KR20190002531U - Filter container for smear of specimen - Google Patents

Abstract

A sample smear filter vessel is provided to minimize the loss of specimen. The filter container includes an upper body having a first internal space; A lower body detachably coupled to the upper body and having a second inner space configured to be in fluid communication with the first inner space; A filter member disposed on the fluid path from the first inner space to the second inner space; And a smear membrane member disposed on a fluid path from the first inner space to the second inner space, wherein the upper body sidewall portion of the upper body at least partially slopes.

Description

Filter container for sample smearing {FILTER CONTAINER FOR SMEAR OF SPECIMEN}

The present invention relates to a sample smearing filter container, and more particularly to a sample smearing filter container for minimizing the loss of the sample during the filtering and smearing of the sample.

Smear test is a method of bacterial testing, in which a sample is stained on a slide glass and stained to observe the microscope.

For example, the bacterium smear test used for the diagnosis of tuberculosis may be performed by microscopic observation after selectively staining only tuberculosis bacteria by thinly coating a sample such as human sputum on a slide glass. Since the smear test can quickly identify infection by simple staining for bacteriological diagnosis, it is possible to quickly detect and treat active TB patients with a relatively simple test compared to other methods.

However, since smear test performs smear test by filtering a sample from a sample of a patient suspected of having a pathogen, an inspector such as a clinician or a pathologist performing the test is always at risk of exposure to pathogens. For example, in the process of filtering a sample from a sample provided from a patient, or in the process of smearing a sample of the filtered sample on a slide glass, there is a risk that pathogens are spread into the air and infect the examiner.

One way to minimize this risk can be illustrated by smearing a sample onto a slide glass using an automatic smearing device. However, the automatic smearing method using the automatic smearing device is not performed by the inspector but by the automated device, so the sample may be lost or lost.If the concentration of pathogens in the sample is scarce, May be inaccurate.

The problem to be solved by the present invention is to provide a filter container that can minimize the loss of the sample in the process of filtering the sample and smearing the filtered sample.

The filter container according to an embodiment of the present invention for solving the above problems has an upper body having a first inner space; A lower body detachably coupled to the upper body and having a second inner space configured to be in fluid communication with the first inner space; A filter member disposed on the fluid path from the first inner space to the second inner space; And a smear membrane member disposed on a fluid path from the first inner space to the second inner space, wherein the upper body sidewall portion of the upper body at least partially slopes.

The lower body may include a lower body sidewall portion and a ceiling portion disposed at an upper end of the lower body sidewall portion and having a plurality of drainage holes.

The upper body may further include a fixed sidewall portion protruding downward from the upper body sidewall portion, and configured to fit into the lower body sidewall portion.

The upper body sidewall part may include a vertical sidewall part and an inclined sidewall part forming the inclination.

The vertical sidewall portion, the inclined sidewall portion and the fixed sidewall portion may be sequentially connected without a physical boundary, and the inclined sidewall portion may decrease in diameter from the vertical sidewall portion toward the fixed sidewall portion.

The minimum inner diameter formed by the upper body side wall portion may be smaller than the inner diameter formed by the lower body side wall portion.

1 is an exploded perspective view of a filter container according to an embodiment of the present invention.
FIG. 2 is a cross-sectional perspective view of the filter vessel of FIG. 1. FIG.
3 is a cross-sectional view of the upper body of FIG.
4 is a cross-sectional view of the lower body of FIG. 1.
FIG. 5 is a cross-sectional view of the filter container of FIG. 1 taken along line II ′. FIG.
FIG. 6 is a cross-sectional view of the filter container of FIG. 1 taken along the line II-II ′. FIG.
7 to 10 are views showing a method of smearing using the filter vessel of FIG.

Advantages and features of the present invention, and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only the embodiments to ensure that the disclosure of the present invention is complete, and those of ordinary skill in the art It is provided to inform the full disclosure of the scope of the invention, and the invention is defined only by the scope of the claims.

The spatially relative terms 'below', 'beneath', 'lower', 'above', 'upper' and the like are shown in FIG. It may be used to easily describe the correlation of a device or components with other devices or components. Spatially relative terms should be understood to include terms that differ in the direction of use of the device in addition to the directions shown in the figures. For example, when the device shown in the figure is reversed, a device described as 'below or beneath' of another device may be placed 'above' of another device. Thus, the exemplary term 'below' may include both directions below and above.

