KR20210012686A - Apparatus for micro particle treatment - Google Patents

Abstract

A microparticle processing apparatus is disclosed. The microparticle processing apparatus according to an embodiment of the present invention includes: a microparticle separation unit in which microparticles are separated; and a microparticle separation solution injection unit providing a microparticle separation solution.

Description

Fine particle treatment device{APPARATUS FOR MICRO PARTICLE TREATMENT}

The present invention relates to a microparticle processing apparatus for separating target microparticles from a fluid sample, and more particularly, after separating the particles, the filter chipset is separately separated to recover and analyze the selected particles in the filter. It relates to a fine particle treatment apparatus that can improve the yield of.

In general, a syringe filter or a syringe filter is a representative technique for trapping microparticles in a fluid.

Conventional membrane filters with materials such as PVDF (Polyvinylidene difluoride), Nylon, PTFE (Polytetrafluoroethylen), PES (Polyethersulfone), PP (Polypropylene), GF (Glass Fiber) filter out particles larger than a specific size, and small particles Pass through. Existing membrane filters are difficult to use because the size or shape of the pores through which the particles pass through are not uniform, and thus only select particles of a specific size.

In addition, since the membrane filter has an integral structure, there is a problem that loss occurs in order to collect and analyze the particles selected in the filter by separating only the filter.

Publication Patent No. 10-2017-0127241

The present invention has been devised to solve the above-described problem, and is easy to collect and analyze the selected particles in the filter by separating the filter chipset separately after particle separation, and a fine particle treatment apparatus capable of improving the yield of particles. It has its purpose to provide.

A microparticle processing apparatus for separating microparticles in a fluid according to an embodiment of the present invention includes: a microparticle separation unit for separating microparticles; And a microparticle separation solution injection unit for providing a microparticle separation solution, wherein the microparticle separation unit includes: a first syringe body fixing unit fixing the outer cylinder of the syringe set; A first syringe presser fixing portion for fixing the piston of the syringe set; And a first driving device for displacing the first syringe presser fixing unit, wherein the microparticle separation solution injection unit comprises: a second syringe body fixing unit fixing the outer cylinder of the injection syringe; A second syringe presser fixing portion for fixing the piston of the injection syringe; And a second driving device for displacing the second syringe presser fixing portion.

In addition, the first syringe body fixing part, the 1-1 syringe body fixing part; And a 1-2 syringe body fixing part positioned below the 1-1 syringe body fixing part.

In addition, the first syringe body fixing part may include a first body guide, and a first flange fixing guide whose separation distance from the first body guide is adjusted.

In addition, the first syringe pressing rod fixing unit may include a first support body and a first pressing rod fixing guide that is spaced apart from the first support body.

In addition, the second syringe body fixing part may include a second body guide, and a second flange fixing guide that is spaced apart from the second body guide.

In addition, the second syringe presser fixing unit may include a second support body, and a second presser bar fixing guide whose separation distance from the second support body is adjusted.

In addition, a hexahedral mounting body may be further included, and the microparticle separation unit may be disposed on a front surface of the mounting body, and the microparticle separation solution injection unit may be disposed on an upper surface of the mounting body.

In addition, it further comprises a cover covering the front and upper surfaces of the mounting body in a state in which the microparticle separation unit and the microparticle separation solution injection unit are mounted,

In addition, the cover may be mounted and detached from the mounting body through a plurality of magnets mounted on the mounting body.

In addition, the fluid may include blood, body fluid, cerebrospinal fluid, somen noodles, sputum, or a mixture thereof collected from human or animal samples.

In addition, the microparticles may include tissues, cells, proteins, nucleic acids, or clusters thereof collected from human or animal samples.

According to the microparticle processing apparatus according to the present invention, a filling syringe and a separation syringe are separately separated in a syringe set, and a filter chip set is provided between the filling syringe and the separation syringe. Accordingly, after particle separation, the filter chipset is separately separated to recover and analyze the selected particles in the filter, and the yield of the particles can be improved.

