JP6889925B2 - Virus inactivating agents, norovirus inactivating agents and sanitary materials - Google Patents

Description

The present invention relates to a virus inactivating agent, a norovirus inactivating agent and a sanitary material.

Viruses include enveloped viruses (eg, influenza virus) and non-enveloped non-enveloped viruses (eg, norovirus).
Some of these viruses infect humans, and virus inactivating agents have been conventionally used to prevent infection.

In recent years, outbreaks of infectious gastroenteritis or food poisoning due to norovirus (human norovirus) have frequently occurred throughout the year, and the peak of the outbreak is from 11 to March. Norovirus is an non-enveloped RNA virus (hereinafter referred to as "norovirus, etc.") classified into Caliciviridae and Norovirus genus, and is alcohol (ethanol, isopropanol, etc.), heat, acidic (stomach acid, etc.), or Has strong resistance to drying and the like. The latency period is considered to be 1 to 2 days, and the main symptoms of vomiting, vomiting, and diarrhea appear, but it may be accompanied by abdominal pain, headache, fever, chills, myalgia, sore throat, and malaise.

Oral infection is known as one of the infection routes of norovirus and the like, and infection is established by ingesting food or water contaminated with norovirus or the like.
Therefore, in places such as restaurants, school lunch facilities, and factories where food is cooked and processed, it is required to prevent food, water, and the like from being contaminated by norovirus and the like.

As a means for preventing contamination by norovirus and the like, there is a method of inactivating norovirus in foods, tableware, countertops, kitchen utensils and the like.
Heat treatment is known as a method for completely inactivating norovirus and the like.
However, it is not realistic to always heat-treat tableware, cooking tables, cooking utensils, etc. in places such as restaurants, feeding facilities, factories, etc. where food is cooked, and depending on the type of food, the flavor is impaired by the heat treatment. It may be lost. That is, the heat treatment is not suitable as a method for inactivating norovirus and the like in places such as restaurants, school lunch facilities, and factories where food is cooked and processed.

Further, as a method for inactivating norovirus or the like, a method using a chlorine bleach (sodium hypochlorite or the like) is also known. However, chlorine bleach has a corrosive effect on metals, an irritating effect on skin and the like, and a bleaching effect on clothing. Therefore, there is a drawback that its use is restricted, and in particular, it is not appropriate to use these chemicals on the fingers, tableware, countertops, cooking utensils, etc. of workers in consideration of safety for the human body. It was not appropriate to let them come into direct contact with food.
Therefore, a method that is safe for the human body and can inactivate norovirus and the like has been desired.

Human norovirus cannot be propagated using cultured cells.
Therefore, feline calicivirus (FCV) and murine norovirus (MNV) are widely used as alternative viruses for verifying the disinfecting effect of various disinfectants and the like on the inactivation of human norovirus. FCV and MNV have been clarified as viruses closely related to human norovirus from their morphological characteristics and genomic structure.

For example, Non-Patent Document 1 describes an inactivation test of FCV and MNV using a neutral or acidic virus inactivating agent containing ethanol as a main component.

GEUN WOO Park et al., J Food Protection 2010 No; Vol. 73: 2232-2238 “Comparative effect of seven hands genist murine norovirus, feline calicivirus, and GII.4 norovirus”

The virus inactivating agents described in Non-Patent Document 1 show some effect on FCV and MNV in tests at the laboratory level.
However, when such a virus inactivating agent is actually used in restaurants, school lunch facilities, factories, etc., it has not been able to show a sufficient virus inactivating effect.

It was considered that the cause of the insufficient effect of the virus inactivating agent was environmental stains, especially protein stains.
Protein stains in the environment will adhere to the surroundings of the virus. The protein stains around the virus are thought to act like a protective film on the virus, preventing ethanol and other inactivating components from coming into contact with the virus.
Therefore, it is considered that the virus inactivating agent as described in Non-Patent Document 1 cannot fully exert its effect.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a virus inactivating agent that exhibits a sufficient virus inactivating action even in the presence of protein stains.

