Improved processes for producing high purity acesulfame potassium. In one embodiment, the process comprises the steps of contacting a solvent, e.g., dichloromethane, and a cyclizing agent, e.g., sulfur trioxide, to form a cyclizing agent composition and reacting an acetoacetamide salt with the cyclizing agent in the composition to form a cyclic sulfur trioxide adduct. The contact time is less than 60 minutes. The process also comprises forming from the cyclic sulfur trioxide adduct composition a finished acesulfame potassium composition comprising non-chlorinated, e.g., non-chlorinated, acesulfame potassium and less than 35 wppm 5-halo acesulfame potassium, preferably less than 5 wppm.

A process for producing acesulfame potassium, the process comprising the steps of providing a cyclizing agent composition comprising a cyclizing agent and a solvent and having an initial temperature, cooling the cyclizing agent composition to form a cooled cyclizing agent composition having a cooled temperature less than 35 C., reacting an acetoacetamide salt with the cyclizing agent in the cooled cyclizing agent composition to form a cyclic sulfur trioxide adduct composition comprising cyclic sulfur trioxide adduct; and, forming from the cyclic sulfur trioxide adduct in the cyclic sulfur trioxide adduct composition the finished acesulfame potassium composition comprising non-chlorinated acesulfame potassium and less than 39 wppm 5-chloro-acesulfame potassium. The cooled temperature is at least 2 C. less than the initial temperature.

A process for producing acesulfame potassium, the process comprising the steps of providing a cyclizing agent composition comprising a cyclizing agent and a solvent and having an initial temperature, cooling the cyclizing agent composition to form a cooled cyclizing agent composition having a cooled temperature less than 35 C., reacting an acetoacetamide salt with the cyclizing agent in the cooled cyclizing agent composition to form a cyclic sulfur trioxide adduct composition comprising cyclic sulfur trioxide adduct; and, forming from the cyclic sulfur trioxide adduct in the cyclic sulfur trioxide adduct composition the finished acesulfame potassium composition comprising non-chlorinated acesulfame potassium and less than 39 wppm 5-chloro-acesulfame potassium. The cooled temperature is at least 2 C. less than the initial temperature.

Compositions and processes for producing high purity acesulfame potassium are described. One process comprises the steps of forming a cyclic sulfur trioxide adduct; hydrolyzing the cyclic sulfur trioxide adduct to form an acesulfame-H composition comprising acesulfame-H; neutralizing the acesulfame-H in the acesulfame-H composition to form a crude acesulfame potassium composition comprising acesulfame potassium and less than 2800 wppm acetoacetamide-N-sulfonic acid, wherein the neutralizing step is conducted or maintained at a pH at or below 11.0; and treating the crude acesulfame potassium composition to form the finished acesulfame potassium composition comprising acesulfame potassium and less than 37 wppm acetoacetamide-N-sulfonic acid.

Compositions and processes for producing high purity acesulfame potassium are described. One process comprises the steps of forming a cyclic sulfur trioxide adduct; hydrolyzing the cyclic sulfur trioxide adduct to form an acesulfame-H composition comprising acesulfame-H; neutralizing the acesulfame-H in the acesulfame-H composition to form a crude acesulfame potassium composition comprising acesulfame potassium and less than 2800 wppm acetoacetamide-N-sulfonic acid, wherein the neutralizing step is conducted or maintained at a pH at or below 11.0; and treating the crude acesulfame potassium composition to form the finished acesulfame potassium composition comprising acesulfame potassium and less than 37 wppm acetoacetamide-N-sulfonic acid.

Compositions and processes for producing high purity acesulfame potassium are described. One process comprises the steps of providing a crude acesulfame potassium composition comprising acesulfame potassium and acetoacetamide, concentrating the crude acesulfame potassium composition to form a water stream and an intermediate acesulfame potassium composition comprising acesulfame potassium and less than 33 wppm acetoacetamide, and separating the intermediate acesulfame potassium composition to form the finished acesulfame potassium composition comprising acesulfame potassium and less than 33 wppm acetoacetamide. The concentrating step is conducted at a temperature below 90 C. and the separating step is conducted at a temperature at or below 35 C.

Compositions and processes for producing high purity acesulfame potassium are described. One process comprises the steps of providing a crude acesulfame potassium composition comprising acesulfame potassium and acetoacetamide, concentrating the crude acesulfame potassium composition to form a water stream and an intermediate acesulfame potassium composition comprising acesulfame potassium and less than 33 wppm acetoacetamide, and separating the intermediate acesulfame potassium composition to form the finished acesulfame potassium composition comprising acesulfame potassium and less than 33 wppm acetoacetamide. The concentrating step is conducted at a temperature below 90 C. and the separating step is conducted at a temperature at or below 35 C.

Provided are embodiments of creatine and creatine ethyl ester (CEE) salts where the anion is an artificial (non-saccharide) taste-modifier. These compounds represent stable white non-hygroscopic solids or semisolids that can readily dissolve in water and buffer solutions. Synthesis of novel creatine salts using environmentally safe solvents such as ethanol resulted in the formation of products in quantitative yields with sodium or potassium chloride as a byproduct. The creatine and creatine alkyl eater derivative salts are stable sweet-tasting compounds that are more palatable to a consumer than creatine or derivatives thereof.

Provided are embodiments of creatine and creatine ethyl ester (CEE) salts where the anion is an artificial (non-saccharide) taste-modifier. These compounds represent stable white non-hygroscopic solids or semisolids that can readily dissolve in water and buffer solutions. Synthesis of novel creatine salts using environmentally safe solvents such as ethanol resulted in the formation of products in quantitative yields with sodium or potassium chloride as a byproduct. The creatine and creatine alkyl eater derivative salts are stable sweet-tasting compounds that are more palatable to a consumer than creatine or derivatives thereof.

A radiation-sensitive resin composition includes a first polymer including a first structural unit that includes a first acid-labile group; a radiation-sensitive acid generator; and a compound represented by formula (1). n is 1 or 2. R.sup.1 represents a hydrogen atom or a monovalent organic group having 1 to 20 carbon atoms in a case in which n is 1. R.sup.1 represents a divalent organic group having 1 to 20 carbon atoms in a case in which n is 2. R.sup.2 represents a hydrogen atom or a monovalent organic group having 1 to 20 carbon atoms. E represents a group represented by formula (i). R.sup.2 and E may taken together represent a ring structure having 3 to 20 ring atoms together with the nitrogen atom. X represents a divalent organic group having 1 to 20 carbon atoms. R.sup.3 represents a second acid-labile group.

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