KR102595329B1 - The crushing device of biological tissue - Google Patents

Abstract

The present invention relates to a biological tissue grinding device, and more specifically, to a biological tissue grinding device that finely grinds biological tissue isolated from the human body,
A biological tissue pulverizing device for pulverizing biological tissue into fine pieces, comprising: a lower chamber portion; An upper chamber part fastened to the upper part of the lower chamber part and having a rotating pulverizing part for pulverizing the biological tissue located inside; A cover part fastened to the upper part of the upper chamber part; a rotary grinding unit rotatably installed on the cover and located inside the upper chamber; and a discharge grid located at a connection end of the lower chamber portion and the upper chamber portion, through which fine pieces pulverized through the rotary pulverizer are discharged.

Description

THE CRUSHING DEVICE OF BIOLOGICAL TISSUE}

The present invention relates to a biological tissue grinding device, and more particularly, to a biological tissue grinding device that finely grinds biological tissue separated from the human body.

It is known that biological tissues, such as human or animal tissues, can be applied in various aspects and for various purposes for treatment or therapeutic assistance.

Biological tissue can be ground and used as fine biomaterial to perform medical tests such as biopsies. Biological tissue may also be ground to obtain data and information that can be used for research purposes or for specific medical treatments.

Conventionally, biological tissues have been pulverized for the purpose of separating cells present in the same biological tissue or preparing micrografts to be used in clinical and regenerative treatments. The ground microtissue may be composed of extracellular matrix and a large number of cells.

The substances that make up the surrounding environment of cells often have a variety of compositions and perform complex functions. The functions of the cells that make up tissues change depending on the environment, and various attempts are being made to study the regeneration of tissues and organs by controlling this. This is because the composition, strength, and secreted growth factors of the biomaterials surrounding the cells affect the differentiation of stem cells. For example, it has been reported that when stem cells are cultured on a low-strength surface, they differentiate into adipocytes, and on a high-strength surface, they differentiate into chondrocytes, and that the mechanical environment affects the differentiation of stem cells. Research is actively underway.

Initially, the main function of biomaterials used for tissue regeneration was to biodegrade to provide space for cell proliferation, but recently, they are decomposed by substances secreted by cells to promote tissue formation, releasing growth factors or genes. It is also used to promote cell differentiation, proliferation, and angiogenesis by imparting functions. The basic purpose of regenerative medicine is to regenerate and replace diseased organs, but regenerative medicine and biomaterials are also used in research to overcome diseases.

For the purpose of medical research or treatment, there is a need for a device that can prepare biomaterials formed by finely pulverizing biological tissues.

Registered Patent Publication No. 10-1628304 (registered on June 1, 2016) Registered Patent Publication No. 10-1815035 (registered on December 28, 2017) Public Patent Publication No. 10-2017-0102479 (published on September 11, 2017)

The purpose of the present invention is to provide a biological tissue grinding device that can efficiently crush and decompose biological tissue and use it as a biological material.

In order to achieve the above object, the present invention provides a biological tissue pulverizing device for pulverizing biological tissue into fine pieces, comprising: a lower chamber portion; An upper chamber part fastened to the upper part of the lower chamber part and having a rotating pulverizing part for pulverizing the biological tissue located inside; A cover part fastened to the upper part of the upper chamber part; a rotary grinding unit rotatably installed on the cover and located inside the upper chamber; and a discharge grid located at a connection end of the lower chamber portion and the upper chamber portion, through which fine pieces pulverized through the rotary pulverizer are discharged.

In the present invention, the lower chamber portion includes a cup-shaped lower chamber body; Screw threads formed on the upper inner peripheral surface of the lower chamber body; And a step formed inside the lower end of the screw thread.

In the present invention, the upper chamber part is characterized by consisting of a cylindrical upper chamber body and screw threads formed on the upper and lower outer peripheral surfaces of the upper chamber body.

In the present invention, the cover part includes a cap-shaped cover body, a screw thread formed on the inner circumferential surface so that the cover body can be coupled to the upper chamber body, and an axial hole formed so that the rotation axis of the rotary crusher can be mounted on the cover body. It is characterized by being carried out.

