KR20160099290A - Membrane filter container for liquid based cytopyge - Google Patents

Abstract

The present invention relates to a membrane filter container for liquid-based cytology, the membrane filter container having an improved structure to prevent non-uniform distribution of the specimen cells due to an excessive vacuum suction force while preventing degeneration of the specimen cells caused by contact pressure of the slide when the specimen cells are smeared on the slide by bringing the slide into contact with the top surface of a membrane film on which specimen cells are remained. A membrane filter container for liquid-based cytology according to the present invention includes: a top part in which an edge of a membrane film (15) is fixed to the top of a membrane body (10), and a flow path (11A) allowing external air to flow into a through hole is formed; and an inner circumference rib which is formed on an inner side of the top part, and a height of which is lower than that of the top part such that the inner circumference rib is spaced apart from the bottom of the membrane film (15).

Description

TECHNICAL FIELD [0001] The present invention relates to a membrane filter container for inspecting a liquid cell,

The present invention relates to a membrane filter container for inspecting a liquid cell for cancer testing. More particularly, the present invention relates to a membrane filter container for inspecting a liquid sample by contacting a slide on an upper surface of a membrane film, The present invention relates to a membrane filter container for inspecting a liquid cell having improved structure so as to prevent denaturation and to prevent uneven distribution of a sample cell due to excessive vacuum suction force.

Generally, in order to examine whether or not a body is abnormal such as cancer, inflammation or virus, cells corresponding to a physical examination site are collected, the collected cells are stored in a solution bottle containing the cell solution solution, And a microscope.

Conventionally, there is a separate solution box for dispersing the cells on the brush into the solution, and the solution bottle is shaken to pour the solution into the other container while the cells are sufficiently spread in the liquid. The suction device is closely attached to the bottom of the filter, , And the filter cells are rubbed on a slide.

When the container is separated from the main body so as to approach the slides, the liquid mixture remaining in the container is poured down by gravity and is lost.

However, since the process of transferring the cells from the solution bottle to the slide must be performed manually by the user, it takes a lot of time and the contamination or impurities may be transferred from the user's hand to the slide, there was.

In addition, foreign substances may be contained in cells other than the cells collected in the solution container. In this case, since separation of foreign substances and cells is not easy, a separate tool for separation is required.

A prior art for this purpose is disclosed in Korean Patent Registration No. 10-1035427, "Solution container ", which is composed of a container body formed such that upper and lower portions thereof are opened, A filter member disposed inside the container body for filtering foreign substances contained in the solution solution, and opening / closing means disposed inside the container body for selectively blocking inflow of the solution solution.

The container body is divided into an upper liquid chamber and a lower liquid chamber communicating with each other, and a receiving member is detachably coupled to the lower portion.

After the solution solution is collected in the lower liquid chamber after being filtered through the filter member, after the receiving member is detached from the container main body, sample cells are applied to the slide using a vacuum adsorber, Has a cumbersome process of smearing through slides through a membrane filter to separate the slides.

In other words, in the past, the process of separating the sample cells from the solution solution before the smearing process and smearing the separated sample cells onto the slide is troublesome, and the process of detaching the receiving member from the bottom of the container body using a mechanical device So that the workability is deteriorated.

The conventional membrane filter has a structure in which a plurality of drainage holes are formed in an upper part of a filter body, a water-soluble material such as a sponge is seated on the drainage hole, and a membrane film is fixed to the upper edge of the filter body on the water- .

Such a membrane filter filters specimen cells on the upper side of a membrane film during the process of draining a solution solution while sucking the same by forming a vacuum negative pressure on the lower side of the sponge and then pressing the slides on the upper side of the membrane film, And then, a pressing force is transmitted to the sponge side.

However, in the conventional membrane filter structure, since the membrane film is disposed in close contact with the sponge, water that is unevenly faded in the sponge is formed on the membrane film, and thus there is a disadvantage in that the cell is not adsorbed during the slide- So that the cells implanted on the surface of the slide are partially lost at the moisture-bearing site and are partially adsorbed, resulting in a vacant circle in the middle.

