KR102448250B1 - Biological Tissue Grinding Device - Google Patents

Abstract

The present invention relates to a biological tissue grinding mechanism that enables rapid trituration of biological tissue. Since the blocking part is formed on the grinding rod, the blocking part blocks the upward movement of the biological tissue moved to the space with the buffer by centrifugal force. , biological tissue stays in the space for a long time and has the effect of being rapidly triturated.

Description

Biological Tissue Grinding Device

The present invention relates to a biological tissue grinding device, and more particularly, to a biological tissue grinding device capable of rapidly grinding biological tissue to improve the grinding efficiency of biological tissue.

Molecular biology is a fundamental background in modern biological research, such as biotechnology research, bioinformatics research, and gene expression and regulation research. It is the science that investigates

In order to study such molecular biology, it is necessary to grind the cellular tissue of a biological sample to extract genes, proteins, etc. in the cells. Cells are surrounded by a cell wall or cell membrane, and there are proteins or genetic materials such as cytoplasm and nucleus used for molecular biology research inside the cell wall or cell membrane. it will grind

Looking at an example of the cell trituration process, in the case of a large sample, a tissue lyser or the like can be used to homogeneously grind the tissue of a large amount of sample. However, in the case of on-site diagnosis where a device such as a tissue crusher cannot be used, for example, plant tissue is put in a tube with a buffer containing cell lysate, distilled water, enzyme, etc., and the tube is rotated to grind it. , At this time, the plant tissue is driven upward by the centrifugal force, and there is a problem in that a lot of time and effort must be invested in grinding the plant tissue.

Domestic Registered Patent Publication No. 10-0567348

It is an object of the present invention to solve the problems of the prior art as described above to provide a biological tissue attrition mechanism to improve the attrition efficiency of biological tissues by enabling rapid trituration of biological tissues with a simple structure.

In order to achieve the above object, the biological tissue grinding mechanism according to the present invention is formed with a pillar portion formed in a pillar shape, convexly extending downwardly below the pillar portion, and concavely formed with a plurality of crushing grooves along the inner periphery. The main body having a friction receiving portion to be; and a connection guide part inserted into the pillar part, and an upper end part exposed to the outside through the pillar part, and a receiving space part formed at the lower end part of the connection guide part to be convex downwardly formed along the outer periphery on the inner periphery of the grinding receiving part A plurality of grinding protrusions are formed to protrude to abut, and the outer periphery includes a grinding unit spaced apart from the inner periphery of the grinding receiving part to form a space, and a grinding rod having a slit penetrating through the grinding part, and into the space part. In a state in which the biological tissue and the buffer are supplied, it is characterized in that the biological tissue is crushed by rotating the grinding rod.

In addition, further comprising a blocking portion for blocking between the lower outer periphery of the connection guide portion and the inner periphery of the pillar portion, the blocking portion is formed to protrude in a ring shape so as to contact the inner periphery of the pillar portion below the outer periphery of the connection guide portion It provides a biological tissue grinding mechanism, characterized in that.

In addition, the thickness between the outer diameter and the inner diameter of the friction receiving portion is formed to be thicker than the thickness between the outer diameter and the inner diameter of the pillar portion, a step is formed on the boundary line between the crushing receiving portion and the pillar portion, and the crushing portion is the friction receiving portion It provides a biological tissue grinding mechanism, characterized in that when inserted into the blocking portion is positioned so as to be caught on the step.

In addition, it provides a biological tissue grinding mechanism, characterized in that the grinding receiving portion and the grinding portion is formed so that the diameter gradually narrows toward the bottom.

In addition, the slit is formed in a long shape along the longitudinal direction of the grinding part, and provides a biological tissue grinding mechanism, characterized in that the plurality of slits are positioned so as to be spaced apart from each other on the outer periphery of the grinding part.

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In addition, the grinding protrusion is formed to be convex in a long shape along the longitudinal direction of the grinding part, and the grinding groove part provides a biological tissue grinding mechanism, characterized in that it is formed to be concave in a long shape along the longitudinal direction of the grinding receiving part. do.

In addition, the grinding protrusion provides a biological tissue grinding mechanism, characterized in that formed convexly in the oblique shape inclined at a predetermined angle along the rotational direction of the grinding part.

In addition, the grinding protrusion provides a biological tissue grinding mechanism, characterized in that formed convex spirally along the rotational direction of the grinding portion.