1 is a view showing the appearance of a fine particle treatment apparatus according to an embodiment of the present invention.
2 is a view showing the appearance of the disassembled state of the cover of the fine particle treatment apparatus according to an embodiment of the present invention.
3 is a view showing the structure of a fine particle separation unit of the fine particle treatment apparatus according to an embodiment of the present invention.
4 is a view showing the structure of the first syringe body fixing part of the microparticle separation part.
5 is a view showing the structure of the first syringe pressing rod fixing portion of the microparticle separation unit.
6 is a view showing the structure of a syringe set used in the microparticle separation unit of the microparticle processing apparatus according to an embodiment of the present invention.
7 is a view showing a form in which a syringe set is coupled to the microparticle separation unit of the microparticle processing apparatus according to an embodiment of the present invention.
8 is a view showing the structure of a microparticle separation solution injection unit of the microparticle treatment apparatus according to an embodiment of the present invention, and is a view showing a form in which a separation solution injection syringe is coupled to the microparticle separation solution injection unit.
9 is a view showing the structure of a third syringe body fixing part of the microparticle separation solution injection part.
10 is a view showing a structure of a second syringe presser fixing portion of the microparticle separation solution injection unit.
11 to 15 are views showing the operating sequence of the fine particle treatment apparatus according to an embodiment of the present invention.

Hereinafter, a preferred embodiment according to the present invention will be described with reference to the accompanying drawings.

First, with reference to FIGS. 1 and 2, the overall structure of a fine particle treatment apparatus according to an embodiment of the present invention will be described. 1 is a view showing the appearance of a fine particle treatment apparatus according to an embodiment of the present invention, Figure 2 is a view showing the appearance of the disassembled state of the cover 40 of the fine particle treatment apparatus according to an embodiment of the present invention It is a drawing.

Hereinafter, in the description, the description indicating the front, rear, left, right, up, down, etc. directions is based on the X axis, Y axis, and Z axis of FIG. 1. That is, the Y axis is the front-rear direction, the X axis is the left and right direction, and the Z axis is the vertical direction.

A fine particle treatment apparatus according to an embodiment of the present invention includes a control unit 1 and a mechanism unit 2. The microparticle processing device is provided to separate target microparticles in a fluid sample, and the fluid may include blood, body fluid, cerebrospinal fluid, somen noodles, sputum, or a mixture thereof collected from a human or animal sample. In addition, the microparticles may include tissues, cells, proteins, nucleic acids, or clusters thereof collected from human or animal samples.

The control unit 1 may mount a CPU, a PCB, a memory, etc. for controlling the microparticle processing apparatus according to an embodiment of the present invention. In addition, the controller 1 may be provided with a touch screen through which a user's signal can be input.

The mechanism unit 2 may perform various operations by signals transmitted from the control unit 1. Accordingly, substantial separation of the fine particles is performed in the mechanism unit 2 and treatment of the fine particles can be performed.

The mechanism unit 2 includes a mounting body 10, a microparticle separation unit 20, a microparticle separation solution injection unit 30, and a cover 40.

The mounting body 10 may have a polygonal three-dimensional shape as a whole, and may be configured as a three-dimensional structure of a hexahedral shape as in the embodiment. Various driving devices driven by signals transmitted from the control unit 1 may be built in the mounting body 10.

The microparticle separation unit 20 receives a separation solution from the microparticle separation solution injection unit 30 to separate the microparticles, and is a part where the microparticles are processed. The microparticle separation unit 20 may be disposed on the front surface of the mounting body 10. The microparticle separation unit 20 may be equipped with a syringe set 200 through which a fluid including microparticles is filled and a separation material can be discharged.

The microparticle separation solution injection unit 30 is a part that provides a separation solution capable of separating microparticles to the microparticle separation unit 20. The microparticle separation solution injection unit 30 may be disposed on the upper surface of the mounting body 10. The microparticle separation solution injection unit 30 may be equipped with a separation solution injection syringe 400. The separation solution injection syringe 400 may be filled with a separation solution used to separate microparticles.

The cover 40 is a part that can cover the microparticle separation unit 20 and the microparticle separation solution injection unit 30. The cover 40 is made of, for example, a light-transmitting material so that the inside can be seen. According to one embodiment, the cover 40 and the mounting body 10 are detachable through a predetermined magnet 12, and thus opening and closing can be achieved easily.

Hereinafter, the fine particle separation unit 20 will be described in detail with reference to FIGS. 3 to 5.

3 is a view showing the structure of the fine particle separation unit 20 of the fine particle treatment apparatus according to an embodiment of the present invention.

The fine particle separation unit 20 includes a first holder 100, a first syringe body fixing portion 110A, 110B, a first syringe pressing rod fixing portion 120, and a first driving device 130. .

