JP6943459B2 - Filter device and slide glass specimen preparation method - Google Patents

Description

The present invention relates to a filter device and a method for preparing a slide glass specimen.

A filter member in which a filter is sandwiched and held by a first filter holding member and a second filter holding member is disclosed (see Patent Document 1).

Further, the cell capture filter is fixed by the first protrusion of the lid member of the cell capture device and the second protrusion of the storage member, and the first fitting portion and the second fitting portion are fitted. Thereby, the structure in which the cell capture filter is fixed between the lid member and the storage member in a state where the filter region of the cell capture filter is surrounded by the annular first protrusion and the second protrusion is disclosed. (See Patent Document 2).

Further, a method for preparing a fixed sample by combining automatic operation and manual operation is disclosed (see Patent Document 3). This document describes collecting cells on a filter to prepare a cytodiagnosis preparation.

Japanese Patent No. 6165574 International Application Publication No. 2015/147086 Japanese Unexamined Patent Publication No. 2002-122523

In the conventional example described in Patent Document 1 described above, installation and removal of the filter member on the apparatus are described, but the filter is removed from the first filter holding member and the second filter holding member, and the filter member is captured by the filter. No consideration was given to the transfer of cells to glass slides.

In the conventional example described in Patent Document 2 described above, after the cell capture operation, the cell capture device is placed on the stage of a microscope as it is without being decomposed and the presence or absence of cells is observed, and the cells captured by the filter are observed. No consideration was given to the transfer of the cells to the slide glass. Further, in this conventional example, it is considered that the cell capture device has a complicated structure.

Further, in the conventional example described in Patent Document 3 described above, there is no particular description about a method of collecting cells with a filter, then removing the filter from the device, and preparing a preparation from the filter.

An object of the present invention is to simplify the filter device and make the filter removable from the container without touching the filter.

The filter device according to the first aspect is provided with a filter for capturing the target cells from a liquid containing the target cells and a drainage side flow path through which the liquid flows, and is upstream of the drainage side flow path. The filter is detachably fitted into the opening of the container, and the liquid containing the target cells is configured to be bound to the container to close the opening and to hold the filter between the container. It has a lid member provided with a liquid supply side flow path for flowing toward the filter, and presses the filter from the opposite side of the opening outside the liquid drainage side flow path in the container. It is configured to be removable from the opening.

In this filter device, the filter is fitted into the opening on the upstream side of the drainage side flow path in the container, the opening is closed by the lid member, and the filter is sandwiched between the filter and the container. Therefore, the configuration of the filter device is simple.

Further, in this filter device, the liquid containing the target cells is injected into the liquid supply side flow path of the lid member. When the liquid containing the target cells passes through the filter, the target cells are captured and separated from the liquid. The liquid that has passed through the filter can be discharged to the outside through the drainage side flow path of the container.

By removing the lid member from the container and pressing the filter from the opposite side of the opening outside the drainage side flow path, the filter can be removed from the container without touching the filter.

The second aspect is that in the filter device according to the first aspect, the opening is provided with three or more hooks protruding inward from the outer edge of the filter, and the filter is provided with the opening. It is fitted to the back side of the hooked portion of the portion.

In this filter device, the opening is provided with three or more hooks protruding inward from the outer edge of the filter, and the filter is fitted to the back side of the hook in the opening. When the target cell is separated from the liquid and then the lid member is removed from the container, even if the filter adheres to the lid member, the filter is caught by the hooking portion, disengages from the lid member, and stays on the container side. Therefore, it is possible to prevent the filter from coming off the container when the lid member is removed.

On the other hand, when the filter is pressed from the opposite side of the opening outside the drainage side flow path in the container, the filter can be removed from the container by getting over the hooking portion.

In the third aspect, in the filter device according to the first aspect or the second aspect, the outer shape of the filter is formed into a polygonal shape.

In this filter device, since the outer shape of the filter is formed into a polygon, the hooking area between the filter and the hooking portion becomes local. Therefore, when the filter is pressed from the opposite side of the opening, the filter can get over the hooking portion relatively easily. The same applies when a filter is attached to the container.

A fourth aspect is the filter device according to any one of the first to third aspects, in which a plurality of container-side fitting claws are separated in the circumferential direction on the radial outer side of the opening in the container. The lid member is provided with a plurality of lids that can be fitted and released from the container-side fitting claw by rotating the lid member forward and backward around the opening with respect to the container. The member-side fitting claws are provided apart from each other in the circumferential direction, and the lid member is coupled to the container by fitting the container-side fitting claw and the lid member-side fitting claw.