In addition, the upper end of the connection guide provides a biological tissue grinding mechanism, characterized in that one or more fitting grooves are formed so as to be fitted with a rotating mechanism to rotate the grinding rod.

In the present invention, since the blocking part is formed on the grinding rod, the blocking part blocks the upward movement of the biological tissue moved to the space with the buffer by centrifugal force, so that the biological tissue stays in the space for a long time and is rapidly crushed.

In addition, since the slit is formed to be elongated in the longitudinal direction of the grinding part, that is, in the vertical direction, when the grinding part is rotated, there is an effect that the buffer spreading in the vertical direction of the receiving space is quickly moved to the space part through the long slit.

In addition, since the grinding protrusion and the grinding groove are formed long in the longitudinal direction of the grinding part, that is, in the vertical direction, when the buffer moved to the space spreads in the vertical direction in the space, the grinding protrusion and the grinding groove are mixed in the buffer. It has the effect of rapidly grinding the tissue.

1 is a view showing a biological tissue grinding mechanism according to an embodiment of the present invention.
Figure 2 is an exploded view showing an exploded biological tissue grinding mechanism according to an embodiment of the present invention.
Figure 3 is a horizontal cross-sectional view showing a cross-section of the main body of the biological tissue grinding device according to an embodiment of the present invention.
Figure 4 is a vertical cross-sectional view showing the disassembled state of the biological tissue grinding mechanism according to an embodiment of the present invention cut in the vertical direction.
Figure 5 is a vertical cross-sectional view showing a cross-section of the biological tissue grinding mechanism according to an embodiment of the present invention is cut in the vertical direction in a coupled state.
Figure 6 is a horizontal cross-sectional view showing a cross-section by cutting in the horizontal direction the state in which the biological tissue grinding mechanism according to an embodiment of the present invention is combined.

Hereinafter, a biological tissue grinding mechanism according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

Figure 1 is a view showing a biological tissue grinding mechanism according to an embodiment of the present invention, Figure 2 is a view showing an exploded biological tissue grinding mechanism according to an embodiment of the present invention, Figure 3 is an embodiment of the present invention It is a view showing the body of the biological tissue grinding mechanism according to the cross-section.

1 to 3 , the biological tissue grinding mechanism according to an embodiment of the present invention (1000) is for grinding biological tissue, and includes a main body 100 and a grinding rod 200.

The main body 100 includes a pillar portion 110 formed in a pillar shape, a friction receiving portion 120 integrally extending downwardly convexly below the pillar portion 110 , and an open portion of the pillar portion 110 . It may be configured to include a lid 130 for opening and closing the upper portion.

The column part 110 is formed in a long cylindrical shape along the longitudinal direction and has a size that can be gripped by hand. The grinding receiving part 120 is formed so that the grinding part 220 of the grinding rod 200 to be described later can be inserted, and its diameter is gradually narrowed toward the lower part.

A biological tissue to be crushed is accommodated in the crushing receiving unit 120 . And the thickness between the outer diameter and the inner diameter of the friction receiving part 120 is formed to be thicker than the thickness between the outer diameter and the inner diameter of the column part 110, the inner diameter of the grinding receiving part 120 and the inner diameter of the column part 110 A step 124 may be formed on the boundary line. Through this configuration, it is possible to improve the grinding efficiency by increasing the strength of the grinding receiving unit 120. And a plurality of grinding grooves 122 are concavely formed along the inner periphery of the grinding receiving portion 120 . The grinding groove part 122 is concavely formed in a long shape along the longitudinal direction of the grinding receiving part 120 .

The lid 130 is formed in a cap shape and is flexibly connected to the upper portion of the column unit 130 to open or close the upper portion of the column portion 130 . At this time, the outer diameter of the lid 130 is formed so that the lid 130 is tightly fitted to the pillar portion 110 of the body 100, or the inner diameter of the lid 130 is a connection guide portion in which the fitting groove 214 is formed ( The upper rim of the 210 or the upper rim of the column part 110 may be formed to be tightly fitted. Through this configuration, the biological tissue grinding mechanism according to the present invention is stored by closing the lid 130 in a state in which the grinding biological tissue and the buffer are accommodated in the main body 100, or the grinding rod 200 in the main body, and the grinding By closing the lid 130 in a state in which the biological tissue and the buffer are accommodated, the internal contents can be safely stored.

