KR102404139B1 - Mouse holder - Google Patents

Abstract

The present invention relates to a mouse holder device, and by mounting a tail fixing means capable of fixing the tail of the experimental animal to the inside of the holder body into which the experimental animal is put, the tail of the experimental animal is maintained in a fixed state, so that the experimental animal Blood can be easily collected from the tail of the experimental animal by using a syringe during exposure to the test substance particle, so that the health status of the experimental animal can be monitored in real time during the test substance particle exposure process rather than after the test substance particle exposure process is completed. can be measured as a scalable device, and the accuracy and reliability of the inhalation toxicity evaluation based on this can be further improved, and by mounting a separate syringe fixing body, it is easy to operate the syringe for blood collection, and thus the test substance particles Provided is a mouse holder device that can more reliably and conveniently perform blood collection during an exposure process.

Description

A mouse holder device capable of collecting blood {MOUSE HOLDER}

The present invention relates to a mouse holder device. More specifically, by mounting a tail fixing means capable of fixing the tail of the experimental animal to the inside of the holder body into which the experimental animal is inserted, the tail of the experimental animal is maintained in a fixed state, so that the experimental animal is exposed to the test material particles. It is possible to easily collect blood from the tail of the experimental animal by using a syringe during It is possible to further improve the accuracy and reliability of the inhalation toxicity evaluation based on this, and by mounting a separate syringe fixing body, it is easy to operate the syringe for blood collection, and thus the blood collection operation during the test substance particle exposure process It relates to a mouse holder device that can perform more stably and conveniently.

If the 20th century was the era of micro, the 21st century can be said to be the nano era. Nanotechnology can be broadly classified into nanomaterials, nanodevices, and environmental and biotechnology-based technologies according to its application fields.

Such nanotechnology is to artificially manipulate ultra-fine materials at the atomic or molecular level to create materials or devices with new properties and functions. It is being revered as a state-of-the-art technology to realize this.

However, although nanotechnology provides many benefits and benefits to the extent that it is recognized as a new technological revolution throughout the industry, on the other hand, it is also known that it has potential risks. This can be attributed to the characteristics of nanotechnology.

That is, the smaller the particle, the wider the specific surface area ratio, and the small particle with such a wide specific surface area ratio increases toxicity when reacting with a living tissue. As an example, some nanoparticles such as titanium dioxide, carbon powder, diesel particles It is a fact already known through academic experiments that the smaller the size, the stronger the toxicity, such as causing inflammation. In addition, ultrafine nanoparticles are not filtered in the airways or mucous membranes and can be lodged deep in the alveoli or migrate to the brain. .

Therefore, in recent years, with the development of nanotechnology, stability evaluation of nanotechnology is also being actively conducted. Representatively, various experiments are conducted to evaluate the toxicity that occurs when nanoparticles are inhaled and accumulated in the human body. It is being studied on animals. The human toxicity data obtained through these nanoparticle inhalation toxicity evaluation tests are being used as various basic data on nanoparticles throughout industries such as nanofibers, cosmetics, semiconductors, and drug delivery systems.

Recently, inhalation toxicity evaluation of these nanoparticles as well as various harmful substances, for example, mist, dust, gas, steam, fine particles, ultra-fine particles, smog, etc., entering the body through breathing Toxicity evaluation is in progress, and these inhalation toxicity evaluation tests are mostly conducted in the same way. Hereinafter, all of the various harmful material particles including nanoparticles are collectively referred to as hazardous material particles.

In the inhalation toxicity evaluation test for these hazardous substance particles, in general, hazardous substance particles are generated in an aerosol state, supplied to an exposure chamber of a certain size, and experimental animals are introduced into these exposure chambers to expose them to hazardous substance particles. It is proceeding in a way that measures various state of change.

The exposure chamber device for performing this inhalation toxicity evaluation test includes a whole body exposure chamber device that allows the experimental animal to be put into a relatively large space, live in the injected space, and exposed to harmful substances particles, and the experimental animal A nose only exposure chamber device that is inserted into a relatively narrow space, fixed in position, and inhales harmful substance particles through the nose in the injected space, is generally used. As a nasal exposure chamber device, a mouse holder device capable of fixing a position by introducing a mouse as an experimental animal is widely used.