In this filter device, by rotating the lid member in the normal direction around the opening with respect to the container, the lid member side fitting claw and the container side fitting claw are fitted, and the lid member is coupled to the container. Further, by reversing the lid member around the opening with respect to the container, the fitting between the lid member side fitting claw and the container side fitting claw is released, and the lid member can be removed. With such a simple operation, the lid member and the container can be connected and the lid member can be removed.

A fifth aspect is the filter device according to the fourth aspect, in which the lid member side fitting claw is placed on the radial outer side of the opening in the container when the lid member is reversed with respect to the container. There is provided an inclined surface that slides with the lid member and guides the lid member in a direction away from the container.

In this filter device, when the lid member is reversed with respect to the container, the lid member-side fitting claw slides on the inclined surface of the container, and the lid member is guided in a direction away from the container. Since the lid member is separated from the container without pulling the lid member in the direction away from the container, the lid member can be easily removed.

The slide glass sample preparation method according to the sixth aspect is provided with a filter for capturing the target cells and a drainage side flow path through which the liquid containing the target cells is flowed, and is upstream of the drainage side flow path. The filter is detachably fitted into the opening of the container, and the liquid containing the target cells is configured to be bound to the container to close the opening and to hold the filter between the container. It has a lid member provided with a liquid supply side flow path for flowing toward the filter, and presses the filter from the opposite side of the opening outside the liquid drainage side flow path in the container. Using a filter device configured to be removable from the opening, the first step of injecting the liquid into the liquid supply side flow path of the filter device and capturing the target cells by the filter, and the filter device. The filter is removed from the container to expose the filter, and a slide glass is applied to the peripheral edge of the opening, and a removal jig is used to remove the filter from the outside of the drainage side flow path in the container. Is pressed from the opposite side of the opening to be removed from the opening, the filter is brought into close contact with the slide glass, and the target cells are adhered to and transferred to the slide glass in the third step and the filter from the slide glass. It has a fourth step of peeling.

In this slide glass specimen preparation method, in the first step, the target cells are captured and separated from the liquid containing the target cells by a filter. Next, in the second step, the lid member is removed from the filter device to expose the filter. Next, in the third step, a slide glass is applied to the peripheral edge of the opening of the container, and the filter is pressed from the opposite side of the opening outside the drainage side flow path in the container using a removal jig to open the filter. Remove it from the part and attach it to the slide glass. At this time, since the liquid remains in the filter, the cell-capturing side surface of the filter removed from the container adheres to the slide glass due to the surface tension of the liquid. Therefore, the filter can be efficiently brought into close contact with the slide glass without touching the filter.

Further, since the cell capture side surface of the filter is in close contact with the slide glass, the target cells captured by the filter are adhered to and transferred to the slide glass. Then, in the fourth step, the filter is peeled off from the slide glass. In this way, a slide glass specimen can be obtained.

According to the present invention, the filter device can be simplified and the filter can be removed from the container without touching the filter.

It is an exploded perspective view which shows the filter apparatus. It is an exploded perspective view which shows the filter apparatus from the direction different from FIG. It is a perspective view which shows the lid member. It is a side view which shows the container. It is sectional drawing which shows the filter apparatus. It is a top view which shows an example of the hooking part of a container, and the filter fitted in the container. It is a top view which shows the hooking part of a container, and another example of a filter fitted in a container. It is a perspective view which shows the filter apparatus. It is a perspective view which shows the state which the lid member was rotated in the filter device. It is a perspective view which shows a container and a removal jig. It is a perspective view which shows the state which put the container on the removal jig, and put the slide glass on the peripheral edge of an opening. FIG. 11 is a cross-sectional view taken along the line XII-XII in FIG. FIG. 11 is a perspective view showing a state in which the container is pushed down together with the slide glass. FIG. 13 is a cross-sectional view taken along the line XIV-XIV in FIG. FIG. 3 is a perspective view showing a state in which the slide glass to which the filter is in close contact is removed from the state of FIG.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

[Filter device]
In FIGS. 1 and 2, the filter device 10 according to the present embodiment includes a filter 12, a container 14, and a lid member 16.

