KR101598082B1 - Toxicity evaluation device of nano material having dual-chamber - Google Patents

Abstract

The present invention relates to an apparatus for evaluating the toxicity of a nanomaterial, so as to accurately evaluate the toxicity of a nanomaterial in microconcentrations, and to significantly secure the uniformity of concentrations of the nanomaterial present inside the apparatus for evaluating the toxicity. The apparatus comprises: a nanomaterial generation device; a plurality of mouse houses connected to the nanomaterial generation device by transporting pipes for enabling the nanomaterial generated from the nanomaterial generation device to be introduced; transporting pipes of the nanomaterial generated from the nanomaterial generation device, which are individually connected to the mouse houses, respectively; and a plurality of mouse chambers constituted with a dual wall, which are positioned inside the mouse houses.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a nano-

The present invention relates to a plurality of diffusion chambers and a nanoparticle inhalation toxicity evaluating apparatus having the same, and more particularly, to a diffusion chamber and a nanoparticle inhalation toxicity evaluating apparatus, which are required to understand a toxic mechanism of a nanomaterial in vivo, And an apparatus for evaluating the nano-particle inhalation toxicity thereof.

Recently, our society has become a popular paradigm for carbon nanotubes, and nanomaterials have become a well-known and well-known material in everyday life such as tires and coatings. Nanotechnology using nanomaterials refers to the technology of making and manipulating objects at the level of nanometers, where the nanometer is one billionth of a meter (m) It means about one-eighth of the size, which corresponds to about 10 hydrogen atoms arranged side-by-side. Nanotechnology is the realization of Information Technology (IT) and other biotechnology (BT) today by artificially manipulating atomic or molecular ultrafine materials to create materials or devices with new properties and functions. It is recognized as one of the cutting-edge technologies to do this. However, nanotechnology, which is recognized as such a new technology or advanced technology, offers many advantages and benefits to be recognized as a new technology revolution throughout the industrial field, but on the other hand it poses a potential danger. The potential risk is due to the nature of nanotechnology. That is, the smaller the particle, the larger the ratio of the specific surface area. The smaller particles having a larger specific surface area ratio increase the toxicity when reacted with the biotissue. For example, some nanoparticles such as titanium dioxide, carbon powder, Has been revealed through scientific experiments that the toxicity is increased as the size decreases as it causes inflammation. In addition, ultrafine nanoparticles may not penetrate the airways or mucous membranes but may penetrate deep into the alveoli or migrate to the brain. Recent studies have shown that nanoparticles accumulate in the body, causing diseases or central nervous disorders.

When the greatest occlusion of nanoparticles is introduced into the body, 98% is released and 2% is accumulated like heavy metal. Thus, 98% of nanomaterials introduced into the body are released into the body within 48 hours, 2% of the nanomaterials are accumulated in each organ in the body. Therefore, if the nanoparticles accumulated in the body are toxic substances, they will have a very lethal effect on the human body. Thus, techniques for assessing the toxicity of such nanomaterials are of considerable importance and are of great interest to those skilled in the art, including air compressors, regulators, HEPA filters, particle generators, heating driers, ionizers, dilution chambers, diffusion driers, exposure chamber devices, , Etc. have been developed. This is the most used animal animal. It is designed to fit the volume of mice by selecting mice among rodents that have a lot of related data and are easy to handle. In order to evaluate the inhalation toxicity of nano particles in vivo It is a device designed.

For example, FIG. 1 illustrates an exposure chamber device of a conventional system for assessing nanoparticle inhalation toxicity, wherein an exposure chamber device 10 has an experimental material outlet 11 formed thereon and an experimental material inlet 12 A hollow vertical exposure chamber 14 having a plurality of mouse holder engagement holes 13 formed on the side surface thereof and a mouse holder 20 coupled to the mouse holder engagement hole 13. The exposure chamber device 10 is a device configuration that is indispensable to the toxicity test of environmental pollutants and the safety confirmation test of other medicines or pesticides. This is because the mouse holder 20, into which an experimental animal (rat, (Not shown) made of activated carbon and a filter, and other power supply means (not shown), and the like.

However, the conventional exposure chamber device is a portion where the inside of the exposure chamber and the mouse holder are coupled, and the diameter of the portion exposed to the experimental animal is narrowed, so that the flow rate of the test material flowing from the exposure chamber to the mouse holder side is relatively increased , Which affects the respiratory activity of laboratory animals, poses a problem that causes inadequate inhalation toxicity assessment. In addition, there is a problem that it is difficult to disperse due to the nature of the nanomaterial, and it is difficult for the nanomaterial to be uniformly distributed in the toxicity evaluation device, resulting in a considerable error in the toxicity evaluation. In addition, as shown in FIG. 2, a conventional mouse holder has a space in which a nanomaterial is allowed to flow out to the outside, and is used only under either a Nose-only condition or a Whole-Body condition. There has been an inconvenience that a separate apparatus should be provided.

