KR20230145820A - Microfluidic channel device, system and method for drug screening using the same - Google Patents

Abstract

The microfluidic channel device according to the present invention, the drug screening system using the same, and the method thereof include culturing dopaminergic neurons regardless of the culture type, injecting a candidate drug for treating Parkinson's disease into the cultured cells, and determining the efficacy of the drug. It is about technology to verify.

Description

Microfluidic channel device, drug screening system and method using the same {Microfluidic channel device, system and method for drug screening using the same}

The present invention relates to a microfluidic channel device, a drug screening system using the same, and a method thereof. The present invention relates to a microfluidic channel device for culturing dopaminergic neurons to verify the efficacy of a drug for treating Parkinson's disease, a drug screening system using the same, and It's about how.

Parkinson's disease, which is well known as a representative degenerative brain disease along with Alzheimer's dementia, is known to be caused by a breakdown in the homeostasis of dopamine in the brain.

In detail, there are various neurotransmitters in our brain, and among them, there is a neurotransmitter called dopamine (involved in reward (pleasure), motivation, exercise, and hormone secretion in the brain) that is essential for exercise. Parkinson's disease is a disease in which nerve cells that secrete dopamine are gradually lost without cause in a specific part of the brain called the substantia nigra located in the midbrain. Parkinson's patients suffer from bradykinesia (slow movement), resting tremor, muscle rigidity, and postural instability. Symptoms occur.

In other words, as dopamine homeostasis is not maintained normally, brain diseases such as schizophrenia, depression, and epilepsy, as well as Parkinson's disease, occur.

In order to study the mechanisms and treatment methods for the invention of these brain diseases, studies aimed at uncovering the relationship between dopamine concentration in the brain and brain diseases are being conducted using various models (cell models, animal models, etc.).

For example, in the past, dopamine homeostasis was monitored by analyzing current values measured according to the concentration of dopamine secreted from dopamine neurons. However, in this case, since the concentration of dopamine secreted from the cell is only measured and the dopamine concentration itself within the cell is not measured, there is a problem in that the response of the cell itself due to external stimulation (drug injection, etc.) cannot be verified. .

In this regard, Korean Patent Publication No. 10-2009-0104923 (“Dopaminergic neurons and proliferative-competent progenitor cells for the treatment of Parkinson's disease”) discloses more optimized neural cells for use in the treatment of specific clinical conditions. We are launching a technology to improve the group.

Korean Patent Publication No. 10-2009-0104923 (publication date 2009.10.06.)

Therefore, the present invention was devised to solve the problems described above, and the purpose of the present invention is to provide a microfluidic channel device capable of culturing dopaminergic cells regardless of the culture type.

In addition, we provide a drug screening system and method that can relatively quickly verify the effect of the drug on cells by continuously controlling the degree of injection of the drug for treating Parkinson's disease into cultured cells through closed-loop control. there is.

A microfluidic channel device according to an embodiment of the present invention to solve the problems described above is a microfluidic channel device in which injected fluid flows in a certain direction, including a substrate and a microfluidic channel element stacked on top of the substrate. The microfluidic channel element includes at least two fluid inlets, a fluid mixing channel for moving and mixing fluids injected from the two fluid inlets, and a cell to which the mixed fluid is supplied by the fluid mixing channel. It is preferable to include a fluid movement channel formed between the culture chamber and the fluid mixing channel and the cell culture chamber to move the mixed fluid.

Furthermore, the cell culture chamber preferably has a predetermined height, but the height of the outlet side of the fluid movement channel is lower than the height of the inlet side of the cell culture chamber.

Furthermore, the substrate is preferably coated on the area in contact with the bottom surface of the cell culture chamber using a predetermined material.

Furthermore, it is preferable that the substrate is coated with a predetermined material on the area in contact with the bottom surface of the microfluidic channel element.

Furthermore, the microfluidic channel element includes a cell injection port for injecting cells to be cultured in the cell culture chamber, and a cell injection channel formed between the cell injection port and the cell culture chamber to move the cells injected from the cell injection port. and a fluid discharge unit connected to the cell culture chamber and discharging the fluid supplied by the fluid transfer channel to the outside.

Furthermore, it is preferable that the substrate is made of glass, and the microfluidic channel element is made of polydimethylsiloxane (PMDS).

A drug screening system using a microfluidic channel device according to an embodiment of the present invention to solve the problems described above is, according to any one of claims 1 to 6, a method for performing screening by drugs. A microfluidic channel device for cultivating cells, an optical sensor unit for observing the cells through an observation area formed on an upper portion of the microfluidic channel device, and a control signal coupled to at least two fluid injection ports of the microfluidic channel device and inputting the control signal. Receives sensing data from the injection unit and the optical sensor unit, which controls the injection level of the drug injected into the cell, analyzes the fluorescence intensity value of the cell, and controls the operating state of the injection unit according to the analysis results. It is desirable to include an analysis control unit that generates the control signal.