In addition, when the density and thickness of the sponge become uneven in the process of pressing the slide, there is a difference in the degree of adhesion with the slide, and thus the adsorption of the cells is not properly performed, Cell degeneration due to development occurs.

When the thickness of the sponge is increased or the edge is fixed with the sponge in close contact with the sponge in order to overcome this problem, the membrane film interferes with the sponge and the pore size of the membrane film adhered to the sponge increases, There is a risk of cell loss.

Further, since the conventional membrane film and the sponge have a fixed diameter, there is a disadvantage that the size of the cell circle implanted on the surface of the slide can not be varied.

As a prior art for improving this, Korean Patent Registration No. 10-1348779 "Membrane filter structure and cell smear method using the same" (registered date: December 31, 2013) and shown in FIGS. 1 to 3, A through hole 105 is formed to allow solution solution S to pass therethrough and a rim of the membrane film 150 for filtering the specimen cells C is fixed to the upper edge of the through hole 105, A hollow portion 205 is formed so that the lower portion of the membrane body 100 is inserted into the outer circumferential surface of the membrane body 100 and a pressing force is transmitted from the upper portion of the membrane body 100 to the inside of the lower fitting portion 110 A receiving solution groove 305 is formed in the lower part of the membrane body 100 to be fitted into the through hole 105 and the cushion member 350 is disposed thereon, A plurality of drain holes 310 are formed so as to pass therethrough, Formation and would configured into the kit 300 that is coupled to the lower suction jig.

3, since the hollow 205 of the sedimentation guide 200 is formed in a linear shape corresponding to the size of the membrane film 150, The solution solution S injected into the hollow 205 of the sedimentation guide 200 is directly contacted to the upper side of the membrane film 150 so that only the specimen cells C contained in the solution solution S 150, respectively.

At this time, in the course of the solution liquid S being drained to the lower side through the drain hole 310 by the suction jig, the middle portion between the membrane film 150 and the cushion member is vacuum suctioned during the vacuum suction process using the suction jig 400 ("A" region).

Therefore, as the intermediate portion between the membrane film 150 and the cushion member 350 is bent in a concave shape, the cells placed on the middle portion of the membrane film 150 are attached to the surface of the slide 50 .

As a result, the cell is not attached to the middle of the cell circle C1 attached to the surface of the slide 50, and the central portion becomes empty.

In addition, since the degree of vacuum of each part is different in the above-described vacuum inhalation process, overlapping of the cells overlapping the part where the vacuum pressure mainly acts is overlapped or the cell is not positioned in the part where the vacuum pressure is low, There is a problem.

In addition, when the vacuum suction force acts on the sponge during the vacuum suction process, the sponge and the membrane film are excessively deformed, causing damage to the components. In addition, specimen cells are concentrated only on the upper side of the portion where the drain hole There is a disadvantage that it is distributed.

Korean Patent Registration No. 10-1035427 "Solution container" (registered on May 11, 2011) Korean Patent Registration No. 10-1348779 "Membrane filter structure and cell smear method using the same" (registered on December 31, 2013)

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and its object is to provide a membrane filtration apparatus which is capable of preventing excessive deformation of a cushion member due to excessive vacuum suction force during a process of draining a solution by a vacuum suction force And to provide a membrane filter container for inspecting liquid-phase cells in which the structure of the solution liquid is uniformly distributed so as to prevent concentration of sample cells only in the vicinity of a drainage hole.

According to an aspect of the present invention, there is provided a membrane-type membrane filter, comprising: a membrane body having a through-hole formed therein to allow a solution solution to pass therethrough and having a rim of a membrane film for filtering specimen cells on an upper edge of the through- And a suction jig is coupled to the bottom of the membrane filter container. The membrane filter container according to claim 1,

And a channel for introducing outside air into the interior of the membrane body is formed at an upper end of the membrane body, the upper end of which is fixed at the edge of the membrane film.