In order to solve the above problems, the present invention provides a nanomaterial generating device comprising a nano powder mixed with water vapor, a transfer chamber for uniformly transferring nanomaterials to individual mousehouses, a mouse chamber composed of double walls, The object of the present invention is to minimize the error of the toxicity evaluation by distributing the nanomaterials in a uniform concentration in the toxicity evaluation apparatus using a mouse house composed of a plurality of mouse chambers.

It is also aimed at constructing a holder that minimizes the stress of the mouse during a 90-day evaluation period through a holder optimized for the body shape of the mouse.

In order to achieve the above object, the present invention provides a nanomaterial toxicity evaluating apparatus comprising: a nanomaterial generating apparatus for generating nanomaterials using powder-type nanomaterials and water vapor; A plurality of mousehouses; A plurality of transfer tubes for individually connecting the nanomaterial generating device and the plurality of mousehouses so that nanomaterials generated from the nanomaterial generating device are introduced into the plurality of mousehouses; And a plurality of mouse chambers provided in the mousehouse, wherein the mouse chamber comprises: an external mixing chamber having a nanomaterial inlet through which the nanomaterial supplied from the mousehouse flows; An inner chamber provided in the outer mixing chamber in which the fixing plate is installed, and a nanomaterial supplied to the nanomaterial inlet are mixed at a uniform concentration, and the diffusion chamber is provided between the outer mixing chamber and the inner chamber, And a plurality of mouse chambers having a double wall.

The present invention has been made in view of the above-described problems, and it is an object of the present invention to provide a method and an apparatus for measuring the concentration of nanomaterials in a mouse chamber, The concentration difference of the nanomaterials that can be generated in each mouse house is minimized and the nanomaterial introduced into the mouse chamber in which the mouse is placed is not incorporated into the mouse immediately after the introduction but mixed at a uniform concentration in the mixing chamber, Thereby minimizing the concentration difference, thereby improving the accuracy of the toxicity evaluation of the nanomaterial.

In addition, the mouse holder and the chamber, which could be used only under either the Nose-Only condition or the Whole-Body condition, can be configured to be used in both conditions.

Figure 1 shows a conventional nanomaterial toxicity evaluation device.
Figure 2 shows the structure of a conventional mouse chamber.
Fig. 3 shows the constitution of the nanomaterial toxicity evaluation apparatus of the present invention.
4 shows a mouse chamber configuration of the present invention.
5 shows a holder configuration of a mouse chamber of the present invention.

The nanomaterial toxicity evaluating apparatus of the present invention can be used as a scanning particle analyzer including an air computer, a regulator, a heparin filter, a particle generator, an ionizer, a dilution chamber, an exposure chamber device, a diffusion drier, a condensation particle counter, A mass flowmeter, a pump, and a dust collector. These devices are well known in the art, and their detailed description will be omitted.

First, the compressed air of the air compressor is controlled by a regulator to adjust the pressure and the amount of the discharged air, and then the controlled The compressed air is passed through the HEPA filter to the particle generator. The aerosol generated through the particle generator becomes charged and neutralizes ionization by a subsequent ionizer (not shown). The neutralized aerosol is delivered to a dilution chamber for dilution, and the aerosol thus delivered is mixed with clean air outside the dilution chamber and diluted to pass through a diffusion drier (not shown) (Not shown) is introduced into the exposure chamber device and exposed to an animal experiment. The aerosol introduced into the exposure chamber device is injected into the exposure chamber device through a scanning moving particle measuring device, that is, a condensation particle counter and an electrostatic powder separator, Is monitored.

Meanwhile, the flow rate of the exposure chamber device is maintained constant using a mass flow meter, and the air is supplied using a pump. The aerosol that has passed through the exposure chamber device passes through a HEPA filter (not shown) and enters a suction port of the dust collector, and is filtered by a filter to be finally discharged.

< Example >

Hereinafter, an exposure chamber device according to an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 3 shows the structure of a nanomaterial toxicity evaluation apparatus of the present invention. FIG. 4 shows the structure of a mouse chamber of the present invention, and FIG. 5 shows the structure of a holder in the mouse chamber of the present invention.

3, the nanomaterial toxicity evaluation apparatus 100 includes a plurality of mousehouses 110 and a plurality of mouse chambers 120 located in the mousehouses 110 . The mouse house 110 is configured such that a plurality of mice can be positioned vertically, such as an apartment, so that a maximum number of mice can be experimented in a narrow space. In the embodiment of the present invention, the mouse house 110 is basically formed in a circular shape, but the shape is not limited to a square shape, a rectangular shape, a hexagonal shape, an octagonal shape, and the like. 3, a nanomaterial transfer tube 60 is connected to the upper part of the mouse house 110, in which nanomaterials generated from the nanomaterial generator 50 can be transferred to the respective mousehouses 110, as shown in FIG. In the conventional apparatus, the nanomaterials generated from the nanomaterial generating apparatus are configured to be sequentially introduced, while the nanomaterials of the present invention are introduced through the respective transfer tubes, so that the variables affecting the accurate concentration estimation can be blocked in advance Respectively. Although not shown in FIG. 3, a mass flow meter may be attached to each of the nanomaterial transfer tubes 60 to enhance the accuracy of such concentration calculation. A connector 111 is formed on a side surface of the mouse house 110 so that a plurality of mouse chambers 120 can be connected. In the embodiment of the present invention, the connector has a screw-type connection type, but this configuration uses a configuration that is commonly used.

The nanomaterials generated from the nanomaterial generating device 50 are transferred to the mouse house 110 through the nanomaterial transfer pipe 60 connected to the respective mouse houses 110, (120). The mouse chamber 120 of FIG. 4 includes a nanomaterial inlet 121 through which the nanomaterial enters, a diffusion zone 122 through which the introduced nanomaterial is not immediately drawn into the mouse and diffuses at a constant concentration, And an inner chamber inlet 124 for entering the inner chamber 123. The mouse is positioned inside the inner chamber 123.

5 shows a configuration of a mouse holder inside the inner chamber 123. In the conventional mouse holder of the Nose-only type, the front of the nose of the mouse is closely contacted with the hole of the toxic substance inlet to fix the rat with the support rod at the rear end, Exposed to the tail of the toxicity test to see whether the mouse is made up of the structure is visible. In order to solve this problem, the structure of the mouse holder is configured as a chamber type in order to suck the closure of the nanomaterial into the mouse in order to improve the disadvantage that the toxic substance escapes from the tail exposed portion of the mouse. In addition, although the conventional mouse holder can be used only in the nose-only condition, the present invention can be used in the whole-body condition. Whole-body, unlike Nose-only, does not need to be fully immobilized by performing tests under conditions that are somewhat active in the mouse. With this in mind, the circular fixing plate 200 is moved to a single mouse holder as shown in FIG. 5, so that the whole body and the Nose-only condition can be satisfied. The circular fixing plate 200 is separated from the mouse holder cap 210 so that it can be moved. Therefore, the circular fixing plate 200 can be tested under two conditions only with one mouse holder main body. When the circular fixing plate 200 is placed in the mouse head of the mouse holder, the mouse can not be used as a whole body because the rat does not approach the toxic substance inlet. When the circular fixing plate is located at the tail portion of the mouse, Nose-only testing is possible because the nose is accessible to the toxic substance inflow.

50: Nano material generating device 60: Nano material conveying pipe
100: Nano material toxicity evaluation device 110: Mouse house
111: connector 120: mouse chamber
121: nanomaterial inlet 122: diffusion zone
123: inner chamber 124: inner chamber inlet
200: circular fixing plate 210: mouse holder cap
10: Exposure chamber device 11: Test material outlet
12: Experimental substance inlet 13: Mouse holder coupling hole
14: vertical exposure chamber 20: mouse holder

Claims (3)

A nanomaterial generating device that generates nanomaterials using powder-type nanomaterials and water vapor;
A plurality of mousehouses;
A plurality of transfer tubes for individually connecting the nanomaterial generating device and the plurality of mousehouses so that nanomaterials generated from the nanomaterial generating device are introduced into the plurality of mousehouses; And
And a plurality of mouse chambers provided in the mousehouse,
Wherein the mouse chamber comprises an external mixing chamber having a nanomaterial inlet through which the nanomaterial supplied from the mousehouse flows, an internal chamber provided inside the external mixing chamber in which a circular fixing plate movable apart from the mouse holder cap is incorporated, And a plurality of mouse chambers having a double wall having a diffusion zone between the outer mixing chamber and the inner chamber so that nanomaterials supplied to the nanomaterial inlet may be mixed at a uniform concentration and moved to the inner chamber Characterized by a nanomaterial toxicity assessment device. delete delete

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