The first holder 100 supports the first syringe body fixing parts 110A and 110B, the first syringe presser fixing part 120, and the first driving device 130 and is fixed to the front of the mounting body 10 Can be. The first syringe body fixing portions 110A and 110B are fixed to the first holder 100 and are provided with two, respectively, and may be positioned at an upper position and an intermediate position of the first holder 100. The first syringe pressing rod fixing portion 120 is disposed under the first syringe body fixing portion 110 and can be moved up and down along the first holder 100. The first driving device 130 provides a power capable of vertically displacing the first syringe presser fixing portion 120.

4 is a view showing the structure of the first syringe body fixing portion 110 of the microparticle separation portion 20. (a) is an exploded view of the first syringe body fixing part 110 of the microparticle separation part 20, and (b) is a view in which the first syringe body fixing part 110 is assembled. As described above, two first syringe body fixing parts 110 are provided, and may be located at an upper position and an intermediate position of the first holder 100, respectively, and two first syringe body fixing parts 110A, 110B) may have the same or corresponding structure. Therefore, for convenience, the first syringe body fixing portion 110 positioned at the top is referred to as the 1-1 syringe body fixing portion 110A, and the first syringe body fixing portion 110 positioned at the lower portion is referred to as the 1-2 It is referred to as a syringe body fixing part 110B. However, since both have a common configuration, hereinafter, the first syringe body fixing portion 110 will be described in common.

The first syringe body fixing part 110 includes a first body guide 111 and a first flange fixing guide 112 that can be connected to a position spaced apart from the first body guide 111 by a predetermined distance.

The first body guide 111 is formed with a guide groove 111a recessed along the outer shape of the outer cylinders 212 and 222 of the syringe set 200. A plurality of guide grooves 111a may be formed. In addition, a fixing knob 113 is provided on the front surface of the first body guide 111 to fix the syringe set 200 mounted on the first body guide 111.

The first flange fixing guide 112 also has a recessed groove formed along the outer shape of the outer cylinders 212 and 222 of the syringe set 200. The first flange fixing guide 112 may be provided with a gap adjustment screw (112a). The distance between the first body guide 111 and the first flange fixing guide 112 may be varied by the gap adjusting screw 112a.

At this time, the 1-1 syringe body fixing part 110A is fixed to the first holder 100 so that the first flange fixing guide 112 is positioned above the first body guide 111. In addition, the 1-2 syringe body fixing part 110B is fixed to the 1st holder 100 so that the 1st flange fixing guide 112 may be located below the 1st body guide 111.

5 is a view showing the structure of the first syringe pressing rod fixing portion 120 of the fine particle separation unit 20. (a) is an exploded view of the first syringe pressing rod fixing portion 120 of the microparticle separation portion 20, and (b) is a diagram in which the first syringe pressing rod fixing portion 120 is assembled.

The first syringe pressing rod fixing part 120 includes a first support body 121 and a first pressing rod fixing guide 122 that can be connected to a position spaced apart from the first support body 121 by a predetermined distance. .

The first support body 121 may be a flat structure.

The first pressing rod fixing guide 122 has a recessed groove formed along the outer shape of the push rod 232 of the syringe set 200. A fixing knob 123 may be provided on the first pressing bar fixing guide 122. The distance between the first support body 121 and the first pressing bar fixing guide 122 may be varied by the fixing knob 123.

Hereinafter, with reference to FIG. 6, a structure of the syringe set 200 used in the microparticle separation unit 20 of the microparticle processing apparatus according to an embodiment of the present invention will be described. 6 is a view showing the structure of the syringe set 200 used in the microparticle separation unit 20 of the microparticle processing apparatus according to an embodiment of the present invention, (a) is a disassembled syringe set 200 It is a drawing, (b) is a view in which the syringe set 200 is assembled.

The syringe set 200 includes an upper syringe 210 positioned at an upper portion, a lower syringe 220 positioned at the lower portion, and a filter chipset 240 positioned between the upper syringe 210 and the lower syringe 220 Includes.

The upper syringe 210 is not a general complete syringe including all of a syringe, a piston, and a needle, but only includes a syringe of a general syringe (ie, the outer cylinder of the syringe).

Accordingly, the upper syringe 210 is formed on the outer cylinder 212 with a space therein, the lower portion of the outer cylinder 212 and protrudes downward and is formed on the open tip 216 and the upper portion of the outer cylinder 212 It includes an opening 214 opened in the direction, and a flange 218 protruding outwardly around the opening 214.