That is, the virus inactivating agent of the present invention is a virus inactivating agent containing ethanol, a carbonate, and an acid agent, and the mass concentration of the carbonate in the virus inactivating agent is 0. It is characterized in that it exceeds .10% by weight and is less than 8.00% by weight.

The virus inactivating agent of the present invention contains ethanol.
The virus can be inactivated by contacting the virus with ethanol.

The virus inactivating agent of the present invention contains a carbonate.
Carbonate is considered to have the effect of separating protein stains from the surroundings of the virus by salting out the protein stains in the environment.
Once the protein stains have been separated from the virus' surroundings, the virus is in direct contact with ethanol and other inactivating components. Therefore, the virus is inactivated. In addition, it is considered that carbonate promotes contact between the virus and ethanol and other inactivating components even when there is no protein contamination in the environment, and enhances the virus inactivating action.

The mass concentration of carbonate in the virus inactivating agent of the present invention is more than 0.10% by weight and less than 8.00% by weight.
When the mass concentration of carbonate in the virus inactivating agent is 0.10% by weight or less, the action of separating protein stains from the surroundings of the virus is not sufficiently exerted.
When the mass concentration of the carbonate in the virus inactivating agent is 8.00% by weight or more, the carbonate is likely to precipitate. In addition, the part where the virus inactivating agent is used becomes sticky or easily leaves a mark.

The virus inactivating agent of the present invention contains an acid agent. The acid agent has an effect of enhancing the virus inactivating action of the virus inactivating agent containing ethanol and carbonate.

In the virus inactivating agent of the present invention, it is desirable that the carbonate is at least one selected from the group consisting of sodium carbonate, potassium carbonate and ammonium carbonate.
These carbonates have a strong effect of separating protein stains from the surroundings of the virus.

In the virus inactivating agent of the present invention, the acid agent may contain at least one selected from the group consisting of citric acid, malic acid, lactic acid, phosphoric acid, tartaric acid, adipic acid, succinic acid and phytic acid. desirable.
These acid agents are particularly effective in enhancing the virus inactivating action of the virus inactivating agent containing ethanol and carbonate.

In the virus inactivating agent of the present invention, the mass concentration of the ethanol in the virus inactivating agent is preferably 8.05 to 85.70% by weight.
When the mass concentration of ethanol in the virus inactivating agent is less than 8.05% by weight, the concentration of ethanol is low, so that the virus inactivating action due to the inclusion of ethanol is less likely to be exhibited.
If the mass concentration of ethanol in the virus inactivating agent exceeds 85.70% by weight, the concentration of ethanol in the virus inactivating agent is too high and it becomes easy to catch fire.

In the virus inactivating agent of the present invention, the mass concentration of the acid agent in the virus inactivating agent is preferably 0.01 to 5.00% by weight.
If the mass concentration of the acid agent in the virus inactivating agent is less than 0.01% by weight, the concentration of the acid agent is too low, and it becomes difficult to sufficiently enhance the virus inactivating action of ethanol.
If the mass concentration of the acid agent in the virus inactivating agent exceeds 5.00% by weight, the concentration of the acid agent is too high, and when the virus inactivating agent is sprayed, it becomes sticky and the acid becomes sticky. Precipitation of the agent is likely to occur. In addition, the pH tends to be low, and irritation appears when it is used on the body or when it adheres to the body.

In the virus inactivating agent of the present invention, the pH of the virus inactivating agent may be 6 to 12.
The virus inactivating agent of the present invention exhibits an excellent virus inactivating effect in the neutral to alkaline range.

The norovirus inactivating agent of the present invention is characterized by comprising the above-mentioned virus inactivating agent of the present invention.
The virus inactivating agent of the present invention exhibits a high virus inactivating effect on norovirus.

The sanitary material of the present invention is characterized by containing the above-mentioned virus inactivating agent of the present invention or the above-mentioned norovirus inactivating agent of the present invention.
Since the virus inactivating agent or norovirus inactivating agent of the present invention exhibits a virus inactivating action, virus infection can be prevented by using the sanitary material of the present invention containing such a virus inactivating agent. Can be done.

The virus inactivating agent of the present invention exhibits a sufficient virus inactivating action because it can salt out proteins and bring ethanol into contact with the virus even in the presence of protein stains.