In the present invention, the rotary grinding unit is characterized in that it consists of a rotating shaft that is connected to a rotating drive device and rotates, and a rotating disk fixed to the lower end of the rotating shaft.

In the present invention, the rotation axis is characterized in that a ring-shaped groove is formed at a certain position so that it can be positioned and fixed in the shaft hole of the cover body, and the ring-shaped groove is formed larger than the thickness of the cover body.

In the present invention, the discharge grid is characterized in that grid-shaped fine perforations are formed on the disk.

In the present invention, the discharge grid is characterized in that it is a metal or synthetic resin plate.

In the present invention, the discharge grid is characterized by being composed of a mesh net and a pair of ring members that secure the edges of the mesh net at the top and bottom of the mesh net.

In the present invention, the ring member is characterized in that it is seated on the step of the lower chamber part.

The biological tissue grinding device according to the present invention has the effect of increasing grinding efficiency because it can grind biological tissue while placing it in a chamber.

In addition, the biological tissue grinding device according to the present invention has the advantage of easy handling of the biological material because the upper chamber and the lower chamber are configured to be separable from each other, and the finely ground biological material can be easily separated from the grinding device. have

In addition, the biological tissue grinding device according to the present invention has the advantage of reducing production costs because each component can be separated.

1 is an overall perspective view of a biological tissue grinding device according to the present invention.
Figure 2 is an exploded perspective view of the biological tissue grinding device according to the present invention.
Figure 3 is a cross-sectional view of the cover part and the rotary grinding part of the biological tissue grinding device according to the present invention.
Figure 4 is a cross-sectional perspective view of the upper chamber portion of the biological tissue grinding device according to the present invention.
Figure 5 is an exploded perspective view of the discharge grid of the biological tissue grinding device according to the present invention.
Figure 6 is a perspective view showing a discharge grid mounted on the lower chamber of the biological tissue grinding device according to the present invention.
Figure 7 is a cross-sectional perspective view of the lower chamber portion of the biological tissue grinding device according to the present invention.
Figure 8 is a perspective view showing another embodiment of the discharge grid according to the present invention.
Figure 9 is a perspective view of an embodiment of the rotating disk of the biological tissue grinding device according to the present invention.
Figure 10 is a perspective view of the pulverizing process showing the process of pulverizing biological tissue using the biological tissue pulverizing device according to the present invention.
Figure 11 is a perspective view of the rotation drive unit on which the biological tissue grinding device according to the present invention is mounted.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the purpose is to provide a detailed description so that a person skilled in the art can easily practice the invention. This does not mean that the technical idea and scope of the present invention are limited.

Figure 1 is an overall perspective view of the biological tissue grinding device according to the present invention, Figure 2 is an exploded perspective view of the biological tissue grinding device according to the present invention, and Figure 3 is a cover portion and a rotating grinding portion of the biological tissue grinding device according to the present invention. It is a cross-sectional view, Figure 4 is a cross-sectional perspective view of the upper chamber of the biological tissue grinding device according to the present invention, Figure 5 is an exploded perspective view of the discharge grid of the biological tissue grinding device according to the present invention, and Figure 6 is a biological tissue grinding device according to the present invention. It is a perspective view showing that the discharge grid is mounted on the lower chamber of the pulverizing device, Figure 7 is a cross-sectional perspective view of the lower chamber of the biological tissue pulverizing device according to the present invention, and Figure 8 is another embodiment of the discharge grid according to the present invention. is a perspective view showing, Figure 9 is a perspective view of an embodiment of the rotating disk of the biological tissue grinding device according to the present invention, and Figure 10 is a pulverization showing the process of pulverizing biological tissue using the biological tissue grinding device according to the present invention. It is a perspective view of the process, and Figure 11 is a perspective view of the rotation drive unit on which the biological tissue grinding device according to the present invention is mounted.