The lower syringe 220 is not a general complete syringe containing all of a syringe, a piston, and a needle, but only includes a syringe of a syringe (i.e., the outer cylinder of the syringe) and a piston (a piston including a packing, a push rod, and a push rod).

Accordingly, the outer cylinder 222 of the lower syringe 220 is formed in the lower portion of the outer cylinder and is formed in the lower opening 224, which is formed on the upper portion of the outer cylinder 222, and protrudes upward and is opened and the tip 226 And a flange 228 protruding outwardly around the opening 224.

In addition, the piston 230 of the lower syringe 220, a push rod 232, a packing 234 located at one end of the push rod 232, and a pressing rod 236 located at the other end of the push rod 232 Includes.

The filter chipset 240 is provided between the upper syringe 210 and the lower syringe 220 and connects the tip 216 of the upper syringe 210 and the tip 216 of the lower syringe 220. The filter chipset 240 may include a filter for selecting and separating cells of a predetermined size.

7 shows a form in which the syringe set 200 is mounted on the fine particle separation unit 20 of the fine particle processing apparatus according to an embodiment of the present invention.

The upper syringe 210 is seated in the guide groove 111a of the 1-1 syringe body fixing part 110A located at the top, and the guide groove of the 1-2 syringe body fixing part 110B located at the bottom ( The lower syringe 220 is mounted on 111a). At this time, each syringe is in close contact with the guide groove 111a by the fixing knob 113 to be fixed in position. In addition, flanges 218 and 228 of each syringe are fitted between the first flange fixing guide 112 and the first body guide 111, and the first flange fixing guide 112 and the first body guide 111 The spacing between the flanges 218 and 228 is adjusted to securely fix the flanges 218 and 228.

In addition, the push rod 232 of the piston 230 of the syringe is seated in the guide groove 111a of the first syringe pressing rod fixing portion 120. In addition, the pressing bar 236 of the piston 230 is inserted between the first supporting body 121 and the first pressing bar fixing guide 122, and the first supporting body 121 and the first pressing bar fixing guide ( The spacing between 122) is adjusted so as to securely fix the pressing bar 236.

Hereinafter, the microparticle separation solution injection unit 30 will be described with reference to FIGS. 8 to 10.

8 is a view showing the structure of the microparticle separation solution injection unit 30 of the microparticle treatment apparatus according to an embodiment of the present invention.

The microparticle separation solution injection part 30 includes a second holder 300, a second syringe body fixing part 310, a second syringe pressing rod fixing part 320, and a second driving device 330. .

The second holder 300 supports the second syringe body fixing portion 310, the second syringe pressing rod fixing portion 320, and the second driving device 330, and may be fixed to the upper surface of the mounting body 10. have. The second syringe body fixing portion 310 is fixed to the second holder 300, and the second syringe pressing rod fixing portion 320 may be displaced in the front-rear direction along the second holder 300. The second driving device 330 provides power to displace the second syringe presser holder 320 vertically.

9 is a view showing the structure of the second syringe body fixing portion 310 of the microparticle separation solution injection unit 30. (a) is an exploded view of the second syringe body fixing part 310 of the microparticle separation solution injection part 30, and (b) is a view in which the second syringe body fixing part 310 is assembled.

The syringe body fixing part includes a second body guide 311 and a second flange fixing guide 312 that can be connected to a position spaced apart from the second body guide 311 by a predetermined distance.

The second body guide 311 is formed with a guide groove 311a recessed along the outer shape of the outer cylinder 212 of the syringe 400 for injection of a separation solution. A plurality of guide grooves 311a may be formed. In addition, a fixing knob 313 is provided on the front surface of the second body guide 311 to fix the syringe 400 for injection of a separation solution mounted on the second body guide 311.

The second flange fixing guide 312 also has a recessed groove formed along the outer shape of the outer cylinder 410 of the syringe 400 for injection of a separation solution. A fixing knob 313 may be provided on the second flange fixing guide 312. The distance between the second body guide 311 and the second flange fixing guide 312 may be varied by the fixing knob 313.

10 is a view showing the structure of the second syringe pressing rod fixing portion 320 of the microparticle separation solution injection portion 30. (a) is an exploded view of the second syringe pressing rod fixing portion 320 of the microparticle separation solution injection portion 30, and (b) is a diagram in which the second syringe pressing rod fixing portion 320 is assembled.

