JP2020043806A - Bioreactors, systems and methods for cell culture - Google Patents

Abstract

To provide bioreactors, systems and methods for cell culture with simple constitution and high efficiency.SOLUTION: The bioreactor 20 of the cell culture system 10 comprises: a cell inoculation member 60 comprising a cell inoculation surface 58 to which cells are inoculated, a housing 62 to accommodate the inoculation member 60; an introducing part 64a provided to the housing 62 to introduce at least one fluid selected from a cell-containing solution, a peeling liquid and a culture medium into the housing 62; and a discharging part 64b provided to the housing 62 to discharge the fluid from the housing 62, where the introducing part 64a comprises a plurality of inlet flow path 79a, and a plurality of inlet valve 82a to open and close the inlet flow path 79a respectively.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a bioreactor for culturing cells, a cell culture system, and a cell culture method.

  For example, Patent Document 1 discloses a method of culturing cells by supplying a medium to the outer surface of a plurality of hollow fiber membranes in a state where cells are seeded on the inner surface of a plurality of hollow fiber membranes housed in a housing. A reactor is disclosed. An inlet cap is connected to one end of the housing, and an outlet cap is connected to the other end of the housing.

  One inlet port for introducing cells for seeding the hollow fiber membrane into the housing is provided at the center of the inlet-side cap. One outlet port is provided at the center of the outlet side cap to allow cultured cells to be drawn out of the housing.

Japanese Patent Publication No.

  In the above-described prior art, since one inlet port is provided at the center of the inlet-side cap, it is not easy to uniformly inoculate cells over the entire plurality of hollow fiber membranes. Therefore, cells may not be cultured efficiently.

  The present invention has been made in view of such problems, and has as its object to provide a bioreactor, a cell culture system, and a cell culture method that can efficiently culture cells with a simple configuration. .

  A first aspect of the present invention is a bioreactor for culturing cells, a seeding member having a cell seeding surface on which cells are seeded, a housing accommodating the seeding member, and a housing provided on the housing. A cell-containing solution, an introduction portion for introducing at least one fluid of a stripping solution and a culture medium for separating cells from the cell seeding surface into the housing, and provided in the housing, and the fluid is supplied from the inside of the housing. A deriving unit for deriving the bioreactor, wherein the introducing unit has a plurality of inlet channels and a plurality of inlet valves for opening and closing each of the plurality of inlet channels.

  The second aspect of the present invention is a bioreactor described above, a circulation flow path for circulating the fluid derived from the derivation part to the introduction part, and a fluid introduction part for guiding the fluid to the circulation flow path, It is a cell culture system provided with.

  A third aspect of the present invention is a cell culture method for culturing cells using a bioreactor, wherein the bioreactor includes a seeding member having a cell seeding surface on which cells are seeded, and the seeding member. A housing provided therein, an introduction unit provided in the housing, for introducing a cell-containing liquid into the housing, and a derivation unit provided in the housing, for deriving the cell-containing liquid from the housing. The unit has a plurality of inlet channels, and a plurality of inlet valves for opening and closing each of the plurality of inlet channels, and a cell-containing liquid selectively in the housing from the plurality of inlet channels. And performing a seeding step of seeding the member to be seeded by introducing a cell culture method.

  ADVANTAGE OF THE INVENTION According to this invention, since a fluid (cell-containing liquid, stripping liquid, and culture medium) can be selectively introduced into a housing from a plurality of inlet flow paths, variation in the flow velocity distribution of the fluid in the housing is suppressed. it can. Thereby, a fluid (cell-containing liquid, medium) at substantially the same flow rate can be supplied to the entire cell seeding surface, and thus cells can be efficiently cultured with a simple configuration. Further, when cells are detached from the cell seeding surface, the flow velocity distribution of the fluid in the housing is concentrated, the force for detaching the cells is increased, and the cell collection efficiency can be improved.

It is a schematic structure figure of the cell culture system concerning one embodiment of the present invention. It is a perspective view of a part of bioreactor. FIG. 3 is a cross-sectional view along the line III-III in FIG. 2. FIG. 4 is a sectional view taken along the line IV-IV in FIG. 3. FIG. 5 is a sectional view taken along line VV of FIG. 3. It is a perspective view of a seeding member. 4 is a flowchart illustrating a cell culture method of the present invention. It is explanatory drawing of the priming process of a cell culture method. It is explanatory drawing of the seeding process of a cell culture method. It is explanatory drawing of the adhesion process of a cell culture method. It is explanatory drawing of the culture process of a cell culture method. It is explanatory drawing of the stripping solution addition process of a cell culture method. It is explanatory drawing of the peeling process of a cell culture method. It is explanatory drawing of the collection | recovery process of a cell culture method.

  Hereinafter, preferred embodiments of a bioreactor, a cell culture system, and a cell culture method according to the present invention will be described with reference to the accompanying drawings.

  The cell culture system 10 according to one embodiment of the present invention is for culturing and growing cells separated from a living tissue. In the present embodiment, the cells used in the cell culture system 10 are adherent cells. However, the cells are not limited to adherent cells, and may be floating cells or a combination of adherent cells and floating cells. As the cells, for example, stem cells (mesenchymal cells, hematopoietic cells, etc.), fibroblasts, keratinocytes, progenitor cells, other fully differentiated cells, or a combination thereof are used.

  As shown in FIG. 1, the cell culture system 10 includes a system body 12, a fluid introduction unit 14 that introduces a predetermined fluid into the system body 12, and a discharge unit 16 that discharges fluid from the system body 12, and is cultured. The system includes a collection unit 18 for collecting cells and a control unit 19.

