed in the through hole 14a formed in the gelatin sheet 14 and thereafter the upper portion of the aligned cell aggregate 2 as in the first embodiment. A second gelatin sheet 14 is placed.
In this embodiment, the cell aggregate 2 is placed and aligned on the upper part of the placed gelatin sheet 14. Again, the cell aggregate 2 is placed in the through hole 14 a of the gelatin sheet 14. , The cell aggregate 2 can be aligned in a required arrangement.
Thereafter, a third gelatin sheet 14 is further placed on the top of the placed second-stage cell aggregate 2 to prevent the cell aggregate 2 from moving, and after that, in accordance with the required three-dimensional structure. In addition, the multilayered cell aggregate 2 and the gelatin sheet 14 may be alternately laminated.

When the culture vessel 3 in which the cell aggregate 2 is accommodated in this manner is then transferred to the incubator 6 and subjected to the culture process, the gelatin sheet 14 is dissolved and the cell aggregate 2 is separated between the cell aggregate 2 and the cell aggregate 2. Since the provided gelatin sheet 14 disappears, the upper and lower cell aggregates 2 can be joined to obtain a three-dimensional structure of cells having a desired shape.
Also in this case, the second gelatin sheet 14 is interposed between the cell aggregates 2 to be laminated, thereby preventing the movement of the cell aggregates 2 in each stage, and also due to the space formed in the gelatin sheet 14. The culture solution can be supplied to the cell aggregates 2 positioned above and below, and the upper and lower cell aggregates 2 can be joined well.
In this example, in order to satisfactorily join the upper and lower cell aggregates 2, the gelatin sheet 14 provided between the cell aggregates 2 and 2 is provided with a through hole 14a as a holding portion, It is desirable to set the thickness to be thin.
By doing in this way, it becomes possible to contact or approach the lower cell aggregate 2 and the upper cell aggregate 2 through the through hole 14a, and the cell aggregates 2 can be easily joined together. Is possible.

FIG. 9 shows a gelatin culturing body 114 as a gelatin support to be used and a supplying step of supplying the cell aggregate 3 to the culture container 3 containing the gelatin casing body 114 in the cell culture method according to the third embodiment. It is a figure to explain.
Also in this example, as in the first example, the work of placing the cell aggregate 2 on the gelatin container 114 accommodated in the culture container 3 in the isolator 5 was performed, and then the whole culture container 3 was aligned. The cell aggregate 2 is transferred to the incubator 6 to perform the culture process.
However, in this embodiment, the supplying step is performed manually by the operator without using the suction nozzle 10 and the nozzle moving means 11 for moving the suction nozzle 10 as in the first embodiment. .
Except as described in detail below, the instrument used in the first embodiment can be used, and the process itself is substantially the same, so detailed description thereof will be omitted.

The gelatin container 114 used in this embodiment has a configuration in which a frame portion 114b is formed on the outer periphery of the gelatin sheet 14 used in the first embodiment, and a through hole serving as a holding portion is formed by the frame portion 114b. The cell aggregate 2 held at 114a is prevented from falling off.
Specifically, the gelatin container 114 is formed with through holes 114a as holding parts for holding the cell aggregate 2 in a state of being aligned vertically and horizontally, and the cell aggregates are formed so as to surround the through holes 114a. The frame portion 114b is formed at substantially the same height as the lump 2.
The gelatin container 114 of this embodiment can also be produced by the method for manufacturing the gelatin sheet used in the first embodiment, and the shape corresponding to the frame portion 114b is formed on the mold 101 used in the above-described forming process. By forming the above, the frame portion 114b and the through hole 114a can be formed simultaneously.

