KR102651182B1 - Incubator - Google Patents

Abstract

The present invention discloses an incubator. The incubator according to the present invention includes a well plate for cultivating samples, a carbon dioxide regulator for supplying carbon dioxide to the well plate, a humidity regulator for supplying water vapor to the well plate, and a carbon dioxide regulator and a humidity regulator for controlling the interior of the well plate to maintain a culture environment. The well plate includes a control unit that has a closed structure, a frame installed inside the frame, and is made of a transparent material so that the sample can be observed. A heater glass is installed inside the frame to maintain a constant temperature to prevent condensation. It is installed and is characterized by including a sensor unit that measures environmental information about the inside of the frame and a receiving unit that is installed inside the frame and has a plurality of wells to accommodate the sample.

Description

Incubator

The present invention relates to an incubator, and more specifically, to an incubator capable of observing samples in real time.

Recently, with the development of bio- and regenerative medicine-related fields, the use of cell culturing using incubators has tended to increase. In order to promote cell culture, it is necessary to prepare a culture space suitable for each cell, and incubators that control temperature, humidity, and atmosphere within the culture space have been developed.

In particular, in medical or biological science experiments, for example, each well of a plate-shaped device (e.g., a microplate, microtiter plate, etc.) in which a large number of concave parts, also called wells, are installed in an array. Biological samples such as cells are cultured in an incubator by injecting liquid or gel-like fluid (e.g., culture medium, medium, etc.).

However, in the past, in order to observe cells, the microplate was extracted from the incubator every day, the biological sample was observed and measured using an imaging device, and then returned to the incubator. As a result, the culture environment that was supposed to be maintained consistently was interrupted. This led to the problem of lack of reliability of observation results.

Therefore, there is a need for an incubator that can observe biological samples in real time while maintaining a constant culture environment.

Korean Patent Publication No. 10-1419915 (2014.07.09.)

The technical problem to be achieved by the present invention is to provide an incubator that allows real-time sample observation by preventing condensation on the well plate.

Another technical problem to be achieved by the present invention is to provide an incubator that minimizes carbon dioxide consumption and outflow to the outside by tightly packing well plates.

In order to achieve the above object, the incubator according to the present invention includes a well plate for cultivating a sample, a carbon dioxide control unit for supplying carbon dioxide to the well plate, a humidity control unit for supplying water vapor to the well plate, and the inside of the well plate is a culture environment. It includes a control unit that controls the carbon dioxide adjusting unit and the humidity adjusting unit to maintain the well plate, a frame having a closed structure, installed inside the frame, and made of a transparent material so that the sample can be observed, and at a constant temperature. A heater glass that maintains and prevents condensation, installed inside the frame, a sensor unit that measures environmental information about the inside of the frame, and a plurality of wells are formed to store the sample. It is characterized in that it includes a receiving portion for receiving.

In addition, it is characterized in that it further includes a main body in which the carbon dioxide adjustment unit, the humidity adjustment unit, and the control unit are installed inside, and the well plate is installed on the upper surface.

In addition, the heater glass is characterized in that a heating wire or electrode is disposed on the rear side to control the temperature.

Additionally, the sensor unit may include a temperature sensor for measuring the temperature inside the well plate, a carbon dioxide sensor for measuring the amount of carbon dioxide inside the well plate, and a humidity sensor for measuring humidity inside the well plate.

The incubator according to the present invention can prevent condensation on the well plate and enable real-time sample observation.

Additionally, by tightly packing the well plate, carbon dioxide consumption and the amount of leakage to the outside can be minimized.

Figure 1 is a block diagram for explaining an incubator according to the present invention.
Figure 2 is a diagram for explaining a well plate according to the present invention.
Figure 3 is an exploded view to explain the well plate according to the present invention.
Figure 4 is a diagram for explaining the incubator system according to the present invention.
Figure 5 is a diagram for explaining the interior of the main body according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. First, it should be noted that when adding reference numerals to components in each drawing, the same components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present invention, if a detailed description of a related known configuration or function is determined to be obvious to those skilled in the art or may obscure the gist of the present invention, the detailed description will be omitted.

Figure 1 is a block diagram for explaining an incubator according to the present invention.

Referring to FIG. 1, the incubator 10 includes a well plate 100, a carbon dioxide adjusting unit 200, a humidity adjusting unit 300, and a control unit 400. Additionally, the incubator 10 further includes a main body 500. The incubator 10 can observe samples in real time by preventing condensation on the well plate 100, and can minimize carbon dioxide consumption and the amount of outflow to the outside by tightly packing the well plate 100.

The well plate 100 is installed on the upper surface of the main body 500 and cultivates the sample. The well plate 100 includes wells that can accommodate samples, and the number of wells can be adjusted depending on the size of the well plate 100. The well plate 100 maintains a constant environment so that the cultured samples can be cultured in optimal conditions. Here, the constant environment may be temperature, humidity, amount of carbon dioxide, etc. The well plate 100 may include various sensors to maintain a constant internal environment, and transmits measurement data measured by the sensors to the control unit 400.