  The predetermined fluid introduced into the system main body 12 is a cell-containing liquid, a culture medium, and a stripping liquid. The cell-containing liquid is a cell suspension for seeding cells on a cell seeding surface 58 of a seeding member 60 described below of the system main body 12. As the cell-containing liquid, for example, MEM (Minimum Essential Medium), DMEM (Dulbecco's Modified Eagle's Medium) and the like are used.

  The culture medium is a fluid (culture solution) that provides a growing environment for the cells seeded on the member 60 to be seeded. As the medium, for example, MEM, DMEM and the like are used. The stripping liquid is a liquid for stripping cells from the seeding member 60. Examples of the stripping solution include a trypsin solution and a trypsin EDTA solution for decomposing cellular proteins.

  The system main body 12 includes a bioreactor 20 for culturing cells, a circulation flow path 22, an oxygen supply unit 24, a plurality of valves 26, a circulation pump 28, and a pressure sensor 30. The detailed configuration of the bioreactor 20 will be described later.

  Predetermined fluids (cell-containing liquid, medium, and stripping liquid) are introduced into the circulation channel 22 from the fluid introduction unit 14. The circulation channel 22 circulates the fluid derived from the outlet 64 b of the bioreactor 20 to the inlet 64 a of the bioreactor 20. The circulation channel 22 has a first channel 22a, a second channel 22b, a third channel 22c, a fourth channel 22d, and a bypass channel 22e.

  The first flow path 22a is connected to the oxygen supply unit 24. The second flow path 22b connects the oxygen supply part 24 and the introduction part 64a of the bioreactor 20 to each other. The third flow path 22c is connected to the outlet 64b of the bioreactor 20. The fourth flow path 22d connects the third flow path 22c and the first flow path 22a to each other. The bypass channel 22e connects the first channel 22a and the second channel 22b to each other.

  The oxygen supply unit 24 includes a gas exchange unit 32, a medium inlet 34a, a medium outlet 34b, a gas inlet 36a, and a gas outlet 36b. The gas exchange unit 32 increases the oxygen concentration of the culture medium by supplying oxygen to the culture medium. The first channel 22a is connected to the medium inlet 34a, and the second channel 22b is connected to the medium outlet 34b. A predetermined gas (a gas containing oxygen) is introduced into the gas inlet 36a. The used gas after gas exchange with the culture medium flows through the gas outlet 36b.

  The plurality of valves 26 are on-off valves that open and close the flow path. The plurality of valves 26 are connected to a valve 26a provided on the fourth flow path 22d side of the connection part with the bypass flow path 22e in the first flow path 22a and a bypass flow path 22e in the first flow path 22a. It includes a valve 26b provided closer to the oxygen supply unit 24 than the connection unit, and a valve 26c provided in the bypass passage 22e.

  The circulation pump 28 is provided in the fourth flow path 22d. The circulation pump 28 is configured to be able to pump a fluid in a first direction and a second direction (a direction opposite to the first direction). That is, the circulation pump 28 is arranged in the order of the first flow path 22a, the oxygen supply unit 24 (bypass flow path 22e), the second flow path 22b, the bioreactor 20, the third flow path 22c, and the fourth flow path 22d (first flow path). Direction). The circulation pump 28 circulates the fluid in the order of the first flow path 22a, the fourth flow path 22d, the third flow path 22c, the bioreactor 20, the second flow path 22b, and the bypass flow path 22e (second direction). Can be done.

  The pressure sensor 30 is provided in the fourth flow path 22d and detects the pressure of the fluid in the circulation flow path 22. The circulation pump 28 and the pressure sensor 30 are not limited to the example provided in the fourth flow path 22d, and may be provided at an arbitrary position in the circulation flow path 22.

  The fluid introduction unit 14 includes a first introduction channel 38a, a second introduction channel 38b, a third introduction channel 38c, a plurality of introduction valves 40, and an introduction pump 42. The first introduction flow path 38a connects the first storage section 44a (cell-containing liquid storage bag) capable of storing the cell-containing liquid and the first flow path 22a to each other. The second introduction flow path 38b connects the second storage section 44b (the release liquid storage bag) capable of storing the release liquid and the first introduction flow path 38a to each other. The third introduction flow path 38c connects the third accommodation section 44c (medium accommodation bag) for accommodating the culture medium and the second introduction flow path 38b to each other.

  The plurality of introduction valves 40 are on-off valves that open and close the flow path. The plurality of introduction valves 40 include an introduction valve 40a provided closer to the first housing portion 44a than a connection portion of the first introduction channel 38a with the second introduction channel 38b, and a plurality of introduction valves 40a. It includes an introduction valve 40b provided on the second housing portion 44b side of the connection portion with the third introduction channel 38c, and an introduction valve 40c provided on the third introduction channel 38c.

  The introduction pump 42 is provided closer to the circulation flow path 22 than the connection between the first introduction flow path 38a and the second introduction flow path 38b. The introduction pump 42 guides fluids (cell-containing liquid, stripping liquid, and culture medium) from the first to third storage units 44a to 44c to the circulation channel 22.

  The second introduction channel 38b is not limited to the example connected to the first introduction channel 38a, and may be directly connected to the circulation channel 22. The third introduction channel 38c is not limited to the example connected to the second introduction channel 38b, and may be directly connected to the circulation channel 22.

  The discharge unit 16 has a discharge channel 46 and a discharge valve 48. The discharge flow path 46 connects the third flow path 22c and the waste accommodating portion 50 (a waste bag) to each other. The discharge valve 48 is an open / close valve that is provided in the discharge channel 46 and opens and closes the discharge channel 46.

  The collection unit 18 has a collection channel 52 and a collection valve 54. The collection channel 52 connects the collection container 56 (collection bag) capable of storing the cultured cells and the third channel 22c to each other. The recovery valve 54 is an open / close valve that opens and closes the recovery flow channel 52.

