KR20130038041A - Mouse holder - Google Patents

Abstract

PURPOSE: A house holder is provided to reduce an exposure degree about the nano particle of an experimental animal and enable a more correct nano particle inhalation toxicity evaluation examination. CONSTITUTION: A house holder includes the body part(110) of a hollow pipe form in order to insert an experimental animal into an internal space; a nose part(120) extended in the one end of the body part; an inner holder(100) in which a through hole is formed in order to be connected to the nano particle exposure chamber in the end of the nose part; and an outer holder(200) having an opening part in one end and hermetically combined with the one side of the nano particle exposure chamber so that an internal space is connected to the nano particle exposure chamber through the opening part. The nose part is formed in a slope form in which an internal diameter becomes smaller to the through hole, and an interval angle about an inner periphery surface forms an acute angle.

Description

Mouse holder device {Mouse Holder}

The present invention relates to a mouse holder device. More specifically, it is necessary to provide a relatively more space for a more comfortable living of the experimental animals put into the holder for the nanoparticle inhalation toxicity assessment test, and to replace with a new type of species as the experimental animals grow. The maintenance period of the holder can be maintained relatively longer, so that the maintenance can be performed more conveniently. The holder into which the experimental animal is introduced is formed in a double structure of the inner holder and the outer holder, so that the installation and replacement work are easy. In addition, the present invention relates to a mouse holder device that can prevent the leakage of nanoparticles to prevent the health risks of administrators entering the laboratory.

If the 20th century was a micro era, the 21st century could be called the nano era. Nanotechnology can be classified into nanomaterials, nanodevices, and environmental and biotechnology-based technologies according to their applications.

These nanotechnologies artificially manipulate microscopic materials at the atomic or molecular level to create materials or devices with new properties and functions, which are the basis for information technology (IT) and other biotechnology (BT) technologies today. It is hailed as a cutting-edge technology for realizing).

However, while nanotechnology offers many benefits and benefits that can be recognized as a new technological revolution throughout the industry, it is also well known that there are potential risks. This is due to the nature of nanotechnology.

In other words, the smaller the particles, the larger the specific surface area ratio, and the smaller the larger the specific surface area ratio, the greater the toxicity when reacting with biological tissues. For example, some nanoparticles such as titanium dioxide, carbon powder, diesel particles, etc. It has already been found in academic experiments that the smaller the size, the stronger the toxicity. In addition, ultra-fine nanoparticles can be lodged deep into the alveoli or migrate to the brain without being trapped by the airways or mucous membranes. Furthermore, recent studies have reported that the accumulation of nanoparticles in the body causes diseases or central nervous system disorders. .

Therefore, in recent years, with the development of nanotechnology, stability evaluation of nanotechnology has been actively progressed. For example, nanoparticle inhalation toxicity evaluation tests that evaluate the toxicity generated when nanoparticles are inhaled and accumulated in the human body have various experiments. Animals are being studied. The human hazard data obtained through the nanoparticle inhalation toxicity evaluation test is used as various basic data on nanoparticles throughout the industry such as nanofibers, cosmetics, semiconductors, and drug carriers.

Inhalation toxicity evaluation tests for these nanoparticles generally generate nanoparticles in an aerosol state and continuously supply them to an exposure chamber of a predetermined size of nanoparticles, and insert the experimental animals (rats, malmots, etc.) into the exposure chambers, and then the nanoparticles. After exposure to a variety of changes in the state of the test animal progress is being made. In this case, a method of measuring the change state of the test animal by directly inserting a plurality of test animals into the exposure chamber may be performed, but in general, a separate mouse holder device is used to measure the individual change state of each test animal. It's going the way.

The mouse holder device is formed to be introduced into the experimental animal, and the communication hole is formed on one side to communicate with the nanoparticle exposure chamber, the mouse holder device is coupled to communicate with the nanoparticle exposure chamber through the communication hole, The injected experimental animal is configured to be exposed to the nanoparticles. Multiple mouse holder devices are coupled to a single nanoparticle exposure chamber to measure the individual state of change in each experimental animal.

However, the conventional mouse holder device according to the prior art is a case in which a test animal can be put therein, and a communication hole is formed at one side of the case. The mouse holder device is formed in such a way that the experimental animal is pushed and fixed to the communication hole side as close as possible so as to expose the nanoparticles to the experimental animal as much as possible.

Therefore, the experimental animals put into such a mouse holder device have problems such as suffocation or severe stress caused by the stress before the nanoparticles are affected, and thus it is not possible to accurately perform the inhalation toxicity evaluation test on the nanoparticles. there was.