The mouse holder device is formed so that the experimental animal is put therein, and a communication hole is formed on one side to communicate with the hazardous substance supply chamber to which the hazardous substance particles are supplied. It is configured so that the injected experimental animal is exposed to the harmful substance particles.

After exposing the harmful substance particles to the experimental animal through the mouse holder device in this way, the health status of the experimental animal is measured to evaluate the inhalation toxicity state for the harmful substance particle. At this time, in order to measure the health status of the experimental animal, the experimental animal is generally put in a separate metabolic cage, and in this state, excrement such as urine or blood discharged from the experimental animal is extracted to measure the health status of the experimental animal. do.

This method does not measure the health status of the experimental animal when the experimental animal is exposed to the harmful substance particles, but measures the health status of the experimental animal after a certain period of time has elapsed from the time the experimental animal is exposed to the harmful substance particle. Because it is to be measured, the health status can be measured in a state in which the effect of the harmful substance particles on the experimental animal is recovered to a certain extent, and when an inhalation toxicity evaluation is performed on the hazardous substance particles based on this, the accuracy of the result and There is a problem that reliability is lowered. In addition, there is a limitation in that the inhalation toxicity effect of the harmful substance particles cannot be determined in real time because the health status of the experimental animal cannot be measured while the experimental animal is exposed to the harmful substance particles.

Domestic Registered Patent No. 10-1642143

The present invention was invented to solve the problems of the prior art, and an object of the present invention is to mount a tail fixing means capable of fixing the tail of the experimental animal to the inside of the holder body into which the experimental animal is inserted, thereby providing the tail of the experimental animal. remains stationary, so that blood can be easily drawn from the tail of the experimental animal using a syringe while the animal is exposed to the test substance particles, and thus the test substance particles rather than after the test substance particle exposure process is complete An object of the present invention is to provide a mouse holder device capable of measuring the health status of experimental animals in real time during the exposure process and further improving the accuracy and reliability of inhalation toxicity evaluation based on this.

Another object of the present invention is to mount a separate syringe fixing body, thereby facilitating the operation of a syringe for blood collection, and thus a mouse holder device that can perform blood collection more stably and conveniently during the test material particle exposure process is to provide

The present invention is a mouse holder device in which an experimental animal is inserted therein, and is coupled in communication with a separate test material supply chamber so that the injected experimental animal is exposed to test material particles, the hollow so that the experimental animal can be inserted into the inner space a holder body including a pipe-shaped body portion and a nose portion extending at one end of the body portion in a shape of decreasing diameter toward the front end and having a communication hole formed at the front end to communicate with the test material supply chamber; a position control plate mounted movably in the body portion along the longitudinal direction to fix the internal position of the experimental animal and having a tail passage hole formed in the center to allow the tail of the experimental animal to pass through; and a tail fixing means for fixing the tail of the experimental animal that has passed through the tail passage hole which is disposed to be located behind the position control plate inside the body portion, It provides a mouse holder device, characterized in that formed to enable blood collection.

In this case, the holder body may further include an outer cover sealingly enclosing the outer space, and a syringe input unit may be formed in the outer cover so that a syringe for blood collection can be inserted in a sealable state.

In addition, the tail fixing means may include: a lower fixing block disposed inside the holder body and formed to seat the tail of the experimental animal on the upper surface; an upper fixing block disposed above the lower fixing block to guide the position of the tail of the experimental animal seated on the lower fixing block; and a tail pressing part mounted on the lower fixing block so as to be positioned at the rear of the upper fixing block to press and fix the tail of the experimental animal.

In addition, a guide groove may be formed on the lower surface of the upper fixing block so that the tail of the experimental animal is penetrated to limit the range of movement.

In addition, the lower fixed block is formed with a horizontal portion formed to form a horizontal plane so that the tail of the experimental animal is seated, and an inclined portion extending downwardly from the rear end of the horizontal portion is formed, and the upper fixing block is disposed on the upper surface of the horizontal portion for the experiment Guide the position of the animal's tail, the tail pressing part may be disposed on the inclined part to press and fix the tail of the experimental animal.

In addition, the tail pressing unit, a rotating rod rotatably coupled to one side of the lower fixed block; a pressing body coupled to the end of the rotating rod to press the tail of the experimental animal; and an elastic member for applying an elastic force to the rotating rod so that the pressing body rotates in a direction in contact with the inclined portion.

In addition, a syringe fixing body capable of mounting and fixing the syringe may be coupled to the upper portion of the pressure body.

