KR102298299B1 - Integrated cell separation device capable of centrifugation and magnetic separation - Google Patents

Abstract

The present invention provides a cell separation device, comprising: a centrifugation vessel which is rotated by a centrifugation module and accommodates a heterogeneous cell sample to be separated and a magnetic bead coated with an antibody that targets one type of cell among the heterogeneous cells; a pipette advancing and retreating in the direction of the centrifugation vessel to suck or spray the reagent loaded in the centrifugation vessel; and a magnetic material generating magnetic force around the pipette, enabling pretreatment of cells by centrifugation and cell separation by magnetic force.

Description

Integrated cell separation device capable of centrifugation and magnetic separation

The present invention relates to a cell separation apparatus for separating heterogeneous cells, and to an integrated cell separation apparatus capable of integrally performing centrifugation and magnetic separation.

Cells are the basic units that make up the body of an animal, and their shape differs according to each organ of the body. In order to diagnose various diseases occurring in the body, so far, it is common to perform a biopsy. However, as the accuracy of cell tests has improved recently, simple and accurate disease diagnosis has become possible. In particular, the importance of cytology is being emphasized in order to obtain a more accurate diagnosis while many patients avoid unnecessary biopsy.

For cell testing, it is necessary to extract a specific target cell of interest. In the case of isolating the target cell from a solid tissue, the target cell may be separated by determining the location through microscopic observation. However, in the case of separating cells in a liquid or mucus, such as amniotic fluid or blood, it is difficult to isolate only a desired target cell because various cells are complexed. Separating only desired target cells or removing unwanted cells in a solution in which cells having various and different properties are mixed are essential elements of cytology.

Recently, magnetic separation technology using magnetic force has been used in various forms in the fields of medical and biotechnology. Magnetic separation technology, due to scalability, efficiency, simplicity, non-demanding conditions, ease of automation, low cost, etc., the interest there is a growing trend. In the magnetic separation technology, after culturing a sample using magnetic particles that have high affinity for a desired target material and are sensitive to magnets, a strong magnet is introduced to separate unwanted materials by gravity or washing. That is, the target material or cell labeled with the magnetic particle is attracted toward the magnet by the magnetic force, and the remaining material or cell is removed by gravity or washing. The separation method using such magnetic force uses fine particles or beads having a diameter of about 10 nm to 20 μm.

In the process of isolating specific cells required from a complex of various components, such as amniotic fluid or blood, several centrifugation and extraction processes must be performed for pretreatment with a buffer for removing contaminants and washing. After that, after binding an antibody targeting a specific cell to be separated to a magnetic bead to sufficiently react with the specific cell, a separation process using magnetic force should be performed.

Conventionally, such a cell separation operation was performed manually by a professional manpower. Using amniotic fluid test as an example, the current cell separation operation will be described as follows. In the case of the conventional amniotic fluid test, 20-30cc of amniotic fluid was collected by inserting a needle into the abdomen of a pregnant woman through ultrasound, and various tests were performed through cell separation. If the test is performed with the collected amniotic water, the cells are sufficiently cultured in the laboratory and then the analysis is carried out. is in demand.

As a non-invasive alternative to the amniotic fluid test, there is a method of collecting cells from the uterine wall, not amniotic fluid, and isolating fetal cells from the collected sample. In this case, the cells of the uterine wall are mixed with various cells of the pregnant woman as well as fetal cells. In order to isolate only fetal cells from a sample in which several types of cells are mixed, a target marker that binds to the fetal cells through an antigen-antibody reaction is bound to magnetic beads and then reacted with the cell sample for magnetic separation.

In this process, multiple centrifugation and multiple magnetic separation operations are required. However, conventionally, a cell separation device capable of performing both centrifugation and magnetic separation has not been provided, so a pretreatment process in which cells are collected in one place and the solution is replaced by a density difference after purification and reagent treatment of cells in the centrifugation device , and the process of separating fetal cells coupled with magnetic beads by applying magnetic force to the performed sample had to be performed manually by a professional manpower.