The biological tissue grinding device 1 will be described in detail with reference to the drawings. When explaining the biological tissue pulverizing device 1 with reference to FIGS. 1 and 2, the biological tissue pulverizing device 1 includes a lower chamber portion 10 in which the pulverized biological material is contained, and a lower chamber portion ( 10), an upper chamber part 20 connected to the upper part, a cover part 30 fastened to the upper part of the upper chamber part 20, and a rotary grinding part 40 rotatably installed on the cover part 30. It consists of a discharge grid 50 that is seated on the step of the lower chamber part 10 and fixed by the upper chamber part 20.

When explaining the lower chamber portion 10 with reference to FIG. 7, the lower chamber portion 10 includes a cup-shaped lower chamber body 11 and a screw thread 12 formed on the upper inner peripheral surface of the lower chamber body 11. It consists of a step (13) formed inside the lower end of the screw thread (12). An internal space 14 is formed inside the lower chamber body 11 into which biological tissue is pulverized and then placed. A discharge grid 50, which will be described later, is mounted on the step 13.

When explaining the upper chamber portion 20 with reference to FIG. 4, the upper chamber portion 20 includes a cylindrical upper chamber body 21 and threads 22 formed on the upper and lower outer peripheral surfaces of the upper chamber body 21. ). The screw thread 22 is composed of an upper screw thread 22a and a lower screw thread 22b. The cover part 30 is fastened to the upper screw thread 22a, and the lower chamber part 10 is fastened to the lower screw thread 22b. . A ring-shaped protrusion 23 may be further provided at the center of the upper chamber body 21 for fixing the rotary grinder 40 when it rotates. The ring-shaped protrusion 23 is inserted into the ring-shaped groove 103 provided in the rotation drive unit 100, and thus the position of the biological tissue grinding device 1 can be fixed.

When explaining the cover part 30 with reference to FIGS. 2 and 3, the cover part 30 includes a cap-shaped cover body 31 and a cap-shaped cover body 31 so that the cover body 31 can be coupled to the upper chamber body 21. It consists of a screw thread 32 formed on the inner peripheral surface and an axial hole 33 formed so that the rotation axis 41 of the rotary grinding unit 40 can be mounted on the cover body 31. As shown in FIG. 3, the thickness (t) of the cover body 31 of the cover portion 30 is the length (d) of the ring-shaped groove 412 provided on the rotation axis 41 of the rotary crusher 40. It is formed smaller. The reason is that the cover part 30 and the lower chamber part 10 are fastened and fixed to the upper chamber part 20, and the position of the biological tissue grinding device 1 is fixed to the rotary drive unit 100, and the rotary grinding unit is This is to enable the motor to be driven while applying a certain pressure to the rotation shaft 41 of the unit 40. That is, the purpose is to apply a certain force to the rotation axis 41 of the rotary grinding unit 40 so that the cover unit 30 can move back and forth.

As shown in FIG. 3, the rotary grinding unit 40 includes a rotary shaft 41 that is connected to the rotary drive device of the rotary drive unit 100 and rotates, and a rotary disk 42 fixed to the lower end of the rotary shaft 41. It comes true. The rotation shaft 41 includes a rotation shaft body 411, a ring-shaped groove 412 formed in the rotation shaft body 411, a joint portion 413 that is connected to the rotation drive device and transmits rotational force, and a rotation disk 42. It consists of a connecting protrusion 414 formed at the bottom of the rotating shaft body 411 to connect to the.

FIG. 5 shows an exploded perspective view of the discharge grid 50, and FIG. 6 shows the discharge grid 50 being seated in the lower chamber portion 10. As shown in the figure, the discharge grid 50 includes a mesh net 51 and a pair of ring members 52:52a that secure the edges of the mesh net 51 at the top and bottom of the mesh net 51. , 52b). A pair of ring members 52 is a component for fixing the edge of the mesh network 51, and is seated on the step 13 of the lower chamber portion 10, and the upper chamber portion 20 is connected to the lower chamber portion 10. ), it is fixed between the upper chamber part 20 and the lower chamber part 10. Accordingly, the rotating disk 42 of the rotating pulverizing unit 40 can crush the biological tissue 2 placed on the mesh network 51 with rotational force. Therefore, the diameter of the rotating disk 42 must have a smaller diameter than the inner diameter of the upper chamber portion 20. The upper and lower ring members 52 may be fixed using fastening means 53 and 54, or may be fixed using adhesive or the like. Additionally, the upper ring member 52a may be inserted into and fixed to the lower ring member 52b by punching. Figure 8 shows an example of a discharge grid 50' in which grid-shaped fine holes are formed on a disk. The discharge grid 50' consists of a disk-shaped grid body 51' and grid-shaped holes 511' formed in the grid body 51'. The discharge grid 50' may be made of metal or synthetic resin.