Furthermore, the optical sensor unit preferably transmits numerical data analyzing the fluorescence intensity value of the cells for a preset region of interest as the sensing data.

Furthermore, it is preferable that the optical sensor unit transmits the observation image data of the cell as the sensing data, and the analysis control unit analyzes the fluorescence intensity value of the cell for a preset region of interest in the observation image data.

Furthermore, it is preferable that the analysis control unit uses a preset reference brightness value to generate a control signal so that the drug is injected through the injection unit when the analyzed fluorescence intensity value is less than the reference brightness value.

Furthermore, the analysis control unit preferably generates a control signal to stop the injection of the drug through the injection unit if the analyzed fluorescence intensity value exceeds the reference brightness value after the drug is injected through the injection unit. do.

Furthermore, it is preferable that the analysis control unit applies a closed-loop control method to repeatedly inject the drug or stop the injection of the drug through the injection unit.

Furthermore, the drug screening system preferably further includes a screening analysis unit that analyzes the degree of response of the cell to the drug by calculating a change in fluorescence intensity of the cell corresponding to the control signal by the analysis control unit. do.

In order to solve the problems described above, the drug screening method using a microfluidic channel device according to an embodiment of the present invention includes the analysis control unit receiving sensing data observing cells cultured in the microfluidic channel device from the optical sensor unit. A data input step, an intensity analysis step in which the analysis control unit analyzes the fluorescence intensity value of the cell using the sensing data from the data input step, and the analysis control unit analyzes the intensity using a preset reference brightness value. A determination step of determining the fluorescence intensity value analyzed by the step and a control step of controlling, in the analysis control unit, the degree of injection of the drug injected into the cell through the microfluidic channel device according to the determination result of the determination step. It is desirable to repeat the above steps by applying a closed-loop control method.

Furthermore, the control step performs an injection control step to control injection of the drug into the cell through the microfluidic channel device when the fluorescence intensity value is below the reference brightness value according to the determination result of the determination step. It is desirable to do so.

Furthermore, the control step is preferably performed to stop injection of the drug into the cell through the microfluidic channel device when the fluorescence intensity value exceeds the reference brightness value.

Furthermore, the drug screening method is a screening analysis in which the degree of response of the cell to the drug is analyzed by calculating the fluorescence intensity change value of the cell corresponding to the degree of injection of the drug by the control step in the screening analysis unit. It is desirable to include further steps.

Furthermore, it is preferable that the screening analysis step calculates the amount of drug injected by the injection control step.

Furthermore, in the data input step, it is preferable to receive numerical data obtained by analyzing the fluorescence intensity value of the cells for a preset region of interest as the sensing data.

Furthermore, the data input step receives observation image data of the cell as the sensing data, and the intensity analysis step preferably analyzes the fluorescence intensity value of the cell for a preset region of interest in the observation image data. .

Furthermore, the drug screening method preferably further includes a cell culture step of culturing cells for which drug screening is to be performed using a microfluidic channel device before performing the data input step.

The microfluidic channel device according to a preferred embodiment of the present invention not only allows the cells being cultured to be safely confined to the cell culture chamber without a microstructure installed to restrain the position of the cells, by controlling the formation height of the cell culture chamber. , it has the advantage of increasing the range of cells that can be cultured.

In addition, the drug screening system and method using a microfluidic channel device according to a preferred embodiment of the present invention can continuously simulate drug administration and can verify how the drug affects the maintenance of cellular dopamine concentration homeostasis. This allows the efficacy of candidate drugs to be verified more accurately.

1 is an exemplary diagram showing a microfluidic channel device according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing a microfluidic channel device according to an embodiment of the present invention.
Figure 3 is an exemplary diagram showing a process of injecting cells into a cell culture chamber of a microfluidic channel device according to an embodiment of the present invention.
Figures 4 and 5 are diagrams illustrating the configuration of a drug screening system using a microfluidic channel device according to an embodiment of the present invention.
Figure 6 is an exemplary flow diagram showing a drug screening method using a microfluidic channel device according to an embodiment of the present invention.

Hereinafter, the microfluidic channel device of the present invention, the drug screening system and method using the same will be described in detail with reference to the attached drawings. The drawings introduced below are provided as examples so that the idea of the present invention can be sufficiently conveyed to those skilled in the art. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. Additionally, like reference numerals refer to like elements throughout the specification.

At this time, if there is no other definition in the technical and scientific terms used, they have meanings commonly understood by those skilled in the art to which this invention pertains, and the gist of the present invention is summarized in the following description and attached drawings. Descriptions of known functions and configurations that may unnecessarily obscure are omitted.

The microfluidic channel device, the drug screening system using the same, and the method according to an embodiment of the present invention include culturing cells to be targeted (Parkinson's disease-infected cells, in vitro PD model) through the microfluidic channel device, It relates to a technology that can monitor the degree of change in cellular dopamine levels in real time by injecting a candidate drug to be screened into a fluid channel device, thereby verifying the efficacy of the candidate drug.

