KR20230072901A - CO2 Incubator - Google Patents

Abstract

The present invention relates to a CO2 incubator for culturing cells under a CO2 gas condition of a certain concentration, and a mixture of a culture gas such as CO2 and water vapor is supplied into a culture chamber.
The CO2 incubator according to the present invention mixes a main body forming the overall appearance, a culture chamber provided inside the main body, and water vapor and culture gas installed outside the culture chamber to create a culture environment inside the culture chamber and supplied to the inside of the culture chamber. It is configured to include a mixed supply module to. As a result, it is possible to uniformly adjust the internal temperature and humidity of the culture chamber, thereby preventing the cells from drying out while maintaining a high humidity suitable for cell culture.

Description

CO2 Incubator {CO2 Incubator}

The present invention relates to an incubator for culturing cells, and more particularly, to a CO2 incubator for culturing cells under a constant concentration of CO2 culture conditions.

The CO2 incubator is a device that helps cell growth by artificially simulating conditions similar to in vivo in vitro for cell culture. Research and actual biopharmaceutical production for biopharmaceutical development, including antibody new drug or vaccine development It is an essential equipment used for

It is known that most mammalian cells, including human-derived cells, are cultured well at 37°C, pH 7.2-7.4, which is similar to human body temperature. To this end, the CO2 gas concentration in the incubator during cell culture is generally maintained at 5%, which means that sodium bicarbonate (NaHCO3) used as a buffer in the liquid medium is equilibrated with the dissolved CO2 gas to keep the pH of the medium constant. make it possible

In addition, in order to cultivate cells that require a strict O2 gas concentration condition as a culture condition, it is necessary to control the O2 gas concentration in the culture space together with the CO2 gas concentration control. In general, in adjusting the O2 gas concentration, O2 is supplied to the culture space when the set O2 gas concentration is low, and N2 gas is supplied to the culture space when the set O2 gas concentration is high.

On the other hand, in the culture space of the CO2 incubator, it is necessary to control the humidity to be maintained at 90% or more to promote the cultivation of cells and the like. As a means of humidifying the culture space, humidification in which water is stored A tray is installed on the bottom surface of the culture space, and the humidification of the culture space is performed by moisture naturally evaporated from the humidification tray.

As described above, since cells are sensitively affected by the surrounding environment, cell culture can be effectively performed in an incubator that provides optimal conditions for cell growth, such as temperature, humidity, and CO2 gas concentration.

However, in the conventional CO2 incubator, CO2 gas, O2 gas, and N2 gas supplied to control the gas concentration in the culture space are directly supplied to the culture space in a dry state. When the dried gas is supplied to the inside of the culture space, the uniformity of humidity is broken, and in particular, the cells around the area where the gas is supplied in the culture space become dry, which can adversely affect cell growth. .

In addition, since the temperature of the gas supplied to the culture space is generally lower than the temperature inside the culture space (37 ° C), condensation occurs due to the temperature gradient (temperature difference) around the area where the gas is supplied in the culture space. Contamination of the inside of the culture space by condensate may adversely affect cell growth.

Korean Registration No. 10-1827291

Korean Publication No. 10-2010-0056017

The basic task of the present invention is to solve the problem of drying the sample by directly supplying dried culture gas from the CO2 incubator to the culture space and the problem of condensation due to the temperature gradient.

Other objects and technical features of the present invention are presented more specifically by the following detailed description, claims and drawings.

The CO2 incubator according to the present invention for solving the above problems is a main body constituting the overall appearance of the device, a culture chamber provided inside the casing, and water vapor and culture installed outside the culture chamber to create a culture environment inside the culture chamber. It is composed of a mixing supply module for mixing and supplying gas into the culture chamber.