Meanwhile, the well plate 100 includes transparent glass so that the sample can be observed, and the transparent glass may be heater glass connected to the heater. Through this, the heater glass prevents temperature changes that may occur due to the supply of carbon dioxide or water vapor. In addition, the heater glass can prevent condensation that may occur on the glass by maintaining a constant temperature.

The carbon dioxide adjusting unit 200 supplies carbon dioxide to the inside of the well plate 100. The carbon dioxide adjusting unit 200 adjusts the amount of carbon dioxide using a carbon dioxide tank and a solenoid valve. The carbon dioxide tank stores carbon dioxide inside in gas form, and a regulator is installed at the top to control the pressure.

The humidity adjusting unit 300 supplies water vapor to the inside of the well plate 100. The humidity control unit 300 is equipped with water inside, and a gas such as air or carbon dioxide is injected from the outside. Through this, the humidity adjusting unit 300 generates water vapor as water inside and gas injected from the outside form bubbling. Here, the humidity adjusting unit 300 is limited to water as a material provided therein, but is not limited to this and may be an aqueous solution containing water or a solution not containing water.

The control unit 400 controls the carbon dioxide adjusting unit 200 and the humidity adjusting unit 300 to maintain a culture environment inside the well plate 100. That is, the control unit 400 controls the temperature, humidity, and amount of carbon dioxide inside the well plate 100 using measurement data received from the well plate 100. For example, the control unit 400 controls the well plate 100 so that the temperature of the heater glass increases when the temperature decreases, and controls the well plate 100 so that the temperature decreases when the temperature increases. The control unit 400 controls the carbon dioxide adjusting unit 200 to increase the amount of carbon dioxide supplied to the well plate 100 when the amount of carbon dioxide decreases, and controls the carbon dioxide adjusting unit 200 to lower the amount of carbon dioxide supplied to the well plate 100 when the amount of carbon dioxide decreases. ) is controlled. The control unit 400 controls the humidity adjustment unit 300 to increase the amount of water vapor supplied to the well plate 100 when the humidity decreases, and controls the humidity adjustment unit 300 to decrease the amount of water vapor supplied to the well plate 100 when the humidity increases. Control 300.

Figure 2 is a diagram for explaining the well plate according to the present invention, and Figure 3 is an exploded view for explaining the well plate according to the present invention.

Referring to FIGS. 2 and 3 , the well plate 100 includes a frame 110, a heater glass 130, a sensor unit 150, and a receiving unit 170.

The frame 110 is a support that supports the well plate 100 and has a closed structure. The frame 110 includes a first frame 111 disposed at the top and a second frame 113 disposed at the bottom. The first frame 111 is formed with a power jack 115, and the second frame 113 ) is formed with a carbon dioxide inlet 117 and a water vapor inlet 119. The power jack 115 is connected to an external power cable to supply power to the well plate 100. At this time, the well plate 100 can receive power from the power jack 115 and transmit the power supplied to the heater glass 130, sensor unit 150, etc. The carbon dioxide inlet 117 is a hole into which a tube supplying carbon dioxide from the carbon dioxide adjusting unit 200 is inserted. The water vapor inlet 119 is a hole into which a tube supplying water vapor from the humidity control unit 300 is inserted.

The heater glass 130 is installed inside the frame 110 and is made of a transparent material so that the sample can be observed. In addition, the heater glass 130 maintains a constant temperature to prevent condensation, thereby facilitating sample observation. The heater glass 130 includes a first heater glass 131 disposed at the top and a second heater glass 133 disposed at the bottom. The first heater glass 131 and the second heater glass 133 may be connected to a heating wire to maintain a constant temperature. At this time, the heating wire can be supplied with power by power transmitted from the power jack 115.

The sensor unit 150 is installed inside the frame 110 and measures environmental information about the inside of the frame 110. The sensor unit 150 includes a temperature sensor 151, a carbon dioxide sensor 153, and a humidity sensor 155. The temperature sensor 151 measures the temperature inside the well plate 100, the carbon dioxide sensor 153 measures the amount of carbon dioxide inside the well plate 100, and the humidity sensor 155 measures the temperature inside the well plate 100. Measure humidity. At this time, the temperature sensor 151, carbon dioxide sensor 153, and humidity sensor 155 can measure the environmental condition inside the well plate 100 in real time, and the measured measurement data is transmitted to the control unit 400. do.

The receiving part 170 is a holder installed inside the frame and formed with a plurality of wells to accommodate the sample. That is, the receiving portion 170 has a substantially circular cross-section and includes a well capable of holding a liquid or solid medium. At this time, the number of wells may vary depending on the size of the well plate 100. The receiving portion 170 accommodates the sample in the well and serves as a holder to hold a liquid or solid medium so that the sample can be cultured safely.