Accordingly, the present applicant has devised an integrated cell separation device capable of simultaneous centrifugation and magnetic separation to automatically and conveniently separate specific cells from a sample in which two or more various cells are mixed.

Korean Patent Publication No. 10-2012-0032255 Korean Patent Publication No. 10-2007-0006021

An object of the present invention is to provide an integrated cell separation apparatus capable of simultaneously performing centrifugation and magnetic separation so that specific cells can be automatically and conveniently separated from a sample in which two or more various cells are mixed.

In order to achieve the above object, the present invention, in a cell separation device, is rotated by a centrifugation module, and in a sample in which heterogeneous or more cells are mixed, an antibody-coated magnetic bead is accommodated. separation vessel; a pipette installed on the upper portion of the centrifugation vessel to suck or spray the reagent loaded in the centrifuge vessel; a pipette tip fitted to an end of the pipette; and a magnetic material that advances and retreats in the direction of the pipette tip to generate a magnetic force to the periphery of the pipette tip so as to separate the magnetic beads from the pipette tip. It is characterized in that it is possible.

Preferably, the centrifugation vessel may have a plurality of wells for accommodating the cell sample, magnetic beads, buffer solution, or pretreatment reagent.

Preferably, the pipette is vertically driven in the direction of the centrifugation vessel, and the magnetic material may be axially aligned with the pipette tip when the pipette is driven upward.

Preferably, in the cell separation device according to the present invention, in the state in which the magnetic material is fixed, the centrifugation vessel is separated by the reagent movement control according to the vertical driving of the pipette, the reagent suction/discharge control of the pipette, and the centrifugation module It may further include a control unit for performing pre-washing of the cell sample by performing a rotation control.

Preferably, the control unit controls the pipette to suction/discharge the mixed solution of the magnetic beads and the heterogeneous cell sample pretreated in the centrifugation vessel, and controls the pipette tip to axially align with the magnetic body, By controlling the advance of the magnetic material in the direction of the pipette tip, one type of cell bound to a magnetic bead coated with an antibody targeting one type of cell among heterogeneous cells can be controlled to be separated and accommodated on the pipette tip. .

The present invention also provides a cell separation device, comprising: a centrifugation vessel which is rotated by a centrifugation module and accommodates magnetic beads coated with an antibody that targets one type of cell among heterogeneous or more cells to be separated; a pipette installed on the upper portion of the centrifugation vessel to suck or spray the reagent loaded in the centrifuge vessel; a pipette tip fitted to an end of the pipette; and a magnetic body that advances and retreats in the direction of the centrifugation vessel to generate a magnetic force around the periphery of the centrifuge vessel so that the magnetic beads can be collected in the centrifugation vessel. Another feature is that cell separation is possible by

Preferably, the centrifugation vessel has a plurality of wells for accommodating the cell sample, magnetic beads, buffer solution or pretreatment reagent along the outer periphery, and the magnetic body moves forward and backward to the position of the well of the centrifugation vessel. can

According to the present invention, high-efficiency cell separation can be performed by automating the complex process of several steps of manually processing and purifying various reagents by professional personnel.

1 is a diagram for explaining the concept of magnetic separation.
2 shows a cell separation apparatus according to an embodiment of the present invention.
3 shows a centrifugation vessel according to an embodiment of the present invention.
4 shows the pre-processing operation of the control unit according to the embodiment of the present invention.
5 shows the magnetic separation driving of the control unit according to an embodiment of the present invention.
6 shows another embodiment of the magnetic material of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the contents described in the accompanying drawings. However, the present invention is not limited or limited by the exemplary embodiments. The same reference numerals provided in the respective drawings indicate members that perform substantially the same functions.

Objects and effects of the present invention can be naturally understood or made clearer by the following description, and the objects and effects of the present invention are not limited only by the following description. In addition, in describing the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a diagram for explaining the concept of magnetic separation. As described in the background technology of the invention, it is impossible to separate the desired cells only by centrifugation from a sample in which several types of cells are mixed.

