JP3148385U - Virus inactivation mask - Google Patents

Abstract

An object of the present invention is to provide a mask for inactivating avian influenza virus. A virus inactivation mask includes an intermediate nonwoven fabric layer 3 in which a nonwoven fabric is impregnated with gluconic acid in which zinc oxide is dissolved. On the front side of the intermediate nonwoven fabric layer 3, an outer nonwoven fabric layer 2 that is in contact with outside air is provided. On the back side of the intermediate nonwoven fabric layer 3, an inner nonwoven fabric layer 4 that is in contact with the skin surface of the nose and mouth is provided. As zinc oxide, zinc oxide nanoparticles having a diameter of 50 nm to 70 nm are used. When the mask according to the present invention was worn on the face, the virus that entered the nostril and the oral cavity from the outside could be efficiently killed. [Selection] Figure 2

Description

  The present invention relates generally to virus inactivation masks, and more particularly to an improved virus inactivation mask so that at least avian influenza virus can be inactivated.

  Conventional masks only physically prevent the passage of particles, for example, by making the eyes of a nonwoven fabric that is a mask base material fine. However, it was not possible to prevent avian influenza virus, cats, dogs, human calicivirus, and norovirus from entering the body through the mouth only by making the nonwoven fabric finer.

  When attention is paid to antibacterial properties, it is known that ultrafine zinc oxide has excellent characteristics. Traditionally, most antibacterial, antifungal and deodorants are organic compounds, which may be problematic in terms of bleed out from the resin and the sustainability of the effect, and may come into contact with the human body or food. The case was difficult to use in terms of safety.

  As an inorganic antibacterial agent, a silver antibacterial agent is generally used. However, it has problems of blackening due to oxidation and elution of silver ions, and is not necessarily universal. On the other hand, since ultrafine zinc oxide is an inorganic compound, there is no problem of bleeding out, it is non-coloring, and a stable effect is maintained. Further, as is apparent from the fact that it is used in cosmetics, anti-inflammatory agents, etc., it is also a great feature that it is highly safe for the human body.

  However, ultrafine zinc oxide has a drawback that it has a small effect on moths other than black mold and ringworm, and there is a problem that it needs to be used according to the purpose.

  An object of the present invention is to provide an improved virus inactivation mask so as to solve the above problems and to inactivate an avian influenza virus.

  The virus inactivation mask according to the present invention relates to a mask that is worn on the face and inactivates at least the avian influenza virus. The virus inactivation mask includes an intermediate nonwoven fabric layer made of a nonwoven fabric to which zinc oxide and / or organic acid is attached. An outer nonwoven fabric layer in contact with the outside air is provided on the front side of the intermediate nonwoven fabric layer. An inner nonwoven fabric layer that contacts the skin surface of the nose and mouth is provided on the back side of the intermediate nonwoven fabric layer.

  By providing the outer nonwoven layer, zinc oxide and / or organic acid adhering to the intermediate nonwoven layer is prevented from scattering to the outside, and by providing the inner nonwoven layer, zinc oxide and / or organic adhered to the intermediate nonwoven layer Acid can prevent entry into the nose and mouth.

  According to the virus inactivation mask according to the present invention, zinc oxide and / or organic acid adheres to the intermediate nonwoven fabric layer. When the mask according to the present invention was worn on the face, viruses entering the nostril and oral cavity from the outside could be efficiently killed. The reason for this is thought to be because the cells of avian influenza virus are destroyed and inactivated by the antibacterial activity of zinc oxide and organic acids.

The zinc oxide preferably contains zinc oxide nanoparticles having a diameter of 50 nm to 70 nm (one nano is one billionth). It is also advantageous that ultrafine zinc oxide dissolves well in organic acids. Metal ions are said to have sterilizing power in the order of Hg>Ag>Cu>Zn>Fe> TiO ₂ , and silver antibacterial agents are generally used. However, by making zinc oxide into ultrafine particles, It has come to show antibacterial properties not inferior to. The antibacterial mechanism of ultrafine zinc oxide is thought to be the same as that of silver ions, and is not due to the toxicity and bactericidal properties of metals. It is thought that some oxygen in the air or water is activated to destroy the cell membrane of the virus. . By using nanoparticles, the specific surface area is increased, the contact on the surface of the virus is expanded, and the growth of the virus is suppressed. Metal ion powder has little elution, high inhibitory effect maintenance and safety, and exhibits antibacterial properties equivalent to silver against viruses that are in direct contact. The virus diameter is 75 nm.

Adhesion amount of the oxide of zinc is preferably a ^{5g / m 2 ~15g / m 2} .

  It is preferable that the nonwoven fabric is impregnated with an organic acid in which zinc oxide is dissolved, and the zinc oxide and the organic acid are adhered to the nonwoven fabric. By doing so, the antibacterial power is further enhanced by the synergistic effect of the organic acid and zinc oxide.

  Preferably, the organic acid includes 30,000 ppm to 50,000 ppm of the zinc oxide in a solid state. By selecting an amount in this range, it is possible to efficiently destroy avian influenza virus cells.

  Gluconic acid is preferably used as the organic acid.

When gluconic acid is dissolved in water, as shown in the following [Chemical Formula 1], a part becomes gluconolactone. This is called equilibrium. The ratio of gluconolactone and gluconic acid varies with temperature, concentration, pH, and the like. When acidified, the amount of acid in water increases, so the proportion of gluconolactone increases. When alkaline, gluconic acid becomes a salt and stabilizes, so the proportion of gluconolactone decreases. Equilibration is like connecting two water tanks with a tube. When water is poured into the left water tank, the water flows to the right through the tube to maintain balance.

Regarding the explanation of the synergistic effect caused by the combined use of zinc oxide and gluconic acid, let us consider the case where gluconic acid touches a protein, avian influenza virus. As shown in [Chemical Formula 2], the protein contains an acidic amino acid and a basic amino acid. Amino acid of the acidic, has a such as -COOH, the negative ion ^- become (COO). Basic amino acids have -NH2 and become positive ions (-NH3 ⁺ ). If there are a lot of positive ions in the protein or a lot of negative ions, the protein will dissolve in water, but if the negative and positive ions are the same (referred to as the isoelectric point), they will be neutral and have no charge. It will not dissolve in. If the virus is set to an isoelectric point, the virus will not melt and will die.

  According to the present invention, it is considered that zinc oxide works synergistically with gluconic acid, adjusts this isoelectric point well, destroys avian influenza virus cells, and inactivates them.

The above non-woven ^{fabric, 30g / m 2 ~50g / m} 2 of PET (polyethylene terephthalate) preferably comprises a spunbonded fabric.

Further, the nonwoven fabric of ^{30g / m 2 ~50g / m 2} , may be 70% and PET30% of混沙nonwoven rayon.

  When the virus inactivation mask according to the present invention was worn on the face, the virus that entered the nostril and the oral cavity from the outside could be efficiently killed.

  For the purpose of obtaining an improved mask that can inactivate avian influenza virus, the mask is composed of at least a three-layer structure including an intermediate nonwoven fabric layer composed of a nonwoven fabric to which zinc oxide and / or organic acid is attached. It was realized by doing. Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a conceptual diagram of a virus inactivation mask according to an embodiment. FIG. 2 is a cross-sectional view of a mask base material constituting the mask. With reference to these drawings, the mask 1 includes an intermediate nonwoven fabric layer 3 formed by impregnating a nonwoven fabric with an organic acid solution in which zinc oxide is dissolved. On the front side of the intermediate nonwoven fabric layer 3, an outer nonwoven fabric layer 2 that is in contact with outside air is provided. On the back side of the intermediate nonwoven fabric layer 3, an inner nonwoven fabric layer 4 that is in contact with the skin surface of the nose and mouth is provided. Nonwoven impregnated with a organic acid solution of zinc oxide is ^{dissolved, 30g / m 2 ~50g / m} 2 of PET (polyethylene terephthalate) spunbond fabric or ^{30g / m 2 ~50g / m 2} , 70% rayon and PET30 % Of blended non-woven fabric. The coating amount of zinc oxide is ^{5g / m 2 ~15g / m 2} . Gluconic acid was used as the organic acid. The gluconic acid solution is an aqueous solution of 40 to 50% by weight and contains 30,000 ppm to 50,000 ppm of zinc oxide in a solid state. As zinc oxide, zinc oxide nanoparticles having a diameter of 50 nm to 70 nm were used.

When the mask according to this example was worn on the face, viruses that entered the nostril and oral cavity from the outside could be efficiently killed. The virus infectivity titer (LOG EID _{50 /} 0.1 ml) was 5.75.

In Example 1, the intermediate nonwoven fabric layer formed by impregnating the nonwoven fabric with an organic acid in which zinc oxide was dissolved was used. However, zinc oxide alone or an organic acid alone has a considerable effect. In the above example, when sterilized distilled water is used instead of gluconic acid, a solution in which zinc oxide nanoparticles are dispersed is adhered to the intermediate nonwoven fabric layer, and the mask is then configured under the same conditions as in Example 1. The virus infectivity titer (LOG EID ₅₀ /0.1 ml) was 7.25.

  Moreover, in the said Example, although gluconic acid was illustrated as an organic acid, this invention is not restricted to this, What synergizes with zinc oxide and destroys a protein film | membrane can be used.

  In the above embodiment, a three-layer structure is illustrated, but the present invention is not limited to this, and a four-layer structure or a multilayer structure having more than that may be used.

  It should be understood that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is indicated not by the above description but by the scope of the utility model registration request, and is intended to include all modifications within the meaning and scope equivalent to the scope of the utility model registration request.

  The present invention provides a mask for inactivation of avian influenza virus.

It is a conceptual diagram of the virus inactivation mask which concerns on an Example. It is sectional drawing of a virus inactivation mask.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Virus inactivation mask 2 Outer nonwoven fabric layer 3 Intermediate nonwoven fabric layer 4 Inner nonwoven fabric layer

Claims (8)

A mask worn on the face to inactivate at least the avian influenza virus,
An intermediate nonwoven fabric layer comprising a nonwoven fabric to which zinc oxide and / or organic acid is attached;
Provided on the front side of the intermediate nonwoven fabric layer, an outer nonwoven fabric layer in contact with the outside air,
A virus inactivation mask comprising an inner nonwoven fabric layer provided on the back side of the intermediate nonwoven fabric layer and in contact with the skin surface of the nose and mouth.   The virus inactivation mask according to claim 1, wherein the zinc oxide includes zinc oxide nanoparticles having a diameter of 50 nm to 70 nm. Adhesion amount of the zinc ^{oxide, 5g / m 2 ~15g / m} 2 viral inactivation mask according to claim 1 or 2.   The virus inactivation mask according to any one of claims 1 to 3, wherein the nonwoven fabric is impregnated with an organic acid in which zinc oxide is dissolved, and the zinc oxide is adhered to the nonwoven fabric.   The virus inactivation mask according to any one of claims 1 to 4, wherein the organic acid contains 30,000 ppm to 50,000 ppm of the zinc oxide in a solid state.   The virus inactivation mask according to any one of claims 1 to 5, wherein the organic acid includes gluconic acid. The non-woven fabric, viral inactivation mask according to claim 1 comprising a PET spunbond fabric ^{30g / m 2 ~50g / m 2} . The non-woven fabric, 30g / m ² ~50g / a m ^2, viral inactivation mask according to claim 1 containing 70% Rayon and PET30% of混沙nonwoven.