The filter 12 is a member for capturing target cells from a liquid containing target cells (not shown), and has a porous region 18 formed on an ultrathin plate. The outer shape of the filter 12 is formed in a polygonal shape, for example, but it may be a shape that can be attached to the container 14, and has various shapes such as a hexagon (FIGS. 1, 2, and 6) and a circle (FIG. 7). It is possible to In the porous region 18, a large number of holes 20 are uniformly or regularly formed by an arrangement such as a lattice arrangement or a staggered arrangement. Further, the pore diameter of the pore 20 is set to a size that does not allow passage of target cells and allows non-target cells such as blood components such as blood cells to pass through body fluid cells other than target cells. The type of the filter 12 can be classified into a plurality of types according to the material and the cross-sectional shape, and examples thereof include a 3D metal filter, a 2D metal filter, a 2D resin filter, and a 3D resin filter (none of which are shown).

The container 14 is provided with a drainage side flow path 24 (FIGS. 1, 2 and 5) through which a liquid flows, and a filter is provided in an opening 22 (FIGS. 1 and 2) on the upstream side of the drainage side flow path 24. 12 is a member to be detachably fitted (FIGS. 5 to 7). The container 14 has a bottom wall portion 14E that is substantially rectangular in a plan view, and side wall portions 14A to 14D are erected above the four sides of the bottom wall portion 14E, respectively. As shown in FIGS. 1 and 2, the side wall portions 14A to 14D are connected in an annular shape, and the height of the upper end with respect to the bottom wall portion 14E is, for example, constant.

An outer cylindrical portion 14F is erected above the bottom wall portion 14E, for example, in the central portion. The opening 22 of the container 14 is formed at the upper end of the outer cylindrical portion 14F. The height of the upper end of the outer cylindrical portion 14F with respect to the bottom wall portion 14E is set higher than the height of the upper end of the side wall portions 14A to 14D. The central portion of the side wall portion 14A and the outer cylindrical portion 14F are connected by a rib 14G. Inside the outer cylindrical portion 14F, the inner cylindrical portion 14H is erected concentrically with the outer cylindrical portion 14F and above the outer cylindrical portion 14F. The height position of the upper end of the inner cylindrical portion 14H with respect to the bottom wall portion 14E is set lower than the height position of the upper end of the outer cylindrical portion 14F.

An annular groove 14J to which the O-ring 34 is attached is formed at the upper end of the inner cylindrical portion 14H in the opening 22. The inside of the inner cylindrical portion 14H and the bottom wall portion 14E form a drainage side chamber 44 that forms a part of the drainage side flow path 24. As shown in FIG. 5, the drainage side flow path 24 passes through the inside of the rib 14G from the drainage side chamber 44 and opens to the side wall portion 14A.

The opening 22 is provided with three or more hooks 28 that project inward from the outer edge of the filter 12. The filter 12 is fitted to the back side of the hooking portion 28 in the opening 22. In the example shown in FIG. 6, the hooking portions 28 are formed at, for example, three locations, and are formed in an arc shape along the inner peripheral surface of the outer cylindrical portion 14F. The hooking portion 28 corresponds to the case where the filter 12 has a hexagonal shape, and regardless of the orientation in which the filter 12 is mounted, the corner portions of the filter 12 enter the lower side of the three hooking portions 28, respectively. Is set to.

Further, in the example shown in FIG. 7, the hooking portion 28 is locally formed at three locations on the inner peripheral surface of the outer cylindrical portion 14F. The hooking portion 28 corresponds to a case where the filter 12 has a circular shape with no directionality, and the filter 12 is set so as to enter the lower side of each of the three hooking portions 28.

A plurality of container-side fitting claws 54 are provided on the outer side of the opening 22 in the container 14 in the radial direction so as to be spaced apart from each other in the circumferential direction. In the illustrated example, for example, four container-side fitting claws 54 are evenly provided. The container-side fitting claw 54 is provided, for example, so as to project radially outward from the upper end of the outer cylindrical portion 14F.

As shown in FIGS. 1, 2, and 4, on the radial outer side of the opening 22 in the container 14, when the lid member 16 is reversed with respect to the container 14, the lid member side fitting claw 56 (described later). ), And the inclined surface 14S that guides the lid member 16 in the direction away from the container 14 is provided. The inclined surfaces 14S are provided between the container-side fitting claws 54 adjacent to each other in the circumferential direction, that is, at four locations. The inclined surface 14S may be provided at one position, but it is desirable that the inclined surface 14S is provided at two or more positions.

As shown in FIG. 5, a jig insertion hole 14K that opens into the bottom wall portion 14E of the container 14 is formed between the outer cylindrical portion 14F and the inner cylindrical portion 14H. The jig insertion hole 14K penetrates from the opening 22 of the container 14 to the bottom wall portion 14E. Further, the jig insertion holes 14K are each formed in an arc shape corresponding to the position of the hooking portion 28 (not shown).

Outside the drainage side flow path 24 in the container 14, the filter 12 is inserted into the jig insertion hole 14K from the bottom wall portion 14E side by inserting the blade 30A (FIG. 10) of the removal jig 30 described later into the jig insertion hole 14K. It is configured to be removable from the opening 22 by pressing from the opposite side (bottom wall portion 14E side) (FIGS. 12 and 14). In FIG. 10, the removal jig 30 is configured by erection of three blades 30A and four guide pillars 30C on a rectangular base portion 30B. The blades 30A are formed in an arc shape in a plan view corresponding to the jig insertion hole 14K of the container 14. The guide pillars 30C are provided at the four corners of the base portion 30B, and are formed in an L shape in a plan view. The inner dimensions W30 and L30 of the guide pillar 30C correspond to the width W14 and the length L14 of the container 14.

In FIGS. 1 to 3, the lid member 16 is configured to be coupled to the container 14 to close the opening 22 and to hold the filter 12 between the lid member 16 and the container 14. The lid member 16 is provided with a liquid supply side flow path 26 through which a liquid containing target cells is flowed toward the filter 12. At least a part of the lid member 16 may be made of a transparent material so that the state of the liquid supply side flow path 26 can be observed from the outside. The entire lid member 16 may be made of a transparent material. Further, at least a part or all of the container 14 may be made of a transparent material so that the drainage side flow path 24 can be observed from the outside.

The lid member 16 has a substantially rectangular upper wall portion 16E in a plan view, and side wall portions 16A to 16D are erected downward from the four sides of the upper wall portion 16E, respectively. The side wall portions 16A to 16D are connected in an annular shape, and the height of the lower end with respect to the upper wall portion 16E is, for example, constant.

An outer cylindrical portion 16F is erected below the upper wall portion 16E, for example, in the central portion. The lower end of the outer cylindrical portion 16F is open. The height position of the lower end of the outer cylindrical portion 16F with respect to the upper wall portion 16E is set to be the same as the height position of the lower end of the side wall portions 16A to 16D. The central portion of the side wall portion 16C and the outer cylindrical portion 16F are connected by a rib 16G. Inside the outer cylindrical portion 16F, the inner cylindrical portion 16H is erected downward concentrically with the outer cylindrical portion 16F. The height of the lower end of the inner cylindrical portion 16H with respect to the upper wall portion 16E is set to be equal to the height of the lower end of the outer cylindrical portion 16F.

An annular groove 16J to which the O-ring 36 (FIGS. 1 and 2) is attached is formed at the lower end of the inner cylindrical portion 16H. The inside of the inner cylindrical portion 16H and the upper wall portion 16E form a liquid supply side chamber 46 that forms a part of the liquid supply side flow path 26. As shown in FIG. 5, the liquid supply side flow path 26 opens to the side wall portion 16C, passes through the inside of the rib 16G, and leads to the liquid supply side chamber 46.

The lid member 16 has a plurality of lid member-side fitting claws that can be fitted and released from the container-side fitting claw 54 by rotating the lid member 16 forward and backward around the opening 22 with respect to the container 14. 56 are provided apart in the circumferential direction. Specifically, as shown in FIG. 5, for example, four lid member-side fitting claws 56 are formed so as to project radially inward from the lower end of the outer cylindrical portion 16F. The forward / reverse angle of the lid member 16 for fitting and disengaging the container-side fitting claw 54 and the lid member-side fitting claw 56 is, for example, 45 °. This angle can be changed as appropriate.