Figure 4 is a vertical cross-sectional view showing the disassembled state of the biological tissue grinding mechanism according to an embodiment of the present invention in a cross-section cut in the vertical direction, Figure 5 is a state in which the biological tissue grinding mechanism according to an embodiment of the present invention is combined It is a vertical cross-section shown as a cross-section by cutting in the vertical direction.

2 to 5 , the grinding rod 200 is inserted into the main body 100 to grind biological tissue, and may be configured to include a connection guide 210 and a grinding part 220 . Here, the grinding rod 200 may be of a tubular shape with a hollow inside. In such a structure, after the grinding is completed, the extraction buffer or juice contained in the inner space of the grinding rod 200 can be easily sampled using a pipette or the like.

The connection guide part 210 is formed in a column shape to be inserted into the column part 110 and is formed in a tubular shape so that a buffer is accommodated therein, and the upper end is extended to be exposed to the outside through the open upper part of the column part 110 . is formed and the lower end is formed to extend downward of the column part 110 . And below the outer periphery of the connection guide 210, the blocking portion 212 is formed to protrude in a ring shape so as to contact the inner periphery of the pillar portion 110, and the blocking portion 212 is connected to the outside of the guide portion 210. Block the space between the lower periphery and the inner periphery of the column part 110, and maximize the grinding effect by separating the outer peripheral surface of the grinding unit 220 and the inner peripheral surface of the grinding receiving unit 120 by a certain distance to maximize the grinding effect and grinding biological tissue This space can be accommodated.

On the other hand, in an embodiment of the present invention, the blocking unit 212 is configured to be formed in the connection guide unit 210 , but this is only an embodiment, and in some cases, the blocking unit 212 is the connection guide unit 210 . In order to block between the lower side of the outer periphery of the column part 110 and the inner periphery of the column part 110 , it may be formed to protrude downward from the outer periphery of the connection guide part 210 on the lower inner periphery of the column part 110 .

And one or more fitting grooves 214 are formed at the upper end of the connection guide 210 to be fitted with a rotating mechanism (not shown) for rotating the connection guide 210 . The rotating mechanism is a conventional one, for example, formed of a drill, a screwdriver, etc. having a rotational force, and a connection guide part inserted into the column part 110 in a state where the tip coupled to the rotating mechanism is fitted into the fitting groove 214 . 210 can be rotated at a high speed. Therefore, the fitting groove 214 is sufficient as long as it has a shape that prevents it from spinning with respect to the rotation of the tip, and the shape is not limited thereto. In addition, the upper portion of the connection guide portion 210 additionally or alternatively to the fitting groove 214 has an outer circumferential surface that is inserted into the rotation tip of the rotation mechanism to receive rotational force by the rotation of the rotation tip so that the grinding rod 200 rotates. It can be angled. Through this configuration, not only when the rotating tip of the rotating mechanism is fitted inside the connection guide 214, but also when the outer circumferential surface of the connection guide 214 is fitted to the rotating tip, using the rotating mechanism, the grinding rod ( 200) can be rotated.

The attrition unit 220 is to triturate the biological tissue accommodated in the attrition receiving unit 120 , and is formed convexly downward so that the receiving space 220a is formed at the lower end of the connection guide 210 . The grinding unit 220 may also be formed to gradually narrow in diameter toward the lower part, like the grinding receiving unit 120 . And when the attrition unit 220 is positioned to be inserted into the attrition receiving unit 120, the outer periphery of the attributing unit 220 is formed to be spaced apart from the inner periphery of the attributing unit 120, and the attrition receiving unit 120 and A gap, that is, a space 230 (shown in FIG. 6 ) may be formed between the grinding units 220 .

The grinding unit 220 has a slit 222 for passing the buffer supplied to the receiving space 220a, or the extraction buffer extracted from the triturated biological tissue is introduced from the grinding receiving unit 120, and the buffer is mixed with it. It may include a grinding protrusion 224 for easily grinding the biological tissue. The slit 222 is formed in a long shape along the longitudinal direction of the grinding unit 220 , and a plurality of slits 222 are formed through the outer periphery of the grinding unit 220 in a hole shape at regular intervals.