Hereinafter, the virus inactivating agent of the present invention will be described while showing specific embodiments. However, the present invention is not limited to the following embodiments, and can be appropriately modified and applied without changing the gist of the present invention.

The virus inactivating agent of the present invention is a virus inactivating agent containing ethanol, a carbonate and an acid agent, and the mass concentration of the carbonate in the virus inactivating agent is 0.10. It is characterized in that it exceeds the weight% and is less than 8.00% by weight.

The virus inactivating agent of the present invention contains ethanol.
The virus can be inactivated by contacting the virus with ethanol.

In the virus inactivating agent of the present invention, the mass concentration of ethanol in the virus inactivating agent is preferably 8.05 to 85.70% by weight, preferably 24.69 to 74.70% by weight. Is more desirable, and is even more desirable to be 33.38 to 60.00% by weight.
When the mass concentration of ethanol in the virus inactivating agent is less than 8.05% by weight, the concentration of ethanol is low, so that the virus inactivating action due to the inclusion of ethanol is less likely to be exhibited.
If the mass concentration of ethanol in the virus inactivating agent exceeds 85.70% by weight, the concentration of ethanol in the virus inactivating agent is too high and it becomes easy to catch fire.

The virus inactivating agent of the present invention contains a carbonate.
Carbonate is considered to have the effect of separating protein stains from the surroundings of the virus by salting out the protein stains in the environment.
Once the protein stains have been separated from the virus' surroundings, the virus is in direct contact with ethanol and other inactivating components. Therefore, the virus is inactivated. In addition, it is considered that carbonate promotes contact between the virus and ethanol and other inactivating components even when there is no protein contamination in the environment, and enhances the virus inactivating action.

The mass concentration of carbonate in the virus inactivating agent of the present invention is more than 0.10% by weight and less than 8.00% by weight. The mass concentration of carbonate is preferably 0.15 to 5.00% by weight.
When the mass concentration of carbonate in the virus inactivating agent is 0.10% by weight or less, the action of separating protein stains from the surroundings of the virus is not sufficiently exerted.
When the mass concentration of the carbonate in the virus inactivating agent is 8.00% by weight or more, the carbonate is likely to precipitate. In addition, the part where the virus inactivating agent is used becomes sticky or easily leaves a mark.

The carbonate is not particularly limited, but it is desirable that it is at least one selected from the group consisting of sodium carbonate, potassium carbonate and ammonium carbonate.
These carbonates have a strong effect of separating protein stains from the surroundings of the virus.
The virus inactivating agent of the present invention may contain only one type of these carbonates, or may contain a plurality of types.

The virus inactivating agent of the present invention may contain an inorganic salt in addition to the carbonate.
Examples of such inorganic salts include sodium chloride, potassium chloride, magnesium chloride, calcium chloride, ammonium chloride, sodium bromide, potassium bromide, calcium bromide, sodium sulfate, potassium sulfate, magnesium sulfate, ammonium sulfate, iron sulfate, and sulfuric acid. Examples thereof include copper, potassium aluminum sulfate, ammonium aluminum sulfate, sodium nitrate, potassium nitrate, ammonium nitrate, sodium nitrite, potassium nitrite, ammonium nitrite, sodium thiocyanate, potassium thiocyanate, ammonium thiocyanate, sodium iodide and the like.
When the virus inactivating agent contains these inorganic salts, the action of separating protein stains from the surroundings of the virus can be enhanced.
The virus inactivating agent of the present invention may contain only one type of these inorganic salts, or may contain a plurality of types.

The virus inactivating agent of the present invention contains an acid agent. The acid agent exhibits the effect of enhancing the virus inactivating action of the virus inactivating agent containing ethanol and carbonate.

The virus inactivating agent of the present invention preferably contains, as an acid agent, at least one selected from the group consisting of citric acid, malic acid, lactic acid, phosphoric acid, tartaric acid, adipic acid, succinic acid and phytic acid. ..
These acid agents are particularly effective in enhancing the virus inactivating action of the virus inactivating agent containing ethanol and carbonate.
The virus inactivating agent of the present invention may contain only one type of these acid agents, or may contain a plurality of types.