In addition, the syringe fixing body may be formed with a syringe mounting groove in which the syringe can be mounted, and a needle guide hole through which the syringe needle of the syringe can be inserted.

According to the present invention, by mounting a tail fixing means capable of fixing the tail of the experimental animal to the inside of the holder body into which the experimental animal is inserted, the tail of the experimental animal is maintained in a fixed state, so that the experimental animal is exposed to the test material particles It is possible to easily collect blood from the tail of the experimental animal using a syringe during , there is an effect that can further improve the accuracy and reliability of the inhalation toxicity assessment based on this.

In addition, by mounting a separate syringe fixing body, the operation of the syringe for blood collection is facilitated, and thus, there is an effect that blood collection operation can be performed more stably and conveniently during the test material particle exposure process.

1 is a view schematically showing the configuration of a mouse holder device according to an embodiment of the present invention;
Figure 2 is a perspective view schematically showing the configuration of the tail fixing means of the mouse holder device according to an embodiment of the present invention;
3 is a cross-sectional view conceptually illustrating a structure for a tail fixing means of a mouse holder device according to an embodiment of the present invention;
4 and 5 are cross-sectional views conceptually showing the structure of the tail fixing means of the mouse holder device according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a view schematically showing the configuration of a mouse holder device according to an embodiment of the present invention, Figure 2 is a diagram schematically showing the configuration of the tail fixing means of the mouse holder device according to an embodiment of the present invention It is a perspective view, and FIG. 3 is a cross-sectional view conceptually illustrating a structure for a tail fixing means of a mouse holder device according to an embodiment of the present invention.

In the mouse holder device according to an embodiment of the present invention, an experimental animal (P) such as a mouse is inserted therein, and the injected experimental animal (P) communicates with a separate test material supply chamber (C) to be exposed to the test material particles. As a device coupled to be so, it is configured to include a holder body 100 , a position adjusting plate 200 , and a tail fixing means 400 .

The holder body 100 is formed so that the experimental animal P can be put into the inner space, and the body part 110 in the shape of a hollow pipe and the nose part 120 extending from one end of the body part 110 are formed. formed by including A communication hole 121 is formed at an end of the nose portion 120 to communicate with the test material supply chamber C, and the nose portion 120 is formed to be inclined in such a way that the diameter decreases toward the end.

For example, the body part 110 may be formed in a hollow cylindrical shape, and the nose part 120 may extend to one end of the body part 110 to have a hollow cone shape, and a conical nose part A communication hole 121 may be formed at the vertex of 120 .

The experimental animal P input into the holder body 100 is inserted so that the nose portion faces the communication hole 121 so as to smoothly inhale the test material particles. Accordingly, as shown in FIG. 1 , the pointed nose part is positioned on the nose part 120 in the direction toward the communication hole 121 , and the body part is mainly positioned on the body part 110 .

One end opposite to the one end on which the communication hole 121 of the holder body 100 is formed is formed in an open form as shown in FIG. 1 . Although not shown, a separate closing cap (not shown) is provided on the holder body 100 It may be configured to be coupled to the open end of the.

A separate outer cover 300 may be coupled to the outside of the holder body 100 to enclose the external space of the holder body 100 to be sealed. The outer cover 300 may be formed to be separated into a fixed cover and a separation cover, the fixed cover is sealingly coupled to the nose portion 120 of the holder body 100 , and the separation cover is detachably coupled to one end of the fixed cover. do.

As a separate outer cover 300 is coupled to the outside of the holder body 100 as described above, the inner space of the holder body 100 into which the experimental animal P is inserted is the holder body 100 and the outer cover 300 . It is formed to be protected by a double case structure, and accordingly, even if the test material particles are leaked from the holder body 100 to the outside, it is once again sealed and blocked from the outside by the outer cover 300 surrounding the outside of the holder body 100, External leakage of test substance particles can be prevented, thereby avoiding a risk to the health of administrators entering the laboratory.