In addition, since the mouse holder device is applied to a cylindrical case having a size almost equal to the size of the torso of the test animal so that the test animal does not move inside, when the test animal grows during the inhalation toxicity test, according to the growth rate There has been the inconvenience of continuing to replace the size of the mouse holder device with a new type.

In addition, since the mouse holder device is generally formed in a single case shape, the structure may allow nanoparticles to leak from the mouse holder device into the laboratory, thereby reducing the accuracy of the nanoparticle inhalation toxicity evaluation test, The health of managers also poses a threat.

The present invention has been invented to solve the problems of the prior art, the object of the present invention is to provide a relatively more comfortable space for living more comfortable living the experimental animals that are put into the holder for the nanoparticle inhalation toxicity evaluation test The present invention provides a mouse holder device that allows more accurate nanoparticle inhalation toxicity assessment test by providing a free space such that the exposure degree of the nanoparticles of the experimental animal is not reduced.

Another object of the present invention is to provide a mouse holder device that can maintain the holder replacement cycle that needs to be replaced with a new type of size as the growth of the experimental animal is relatively longer, so that maintenance can be performed more conveniently.

Another object of the present invention is to form a holder in which the experimental animal is put into a double structure of the inner holder and the outer holder, the installation and replacement is easy, and the health risk of the administrator entering the laboratory by preventing the external leakage of nanoparticles It is to provide a mouse holder device that can prevent the.

The present invention is a mouse holder device which is connected to the separate nanoparticle exposure chamber so that the experimental animal is injected inside and the experimental animal is exposed to the nanoparticles, the hollow pipe shape so that the experimental animal can be injected into the inner space A body portion and a nose portion extending from one end of the body portion, and an inner holder having a communication hole formed at the end of the nose portion so as to communicate with the nanoparticle exposure chamber, wherein the nose portion has an inner diameter toward the communication hole. It is formed to be inclined in a small form, the inner peripheral surface of the nose portion provides a mouse holder device, characterized in that the angle of the inner circumferential surface is formed at an acute angle so as to wrap around the nose portion of the experimental animal.

The mouse holder device may further include an outer holder formed at one end thereof and sealingly coupled to one side of the nanoparticle exposure chamber through which the internal space communicates with the nanoparticle exposure chamber. Is disposed in the outer holder, one end of the nose portion may be in close contact with the opening so that the communication hole communicates with the nanoparticle exposure chamber through the opening.

In this case, a sealing member may be mounted around the opening circumference of the outer holder to seal the outer holder to the nanoparticle exposure chamber.

In addition, a holder cover for sealing the inner space of the outer holder is detachably mounted at the other end of the outer holder, and the holder cover is separately pressurized so as to be linearly movable in the longitudinal direction of the outer holder by a user's operation. The operation unit may be coupled through and the inner holder may be coupled to or released from the opening in association with a linear movement of the pressing operation unit.

In addition, the inner holder may be mounted so that the position control plate is movable in the longitudinal direction to adjust the injection position of the experimental animal.

In addition, the body hole of the inner holder may be formed with a dropping hole so that the excretion of the experimental animal can be discharged to the outside of the inner holder.

At this time, the excrement hole is formed at the other end opposite to the communication hole of the inner holder, the excrement guide groove of the form inclined downward toward the excrement hole to communicate with the excrement hole in the body portion of the inner holder of the body portion It may be formed long along the longitudinal direction.

According to the present invention, the inner holder into which the experimental animal is introduced is formed by a body part and a nose part, and the nose part is formed in an inclined shape with an acute angle that wraps and contacts the nose part of the experimental animal, thereby allowing the injected experimental animal to live more comfortably. It is possible to provide a relatively more comfortable space, and even in this case, it is possible to prevent a decrease in the exposure degree of the nanoparticles of the experimental animal to enable more accurate nanoparticle inhalation toxicity evaluation test.

In addition, the inner holder into which the experimental animal is introduced is formed as a cylindrical nose and an inclined nose portion having an acute angle in contact with the nose of the experimental animal, whereby a relatively free space is provided in the body where the torso of the experimental animal is located. Therefore, it is possible to maintain the holder replacement cycle relatively longer to be replaced with a new type of type as the growth of the experimental animal has the effect that can be more easily performed maintenance.

In addition, by forming the holder of the experiment animal into the dual structure of the inner holder and the outer holder, it is easy to install and replace, and to prevent the external leakage of nanoparticles to prevent the health risk of the administrator entering the laboratory. It works.