First, let's look at the microfluidic channel device according to an embodiment of the present invention. As shown in FIGS. 1 to 3, it is comprised of a substrate and a microfluidic channel element stacked on top of the substrate. At this time, the fluid flow of the microfluidic channel device is controlled so that the injected fluid flows in a constant direction.

The microfluidic channel device according to an embodiment of the present invention is not limited to the stacking process of the substrate and the microfluidic channel element, and is bonded to each other by oxygen plasma treatment according to a commercial technology, or stacked without a separate bonding process. It can be applied in various ways.

However, in the microfluidic channel device according to an embodiment of the present invention, the substrate is preferably formed of a glass substrate, and the microfluidic channel element is preferably made of polydimethylsiloxane (PDMS).

Polydimethylsiloxane is a transparent polymer material used in various fields such as biology, medicine, pharmacy, materials engineering, and mechanical engineering. Due to its excellent bio-compatibility, it has recently been used as an organ-on-a-chip. ) is being used in research, etc.

An organ simulation chip is an in vitro device that can simulate the physiology and medical/pharmaceutical characteristics of human organs, and is used as a test bed that can replace human subjects in pharmaceutical research. In consideration of this, the microfluidic channel device according to an embodiment of the present invention also utilizes polydimethylsiloxane as the microfluidic channel element and cultivates cells, thereby preventing degenerative brain diseases (in particular, dopaminergic brain diseases). Screening is performed to detect drugs that are effective against Parkinson's disease, etc.

As shown in FIGS. 1 and 2, the microchannel fluidic device includes a fluid inlet, a fluid mixing channel, a cell culture chamber, and a loading channel. It is desirable that it be configured to include.

At this time, the fluid inlet is preferably composed of at least two fluid inlets, as shown in FIG. 1.

A cell culture medium is injected into one of the at least two fluid inlets, and a compound that causes cell function and state regulation or a candidate drug to be screened is injected into the other one. Therefore, the micro-channel fluid device forms at least two fluid injection ports, and additional injection ports may be formed as needed, so the number of two or more is not limited. Additionally, the injection of fluid is preferably performed through a syringe pump connected to the outside of the microfluidic channel device.

As shown in FIGS. 1 and 2, the fluids injected from the at least two fluid injection ports are mixed as they pass through the fluid mixing channel.

The cell culture chamber is supplied with a mixed fluid through the fluid mixing channel, thereby cultivating cells. All types of cells used for experimental purposes in biological experiments are possible, including cell lines, primary culture cells, and patient-derived cells.

The fluid mixing channel and the cell culture chamber are connected through the fluid movement channel, and through this, the fluid mixed by the fluid mixing channel is moved to the cell culture chamber through the fluid movement channel.

At this time, the microfluidic channel device according to an embodiment of the present invention is formed so that cells can be cultured in both two-dimensional (monolayer) and three-dimensional (spheroid, cell mixed with gel) forms through the cell culture chamber.

In detail, as shown in FIG. 2, the cell culture chamber is formed to have a predetermined height, so that the height of the inlet side of the cell culture chamber is higher than the height of the outlet side of the fluid movement channel.

More specifically, by forming the cell culture chamber to have a thickness of 250 ㎛, cells can be cultured in a three-dimensional form through the cell culture chamber. In other words, by increasing the height of the cell culture chamber from 70 ㎛, which is the typical height of the fluid movement channel (configuration located at the front end of the cell culture chamber), it becomes possible to cultivate cells with a three-dimensional shape.

If you simply increase the height of all channels through which fluid moves, a phenomenon occurs in which cells in culture cannot be located in the cell culture chamber and leak into the fluid movement channel, or go beyond the fluid movement channel and into the fluid mixing channel. I do it.

In order to solve this problem, the conventional microfluidic channel device installs a microstructure between the fluid movement channel (or the fluid mixing channel) and the cell culture chamber to constrain the position of the cells to the cell culture chamber. However, it is natural that there are technical difficulties in installing microstructures in microfluidic channel devices where cells that can be observed under a microscope are cultured.

Therefore, the microfluidic channel device according to an embodiment of the present invention can not only safely confine cells in culture to a cell culture chamber without a microstructure installed to confine the position of the cells, but also can secure the height of the cell culture chamber. There is an advantage in that the range of cells that can be cultured can be increased by controlling .

In addition, the microfluidic channel device is configured to further include a cell injection port, a cell injection channel, and a fluid outlet, as shown in FIGS. 1 to 3.

The cell injection port injects cells to be cultured in the cell culture chamber, and the cell injection channel is provided between the cell injection port and the cell culture chamber to move the cells injected from the cell injection port to the cell culture chamber. is formed.

The fact that the cell injection port is not formed at the top of the cell culture chamber and is provided in a location different from the cell culture chamber means that when observing the cell culture chamber through an optical sensor unit (microscope, etc.) later, the cell injection port is not formed at the top of the cell culture chamber. This is to minimize the influence on the observation area of the optical sensor unit.