  1 to 6, the bioreactor 20 includes a seeding member 60 (see FIGS. 3 to 6) having a cell seeding surface 58 on which cells are seeded, a housing 62 that houses the seeding member 60, and a housing 62. And an introduction portion 64a and a derivation portion 64b.

  As shown in FIGS. 3 to 6, the seeding member 60 is configured as a so-called petri dish lamination type, and has a plurality of plate-like members 68 stacked in the arrow Z direction. The plate-shaped member 68 is integrally formed of a material (for example, a hard resin material) into which cells can be seeded. The plate-shaped member 68 is formed in a rectangular shape, and extends in one direction (the arrow X direction).

  A plurality of projections 70 protrude from the surface 68a (the surface in the direction of the arrow Z2) of the plate member 68 along the stacking direction of the plurality of the plate members 68 (in the direction of the arrow Z2). Each projection 70 extends linearly, for example, along the entire length of the plate-shaped member 68 (in a direction from the introduction portion 64a to the extraction portion 64b in FIG. 4).

  The plurality of projections 70 are arranged in a direction intersecting the direction in which the plurality of plate-shaped members 68 are stacked and the direction in which the projections 70 extend (the direction of the arrow Y) so as to be separated from each other. In other words, the plurality of protrusions 70 are provided at equal intervals in the short direction of the plate member 68. The protruding end surfaces 70a of the plurality of protrusions 70 are in contact with the back surface 68b of the plate-shaped member 68 adjacent in the direction in which the protrusions 70 protrude (the direction of arrow Z2). That is, the plurality of projections 70 support the plurality of plate-shaped members 68.

  A planar cell seeding surface 58 is formed between adjacent projections 70 on the surface 68a of the plate-shaped member 68. The cell seeding surface 58 extends linearly of the plate member 68 over the entire length of the plate member 68. In the plate member 68 facing each other, a plurality of fluids (cell-containing liquid, medium, and detachment liquid) flow between the cell seeding surface 58 and the back surface 68b of the plate member 68 to form the cell seeding surface 58. Are formed. In other words, a plurality of flow paths 72 through which fluids (cell-containing liquid, stripping liquid, and culture medium) flow are formed in each plate member 68. That is, the flow channel 72 is formed by the protrusion 70 and the cell seeding surface 58 adjacent to each other. The flow path 72 has a first opening 72a that opens toward the introduction portion 64a (in the direction of the arrow X1) and a second opening 72b that opens toward the outlet 64b (in the direction of arrow X2) (FIG. 3 and FIG. 4).

  The number, shape, and position of the projections 70 can be arbitrarily set. For example, the protrusion 70 is not limited to a linearly extending protrusion, and may be curved or formed in a point shape.

  As shown in FIGS. 2 to 5, the housing 62 is formed in a square tubular shape so as to cover the member 60 to be seeded. The overall length of the housing 62 (the dimension in the arrow X direction) is longer than the overall length of the seeding member 60 (the dimension in the arrow X direction). The housing 62 is formed of, for example, a hard resin. The housing 62 may be formed transparent so that the seeding member 60 inside can be visually recognized from the outside of the housing 62.

  The housing 62 includes two walls 74a and 74b that cover the seeded member 60 in the direction of the arrow Z, and two walls 74c and 74d that cover the member 60 in the direction of the arrow Y. In FIG. 5, the wall portion 74a is in contact with the back surface 68b of the plate-shaped member 68 located most in the direction of arrow Z1. The wall portion 74b is in contact with the protruding end surface 70a of each projection 70 of the plate-shaped member 68 located most in the arrow Z2 direction. Each of the wall portions 74c and 74d is in contact with the side surface of each of the plate members 68.

  As shown in FIGS. 1 to 4, the introduction portion 64 a introduces the fluid in the second flow path 22 b into the housing 62. The introduction part 64a has an inlet-side end wall part 76a, one introduction flow path 78a, a plurality of inlet-side connection flow paths 80a, and a plurality of inlet valves 82a. In FIG. 2, the illustration of the introduction channel 78a, the plurality of inlet-side connection channels 80a, and the plurality of inlet valves 82a is omitted.

  The inlet-side end wall 76a is provided at one end of the housing 62 so as to close the opening 62a of the housing 62 in the direction of the arrow X1. An entrance-side space 84a is formed between the entrance-side end wall 76a and the seeding member 60 (see FIGS. 3 and 4). The inlet-side end wall portion 76a is provided with a plurality of inlet port rows 88a in the arrow Z direction, each of which includes a plurality of inlet ports 86a arranged in the arrow Y direction (see FIG. 2).

  Each of the inlet ports 86a is a circular through-hole that penetrates the inlet-side end wall portion 76a in the thickness direction (the direction of the arrow X). In FIG. 4, the plurality of inlet ports 86a are arranged so as to correspond to the plurality of flow paths 72 of the member 60 to be seeded. That is, the plurality of inlet ports 86a are located in the arrow X1 direction with respect to the flow path 72 of the seeded member 60. However, the size, shape, position and number of the plurality of entrance ports 86a can be set arbitrarily.

  The introduction channel 78a is connected to the second channel 22b (see FIG. 1). 3 and 4, the plurality of inlet-side connecting flow paths 80a are branched from the second flow path 22b to a plurality of inlet ports 86a. That is, the plurality of inlet-side connection channels 80a guide the fluid in the second channel 22b to each of the plurality of inlet ports 86a. Each of the plurality of inlet-side connection channels 80a is connected to each of the plurality of inlet ports 86a to form a plurality of inlet channels 79a. The plurality of inlet valves 82a are provided in each of the plurality of inlet-side connection channels 80a. That is, the introduction portion 64a has a plurality of inlet channels 79a and a plurality of inlet valves 82a for opening and closing each of the plurality of inlet channels 79a. The plurality of inlet valves 82a are individually provided on the inlet-side end wall 76a.