1 is a perspective view schematically showing an assembly shape of a mouse holder device according to an embodiment of the present invention;
Figure 2 is a cross-sectional view schematically showing the shape of the inner holder of the mouse holder device according to an embodiment of the present invention,
3 is an exploded perspective view schematically showing a detailed configuration of a mouse holder device according to an embodiment of the present invention;
4 is a cross-sectional view schematically showing the internal structure of the mouse holder device according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a perspective view schematically illustrating an assembly shape of a mouse holder device according to an embodiment of the present invention, and FIG. 2 schematically illustrates a shape of an inner holder of a mouse holder device according to an embodiment of the present invention. It is a cross section.

Mouse holder device according to an embodiment of the present invention is formed so that the experimental animal (P) can be injected therein, the device is coupled to communicate in a separate nanoparticle exposure chamber so that the experimental animal (P) is exposed to the nanoparticles As an inner holder 100 having a communication hole 121 formed at one end thereof, the outer holder 200 surrounding the outside of the inner holder 100 may be further configured.

The inner holder 100 is formed so that the experimental animal can be introduced into the inner space, and includes a hollow pipe-shaped body portion 110 and a nose portion 120 extending at one end of the body portion 110. A communication hole 121 is formed at the end of the nose portion 120 to communicate with the nanoparticle exposure chamber C (see FIG. 4). At this time, the nose portion 120 is formed to be inclined in the form of the inner diameter toward the communication hole 121 is reduced.

For example, the body portion 110 may be formed in a hollow cylindrical shape, the nose portion 120 may extend to one end of the body portion 110 may be formed in a hollow conical shape, a cone-shaped nose portion The communication hole 121 may be formed at a vertex portion of the 120.

The experimental animal P introduced into the inner holder 100 is introduced so that the nose portion P1 faces the communication hole 121 so as to smoothly inhale the nanoparticles, thus, as shown in FIG. 2. As pointed nose portion (P1) is located in the nose portion 120 in the direction toward the communication hole 121, the trunk portion (P2) is mainly located in the body portion (110).

The outer holder 200 is formed to surround the outside of the inner holder 100 so that the inner holder 100 can be disposed in the inner space, and an opening 201 is formed at one end thereof so that the inner holder 100 can be disposed in the inner space. It is sealingly coupled to one side of the nanoparticle exposure chamber (C) so as to be in communication with the nanoparticle exposure chamber (C).

For example, the outer holder 200 is formed in a hollow cylindrical shape, one end portion is formed with a coupling portion protruding in the longitudinal direction, the separate coupling groove 211 on the outer peripheral surface of the coupling portion 210 It may be formed to be coupled to the nanoparticle exposure chamber (C) in a detachable manner.

According to this structure, the inner holder 100 is disposed inside the outer holder 200, and the communication hole 121 of the inner holder 100 passes through the opening 201 of the outer holder 200 to expose the nanoparticle exposure chamber ( One end of the nose portion 120 is configured to be in close contact with the opening 201 to communicate with C).

Therefore, the mouse holder device according to an embodiment of the present invention is formed by a double case structure of the inner holder 100 into which the experimental animal P is inserted and the outer holder 200 surrounding the outside of the inner holder 100. Although the nanoparticles leak out from the inner holder 100, the outer holder 200 is sealed off once again by the outer holder 200 surrounding the outside of the inner holder 100, thereby preventing external leakage of the nanoparticles to enter and exit a laboratory. It can prevent the health risks of managers.

On the other hand, the inner holder 100 according to an embodiment of the present invention is formed of a nose portion 120 which is formed to be inclined to extend to the body portion 110 and one end of the body portion 110 as described above, The nose portion P1 of the experimental animal P injected accordingly is positioned in the nose portion 120. At this time, the inner circumferential surface of the nose portion 120 is formed to form an acute angle with respect to the inner circumferential surface α so that the inner circumferential surface of the nose 120 may be wrapped around the nose portion P1 of the experimental animal.

According to this structure, the mouse holder device according to an embodiment of the present invention does not need to push the experimental animal P tightly into the inner holder 100, so that the experimental animal P is less stressed, and the experimental animal ( Even if P) grows, the replacement cycle of the inner holder 100 can be maintained relatively long.

In more detail, in general, the experimental animal (P) is formed in the shape of the pointed nose portion (P1) as shown in FIG. In response to the shape of the experimental animal (P), the nose portion 120 of the inner holder 100 is formed in a pointed shape so that the angle (α) of the inner circumferential surface is acute, a communication hole at the end of the nose portion 120 121 is formed. Therefore, the nanoparticles introduced through the communication hole 121 is induced through the nose portion 120, because the nose portion 120 is formed in a sharp shape at an acute angle, the nose portion of the experimental animal (P) ( P1) is positioned in contact with the inner circumferential surface of the nose portion 120.