Additionally, the fluid discharge unit is connected to the cell culture chamber and discharges the fluid supplied by the fluid movement channel to the outside. That is, the fluid injected through the fluid inlet is discharged to the outside of the fine oil channel element through the fluid discharge part.

Typically, cells cultured in the cell culture chamber can be cultured for a long period of time (up to a month) through the supply of cell culture medium continuously injected from the fluid inlet.

In addition, the microfluidic channel device according to an embodiment of the present invention coats the substrate using a preset material.

With respect to the coating area of the substrate, the coating layer is most preferably applied to the area in contact with the bottom surface of the cell culture chamber or, in some cases, to the entire bottom surface of the microfluidic channel element, that is, to the entire upper surface of the substrate. It can also be formed.

Preset substances include compounds that help cell attachment and differentiation, extracellular matrix, and recombinant proteins (for example, PLL, PDL, collagen, matrigel, laminin), etc., and help cell attachment and differentiation. It is most desirable to perform coating treatment on the substrate in the area in contact with the bottom surface of the cell culture chamber as it is configured for function.

Figures 4 and 5 are diagrams illustrating the configuration of a drug screening system using a microfluidic channel device according to an embodiment of the present invention.

As shown in FIGS. 4 and 5, the drug screening system using the microfluidic channel device includes a microfluidic channel device, an optical sensor unit, an injection unit, and an analysis control unit.

To learn more about each configuration,

As described above, the microfluidic channel device is formed so that the height of the inlet side of the cell culture chamber is higher than the height of the outlet side of the fluid movement channel, so that not only two-dimensional cells but also three-dimensional cells can be cultured, Cells for which screening is to be performed can be cultured without restrictions on their form.

To explain the cell culture process using the microfluidic channel device,

First, steady-state cells that can be cultured in the micro rape channel device are prepared from the outside and injected through the cell injection port.

Afterwards, retinoic acid is injected through any fluid injection port selected so that the injected steady-state cells can be differentiated into dopaminergic neurons. At this time, the cell culture medium is injected through another fluid inlet.

In order to monitor the dopamine concentration in these dopaminergic neurons, a protein dopamine sensor (dLight) is injected through one of the fluid injection ports to infect the dopaminergic neurons. This is to sense the dopamine concentration of the cell through fluorescence intensity. At this time, the cell culture medium is injected through another fluid inlet.

dLight is a sensor that senses the amount of dopamine inside a cell using fluorescence intensity, and can estimate the intracellular dopamine concentration by observing the fluorescence intensity of the cell using an optical sensor unit (for example, a microscope, etc.).

Afterwards, MPP+, an inducing drug for Parkinson's disease, is injected through one of the above fluid injection ports to create an in vitro Parkinson's disease model (PD model), thereby completing cell culture.

In addition, as described above, the microfluidic channel device includes at least two fluid inlets, and the concentration of the fluid injected through each fluid inlet is adjusted by changing the injection flow rate of the syringe pump.

The above-described process is a cell culture process for application to drug screening for treating Parkinson's disease using dopaminergic neurons, and is not limited thereto. In other words, in some cases, in order to screen therapeutic drugs for various diseases, cells with various diseases other than dopaminergic neurons can be cultured, and the cell shape can be in two-dimensional as well as three-dimensional form as described above. can also be cultured, allowing drug screening to be performed more easily.

The drug screening system using the microfluidic channel device verifies the efficacy of the candidate drug by injecting the candidate drug to be screened into the cultured in vitro PD model and monitoring the dopamine level of the in vitro PD model.

The optical sensor unit is a means for observing the cells (cultured in vitro PD model) through an observation area formed on the top of the microfluidic channel device, and preferably includes a microscope, etc.

The injection unit is coupled to at least two fluid injection ports of the microfluidic channel device, and is preferably configured to include a syringe pump, etc. as a means for controlling the injection level of the candidate drug injected into the cell by an input control signal. do.

As an example of the process of controlling the inflow of fluid through the injection unit, when a cell culture medium is injected through the first fluid inlet, compounds (e.g., retinoic acid, dLight, and MPP+) are injected through the second fluid inlet. etc.) Alternatively, the candidate drug is injected. If the total flow rate injected through the two injection ports is fixed at 10 and the injection flow rate of the cell culture medium is reduced from 9 to 1, at the same time, the fluid injection flow rate through another fluid inlet increases from 1 to 9. I do it. Through this, the concentration of the compound or candidate drug flowing into the cell culture chamber through the fluid mixing channel and the fluid movement channel is controlled.

In particular, controlling the concentration of a candidate drug is a key function in performing screening for a candidate drug by deriving a drug control value that can maintain a normal dopamine level in a drug screening system using a microfluidic channel device, which will be described later.

