WO2019245070A1 - Device and method for proliferating stem cell, and system and method for continuously proliferating, extracting, and separating stem cell - Google Patents

Abstract

The present invention provides a device and a method for proliferating a stem cell, and a system and a method for continuously proliferating, extracting, and separating a stem cell. A stem cell proliferation device according to an embodiment of the present invention comprises: a proliferation pipe in which a stem cell is proliferated, and which comprises a helical pipe part formed in a helical shape, a first extended pipe part extending from one end of the helical pipe part so as to receive a stem cell extracted from the outside and a proliferation medium for the proliferation of the stem cell, and a second extended pipe part extending from the other end of the helical pipe part so as to supply the proliferated stem cell to the outside; a medium supply unit for supplying the proliferation medium to the proliferation pipe; a first opening/closing unit for selectively connecting/separating the first extended pipe part to/from a first supply pipe for supplying the extracted stem cell to the proliferation pipe; a second opening/closing unit for selectively connecting/separating the second extended pipe part to/from a second supply pipe for supplying the stem cell proliferated in the proliferation pipe; and a rotation-driving unit for rotating the proliferation pipe, wherein, when the extracted stem cell and the proliferation medium are supplied to the helical pipe part, the proliferation pipe is rotated by the rotation-driving unit in the state in which the first extended pipe part and the second extended pipe part are separated from the first supply pipe and the second supply pipe by the first opening/closing unit and the second opening/closing unit, respectively.

Description

[Revision 30.08.2018 by Rule 26] Stem Cell Proliferation and Proliferation Methods, Stem Cell Continuous Proliferation, Extraction and Separation Systems and Methods

The present invention relates to stem cell proliferative phase and proliferation method, stem cell continuous proliferation, extraction and separation system and method.

Stem cells are capable of differentiating into various body tissue cells such as bone, nerve, muscle, cartilage, etc., depending on the method of obtaining, embryonated embryonic stem cells, somatic cell cloned embryonic stem cells, inverted induced stem cells, and adults Stem cells and the like.

In the case of the adult stem cells (Adult Stem Cell), which is extracted from the fat, bone marrow, umbilical cord blood, etc. of the adult, in the case of autologous transplantation is unlikely to generate an immune rejection reaction, there is an advantage that the stable transplantation. In the case of such adult stem cells, it is extracted from the fat of the adult and then used to proliferate it.

Republic of Korea Patent No. 1507621 (hereinafter referred to as "prior patent document") discloses a multiplier according to the prior art. Referring to the prior patent document, conventionally, live cells grow on the surface of the pipe 1 by the growth medium contained in the flexible pipe 1, and the clamps / gates 3, 4, and 5 are applied. The pipe 1 is divided into an upstream region of the unused culture medium 7, a downstream region of the culture medium 15 used, and a growth chamber region 10 between the upstream region and the downstream region in accordance with opening and closing by the opening and closing process. And conventionally, continuous growth of live cells is achieved while the pipe 1 is continuously moved, ie, continuously moved to the upstream region-the growth chamber region 10-downstream region.

However, according to the multiplier according to the prior art, the following problems occur.

First, conventionally, separately extracted cells should be supplied to the multiplier, substantially the pipe 1. Therefore, in the related art, there is a disadvantage in that the extraction and proliferation of the cells are substantially impossible. Furthermore, in the prior art, there is a fear of contamination in the process of supplying the extracted cells to the inside of the pipe (1).

In addition, conventionally, when the proliferation of cells using the pipe 1 having a predetermined length is completed, a new pipe 1 must be added and supplied. Therefore, in the related art, it is necessary to continuously supply the pipe 1, and there is a inconvenience that a configuration for this needs to be added.

And conventionally, the area | region of the piping 1 is opened and closed by clamp / gate (3) (4) (5), and each area | region is divided | segmented. Therefore, in the related art, since the pipe 1 has to be molded of a flexible material in order to divide the area by the clamps / gates 3, 4, 5, the clamps / gates 3, 4, 5 The pipe 1 may be damaged during the opening and closing process.

In addition, conventionally, since the tube 1 must be sequentially partitioned into an upstream region-growth region 10-downstream region for cell proliferation, a predetermined length of space must be secured. Therefore, in the related art, there is a disadvantage that the space for installing the cell multiplier, that is, the cell proliferation is unnecessarily consumed.

The present invention is to solve the problems caused by the prior art as described above, an object of the present invention, the stem cell proliferative phase and proliferation configured to enable the extraction and proliferation of continuous stem cells and separation for the proliferated cells It is to provide a method, a stem cell continuous proliferation, extraction and separation system and method.

Another object of the present invention is to provide a stem cell multiplier and proliferation method, a stem cell continuous proliferation, extraction and separation system and method configured to prevent the contamination of stem cells.