Figure 4 is a diagram for explaining the incubator system according to the present invention, and Figure 5 is a diagram for explaining the interior of the main body according to the present invention.

Referring to Figures 4 and 5, the incubator system includes an incubator 10, a screen display unit 20, an input unit 30, and an imaging unit (not shown).

The incubator 10 is formed as one structure. That is, the incubator 10 may be formed into a single structure including the well plate 100, the carbon dioxide adjusting unit 200, the humidity adjusting unit 300, and the control unit 400 through the main body 500. At this time, a transport means may be installed at the bottom of the main body 500 to facilitate movement. Here, the well plate 100, the carbon dioxide adjusting unit 200, the humidity adjusting unit 300, and the control unit 400 are connected with a tube or wire. In detail, the well plate 100 is connected to the circuit board 510 and the SMPS 510 to control the power supplied to the heating wire of the heater glass, and the carbon dioxide adjusting unit 200 is connected to the solenoid valve 510 to control carbon dioxide. Adjust the amount. Additionally, the incubator 10 may be equipped with a fan 570 to prevent the temperature inside the main body 500 from increasing.

The screen display unit 20 displays a screen so that the user can check the results analyzed by the control unit 400. The screen display unit 20 may be a monitor, TV, projector, etc. Here, the screen display unit 20 may be disposed on the upper surface of the main body 500 as shown in the drawing, but is not limited to this.

The input unit 30 receives user input. The input unit 30 can input information about the culture environment of the sample. The input unit 30 may be a keyboard, mouse, etc. Here, when the screen display unit 20 includes a touch screen function, the configuration of the input unit 30 may be omitted.

The imaging unit observes the sample cultured in the incubator 10. The imaging unit may be a microscope using optics. At this time, since condensation does not occur in the incubator 10, the imaging unit can make more accurate observations.

Although preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific preferred embodiments described above, and can be used in the technical field to which the invention pertains without departing from the gist of the present invention as claimed in the claims. Anyone skilled in the art can make various modifications, and such modifications fall within the scope of the claims.

10: Incubator 20: Screen display unit
30: input unit 100: well plate
110: frame 111: first frame
113: second frame 115: power jack
117: carbon dioxide inlet 119: water vapor inlet
130: heater glass 131: first heater glass
133: second heater glass 150: sensor unit
151: temperature sensor 153: carbon dioxide sensor
155: humidity sensor 170: receiving part
200: carbon dioxide control unit 300: humidity control unit
400: Control unit 500: Main body
510: circuit board 530: SMPS
550: solenoid valve 570: fan

Claims (4)

A well plate for culturing samples;
a carbon dioxide adjusting unit that supplies carbon dioxide to the well plate;
a humidity control unit supplying water vapor to the well plate; and
A control unit that controls the carbon dioxide adjusting unit and the humidity adjusting unit to maintain a culture environment inside the well plate,
The well plate is,
A frame having a closed structure;
A heater glass installed inside the frame, made of a transparent material so that the sample can be observed, and preventing condensation by maintaining a constant temperature;
A sensor unit installed inside the frame and measuring environmental information about the inside of the frame; and
It includes a receiving portion installed inside the frame and forming a plurality of wells to accommodate the sample,
The frame is,
a first frame disposed at the top, having a power jack supplied from the outside to transmit power to the heater glass and the sensor unit, and having an opening formed through a central portion; and
It is disposed at the lower part of the first frame, and a penetrating internal space in which the receiving part is installed is formed, the internal space communicates with the opening part of the first frame, and carbon dioxide is supplied from the carbon dioxide adjusting unit to the internal space. A second frame is formed with a carbon dioxide inlet that receives carbon dioxide and a water vapor inlet that receives water vapor from the humidity control unit to the internal space.
The heater glass is,
A first heater glass disposed on the upper part of the frame, interposed between the first and second frames and covering the upper part of the inner space of the second frame, the first heater exposed to the opening of the first frame The first heater glass through which the sample of the accommodation unit installed in the inner space of the second frame can be observed through the glass; and
a second heater glass disposed below the frame and covering the lower portion of the interior space of the second frame;
An incubator comprising: According to clause 1,
a main body in which the carbon dioxide adjusting unit, the humidity adjusting unit, and the control unit are installed inside, and the well plate is installed on the upper surface;
An incubator further comprising: According to clause 1,
The heater glass is,
An incubator characterized by a heating wire or electrode placed on the back to control the temperature. According to clause 1,
The sensor unit,
A temperature sensor that measures the temperature inside the well plate;
A carbon dioxide sensor that measures the amount of carbon dioxide inside the well plate; and
A humidity sensor that measures humidity inside the well plate;
An incubator comprising: