KR101693972B1 - A filter for preparing liquid-based cytology specimen slide - Google Patents

Abstract

The present invention can easily prepare a specimen slide for use in a liquid-based cytological examination. In particular, it is possible to collect a cell in a rectangular shape on a slide, An injection unit having an inner space through which the solution injected through the opened upper portion can be received and an outlet formed at the lower portion; A base end portion connected to a lower portion of the injection portion and supporting the injection portion, receiving a solution discharged from the injection portion through an open upper portion and discharging the solution to the outside through a lower suction port; A cushion portion disposed on a piercing plate having a plurality of pores between the injection portion and the base portion, the cushion portion positioned at an outlet of the injection portion; And a filter sheet attached in close contact with the cushion portion; And a control unit.

Description

TECHNICAL FIELD [0001] The present invention relates to a filter for preparing a specimen slide for a liquid-based cell test,

The present invention relates to a filter for preparing a specimen slide for liquid-based cytology, more specifically, to a specimen slide for use in a liquid-based cytology, And more particularly, to a filter for producing a specimen slide for liquid-based cytology, which can capture cells in a rectangular shape on a slide and is advantageous for cell collection and observation.

Generally, in order to examine whether or not a body is abnormal, cells corresponding to a body part are collected using a cell harvesting tool, the collected cells are stored in a solution bottle containing the cell preservation solution, the cells are attached to a slide, As shown in Fig.

That is, a solution container for dispersing the cells attached to the cell harvesting tool is separately present, and the solution container is shaken to pour the solution into another container while the cells are sufficiently spread in the liquid, And the cells that are filtered are rubbed on a slide.

Here, the filter of the test sample according to the prior art has a liquid sample collecting bottle 1 storing the cell preserving solution 9 containing the sample cells collected as shown in FIG. 1, the sample collecting bottle 1 A tubular portion 2 connected to an upper side of the lid 3 to allow the cell preserving solution 9 to pass therethrough and a porous member 6 fixed to the lower end of the lid 3, And a plunger 5 inserted into the syringe bar 4 so as to be movable upward and downward.

On the other hand, a cell collection brush 2b is formed on the lower side of the conduit part 2, and a disk 2c is formed on the upper side of the conduit part 2. On the lower side of the syringe 4, And an O-ring 8 which is in contact with the upper folded end 2a of the upper shell 2c.

Here, reference numeral 7 denotes a filter member.

The use state of the specimen sample filter configured as described above will be described below.

First, the lid 3 is separated from the sample collecting container 1 and then inserted into the human body such as the uterus using the brush 2b to collect sample cells from the uterus, After the brush 2b is placed in the container 1 and then the lid 3 is engaged, sample cells are accommodated in the cell preservation liquid 9. [

Then the filter member 7 is placed on the circular plate 2c and the flange 4a of the syringe barrel 4 is positioned on the upper side of the lid 3, The cell storage liquid 9 containing the sample cells is sucked upward through the channel section 2. The sample cells are caught by the filter member 7 and attached to the lower side of the filter member, The cell-preserving solution 9 filtered through the porous member 6 is sucked into the syringe barrel 4.

When the sample cells are filtered on the filter member 7, the syringe barrel 4 is separated from the sample collecting container 1, the filter member 7 is taken out, placed on a slide for sample inspection (not shown) After the slides for specimen inspection with attached cells are prepared, the slides are inspected microscopically.

However, the filter of the liquid specimen sample according to the above-described prior art has a complicated configuration and requires a sophisticated work, which requires a highly skilled inspector. If excessive pressure is maintained or the suction is kept too long, the cells that have been collected will be destroyed or excessively larger than the amount required for inspection will be stacked on the filter surface and transferred to a nested form at the time of slide transfer The abnormal cells to be observed at the time of diagnosis are concealed by normal cells, and the possibility of causing misdiagnosis increases.

Also, the result of the cell collection through such a filter will be such that a circular filter is collected on the filter member, and finally, the shape of the cell transferred to the slide will also show a circular cell shape as shown in Fig. However, since the circular shape of such a circular cell is not matched with a slice having a generally rectangular shape, it is disadvantageous for cell collection and cell migration, and when the microscope is observed, the cell moves to the front and rear, It has a problem that it is not intuitive to observe all of them.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a filter for preparing a specimen slide for a liquid-based cell test which can easily prepare a specimen slide for use in a liquid- .

In particular, when the suction pressure is applied to the bottom of the filter in the process of collecting the cells by permeating the solution containing the cells dispensed in the upper portion of the filter to the filter, the cells can be evenly dispersed, The present invention provides a filter for preparing sample slides for liquid-based cytology, which can capture cells in a rectangular shape on a slide and is advantageous for cell collection and observation.

According to the present invention, there is provided an injection apparatus comprising: an injection unit having an inner space in which a solution injected through an open top can be received; A base end portion connected to a lower portion of the injection portion and supporting the injection portion, receiving a solution discharged from the injection portion through an open upper portion and discharging the solution to the outside through a lower suction port; A cushion portion disposed on a piercing plate having a plurality of pores between the injection portion and the base portion, the cushion portion positioned at an outlet of the injection portion; And a filter sheet attached in close contact with the cushion portion; The filter is characterized by comprising:

Preferably, the filter sheet is formed of grids smaller than the size of the cells.

Preferably, the injecting portion is formed with a liquid-collecting protrusion protruding along the inner circumference of the outer wall to constitute a discharge port.

Preferably, the injection unit is formed with a slide groove formed along the outer circumference of the outer wall.

Preferably, the injection unit is formed by intersecting at least one downward flange projecting downwardly circumferentially from a lower position of the discharge port and a coupling flange.

Preferably, a circular rising portion is formed at an upper portion of the base end portion so as to protrude upward, and is inserted into the downward flange of the injection portion and the inner wall of the coupling flange, thereby coupling the injection portion and the base end portion.

Preferably, at least one mounting protrusion is formed on the outer surface of the base end portion so as to protrude laterally, a downward flange end of the injection portion is mounted on the mounting protrusion, a coupling flange of the injection portion is inserted between the mounting protrusions, .

Preferably, the perforated plate supporting the cushion part is formed with a perforation on the entire surface, and the perforation holes are formed in a square.

Preferably, the cushion portion is formed of an elastic material so that pressure can be dispersed.

Preferably, at least one latching protrusion is formed on the outer surface of the base end portion so as to protrude laterally, at least one or more latching lats are projected upward from the upper surface of the injection portion, and an outer diameter of the base end portion corresponds to an inner diameter of the injection portion And the filter is stacked in such a manner that the proximal end portion is inserted into the injection portion and the fixing protrusion of the proximal end portion is sandwiched between the separating latches.

According to the present invention, it is possible to easily prepare a specimen sample slide for use in a liquid-based cytological examination even if it is not a highly skilled person.

In particular, it can capture cells in a rectangular shape on a slide, which is advantageous for cell collection and observation.

1 is a view for explaining a filter of a specimen sample according to the prior art;
Figure 2 shows a cell slide transferred through a filter according to the prior art;
3 is a sectional view showing a filter according to the present invention.
4 is a sectional view for explaining a cushion portion and a filter sheet of a filter according to the present invention;
Figure 5 shows a cell slide transferred through a filter according to the present invention.
6 is a cross-sectional view showing a laminated state of the filter according to the present invention.

Hereinafter, a filter for preparing a specimen slide for a cell test according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a cross-sectional view of a filter according to the present invention, wherein FIG. 3A is a filter seen from the front and FIG. 3B is a filter viewed from behind.

The filter according to the present invention is a filter for preparing sample slides for performing cytological microscopy of various cells by liquid-based cytology.

As shown in FIG. 3, the filter according to the present invention includes an injection unit 10 having an inner space in which a solution to be injected through an open upper part can be received, And is connected to the lower part of the injection part 10 to support the injection part 10 and receives the solution discharged from the injection part 10 through the opened upper part and discharges the solution to the outside through the lower suction port 25 A cushion part 30 disposed on a piercing plate 33 having a plurality of pores between the pouring part 10 and the base part 20 and positioned at an outlet of the pouring part 10, And a filter sheet 40 adhered to and attached to the cushion 30.

The injection unit 10 receives a liquid containing cells from an external storage container through a wide opened top opening. Since the upper part of the injection part 10 is opened and the inner space of the injection part 10 is partitioned by the outer wall of a certain height, the storage container having an outer diameter smaller than the inner diameter of the injection part 10 is accommodated in the injection part 10 So that the liquid can be safely dispensed inside. Here, a scale for confirming the amount of the solution in the injection part may be formed on the inner surface of the injection part 10.

A plurality of divisional latches 16 are formed on the upper portion of the outer wall of the injection unit 10 so as to protrude upward. The slide groove 12 is formed along the outer circumference of the outer wall of the injection part 10 along the circumference of the groove and the slide groove 12 is formed in a groove for transferring the filter when the filter of the present invention is inserted into the automatic device. to be.

A liquid-collecting protrusion 13 protrudes inward along the inner periphery of the lower portion of the injection unit 10 to form an outlet 17 through which liquid containing the cells can be discharged. At least one downward flange 14 protruding downward circumferentially from the lower end of the discharge port 17 and a coupling flange 15 are formed so as to intersect with each other. Here, the downward flange 14 and the engagement flange 15 are configured to engage the injection portion 10 with the proximal portion 20, and the engagement flange 15 is formed longer than the downward flange 14.

The proximal end 20 is connected to a lower portion of the injection unit 10 to support the injection unit 10. To this end, the upper portion of the proximal portion 20 connected to the discharge port 17 of the injection unit 10 is opened and the lower portion is formed with the suction port 25 for discharging the solution to the outside. In the test, the external suction head is tightly connected to the suction port 25, and the solution is discharged to the suction head side through the suction port 25 by the suction force from the suction head.

A circular rising part 21 protrudes upward and protrudes laterally from the base part 20 so that the rising part 21 of the base part 20 protrudes in the lateral direction, The flange 14 and the inner flange 15 of the coupling flange 15 are engaged with each other so that the injection portion 10 and the proximal portion 20 are engaged with each other. The coupling flange 15 of the injection unit 10 is connected to the fixing protrusion 22 of the base unit 20 and the downward flange 14 of the injection unit 10 is fixed to the base unit 20 And is fitted between the projections 22.

Here, the injection unit 10 and the base 20 may be made of ABS (Acrylonitrile Butadiene Styrene Plastic), polycarbonate (PC), or polyethylene (PE).

A first seat portion 23 and a second seat portion 24 on the upper side are protruded inward from the proximal end portion 20 so as to protrude inwardly of the proximal end portion 20 to support the cushion portion 30 33 are seated in the base 20.

The cushion unit 30 and the pier plate 33 for supporting the cushion unit 30 are disposed between the injection unit 10 and the base unit 20 and include a mounting part 32 and a support part 31 connected to the lower part of the perforated plate 33, As shown in Fig.

More specifically, a support portion 31 formed as an outer wall is seated on the second seat portion 24, and a mounting portion 32 protruded from the outer periphery of the support portion 31 is provided on the first seat portion 23 on the upper side. The cushion part 30 and the perforated plate 33 for supporting the cushion part 30 are stably embedded.

At this time, a cushion part 30 is disposed on the upper surface of the pier plate 33 as shown in FIG. 4, and a filter sheet 40 for filtering cells in solution is adhered to the upper surface of the cushion part 30, Will be. Such a perforated plate 33, the cushion 30 and the filter sheet 40 will be located at the outlet 17 of the injection unit 10.

Here, the filter sheet 40 is a film-type filter sheet (membrane filter), and is laminated on the cushion portion 30 by ultrasonic / high-frequency welding. The shape of the filter sheet 40 is not limited. For example, the filter sheet 40 may be processed into a circular shape at the time of processing, and the filter sheet 40 may be fused so as to be in a quadrangular shape along the outer periphery of the cushion 30, have. The reason why the filter sheet 40 is processed into a circular shape as described above is that it is for processing convenience, and it is for ensuring the maximum free space that can be used for fusion welding. The filter sheet 40 is preferably formed of grids smaller than the size of the cells. The filter sheet 40 may be made of a material such as polyethylene (PE), Teflon (PTFE, PVDF), polypropylene (PP) or the like so as to have resistance to chemicals used in preserving solutions.

The perforated plate 33 is made of, for example, a plastic material, and the perforations are formed on the entire surface of the perforated plate 33, and the perforation holes are generally quadrilateral as shown in FIG. 4 (b). Here, the reason for forming the perforations of the perforated plate 33 is to uniformly distribute the suction pressure applied from below.

The cushion part 30 is formed of an elastic material so as to provide appropriate cushion and allow pressure dispersion during the cell transfer process. Therefore, by processing the piercing structure of the perforated plate 33 to function effectively for pressure dispersion, the pressure is uniformly dispersed on the surface of the filter sheet 40, and the cells filtered by the filter sheet 40 are dispersed widely And is collected in a single-layered state. In this process, the cushion part 30 may be made of an elastic material such as a latex of a porous material or a similar material. In particular, when the thickness of the cushion part 30 is excessively large, the solution solution is squeezed in pressing process for transferring the cells to the slide to prevent cell migration, so that the thickness of the cushion part 30 is appropriately thinned, It is preferable to mold the solution solution so that it is not excessively absorbed.

If the cushion part 30 can be supported horizontally, it is advantageous to maximize the puncture of the perforated plate 33. However, when the suction pressure is applied, the elastic cushion part 30 is bent. When the pressure is removed, the cushion part 30 is restored to its original shape (plane) due to its own restoring force, but the restoration is not completely performed after the solution is absorbed. In the process of cell stamping on the glass slide, the cells corresponding to the puncture site of the perforated plate 33 are relatively less transferred than those not punctured. Therefore, in order to minimize such uneven cell migration, it is possible to uniformly transfer cells by dispersing the pores of the perforated plate 33 as much as possible and having an appropriate opening rate.

As a result, in the solution discharged from the injection unit 10, the cells will be adsorbed on the filter sheet 40, and since the discharge path of the solution in the adsorption process is quadrangular by the perforated plate 33, ) Will have a quadrangular shape as shown in FIG.

Unlike the existing round shape, if the cells are adsorbed in a square, the cells can be captured in a rectangular shape on the slide, which makes it possible to prepare a specimen slide specimen for cell examination, which is advantageous for cell collection and observation. For example, when observing cells collected by microscope at a magnification of 50 to 400 times under a microscope, the sample slide moves back and forth and left and right. When the cells are transferred in a circular shape, they are observed across the whole cell area Although it is not intuitive, it is more intuitive and advantageous for surface movement when cells are transferred to a square. In addition, more cells can be captured and transferred to a limited area of the upper surface of the slide, which typically has a rectangular shape.

On the other hand, in the automation process, it is necessary to stack and laminate such filters in order to save space.

The filter of the present invention is characterized in that at least one mounting protrusion 22 protrudes laterally on the outer surface of the proximal end portion 20 and at least one or more division lugs 16 protrude upward from the upper surface of the injection portion 10 The proximal end 20 of the proximal end 20 corresponds to the inside diameter of the injection part 10 and the proximal end 20 of the proximal end 20 of the proximal end 20 is inserted into the injection part 10, The filter is stacked in such a manner that it is sandwiched between the separating latches 16. That is, one filter lower base portion 20 is inserted into the upper injection portion 10 of the other filter.

FIG. 6 is a cross-sectional view showing a laminated state of the filter according to the present invention, and the filters are stacked for automation and the like, and the supply to the packaging and the mechanical device will be smoothly and efficiently performed.

As described above, an optimal embodiment has been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: injection part 11: outer wall
12: slide groove 13: liquid collecting projection
14: Downward flange 15: Coupling flange
16: Latch 17: Outlet
20: proximal portion 21:
22: fixture projection 23: first seat portion
24: second seat portion 25: inlet
30: Cushion part 31: Support part
32: mounting portion 33: perforated plate
40: Filter sheet

Claims (10)

An injection part having an inner space through which the solution injected through the open upper part can be received and an outlet formed at the lower part;
A base end portion connected to a lower portion of the injection portion and supporting the injection portion, receiving a solution discharged from the injection portion through an open upper portion and discharging the solution to the outside through a lower suction port;
A cushion portion disposed on a piercing plate having a plurality of pores between the injection portion and the base end portion and positioned at an outlet of the injection portion; And
A filter sheet attached in close contact with the cushion portion; / RTI >
At least one mounting protrusion is formed on the outer surface of the base end so as to be able to laminate the individual filters in a state in which the upper injection part and the lower base end part are coupled to each other and at least one or more divisional ratchet teeth are formed on the upper surface of the injection part The outer diameter of the proximal end portion corresponds to the inner diameter of the injection portion,
Wherein a plurality of filters are stacked in such a manner that a fixing protrusion of the base end is sandwiched between the separating latches in the process of inserting and inserting the lower base end of another individual filter into the upper injection part of the individual filter.
The method according to claim 1,
Wherein the filter sheet is formed of grids smaller than the size of the cells.
The method according to claim 1,
Wherein the injecting portion is formed with a liquid-collecting protrusion protruding along an inner circumference of the outer wall to constitute a discharge port.
The method according to claim 1,
Wherein the injection unit is formed with a slide groove formed along the outer circumference of the outer wall.
The method according to claim 1,
Wherein the injection unit is formed by crossing at least one downward flange projecting downwardly circumferentially from a lower position of the discharge port and a coupling flange.
6. The method of claim 5,
Wherein a circular rising portion is formed at an upper portion of the base end portion so as to protrude upward and is fitted into an inner wall of a downward flange and a coupling flange of the injection portion, thereby coupling the injection portion and the base end portion.
The method according to claim 6,
At least one or more engaging projections are formed on the outer surface of the base end portion. The downward flange end of the injecting portion is fixed to the engaging projection, and the engaging flange of the injecting portion is fitted between the engaging projections. .
The method according to claim 1,
Wherein the perforated plate for supporting the cushion portion is formed with a perforation on the entire surface thereof, and the perforation holes are formed into a square.
The method according to claim 1,
Wherein the cushion part is formed of an elastic material so that pressure can be dispersed.
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