Here, the mixed supply module according to the first embodiment of the present invention includes a water reservoir for storing water, a housing located above the water reservoir and creating a steam space in which steam is generated by heating the water, Water vapor and gas forming a gas inlet formed on one side of the housing through which the culture gas flows into the water reservoir and a path formed on the other side of the housing through which the steam and culture gas are mixed and supplied to the inner space of the culture chamber Including supply.

At this time, a heater for heating the water and a water level sensor for detecting the water level are provided in the water reservoir.

On the other hand, the mixing supply module according to the second embodiment of the present invention includes a housing with an empty interior, a gas inlet formed on one side of the housing through which the culture gas flows into the housing, and a gas inlet on the other side of the housing. It includes a steam inlet through which the steam is introduced into the housing, and a steam and gas supply part formed on the other side of the housing to form a path through which the steam and the culture gas are mixed and supplied to the inner space of the culture chamber.

At this time, the housing is provided with a heater for heating the culture gas and water vapor.

In addition, the mixed supply module according to the third embodiment of the present invention is connected to the humidification tank for generating water vapor, and the steam is sucked by increasing the flow rate of the culture gas flowing into the inlet to obtain the water vapor and the culture gas. It includes an ejector that discharges together, and an outlet of the ejector forms a path through which the water vapor and the culture gas are mixed and supplied to the inner space of the culture chamber.

At this time, a heater for heating the culture gas and water vapor is provided inside the ejector.

Here, the gas inlet according to each embodiment includes a plurality of gas inlets through which CO2 gas, O2 gas, or N2 gas flows.

Meanwhile, the housing has a cylindrical shape and the gas inlet is formed at an eccentric position of the housing. At this time, when the steam inlet is further formed, it is preferable that the gas inlet and the steam inlet are respectively formed at eccentric positions in different directions of the housing.

In the present invention, since water vapor is contained in the culture gas supplied to the culture chamber forming the culture space, it is possible to maintain the uniformity of humidity inside the culture chamber, and in particular, to prevent the drying of cells around the region where the culture gas is supplied. There is a preventive effect.

In addition, the present invention can maintain the uniformity of the temperature by supplying the culture gas into the culture chamber in a state where it is heated to a predetermined temperature, and in particular, it is possible to prevent condensation due to the temperature gradient around the area where the gas is supplied. It works.

1 is a perspective view of the CO2 incubator of the present invention;
2 is a cross-sectional view of a CO2 incubator according to a first embodiment of the present invention;
Figure 3 is a cross-sectional view of the mixing supply module shown in Figure 2;
4 is a cross-sectional view of a mixing supply module according to a second embodiment of the present invention;
5 is a cross-sectional view of a mixing supply module according to a third embodiment of the present invention;
6 is a perspective view showing the external appearance of the mixing supply module according to the first and second embodiments of the present invention.

Since the present invention can apply various transformations and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, it should be understood that this is not intended to limit the present invention to specific embodiments, and includes all transformations, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings, and in the description with reference to the accompanying drawings, the same or corresponding components are assigned the same reference numerals, and overlapping descriptions thereof are omitted. do it with

Figure 1 is a perspective view of the CO2 incubator of the present invention, Figure 2 is a cross-sectional view of the CO2 incubator according to the first embodiment of the present invention, Figure 3 is a cross-sectional view of the mixing supply module shown in Figure 2, Figure 4 is a second embodiment of the present invention 5 is a cross-sectional view of the mixed supply module according to the third embodiment of the present invention, and FIG. 6 is a perspective view showing the external appearance of the mixed supply module according to the first and second embodiments of the present invention. am.

1 to 2, the CO2 incubator of this embodiment includes a main body 10 constituting the overall appearance of the device, a culture chamber 20 for culturing cultured cells, and opening and closing the front opening of the culture chamber 20. The door 11, the heater 70 for maintaining the temperature of the culture chamber 20 at a constant temperature, and gas and water vapor are supplied together to maintain the gas concentration and humidity of the culture chamber 20 in a constant range. It is composed of a mixing supply module 30 and the like.