  As shown in FIGS. 1 to 4, the lead-out portion 64 b guides the fluid out of the housing 62. The outlet portion 64b has an outlet-side end wall portion 76b, one outlet channel 78b, a plurality of outlet-side connection channels 80b, and a plurality of outlet valves 82b. The outlet-side end wall 76b is provided at the other end of the housing 62 so as to close the opening 62b of the housing 62 in the direction of the arrow X2. An outlet-side space 84b is formed between the outlet-side end wall 76b and the seeding member 60 (see FIGS. 3 and 4). The outlet-side end wall portion 76b is provided with a plurality of outlet port rows 88b in the arrow Z direction, each of which includes an outlet port 86b arranged in the arrow Y direction (see FIG. 2).

  Each outlet port 86b is a circular through-hole that passes through the outlet-side end wall portion 76b in the thickness direction (the direction of the arrow X). In FIG. 4, the plurality of outlet ports 86b are arranged so as to correspond to the plurality of flow paths 72 of the member 60 to be seeded. That is, the plurality of outlet ports 86b are located in the arrow X2 direction with respect to the flow path 72 of the seeded member 60. That is, the same number of outlet ports 86b as the inlet ports 86a are provided. In other words, the positions of the plurality of outlet ports 86b are provided at positions overlapping the plurality of inlet ports 86a in plan view from the arrow X direction. However, the size, shape, position and number of the plurality of outlet ports 86b can be set arbitrarily.

  As shown in FIGS. 3 and 4, the plurality of outlet-side connection channels 80b extend from the plurality of outlet ports 86b to the outlet channel 78b. That is, the plurality of outlet-side connection channels 80b guide the fluid drawn out from the plurality of outlet ports 86b to the outlet channel 78b. Each of the plurality of outlet-side connection channels 80b is connected to each of the plurality of outlet ports 86b to form a plurality of outlet channels 79b. The outlet channel 78b is connected to the third channel 22c (see FIG. 1). The plurality of outlet valves 82b are provided in each of the plurality of outlet side connection flow paths 80b. In other words, the outlet 64b has a plurality of outlet channels 79b and a plurality of outlet valves 82b for opening and closing each of the plurality of outlet channels 79b. The plurality of outlet valves 82b are individually provided on the outlet side end wall 76b.

  In FIG. 1, a control unit 19 is a computer including a microcomputer, and includes a CPU (Central Processing Unit), a ROM, a RAM, and the like. The CPU reads and executes a program stored in the ROM. By doing so, it functions as various function realizing units (functional realizing means). Note that the various function realizing units can also be configured by function realizing devices as hardware.

  The control unit 19 controls driving of the oxygen supply unit 24. The control unit 19 includes a pump control unit 90 and a valve control unit 92. The pump control unit 90 controls driving of the introduction pump 42 and the circulation pump 28. The valve control unit 92 controls opening and closing of the plurality of valves 26, the plurality of introduction valves 40, the discharge valve 48, and the collection valve 54. The valve control unit 92 selectively controls the plurality of inlet valves 82a to open and close, and selectively controls the plurality of outlet valves 82b to open and close.

  Next, a cell culture method using the cell culture system 10 according to the present embodiment configured as described above will be described.

  In the preparation process of step S1 in FIG. 7, each of the storage units (the first storage unit 44a, the second storage unit 44b, the third storage unit 44c, the waste storage unit 50, and the collection storage unit 56) is connected to a predetermined flow path. . In addition, the cell-containing liquid is stored in the first storage part 44a, the stripping liquid is stored in the second storage part 44b, and the culture medium is stored in the third storage part 44c. Further, in the state of the preparation process, the plurality of valves 26, the plurality of introduction valves 40, the discharge valve 48, the collection valve 54, the plurality of inlet valves 82a, and the plurality of outlet valves 82b are closed.

  Subsequently, in a priming step of step S2, a priming process of the cell culture system 10 is performed. Specifically, as shown in FIG. 8, the valve control unit 92 opens the plurality of valves 26a, 26b, 26c, the introduction valve 40c, the discharge valve 48, the plurality of inlet valves 82a, and the plurality of outlet valves 82b. I do. In addition, the pump control unit 90 continuously or intermittently drives the introduction pump 42 and drives the circulation pump 28 continuously or intermittently so that the fluid (medium) flows in the circulation channel 22 in the first direction. Let it. Note that the control unit 19 does not drive the oxygen supply unit 24.

  Then, the culture medium is introduced from the third storage section 44c into the first flow path 22a via the third introduction flow path 38c, the second introduction flow path 38b, and the first introduction flow path 38a. The culture medium introduced into the first flow path 22a is guided to the second flow path 22b via the oxygen supply unit 24 and to the second flow path 22b via the bypass flow path 22e.

  Then, the medium guided to the second flow path 22b is introduced into the housing 62 through the plurality of inlet-side connection flow paths 80a and the plurality of inlet ports 86a, and the inside of the housing 62 is filled with the medium. The culture medium in the housing 62 is led out to the third flow path 22c through the plurality of outlet ports 86b and the plurality of outlet-side connection flow paths 80b. The culture medium led out to the third flow path 22c is returned to the first flow path 22a through the fourth flow path 22d. That is, the medium circulates in the circulation channel 22 in the first direction under the action of the circulation pump 28. The excess of the culture medium supplied to the circulation flow path 22 is discharged to the discharge flow path 46 and stored in the waste storage unit 50.

  Next, in the seeding step of step S3 in FIG. 7, cells are seeded on the cell seeding surface 58 of the member 60 to be seeded. Specifically, as shown in FIG. 9, the valve control unit 92 closes the valve 26b and the introduction valve 40c and opens the introduction valve 40a. Note that the valves 26a and 26c and the discharge valve 48 are kept open.