The lid member 16 is coupled to the container 14 by fitting the container-side fitting claw 54 and the lid member-side fitting claw 56. As a mark when the lid member 16 is manually attached to and detached from the container 14, the side wall portion 16A of the lid member 16 and the side wall portion 14A of the container 14 are provided with markings 16M and 14M for alignment (FIG. 6). 9). Further, as shown in FIGS. 1 and 2, an arrow 16Y indicating the rotation direction of the lid member 16 when the lid member 16 is removed is displayed on the outer surface of the upper wall portion 16E of the lid member 16.

In the illustrated example, the container 14 is arranged on the lower side and the lid member 16 is arranged on the upper side. Therefore, the container 14 can be referred to as a lower container, and the lid member 16 can be referred to as an upper container.

(Action)
This embodiment is configured as described above, and its operation will be described below. In FIGS. 1, 2, and 5, in the filter device 10 according to the present embodiment, the filter 12 is fitted into the opening 22 on the upstream side of the drainage side flow path 24 in the container 14, and the opening 22 is fitted by the lid member 16. The filter 12 is sandwiched between the container 14 and the container 14. Specifically, the filter 12 is watertightly sandwiched by the O-rings 34 and 36. Therefore, the configuration of the filter device 10 is simple.

Further, by rotating the lid member 16 in the normal direction around the opening 22 with respect to the container 14 (rotating in the direction opposite to the arrow 16Y), the lid member side fitting claw 56 (FIG. 3) and the container side fitting claw 54 Fits and the lid member 16 is coupled to the container 14. Further, by reversing the lid member 16 around the opening 22 with respect to the container 14 (rotating in the direction of the arrow 16Y), the fitting between the lid member side fitting claw 56 and the container side fitting claw 54 is released. The lid member 16 can be removed. With such a simple operation, the lid member 16 and the container 14 can be connected to each other, and the lid member 16 can be removed.

When the lid member 16 is reversed with respect to the container 14, the lid member side fitting claw 56 slides on the inclined surface 14S (FIGS. 1 and 2) of the container 14, and the lid member 16 is moved from the container 14. You will be guided away. Since the lid member 16 is separated from the container 14 without pulling the lid member 16 in the direction away from the container 14, the lid member 16 can be easily removed.

In FIGS. 5 and 8, in the filter device 10, the liquid containing the target cells is injected into the liquid supply side flow path 26 of the lid member 16 (arrow IN direction). When at least a part of the lid member 16 is made of a transparent material, the state of the liquid supply side flow path 26 can be visually observed from the outside. When the liquid containing the target cells passes through the filter 12, the target cells are captured and separated from the liquid. The liquid that has passed through the filter 12 can be discharged to the outside through the drainage side flow path 24 of the container 14 (arrow OUT direction).

9 to 15, the lid member 16 is reversed and removed from the container 14, and the filter 12 is pressed from the opposite side of the opening 22 outside the drainage side flow path 24, so that the filter 12 is not touched. The filter 12 can be removed from the opening 22. Specifically, the lid member 16 is removed from the filter device 10 to expose the filter 12 fitted in the container 14 (FIGS. 9 and 10). The opening 22 is provided with three or more hooking portions 28 protruding inward from the outer edge of the filter 12, and the filter 12 is fitted to the back side of the hooking portion 28 in the opening 22. When the lid member 16 is removed from the container 14 after separating the target cells from the liquid by the filter 12, even if the filter 12 is attached to the lid member 16, the filter 12 is caught by the hooking portion 28 and the lid member It comes off from 16 and stays on the container 14 side. Therefore, it is possible to prevent the filter 12 from coming off the container 14 when the lid member 16 is removed.

The container 14 is removed, set on the jig 30, and the slide glass 32 is applied to the peripheral edge of the opening 22. In the illustrated example, the slide glass 32 is placed on the upper end of the outer cylindrical portion 14F constituting the opening 22 (FIGS. 11 and 12). At this time, the blade 30A of the removal jig 30 is inserted into the jig insertion hole 14K from the bottom wall portion 14E side of the container 14. When the slide glass 32 is pushed downward (in the direction of arrow F), the container 14 is lowered, while the blade 30A of the removal jig 30 hits the peripheral edge of the filter 12 outside the drainage side flow path 24 in the container 14 from below. Since they come into contact with each other, the filter 12 is pressed from the opposite side of the opening 22 and comes off from the container 14. At this time, the filter 12 can be removed from the opening 22 of the container 14 by the peripheral edge of the filter 12 getting over the hooking portion 28.