The second syringe presser fixing part 320 includes a second support body 321 and a second presser bar fixing guide 322 that can be connected to a position spaced apart from the second support body 321 by a predetermined distance. .

The second support body 321 may be a flat structure.

The second pressing rod fixing guide 322 has a guide groove recessed along the outer shape of the push rod 422 of the syringe 400 for injection of a separation solution. A fixing knob 323 may be provided on the second pressing bar fixing guide 322. The distance between the second support body 321 and the second pressing bar fixing guide 322 may be varied by the fixing knob 323.

Hereinafter, referring again to FIG. 8, the structure of the syringe 400 for injecting the separation solution used in the injection unit 30 for separating fine particles of the device for processing fine particles according to an embodiment of the present invention will be described. A form in which a separate solution injection syringe 400 is mounted on the solution injection unit 30 will be described.

First, the syringe 400 for injection of the separation solution will be described.

Separated solution injection syringe 400 is not a general complete syringe including all of a syringe, a piston, and a needle, but only includes a syringe (i.e., a syringe outer cylinder) and a piston (a piston including a packing, a push rod and a pressing rod) do.

Accordingly, the outer cylinder 410 of the syringe 400 for injection of the separation solution is formed in the front and protrudes downward and is opened, and the opening 414 is formed in the rear of the outer cylinder 410 and opened to the rear. , And a flange 416 protruding outwardly around the opening 414.

In addition, the piston 420 of the syringe 400 for injection of the separation solution includes a push rod 422, a packing 424 positioned at one end of the push rod 422, and a pressing rod located at the other end of the push rod 422 (426) is included.

Next, a form in which a syringe 400 for injecting a separation solution is mounted in the microparticle separation solution injection unit 30 is described.

A separate solution injection syringe 400 is seated in a guide groove of the second syringe body fixing part 310 positioned in front. At this time, the syringe 400 for injecting the separation solution may be in close contact with the guide groove 311a by the fixing knob 313 to be fixed in position. In addition, a flange 416 is fitted between the second flange fixing guide 312 and the second body guide 311, and the distance between the second flange fixing guide 312 and the second body guide 311 is a flange ( 416) is adjusted to hold firmly.

In addition, the push rod 422 of the piston 420 is seated on the second syringe pressing rod fixing part 320. In addition, the pressing bar 426 of the piston 420 is inserted between the second support body 321 and the second pressing bar fixing guide 322, and the second support body 321 and the second pressing bar fixing guide ( The spacing between 322 is adjusted to fix the pressing bar 426 firmly.

Hereinafter, with reference to FIGS. 11 to 14, a description will be given of a sequence of operations of a fine particle treatment apparatus according to an embodiment of the present invention and a process of separating fine particles thereby.

First, the cover 40 is removed as shown in (a) of FIG. 11. Then, as shown in (b), the syringe set 200 mounted on the microparticle separation unit 20 is assembled. As described above, the syringe set 200 is assembled in a form in which the filter chipset 240 is coupled between the upper syringe 210 set 200 and the lower syringe 220 set 200. Then, the assembled syringe set 200 is mounted on the microparticle separation unit 20 as shown in (c).

At this time, the mounting form of the syringe set 200 is as described above. That is, the upper syringe 210 is seated in the guide groove 111a of the first syringe body fixing portion 110 located at the top, and the guide groove 111a of the first syringe body fixing portion 110 located at the bottom In the lower syringe 220 is seated. At this time, each syringe is in close contact with the guide groove 111a by the fixing knob 113 and fixed in position. In addition, a flange 218 of each syringe is fitted between the first flange fixing guide 112 and the first body guide 111, and between the first flange fixing guide 112 and the first body guide 111 The spacing is adjusted to securely fix the flange 218.

In addition, the push rod 232 of the piston 230 of the lower syringe 220 is mounted on the first syringe pressing rod fixing portion 120. In addition, the pressing bar 236 of the piston 230 is inserted between the first supporting body 121 and the first pressing bar fixing guide 122, and the first supporting body 121 and the first pressing bar fixing guide ( The spacing between 122) is adjusted so as to securely fix the pressing bar 236.

In addition, at this time, the syringe set 200 is mounted on the microparticle separation unit 20 in a state in which the piston 230 of the lower syringe 220 is pushed all the way upward.

Next, as shown in (a) of FIG. 12, a fluid containing microparticles is filled into the upper syringe 210 of the syringe set 200. Next, as shown in (b), the separation solution injection syringe 400, which is previously filled with the separation solution, is mounted on the microparticle separation solution injection unit 30.