The grinding protrusion 224 may be formed in a long shape along the longitudinal direction of the grinding unit 220 so as not to overlap the slit 222 . Here, the plurality of grinding protrusions 224 formed in the vertical direction are formed to protrude convexly in a protrusion shape at a predetermined interval on the outer periphery of the grinding unit 220 . At this time, the grinding protrusion 224 may be formed to protrude in contact with the inner periphery of the grinding receiving part 120 . And when the slit 222 and the grinding protrusion 224 are formed in the grinding unit 220, one or a plurality of grinding units 220 are positioned between a pair of adjacent slits 222, for example, The slit 222 is composed of four, and the grinding protrusion 224 is composed of 12, so that three grinding protrusions 224 may be positioned between a pair of adjacent slits 222 . As such, when the grinding protrusion 224 is formed in the vertical direction, the grinding protrusion 224 is formed in a direction orthogonal to the rotational direction, so that the grinding force can be improved.

In addition, although not shown in the drawings, the grinding protrusion 224 may be formed in plurality in a horizontal direction parallel to the rotation direction of the grinding rod 200 . In this way, when the grinding protrusion 224 is formed in the horizontal direction, the trituration protrusion 224 suppresses the biological tissue from leaving the space 230 in which the grinding occurs, so that the grinding efficiency can be improved.

In addition, although not shown in the drawings, the grinding protrusion 224 may be formed in a diagonal direction inclined at a predetermined angle with respect to the vertical direction. In particular, in the structure in which the upper portion of the friction protrusion 224 is ahead of the lower portion in the rotational direction, the friction force is further increased compared to the case where the friction protrusion 224 is in the horizontal direction, as well as the space portion 230 in which the friction occurs. By suppressing the deviation of the tissue, the grinding efficiency can be improved.

Furthermore, the grinding protrusion 224 may be formed in a spiral structure. In particular, the spiral direction of the grinding protrusion 224 may be formed in a spiral direction in which the grinding rod 200 is unwound from the main body 100 when the grinding rod 200 rotates according to a predetermined rotational direction. In this structure, compared to the case where the grinding protrusion 224 is in the horizontal direction, the grinding force is further increased, as well as suppressing the biological tissue from leaving the space 230 in which the grinding occurs, thereby further improving the grinding efficiency.

Hereinafter, the operation of the biological tissue grinding mechanism according to an embodiment of the present invention will be described.

6 is a view showing a cross-section of a biological tissue grinding mechanism according to an embodiment of the present invention.

1 to 6, the main body 100 and the grinding rod 200 of the biological tissue grinding mechanism according to the present invention are positioned such that the grinding unit 220 is inserted into the grinding receiving unit 120, at this time, The lower side of the blocking part 212 is positioned so as to be caught on the step 124, and the outer periphery side of the blocking part 212 is positioned so as to be in contact with the inner periphery of the column part 110, and the friction receiving part 120 and the grinding The upper portion of the space portion 230 provided between the chain portions 220 is blocked by the blocking portion 212 .

Looking at the process of grinding biological tissue using the biological tissue grinding mechanism according to the present invention, first, biological tissue and a buffer are supplied to the grinding receiving part 120 of the main body 100 and then the grinding rod through the column part 110 . Inserting the 200, and rotating the grinding rod 200 using a rotating mechanism, it is possible to grind the biological tissue. By the rotation of the grinding rod 200, the biological tissue between the outer peripheral surface of the grinding unit 220 and the inner peripheral surface of the grinding receiving unit 120 is triturated, and the buffer is formed by the slit 222 formed in the grinding unit 220. Since it is prevented from ascending along the column part 110 , the biological tissue can continue to stay in the space part 230 , thereby increasing the grinding efficiency. In addition to this, the blocking portion 212 formed in the grinding rod 200 may further inhibit the biological tissue from leaving the space 230, thereby further improving the grinding efficiency.

In addition, when the biological tissue is sufficiently smaller than the slit 222, a method of supplying the biological tissue and the buffer to the receiving space 220a in the state in which the main body 100 and the grinding rod 200 are inserted is also possible. At this time, when the grinding rod 200 is rotated using a rotating mechanism, the buffer supplied to the receiving space 220a by centrifugal force flows into the space 230 through the slit 222, and the grinding protrusion 224. is rotated together with the attrition unit 220 to rapidly triturate the biological tissue located in the space unit 230 . At this time, the biological tissue is crushed finely while continuously colliding along the uneven shape of the grinding protrusion 224 and the grinding groove 122 .

On the other hand, the biological tissue moved to the space 230 by the centrifugal force cannot be moved to the upper part of the blocking part 212 by the blocking part 212, so the biological tissue located in the space 230 is not moved to the blocking part ( 212), while staying in the space 230 for a long time, there is an effect of being rapidly crushed by the grinding protrusion 224 and the grinding groove 122.