In the following examples for explaining the present invention, the cell separation device 1 will be described by way of an example of separating fetal cells from maternal cells present in a cervical sample. The cervical sample test is one of the tests that pregnant women receive. Cervical sample testing is a non-invasive method used for prenatal genetic diagnosis, and since there are very few nucleated cells of the fetus in the collected sample, the development of a method for successful separation and enrichment is required. is the field Therefore, the cell separation apparatus 1 according to the present embodiment may be a suitable example of cell separation to be used.

Referring to FIG. 1 , in a sample taken from the uterus of a pregnant woman, not only the pregnant woman's cells 3 but also the fetal cells 5 are present. Cervical samples contain several species of cells (3) from pregnant women together with fetal cells (5), so simple centrifugation cannot separate only fetal cells (5). Therefore, the MACS separation technique for isolating fetal cells 5 is used. MACS is one of the magnetic separation techniques that uses a magnetic field to separate cells. MACS attaches an antibody that acts on a target cell to a magnetic bead, induces an antigen-antibody reaction, and then separates the target cell from the magnetic bead. Referring back to FIG. 1 , when MACS is applied, the target cell is a fetal cell (5), and an HLA-G marker (91), which is an antibody reacting with the fetal cell (5), is attached to the magnetic bead (9), and a cervical sample is obtained. After reacting sufficiently with the fetal cells (5), the process of isolating the fetal cells (5) is schematically illustrated.

2 shows a cell separation apparatus 1 according to an embodiment of the present invention.

Referring to FIG. 2 , the cell separation apparatus 1 according to an embodiment of the present invention includes a centrifugation vessel 10 , a pipette 30 , a pipette tip 31 , a first slider 33 , and a second slider 35 . ), a magnetic material 50 , and a control unit 70 may be included.

The centrifugation vessel 10 is rotated by the centrifugation module, and a heterogeneous cell sample to be separated and a magnetic bead coated with an antibody targeting one type of heterogeneous cell are accommodated. In this embodiment, the heterogeneous cell sample may refer to a cell sample in which two or more types of cells of different types are mixed. The magnetic bead may be a bead-shaped member that responds to a magnetic force of a size of 10 nm to 20 μm. 1 , the heterogeneous cell sample becomes the cervical sample 3 and 5, and magnetic beads 9 coated with the HLA-G marker 91 targeting the fetal cell 5, which is one type of cell. ) may be accommodated in the centrifugation vessel 10 .

As the centrifugation vessel 10 is rotated by the centrifugation module, cells can be collected in one place in a heterogeneous cell sample received with a difference in density and cell pretreatment can be performed. The centrifugation module collectively refers to well-known components necessary for rotating the centrifugation vessel 10 . The centrifugation module is disposed in the lower direction of the centrifugation vessel 10 and is not visually shown on the drawing, but it is a configuration that can be understood and practiced by those of ordinary skill in the art, and the features of the present invention are unnecessary Since it can be diluted, a detailed description will be omitted.

3 shows a centrifugation vessel 10 according to an embodiment of the present invention. In this embodiment, the centrifugation vessel 10 may have a plurality of wells 13 for accommodating a cell sample, magnetic beads, buffer solution, or pretreatment reagent. The well 13 may be implemented as an area partitioned by a partition wall. The plurality of wells 13 include a well accommodating a heterogeneous cell sample, a well accommodating magnetic beads, a well accommodating a buffer solution, a well accommodating various reagents for various pretreatments, a well accommodating the separated cell sample, etc. , and can be used separately according to the function.

In this embodiment, the wells 13 of the centrifuge vessel 10 may be formed circumferentially along the circumference on the distal side of the vessel. More specifically, the plurality of wells 13 formed in the circumferential direction along the circumference on the distal side have the same pipette 30 as the centrifugation vessel 10 is rotated when the pipette 30 is positioned in any one area. Even if it is driven only in the height direction from the position, the pipette tip 31 can suck or spray the sample in all areas.

In the cell separation apparatus 1 according to the present embodiment, both pretreatment and separation of cells may be performed automatically. Accordingly, the centrifugation vessel 10 is formed with a divided space in which the reagent and the sample are accommodated, respectively, unlike the conventional reagent flask for centrifugation in which both the reagent and the sample are mixed and centrifuged. The pipette tip 31 can mix and separate a sample or a sample in the well 13 as the centrifugation vessel 10 is properly rotationally controlled.