  Further, the valve control unit 92 selectively controls the opening and closing of the plurality of inlet valves 82a and selectively controls the opening and closing of the plurality of outlet valves 82b. In other words, the valve control unit 92 selectively controls the opening and closing of the plurality of inlet valves 82a and the plurality of outlet valves 82b based on a predetermined program. Here, the predetermined program is a program in which the order and the opening time for opening the plurality of inlet channels 79a and the plurality of outlet channels 79b are defined. The fluid (cell-containing liquid) is set to be supplied substantially uniformly.

  Specifically, for example, the valve control unit 92 simultaneously opens the corresponding inlet flow channel 79a and outlet flow channel 79b (the inlet port 86a and the outlet port 86b located at positions overlapping each other in plan view from the arrow X direction). The opening and closing of the plurality of inlet valves 82a and the plurality of outlet valves 82b are controlled. In this case, the fluid can be smoothly circulated in the housing 62.

  The predetermined program may be stored in a storage unit (not shown) of the control unit 19 in advance, or may be stored in a server (not shown) or the like so that the control unit 19 can acquire the program. However, the valve control unit 92 may randomly control the opening and closing operations of the plurality of inlet valves 82a and the plurality of outlet valves 82b. The pump control unit 90 continuously or intermittently drives the introduction pump 42 and continuously or intermittently drives the circulation pump 28 so that the fluid (cell-containing liquid) flows in the circulation channel 22 in the first direction. Let it.

  In this case, the introduction of the culture medium into the first flow path 22a is stopped, and the cell-containing liquid is introduced from the first storage section 44a into the first flow path 22a via the first introduction flow path 38a. The cell-containing liquid guided to the first flow path 22a is guided to the second flow path 22b via the bypass flow path 22e.

  The cell-containing liquid in the second flow path 22b is selectively introduced into the open inlet flow path 79a among the plurality of inlet flow paths 79a, and is guided to the inlet-side space 84a in the housing 62. The cell-containing liquid guided to the inlet-side space 84a flows to the outlet-side space 84b through the plurality of channels 72 of the member 60 to be seeded. At this time, the cell-containing liquid comes into contact with the cell seeding surface 58. Therefore, the cells in the cell-containing liquid adhere (seed) to the cell seeding surface 58.

  The cell-containing liquid that has flowed to the outlet-side space 84b is selectively led out to the open outlet channel 79b among the plurality of outlet channels 79b, and is sent to the third channel 22c via the outlet-side connecting channel 80b. Be guided. The cell-containing liquid led out to the third flow path 22c is returned to the first flow path 22a via the fourth flow path 22d. That is, the cell-containing liquid circulates in the circulation channel 22 in the first direction.

  Thereby, the cells that have not been seeded on the cell seeding surface 58 can be guided to the cell seeding surface 58 again. A part of the cell-containing liquid led out to the third flow path 22c flows through the discharge flow path 46 together with the medium filling the circulation flow path 22 and the housing 62 at the time of priming, and is stored in the waste storage section 50. . Thereby, the cell-containing liquid in the first storage section 44a can be smoothly introduced into the circulation channel 22. The seeding step is performed for a predetermined time until cells are uniformly seeded on the entire cell seeding surface 58 of the member 60 to be seeded.

  Subsequently, in the bonding step of step S4 in FIG. 7, the cells are bonded to the cell seeding surface 58. Specifically, as shown in FIG. 10, the valve control unit 92 closes the introduction valve 40a and the discharge valve 48. Further, the pump control unit 90 stops driving the introduction pump 42 and the circulation pump 28. Thereby, the flow of the fluid in the circulation channel 22 is completely stopped, and the cells are adhered to the cell seeding surface 58.

  In the bonding step, the pump control unit 90 stops driving the circulating pump 28 for a certain period of time (after the cells in the housing 62 are bonded to the cell seeding surface 58) and then remains in the circulating channel 22. The circulation pump 28 may be driven to send the existing cells to the cell seeding surface 58, and the driving of the circulation pump 28 may be stopped again for a certain period of time. In this case, the cells in the circulation channel 22 can also be adhered to the cell seeding surface 58. In the bonding step, the time during which the driving of the circulation pump 28 is stopped is preferably about 4 to 10 minutes.

  Thereafter, in the culture step of step S5 in FIG. 7, the cells seeded (adhered) to the cell seeding surface 58 are cultured. Specifically, as shown in FIG. 11, the valve control unit 92 closes the valve 26c and the introduction valve 40a, and opens the valve 26b, the discharge valve 48, and the introduction valve 40c. Note that the valve 26a is kept open.

  Further, the valve control unit 92 selectively controls the opening and closing of the plurality of inlet valves 82a and selectively controls the opening and closing of the plurality of outlet valves 82b. The control of the plurality of inlet valves 82a and the plurality of outlet valves 82b is the same as in the case of the seeding step. The pump control unit 90 continuously or intermittently drives the introduction pump 42 and continuously or intermittently drives the circulation pump 28 so that the fluid (cell-containing liquid) flows in the circulation channel 22 in the first direction. Let it. Further, the control unit 19 drives the oxygen supply unit 24 to flow a predetermined gas containing oxygen to the gas exchange unit 32.

  In this case, the introduction of the cell-containing liquid into the first flow path 22a is stopped, and the first liquid is supplied from the third storage portion 44c to the first flow path 38c, the second flow path 38b, and the first flow path 38a. A culture medium is introduced into the channel 22a. The culture medium introduced into the first flow path 22a is guided to the second flow path 22b in a state where oxygen is supplied by the oxygen supply unit 24.