In the present specification, the first direction X means any one direction in the plane, and the second direction Y means the direction crossing the first direction X in the plane. In addition, the third direction Z means a direction perpendicular to the plane.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is an exploded perspective view of a filter container according to an embodiment of the present invention. FIG. 2 is a cross-sectional perspective view of the filter vessel of FIG. 1. FIG. 3 is a cross-sectional view of the upper body of FIG. 4 is a cross-sectional view of the lower body of FIG. 1. FIG. 5 is a cross-sectional view of the filter container of FIG. 1 taken along the line II ′, and a cross-sectional view of the filter container in a coupled state taken along the first direction X. FIG. FIG. 6 is a cross-sectional view of the filter container of FIG. 1 taken along the line II-II ′, and a cross-sectional view of the filter container in a coupled state taken along the second direction Y;

1 to 6, the filter container 10 according to the present exemplary embodiment may include an upper body 100, a lower body 200, a filter member 300, and a smear membrane member 400. The upper body 100 may be a sample injection container, and the lower body 200 may be a sample drain container.

First, the upper body 100 will be described. The upper body 100 may be a container member having a first inner space S1 through which a fluid may be received or flow therein. The first internal space S1 of the upper body 100 may be a sample injection space or a sample receiving space.

The upper body 100 may include an upper cylindrical side wall portion 110 and a filter member support portion 130 protruding from the upper body side wall portion 110.

Both the upper end and the lower end of the upper body side wall portion 110 of the upper body 100 may be in an open state. A patient's sample, such as a sputum in solution, may be injected through the opening at the upper end of the upper body sidewall part 110. In addition, the opening of the lower end of the upper body side wall portion 110 may be configured to be in fluid communication with the lower body 200 to be described later. For example, the upper body 100 may be configured to be detachably coupled with the lower body 200.

The filter member supporter 130 of the upper body 100 may protrude inward from the inner wall of the upper body sidewall part 110. For example, the filter member supporter 130 may protrude inward from the lower end of the upper body sidewall part 110. In the plan view, the filter member supporter 130 may have an annular shape with an open center. The annular filter member supporter 130 protruding inwardly from the inner sidewall of the upper body sidewall part 110 may provide a space capable of stably supporting the filter member 300 to be described later. The filter member support 130 and the upper body sidewall 110 may be integrally formed without physical boundaries.

In an exemplary embodiment, the upper body side wall portion 110 forming the first internal space S1 may be partially inclined. For example, the inner wall of the upper body side wall portion 110 may form a slope in part. For more detailed example, the upper body side wall portion 110 is connected to the vertical side wall portion 111 (eg, the first side wall portion) and the vertical side wall portion 111 having an approximately vertical inner wall and inclined inner wall. And an inclined sidewall portion 113 (eg, a second sidewall portion). The inner diameter of the first internal space S1 formed by the inclined side wall portion 113 may gradually decrease in the flow direction of the sample, that is, from the upper side to the lower side. That is, the inner diameter D _{100, min} of the lower end of the upper body 100 may be smaller than the inner diameter D _{100, max} of the upper end of the upper body 100. The inner diameter D _{100, max} of the upper end of the upper body 100 is the maximum inner diameter of the upper body 100, and the inner diameter D _{100, min} of the lower end of the upper body 100 is of the upper body 100. It can form a minimum inner diameter.

FIG. 2 and the like illustrate a case in which the vertical side wall portion 111 is completely perpendicular to the plane in which the first direction X and the second direction Y belong, but in another embodiment, the vertical side wall portion 111 is also defined. It can also form a slope of. That is, the vertical sidewall portion 111 and the inclined sidewall portion 113 may be distinguished in that they form inclined surfaces having different inclinations. In other words, the vertical side wall portion 111 and the inclined side wall portion 113 are formed such that the inner wall of the upper body side wall portion 110 of the upper body 100 forms inclined surfaces of partially different technologies along the path of fluid movement. Can be configured. The vertical sidewall 111 and the inclined sidewall 113 may be integrally formed without physical boundaries.

As a non-limiting example, the upper body 100 may include a vertical side wall portion 111, an inclined side wall portion 113, and a filter member support 130 that are sequentially connected.

Next, the lower body 200 will be described. The lower body 200 may be a container member having a second internal space S2 through which fluid may flow or drain. The second internal space S2 of the lower body 200 may be a sample drainage space.

The lower body 200 may include a substantially cylindrical lower body sidewall portion 210 and a ceiling portion 230 disposed at an upper end of the lower body sidewall portion 210.

The lower end of the lower body sidewall portion 210 of the lower body 200 may be in an open state. The sample may be drained through the opening at the lower end of the lower body side wall portion 210. That is, the sample injected through the opening at the upper end of the upper body side wall portion 110 may be drained through the opening at the lower end of the lower body side wall portion 210.

The ceiling portion 230 of the lower body 200 may be disposed at an upper end of the lower body side wall portion 210. The lower body sidewall part 210 and the ceiling part 230 may together form a second internal space S2. The ceiling portion 230 and the lower body sidewall portion 210 may be integrally formed without physical boundaries.