In the virus inactivating agent of the present invention, the mass concentration of the acid agent in the virus inactivating agent is preferably 0.01 to 5.00% by weight, preferably 0.10 to 3.00% by weight. Is more desirable.
If the mass concentration of the acid agent in the virus inactivating agent is less than 0.01% by weight, the concentration of the acid agent is too low, and it becomes difficult to sufficiently enhance the virus inactivating action of ethanol.
If the mass concentration of the acid agent in the virus inactivating agent exceeds 5.00% by weight, the concentration of the acid agent is too high, and when the virus inactivating agent is sprayed, it becomes sticky and the acid becomes sticky. Precipitation of the agent is likely to occur. In addition, the pH tends to be low, and irritation appears when it is used on the body or when it adheres to the body.

In the virus inactivating agent of the present invention, the pH is not particularly limited and may be, for example, 6 to 12.
The virus inactivating agent of the present invention exhibits an excellent virus inactivating effect in the neutral to alkaline range.

In particular, the virus inactivating agent of the present invention preferably has a pH of 8 to 12.
Some noroviruses contain ethanol and antacids and are resistant to neutral to alkaline virus inactivating agents (eg, feline calicivirus).
Therefore, the virus inactivating agent is generally used in an acidic state.
However, when the virus inactivating agent is acidic, there is a problem that it is highly irritating to the skin.
Since the virus inactivating agent of the present invention contains a carbonate, it exhibits a sufficient virus inactivating effect even at a pH of 8 to 12. In addition, the skin irritation of the virus inactivating agent is sufficiently reduced.
The pH can be adjusted by adjusting the mass concentration of the acid agent and carbonate contained in the virus inactivating agent of the present invention. Further, the pH may be adjusted by using a pH adjusting agent.

The virus inactivating agent of the present invention exhibits a virus inactivating effect against enveloped viruses such as influenza virus and non-enveloped viruses such as norovirus.
In particular, the virus inactivating agent of the present invention exhibits a high virus inactivating effect on norovirus.
Therefore, it is desirable that the virus inactivating agent of the present invention be used as a norovirus inactivating agent.
In addition, in this specification, a "norovirus inactivating agent" is a virus inactivating agent used for at least one virus selected from the group consisting of feline calicivirus, murine norovirus and human norovirus. means.

In the virus inactivating agent of the present invention, in the measurement of feline calicivirus infection titer in the presence of the following protein stains using feline calicivirus as a test virus, the value of the virus infection titer (log) at the action time of 1 minute is the action time. It is desirable that it is 2.0 or more smaller than the value of virus infectivity (log) at 0 minutes, and more preferably 4.0 or more.
When the virus inactivating agent of the present invention exerts such a virus inactivating action, infection with a Caliciviridae virus can be prevented.

(Measurement of feline calicivirus infection titer in the presence of protein stains)
(1) The feline calicivirus is infected with CRFK cells (ATCC CCL-94), which are cells derived from the feline kidney, and the cells are cultured.
(2) Next, it is confirmed by the cytopathic effect (CPE) whether or not the feline calicivirus is infected.
After confirming the cytopathic effect, the cultured cells are disrupted by repeating freezing and thawing of the cultured cells.
(3) 0.1 g of beef extract (manufactured by Nacalai Tesque) was dissolved in OPTI-MEM medium to prepare a 10% meat extract solution, and the supernatant of the cultured cell crushed solution after centrifugation and the 10% meat extract were used. Are mixed at a ratio (volume) of 1: 1 to prepare a virus solution.
(4) The virus inactivating agent is mixed with the virus solution at a ratio (volume) of 9: 1, and after 1 minute at room temperature, the virus inactivating agent is diluted 100-fold with OPTI-MEM medium. Stops the action of the virus on the virus.
The solution obtained by this step is used as a virus solution acting on the virus inactivating agent for 1 minute.
(5) Immediately after mixing OPTI-MEM medium and virus solution at a ratio (volume) of 9: 1, the obtained solution was diluted 100-fold with OPTI-MEM medium, and the virus inactivating agent was used for 0 minutes. Acting virus solution.
(6) The virus inactivating agent 0-minute action virus solution and the virus inactivating agent 1-minute action virus solution are diluted 10-fold with OPTI-MEM medium, respectively. Discard the medium of the 96-well microplate in which the CRFK cells have been cultured, and add 100 μL of the serial diluent.
(7) Virus inactivating agent 0-minute action CRFK cells to which a serially diluted solution of a virus solution and a virus inactivating agent 1-minute action virus solution have been added are cultured at 37 ° C. and 5% CO ₂ for 4 days. ..
(8) Using the CPE of cultured CRFK cells as an index, the virus infectivity titer (logarithm) of each virus solution is quantified by _{TCID 50 (Tissue Culture Infectious Dose 50%).}
(9) The above steps (1) to (8) are independently performed three times, and the average value of the virus infectious titer calculated using the virus inactivating agent 0-minute action virus solution is taken at the action time of 0 minutes. The virus infectivity titer is defined as the average value of the virus infectivity titer calculated using the virus inactivating agent 1-minute action virus solution, and the value of the virus infectivity titer in the action time of 1 minute is used.

In the virus inactivating agent of the present invention, in the measurement of the infectivity of mouse norovirus in the presence of the following protein stain using mouse norovirus as a test virus, the value of the virus infectivity (log) at the action time of 1 minute is 0 minutes of action time. It is desirable that it is 2.0 or more smaller than the value of virus infectivity (log) in, and it is more desirable that it is 4.0 or more smaller.
When the virus inactivating agent of the present invention exerts such a virus inactivating action, infection with a Caliciviridae virus can be prevented.

(Measurement of murine norovirus infection titer in the presence of protein stains)
(1) Murine norovirus is infected with RAW 264.7 cells (ATCC TIB-71), which is a mouse macrophage-derived cell line, and the cells are cultured.
(2) Next, it is confirmed by the cytopathic effect (CPE) whether or not the mouse norovirus is infected.
After confirming the cytopathic effect, the cultured cells are disrupted by repeating freezing and thawing of the cultured cells.
(3) 0.1 g of beef extract (manufactured by Nacalai Tesque) was dissolved in DMEM medium to prepare a 10% meat extract solution, and the supernatant of the cultured cell crushed solution after centrifugation and the 10% meat extract were 1 Mix at a ratio (volume) of 1 to make a virus solution.
(4) The virus is mixed by mixing the virus inactivating agent and the virus solution at a ratio (volume) of 9: 1, and after 1 minute at room temperature, diluting the virus 100-fold with DMEM medium containing 10% fetal bovine serum. Stops the action of the inactivating agent on the virus.
The solution obtained by this step is used as a virus solution acting on the virus inactivating agent for 1 minute.
(5) Immediately after mixing 10% fetal bovine serum-containing DMEM medium and virus solution at a ratio (volume) of 9: 1, the solution obtained by diluting 100-fold with 10% fetal bovine serum-containing DMEM medium. Is a virus inactivating agent 0 minute action virus solution.
(6) The virus inactivating agent 0-minute action virus solution and the virus inactivating agent 1-minute action virus solution are diluted 10-fold with DMEM medium containing 10% fetal bovine serum, respectively. 50 μL of each serial diluent is added to a 96-well microplate in which 50 μL of RAW 264.7 cells are dispensed into 1 well.
(7) Virus inactivating agent 0-minute action Virus solution and virus inactivating agent 1-minute action RAW 264.7 cells to which a serially diluted solution of the virus solution was added were subjected to 4 _{at 37 ° C. and 5% CO 2.} Incubate for days.
(8) Using the CPE of cultured RAW 264.7 cells as an index, the virus infectivity titer (logarithm) of each virus solution is quantified by _{TCID 50 (Tissue Culture Infectious Dose 50%).}
(9) The above steps (1) to (8) are independently performed three times, and the average value of the virus infectious titer calculated using the virus inactivating agent 0-minute action virus solution is taken at the action time of 0 minutes. The virus infectivity titer is defined as the average value of the virus infectivity titer calculated using the virus inactivating agent 1-minute action virus solution, and the value of the virus infectivity titer in the action time of 1 minute is used.