  The culture medium in the second flow path 22b is selectively introduced into the open entrance flow path 79a among the plurality of entrance flow paths 79a, and is introduced into the entrance side space 84a in the housing 62. The culture medium guided to the inlet-side space 84a flows to the outlet-side space 84b through the plurality of flow paths 72 of the member 60 to be seeded. At this time, the medium comes into contact with the cells seeded on the cell seeding surface 58. In other words, oxygen (nutrition) is supplied to the cells seeded on the cell seeding surface 58. Therefore, a favorable growth environment is provided for the cells seeded on the seeding member 60.

  The seeding that has flowed to the outlet side space 84b is selectively led out to the open outlet channel 79b among the plurality of outlet channels 79b, and is led to the third channel 22c via the outlet side connecting channel 80b. . The seeding led out to the third flow path 22c is returned to the first flow path 22a via the fourth flow path 22d. That is, the culture medium circulates in the circulation channel 22 in the first direction.

  As a result, the used medium (after supplying oxygen to the cells) is introduced into the housing 62 in a state where oxygen is taken in again by the oxygen supply unit 24, so that the medium containing sufficient oxygen is inoculated. The cells seeded on the member 60 can be supplied. A part of the culture medium led out to the third flow path 22c flows through the discharge flow path 46 and is stored in the waste storage unit 50. The culturing step is performed for a predetermined time until the cells seeded on the cell seeding surface 58 are sufficiently cultured.

  Then, in the stripping solution adding step of step S6 in FIG. 7, the stripping solution is added and uniformly dispersed on the cell seeding surface 58. Specifically, as shown in FIG. 12, the valve control unit 92 closes the valve 26b and the introduction valve 40c and opens the valve 26c and the introduction valve 40b. Note that the valve 26a and the discharge valve 48 are kept open.

  Further, the valve control unit 92 selectively controls the opening and closing of the plurality of inlet valves 82a and selectively controls the opening and closing of the plurality of outlet valves 82b. The control of the plurality of inlet valves 82a and the plurality of outlet valves 82b is the same as in the case of the seeding step. The pump control unit 90 continuously or intermittently drives the introduction pump 42 and continuously or intermittently drives the circulation pump 28 so that the fluid (cell-containing liquid) flows in the circulation channel 22 in the first direction. Let it. Further, the control unit 19 stops driving the oxygen supply unit 24.

  In this case, the flow of the culture medium from the third storage section 44c to the first flow path 22a is stopped, and the first flow path 22a is transferred from the second storage section 44b through the second introduction flow path 38b and the first introduction flow path 38a. A stripping solution is introduced into the device. The stripping liquid introduced into the first flow path 22a is guided to the second flow path 22b via the bypass flow path 22e.

  The stripping liquid in the second flow path 22b is selectively introduced into the open inlet flow path 79a among the plurality of inlet flow paths 79a, and is guided to the inlet-side space 84a in the housing 62. The stripping liquid guided to the inlet space 84a flows to the outlet space 84b via the plurality of flow paths 72 of the member 60 to be seeded.

  The stripper that has flowed to the outlet side space 84b is selectively led out to the open outlet channel 79b among the plurality of outlet channels 79b, and is guided to the third channel 22c via the outlet side connecting channel 80b. I will The stripping liquid led out to the third flow path 22c is returned to the first flow path 22a via the fourth flow path 22d, and is reused. Thereby, the stripping solution is added into the circulation channel 22 and the housing 62.

  Thereafter, the cultured cells are detached from the cell seeding surface 58 in the detaching step of step S7 in FIG. Specifically, as shown in FIG. 13, the valve control unit 92 closes the introduction valve 40b and the discharge valve 48. Note that the valves 26a and 26c are kept open.

  Further, the valve control unit 92 selectively controls the opening and closing of the plurality of inlet valves 82a and selectively controls the opening and closing of the plurality of outlet valves 82b. The valve control unit 92 controls the opening and closing of the plurality of inlet valves 82a and the plurality of outlet valves 82b so that the flow rate distribution of the stripping liquid is concentrated. That is, valve control in the peeling step is different from valve control in the seeding step for making the flow velocity distribution uniform.

  The pump controller 90 stops the driving of the introduction pump 42 and drives the circulation pump 28 continuously or intermittently so that the fluid (stripping liquid) circulates in the circulation channel 22 in the first direction. At this time, the fluid is maintained at a predetermined temperature (a temperature at which an enzyme reaction is performed, for example, 37 ° C.) by, for example, a heater (not shown).

  In this case, the cells are chemically separated from the cell seeding surface 58 because the removing solution decomposes the protein of the cells. In addition, the cells are physically separated from the cell seeding surface 58 because the peeling liquid, which has been increased in pressure when passing through the inlet channel 79a, directly hits the adhesion portion between the cell seeding surface 58 and the cells.

  In the stripping step, the pump controller 90 may drive the circulation pump 28 continuously or intermittently so that the stripping liquid alternately flows in both the first direction and the second direction. In this case, the cells can be effectively detached from the seeding member 60.

  Subsequently, in the collecting step of step S8 in FIG. 7, the detached cells are collected. Specifically, as shown in FIG. 14, the valve control unit 92 opens the introduction valve 40c and the collection valve 54. Note that the valves 26a and 26c are kept open.

  Further, the valve control unit 92 selectively controls the opening and closing of the plurality of inlet valves 82a and selectively controls the opening and closing of the plurality of outlet valves 82b. The control of the plurality of inlet valves 82a and the plurality of outlet valves 82b is the same as in the case of the seeding step. The pump control unit 90 continuously or intermittently drives the introduction pump 42 and continuously or intermittently drives the circulation pump 28 so that the fluid (cell-containing liquid) flows in the circulation channel 22 in the first direction. Let it.

  In this case, the flow of the stripping liquid from the second storage portion 44b to the first flow channel 22a is stopped, and the third introduction flow channel 38c, the second introduction flow channel 38b, and the first introduction flow channel 38a from the third storage portion 44c. Through the first flow path 22a. The culture medium introduced into the first channel 22a is guided to the second channel 22b via the bypass channel 22e.