In the example shown in FIG. 1 and the like, the hooking portions 28 at three locations are formed in an arc shape, and the outer shape of the filter 12 is formed in a polygonal shape (hexagon). Region becomes local. Further, in the example shown in FIG. 7, the outer shape of the filter 12 is circular, but three hooking portions 28 are locally formed. Therefore, when the filter 12 is pressed from the opposite side of the opening 22, the filter 12 can get over the hooking portion 28 relatively easily. This also applies when the filter 12 is attached to the opening 22 of the container 14.

Since the liquid remains in the filter 12, the cell-capturing side surface of the filter 12 removed from the container 14 adheres to the slide glass 32 due to the surface tension of the liquid. At this time, the target cells captured by the filter 12 are adhered to and transferred to the slide glass 32. Since there are three hooking portions 28, for example, the filter 12 comes off from the opening 22 of the container 14 in a state parallel to the slide glass 32 (horizontal state) and adheres to the slide glass 32, so that the target cells are in a uniform state. Is transferred to the slide glass 32.

As described above, according to the present embodiment, the filter device 10 can be simplified and the filter 12 can be removed from the container 14 without touching the filter 12.

[Method for preparing slide glass specimens]
8 to 15, the slide glass specimen preparation method includes first steps S1 to fourth steps S4. This slide glass specimen preparation method can be automatically performed using an apparatus (not shown).

In the first step S1, a filter 12 for capturing the target cells and a drainage side flow path 24 through which the liquid containing the target cells is flowed are provided, and the filter is provided in the opening 22 on the upstream side of the drainage side flow path 24. The container 14 to which the 12 is detachably fitted and the container 14 are coupled to the container 14 to close the opening 22 and the filter 12 can be sandwiched between the container 14, and the liquid containing the target cells is directed toward the filter 12. It has a lid member 16 provided with a liquid supply side flow path 26 to be flowed, and a filter 12 is pressed from the opposite side of the opening 22 to the outside of the drainage side flow path 24 in the container 14. This is a step of injecting a liquid into the liquid supply side flow path 26 of the filter device 10 using the filter device 10 which is configured to be removable from the filter device 10 and capturing the target cells by the filter 12.

The second step S2 is a step of removing the lid member 16 from the filter device 10 to expose the filter 12.

In the third step S3, the slide glass 32 is applied to the peripheral edge of the opening 22, and the filter 12 is pressed from the opposite side of the opening 22 outside the drainage side flow path 24 in the container 14 by using the removal jig 30. This is a step of removing the cells from the opening 22, bringing the filter 12 into close contact with the slide glass 32, and adhering and transferring the target cells to the slide glass 32.

The fourth step S4 is a step of peeling the filter 12 from the slide glass 32.

In this slide glass specimen preparation method, in the first step, the target cells are captured and separated from the liquid containing the target cells by the filter 12. Next, in the second step, the lid member 16 is removed from the filter device 10 to expose the filter 12. Next, in the third step, the slide glass 32 is applied to the peripheral edge of the opening 22 of the container 14, and the filter 12 is set to the opposite side of the opening 22 outside the drainage side flow path 24 in the container 14 by using the removal jig 30. The filter 12 is removed from the opening 22 of the container 14 by pressing from the side, and is brought into close contact with the slide glass 32. At this time, since the liquid remains in the filter 12, the surface of the filter 12 on the cell capture side removed from the container 14 adheres to the slide glass 32 due to the surface tension of the liquid. Therefore, the filter 12 can be efficiently brought into close contact with the slide glass 32 without touching the filter 12.

Further, since the cell capture side surface of the filter 12 is in close contact with the slide glass 32, the target cells captured by the filter 12 are adhered to and transferred to the slide glass 32. Then, in the fourth step, the filter 12 is peeled from the slide glass 32 (in the direction of arrow R). For example, the filter 12 can be naturally peeled off by immersing the slide glass 32 in a container (not shown) in which the storage liquid is stored. In this way, a slide glass specimen can be obtained.

[Other Embodiments]
Although an example of the embodiment of the present invention has been described above, the embodiment of the present invention is not limited to the above, and other than the above, various modifications can be made within a range not deviating from the gist thereof. Of course there is.

The lid member 16 is attached / detached by rotating the lid member 16 forward / reversely around the opening 22 with respect to the container 14, but the attachment / detachment configuration of the lid member 16 is not limited to this, and the dovetail groove is formed. It may be a detachable configuration using a fitting structure using or the like.