In this embodiment, in the preparation step of preparing the culture vessel 3 and the like in the isolator 5, it is not necessary to supply the cell aggregate 2 to the isolator 5 in a state of being accommodated in the accommodation vessel 7, as shown in FIG. Thus, a plurality of cell aggregates 2 can be supplied in a state of being accommodated in a cylindrical container 111.
The vessel 111 contains the culture solution together with the cell agglomerate 2 and is carried into the isolator 5 with a lid attached to the vessel 111 (not shown). In 5a, the outside of the container 111 is sterilized.
In the preparation step, when the gelatin container 114 is accommodated in the culture container 3, it is not necessary to supply a culture solution to the culture container 3. Although the culture solution may be supplied to the culture vessel 3, in that case, it is desirable to set the liquid level so that the gelatin container 114 is exposed from the liquid level of the culture solution.

In the supplying step, the operator supplies the cell aggregate 2 together with the culture solution from the container 111 to the inside of the frame portion 114b of the gelatin container 114, and then uses each of the through holes 114a using an instrument such as tweezers. The cell aggregate 2 is moved to the position of the cell, thereby aligning the cell aggregate 2 on the gelatin container 114.
At this time, the culture solution accommodated in the container 111 together with the cell aggregate 2 is supplied to the culture container 3, whereby the cell aggregate 2 together with the gelatin container 114 can be immersed in the culture solution. In addition, when the culture solution is insufficient, the culture solution is appropriately supplied so that the cell aggregate 2 is completely immersed.
Subsequently, the operator places the same gelatin sheet 14 used in the first embodiment on the top of the cell aggregate 2 supported by the gelatin container 114, thereby moving the cell aggregate 2. To prevent.
In addition, since the movement of the cell aggregate 2 can be prevented by the frame portion 114b of the gelatin container 114, this may be omitted for the gelatin sheet 14 placed on top of the cell aggregate 2, Further, if a required number of cell aggregates 2 are supplied to the gelatin container 114, the cell aggregates 2 are aligned to some extent inside the frame portion 114b, so that the through hole 114a is omitted and The operation of aligning the cell aggregates can be simplified.
Thereafter, as in the above embodiment, the culture vessel 3 is transferred to the incubator 6 to perform a culture step of culturing the cell aggregate 2 in the culture vessel 3, and the shape in which the cell aggregate 2 is arranged in a plane is formed. It is possible to obtain the fusion pad 4 as an aggregate structure of cells by fusing with each other while maintaining.

In the culturing process of the above embodiment, the gelatin sheet 14 and the gelatin container 114 are dissolved with the culturing, but the gelatin sheet 14 and the gelatin container 114 are not lost in the culture vessel 3. May be.
In this case, the gelatin can be transplanted into the patient's body together with the cultured fusion pad, and the gelatin can be absorbed in the body. The period until the gelatin is absorbed into the body can be adjusted according to the degree of cross-linking when the gelatin container 114 is manufactured.
Moreover, in the said Example, if the cell aggregate 2 is mounted in the gelatin sheet 14 or the gelatin container 114 in the said supply process, and also the gelatin sheet 14 is mounted in the upper part of the said cell aggregate 2, it will culture | cultivate as it is. The whole container 3 is transferred to the incubator 6 and the cell aggregate 2 is cultured, but the cell aggregate 2 is held vertically by the gelatin sheet 14 or the gelatin container 114 while standing upright. Alternatively, the cells may be cultured while being inclined at a required angle.

DESCRIPTION OF SYMBOLS 1 Preparation apparatus 2 Cell aggregate 3 Culture container 4 Fusion pad 14 Gelatin sheet (gelatin support body) 14a Through hole (holding part)

Claims (5)

  A plurality of cell aggregates are supported on a cross-linked gelatin support, and the cell aggregates are immersed in a culture solution together with the gelatin support and cultured to fuse adjacent cell aggregates. A cell culture method using a gelatin support.   2. The cell culture method using a gelatin support according to claim 1, wherein a holding part for holding the cell aggregate is formed on the gelatin support.   3. The cell culture method using a gelatin support according to claim 1, wherein the cell aggregate is supported with a plurality of gelatin supports sandwiched therebetween.   The cell culture method using a gelatin support according to any one of claims 1 to 3, wherein a plurality of cell aggregates are supported in an aligned state.   The cell culture method using a gelatin support according to any one of claims 1 to 4, wherein the gelatin support and a plurality of cell aggregates are alternately laminated.

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