Still another object of the present invention is to provide a stem cell multiplier and proliferation method, a stem cell continuous proliferation, extraction and separation system and method, which are configured to more simply extract, proliferate, and separate continuous stem cells.

Still another object of the present invention is to provide a stem cell multiplier and a proliferation method, a stem cell continuous proliferation, an extraction and separation system and a method configured to ensure durability.

Still another object of the present invention is to provide a stem cell multiplier and a method of proliferation, a stem cell continuous proliferation, an extraction and separation system and a method which are more compactly configured.

One aspect of the stem cell multiplier according to an embodiment of the present invention for achieving the above object is a spiral tube portion formed in a spiral shape, the proliferation of stem cells and stem cells extracted from the outside extending from one end of the spiral portion A proliferation tube including a first extension tube part receiving the proliferation medium for supplying the second extension tube part extending from the other end of the spiral part and supplying stem cells proliferated to the outside; A medium supply unit supplying a growth medium to the growth tube; A first opening / closing unit for selectively communicating / separating the first extension tube part with the first supply tube for supplying the stem cells extracted into the growth tube; A second opening / closing unit for selectively communicating / separating the second extension tube part with a second supply tube for supplying stem cells proliferated in the growth tube; And a rotation drive unit for rotating the propagation tube. When the stem cells and the proliferation medium extracted from the spiral tube part is supplied, the first and second extension tube portion and the first and second supply tube in the state separated by the first and second opening and closing unit The growth tube is rotated by the rotation driving unit.

In one aspect of the stem cell multiplier according to an embodiment of the present invention, the proliferation tube, one end is connected to one side of the spiral tube portion or one side of the first extension tube portion adjacent to the first extension tube portion, the second extension Further comprising a circulation pipe portion having the other end connected to the other side of the spiral tube portion adjacent to the tube portion or one side of the second extension tube portion, the first and second extension tube portion and the first by the first and second opening and closing unit And a circulation pump for pumping the stem cells and the growth medium from one end of the spiral tube to the other end of the spiral tube so that the stem cells and the growth medium circulate the spiral tube in a state in which the first and second supply pipes are separated.

In one aspect of the stem cell multiplier according to an embodiment of the present invention, at least the spiral tube portion is disposed to be inclined at an angle of more than 0 ° and less than 45 ° with respect to the horizontal plane.

One aspect of the stem cell multiplier according to an embodiment of the present invention, the growth tube is further disposed therein, further comprises a growth vessel that rotates with the growth tube by the rotation drive unit.

One aspect of the stem cell multiplier according to an embodiment of the present invention further comprises a temperature control unit for controlling the temperature for the proliferation of stem cells in the growth tube.

One aspect of the stem cell multiplier according to an embodiment of the present invention further comprises an air supply unit for supplying air to the growth tube.

One embodiment of the stem cell proliferation method according to an embodiment of the present invention, in the stem cell proliferation method using the stem cell proliferator of claim 1: The proliferation medium for proliferation of the extracted stem cells and stem cells is supplied to the growth tube Supplying the extracted stem cells and the growth medium; And stem cell proliferation step in which stem cells proliferate inside the growth tube; It includes.

In one aspect of the stem cell proliferation method according to an embodiment of the present invention, in the extracting stem cells and proliferation medium supplying step, the first extension tube portion and the first supply tube is communicated by the first opening and closing unit, the second The stem cells and the proliferation medium extracted through the first extension pipe part and the first supply pipe in a state where the second extension pipe part and the second supply pipe are separated by the opening / closing unit are supplied to the growth pipe.

In one aspect of the stem cell proliferation method according to an embodiment of the present invention, in the stem cell proliferation step, the rotation drive unit, the first and second extension tube portion and the first by the first and second opening and closing unit The propagation tube is rotated while the first and second supply tubes are separated.

In one aspect of the stem cell proliferation method according to an embodiment of the present invention, in the stem cell proliferation step, a circulation pump pumps the stem cells and the proliferation medium to circulate the proliferation tube.

In one aspect of the stem cell proliferation method according to an embodiment of the present invention, in the stem cell proliferation step, the temperature control unit, the temperature for the proliferation of stem cells in the growth tube, the air supply unit, Supply air into the growth tube.

One embodiment of the stem cell continuous proliferation, extraction and separation system according to an embodiment of the present invention, the stem cell extractor for extracting stem cells from the sample; A stem cell multiplier according to any one of claims 1 to 6 for receiving and proliferating stem cells extracted from the stem cell extractor; And a centrifugal separator for receiving the stem cells proliferated from the stem cell multiplier to separate by component; It includes.

In one aspect of the stem cell extraction, proliferation and separation system according to an embodiment of the present invention, the stem cell extractor, the first supply pipe for supplying the stem cell proliferation to the stem cell multiplier in communication with the first extension tube portion; The centrifuge includes a second supply pipe that receives stem cells proliferated in communication with the second extension tube part from the stem cell multiplier.