The main body 10 constitutes the overall appearance of the CO2 incubator, and has an open front surface, and a space for culturing cells is created inside. The main body 10 is provided with a door 11 for opening and closing the front opening. The door 11 is composed of a double door of an inner door 11a and an outer door 11b. The inner door 11a is made of a transparent glass plate or the like that allows the inside of the culture space to be seen through. A gasket is installed around the door 11 so that the culture space can be sealed from the outside. In addition, although not shown in the drawings, a display for operating and displaying temperature, gas concentration, humidity, and the like is installed on one side of the main body 10 .

The culture chamber 20, which creates a culture space, is made of a thermally conductive material in the shape of a rectangular parallelepiped with an open front surface and installed inside the main body 10. A heater 70 for heating the inner space of the culture chamber 20 is installed between the culture chamber 20 and the main body 10 . In addition, on the left and right sides constituting the culture chamber 20, a plurality of holders 21 on which shelves on which containers containing cultured cells are placed are mounted protrude vertically at regular intervals. In the culture chamber 20, each wall constituting a rectangular parallelepiped may be welded to each other, or may be integrally manufactured without a joint by a deep drawing method. Corners of each wall constituting the culture chamber 20 are preferably rounded to prevent bacteria from proliferating.

The heater 70 heats the inner space of the culture chamber 20 by a six-side direct heating method disposed on six surfaces constituting the outer surface of the culture chamber 20 with hot wires. More specifically, the heater 70 It is installed on the outer surface forming the top, bottom, left and right sides, and rear of the culture chamber 20 between the culture chamber 20 and the main body 10, and is built-in to the inner door 11a. Due to this, the heater 70 can be heated on all sides of the culture chamber 20, that is, on six sides.

Meanwhile, although not shown in the drawings, a temperature sensor, a CO2 gas concentration sensor, an O2 gas concentration sensor, a humidity sensor, and the like are provided inside the culture chamber 20 . All of these sensors are connected to the control unit built into the body 10, and based on the detection of these sensors, the heater, the CO2 gas solenoid valve, the O2 gas solenoid valve, and the N2 gas solenoid valve are controlled, and a mixing supply module described later. (30) is also controlled.

The CO2 incubator of the present invention is designed with a structure in which the culture gases (CO2 gas, O2 gas, and N2 gas) supplied to control the gas concentration of the culture chamber 20 absorb moisture and supply it to the culture chamber. (20) It is designed to maintain internal temperature and humidity uniformity.

To this end, the CO2 incubator of the present invention has a structure in which culture gas is mixed with water vapor and supplied to the culture chamber 20 . More specifically, the first embodiment (Figs. 2 and 3) in which the culture gas is supplied to the culture chamber 20 by directly passing through a humidification tank generating water vapor, and the humidification tank without the culture gas directly passing through the humidification tank It is divided into second and third embodiments (FIGS. 4 and 5), which are mixed with steam generated in and supplied to the culture chamber 20. Here, the second embodiment is a method in which the culture gas and water vapor are naturally mixed, and the third embodiment is a method in which the water vapor is forcibly mixed by an ejector principle according to an increase in the flow rate of the culture gas.

All of the above-described first to third embodiments are based on a structure in which culture gas and water vapor are mixed outside the culture chamber 20 and supplied to the inside of the culture chamber 20 . This is because when mixing is performed inside the culture chamber 20, various gas pipes and water supply pipes must pass through the culture chamber 20 and extend to the inside, so it is very difficult to install the pipe and connect the structure. ) Not only cannot efficiently utilize the internal space of the humidifier, but in the process of mixing gas and water in the humidification tank, water is discharged to the culture chamber 20 and can contaminate the floor, and the mixing path of gas and water vapor is short This is because there is a problem in that sufficient mixing is not achieved.