The flow path may be a flow path groove formed in a concave shape downward at the upper end portion or a vent hole formed in the upper end side portion to communicate with the outside and the inside.

An inner diameter rib formed inside the upper end portion and relatively lower than a height of the upper end portion so as to be spaced apart from the bottom surface of the membrane film.

The inner diameter rib is further provided with an air passage for supplying outside air supplied through a flow path into the through hole at a position corresponding to the flow passage.

A flange protruding outwardly is formed on the upper outer peripheral surface of the membrane body so that the lower surface of the sedimentary guide is seated.

First, by forming a flow path 11A for introducing outside air outside the upper end portion 11 of the membrane body 10 into the through hole 10a, the suction force of the cushion member 35 in the vacuum drainage process of the solution solution, Even if the central part of the membrane film 15 and the membrane film 15 are deformed into a concave shape, it is possible to prevent excessive vacuum suction force from being exerted as the outside air flows into the through hole 10a, It is possible to prevent the sample cells from concentrating only around the drain hole 31 in the process of draining the solution solution through the drain hole 31 and to obtain a cell circle having a uniform distribution profile .

The present invention is characterized in that an upper end portion 11 and an inner diameter rib 13 are formed at an upper end portion of the membrane body 10 so as to have a height difference therebetween and an outer end portion 11 and an inner diameter rib 13 are formed, The inner diameter ribs 13 support the membrane film 15 so that normal deflection is performed during the vacuum suction process and the pressing process of the slide and the outer air is easily supplied into the through holes It is possible to prevent an excessive vacuum suction force from being applied.

1 and 2 are a perspective view and a sectional view of a conventional membrane filter container;
3 is a view showing the state of use of a conventional membrane filter container.
4 is an exploded perspective view of a membrane filter container according to an embodiment of the present invention.
Fig. 5 is a sectional view of Fig. 4; Fig.
6 is a perspective view showing an example of the flow path of the present invention.
7 is a perspective view showing another example of the flow path of the present invention.
8 is a cross-sectional view of a membrane body according to another embodiment of the present invention.
9 is an exemplary view schematically showing the use state of another embodiment of the present invention.
10 is a view showing the state of use of the membrane filter container of the present invention.

4 to 7, the membrane filter container according to the present invention has a through hole 10a formed therein so as to allow a solution solution S to pass therethrough, A sedimentation guide 20 in which a hollow 20a is formed so that a lower portion of the membrane body 10 is fitted to an upper outer peripheral surface of the membrane body 10; And a suction jig (not shown) is coupled to the lower part of the lower part of the body 10a, and a plurality of drain holes 31 are formed in the upper part of the through hole 10a so that the cushion member 35 is disposed on the upper part, And a kit (30).

Such a configuration makes it possible to reduce deflection of the membrane film 15 when the slide 50 is pressed against the membrane film 15 to smear the sample cells, thereby reducing the denaturation of the sample cells due to the pressure of the slide 50

The settling guide 20 and the inner kit 30 may be formed of a relatively soft material (rubber or silicone) than the membrane body 10 so that the settling guide 20 and the inner body 30 may be formed between the settling guide 20 and the membrane body 10, Leakage of specimen cells between the kit 30 and the membrane body 10 was prevented.

The membrane body 10 has an upper end 11 on which an edge of the membrane film 15 is fixed and a flange 12 projecting outward so that the lower surface of the sedimentation guide 20 is seated on an upper outer circumferential surface thereof. ) Are formed.

The upper end portion 11 is formed with a flow path 11A through which external air communicates with the inside of the membrane body 10 to introduce outside air outside the membrane body 10 into the inside of the membrane body 10.