The analysis control unit receives sensing data from the optical sensor unit, analyzes the fluorescence intensity value of the cell (cultured in vitro PD model), and, according to the analysis result, sends the control signal to control the operating state of the injection unit. will be created. For this purpose, it is most preferable that the analysis control unit is an arithmetic processing means including a computer.

In addition, as described above, in order to more easily explain the analysis of the fluorescence intensity value of the cell for application to drug screening for the treatment of Parkinson's disease using dopaminergic neurons, the characteristic value of the cell to be analyzed is the fluorescence intensity. Although it is limited to a value, of course, in order to apply it to therapeutic drug screening for cells suffering from various diseases, the characteristic value of the cell to be analyzed can be replaced with a characteristic value other than the fluorescence intensity value.

The analysis control unit receives the sensing data from the optical sensor unit, and the optical sensor unit generates and transmits numerical data that analyzes the fluorescence intensity value for a preset region of interest within the cell (cultured in vitro PD model). Alternatively, observation image data of the cells (cultured in vitro PD model) are transmitted.

Most preferably, numerical data analyzing the fluorescence intensity value for a preset region of interest within the cell (cultured in vitro PD model) is generated and transmitted as the sensing data. To do this, in advance, the cell ( A region of interest (ROI) is set for the cultured in vitro PD model area.

Of course, even when the analysis control unit receives the observation image data of the cells (cultured in vitro PD model) from the optical sensor unit as the sensing data, a preset region of interest is used to detect the area of interest corresponding to the region of interest. The fluorescence intensity value is analyzed.

In other words, the cells (cultured in vitro PD model) are observed through an observation area formed at the top of the microfluidic channel device (most preferably, at the top of the cell culture chamber), and the entire cell culture chamber is observed. Since the cells are not cultured tightly in the area, a region of interest where fluorescence intensity values can be analyzed is set in advance among the cell areas, and the fluorescence intensity value for the region of interest is analyzed as numerical data through the optical sensor unit. Then, the fluorescence intensity value for the region of interest is analyzed from the observed image data.

The analysis control unit uses the fluorescence intensity value to control the operating state of the injection unit.

In detail, generating the cells (cultured in vitro PD model) through the microfluidic channel device is not limited to injecting MPP+, an inducing drug for Parkinson's disease, through the above-mentioned processes, but also injecting it. Afterwards, when the fluorescence intensity value analyzed by the analysis control unit through observation from the optical sensor unit becomes lower than the preset reference brightness value, it is determined that the creation of the final cultured in vitro PD model is complete, and then drug screening is performed. It will proceed.

When drug screening proceeds, the analysis control unit uses a preset reference brightness value to generate the control signal so that the candidate drug is injected through the injection unit.

At this time, if the fluorescence intensity value analyzed by the analysis control unit is lower than the preset reference brightness value, it is determined that the creation of the final cultured in vitro PD model is completed, and then drug screening is performed, so the analysis control unit After determining that the creation of the cultured in vitro PD model is finally complete, it generates the control signal so that the candidate drug is injected through the injection unit.

Accordingly, the injection unit is controlled to inject the candidate drug through the fluid injection unit through manipulation of the syringe pump.

In connection with this, the efficacy of the cell disease caused by injection of the candidate drug is verified through the change in the fluorescence intensity value analyzed by the analysis control unit through observation from the optical sensor unit.

The analysis control unit not only verifies that the candidate drug is effective for the disease, but also continuously observes from the optical sensor unit after the candidate drug is injected through the injection unit through closed-loop control. When the fluorescence intensity value analyzed by the analysis control unit exceeds a preset reference brightness value, the control signal is generated to stop injection of the candidate drug through the injection unit.

Here, the preset reference brightness value is a fluorescence intensity value according to the dopamine concentration of cells in a steady state, that is, the dopamine concentration of cells in a steady state to establish a standard for the cultured in vitro PD model to have alleviated the disease to a normal cell state. It is desirable to set the fluorescence intensity value accordingly.

The analysis control unit repeats the above-described control process and repeatedly controls the injection and cessation of injection of the candidate drug into the cells (cultured in vitro PD model). Through this, the treatment progress according to drug administration can be screened.

That is, the analysis control unit uses a preset reference brightness value, and when the fluorescence intensity value for the region of interest of the cell (cultured in vitro PD model) falls below the reference brightness value, the injection unit containing the candidate drug is activated. It is operated to cause injection of the candidate drug, and when the fluorescence intensity value of the region of interest of the cell (cultured in vitro PD model) exceeds the reference brightness value according to the injection of the candidate drug, the The operation of the injection unit is stopped to screen the treatment progress according to drug administration.

Through this, drug administration can be simulated by continuously repeating drug injection/stop drug injection and simultaneously analyzing the fluorescence intensity value for the region of interest of the cell (cultured in vitro PD model) using the reference brightness value. It is possible to verify how the drug affects the maintenance of cellular dopamine concentration homeostasis, thereby verifying the efficacy of the candidate drug.