The pipette 30 advances and retreats in the direction of the centrifugation vessel 10 , and the pipette tip 31 sucks or sprays the reagent loaded in the centrifuge vessel 10 . The pipette 30 is driven up and down in the direction of the centrifugation vessel 10 . As the cell separation device 1 , according to the embodiment of FIG. 2 in which the centrifugation vessel 10 and the pipette 30 are vertically arranged, the pipette 30 is driven and controlled in the Z-axis (height) direction.

The pipette 30 is driven by a fluid control module driven up and down. The fluid control module for controlling the pipette 30 may include a first slider 33 and a second slider 35 . The fluid control module may include a configuration in which the pipette 30 is press-fitted or pumped to form a negative pressure in the pipette 30 . 2 discloses an embodiment in which two sliders 33 and 35 are included in the fluid control module. It is not limited to the embodiment of FIG. 2 , and the pipette 30 may be linked with one slider driven up and down. In the embodiment of FIG. 2 , the first slider 33 collectively refers to a frame for vertically driving the pipette 30 , the magnetic body 50 , and the second slider 35 . The second slider 35 may be connected to an end of the pipette 30 to control a suction or injection process of the pipette 30 . In addition, the second slider 35 is driven up and down from the first slider 33 to enable more precise work of the pipette 30 .

The magnetic material 50 generates a magnetic force around the pipette. The magnetic material 50 functions to separate target cells bound to magnetic beads. The magnetic material 50 is disposed on the periphery of the pipette 30 so that only target cells to which magnetic beads are bound inside the pipette 30 that sucked the cell sample remain on the inner wall of the pipette 30 by magnetic force.

The magnetic body 50 is driven forward and backward in the direction of the pipette by the magnetic control module. When the pipette 30 is driven upward, the magnetic material 50 is axially aligned with the pipette tip 31 , and advances in a state coaxial with the pipette tip 31 to apply a magnetic force to the pipette tip 31 . apply In this embodiment of FIG. 2 , it is an example in which the magnetic material 50 is implemented to perform magnetic separation on the pipette tip 31 . Unlike the present embodiment, an embodiment of the magnetic body 50 in which magnetic separation is performed on the centrifuge vessel 10 will be described later with reference to FIG. 6 .

The magnetic control module collectively refers to a configuration necessary to advance and retreat the magnetic body 50 . The magnetic control module may include a third slider 51 for moving the magnetic body 50 forward or backward.

The magnetic material 50 is controlled to retreat and spaced apart from the pipette 30 before the separation operation of the target cell to which the magnetic beads are coupled is performed. When the cell separation process is performed by the control unit 70 after the pipette 30 is completed, the magnetic body 50 is driven forward in the pipette 30 direction.

The magnetic body 50 may have a rear end connected to the third slider 51 . The third slider 51 may be provided on the first slider 33 .

The control unit 70 controls the first to third sliders 33 , 35 , 51 and the centrifugation module to perform two modes of centrifugation and magnetic separation. The three components of the centrifugation vessel 10 , the pipette 30 , and the magnetic body 50 are organically operated under the control of the controller 70 .

4 shows the pre-processing operation of the control unit according to the embodiment of the present invention. 4A shows that the first slider 33 is lowered for reagent loading, and then the second slider 35 is lowered, so that the pipette tip 31 is sufficiently moved into the well 13 of the centrifuge vessel 10. The figure is shown in a side view. In this case, the magnetic material 50 is driven backward by the third slider 51 , and no magnetic force is applied to the pipette tip 31 . Figure 4b shows a front view of the reagent loading operation described above.

Referring to FIG. 4 , the control unit 70 controls the suction/discharge control according to the vertical driving of the pipette 30 and rotation of the centrifugal separation vessel 10 by the centrifugal separation module in a state in which the magnetic body 50 is fixed. to perform washing pretreatment of the cell sample. This may be understood as a centrifugal separation control mode of the control unit 70 .