Referring first to the first embodiment with reference to FIGS. 2 and 3 , a mixing supply module 30 for mixing culture gas and steam and supplying them to the culture chamber 20 is installed on the rear surface of the main body 10 . The mixing supply module 30 in the present invention is installed outside the culture chamber 20, not in the inner space of the culture chamber 20, and adopts an external humidification method in which water vapor is supplied from the outside of the culture chamber 20 . Therefore, even if the mixed supply module 30 is installed in a different location of the main body 10 or in a separate space separated from the main body 10 instead of the back of the main body 10, the culture gas and water vapor are delivered to the culture chamber 20 together. Any structure that can be supplied can be applied.

The mixing supply module 20 includes a housing 31 constituting an exterior, a gas inlet 34 through which gas flows into the housing 31, and a path through which steam and culture gas are mixed and supplied to the inner space of the culture chamber 20. It is composed of water vapor and gas supply port 35 to create a.

The housing 31 is made of an enclosed space with an empty inside, and a water storage tank filled with water used to maintain the humidity of the culture chamber 20 at a predetermined value (eg, 90%) or higher ( 32) and a steam space 33 in which steam is generated by heating water.

A water inlet 35 through which water flows in from the outside is formed on the bottom surface of the housing 31 constituting the water storage tank 32 . And, as shown in FIG. 2, a water supply tank 40 for storing water supplied to the housing 31 is provided below the housing 31, and one end of a water supply pipe is connected to the water supply tank 40. The other end of the water supply pipe is connected to the water inlet 35 of the housing 31. The water stored in the water supply tank 40 is supplied to the water storage tank 32 through the water supply pipe and the water inlet 35. Between the water supply tank 40 and the housing 31, a water supply pump 50 for forcibly raising water in the water supply tank 40 is installed. The water supply tank 40 may be directly filled with water by the user or may be connected to a drainage facility at the installation site to supply water. A water level sensor 41 is installed in the water supply tank 40 to notify a user of a time to supply water to the water supply tank 40 or a failure.

In addition, the water storage tank 32 is provided with a heater 36 for heating water. During operation of the humidification module, water is heated by the heater and steam is generated. The generated water vapor is supplied into the culture chamber 20 together with the culture gas. In addition, the water tank 32 is provided with a water level sensor 37 for maintaining a constant water level. When the water level in the reservoir 32 is reduced due to the generation of steam, water is automatically replenished in the water tank 40 by the detection of the water level sensor 37 .

Here, the gas inlet 34 is formed on one side of the housing 31 forming a space in which the water storage tank 32 is formed. Accordingly, the culture gas may flow into the reservoir 32 and sufficiently absorb moisture while rising in the water, and then may be supplied to the culture chamber 20 while being mixed with water vapor generated in the steam space 33.

At this time, the gas inlet 34 basically introduces CO2 gas. However, in the case of culturing cells that require strict O2 gas concentration conditions as culture conditions among cultured cells, a plurality of the gas inlets 34 need to be provided. Specifically, a CO2 gas inlet 34a through which CO2 gas flows, an O2 gas inlet 34b into which O2 gas flows, and an N2 gas inlet 34c into which N2 gas flows are respectively provided. The respective gas inlets 34a, 34b, and 34c are connected to gas cylinders 61, 62, and 63 for CO2, O2, and N2 gas through gas supply pipes. Gases having a predetermined CO2 concentration (5% concentration), O2 concentration, and N2 concentration are supplied to the culture chamber 20 through each gas supply pipe through an electronic valve (not shown). In this embodiment, both the O2 gas and the N2 gas are supplied to control the 02 concentration, but it is also possible to supply only one of them, if necessary.