Figure 9 shows an embodiment of the rotating disk 42. Figure 9(a) shows that the lower surface of the rotating disk 42 is in the shape of a disk. Figure 9(b) shows that a number of small protrusions 421' are formed on the rotating disk 42' to make it easier to crush the biological tissue 2 while rotating. Figure 9(c) shows a ring-shaped blade 421" formed on the lower surface of the rotating disk 42" to crush biological tissue 2, and Figure 9(d) shows a rotating disk 42"'. ) is formed on the lower surface of the inclined blade (421"') to crush the biological tissue (2). In the case of Figure 9(d), since the inclined blade 421"' is formed, it can provide the effect of applying a certain pressure to the biological tissue 2, and the biological tissue pressed by the inclined blade 421"' is As it passes through the discharge grids 50 and 50', it can be pulverized into fine biomaterials.

Figure 10 shows the process of pulverizing biological tissue using the biological tissue pulverizing device 1 according to the present invention. Figure 10(a) shows the process of first inserting the biological tissue 2 before fastening the cover 30 of the biological tissue grinding device 1. With the cover part 30 removed, the biological tissue 2 is first introduced into the upper chamber part 20. Figure 10(b) shows that when the biological tissue 2 is introduced into the upper chamber 20, the rotating pulverizer 40 coupled to the cover 30 is introduced into the upper chamber 20 and the cover 30 ) shows the process of fastening and fastening. Figure 10(c) shows the cover part 30 fastened to the upper chamber part 20. Once the cover unit 30 and the rotary grinding unit 40 are inserted and fixed into the upper chamber unit 20, the biological tissue grinding device 1 is mounted on the rotary drive unit 100. The rotation drive unit 100 is shown in FIG. 11. Figure 10(d) shows that when the biological tissue grinding device 1 is input to the rotary drive unit 100, the motor mounted on the rotary drive unit 100 is driven to rotate the rotation shaft 41 of the rotary grinder 40 to crush the living tissue. It shows finely pulverizing the tissue (2). Figure 10(e) shows that when the biological tissue 2 is finely pulverized by the rotary grinding unit 40 and introduced into the lower chamber 10, the rotation driving unit 100 stops operating and the lower chamber 10 is moved to the upper chamber. The process of separating from the chamber portion 20 is shown. FIG. 10(f) shows a process of collecting biomaterials, which are fine particles, introduced into the internal space 14 of the lower chamber 10 when the lower chamber 10 is separated from the upper chamber 20. Through this series of processes, the biological tissue 2 is pulverized into fine particles of biomaterial, and the pulverized biomaterial can be reintroduced into the patient's body or used for research purposes.

Figure 11 shows the rotation drive unit 100. The rotation drive unit 100 includes a drive unit main body 101 in which a motor (not shown) is provided inside, a grinding device seating groove 102 in which the biological tissue grinding device 1 is seated so that it can be connected to the motor, and a biological tissue A pulverizing device position fixing groove 103 formed in the pulverizing device seating groove 102 to fix the position of the biological tissue pulverizing device 1, and a driving unit main body 101 to facilitate attachment and detachment of the biological tissue pulverizing device 1. ), a side portion 104 formed by regularly cutting the lower side of the arc-shaped cover seating portion 105 formed before and after the grinding device seating groove 102 for fixing and seating the arc-shaped driving unit cover 110, and , fixing protrusions 105-1 formed on both lower sides of the arc-shaped cover seating portion 105, a rotation shaft insertion hole 106 into which the joint 413 side of the rotation shaft 41 is inserted, and an arc-shaped cover. It consists of an arc-shaped cover 110 that is seated on the seating portion 105. The arc-shaped cover 110 is mounted and its position is fixed by the fixing protrusion 105-1. In a fixed state, the arc-shaped cover 110 applies a certain force to the biological tissue grinding device 1. The rotation shaft 41 is connected to the motor shaft by a joint 413, and transmits the rotational force of the motor to the rotation shaft 41. When the biological tissue grinding device 1 is seated on the rotation drive unit 100, power is applied. When power is applied, a certain force is applied to the motor shaft of the motor, and when a certain force is applied to the motor shaft, a certain force is applied to the motor shaft. The force pushes the rotating shaft 41 toward the discharge grid 50, and accordingly, the rotating disk 42 mounted on the rotating shaft 41 comes into close contact with the biological tissue 2 while applying pressure to the biological tissue 2. As the rotating disk 42 rotates, the biological tissue 2 is introduced into the lower chamber 10 as a fine biological material through a hole in the mesh network or through a lattice hole.