The position control plate 200 is movably mounted on the body part 110 of the holder body 100 in the longitudinal direction to fix the internal position of the experimental animal P put into the holder body 100 . To this end, a guide groove 111 is formed in the body portion 110 of the holder body 100 along the longitudinal direction, and at one side of the position adjustment plate 200, a coupling protrusion that can be inserted and coupled to the guide groove 111 ( 201) is formed. The coupling protrusion 201 may be formed in such a way that it is screwed to the position adjusting plate 200 , and may be configured to be fixed in position by a screw coupling method while being inserted into the guide groove 111 of the holder body 100 . At this time, a separate tail passage hole 210 is formed on one side of the position control plate 200 so that the tail of the experimental animal P can pass through in order to provide a more comfortable environment for the experimental animal P.

According to this structure, when the holder body 100 is coupled to the test material supply chamber (C), the test material particles are introduced into the space inside the holder body 100 through the communication hole 121 from the test material supply chamber (C). is exposed to the experimental animal (P) inside the holder body (100), the experimental animal (P) is inhaled the test material particles. The experimental animal P put into the holder body 100 is fixed in position so that the nose portion is adjacent to the communication hole 121 by the position control plate 200, and thus the test material particles introduced through the communication hole 121 is intensively inhaled by the experimental animal (P).

The mouse holder device according to an embodiment of the present invention can measure the health status of the experimental animal (P) in real time in the process of exposing the test material particles to the experimental animal (P), for this purpose, a separate tail is fixed Means 400 are provided.

The tail fixing means 400 is disposed to be positioned at the rear of the position control plate 200 inside the body part 110 to position and fix the tail P1 of the experimental animal P that has passed through the tail passage hole 210 . is composed

As such, when the tail P1 of the experimental animal P is fixed in position through the tail fixing means 400, blood is collected from the tail P1 of the experimental animal P in the fixed position using a syringe 10 or the like. It is possible. That is, it is difficult to insert the syringe needle of the syringe 10 into the tail P1 of the experimental animal P in a state in which the tail P1 of the experimental animal P moves freely. When the tail of the animal P is fixed in position, in this state, the syringe needle of the syringe 10 can be easily inserted into the tail P1 of the experimental animal P. Blood may be collected while the syringe 10 is inserted into the tail of the experimental animal P.

Such blood collection may be performed during the process in which the experimental animal P is exposed to the test material particles, and thus, the outer cover 300 to prevent the test material particles from leaking into the external space during the blood collection process through the syringe 10 . In the syringe 10, the injectable syringe input unit 310 may be formed in a sealable form. The syringe input unit 310 may be formed, for example, in the form of a valve made of a flexible material, such as rubber, in a form in which a central portion is cut, and in the process of inserting the syringe 10 through the cutout, a valve made of a flexible material. It may be configured to be maintained in close contact with the outer circumferential surface of the syringe body to maintain a sealed state.

Looking at the configuration of the tail fixing means 400 in more detail, the tail fixing means 400 is disposed inside the holder body 100 and is formed to seat the tail P1 of the experimental animal P on the upper surface. The lower fixing block 410 to be, and the upper fixing block 420 disposed on the upper portion of the lower fixing block 410 to guide the position of the tail of the experimental animal (P) seated on the lower fixing block 410, and the upper fixing It is mounted on the lower fixing block 410 so as to be located at the rear of the block 420 and may include a tail pressing unit 430 for pressing and fixing the tail P1 of the experimental animal P.

The lower fixing block 410 includes a horizontal portion 411 formed to form a horizontal plane so that the tail P1 of the experimental animal P is seated, and an inclined portion 412 extending downwardly from the rear end of the horizontal portion 411. is formed, and a guide groove 413 may be formed in the center of the horizontal portion 411 to guide the tail P1 of the experimental animal P to be seated.

The upper fixing block 420 is disposed on the upper surface of the horizontal portion 411 of the lower fixing block 410 to guide the tail position of the experimental animal (P), and the lower surface of the center of the upper fixing block 420 is the experimental animal (P) A guide groove 421 may be formed so that the tail P1 is penetrated to limit the range of movement. The guide groove 413 formed in the lower fixing block 410 and the guide groove 421 formed in the upper fixing block 420 may be formed in the same shape, but unlike the guide groove 413 formed in the upper fixing block 420, the guide groove formed in the upper fixing block 420 ( 421) may be formed in a form having a relatively wide diameter, and this guide groove 421 is not to fix the position of the tail P1 of the experimental animal P, but to simply limit the movement range within a certain section. can