As described above, in the first embodiment of the present invention, the culture gas is supplied to the culture chamber 20 by directly passing through the water storage tank 32 in which water is heated to generate water vapor. Accordingly, the culture gas is supplied to the culture chamber 20 while being mixed with water vapor after sufficiently absorbing moisture while rising in the water in the reservoir 32, compared to the conventional method of directly supplying dry gas to the culture chamber. The uniformity of the internal humidity can be maintained. In particular, it is possible to prevent the drying of the cells around the region where gas is supplied into the culture chamber. Furthermore, temperature uniformity of the culture chamber 20 can be maintained as the culture gas is mixed with high-temperature water vapor in a state where the temperature is elevated to a certain level while passing through the heated water and supplied to the culture chamber 20, and in particular, the gas It is possible to prevent condensation due to the temperature gradient around the supplied area.

4 is a cross-sectional view illustrating a mixing supply module 30 according to a second embodiment of the present invention. Referring to FIG. 4 , the second embodiment is different from the first embodiment in that the culture gas is mixed with water vapor generated in the reservoir and supplied to the culture chamber 20 without directly passing through the reservoir.

More specifically, the mixing supply module 30 includes a housing 31 having an empty interior, a gas inlet 34 formed on one side of the housing 31 through which culture gas flows into the housing 31, and a housing It is formed on the other side of (31) and consists of a steam inlet 38 through which steam flows into the housing 31. At this time, the steam inlet 38 is connected to a steam supply pipe connected to a humidification tank for heating water, although not shown in the figure. And, on the other side of the housing 31, steam and culture gas are mixed to form a culture chamber 20 A steam and gas supply unit 35 forming a path to be supplied to is formed. Accordingly, the culture gas introduced into the housing 31 is sufficiently mixed with water vapor inside the housing 31 to be humidified and then supplied to the culture chamber 20 .

Meanwhile, inside the housing 31, a heater 36 is installed long along the longitudinal direction of the housing 31. Accordingly, the culture gas may be supplied to the culture chamber 20 while being heated to a predetermined temperature (approximately 37 degrees) by the heater 36 while passing through the housing 31 .

5 is a cross-sectional view illustrating a mixing supply module 30 according to a third embodiment of the present invention. Referring to FIG. 5 , the third embodiment is the same as the second embodiment in that the culture gas is mixed with steam generated in the reservoir and supplied to the culture chamber without directly passing through the reservoir. However, in the third embodiment, there is a difference in that the culture gas and water vapor are forcibly mixed by the ejector principle by the flow rate (negative pressure) of the culture gas.

More specifically, the mixing supply module 30 is composed of a humidifier 80 that heats water to generate steam and an ejector 90 that increases the flow rate of the introduced gas. The ejector 90 is in the form of a tube having a certain length, at one end of which a gas inlet 34 through which culture gas flows is formed, and at the other end, gas and steam are discharged together to supply water vapor to the culture chamber 20. and a gas supply unit 35 is formed. In the middle of the ejector 90, a steam inlet 38 connected to the humidification tank 80 through a pipe and through which steam is sucked into the ejector 90 is formed. Immediately in front of the steam inlet 38 inside the ejector 90, a venturi unit 91 is formed that rapidly increases the flow rate of the culture gas because its cross-sectional area decreases in the flow direction of the culture gas.

As such, the flow rate of the culture gas can be increased through the venturi part 91 provided inside the ejector 90, thereby generating a negative pressure that provides a suction power of water vapor, and the negative pressure causes gas and water vapor to be instantaneously transported. It is possible to perform the function of sufficiently mixing and supplying the mixture to the culture chamber 20 .

Meanwhile, inside the ejector 90, a heater 36 is installed long along the longitudinal direction of the ejector 31. Accordingly, the culture gas may be supplied to the culture chamber 20 while being heated to a predetermined temperature (approximately 37 degrees) by the heater 36 while passing through the ejector 90 .

6 is a perspective view showing the exterior of the housing 31 of the mixing supply module 30 according to the first and second embodiments of the present invention.

The housing 31 is formed in a cylindrical shape, and the gas inlet 34 is formed at an eccentric position in the housing 31 . That is, when viewed from the front of the housing 31, the gas inlet 34 is formed in a tangential direction at the side rather than the center. As a result, the culture gas flowing into the gas inlet 34 forms a vortex flowing along the inner circumferential surface of the housing 31 so that it can be sufficiently mixed with the water inside the water storage tank 32 .