At this time, the mounting form of the syringe 400 for injection of the separation solution is also as described above. That is, the syringe 400 for injecting the separation solution is seated in the guide groove of the second syringe body fixing part 310 positioned in front. At this time, the syringe 400 for injecting the separation solution may be in close contact with the guide groove 311a by the fixing knob 313 to be fixed in position. In addition, a flange 416 is fitted between the second flange fixing guide 312 and the second body guide 311, and the distance between the second flange fixing guide 312 and the second body guide 311 is a flange ( 416) is adjusted to hold firmly.

In addition, the push rod 422 of the piston 420 is seated on the second syringe pressing rod fixing part 320. In addition, the pressing bar 426 of the piston 420 is inserted between the second support body 321 and the second pressing bar fixing guide 322, and the second support body 321 and the second pressing bar fixing guide ( The spacing between 322 is adjusted to fix the pressing bar 426 firmly.

At this time, the separation solution injection syringe 400 is in a state filled with the separation solution, and the piston 420 of the separation solution injection syringe 400 is in a retracted state, so that the second syringe pressing rod fixing part 320 Is a state spaced apart from the second syringe body fixing portion 310.

Subsequently, as shown in (c), after the cover 40 is mounted, an operation command may be input through the touch screen of the controller 1.

13 shows the operation of the microparticle separation solution injection unit 30. When the operation command is input as described above, the second syringe presser fixing part 320 of the microparticle separation solution injection part 30 moves forward as shown in the arrow A as shown in FIG. 13A. This operation may be performed by the second driving device 330. The second driving device 330 moves the second syringe presser bar fixing part 320 forward at a set speed. Of course, at this time, the outer cylinder 410 of the syringe 400 for injection of the separation solution is fixed in position, so that it does not displace.

As shown in Fig. 13(a) to 13(b), the second syringe presser fixing part 320 moves forward and at the same time, for injecting the separated solution fixed to the second syringe presser holder 320 The piston 420 of the syringe 400 also moves forward. In this process, the separation solution filled in the separation solution injection syringe 400 is discharged to the outside. Although not clearly shown in the drawing, the separation solution is the upper syringe 210 through a predetermined tube (not shown) connecting between the syringe 400 for injection of the separation solution and the upper syringe 210 of the syringe set 200. ) Is injected.

14 shows the operation of the fine particle separation unit 20. As described above, the separation solution is injected from the separation solution injection syringe 400 into the upper syringe 210 through the tube, so that the fluid including the microparticles in the upper syringe 210 and the separation solution are mixed.

Subsequently (or simultaneously with the injection of the separation solution), the first syringe presser fixing unit 120 of the microparticle separation unit 20 moves downward as shown in the arrow B as shown in FIG. 14A. Such an operation may be performed by the first driving device 130. The first driving device 130 moves the first syringe presser bar fixing part 120 downward at a set speed. Of course, at this time, the outer cylinder 212 of the upper syringe 210 and the outer cylinder 222 of the lower syringe 220 are fixed in position and thus do not displace. In addition, the operation of the first driving device 130 and the operation of the second driving device 330 may be performed simultaneously, or sequentially (for example, after the second driving device 330 operates, the first driving device 130 is The order of operation) may be performed.

In Fig. 14, as shown in Fig. 15, the first syringe pressing rod fixing portion 120 moves downward and the piston 230 of the lower syringe 220 fixed to the first syringe pressing rod fixing portion 120 is also downward Go to. In this process, a mixture of a fluid containing microparticles and a separation solution filled in the upper syringe 210 is subjected to a downward pressure. By the pressure, a mixture of the fluid including the microparticles and the separation solution is injected into the lower syringe 220, which passes through the filter chipset 240 in this process. Accordingly, only the material that can pass through the filter chipset 240 is injected into the lower syringe 220, and the material that cannot pass through the filter chipset 240 is the outer cylinder 212 of the upper syringe 210 ). That is, particles having a relatively large size, such as various cells, are separated in a form positioned on the filter chipset 240.

When the separation operation is completed as shown in FIG. 15, the cover 40 is opened again, and the used syringe set 200 is removed. At this time, since the selected cells are separated in the separated filter chipset 240, the cells separated and selected using the filter chipset 240 may be obtained.