To this end, the drug screening system using a microfluidic channel device according to an embodiment of the present invention is configured to further include a screening analysis unit, as shown in FIGS. 4 and 5.

The screening analysis unit determines the fluorescence intensity change value of the cell as the injection/stop of injection of the candidate drug into the cell (cultured in vitro PD model) according to the control signal from the analysis control unit. By calculating the fluorescence intensity change value of the cell corresponding to the control signal by the analysis control unit, the degree of response of the cell to the candidate drug is analyzed.

In other words, the screening analysis unit performs analysis to verify how the candidate drug affects the maintenance of cellular dopamine concentration homeostasis, and the efficacy of the candidate drug is verified using the analysis results.

In addition, the screening analysis unit can estimate the amount of candidate drug injected into the cell according to the control signal from the analysis control unit.

Simply, the injection amount of the candidate drug can be estimated using the operation time of the injection unit and the controlled injection flow rate.

Alternatively, the point where the candidate drug substantially affects the cell is the point where the fluorescence intensity value exceeds the reference brightness value, and the injection of the candidate drug is stopped because the fluorescence intensity value of the cell exceeds the reference brightness value. However, considering the fact that the already injected candidate drug is affecting the cells, not only the operation time of the injection unit and the controlled injection flow rate, but also the point at which the fluorescence intensity value of the cell exceeds the reference brightness value Again, the injected amount of the candidate drug can be estimated through integration based on the point at which the fluorescence intensity value inflects and decreases.

As shown in FIG. 6, the drug screening method using a microfluidic channel device according to an embodiment of the present invention includes a data input step, an intensity analysis step, a judgment step, and a control step, and each step is performed using a computer. It is performed by a drug screening system operating in an arithmetic processing unit comprising:

To learn more about each step,

In the data input step, the analysis control unit receives sensing data observing cells cultured in the microfluidic channel device from the optical sensor unit.

At this time, the drug screening method using the microfluidic channel device further performs a cell culture step before performing the data input step, as shown in FIG. 6.

In the cell culture step, cells for which drug screening is to be performed are cultured using the microfluidic channel device.

In detail, first, steady-state cells that can be cultured in the micro rape channel device are prepared from the outside and injected through the cell injection port.

Afterwards, retinoic acid is injected through any fluid injection port selected so that the injected steady-state cells can be differentiated into dopaminergic neurons. At this time, the cell culture medium is injected through another fluid inlet.

In order to monitor the dopamine concentration in these dopaminergic neurons, a protein dopamine sensor (dLight) is injected through one of the fluid injection ports to infect the dopaminergic neurons. This is to sense the dopamine concentration of the cell through fluorescence intensity. At this time, the cell culture medium is injected through another fluid inlet.

dLight is a sensor that senses the amount of dopamine inside a cell using fluorescence intensity, and can estimate the intracellular dopamine concentration by observing the fluorescence intensity of the cell using an optical sensor unit (for example, a microscope, etc.).

Afterwards, MPP+, an inducing drug for Parkinson's disease, is injected through one of the above fluid injection ports to create an in vitro Parkinson's disease model (PD model), thereby completing cell culture.

In the intensity analysis step, the analysis control unit analyzes the fluorescence intensity value of the cell (in vitro PD model) using the sensing data from the data input step.

At this time, in the data input step, the analysis control unit receives the sensing data from the optical sensor unit, and the optical sensor unit determines the fluorescence intensity value for a preset region of interest within the cell (cultured in vitro PD model). Numerical data analyzed is generated and transmitted, or observation image data of the cells (cultured in vitro PD model) is transmitted.

Most preferably, numerical data analyzing the fluorescence intensity value for a preset region of interest within the cell (cultured in vitro PD model) is generated and transmitted as the sensing data. To do this, in advance, the cell ( A region of interest (ROI) is set for the cultured in vitro PD model area.

Of course, when the analysis control unit receives observation image data of the cell (cultured in vitro PD model) as the sensing data from the optical sensor unit, the intensity analysis step uses a preset region of interest to determine the area of interest. The fluorescence intensity value corresponding to the area is analyzed.

In other words, the cells (cultured in vitro PD model) are observed through an observation area formed at the top of the microfluidic channel device (most preferably, at the top of the cell culture chamber), and the entire cell culture chamber is observed. Since the cells are not cultured tightly in the area, a region of interest where fluorescence intensity values can be analyzed is set in advance among the cell areas, and the fluorescence intensity value for the region of interest is analyzed as numerical data through the optical sensor unit. Then, the fluorescence intensity value for the region of interest is analyzed from the observed image data.

In the determination step, the analysis control unit determines the fluorescence intensity value analyzed by the intensity analysis step using a preset reference brightness value.

At this time, generating the cells (cultured in vitro PD model) through the microfluidic channel device in the cell culture step is not limited to injecting MPP+, an inducing drug for Parkinson's disease, through the above-described processes. , After injection, if the fluorescence intensity value analyzed by the analysis control unit through observation from the optical sensor unit becomes lower than the preset reference brightness value, it is determined that the creation of the final cultured in vitro PD model is complete. , drug screening will be conducted.