As shown in FIG. 6, the flow path 11A is formed so that a flow path groove 11a having a downward concave shape is formed in the upper end portion 11, or the flow path groove 11a is formed in the upper end portion 11, A vent hole 11b in which the side portion of the upper end portion 11 is perforated can be adopted.

It is preferable that the channel grooves 11a or the air vents 11b are formed in a plurality of spaced apart portions on the edge of the upper end portion 11. [

The vent hole 11b may be formed such that external air flows in a horizontal or downward inclined direction.

More preferably, the flow path 11A of the present invention may use the flow path groove 11a and the vent hole 11b in parallel.

 The sedimentation guide 20 has a lower inner diameter than the upper inner diameter of the hollow 20a. The sedimentation guide 20 is formed on the inner side of the hollow 20a so as to be spaced apart from the outer wall and has a rounded inclined surface 22a. (22). ≪ / RTI >

The reinforcing rib 23 is formed at a lower end portion of the reinforcing rib 23 when the reinforcing rib 23 is engaged with the membrane body 10, And is seated in the upper end portion.

The guide part 22 functions to guide the solution solution S to the center of the membrane film 15.

8 and 9 showing another embodiment of the present invention, in another modification of the membrane body 10, the edge of the membrane film 15 is fixed to the upper end of the membrane body 10 An upper end portion 11 formed with a flow path 11A for introducing outside air into the inside and an inner diameter rib 13 formed inside the upper end portion 11 and spaced apart from the bottom surface of the membrane film 15 are formed have.

The inner diameter rib 13 is formed to be lower than the height of the upper end portion 11.

More preferably, the inner diameter rib 13 is formed with an air passage 13A for supplying the outside air supplied through the flow passage 11A into the through hole 10a.

The air passage 13A is formed in the form of a flow path groove 11a or a vent hole 11b having the same structure as the flow path 11A described above.

In the first embodiment of the present invention, an assembling process of each component is described. First, an inner kit 10 in which a cushion member 35 is disposed on the upper side is provided in a through hole 10a formed to be opened on the lower side of the membrane body 10 (30) is inserted and assembled.

At this time, the cushion member 35 is brought into contact with the lower side of the membrane film 15 in the process of entering the through hole 10a.

The upper end of the membrane body 10 is engaged with the lower portion of the sedimentation guide 20 while the sedimentation guide 20 is seated on the upper side of the membrane body 10. [

The lower end of the outer wall of the sedimentation guide 20 is seated on the upper side of the flange 12 of the membrane body 10 and the end of the guide part 22 of the sedimentation guide 20 is brought into contact with the upper side of the membrane film 15 .

Further, the reinforcing ribs 23 are assembled such that the lower end thereof is brought into contact with the upper end portion of the membrane body 10.

10, when the solution solution is injected on the upper side of the hollow 20a of the sedimentation guide 20, the hollow 20a in the sedimentation guide 20 and the upper side of the membrane film 15 The solution solution temporarily flows through the drainage hole 31 in the lower side when the vacuum suction of the suction jig is performed.

At this time, the specimen cells C contained in the solution solution S are filtered so as to remain on the upper side of the membrane film 15. In this process, the specimen cells are collected on the inclined surface 22a of the guide part 22 of the sedimentation guide 20, And concentrated to the center side.

This causes the sample cells to descend on the inclined surface 22a of the sedimentation guide 20 when the solution solution is temporally filled between the sedimentation guide 20 and the membrane film 15 and to move down through the lower part of the hollow 20a to the membrane film 15 The sample cells are not scattered unevenly in the central portion of the membrane film 15 but also the sample cells may be superimposed on the central portion of the membrane film 15 .

The vacuum suction force is transmitted to the inside of the lower through hole 10a of the membrane film 15 through the suction jig (not shown) so that the central portion of the cushion member 35 and the membrane film 15 are bent concave downward The external air outside the membrane body 10 flows into the through hole 10a through the flow path 11A formed in the upper end portion 11 and the vent path 13A formed in the inner diameter rib so that an excessive vacuum suction force is applied to the cushion member 10a, (35) and the membrane film (15).