In one aspect of the stem cell extraction, proliferation and separation system according to an embodiment of the present invention, in the state in which the first extension tube and the first supply tube in communication with the first opening and closing unit, extracted by the stem cell extractor And a first supply pump for pumping the stem cells and the growth medium supplied by the growth medium supply unit to the growth tube.

In one aspect of the stem cell extraction, proliferation and separation system according to an embodiment of the present invention, in the state in which the second extension tube portion and the second supply tube is in communication by the second opening and closing unit, it is propagated by the stem cell multiplier It further comprises a second feed pump for pumping stem cells into the centrifuge.

In one aspect of the method for continuously proliferating, extracting and separating stem cells according to an embodiment of the present invention, the method for continuously proliferating, extracting and separating stem cells using the stem cell continuous proliferation, extraction and separation system of claim 12: Stem cells, the stem cell extraction step is extracted by the stem cell extractor; Extracting stem cells and a growth medium supplying a proliferation medium for proliferation of stem cells and stem cells extracted in the stem cell extraction step to the growth tube; A stem cell proliferation step of proliferating the stem cells supplied to the growth tube in the extracting stem cells and the growth medium supplying step in the growth tube; A proliferating stem cell supplying step of supplying the stem cells proliferated in the stem cell proliferation step to the centrifuge; And a stem cell separation step of separating the stem cells supplied in the proliferating stem cell supply step by component by the centrifuge. It includes.

In one aspect of the stem cell continuous growth, extraction and separation method according to an embodiment of the present invention, in the step of supplying the extracted stem cells and growth medium, the first extension tube and the first supply tube is communicated by the first opening and closing unit The stem cells and the proliferation medium supply unit extracted from the stem cell extractor through the first extension pipe part and the first supply pipe in a state in which the second extension pipe part and the second supply pipe are separated by the second opening and closing unit. Propagation medium from is supplied to the growth vessel.

In one aspect of the stem cell continuous growth, extraction and separation method according to an embodiment of the present invention, in the stem cell proliferation step, the rotation drive unit, the first and second opening and closing unit by the first and second opening and closing unit The propagation tube is rotated while the extension tube portion and the first and second supply tubes are separated.

In one aspect of the stem cell continuous proliferation, extraction and separation method according to an embodiment of the present invention, in the stem cell proliferation step, the circulation pump, the first and second extension tube by the first and second opening and closing unit In the state where the first and second supply pipes are separated, stem cells and proliferation medium are pumped to circulate the proliferation pipes.

In one aspect of the method for continuously proliferating, extracting and separating stem cells according to an embodiment of the present invention, when the extracting stem cells and the proliferation medium supply step are completed, the stem cell extraction step may be performed regardless of the completion of the stem cell proliferation step. Is initiated.

In one aspect of the method for continuously proliferating, extracting and separating stem cells according to an embodiment of the present invention, when the proliferating stem cell supplying step is completed, the extracting stem cells and proliferation medium supplying step are independent of completion of the stem cell separation step. Is disclosed.

According to the stem cell proliferative phase and the proliferation method, the stem cell continuous proliferation, extraction and separation system and method according to an embodiment of the present invention can be expected the following effects.

First, in the embodiment of the present invention, the extraction, proliferation and separation of the components of the stem cells are made continuously. Therefore, according to an embodiment of the present invention, stem cells can be more quickly extracted, expanded, and separated by components.

In addition, in the embodiment of the present invention, the stem cells extracted from the stem cell extractor is directly supplied to the stem cell proliferator through the tube, the stem cells proliferated in the stem cell proliferator are directly supplied to the centrifuge through the tube. Therefore, according to the embodiment of the present invention, it is possible to prevent contamination during the movement of stem cells between the stem cell extractor, stem cell multiplier and centrifuge.

In an embodiment of the present invention, by selectively communicating / separating the tube between the stem cell extractor and the stem cell multiplier and between the stem cell multiplier and the centrifuge, the extraction, proliferation and separation of the stem cells are continuously performed. Therefore, according to the embodiment of the present invention, it is possible to extract, proliferate, and separate components by successive stem cells in a simpler configuration.

Furthermore, in the embodiment of the present invention, stem cells are proliferated by the rotation of the proliferative tube through which the stem cells are proliferated and the circulation of the stem cells and the proliferation medium in the proliferating tube. Therefore, according to the embodiment of the present invention, it is possible to use a propagation tube having a predetermined rigidity, thereby ensuring the durability of the system.

In addition, in the embodiment of the present invention, by forming a portion of the growth tube in a spiral shape, the overall size and volume of the stem cell proliferative phase can be reduced. Therefore, according to the embodiment of the present invention, by adjusting only the temperature of the relatively small size and volume of the space, it is possible to more easily control the environment for the proliferation of stem cells.

1 is a schematic view showing a stem cell continuous proliferation, extraction and separation system according to a first embodiment of the present invention.