At this time, the upper fixed block 420 may be configured to be disposed separately from the lower fixed block 410 , but the upper fixed block 420 is attached to the lower fixed block 410 through a separate upper and lower guide means (not shown). It may be configured to be coupled to be movable up and down with respect to each other. The vertical guide means includes a guide bar (not shown) mounted to protrude upward in a vertical direction to the lower fixing block 410 to guide a vertical movement path with respect to the upper fixing block 420 , and the upper fixing block so that the guide bar passes through. It may be configured in a form including a guide hole (not shown) formed in the 420 . In this case, an elastic spring (not shown) for applying a downward elastic force to the upper fixing block 420 may be coupled to the lower fixing block 410 so that the upper fixing block 420 is pressed in close contact with the lower fixing block 410 . Since the lower fixing block 410 is in close contact with the upper fixing block 420 by the elastic force of the elastic spring, the function of limiting the movement range of the tail P1 of the experimental animal P can be further strengthened.

The tail pressing part 430 is disposed on the inclined part 412 of the lower fixing block 410 and passed through the guide grooves 413,421 of the lower fixing block 410 and the upper fixing block 420 of the experimental animal P. It is formed to press and fix the tail P1.

The tail pressing part 430 is coupled to the other end of the rotating rod 431 and the other end of the rotating rod 431, one end of which is rotatably coupled to one side of the lower fixed block 410 about the horizontal axis of rotation, and is an experimental animal. A pressing body 432 for pressing the tail P1 of (P), and an elastic member 433 for applying an elastic force to the rotating rod 431 so that the pressing body 432 rotates in a direction in contact with the inclined portion 412 . It may be composed of

Accordingly, the tail P1 of the experimental animal P passes through the guide groove 413,421, which is a space between the lower fixing block 410 and the upper fixing block 420, and the inclined portion 412 of the lower fixing block 410. is positioned along, and in this state, the pressure body 432 presses and fixes the tail P1 of the experimental animal P by the elastic force of the elastic member 433 .

Looking at the process of fixing the tail P1 of the experimental animal P using the tail fixing means 400, first, the experimental animal P passing through the tail passage hole 210 of the position control plate 200 is The tail P1 is seated on the upper surface of the lower fixing block 410 , and in this state, the upper fixing block 420 is arranged and fixed on the upper surface of the lower fixing block 410 . At this time, the tail P1 of the experimental animal P passes through the guide groove 421 of the upper fixing block 420, and accordingly, the tail P1 of the experimental animal P is moved by the guide groove 421. Movement range is limited within a certain section. The pressing body 432 of the tail pressing part 430 pulls the rotating rod 431 apart from the inclined part 412 and rotates it clockwise (based on the direction shown in FIG. 3), and in this state, the experimental animal ( The tail P1 of P) is arranged in a form that hangs along the inclined portion 412 of the lower fixing block 410 . At this time, the tail P1 of the experimental animal P is positioned in the space between the surface of the inclined portion 412 and the pressing body 432 . When the rotating rod 431 is released in this state, the rotating rod 431 rotates counterclockwise by the elastic force of the elastic member 433 and the pressing body 432 presses the tail P1 of the experimental animal P will be fixed

As such, when the tail P1 of the experimental animal P is pressurized and fixed, the user can easily collect blood by inserting the syringe 10 into the tail of the experimental animal P.

4 and 5 are cross-sectional views conceptually showing the structure of the tail fixing means of the mouse holder device according to another embodiment of the present invention.

The tail fixing means 400 according to an embodiment of the present invention is configured to include a lower fixing block 410, an upper fixing block 420 and a tail pressing unit 430 as described above, at this time, the tail pressing A syringe fixing body 440 capable of mounting and fixing the syringe 10 as shown in FIG. 4 may be coupled to the upper portion of the pressure body 432 of the portion 430 .

In the process of exposing the test material particles to the experimental animal (P) put into the holder body 100, the sealed state is maintained through the syringe inlet 310 of the outer cover 300, and the syringe 10 is put inside. Since the operation of the syringe 10 for blood collection is not easy, the syringe fixing body 440 is coupled to the upper portion of the pressing body 432 to guide the injection path of the syringe 10 and at the same time to guide the fixing position. can

A syringe mounting groove 441 is formed in the syringe fixing body 440 so that the front end of the syringe 10 is inserted and mounted, and a needle guide hole 442 through which a syringe needle can be inserted is formed to guide the insertion path of the syringe needle. do. At this time, in the syringe fixing body 440, the syringe needle passes through the needle guide hole 442 and the syringe 10 is inserted and mounted in the syringe mounting groove 441, and the syringe needle is inserted into the tail P1 of the experimental animal P. ) may be formed to be inserted into.