In the virus inactivating agent of the present invention, in the measurement of influenza virus infectivity titer in the presence of the following protein stains using influenza virus as a test virus, the value of virus infectivity (log) at action time of 1 minute is 0 minutes of action time. It is desirable that it is 2.0 or more smaller than the value of virus infectivity (log) in, and it is more desirable that it is 4.0 or more smaller.
When the virus inactivating agent of the present invention exerts such a virus inactivating action, influenza virus infection can be prevented.

(Measurement of influenza virus infection titer in the presence of protein stains)
(1) The influenza virus is infected with MDCK cells, which are cell lines derived from canine renal tubular epithelial cells, and the cells are cultured.
(2) Next, it is confirmed by the cytopathic effect (CPE) whether or not the influenza virus is infected.
After confirming the cytopathic effect, the cultured cells are disrupted by repeating freezing and thawing of the cultured cells.
(3) 0.1 g of beef extract (manufactured by Nacalai Tesque) was dissolved in EMEM medium to prepare a 10% meat extract solution, and the supernatant of the cultured cell crushed solution after centrifugation and the 10% meat extract were 1 Mix at a ratio (volume) of 1 to make a virus solution.
(4) The virus inactivating agent and the virus solution are mixed at a ratio (volume) of 9: 1, and after 1 minute has passed at room temperature, EMEM medium containing 2 μg / mL trypsin (crystals derived from bovine spleen) (hereinafter, By diluting 100-fold with trypsin-containing EMEM medium), the action of the virus inactivating agent on the virus is stopped.
The solution obtained by this step is used as a virus solution acting on the virus inactivating agent for 1 minute.
(5) Immediately after mixing the trypsin-containing EMEM medium and the virus solution at a ratio (volume) of 9: 1, the solution obtained by diluting the trypsin-containing EMEM medium 100-fold is used as a virus inactivating agent for 0 minutes. Acting virus solution.
(6) The virus inactivating agent 0-minute action virus solution and the virus inactivating agent 1-minute action virus solution are diluted 10-fold with EMEM medium containing trypsin, respectively. Discard the 96-well microplate medium in which MDCK cells are cultured and add 100 μL of the serial diluent.
(7) Virus inactivating agent 0 minute action MDCK cells to which a serially diluted solution of virus solution and virus inactivating agent 1 minute action virus solution are added are cultured at 37 ° C. under _{the condition of 5% CO 2} for 4 days. ..
(8) Using the CPE of cultured MDCK cells as an index, the virus infectivity titer (logarithm) of each virus solution is quantified by _{TCID 50 (Tissue Culture Infectius Dose 50%).}
(9) The above steps (1) to (8) are independently performed three times, and the average value of the virus infectious titer calculated using the virus inactivating agent 0-minute action virus solution is taken at the action time of 0 minutes. The virus infectivity titer is defined as the average value of the virus infectivity titer calculated using the virus inactivating agent 1-minute action virus solution, and the value of the virus infectivity titer in the action time of 1 minute is used.

The virus inactivating agent of the present invention may further contain a flocculant.
Examples of the flocculant include polyglutamic acid and salts thereof.
The flocculant can aggregate protein stains in the environment and can separate protein stains from the surroundings of the virus.
Once the protein stains have been separated from the virus' surroundings, ethanol is in direct contact with the virus. Therefore, the virus is inactivated by the action of ethanol.

The virus inactivating agent of the present invention may further contain a glycerin fatty acid ester or the like.
The glycerin fatty acid ester may be a monoglycerin fatty acid ester or a polyglycerin fatty acid ester. For example, monoglycerin caprylic acid ester, monoglycerin capric acid ester, monoglycerin lauric acid ester, diglycerin capric acid ester, hexaglycerin lauric acid ester, decaglycerin lauric acid ester and the like can be mentioned.

The virus inactivating agent of the present invention may further contain a compound having a virus inactivating action.
Examples of such compounds include green tea extract, purple tea extract, makiberry extract, grape extract, kankanikujuyo extract, evening primrose seed extract, oolong tea extract, peanut seed coat extract, and bilberry extract. , Natural product extracts such as seaweed extracts extracted from seaweeds of the Hibamata family.