Although several embodiments have been described above as examples, it is obvious to those skilled in the art that the present invention can be embodied in various other forms without departing from the spirit and scope thereof. Accordingly, the above-described embodiments should be considered illustrative rather than restrictive, and the appended claims and all implementations within the equivalent scope thereof will be included within the scope of the present invention.

1: Living tissue grinding device
10: lower chamber part 11: lower chamber main body
12: thread 13: step
14: Internal space
20: upper chamber part 21: upper chamber body
22: thread 23: ring-shaped protrusion
30: cover part 31: cover body
32: thread 33: rotation axis hole
40: Rotating grinding unit 41: Rotating shaft
42: rotating disk
50: discharge grid 51: mesh net
52: ring member 53, 54: fastening means
100: rotation driving unit 101: driving unit main body
102: Grinding device seating groove 103: Position fixing groove
104: side portion 105: cover seating portion
106: Rotation shaft insertion hole
110: arc-shaped cover

Claims (10)

In the biological tissue grinding device that grinds biological tissue into fine pieces,
lower chamber part;
An upper chamber part fastened to the upper part of the lower chamber part and having a rotating pulverizing part for pulverizing the biological tissue located inside;
A cover part fastened to the upper part of the upper chamber part;
a rotary grinding unit rotatably installed on the cover and located inside the upper chamber; and
Located at a connection end of the lower chamber portion and the upper chamber portion, it includes a discharge grid through which fine pieces pulverized through the rotary pulverizer are discharged,
The cover portion includes a cap-shaped cover body and an axial hole formed so that the rotation axis of the rotary crusher can be mounted on the cover body,
The rotary crushing unit consists of a rotating shaft that is connected to a rotating drive device and rotates, and a rotating disk fixed to the lower end of the rotating shaft,
The rotating shaft has a ring-shaped groove formed at a certain position so that it can be fixed in the shaft hole of the cover body,
A biological tissue grinding device, wherein the ring-shaped groove is formed to be larger than the thickness of the cover body.
According to paragraph 1,
The lower chamber part,
A cup-shaped lower chamber body;
Screw threads formed on the upper inner peripheral surface of the lower chamber body; and
A step formed inside the lower end of the screw thread;
A biological tissue grinding device characterized by consisting of.
According to paragraph 2,
The upper chamber portion is a biological tissue grinding device characterized in that it consists of a cylindrical upper chamber body and screw threads formed on the upper and lower outer peripheral surfaces of the upper chamber body.
According to paragraph 3,
The cover part is a biological tissue grinding device characterized in that it includes a screw thread formed on an inner peripheral surface so that the cover main body can be coupled to the upper chamber main body.
delete delete According to paragraph 1,
The discharge grid is,
A biological tissue grinding device characterized by forming grid-shaped fine perforations on a disk.
In clause 7,
The discharge grid is a biological tissue grinding device, characterized in that the disk is made of metal or synthetic resin.
According to paragraph 1,
The discharge grid is,
A biological tissue grinding device comprising a mesh net and a pair of ring members that secure edges of the mesh net at the top and bottom of the mesh net.
According to clause 9,
The ring member is a biological tissue grinding device, characterized in that it is seated on a step formed on the inner peripheral surface of the lower chamber portion.