Figure 2 is a flow chart showing the stem cell continuous proliferation, extraction and separation method according to a first embodiment of the present invention.

Figure 3 is a schematic diagram showing a stem cell continuous proliferation, extraction and separation system according to a second embodiment of the present invention.

Hereinafter, the stem cell continuous proliferation, extraction and separation system according to the first embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a schematic view showing a stem cell continuous proliferation, extraction and separation system according to a first embodiment of the present invention.

Referring to Figure 1, the stem cell continuous proliferation, extraction and separation system 1 according to the present embodiment, stem cell extractor 100, stem cell multiplier 200, centrifuge 300 and the first and second Feed pumps 410 and 420. In the stem cell continuous proliferation, extraction and separation system 1 according to the present embodiment, in particular, the proliferation, extraction and separation of the stem cells are carried out continuously.

In more detail, the stem cell extractor 100 extracts stem cells from a sample. For example, the stem cell extractor 100 may extract stem cells, that is, adult stem cells from adult fat, bone marrow, umbilical cord blood, and the like. The stem cell extractor 100 may extract stem cells by various kinds of known extraction methods. The stem cell extractor 100 includes a first supply pipe 110 for supplying the extracted stem cells to the stem cell multiplier 200.

The stem cell multiplier 200 receives and proliferates stem cells extracted from the stem cell extractor 100. The stem cell multiplier 200, the growth tube 210, growth vessel 220, medium supply unit 230, the first and second opening and closing unit 241, 242, rotation drive unit 250, circulation A pump 260, a temperature control unit 270 and an air supply unit 280.

More specifically, the growth tube 210 is a place where stem cells proliferate. In the present embodiment, the growth tube 210 includes a spiral tube portion 211, the first and second extension tube portion 213, 215 and the circulation tube portion 217.

The spiral pipe portion 211 is formed in a spiral shape as a whole. Substantially the stem cells supplied into the growth tube 210 will be proliferated by the growth medium in a state implanted in the inner surface of the spiral tube portion 211.

The first extension tube portion 213 extends from one end of the spiral tube portion 211 positioned relatively upward to provide a growth medium for proliferation of stem cells and stem cells extracted from the stem cell extractor 100. To be supplied. The second extension tube portion 215 extends from the other end of the spiral tube portion 211 positioned relatively downward to the stem cell multiplier 200 and substantially the stem cells proliferated in the growth tube 210. Supply to the centrifuge (300).

On the other hand, the circulation pipe 217, the stem cells and proliferation medium, in particular, after the stem cells are implanted on the surface of the spiral pipe portion 211 mainly for the growth medium to circulate the spiral pipe portion 211 will be. Substantially inside the circulation pipe 217 flows stem cells and proliferation medium, which are pushed to one end from the other end of the spiral pipe 211. To this end, one end of the circulation pipe part 217 is connected to one side of the spiral pipe part 211 adjacent to the first extension pipe part 213 or to one side of the first extension pipe part 213, and the circulation pipe part 217 The other end of) is connected to the other end of the spiral tube portion 211 adjacent to the second extension tube portion 215 or to one side of the second extension tube portion 215. Of course, stem cells may also be implanted into the inner surface of the circulation tube 217.

In particular, in the present embodiment, the spiral pipe portion 211 is disposed to be inclined at an angle of more than 0 ° and 45 ° or less with respect to the horizontal plane. This is to ensure efficient circulation of stem cells and stem cells and proliferation medium. In more detail, when the spiral tube portion 211 is disposed at an angle of more than 45 ° with respect to the horizontal plane, the stem cells flow in the spiral tube portion 211 at an excessively high speed so that the stem cells flow. The idea of not being made enough. On the contrary, when the spiral tube portion 211 is disposed at 0 ° with respect to the horizontal plane, that is, parallel to the horizontal plane, the stem cells and the proliferation medium flow in the spiral tube portion 211 at a relatively excessively slow speed, thereby causing the stem Cells may be locally implanted on the inner surface of the spiral tube portion 211 or proliferation medium may not flow at a sufficient speed. Of course, as will be described later, the circulation of the stem cells and the growth medium in the spiral pipe portion 211 and the circulation pipe portion 217 by the pressure of the circulation pump 260, but the circulation pump 260, The stem cell and the proliferation medium are forcibly flowed from one end of the spiral tube portion 211 positioned relatively upward from the other end of the spiral tube portion 211 positioned relatively downward, and substantially the spiral tube portion 211 The flow of stem cells and proliferation medium in the inside is relatively slow due to its own weight. Therefore, in this embodiment, by limiting the inclination angle to the horizontal plane of the spiral tube portion 211 to more than 0 ° and less than 45 °, the implantation of stem cells and circulation of the growth medium is made to a sufficient level for the proliferation of stem cells To lose.