In this embodiment, the centrifugation control mode of the control unit 70 will be described as the embodiment of cervical sample processing described with reference to FIG. 1 . The control unit 70 should mix a buffer solution and 3% acetic acid in the cell sample in the fractionated area of the centrifugation vessel 10 for pretreatment of the cell sample. In this process, the centrifugation module is controlled so that the pipette 30 is placed in the region of the centrifugation vessel 10 in which a reagent for pretreatment such as a buffer solution or acetic acid is supported. Thereafter, the control unit 70 drives the pipette 30 up and down by the fluid control module. By driving the pipette 30 , a reagent for pretreatment is mixed with the cell sample in a specific well of the centrifugation vessel 10 . The control unit 70 rotates the centrifugation vessel 10 by the centrifugation module. According to this control sequence, the centrifugation process may be repeated about 3 to 5 times.

Thereafter, the control unit 70 rotates the centrifugation vessel 10 so that the second region 13 in which the magnetic beads are accommodated is located in the pipette 30 . The control unit 70 operates the slider configuration of the fluid control module and the centrifugation module to control the pipette 30 to suck the magnetic beads and inject the magnetic beads into the mixing well in which the pre-treated sample is loaded. Thereafter, when a predetermined time is required for the magnetic beads to sufficiently react with the cell sample, the pretreatment process for cell separation is completed.

5 shows the magnetic separation driving of the control unit 70 according to an embodiment of the present invention. FIG. 5A is a side view of the magnetic body 50 being advanced in axial alignment with the pipette tip 31 to perform magnetic separation in the pipette tip 31 . Figure 5b is a side view of the magnetic body 50 according to another embodiment is advanced and retreated onto the centrifugation vessel 10 to perform magnetic separation on the centrifuge vessel 10 .

The control unit 70 controls the pipette 30 to suction/discharge the pre-treated magnetic bead and heterogeneous cell sample mixed solution in the centrifugation vessel 10 according to the vertical drive, and the magnetic material 50 to the pipette 30 ) direction, it is possible to control to separate and accommodate one type of cell bound to a magnetic bead coated with an antibody targeting one type of cell among heterogeneous cells on the pipette tip 31 . Referring to FIG. 5A , in the embodiment in which magnetic separation is performed on the pipette tip 31 , the controller 70 drives both the first slider 33 and the second slider 35 upward. Accordingly, the pipette tip 31 is disposed on the axis in which the magnetic body 50 is located. Thereafter, when the magnetic material 50 is advanced and a magnetic force is applied to the periphery of the pipette tip 31, magnetic separation may be performed on the pipette tip.

In this embodiment, the self-separation control mode of the control unit 70 will be described as the embodiment of the cervical sample processing described with reference to FIG. 1 . After pretreatment, magnetic beads in the mixed well are bound to fetal cells (5) by antigen-antibody reaction. The control unit 70 drives the fluid control module so that the pipette 30 sucks the cervical cell sample from the mixing well, and advances the third slider 51 so that the magnetic body 50 is placed close to the periphery of the pipette 30 . control as much as possible. In this process, the fetal cells 5 to which the magnetic beads are bonded remain inside the pipette tip 31 even though the injection operation of the pipette 30 is performed by the attractive force of the magnetic body 50 . After repeating the above operation several times, the control unit 70 causes the pipette 30 to suck the PBD buffer solution again in a separate area of the centrifugation vessel 10, so that the fetal cells 5 remaining inside the pipette 30 are ) and magnetic beads. Finally, the control unit 70 removes DNA by mixing DNAse in the well in which the separated cell sample is accommodated, and completes the magnetic separation control process of separating the fetal cells 5 by performing a PBS buffer washing process 3 to 5 times. can do.

In the same principle, magnetic separation may be performed on the centrifuge vessel 10 as shown in FIG. 5B . In this case, the magnetic body 50 may be provided inside the cell separation device, and may advance and retreat toward the outer periphery of the centrifuge vessel 10 in which the well 13 is formed.