The crushed biological tissue stays in the space 230 between the main body 100 and the crushing rod 200, and the extraction buffer extracted from the crushed biological tissue is accommodated in the receiving space 220a within the crushing rod 200. . In this case, the user may sample the extraction buffer using a pipette (not shown) and use it for diagnosis, examination, and research. Here, the biological tissue may be a general animal or plant tissue, but preferably a plant tissue.

In addition, in the biological tissue grinding mechanism according to the present invention, since the slit 222 is formed to be elongated in the longitudinal direction and vertical direction of the grinding unit 220, that is, in the vertical direction, when the grinding unit 220 is rotated, the receiving space portion 220a ) has an effect that the buffer spreading in the vertical direction is quickly moved to the space 230 through the long slit 222 .

In addition, since the grinding protrusion 224 and the grinding groove 122 are elongated in the longitudinal direction of the grinding unit 220 , that is, in the vertical direction, the buffer moved to the space 230 is moved in the space 230 . When spread in the vertical direction, the grinding protrusion 224 and the grinding groove 122 have the effect of rapidly grinding the biological tissue mixed in the buffer.

In addition, the attrition groove 122 secures a space in which the crushed biological tissue is accommodated, thereby minimizing penetration of a part of the crushed biological tissue into the receiving space 220a of the crushing rod through the slit.

1000: biological tissue grinding device
100: body 110: pillar portion
120: grinding receiving portion 122: grinding groove portion
124: step 130: lid
200: grinding rod 210: connection guide
212: blocking portion 214: fitting groove
220: grinding unit 220a: receiving space unit
222: slit 224: grinding protrusion
230: space part

Claims (11)

A main body having a pillar portion formed in the shape of a pillar, a friction receiving portion extending convexly downwardly below the pillar portion, and having a plurality of crushing grooves concavely formed along an inner periphery; and
Doedoe inserted into the pillar, the upper end is formed convexly downward to form a connection guide portion exposed to the outside through the pillar portion, and a receiving space at the lower end of the connection guide portion, and abuts against the inner periphery of the grinding receiving portion along the outer periphery A plurality of grinding protrusions are formed to protrude so that the outer periphery is spaced apart from the inner periphery of the grinding accommodating part to form a space portion, and a grinding rod having a slit penetrating through the grinding part,
In a state in which the biological tissue and the buffer are supplied to the space part, the biological tissue grinding mechanism, characterized in that the grinding rod is rotated to grind the biological tissue.
The method of claim 1,
Further comprising a blocking portion for blocking between the lower outer periphery of the connection guide portion and the inner periphery of the pillar portion,
The blocking part is biological tissue grinding mechanism, characterized in that the ring-shaped protrusion is formed so as to contact the inner periphery of the pillar on the lower side of the outer periphery of the connection guide.
3. The method of claim 2,
The thickness between the outer diameter and the inner diameter of the friction receiving portion is formed to be thicker than the thickness between the outer diameter and the inner diameter of the pillar portion, a step is formed on the boundary line between the crushing receiving portion and the pillar portion,
When the attrition unit is inserted into the attrition receiving unit, the biological tissue attrition mechanism is characterized in that the blocking unit is positioned so as to be caught on the step.
The method of claim 1,
Biological tissue grinding mechanism, characterized in that the grinding receiving portion and the grinding portion is formed such that the diameter gradually narrows toward the bottom.
The method of claim 1,
The slit is formed in a long shape along the longitudinal direction of the grinding part,
A biological tissue grinding mechanism, characterized in that the plurality of slits are positioned to be spaced apart from each other on the outer periphery of the grinding unit.
delete delete The method of claim 1,
The grinding protrusion is formed convexly in a long shape along the longitudinal direction of the grinding part,
The grinding groove portion biological tissue grinding mechanism, characterized in that formed concave in a long shape along the longitudinal direction of the grinding receiving portion.
The method of claim 1,
The grinding protrusion is biological tissue grinding mechanism, characterized in that it is convexly formed in an oblique shape inclined at a predetermined angle along the rotational direction of the grinding unit.
The method of claim 1,
The grinding protrusion is biological tissue grinding mechanism, characterized in that the convex helically along the rotational direction of the grinding unit.
The method of claim 1,
At the upper end of the connection guide, one or more fitting grooves are formed so as to be fitted with a rotating mechanism to rotate the grinding rod.

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