According to the microparticle processing apparatus according to the present invention, the upper syringe 210 and the lower syringe 220 are separately separated in the syringe set 200, and between the upper syringe 210 and the lower syringe 220 A filter chipset 240 is provided. Accordingly, after particle separation, the filter chipset 240 is separated to recover and analyze the selected particles in the filter, and the yield of the particles may be improved.

In the above, the present invention has been described by specific matters such as specific components and limited embodiments and drawings, but this is provided only to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments, Those of ordinary skill in the art to which the present invention pertains can make various modifications and variations from these descriptions.

Therefore, the spirit of the present invention is limited to the above-described embodiments and should not be determined, and all modifications that are equally or equivalent to the claims as well as the claims to be described later fall within the scope of the spirit of the present invention I would say.

1: control unit 2: mechanical unit
10: mounting body 12: magnet
20: fine particle separation unit 30: fine particle separation solution injection unit
40: cover 100: first holder
110: 1st syringe body fixing part 110A: 1-1st syringe body fixing part
110B: 1-2 syringe body fixing portion 111a: guide groove
111: first body guide 112a: gap adjustment screw
112: fixing guide 113: fixing knob
120: first syringe pressing rod fixing portion 121: first support body
122: pressing bar fixing guide 123: fixing knob
130: first drive device 200: syringe set
210: upper syringe 212: external cylinder
214: opening 216: tip
218: flange 220: lower syringe
222: outer cylinder 224: opening
226: tip 228: flange
230: piston 240: filter chipset
232: pusher 234: packing
236: pressing bar 300: second holder
310: second syringe body fixing portion 311a: guide groove
311: second body guide 312: second flange fixing guide
313: fixing knob 320: second syringe pressing rod fixing portion
321: second support body 322: second pressing bar fixing guide
323: fixing knob 330: second driving device
400: syringe for injection of separation solution 410: external cylinder
412: tip 414: opening
416: flange 420: piston
422: pusher 424: packing
426: presser bar

Claims (10)

In the microparticle processing apparatus for separating microparticles in a fluid,
A fine particle separation unit for separating the fine particles; And
Includes; a microparticle separation solution injection unit for providing a microparticle separation solution,
The fine particle separation unit,
A first syringe body fixing portion for fixing the outer cylinder of the syringe set;
A first syringe presser fixing portion for fixing the piston of the syringe set; And
Including; a first driving device for displacing the fixing portion of the first syringe presser,
The microparticle separation solution injection unit,
A second syringe body fixing portion for fixing the outer cylinder of the injection syringe;
A second syringe presser fixing portion for fixing the piston of the injection syringe; And
Microparticle processing apparatus comprising a; a second driving device for displacing the second syringe pressing rod fixing portion. The method of claim 1,
The first syringe body fixing part,
1-1 syringe body fixing portion; And
Particle processing apparatus comprising a; 1-2 syringe body fixing portion located below the 1-1 syringe body fixing portion. The method of claim 1,
The first syringe body fixing part,
A fine particle processing apparatus comprising a first body guide, and a first flange fixing guide that is spaced apart from the first body guide. The method of claim 1,
The first syringe pressure bar fixing part,
A fine particle processing apparatus comprising a first support body, and a first presser fixing guide whose separation distance from the first support body is adjusted. The method of claim 1,
The second syringe body fixing part,
A fine particle processing apparatus comprising a second body guide, and a second flange fixing guide that is spaced apart from the second body guide. The method of claim 1,
The second syringe presser fixing part,
A particle processing apparatus comprising a second support body, and a second presser fixing guide that is spaced apart from the second support body. The method of claim 1,
Further comprising a hexahedral mounting body,
The fine particle separation unit is disposed on the front surface of the mounting body,
The microparticle separation solution injection unit is a microparticle processing device disposed on an upper surface of the mounting body. The method of claim 7,
Further comprising a cover covering the front and upper surfaces of the mounting body in a state in which the microparticle separation unit and the microparticle separation solution injection unit are mounted,
The cover is capable of being mounted and detached from the mounting body through a plurality of magnets mounted on the mounting body. The method of claim 1,
The fluid is a microparticle processing device, characterized in that it contains blood, bodily fluid, cerebrospinal fluid, somen noodles, sputum, or a mixture thereof collected from human or animal samples. The method of claim 1,
The microparticles processing apparatus, characterized in that it comprises a tissue, cell, protein, nucleic acid or a cluster thereof collected from a human or animal sample.

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