In addition to the above components, the virus inactivating agent of the present invention may contain a moisturizer, an emollient, a fragrance, a pigment, a cationic surfactant, a thickener, an anti-inflammatory agent and the like.

Next, the use of the virus inactivating agent of the present invention and the norovirus inactivating agent of the present invention will be described.
The virus inactivating agent of the present invention or the norovirus inactivating agent of the present invention may be added to a hand-washing solution, a neutral detergent, or a deodorant.
The virus inactivating agent of the present invention, or a hand-washing solution containing the norovirus inactivating agent of the present invention, a neutral detergent, a deodorant, or the like may be packed in a pump bottle or a spray gun.

It may also be used as a sanitary material. Such sanitary materials are also sanitary materials of the present invention.

The sanitary material of the present invention is characterized by containing the above-mentioned virus inactivating agent of the present invention or the above-mentioned norovirus inactivating agent of the present invention.
Since the virus inactivating agent of the present invention exerts a virus inactivating action, virus infection can be prevented by using a sanitary material containing such a virus inactivating agent.

The sanitary material of the present invention is not particularly limited, and examples thereof include masks, disposable gloves, disposable cloths, tissue paper, and wet tissues.

Examples of the present invention will be described in more detail below, but the present invention is not limited to these examples.

(Example 1)
These compounds were mixed with water so that ethanol was 50.18% by weight, sodium carbonate was 1.00% by weight, citric acid was 0.60% by weight, and sodium citrate was 0.01% by weight. The virus inactivating agent according to Example 1 was prepared.

(Examples 2 to 8) and (Comparative Examples 1 to 8)
The virus inactivating agents according to Examples 2 to 8 and Comparative Examples 1 to 8 were prepared in the same manner as in Example 1 except that the types and proportions of the materials of the virus inactivating agent were changed as shown in Table 1. ..
In addition, "%" in Table 1 means weight%.

(Measurement of feline calicivirus infection titer in the presence of protein stains)
As the virus inactivating agent, the virus inactivating agent according to each Example and each Comparative Example was used, and based on the above method (measurement of feline calicivirus infection titer in the presence of protein stains), virus infection with an action time of 0 minutes. The difference between the titer value and the virus infection titer value at an action time of 1 minute was calculated and evaluated. The evaluation criteria are as follows. The results are shown in Table 1.
A: Reduction of infectious titer of 4.0 or more (sufficient effect)
B: Decrease in infectious titer of 2.0 or more and less than 4.0 (effective)
C: Decrease in infectious titer below 2.0 (no effect)

(Measurement of feline calicivirus infection titer when there is no protein stain)
As the virus inactivating agent, the virus inactivating agent according to each Example and each Comparative Example was used, and 10% meat extract was added in step (3) of the above (measurement of feline calicivirus infection titer in the presence of protein stains). Feline calicivirus infection titer without protein stain, similar to the above (measurement of feline calicivirus infection titer in the presence of protein stain), except that the supernatant of the cultured cell disruption solution after centrifugation was used as the virus solution without mixing. Measurements were made.
The difference between the value of the virus infectious titer at the action time of 0 minutes and the value of the virus infectious titer at the action time of 1 minute was calculated and evaluated. The evaluation criteria are the same as the above evaluation criteria (measurement of feline calicivirus infection titer in the presence of protein stains). The results are shown in Table 1.

(Measurement of murine norovirus infection titer in the presence of protein stains)
As the virus inactivating agent, the virus inactivating agent according to each Example and each Comparative Example was used, and the virus infectivity at an action time of 0 minutes based on the above method (measurement of murine norovirus infectivity titer in the presence of protein stain). The difference between the value of the titer and the value of the virus infectivity titer at the action time of 1 minute was calculated and evaluated. The evaluation criteria are as follows. The results are shown in Table 1.
A: Reduction of infectious titer of 4.0 or more (sufficient effect)
B: Decrease in infectious titer of 2.0 or more and less than 4.0 (effective)
C: Decrease in infectious titer below 2.0 (no effect)