Therefore, the first operation of the determination step is to determine whether screening of the candidate drug can proceed through injection of the candidate drug, and the subsequent operation is to determine whether to inject/stop the injection of the candidate drug.

That is, because drug screening must be performed, the control step performs drug screening when the fluorescence intensity value analyzed by the intensity analysis step is less than or equal to a preset reference brightness value according to the judgment result of the initial operation of the judgment step. begins.

To start drug screening, the control step is performed through the microfluidic channel device when the fluorescence intensity value analyzed by the intensity analysis step is less than or equal to a preset reference brightness value according to the judgment result of the determination step. An injection control step is performed to generate the control signal so that the candidate drug can be injected into the cell.

The drug screening method using a microfluidic channel device according to an embodiment of the present invention applies a closed-loop control method to repeatedly perform the above steps.

Through this, the control step determines that, according to the judgment result of the determination step, if the fluorescence intensity value analyzed by the intensity analysis step exceeds a preset reference brightness value, in other words, injection of the candidate drug into the cell When the efficacy of the candidate drug appears, an injection interruption step is performed to generate the control signal to stop the injection of the candidate drug into the cell.

The drug screening method using a microfluidic channel device according to an embodiment of the present invention repeatedly performs the above-described steps and repeatedly controls the injection and cessation of injection of the candidate drug into the cells (cultured in vitro PD model). , Through this, the treatment progress according to drug administration can be screened.

That is, the analysis control unit uses a preset reference brightness value, and when the fluorescence intensity value for the region of interest of the cell (cultured in vitro PD model) falls below the reference brightness value, the injection unit containing the candidate drug is activated. It is operated to cause injection of the candidate drug, and when the fluorescence intensity value of the region of interest of the cell (cultured in vitro PD model) exceeds the reference brightness value according to the injection of the candidate drug, the The operation of the injection unit is stopped to screen the treatment progress according to drug administration.

Through this, drug administration can be simulated by continuously repeating drug injection/stop drug injection and simultaneously analyzing the fluorescence intensity value for the region of interest of the cell (cultured in vitro PD model) using the reference brightness value. It is possible to verify how the drug affects the maintenance of cellular dopamine concentration homeostasis, thereby verifying the efficacy of the candidate drug.

To this end, the drug screening method using a microfluidic channel device according to an embodiment of the present invention further performs a screening analysis step, as shown in FIG. 6.

In the screening analysis step, the screening analysis unit calculates a change in fluorescence intensity of the cell corresponding to the degree of drug injection by the control step to analyze the degree of response of the cell to the candidate drug.

In other words, the fluorescence intensity change value of the cell as the injection/stop of injection of the candidate drug into the cell (cultured in vitro PD model) according to the control signal, that is, the control by the analysis control unit. By calculating the change in fluorescence intensity of the cell corresponding to the signal, the degree of response of the cell to the candidate drug is analyzed. Through this, analysis is performed to verify how the candidate drug affects the maintenance of cellular dopamine concentration homeostasis, and the efficacy of the candidate drug is verified using the analysis results.

In addition, the screening analysis unit can estimate the amount of candidate drug injected into the cell according to the control signal from the analysis control unit.

Simply, the injection amount of the candidate drug can be estimated using the operation time of the injection unit and the controlled injection flow rate.

Alternatively, the point where the candidate drug substantially affects the cell is the point where the fluorescence intensity value exceeds the reference brightness value, and the injection of the candidate drug is stopped because the fluorescence intensity value of the cell exceeds the reference brightness value. However, considering the fact that the already injected candidate drug is affecting the cells, not only the operation time of the injection unit and the controlled injection flow rate, but also the point at which the fluorescence intensity value of the cell exceeds the reference brightness value Again, the injected amount of the candidate drug can be estimated through integration based on the point at which the fluorescence intensity value inflects and decreases.

As described above, the present invention has been described with reference to specific details such as specific components and drawings of limited embodiments, but this is only provided to facilitate a more general understanding of the present invention, and the present invention is not limited to the above-mentioned embodiment. No, those skilled in the art can make various modifications and variations from this description.

Accordingly, the spirit of the present invention should not be limited to the described embodiments, and all matters that are equivalent or equivalent to the claims of this patent as well as the claims described below shall fall within the scope of the spirit of the present invention. .