At this time, even if the nose portion (P1) of the experimental animal (P) is located at a position spaced apart from the communication hole 121 as shown in FIG. Since the nanoparticles introduced in the structure can be smoothly sucked into the experimental animal (P), the experimental animal (P) can be relatively living in a more relaxed space.

In particular, even if the nose portion P1 of the experimental animal P is wrapped in contact with any part of the inner circumferential surface of the nose portion 120, the trunk portion P2 of the experimental animal P is formed on the inner circumferential surface of the body portion 110. Can be positioned comfortably without contact. That is, as shown in (a) of FIG. 2, the body part 110 of the inner holder 100 having the inner diameter X in the state where the nose part P1 of the experimental animal P is in contact with the nose part 120. The trunk portion P2 may be located at a distance from the inner circumferential surface by an X1 distance. In this case, when the experimental animal P grows more, the shape of the nose part P1 is maintained as it is, and only the trunk part P2 grows a little more. As shown, the inner holder 100 can be continuously applied to the same inner holder 100 without replacing the inner holder 100. Of course, in this case, as the experimental animal P grows as shown in FIGS. 2A and 2B, the torso portion P2 and the inner holder 100 body of the experimental animal P are grown. The distance X1 from the inner circumferential surface of the unit 110 is reduced, and the position of the position adjusting plate 400 for adjusting the input position of the experimental animal P is changed.

Therefore, the mouse holder device according to an embodiment of the present invention can be relatively leisurely living the experimental animal (P) through the nose portion 120 that wraps in contact with the nose portion (P1) of the experimental animal (P), Accordingly, it is possible to more accurately evaluate the inhalation toxicity of nanoparticles due to less stress, and the structure that can take longer replacement cycle of the mouse holder device according to the growth of the experimental animal (P).

Next, a detailed configuration of the mouse holder device according to an embodiment of the present invention will be described in more detail with reference to FIGS. 3 and 4.

3 is an exploded perspective view schematically showing a detailed configuration of a mouse holder device according to an embodiment of the present invention, Figure 4 is a cross-sectional view schematically showing the internal structure of the mouse holder device according to an embodiment of the present invention. .

As described above, the inner holder 100 is formed of the body part 110 and the nose part 120, and a communication hole 121 is formed at the end of the nose part 120. The outer holder 200 is coupled in communication with the nanoparticle exposure chamber C through the coupling portion 210 and the opening 201. The inner holder 100 is disposed inside the outer holder 200, and the communication hole 121 of the inner holder 100 communicates with the nanoparticle exposure chamber C through the opening 201 of the outer holder 200. One end of the nose portion 120 is closely coupled to the opening 201 so as to be close to the opening 201. One end of the nose portion 120 for the close coupling is formed with a separate coupling wing 122 to contact the inner periphery of the opening 201 of the outer holder 200.

In addition, the inner holder 100 is equipped with a separate position control plate 400 so as to be movable in the longitudinal direction to adjust the injection position of the experimental animal (P). To this end, the body 110 of the inner holder 100 is formed with a guide groove 111 long along the longitudinal direction, and one side of the positioning plate 400, the engaging projection that can be inserted into the guide groove 111 ( 410 is formed, the coupling protrusion 410 is formed in a manner that is screwed to the positioning plate 400 is configured to be fixed in the screw coupling manner in the state inserted into the guide groove 111 of the inner holder 100 Can be. At this time, it is preferable that a separate tail passage hole 401 is formed at one side of the positioning plate 400 so that the tail portion of the experimental animal P can pass in order to provide a more comfortable environment for the experimental animal P. .

In addition, the nose portion 120 of the inner holder 100 may be formed with a separate ventilation hole 123 on one side so that the breathing of the experimental animal (P) can be more comfortable, on one side of the body portion 110 The excrement hole 112 may be formed so that the excretion of the experimental animal (P) can be discharged to the outside of the inner holder (100).

At this time, the excrement hole 112 is formed at the other end opposite to the communication hole 121 of the inner holder 100, the excrement hole in the body portion 110 of the inner holder 100 so as to communicate with the excrement hole 112. The excrement guide groove 113 inclined downward toward the 112 may be formed long along the longitudinal direction of the body portion 110. Therefore, the excretion of the experimental animal (P) is discharged to the outside of the inner holder 100, that is, the outer holder 200 through the excretion guide groove 113 and the excrement hole 112, accordingly the inner holder 100 The interior space can be kept relatively clean.