  The medium in the second flow path 22b is selectively introduced into the open inlet flow path 79a among the plurality of inlet flow paths 79a, and is guided to the inlet-side space 84a in the housing 62. The culture medium guided to the inlet-side space 84a flows to the outlet-side space 84b through the plurality of flow paths 72 of the member 60 to be seeded. At this time, the medium causes the cells present in the plurality of flow paths 72 of the seeding member 60 to flow into the outlet side space 84b.

  The medium (medium containing cells, cell suspension) flowing to the outlet side space 84b is selectively led out to the open outlet channel 79b among the plurality of outlet channels 79b, and is connected to the outlet side connecting channel. The liquid is guided to the third flow path 22c via 80b. The culture medium containing cells led to the third flow path 22c flows through the recovery flow path 52 and is stored in the recovery storage unit 56. Part of the culture medium is returned to the first flow path 22a via the fourth flow path 22d, and is reused for collecting cells in the housing 62. When the collection of the cells in the housing 62 and the circulation channel 22 is completed, a series of operation flows ends.

  The bioreactor 20, the cell culture system 10, and the cell culture method have the following effects.

  According to the present embodiment, since fluids (cell-containing solution, stripping solution, and culture medium) can be selectively introduced into the housing 62 from the plurality of inlet channels 79a, the flow velocity distribution of the fluid in the housing 62 varies. Can be suppressed. As a result, a fluid having substantially the same flow rate can be supplied to the entire cell seeding surface 58, so that cells can be efficiently cultured with a simple configuration.

  The lead-out portion 64b has a plurality of outlet channels 79b and a plurality of outlet valves 82b for opening and closing each of the plurality of outlet channels 79b.

  According to such a configuration, the fluid selectively introduced into the housing 62 from the plurality of inlet channels 79a can be selectively led out of the housing 62 from the plurality of outlet channels 79b. This allows the fluid to flow smoothly into the housing 62, so that it can be more efficiently supplied to the entire cell seeding surface 58.

  A plurality of flow paths 72 through which fluid flows to form the cell seeding surface 58 are formed in the seeding member 60. Each of the plurality of flow paths 72 has a first opening 72a that opens toward the introduction portion 64a and a second opening 72b that opens toward the outlet 64b.

  According to such a configuration, the fluid introduced into the housing 62 from the plurality of inlet channels 79a can be smoothly circulated to the plurality of channels 72. Thereby, cells can be cultured more efficiently with a simple configuration.

  The seeding member 60 has a plurality of plate members 68 stacked on each other. At least one of the plurality of flow paths 72 is formed in each of the plurality of plate members 68.

  According to such a configuration, the configuration of the seeding member 60 can be simplified.

  On each surface 68a of the plurality of plate members 68, a plurality of protrusions 70 extending along the direction from the introduction portion 64a toward the lead-out portion 64b project in the stacking direction of the plurality of plate members 68. . The plurality of projections 70 form the plurality of flow paths 72 while supporting the plurality of plate-shaped members 68.

  According to such a configuration, the flow path 72 can be formed in each plate member 68 with a simple configuration.

  The plurality of protrusions 70 are arranged so as to sandwich the cell seeding surface 58 in a direction perpendicular to the direction in which the plurality of plate members 68 are stacked and the direction in which the plurality of protrusions 70 extend.

  According to such a configuration, since the protrusions 70 are arranged so as to sandwich the cell seeding surface 58, the fluid introduced into the housing 62 from the plurality of inlet channels 79a can be efficiently guided to the cell seeding surface 58. Can be.

  The cell culture system 10 includes the bioreactor 20 described above, a circulation channel 22 that circulates the fluid derived from the derivation unit 64b to the introduction unit 64a, and a fluid introduction unit 14 that introduces the fluid into the circulation channel 22. .

  According to such a configuration, it is possible to obtain the cell culture system 10 having the same effect as the bioreactor 20 described above.

  The cell culture system 10 includes an oxygen supply unit 24 that is provided in the circulation channel 22 and supplies oxygen to a medium flowing through the circulation channel 22.

  According to such a configuration, the medium containing oxygen can be efficiently supplied to the cells seeded on the member 60 to be seeded.

  In the cell culture method of culturing cells using the bioreactor 20, a seeding step of selectively introducing a cell-containing solution into the housing 62 from the plurality of inlet channels 79a and seeding the seeded member 60 is performed.

  According to such a method, cells can be efficiently and uniformly seeded on the entire cell seeding surface 58 of the member 60 to be seeded.

  In the cell culture method, after the seeding step, an adhesion step of adhering the cells to the seeding member 60 is performed in a state where the introduction of the cell-containing liquid from the plurality of inlet channels 79a into the housing 62 is stopped.

  According to such a method, the cells can be securely adhered to the seeding member 60.

  In the cell culture method, after the adhesion step, a culture step of selectively introducing a medium into the housing 62 from the plurality of inlet channels 79a and culturing the cells seeded on the member 60 to be seeded is performed.

  According to such a method, the medium can be efficiently supplied to all the cells seeded on the cell seeding surface 58.

  In the cell culture method, a stripping solution adding step of selectively introducing a stripping solution into the housing 62 from the plurality of inlet channels 79a is performed after the culture step.

  According to such a method, the stripping solution can be efficiently supplied to all the cells seeded on the cell seeding surface 58.

  In the cell culture method, after the stripping solution adding step, the stripping solution derived from the plurality of outlet channels 79b is selectively circulated from the plurality of inlet channels 79 into the housing 62 while being circulated through the plurality of inlet channels 79a. A stripping step of stripping cells cultured by introducing a stripping solution from the seeding member 60 is performed.