In the second embodiment, not only the gas inlet 34 but also the steam inlet 38 are formed at eccentric positions in the housing 31, so that the culture gas and the steam are mixed effectively. At this time, the gas inlet 34 and the steam inlet 38 are formed in different directions to maximize the mixing effect of the culture gas and steam. Specifically, the mixing effect can be maximized as the culture gas and water vapor introduced into the housing 31 collide with each other while forming vortices in different directions of the housing 31 .

In the above, each embodiment of the present invention has been described with reference to the drawings, but those skilled in the art can make the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. It will be appreciated that various modifications and variations may be made.

10: body 11: door
20: culture chamber 21: cradle
30: external humidification module 31: housing
32: water tank 33: steam space
34: gas inlet 35: gas and water vapor inlet
36: heater 37: water level sensor
38: steam inlet 40: water supply tank
41: water level sensor 50: pump
60: humidification supply unit 61: CO2 supply unit
62: O2 supply part 63: N2 supply part
70: heater 80: humidifier
90: ejector 91: venturi part

Claims (10)

Body 10 forming the overall appearance;
a culture chamber 20 provided inside the main body 10; and
A mixing supply module 30 installed outside the culture chamber 20 to mix water vapor and culture gas to create a culture environment inside the culture chamber 20 and supply it to the inside of the culture chamber 20; A CO2 incubator, characterized in that.
The method of claim 1,
The mixed supply module 30 is a housing 31 in which a water storage part 32 for storing water and a steam space 33 located above the water storage part 32 and generating water vapor by heating the water are formed. )class,
A gas inlet 34 formed on one side of the housing 31 and through which the culture gas flows into the water reservoir 32;
A CO2 incubator, characterized in that it comprises a steam and gas supply unit 35 formed on the other side of the housing 31 to form a path through which the steam and culture gas are mixed and supplied to the inner space of the culture chamber 20.
The method of claim 2,
The CO2 incubator, characterized in that the water reservoir (32) is provided with a heater (36) for heating the water and a water level sensor (37) for detecting the water level.
The method of claim 1,
The mixing supply module 30 includes a housing 31 with an empty inside,
A gas inlet 34 formed on one side of the housing 31 through which the culture gas flows into the housing 31;
A steam inlet 38 formed on the other side of the housing 31 and through which the steam flows into the housing 31;
A CO2 incubator, characterized in that it comprises a steam and gas supply unit 35 formed on the other side of the housing 31 to form a path through which the steam and culture gas are mixed and supplied to the inner space of the culture chamber 20.
The method of claim 4,
A CO2 incubator, characterized in that the housing (31) is provided with a heater (36) for heating the culture gas and water vapor.
The method of claim 1,
The mixed supply module 30 includes a humidifier 80 generating water vapor,
An ejector 90 connected to the humidifier 80 and sucking in the water vapor by increasing the flow rate of the culture gas flowing into the inlet 34 and supplying the water vapor and the culture gas to the culture chamber 20. A CO2 incubator, characterized in that.
The method of claim 6,
The CO2 incubator, characterized in that the ejector (90) is provided with a heater (93) for heating the culture gas and water vapor.
According to any one of claims 1 to 7,
The CO2 incubator, characterized in that the gas inlet (34) consists of a plurality of CO2 gas, O2 gas and N2 gas is introduced.
The method of claim 2,
The CO2 incubator, characterized in that the housing (31) is made of a cylindrical shape and the gas inlet (34) is formed at an eccentric position of the housing (31).
The method of claim 4,
The CO2 incubator, characterized in that the housing (31) is made of a cylindrical shape, and the gas inlet (34) and the steam inlet (28) are formed at eccentric positions in different directions of the housing (31).

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