Meanwhile, a separate sealing member 300 is mounted around the outer periphery of the opening 201 of the outer holder 200 such that the outer holder 200 is hermetically coupled to the nanoparticle exposure chamber C. At the other end, the holder cover 220 is detachably coupled to seal the inner space of the outer holder 200.

At this time, the holder cover 220 is coupled to the separate pressing operation unit 230 to be linearly movable in the longitudinal direction of the outer holder 200 by the user's operation, the pressing operation unit 230 is a holder cover 220 The pressure rod 232 penetrates and has a pressure knob formed at an outer end thereof, and a pressure plate 231 coupled to an inner end of the pressure rod 232 and positioned inside the outer holder 200. The pressing manipulation unit 230 is coupled to the linear movement in the longitudinal direction of the outer holder 200 through the pressing rod 232, which is located in the outer holder 200 in accordance with the linear movement of the pressing manipulation unit 230. The inner holder 100 moves in association with each other and is configured to be tightly coupled to or released from the opening 201.

That is, as shown in FIG. 4A, by pressing the pressing rod 232 of the pressing manipulation unit 230 inward, the pressing plate 231 pressurizes the inner holder 100. The holder 100 is tightly coupled to the opening 201 of the outer holder 200, and as shown in FIG. 4B, the holder 100 is pulled out by pressing the pressing rod 232 of the pressing operation unit 230 outward. The plate 231 depressurizes the inner holder 100, and thus the inner holder 100 is released from the opening 201 of the outer holder 200.

According to this structure, the outer holder 200 is fixed to the nanoparticle exposure chamber C as it is, and the holder cover 220 of the outer holder 200 is removed to replace the inner inner holder 100 with a new inner holder. Can be replaced with (100). At this time, the holder cover 220 is coupled in a state where the new inner holder 100 is inserted into the outer holder 200, and then the pressure holder 232 of the pressure manipulation unit 230 is pressed to operate the inner holder 100. The nose part 120 may be closely coupled to the opening 201 of the outer holder 200.

Therefore, in the mouse holder device according to the embodiment of the present invention, the inner holder 100 is fixed to the nanoparticle exposure chamber C while the outer holder 200 is fixedly coupled to the nanoparticle exposure chamber C. Since it can be combined to communicate with, the installation and replacement can be performed more easily and reliably.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

100: inner holder 110: body
112: dropping hole 113: dropping guide groove
120: nose part 121: communication hole
200: outer holder 201: opening
220: holder cover 230: pressurizing operation unit
300: sealing member

Claims (7)

In the mouse holder device that is inserted into the experimental animal in communication with the separate nanoparticle exposure chamber so that the experimental animal is exposed to the nanoparticles,
An inner holder including a hollow pipe-shaped body portion and a nose portion extending from one end of the body portion so that an experimental animal can be introduced into the inner space, and a communication hole is formed at the end of the nose portion so as to communicate with the nanoparticle exposure chamber.
It includes, the nose portion is formed to be inclined in the form of the inner diameter is reduced toward the communication hole, the inner circumferential surface of the nose portion is formed at an acute angle with respect to the inner circumferential surface so as to wrap around the nose portion of the experimental animal Mouse holder device, characterized in that.
The method of claim 1,
An outer holder formed at one end thereof and sealingly coupled to one side of the nanoparticle exposure chamber such that an inner space communicates with the nanoparticle exposure chamber through the opening;
The inner holder is disposed inside the outer holder, the mouse holder device, characterized in that one end of the nose portion is in close contact with the opening so that the communication hole communicates with the nanoparticle exposure chamber through the opening.
The method of claim 2,
And a sealing member mounted around the periphery of the opening of the outer holder to seal the outer holder to the nanoparticle exposure chamber.
The method of claim 2,
The other end of the outer holder is detachably mounted to the holder cover for sealing the inner space of the outer holder,
The holder cover is coupled through a separate pressing operation portion so as to be linearly moved in the longitudinal direction of the outer holder by a user's operation, and the inner holder is coupled to or released from the opening in association with the linear movement of the pressing operation portion. Mouse holder device characterized in that the.
5. The method according to any one of claims 2 to 4,
The inner holder is a mouse holder device, characterized in that the positioning plate is mounted to be movable in the longitudinal direction to adjust the injection position of the experimental animal.
The method of claim 5, wherein
Mouse holder device, characterized in that the excrement hole is formed in the body portion of the inner holder so that the excretion of the experimental animal can be discharged to the outside of the inner holder.
The method according to claim 6,
The excrement hole is formed at the other end opposite to the communication hole of the inner holder,
Mouse holder device, characterized in that the body portion of the inner holder is formed along the length direction of the body portion of the excrement guide groove inclined downward toward the excrement hole to communicate with the excrement hole.

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