Claims (21)

In a microfluidic channel device where the injected fluid flows in a certain direction,
Board;
It includes a microfluidic channel element stacked on top of the substrate,
The microfluidic channel device is
at least two fluid inlets;
a fluid mixing channel that moves and mixes the fluids injected from each of the two fluid injection ports;
a cell culture chamber to which the mixed fluid is supplied by the fluid mixing channel; and
a fluid movement channel formed between the fluid mixing channel and the cell culture chamber to move the mixed fluid;
Including, microfluidic channel device.
According to clause 1,
The cell culture chamber is
It has a preset height,
The height of the outlet side of the fluid movement channel is
lower than the height of the entrance side of the cell culture chamber,
Characterized by a microfluidic channel device.
According to clause 2,
The substrate is
Coating the area in contact with the bottom of the cell culture chamber using a predetermined material,
Characterized by a microfluidic channel device.
According to clause 2,
The substrate is
Coating the area in contact with the bottom surface of the microfluidic channel element using a preset material,
Characterized by a microfluidic channel device.
According to clause 2,
The microfluidic channel device is
a cell injection port for injecting cells to be cultured in the cell culture chamber;
a cell injection channel formed between the cell injection port and the cell culture chamber to move cells injected from the cell injection port; and
a fluid discharge unit connected to the cell culture chamber and discharging the fluid supplied by the fluid transfer channel to the outside;
A microfluidic channel device further comprising:
According to clause 2,
The substrate is made of glass,
The microfluidic channel element is made of polydimethylsiloxane (PMDS),
Characterized by a microfluidic channel device.
According to any one of claims 1 to 6, a microfluidic channel device for culturing cells for which screening by drugs is to be performed;
An optical sensor unit that observes the cells through an observation area formed on the top of the microfluidic channel device;
an injection unit that is coupled to at least two fluid injection ports of the microfluidic channel device and controls the degree of drug injection into the cell by an input control signal; and
An analysis control unit that receives sensing data from the optical sensor unit, analyzes the fluorescence intensity value of the cell, and generates the control signal to control the operating state of the injection unit according to the analysis result;
Including, drug screening system.
According to clause 7,
The optical sensor unit
A drug screening system that transmits numerical data obtained by analyzing the fluorescence intensity value of the cell for a preset region of interest as the sensing data.
According to clause 7,
The optical sensor unit
Transmitting the observation image data of the cell to the sensing data,
The analysis control unit
A drug screening system that analyzes the fluorescence intensity value of the cell for a preset region of interest in the observation image data.
According to clause 7,
The analysis control unit
A drug screening system that generates a control signal to inject the drug through the injection unit when the analyzed fluorescence intensity value is less than or equal to the reference brightness value using a preset reference brightness value.
According to clause 10,
The analysis control unit
After the drug is injected through the injection unit, if the analyzed fluorescence intensity value exceeds the reference brightness value, a control signal is generated to stop the injection of the drug through the injection unit.
According to clause 11,
The analysis control unit
A drug screening system that applies a closed-loop control method to repeatedly inject the drug through the injection unit or stop the injection of the drug.
According to clause 12,
The drug screening system is
a screening analysis unit that analyzes the degree of response of the cell to the drug by calculating a change in fluorescence intensity of the cell corresponding to the control signal from the analysis control unit;
Further comprising a drug screening system.
A data input step of receiving, in the analysis control unit, sensing data observing cells cultured in the microfluidic channel device from the optical sensor unit;
In the analysis control unit, an intensity analysis step of analyzing the fluorescence intensity value of the cell using the sensing data from the data input step;
A determination step of determining, in an analysis control unit, the fluorescence intensity value analyzed by the intensity analysis step using a preset reference brightness value; and
A control step of controlling, in the analysis control unit, the degree of injection of the drug injected into the cell through the microfluidic channel device according to the determination result of the determination step;
Includes,
A drug screening method performed on a computer, in which the above steps are repeatedly performed by applying a closed-loop control method.
According to clause 14,
The control step is
An injection control step of controlling injection of the drug into the cell through the microfluidic channel device when the fluorescence intensity value is below a reference brightness value according to the determination result of the determination step;
A drug screening method for performing a.
According to clause 14,
The control step is
When the fluorescence intensity value exceeds the reference brightness value, an injection interruption step of controlling injection of the drug into the cell through the microfluidic channel device to be stopped;
A drug screening method for performing a.
According to claim 15 or 16,
The drug screening method is
A screening analysis step of analyzing the degree of response of the cell to the drug by calculating, in the screening analysis unit, a change in fluorescence intensity of the cell corresponding to the degree of injection of the drug by the control step;
A drug screening method performed on a computer, further comprising:
According to clause 17,
The screening analysis step is
A drug screening method performed on a computer, which calculates the injection amount of drug by the injection control step.
According to clause 14,
The data input step is
A drug screening method performed on a computer, in which numerical data obtained by analyzing the fluorescence intensity value of the cell for a preset region of interest is input as the sensing data.
According to clause 14,
The data input step is
Receives observation image data of the cell as the sensing data,
The intensity analysis step is
A drug screening method performed on a computer, analyzing the fluorescence intensity value of the cell for a preset region of interest in the observation image data.
According to clause 14,
The drug screening method is
Before performing the above data entry steps,
A cell culture step of culturing cells for which screening by drugs is to be performed using a microfluidic channel device;
Further comprising a drug screening method.