In addition, in the present embodiment, a coating layer (not shown) may be provided on the inner surface of the growth tube 210 in order to induce the implantation of stem cells and to prevent toxic generation of stem cells in the proliferation process. For example, hyaluronic acid or hydroxy-apatite containing a nitroso-glutathione (GSNO), nitroso-cysteine (cysNO), or hydroxy-apatite (hydrogel) to prevent stem cell implantation and toxicity generation. Hydrogel and parasitic polysaccharides (SPS-CF: marine algalsulphated polysaccharides of Capsosiphon Fulvescens ) may be coated on the inner surface of the growth tube 210.

On the other hand, the growth vessel 220 may be formed in a hollow cylindrical shape of which the upper surface is approximately open. The growth vessel 220 is rotated in a state where the growth vessel 210 is disposed therein, thereby substantially rotating together with the growth vessel 210.

The growth medium supply unit 230 supplies a growth medium to the growth tube 210. The growth medium supply unit 230 may be connected to, for example, the first supply pipe 110. Therefore, the growth medium supplied by the growth medium supply unit 230 may be supplied to the growth tube 210 together with the stem cells extracted from the stem cell extractor 100. In this case, any one of GSH (Glutathione), GSNO (nitroso-glutathione), and CysNO (nitroso-cysteine) may be included in the growth medium supplied to the growth tube 210 to prevent the oxidation of stem cells.

The first opening and closing unit 241 selectively communicates / separates the first extension pipe part 213 and the first supply pipe 110. In addition, the second opening and closing unit 242 selectively communicates / separates the second extension pipe part 215 and the second supply pipe 310 to be described later. Substantially, the supply of the extracted stem cells and the proliferation medium through the first extension tube 213 and the first supply tube 110 by the first opening and closing unit 241 is selectively made. And the second opening and closing unit 242 is selectively made of the supply of proliferated stem cells through the second extension tube 215 and the second supply tube 310. In the present embodiment, the first opening and closing unit 241 includes a pair of first valves 241V for opening and closing the ends of the first extension pipe part 213 and the first supply pipe 110, respectively, and the second The opening and closing unit 242 includes a pair of second valves 242V for opening and closing ends of the second extension pipe part 215 and the second supply pipe 310, respectively. Accordingly, the first extension pipe part 213 and the first supply pipe 110 communicate / separate according to the opening and closing of the first valve 241V, and the second extension pipe part (2) according to the opening and closing of the second valve 242V. 215 and the second supply pipe 310 will be in communication / separation. In the process of supplying the stem cells and the proliferation medium extracted to the spiral tube portion 211, the first extension tube portion 213 and the first supply tube 110 is in communication by the first opening and closing unit 241, The second extension pipe part 215 and the second supply pipe 310 will be separated by the second opening and closing unit 242. When the stem cells and the proliferation medium extracted to the spiral tube part 211 are supplied, the first extension tube part 213 and the first supply tube 110 will be separated by the first opening / closing unit 241. .

On the other hand, the rotation drive unit 250 rotates the growth tube 210. Substantially in this embodiment, the rotation drive unit 250 rotates the growth vessel 220 in which the growth tube 210 is installed therein. Of course, in the state in which the growth vessel 220 is fixed, the rotation drive unit 250 may rotate the growth tube 210. However, the rotation of the propagation pipe 210 by the rotation driving unit 250 is performed by the first and second opening and closing units 241 and 242 to the first and second extension pipe parts 213 and 215. ) And the first and second supply pipes 110 and 310 in a separated state.

The circulation pump 260 pumps the stem cells and the proliferation medium to circulate the spiral tube portion 211 and the circulation tube portion 217. As described above, the circulation pump 260 substantially flows the stem cells and the growth medium from one end of the spiral tube portion 211 to one end. The pumping of the stem cells and the proliferation medium by the circulation pump 260 is performed by the first and second opening and closing units 241 and 242 and the first and second extension pipe parts 213 and 215. In a state in which the first and second supply pipes 110 and 310 are separated, it will be made.

In addition, the temperature control unit 270, adjusts the temperature for the proliferation of stem cells in the growth tube 210. For example, the temperature control unit 270 may be installed at one side of the growth vessel 220 to adjust the internal temperature of the growth vessel 220 to maintain a predetermined temperature.

The air supply unit 280 supplies air to the growth tube 210. The air supply unit 280 is connected to one side of the growth tube 210, for example, one side of the spiral tube portion 211, and supplies air to the interior of the growth tube 210. In this case, the air supply unit 280 supplies air to the growth pipe 210 in which the concentration of carbon dioxide is increased relative to the atmosphere. In addition, the air supplied to the growth pipe 210 by the air supply unit 280 may be supplied in a state in which foreign matters and the like are removed by the filter 281.