The ceiling portion 230 of the lower body 200 may have a plurality of drainage holes 230h. The first inner space S1 of the upper body 100 and the second inner space S2 of the lower body 200 are in fluid communication with each other through a drainage hole 230h formed in the ceiling portion 230 of the lower body 200. Can be. That is, the sample may flow from the first internal space S1 to the second internal space S2 through the drainage hole 230h.

The upper body 100 and the lower body 200 of the filter container 10 described above may be configured to be detachable from each other. In an exemplary embodiment, the upper body 100 may further include a fixed sidewall portion 150 protruding downward from the upper body sidewall portion 110. The fixed sidewall portion 150 may be substantially cylindrical in shape. The fixed sidewall part 150 may be integrally formed with the upper body sidewall part 110 without a physical boundary.

The lower body 200 may be inserted at least partially into the third internal space S3 formed by the fixed sidewall part 150 of the upper body 100. That is, the lower body sidewall portion 210 and the ceiling portion 230 of the lower body 200 may be at least partially surrounded by the fixed sidewall portion 150 of the upper body 100. An outer diameter of the lower body sidewall portion 210 of the lower body 200 may be smaller than an inner diameter of the fixed sidewall portion 150 of the upper body 100. The fixed side wall part 150 may provide a third internal space S3 into which the lower body 200 is inserted. The fixed side wall part 150 may be configured to be fitted into the lower body side wall part 210 of the lower body 200.

In some embodiments, the inner wall of the fixed side wall portion 150 of the upper body 100 has a partially recessed groove 150a and the lower body 200 protrudes from the outer wall of the lower body side wall portion 210. It may have a locking portion (210a). Two or more grooves 150a of the fixed side wall part 150 may be provided, and two or more recesses 210a of the lower body 200 may be provided. Each locking portion 210a may be configured to be inserted into and fixed in the corresponding groove portion 150a. The locking portion 210a and the groove 150a may prevent the upper body 100 and the lower body 200 from slip-rotating with each other.

As described above, the sample injected into the first internal space S1 through the opening of the upper end of the upper body 100 of the filter container 10 may be the filter member 300, the smear membrane member 400, and the lower portion which will be described later. It may be drained through the opening of the lower end of the lower body 200 through the second inner space (S2) of the body 200. In particular, the upper body 100 of the filter container 10 according to the present embodiment includes an inclined side wall portion 113, the inner diameter of the upper body 100 may be smaller as the sample flow direction, that is, from the upper side to the lower side have. In this case, before the sample is in contact with and permeable to the filter member 300, the upper body sidewall portion 110 of the upper body 100 forming a space through which the fluid can flow (that is, the first internal space S1). By including the inclined side wall portion 113, it is possible to minimize the area of the lower opening of the upper body 100 in fluid communication with the lower body 200, through which the filter member ( 300). For example, a viscous sample such as human sputum may adhere to the inner wall of the upper body 100 of the filter container 10 to make it difficult to filter the sample or even cause the loss of the sample. This problem may be further exacerbated when filtering and smearing are performed by an automated device such as an automatic smearing device. However, the sample injected through the upper opening of the upper body 100 of the filter container 10 according to the present embodiment may pass through the filter member 300 and be drained toward the lower body 200 without substantial loss. In addition, there is an effect that can further improve the accuracy of the test results by minimizing the samples lost in the smear test process.

To this end, the minimum inner diameter (D _{100, min} ) formed by the upper body side wall portion 110 of the upper body ₁₀₀ is to the inner diameter (D ₂₀₀ ) formed by the lower body side wall portion 210 of the lower body ₂₀₀ . Can be smaller than. Furthermore, the inner diameter D ₂₀₀ of the lower body side wall portion 210 of the lower body 200, which provides a path through which the sample is drained after passing through the filter member 300, is relatively large to induce smooth drainage of the sample. The sample may be prevented from flowing back from the second internal space S2 of the lower body 200 to the first internal space S1 of the upper body 100.

In some embodiments, the upper body 100 has a first protrusion 170 protruding outward from the outer wall of the upper body sidewall portion 110 and / or a second protrusion protruding outward from the outer wall of the fixed sidewall portion 150. 190, the lower body 200 may further include a third protrusion 250 protruding outward from an outer wall of the lower body sidewall part 210. The first protrusion 170, the second protrusion 190, and the third protrusion 250 may be configured to facilitate the detachment and separation of the upper body 100 and the lower body 200. For example, when the sample is filtered and the filtered sample is smeared on the slide glass by using the automatic smearing device, the automatic smearing device may include the first protrusion 170 of the upper body 100 and the lower body 200. 3 The upper body 100 and the lower body 200 is clamped by clamping the protrusion 250 or by clamping the second protrusion 190 of the upper body 100 and the third protrusion 250 of the lower body 200. Can be separated.