According to this structure, when the user inserts and mounts the syringe 10 into the syringe fixing body 440, the syringe needle is inserted into the tail P1 of the experimental animal P, and in this state, the syringe piston without additional manipulation can be withdrawn to collect blood.

On the other hand, as shown in FIG. 5, the syringe fixing body 440 may be configured to be linearly movable for a certain section. The support sleeve 450 is coupled, and an elastic spring 451 for elastically supporting the syringe fixing body 440 to be upwardly spaced apart from the bottom surface of the support sleeve 450 may be mounted on a lower portion of the support sleeve 450 .

At this time, in the state in which the syringe 10 is inserted and mounted in the syringe fixing body 440, the syringe needle is maintained without being inserted into the tail P1 of the experimental animal P, as shown in FIG. 5, in this state When the syringe 10 is pressed in, the syringe fixing body 440 moves downward along the support sleeve 450, and accordingly, the syringe needle may be configured to be inserted into the tail P1 of the experimental animal P. .

According to this structure, the syringe 10 is first inserted into the syringe fixing body 440 during the blood collection process, and then the syringe 10 is pressed and the syringe needle is inserted into the tail P1 of the experimental animal P. In this way, the insertion process of the syringe needle can be performed more stably and accurately.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: holder body
110: body part
120: nose part
121: communication hall
200: position control panel
210: tail through hole
300: outer cover
310: syringe inlet
400: tail fixing means
410: lower fixed block
420: upper fixed block
430: tail pressing part
431: rotating rod
432: pressurized body
433: elastic member
440: syringe holding body
450: support sleeve

Claims (8)

In the mouse holder device in which the experimental animal is put therein, and is coupled in communication with a separate test material supply chamber so that the injected experimental animal is exposed to the test material particles,
A hollow pipe-shaped body portion so that an experimental animal can be introduced into the internal space, and one end of the body portion in a shape that decreases in diameter toward the front end, and a communication hole is formed at the front end to communicate with the test material supply chamber. a holder body including a nose part;
a position control plate mounted movably in the longitudinal direction on the body portion to fix the internal position of the experimental animal and having a tail passage hole formed in the center to allow the tail of the experimental animal to pass through;
a tail fixing means for fixing the tail of the experimental animal that has passed through the tail passage hole, which is disposed to be located behind the position control plate inside the body part; and
An outer cover sealingly enclosing the outer space of the holder body
Including, a syringe inlet is formed in the outer cover so that a syringe for blood collection can be injected in a sealable state, so that blood can be collected from the tail of the experimental animal fixed through the tail fixing means,
The tail fixing means is
a lower fixing block disposed inside the holder body and formed to seat the tail of the experimental animal on the upper surface;
an upper fixing block disposed above the lower fixing block to guide the position of the tail of the experimental animal seated on the lower fixing block; and
It is mounted on the lower fixed block to be located at the rear of the upper fixed block and includes a tail pressing unit for pressing and fixing the tail of the experimental animal,
The lower fixing block has
A horizontal part formed to form a horizontal plane so that the tail of the experimental animal is seated, and an inclined part extending downwardly from the rear end of the horizontal part are formed,
The upper fixing block is disposed on the upper surface of the horizontal part to guide the position of the tail of the experimental animal, and the tail pressing part is disposed on the inclined part to press and fix the tail of the experimental animal,
The tail pressing part
a rotating rod rotatably coupled to one side of the lower fixed block;
a pressure body coupled to the end of the rotating rod to press the tail of the experimental animal; and
and an elastic member for applying an elastic force to the rotating rod so that the pressing body rotates in a direction in contact with the inclined portion,
A mouse holder device, characterized in that a syringe fixing body capable of mounting and fixing the syringe is coupled to the upper portion of the pressure body.
delete delete The method of claim 1,
A mouse holder device, characterized in that a guide groove is formed on the lower surface of the upper fixing block to limit the range of movement through the tail of the experimental animal.
delete delete delete The method of claim 1,
The syringe fixing body has
A mouse holder device, characterized in that the syringe holder groove in which the syringe can be mounted, and a needle guide hole through which the syringe needle of the syringe can be inserted.

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