Particularly, when a vacuum suction force is applied to the inside of the inner kit 30 by a suction jig, the membrane film 15 is squeezed and at the same time, the external air flowing through the channel 11A formed at the upper edge of the membrane body 10 The solution solution passing through the membrane film 15 is guided to the center side of the membrane film 15 and drained.

Accordingly, the sample solution is collected at the center of the membrane filter 15 by the solution solution which is led to the center side of the membrane film 15, thereby improving the analysis efficiency at the time of microscopic observation.

Thereafter, the operator separates the sedimentation guide 20 from the membrane body 10 and then moves the slide 50 downward from the top of the membrane film 15 to contact the membrane film 15, The sample cells remaining on the upper side of the membrane film 15 are attached.

These specimen cells adhere to the surface of the slide in the form of a circular cell circle, and are uniformly distributed in the central part of the slide within the circular cell circle.

Therefore, since the inner diameter of the hollow 20a of the sedimentation guide 20 is narrower than the upper portion of the sedimentation guide 20, when the solution solution is drained to the lower side of the membrane body 10 after the solution solution is injected, Not only is it concentrated on the center of the upper side of the film 15 and then filtered, it sticks in the contact process of the slide to obtain a uniformly distributed cell circle C1, It is possible to prevent the excessive vacuum suction force from being applied to the cushion member 35 and the membrane film 15 and to prevent deformation of the membrane 15, By preventing the cells from concentrating and uniformly distributing the sample cells, it is possible to obtain the complete type of cell circle (C1) There is an advantage that it can be improved.

10; Membrane body 10a: through hole
11: upper end portion 11A:
11a: a channel groove 11b: a vent hole
12: flange 13: inner diameter rib
13A: through-air passage 15: membrane film
20: Deposition guide 20a: hollow
22: guide portion 22a: inclined surface
23: reinforcing rib 30: inner kit
31: drainage hole 35: cushion member
C: specimen cell C1: cell circle
S: solution amount

Claims (6)

A membrane body 10 in which a through hole 10a is formed to allow a solution solution S to pass therethrough and a rim of a membrane film 15 for filtering specimen cells is fixed to an upper edge of the through hole 10a, A plurality of drain holes 31 are formed on the lower side of the body 10 so as to be inserted into the through holes 10a and a cushion member 35 is disposed on the upper side and a solution solution S is passed therethrough, 1. A membrane filter container for liquid-cell inspection comprising a kit (30)
Wherein a channel 11A for introducing outside air into the interior of the membrane body 10 is formed on the upper end 11 of the membrane body 10 to which the rim of the membrane film 15 is fixed. Membrane filter containers for. The membrane filter container according to claim 1, wherein the channel (11A) is a channel groove (11a) formed in the upper end (11) of the membrane body (10) in a downwardly concave shape. The membrane filter apparatus according to claim 1, wherein the channel (11A) is a vent hole (11b) formed in the side surface of the upper end (11) of the membrane body (10) . The membrane film (15) according to any one of claims 1 to 3, further comprising an inner diameter rib (21) formed on an inner side of an upper end (11) of the membrane body (10) and spaced from a bottom surface of the membrane film (13) is further formed in the membrane filter container. The air conditioner according to claim 4, wherein the inner diameter rib (13) further includes an air passage (13A) for supplying outside air supplied through the oil passage (11A) into the through hole (10a) at a position corresponding to the oil passage Wherein the membrane filter is a membrane filter. [7] The apparatus according to claim 4, further comprising a sedimentation guide (20) having a hollow to be fitted to an upper outer circumferential surface of the membrane body (10)
Wherein a flange (12) protruding outward is formed on an upper outer circumferential surface of the membrane body (10) so that a lower surface of the settling guide (20) is seated.

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