On the other hand, the centrifuge 300 receives the stem cells proliferated from the stem cell multiplier 200 and separates by component. As the centrifuge 300, various kinds of well-known centrifuges may be used. The centrifuge 300 includes a second supply pipe 310. The second supply pipe 310 is in communication with the second extension tube 215 receives the stem cells proliferated from the stem cell multiplier 200.

The first supply pump 410 pumps the stem cells extracted by the stem cell extractor 100 and the growth medium supplied by the growth medium supply unit 230 to the growth tube 210. The second supply pump 420 pumps the stem cells proliferated by the stem cell multiplier 200 to the centrifuge 300. Substantially, the pumping of the stem cells and the proliferation medium extracted by the first supply pump 410 and the pumping of the stem cells proliferated by the second supply pump 420 may be performed by the first extension pipe part 213 and, respectively. In a state in which the first supply pipe 110 is in communication, or in a state in which the second extension pipe part 215 and the second supply pipe 310 are in communication, it will be made.

Hereinafter, with reference to the accompanying drawings, the stem cell continuous proliferation, extraction and separation method according to an embodiment of the present invention will be described in more detail.

Figure 2 is a flow chart showing a method of continuous proliferation, extraction and separation of stem cells according to the first embodiment of the present invention.

Referring to Figure 2, the stem cell continuous proliferation, extraction and separation method according to the present embodiment, stem cell extraction step (S100), extracted stem cells and proliferation medium supply step (S200), stem cell proliferation step (S300), Proliferating stem cell supply step (S400) and stem cell separation step (S500).

More specifically, in the stem cell extraction step (S100), stem cells are extracted from the sample by the stem cell extractor (100). As described above, the extraction of stem cells by the stem cell extractor 100 may use a well-known technique, and thus a detailed description thereof will be omitted.

Next, in the extracting stem cells and proliferation medium supply step (S200), the proliferation medium for proliferation of the stem cells and stem cells extracted in the stem cell extraction step (S100) is a stem cell multiplier 200, substantially proliferating Supplied to the tube 210. More specifically, the stem cells extracted from the stem cell extractor 100 and the growth medium supplied by the growth medium supply unit 230 may be pumped to the growth tube 210 by the first supply pump 410. will be. Supply of the extracted stem cells and proliferation medium, the first extension tube portion 213 and the first supply tube 110 is communicated by the first opening and closing unit 241, the second extension tube portion 215 and the second supply tube ( The 310 is separated by the second opening and closing unit 242, it will be made through the first extension pipe portion 213 and the first supply pipe 110.

And in the stem cell growth step (S300), the stem cells supplied to the growth tube 210 in the extracting stem cells and growth medium supply step (S200) is proliferated inside the growth tube 210. In this embodiment, in the stem cell proliferation step (S300), rotation of the growth tube 210 and circulation of the stem cells and the growth medium in the growth tube 210, substantially the spiral tube portion 211 is made.

More specifically, in the stem cell proliferation step (S300), the first and second extension tube portion 213, 215 and the first and second supply tube 110, 310 is the first and second In the state separated by the opening / closing unit 241 or 242, the rotation driving unit 250 rotates the growth tube 210. In the stem cell proliferation step (S300), the first and second extension pipe parts 213 and 215 and the first and second supply pipes 110 and 310 are connected to the first and second opening and closing units 241. In a state separated by 242), the circulation pump 260 pumps the stem cells and the growth medium to circulate the growth pipe 210.

In addition, the stem cell growth step (S300), the temperature control by the temperature control unit 270 and the air supply by the air supply unit 280 is also made. That is, in the stem cell growth step (S300), the temperature control unit 270, the temperature for the growth of stem cells in the growth tube 210, the air supply unit 280, the growth Air is supplied to the inside of the pipe (210).

Finally, in the proliferating stem cell supplying step (S400) and the stem cell separation step (S500), supply of the proliferated stem cells to the centrifuge 300, and separation of the components of the stem cells in the centrifuge 300 Is done. In the proliferating stem cell supplying step (S400), the first extension pipe part 213 and the first supply pipe 110 are separated by a first opening and closing unit 241, the second extension pipe part 215 and the second. In the state in which the supply pipe 310 is separated by the second opening and closing unit 242, the stem cells proliferated through the second extension pipe part 215 and the second supply pipe 310 are separated from the stem cell multiplier 200. It will be supplied to the centrifuge 300. In addition, in the stem cell separation step (S500), in the state in which the second extension tube part 215 and the second supply tube 310 are separated by the second opening and closing unit 242, by the centrifuge 300 Stem cells will be separated by component.

In particular, in the present embodiment, the stem cell extraction by the stem cell extractor 100, the proliferation of stem cells by the stem cell multiplier 200 and the separation of the stem cells by component centrifuge 300 It is done continuously. To this end, when the extraction of the stem cells and the growth medium supply step (S200) is completed, the stem cell extraction step (S100) is initiated regardless of the completion of the stem cell growth step (S300). In addition, when the proliferating stem cell supply step (S400) is completed, regardless of the completion of the stem cell separation step (S500), the extracted stem cells and proliferation medium supply step (S200) is started. Therefore, in this embodiment, continuous stem cells can be proliferated, extracted, and separated by components.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various modifications and adaptations within the scope of the claims are made by those skilled in the art. It is self evident.

