Described herein are chlorite formulations having a pH between about 7 and about 8.5, wherein the chlorite formulations are substantially free of deleterious non-chlorite components. Described herein are chlorite formulations, including pharmaceutical formulations, which are formulated for systemic, parenteral, or intravenous administration. Described herein are methods of preparing and methods of using the chlorite formulations described herein.

Described herein are chlorite formulations having a pH between about 7 and about 8.5, wherein the chlorite formulations are substantially free of deleterious non-chlorite components. Described herein are chlorite formulations, including pharmaceutical formulations, which are formulated for systemic, parenteral, or intravenous administration. Described herein are methods of preparing and methods of using the chlorite formulations described herein.

The present invention provides an oral care agent suitable for removing oral deposits. An oral care agent of the present invention is a semi-solid oral care agent that is an agent for removing oral deposits.

Disclosed herein are methods of treating a subject having, or at risk of developing, acute respiratory distress syndrome (ARDS) by administering a chlorite composition in an amount effective to treat the subject. Aspects of the methods also include administering a chlorite formulation to a subject having or suspected of having a coronavirus infection, e.g., severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), severe acute respiratory syndrome (SARS-CoV), or Middle East respiratory syndrome coronavirus (MERS-CoV) infection. Also disclosed herein are methods of regulating macrophage activity in a subject having, or at risk of developing ARDS by contacting a macrophage of a subject having or at risk of developing ARDS with a chlorite composition in an amount effective to regulate one or more functional properties of the macrophage. The disclosure also features methods of determining inhibition of a ARDS-induced macrophage activity by a chlorite agent.

The purpose of the present invention is to provide a method for manufacturing a new disinfectant from sodium hypochlorite that has degraded in quality during storage. A method for manufacturing a novel disinfectant from a solution containing hypochlorite ions, chlorate ions, and chloride ions, wherein the method includes: a first reaction step for adding sulfuric acid to the solution and generating chlorine gas; a step in which, in a recovery liquid A, the generated chlorine gas is caused to react with sodium hydroxide or calcium hydroxide and recovered as hypochlorite ions; a second reaction step for adding, to a reaction mother liquid after the first reaction step, sulfuric acid having a higher concentration than that in the first reaction step, and generating chlorine dioxide gas; a step in which, in a recovery liquid B, the generated chlorine dioxide gas is caused to react with sodium hydroxide and hydrogen peroxide and recovered as chlorite ions; and a step for mixing the recovery liquid A and the recovery liquid B and obtaining a novel disinfectant.

The purpose of the present invention is to provide a method for manufacturing a new disinfectant from sodium hypochlorite that has degraded in quality during storage. A method for manufacturing a novel disinfectant from a solution containing hypochlorite ions, chlorate ions, and chloride ions, wherein the method includes: a first reaction step for adding sulfuric acid to the solution and generating chlorine gas; a step in which, in a recovery liquid A, the generated chlorine gas is caused to react with sodium hydroxide or calcium hydroxide and recovered as hypochlorite ions; a second reaction step for adding, to a reaction mother liquid after the first reaction step, sulfuric acid having a higher concentration than that in the first reaction step, and generating chlorine dioxide gas; a step in which, in a recovery liquid B, the generated chlorine dioxide gas is caused to react with sodium hydroxide and hydrogen peroxide and recovered as chlorite ions; and a step for mixing the recovery liquid A and the recovery liquid B and obtaining a novel disinfectant.

The present invention is intended to provide a radical generating catalyst that can generate (produce) radicals under mild conditions. In order to achieve the above object, the first radical generating catalyst of the present invention includes: at least one selected from the group consisting of amino acids, peptides, phospholipids, and salts thereof. The second or third radical generating catalyst of the present invention includes an ammonium salt represented by the following chemical formula (XI) (excluding peroxodisulfate) and having a Lewis acidity of 0.4 eV or more.

##STR00001##

An aqueous composition includes an activator, a chlorite ion source, and water. The aqueous composition is alkaline. The aqueous composition produces chlorine dioxide upon contact with an acid. A method of producing chlorine dioxide includes contacting the aqueous composition with an acid.

An aqueous composition includes an activator, a chlorite ion source, and water. The aqueous composition is alkaline. The aqueous composition produces chlorine dioxide upon contact with an acid. A method of producing chlorine dioxide includes contacting the aqueous composition with an acid.

A method of manufacturing a dry solid comprising a hypochlorite and a chlorite may include preparing a solution comprising a hypochlorite ion, a chlorate ion, and a chloride ion; a first reaction step for adding sulfuric acid to the solution to generate chlorine gas; reacting the generated chlorine gas with sodium hydroxide or calcium hydroxide and recovering a reaction product as a hypochlorite ion in recovery liquid A; a second reaction step for adding sulfuric acid to a reaction mother liquor after the first reaction step at a concentration that is higher than that in the first reaction step to generate chlorine dioxide gas; reacting the generated chlorine dioxide gas with sodium hydroxide and hydrogen peroxide and recovering a reaction product as a chlorite ion in recovery liquid B; mixing recovery liquid A with recovery liquid B; and drying and solidifying the resulting mixture.