(Measurement of murine norovirus infection titer when no protein stains)
As the virus inactivating agent, the virus inactivating agent according to each Example and each Comparative Example was used, and 10% meat extract was mixed in the step (3) of the above (measurement of murine norovirus infection titer in the presence of protein stain). The mouse norovirus infection titer was measured when there was no protein stain, as in the above (measurement of murine norovirus infection titer in the presence of protein stain), except that the supernatant of the cultured cell disruption solution after centrifugation was used as the virus solution. It was.
The difference between the value of the virus infectious titer at the action time of 0 minutes and the value of the virus infectious titer at the action time of 1 minute was calculated and evaluated. The evaluation criteria are the same as the above evaluation criteria (measurement of murine norovirus infection titer in the presence of protein stains). The results are shown in Table 1.

(Measurement of influenza virus infection titer in the presence of protein stains)
As the virus inactivating agent, the virus inactivating agent according to each Example and each Comparative Example was used, and the virus infectivity at an action time of 0 minutes based on the above method (measurement of influenza virus infectivity titer in the presence of protein stain). The difference between the value of the titer and the value of the virus infectivity titer at the action time of 1 minute was calculated and evaluated. The evaluation criteria are as follows. The results are shown in Table 1.
A: Reduction of infectious titer of 4.0 or more (sufficient effect)
B: Decrease in infectious titer of 2.0 or more and less than 4.0 (effective)
C: Decrease in infectious titer below 2.0 (no effect)

(Measurement of influenza virus infection titer when protein is not contaminated)
As the virus inactivating agent, the virus inactivating agent according to each Example and each Comparative Example was used, and 10% meat extract was mixed in the step (3) of the above (measurement of influenza virus infection titer in the presence of protein stain). The influenza virus infection titer was measured when there was no protein stain, as in the above (measurement of influenza virus infection titer in the presence of protein stain), except that the supernatant of the cultured cell disruption solution after centrifugation was used as the virus solution. It was.
The difference between the value of the virus infectious titer at the action time of 0 minutes and the value of the virus infectious titer at the action time of 1 minute was calculated and evaluated. The evaluation criteria are the same as the above evaluation criteria (measurement of influenza virus infection titer in the presence of protein stains). The results are shown in Table 1.

As shown in Table 1, the virus according to Examples 1 to 8 containing ethanol, carbonate, and an acid agent, and the mass concentration of carbonate exceeds 0.10% by weight and is less than 8.00% by weight. The inactivating agent showed a good virus inactivating effect on feline calicivirus, murine norovirus and influenza virus.
On the other hand, the virus inactivating agents (Comparative Examples 1 to 8) containing no of ethanol, carbonate, and acid agents show a sufficient virus inactivating effect on all of these viruses. It turned out that I couldn't say that.

Claims (7)

A virus inactivating agent containing ethanol, a carbonate, and an acid agent.
The mass concentration of the carbonate in the virus inactivating agent is more than 0.10% by weight and less than 8.00% by weight.
The carbonate is at least one selected from the group consisting of potassium carbonate and ammonium carbonate.
A virus inactivating agent characterized by not containing a polyhexamethylene guanidine compound (excluding those having a pH (JIS Z-8802: 2011 "pH measurement method") of 9.5 or higher at 25 ° C.). .. The virus inactivating agent according to claim 1, wherein the acid agent contains at least one selected from the group consisting of citric acid, malic acid, lactic acid, phosphoric acid, tartaric acid, adipic acid, succinic acid and phytic acid. The virus inactivating agent according to claim 1 or 2, wherein the mass concentration of the ethanol in the virus inactivating agent is 8.05 to 85.70% by weight. The virus inactivating agent according to any one of claims 1 to 3, wherein the mass concentration of the acid agent in the virus inactivating agent is 0.01 to 5.00% by weight. The virus inactivating agent according to any one of claims 1 to 4, wherein the pH of the virus inactivating agent is 6 to 12. A norovirus inactivating agent comprising the virus inactivating agent according to any one of claims 1 to 5. A hygienic material comprising the virus inactivating agent according to any one of claims 1 to 5 or the norovirus inactivating agent according to claim 6.