  According to such a method, cells can be efficiently detached from the cell seeding surface 58.

  In the cell culture method, after the exfoliation step, a medium exfoliated from the seeding member 60 is led out from the lead-out portion 64b and collected by selectively introducing a culture medium into the housing 62 from the plurality of inlet channels 79a. Perform a recovery step.

  According to such a configuration, cells can be efficiently collected.

  The present invention is not limited to the configuration described above. The inlet valve 82a and the outlet valve 82b may be configured to be able to manually open and close. The seeding member 60 may have a plurality of hollow fiber membranes extending from the introduction part 64a toward the outlet part 64b.

  Each of the inlet valves 82a and each of the inlet ports 86a may be connected to each other by a flow path (the inlet side connection flow path 80a). The plurality of inlet valves 82a are not limited to the configuration provided individually on the inlet side end wall portion 76a, and may constitute one valve unit. Each of the outlet valves 82b and each of the outlet ports 86b may be connected to each other by a flow path (an outlet side connection flow path 80b). The plurality of outlet valves 82b are not limited to the configuration provided individually on the outlet side end wall 76b, and may constitute one valve unit.

  The bioreactor, the cell culture system, and the cell culture method according to the present invention are not limited to the above-described embodiment, and may adopt various configurations without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 10 ... Cell culture system 14 ... Fluid introduction part 20 ... Bioreactor 22 ... Circulation flow path 24 ... Oxygen supply part 58 ... Cell seeding surface 60 ... Sseeding member 62 ... Housing 64a ... Introduction part 64b ... Derivation part 68 ... Plate member 70 ... projection 72 ... flow path 72a ... first opening 72b ... second opening 78a ... introduction flow path 78b ... derivation flow path 79a ... entrance flow path 79b ... exit flow path 80a ... entrance side connection flow path 80b ... exit side Connection flow path 82a Inlet valve 82b Outlet valve 86a Inlet port 86b Outlet port

Claims (14)

A bioreactor for culturing cells, comprising:
A seeding member having a cell seeding surface on which cells are seeded,
A housing for accommodating the seeded member,
Provided in the housing, a cell-containing solution, an introduction unit for introducing at least one fluid of a stripping solution and a culture medium for separating cells from the cell seeding surface into the housing,
A deriving unit provided in the housing, for deriving the fluid from inside the housing,
The introduction unit,
A plurality of inlet channels;
A plurality of inlet valves for opening and closing each of the plurality of inlet channels. The bioreactor according to claim 1, wherein
The deriving unit includes:
A plurality of outlet channels;
A plurality of outlet valves for opening and closing each of the plurality of outlet channels. The bioreactor according to claim 2, wherein
In the member to be seeded, a plurality of flow paths forming the cell seeding surface through which the fluid flows are formed,
Each of the plurality of flow paths,
A first opening that opens toward the introduction unit side;
A second opening that opens toward the outlet side. The bioreactor according to claim 3, wherein
The seeding member has a plurality of plate-like members stacked on each other,
The bioreactor, wherein at least one of the plurality of flow paths is formed in each of the plurality of plate members. The bioreactor according to claim 4, wherein
On each surface of the plurality of plate-like members, a plurality of protrusions extending along a direction from the introduction portion toward the lead-out portion project along a stacking direction of the plurality of plate-like members,
The bioreactor, wherein the plurality of protrusions form the plurality of flow paths while supporting the plurality of plate members. The bioreactor according to claim 5, wherein
The plurality of protrusions are arranged so as to sandwich the cell seeding surface in a direction orthogonal to the stacking direction of the plurality of plate members and the extending direction of the plurality of protrusions,
Bioreactor. A bioreactor according to any one of claims 1 to 6,
A circulation channel for circulating the fluid derived from the derivation unit to the introduction unit,
A fluid introduction unit for guiding the fluid to the circulation flow path. The cell culture system according to claim 7,
A cell culture system, comprising: an oxygen supply unit provided in the circulation channel to supply oxygen to a medium flowing through the circulation channel. A cell culture method for culturing cells using a bioreactor,
The bioreactor is
A seeding member having a cell seeding surface on which cells are seeded,
A housing for accommodating the seeded member,
An introduction unit provided in the housing, for introducing a cell-containing liquid into the housing,
A deriving unit that is provided in the housing and that derives a cell-containing liquid from inside the housing,
The introduction unit,
A plurality of inlet channels;
A plurality of inlet valves for opening and closing each of the plurality of inlet flow paths,
A cell culture method, comprising performing a seeding step of selectively introducing a cell-containing solution into the housing from the plurality of inlet channels and seeding the seeded member with cells. The cell culture method according to claim 9, wherein
A cell culture method, wherein after the seeding step, an adhesion step of adhering cells to the member to be seeded is performed in a state where the introduction of the cell-containing liquid from the plurality of inlet channels into the housing is stopped. The cell culture method according to claim 10, wherein
A cell culture method, comprising, after the adhesion step, a culture step of selectively introducing a culture medium into the housing from the plurality of inlet channels and culturing cells seeded on the member to be seeded. The cell culture method according to claim 11,
A cell culture method, comprising, after the culturing step, a stripping solution adding step of selectively introducing a stripping solution into the housing from the plurality of inlet channels. The cell culture method according to claim 12,
After the stripping solution adding step, selectively introducing the stripping solution into the housing from the plurality of inlet channels while circulating the stripping solution derived from the plurality of outlet channels through the plurality of inlet channels. A cell culture method, comprising: performing a peeling step of peeling the cells cultured by the method from the member to be seeded. The cell culture method according to claim 13,
After the detachment step, by selectively introducing a culture medium into the housing from the plurality of inlet channels, a collection step of collecting cells detached from the seeded member from the outlet portion and collecting the detached cells. Perform cell culture method.

Images