Hereinafter, with reference to the accompanying drawings, the stem cell continuous proliferation, extraction and separation system according to a second embodiment of the present invention will be described in more detail.

Figure 3 is a schematic view showing a stem cell continuous proliferation, extraction and separation system according to a second embodiment of the present invention. For the same components as those of the first embodiment of the present invention described above among the components of the present embodiment, reference numerals of FIG. 1 are used, and detailed description thereof will be omitted.

Referring to FIG. 3, the stem cell continuous proliferation, extraction and separation system 2 according to the present embodiment further includes a tilting unit 290. The tilting unit 290 tilts the growth tube 210, substantially the growth tube 210 and the growth vessel 220 at a predetermined tilting angle. However, in the present embodiment, the 'tilting angle' will be set in a range in which the spiral tube portion 211 can be inclined at an angle of more than 0 ° and 45 ° or less with respect to the horizontal plane.

Claims (21)

1. The spiral tube portion 211 formed in a spiral shape, the first extension tube portion 213 and the spiral extending from one end of the spiral tube portion 211 and receiving a growth medium for proliferation of stem cells and stem cells extracted from the outside A proliferation tube 210 including a second extension tube portion 215 extending from the other end of the tube portion 211 to supply stem cells proliferated to the outside, and proliferating the stem cells;

   A growth medium supply unit 230 for supplying a growth medium to the growth pipe 210;

   A first opening / closing unit 241 for selectively communicating / separating the first extension tube part 213 with the first supply tube 110 for supplying the stem cells extracted into the growth tube 210;

   A second opening and closing unit 242 for selectively communicating / separating the second extension tube part 215 with a second supply tube 310 for supplying stem cells proliferated in the growth tube 210; And

   A rotation drive unit 250 for rotating the growth tube 210; Including,

   When the stem cells and the proliferation medium extracted to the spiral tube part 211 are supplied, the first and second extension tube parts 213 and 215 and the first and second opening and closing units 241 and 242 are supplied. Stem cell multiplier in which the growth pipe 210 is rotated by the rotation drive unit 250 in a state in which the first and second supply pipes (110) (310) are separated.
2. The method of claim 1,

   The growth tube 210 is connected to one side of the spiral tube portion 211 adjacent to the first extension tube portion 213 or one side of the first extension tube portion 213, and the second extension tube portion ( Further comprising a circulation pipe portion 217 that the other end is connected to the other side of the spiral tube portion 211 adjacent to the 215 or one side of the second extension tube portion 215,

   In a state where the first and second extension pipe parts 213 and 215 and the first and second supply pipes 110 and 310 are separated by the first and second opening and closing units 241 and 242, And a circulation pump (260) for pumping stem cells and proliferation medium from one end of the helix tube portion (211) to one end so that the stem cells and the growth medium circulate through the helix tube portion (211).
3. The method of claim 2,

   At least the spiral tube portion 211, the stem cell multiplier is disposed inclined at an angle of more than 0 ° and less than 45 ° with respect to the horizontal plane.
4. The method of claim 1,

   The propagation tube 210 is disposed therein, further comprising a growth vessel 220 which rotates together with the growth tube 210 by the rotation drive unit 250 further stem cell proliferator.
5. The method of claim 1,

   Stem cell multiplier further comprises a temperature control unit for adjusting the temperature for the proliferation of stem cells in the growth tube 210.
6. The method of claim 1,

   Stem cell multiplier further comprises an air supply unit (280) for supplying air to the growth pipe (210).
7. In the stem cell proliferation method using the stem cell multiplier of claim 1:

   A step of supplying the extracted stem cells and the propagation medium, wherein the proliferation medium for proliferation of the extracted stem cells and stem cells is supplied to the growth tube 210; And

   Stem cell proliferation step of proliferating inside the growth tube 210, the stem cell (S300); Stem cell proliferation method comprising a.
8. The method of claim 7, wherein

   In the extracting stem cells and proliferation medium supply step (S200),

   The first extension pipe part 213 and the first supply pipe 110 communicate with each other by the first opening / closing unit 241, and the second extension pipe part 215 and the second opening by the second opening / closing unit 242. Stem cell proliferation method in which the stem cells and the proliferation medium extracted through the first extension tube portion 213 and the first supply tube 110 in a state in which the supply tube 310 is separated are supplied to the growth tube 210.
9. The method of claim 7, wherein

