Abstract: A process for manufacturing an enriched fructose syrup, which is characterized in that dextrose is crystallized from a syrup containing fructose and dextrose and then an alcohol is added to enhance separation of the dextrose crystals from the mother liquor.Process can be adjusted to yield dextrose monohydrate, anhydrous alpha dextrose or a 40 percent fructose crystalline product in addition to an enriched fructose syrup.

Abstract: Alpha, beta carbonyl compounds are prepared from an acid anhydride selected from the group consisting of glutaric anhydride and 3-alkyl glutaric anhydride, and a beta-hydroxy carbonyl compound having the following chemical formula:R.sub.2 COH--CHR--CRO or R.sub.2 COH--CHR--CNwhere each R is any substitutent group.The process comprises: (a) reacting the acid anhydride and the beta-hydroxy carbonyl compound in the presence of a catalytically effective amount of an acid catalyst to form an ester; (b) reacting the ester in the presence of a catalytically effective amount of a base catalyst to form a alpha, beta-unsaturated carbonyl compound and a carboxylic acid; and (c) separating the alpha, beta-unsaturated carbonyl compound and the carboxylic acid.

Abstract: Diacetone fructose solutions may be effectively hydrolyzed to fructose by acid exchange resins. Hydrolysis of diacetone fructose with acid exchange resins substantially reduces the formation of objectionable flavoring, coloring and other hydrolyzate by-products. The immobilized acid catalysis provides a fructose product substantially free from ash residues and significantly reduces the carbon, cation and anion exchange requirements for the manufacture of enriched, food-grade fructose syrups. Perfluorinated acid exchange resins have been found to be particularly effective for hydrolyzing aqueous diacetone fructose solutions into fructose.

Abstract: Aqueous fructose and aldehydes, ketones and/or acetals may be effectively catalyzed into alkylidene fructose derivatives with immobilized acid catalysts. The reaction provides a means for enriching the fructose content of conventional high fructose corn syrups. Perfluorinated acid resins are especially effective catalysts for converting aqueous fructose and acetone solutions into diacetone fructose. Catalysis with the perfluorinated acid resins may be conducted at significantly lower conversion temperatures with superior reactant and reaction product exchange rates. Enrichment of high fructose corn syrups may be generally accomplished by catalyzing the fructose and acetone into a diacetone fructose solution with the perfluorinated acid resin, allowing the dextrose to precipitate from the diacetone solution, hydrolyzing the diacetone fructose to fructose and recovery of the enriched fructose product therefrom.

Abstract: Acidophilic and acidoduric streptomycetes strains have been found to produce carbohydrases. These Streptomyces effectively elaborate glucose isomerase under acid conditions typically unfavorable for growth of conventional glucose isomerase producing Streptomyces. Sterilization of the culture and production media may be avoided by selectively propagating newly discovered Streptomyces acidodurans under acidic conditions which will effectively eliminate contaminating micro-organisms. The Streptomyces acidodurans herein also have the ability to undergo cultivation and elaborate glucose isomerase over a relatively broad pH range. Constitutive streptomycetes strains have also been isolated. Glucose isomerases derived from these Streptomyces strains are particularly effective for isomerizing glucose syrups to fructose-containing syrups.

Abstract: Acidophilic and acidoduric streptomycetes strains have been found to produce carbohydrases. These Streptomyces effectively elaborate glucose isomerase under acid conditions typically unfavorable for growth of conventional glucose isomerase producing Streptomyces. Sterilization of the culture and production media may be avoided by selectively propagating newly discovered Streptomyces acidodurans under acidic conditions which will effectively eliminate contaminating microorganisms. The Streptomyces acidodurans herein also have the ability to undergo cultivation and elaborate glucose isomerase over a relatively broad pH range. Constitutive streptomycetes strains have also been isolated. Glucose isomerases derived from these Streptomyces strains are particularly effective for isomerizing glucose syrups to fructose-containing syrups.