Next, the filter member 300 and the smear membrane member 400 will be described.

The filter member 300 may be inserted into the upper body 100. Specifically, the filter member 300 may be disposed on the filter member support 130 that protrudes inward from the upper body sidewall portion 110 of the upper body 100. The filter member 300 may be disposed on a fluid path from the first inner space S1 of the upper body 100 to the second inner space S2 of the lower body 200. The filter member 300 may be coupled through the filter member support 130 of the upper body 100 and an adhesive layer (not shown).

The filter member 300 may first filter a foreign substance or impurities contained in a sample, for example, human sputum, to permeate only cells such as pathogens included in the sample. That is, the filter member 300 may allow foreign substances or impurities that do not penetrate the filter member 300 to be accommodated in the first internal space S1 of the upper body 100 as they are. The mesh size of the filter member 300 may be appropriately selected in consideration of the size of the cells to be examined.

The smear membrane member 400 may be disposed on the ceiling 230 of the lower body 200. In addition, the smear membrane member 400 may be disposed at least partially overlapping the drainage hole 230h of the ceiling 230. In addition, in a state where the upper body 100, the lower body 200, the filter member 300, and the smear membrane member 400 are coupled, the smear membrane member 400 is the filter member 300 and the lower body 200. It may be disposed between the ceiling portion 230 of the.

The smear membrane member 400 may be configured to take a sample for smearing the slide glass at least partially absorbed or adsorbed by the sample filtered by the filter member 300. That is, at least a portion of the filtered sample after passing through the filter member 300 is absorbed or adsorbed to the smear membrane member 400, and at least a portion of the sample after passing through the filter member 300 is applied to the smear membrane member 400. And it may pass through the drain hole (230h) can be drained through the second internal space (S2). The smear membrane member 400 is not particularly limited as long as it can absorb or adsorb and receive a sample, and can have a predetermined elasticity to facilitate smearing on the slide glass, but may include, for example, a sponge material or the like.

Hereinafter, a method of smearing using a filter container according to an embodiment of the present invention will be described in detail with reference to FIGS. 7 to 10. 7 to 10 are views showing a method of smearing using the filter vessel of FIG.

First, referring to FIG. 7, the sample 20 in a solution state is injected into the first internal space S1 of the upper body 100 of the filter container 10, and the sample is opened from the opening at the lower end of the lower body 200. Drain (20). Through this, the sample 20 may flow from the first internal space S1 of the upper body 100 to the second internal space S2 of the lower body 200. Foreign substances or impurities in the sample 20 do not penetrate the filter member 300 and remain in the first internal space S1, and cells such as pathogens may penetrate the filter member 300 to the smear membrane member 401. It may be adsorbed or absorbed. That is, the smear membrane member 401 illustrated in FIG. 7 or the like may be in a state including cells or the like seated on or inside the surface. In addition, at least a part of the drained sample is discharged through the discharge hole formed in the smear membrane member 401 and the ceiling portion 230 of the lower body 200 to be introduced into the second internal space S2 and the second internal space S2. Can be drained from).

As described above, the upper body sidewall part 110 forming the first internal space S1 in the process of flowing the drained sample 20 into the second internal space S2 from the first internal space S1. By partially inclined, the loss of the sample 20 can be minimized.

Next, referring to FIGS. 7 and 8, the upper body 100 and the lower body 200 are separated, and the slide glass 30 is inserted between the upper body 100 and the lower body 200. In a state where the upper body 100 and the lower body 200 are separated, the filter member 300 is supported and coupled by a filter member supporter (not shown) of the upper body 100, and the smear membrane member 401 ) May be supported and coupled by the ceiling part 230 of the lower body 200.

Next, referring to FIGS. 7 to 9, the slide glass 30 and the smear membrane member 401 are brought into contact with each other. This step may be performed by lowering the slide glass 30 or raising the smear membrane member 401 and the lower body 200.

Next, referring to FIGS. 7 to 10, the slide glass 30 and the smear membrane member 401 are spaced apart from each other. This step may be performed by raising the slide glass 30 or by lowering the smear membrane member 401 and the lower body 200. On the back surface of the slide glass 30 in contact with the smear membrane member 401, a sample 40, for example, a pathogen-containing sample taken from a specimen may be transferred and smeared.

10: filter container
100: upper body
200: lower body
300: filter member
400: smear membrane member

Claims (1)

An upper body having a first interior space;
A lower body detachably coupled to the upper body and having a second inner space configured to be in fluid communication with the first inner space;
A filter member disposed on the fluid path from the first inner space to the second inner space; And
A smear membrane member disposed on the fluid path from the first internal space to the second internal space,
An upper body sidewall portion of the upper body at least partially inclined.

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