   In the stem cell proliferation step (S300),

   The first and second extension pipe parts 213 and 215 and the first and second supply pipes 110 are rotated by the rotation driving unit 250 by the first and second opening and closing units 241 and 242. Stem cell proliferation method for rotating the growth tube 210 in the state 310 is separated.
10. The method of claim 7, wherein

    In the stem cell proliferation step (S300),

    Stem cell proliferation method, the circulation pump 260, the stem cells and proliferation medium is pumped to circulate the growth pipe (210).
11. The method of claim 7, wherein

    In the stem cell proliferation step (S300),

    Temperature control unit 270, to adjust the temperature for the proliferation of stem cells in the growth tube 210,

    Stem cell proliferation method that the air supply unit 280, supplying air into the growth tube 210.
12. A stem cell extractor 100 for extracting stem cells from a sample;

    A stem cell multiplier according to any one of claims 1 to 6 for receiving and proliferating the stem cells extracted from the stem cell extractor 100; And

    A centrifugal separator 300 for receiving the stem cells proliferated from the stem cell multiplier 200 and separating the stem cells by components; Stem cell continuous proliferation, extraction and separation system comprising a.
13. The method of claim 12,

    The stem cell extractor 100 includes a first supply pipe 110 for supplying the stem cells extracted in communication with the first extension tube part 213 to the stem cell multiplier 200,

    The centrifuge 300, the stem cell continuous proliferation, extraction and the stem cell comprising a second supply pipe 310 receives the stem cells proliferated in communication with the second extension tube portion 215 from the stem cell multiplier 200 Separation system.
14. The method of claim 13,

    Stem cells and the proliferation medium supply unit extracted by the stem cell extractor 100 in a state where the first extension pipe part 213 and the first supply pipe 110 communicate with each other by the first opening and closing unit 241. Stem cell continuous proliferation, extraction and separation system further comprises a first supply pump 410 for pumping the growth medium supplied by 230 to the growth tube 210.
15. The method of claim 13,

    In the state in which the second extension pipe part 215 and the second supply pipe 310 are in communication with each other by the second opening and closing unit 242, the stem cells proliferated by the stem cell multiplier 200 are centrifugal separator 300. Stem cell continuous proliferation, extraction and separation system further comprises a second feed pump (420) for pumping.
16. 13. A method of continuously proliferating, extracting and isolating stem cells using the stem cell continuous proliferation, extraction and isolation system of claim 12:

    Stem cells, the stem cell extraction step is extracted by the stem cell extractor (100) (S100);

    Extracting stem cells and proliferation medium supplied with the proliferation medium for proliferation of the stem cells and the stem cells extracted in the stem cell extraction step (S100) to the proliferation tube 210 (S200);

    A stem cell proliferation step of proliferating the stem cells supplied to the proliferation tube 210 in the extracting stem cells and the proliferation medium supplying step (S200) inside the proliferation tube 210 (S300);

    Proliferating stem cell supply step (S400) is the stem cells proliferated in the stem cell proliferation step (S300) is supplied to the centrifuge (300); And

    A stem cell separation step of separating the stem cells supplied by the proliferating stem cell supplying step (S400) for each component by the centrifuge 300 (S500); Stem cell continuous proliferation, extraction and separation method comprising a.
17. The method of claim 16,

    In the extracting stem cells and proliferation medium supply step (S200),

    The first extension pipe part 213 and the first supply pipe 110 communicate with each other by the first opening / closing unit 241, and the second extension pipe part 215 and the second opening by the second opening / closing unit 242. In a state in which the supply pipe 310 is separated, the stem cells extracted from the stem cell extractor 100 through the first extension pipe part 213 and the first supply pipe 110 and from the growth medium supply unit 230. Stem cell continuous proliferation, extraction and separation method, the growth medium is supplied to the growth tube (210).
18. The method of claim 16,

    In the stem cell proliferation step (S300),

    The first and second extension pipe parts 213 and 215 and the first and second supply pipes 110 are rotated by the rotation driving unit 250 by the first and second opening and closing units 241 and 242. Stem cell continuous proliferation, extraction and separation method for rotating the growth tube 210 in a separated state (310).
19. The method of claim 16,

    In the stem cell proliferation step (S300),

    The circulation pump 260 is connected to the first and second extension pipe parts 213 and 215 and the first and second supply pipes 110 and 310 by the first and second opening and closing units 241 and 242. Stem cell continuous proliferation, extraction and separation method in which the stem cells and proliferation medium are transported to circulate the growth tube 210 in the isolated state.
20. The method of claim 16,

    When the extraction of the stem cell and growth medium supply step (S200) is completed, regardless of the completion of the stem cell growth step (S300), the stem cell extraction step (S100) is a continuous proliferation, extraction and separation method.
21. The method of claim 16,

    When the proliferating stem cell supply step (S400) is completed, regardless of the completion of the stem cell separation step (S500), the extraction of the stem cells and proliferation medium supply step (S200) is a continuous proliferation, extraction and separation method.

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