Further, the present invention makes it possible to automate a series of operations for removing the filter 12 from the container 14 without touching the filter 12, and is limited to the medical field of recovering the target cells from a liquid containing the target cells. However, even in the industrial field, for example, metal nanoparticles (gold nanoparticles, silver nanoparticles, nickel nanoparticles, magnetic nanoparticles such as iron oxide, etc.), organic nanoparticles (acrylic nanoparticles, styrene nanoparticles, etc.), ceramic nanoparticles, etc. It is useful as a filter device capable of separating the sizes of nanoparticles and automatically collecting the desired particles.

10 Filter device 12 Filter 14 Container 14S Inclined surface 16 Lid member 22 Opening 24 Drainage side flow path 26 Liquid supply side flow path 28 Hooking part 30 Removing jig 54 Container side fitting claw 56 Lid member side fitting claw

Claims (6)

A filter for capturing the target cells from the liquid containing the target cells,
A container in which a drainage side flow path through which the liquid flows is provided, and the filter is detachably fitted into an opening on the upstream side of the drainage side flow path.
A liquid supply side flow path is provided which is bound to the container to close the opening and is configured to be able to hold the filter between the container and the liquid containing the target cells to flow toward the filter. With a lid member,
The container is erected from the bottom wall portion and has an outer cylindrical portion whose upper end constitutes the opening and an inner cylindrical portion which is erected concentrically inside the outer cylindrical portion and forms a part of the drainage side flow path. It has a cylindrical portion and a jig insertion hole formed between the outer cylindrical portion and the inner cylindrical portion and opened in the bottom wall portion.
By inserting the blade of the removal jig into the jig insertion hole from the bottom wall side , the filter is pressed from the opposite side of the opening outside the drainage side flow path in the container to open the opening. A filter device that is configured to be removable from the unit. The opening is provided with three or more hooks protruding inward from the outer edge of the filter.
The filter is fitted on the drain side from the hooking portion in the opening .
The filter device according to claim 1 , wherein the jig insertion holes are formed corresponding to the positions of the hooking portions. The filter device according to claim 1 or 2, wherein the outer shape of the filter is formed into a polygon. A plurality of container-side fitting claws are provided on the outer side of the opening in the container in the radial direction so as to be spaced apart from each other in the circumferential direction.
The lid member has a plurality of lid member-side fitting claws that can be fitted and released from the container-side fitting claw by reversing the lid member forward and backward around the opening with respect to the container. Are provided apart in the circumferential direction,
The filter device according to any one of claims 1 to 3, wherein the lid member is coupled to the container by fitting the container-side fitting claw and the lid member-side fitting claw. On the radial outer side of the opening in the container, when the lid member is reversed with respect to the container, it slides with the fitting claw on the lid member side and guides the lid member in a direction away from the container. The filter device according to claim 4, wherein an inclined surface is provided. A container provided with a filter for capturing target cells and a drainage side flow path through which a liquid containing the target cells flows, and the filter is detachably fitted into an opening on the upstream side of the drainage side flow path. And, the liquid supply side flow path which is bound to the container to close the opening and is configured so that the filter can be sandwiched between the container and the liquid containing the target cells is flowed toward the filter. The container has a lid member provided, and the container is concentrically erected inside the outer cylindrical portion and the outer cylindrical portion whose upper end is erected from the bottom wall portion and has the upper end forming the opening. The container has an inner cylindrical portion that forms a part of the liquid-side flow path, and a jig insertion hole that is formed between the outer cylindrical portion and the inner cylindrical portion and opens to the bottom wall portion. Outside the drainage side flow path, a filter device configured to be removable from the opening by pressing the filter from the opposite side of the opening is used, and the liquid supply side flow path of the filter device is described. In the first step of injecting a liquid and capturing the target cells with the filter,
The second step of removing the lid member from the filter device and exposing the filter,
Applying a slide to the periphery of the opening, by inserting the blade of the removal jig into the jig insertion hole from the bottom wall portion side, outside of the drainage side flow path in said vessel, said filter A third step of pressing from the opposite side of the opening to remove it from the opening, bringing the filter into close contact with the slide glass, and adhering and transferring the target cells to the slide glass.
The fourth step of peeling the filter from the slide glass and
A method for preparing a slide glass specimen having.

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