6 shows another embodiment of the magnetic body 50' of the present invention. Referring to FIG. 6 , the cell separation device 1 ′ may include a centrifugation vessel 10 , a pipette 30 , and a magnetic body 50 ′.

The centrifugation vessel 10 is rotated by the centrifugation module, and magnetic beads coated with an antibody targeting one type of cell among heterogeneous or more cells to be separated are accommodated. The pipette 30 is installed on the upper portion of the centrifugation vessel 10 to suck or spray the reagent loaded in the centrifuge vessel 10 . The magnetic body 50 ′ advances and retreats in the direction of the centrifugation vessel 10 to generate a magnetic force around the periphery of the centrifugation vessel 10 so as to collect magnetic beads.

In the embodiment of FIG. 6 with a difference from the embodiment described in FIGS. 1 to 5 , the magnetic material 50 ′ generates a magnetic force on the centrifugation vessel 10 to grip the magnetic beads. Configurations other than the magnetic body 50 ′ may be common to the embodiments of FIGS. 1 to 5 , and overlapping references are omitted. In this embodiment, the magnetic body 50' is built-in and arranged as a peripheral part of the centrifugal separation module. The magnetic material 50' is disposed under the centrifugation vessel 10 so that the third slider 51' can be driven forward and backward in the vertical direction in the direction of the centrifugation vessel 10. The magnetic material 50' is the cell When the pretreatment is driven, it is driven backward to be separated from the centrifuge vessel 10. The magnetic material 50' is driven upward in the direction of the centrifugation vessel 10 when the magnetic separation of cells is driven. ') is shown in the lower direction of the centrifugation vessel 10, but the magnetic body 50' is sufficient if it is provided at a position where magnetic force is applied or not applied to the centrifugation vessel 10, and as another example, the magnetic body 50 is It may be disposed in the lateral direction of the centrifugal separation vessel 10 and may be driven by sliding in the lateral direction.

Although the present invention has been described in detail through representative embodiments above, those of ordinary skill in the art to which the present invention pertains will understand that various modifications are possible within the limits without departing from the scope of the present invention with respect to the above-described embodiments. will be. Therefore, the scope of the present invention should not be limited to the described embodiments and should be defined by all changes or modifications derived from the claims and equivalent concepts as well as the claims to be described later.

1: Cell separation device
3: Pregnant cells
5: Fetal cells
9: Magnetic Bead
91: antibody
10: centrifugation vessel
13: well
30: pipette
31: pipette tip
33: first slider
35: second slider
50: magnetic material
51: third slider
70: control unit

Claims (7)

A cell separation device comprising a centrifugation module, a centrifugation vessel rotated by the centrifugation module, a pipette having a pipette tip inserted at an end thereof, a magnetic body, and a control unit,
The centrifugation vessel includes a first well accommodating a cell sample in which heterogeneous cells are mixed, a second well accommodating a magnetic bead coated with an antibody targeting a cell to be separated from the cell sample, and a buffer solution. A plurality of wells including a third well to receive and a fourth well to receive the separated cell sample,
The centrifugation vessel allows the received cell sample to be separated by a density difference by centrifugal force generated while rotating by the centrifugation module,
The pipette is installed on the upper part of the centrifugation vessel, and is driven up and down in the direction of the centrifugation vessel, and the cell sample accommodated in the first well, the magnetic beads accommodated in the second well, and the buffer solution accommodated in the third well. to separate the cells into the fourth well,
The control unit causes the centrifugation vessel to rotate at a specific angle through the centrifugation module so that a specific well is positioned below the pipette among a plurality of wells including the first to fourth wells, and the pipette moves up and down to move and mix the solution accommodated in the plurality of wells,
The control unit causes the magnetic material to be disposed close to the pipette tip when the pipette performs the spraying operation, so that the cells to be separated by the magnetic force of the magnetic material remain inside the pipette tip. cell separation device.
delete According to claim 1,
The magnetic material is a cell separation device, characterized in that axially aligned with the pipette tip.
According to claim 1,
The control unit is a cell separation device, characterized in that for controlling the vertical driving of the pipette and the suction/discharge of the reagent. delete delete delete

Images