The present disclosure provides methods for generating sugars from a cellulosic biomass. The methods combine treatment of the biomass using a high-shear milling device and saccharification of the biomass to partially hydrolyze the biomass. The biomass can be saccharified either after or simultaneously with the high-shear milling treatement. The partially hydrolyzed biomass is then separated into a solids stream with saccharification enzymes, and a liquid stream with sugars. The solids stream and associated enzymes are further incubated under saccharification conditions to produce additional sugars, or are recycled and added to fresh biomass, which is saccharified under high-shear milling conditions. The methods result in improved conversion of cellulosic biomass to glucose.

This invention relates to the use of a nutritional composition comprising sialylated oligosaccharides for enhancing cognitive development and learning skills in mammals. The nutritional composition comprises 3′-Siallylactose (3′-SL) and 6′-Siallylactose (6′-SL) in a weight ratio between 10:1 and 1:10 and is specifically for use in enhancing learning skills and/or enhancing memory function in an individual by increasing the sialic acid (Neu5Ac) concentration in the brain of said individual.

This invention relates to the use of a nutritional composition comprising sialylated oligosaccharides for enhancing cognitive development and learning skills in mammals. The nutritional composition comprises 3′-Siallylactose (3′-SL) and 6′-Siallylactose (6′-SL) in a weight ratio between 10:1 and 1:10 and is specifically for use in enhancing learning skills and/or enhancing memory function in an individual by increasing the sialic acid (Neu5Ac) concentration in the brain of said individual.

Provided herein is a peptide composition that is highly stable and can be stored long term, said composition containing one or more types of peptides having an amino acid sequence represented by any of SEQ ID Nos. 1-5, or a peptide in which one or two of the amino acids of the abovementioned peptides are independent and may be substituted, deleted or added, and saccharides and an inorganic salt.

Provided herein is a peptide composition that is highly stable and can be stored long term, said composition containing one or more types of peptides having an amino acid sequence represented by any of SEQ ID Nos. 1-5, or a peptide in which one or two of the amino acids of the abovementioned peptides are independent and may be substituted, deleted or added, and saccharides and an inorganic salt.

The present disclosure discloses a method for preparation of derivatives of gram-positive bacteria surface capsular polysaccharide, and belongs to the field of carbohydrate chemistry. The present disclosure takes glucose as a glycosyl donor to obtain a target β-glucosidic bond, then successfully synthesizes a disaccharide building block through a method of redox of a glucose C-2 site, and then takes the disaccharide building block as a repeat unit to synthesize a target oligosaccharide structure such as a derivative [.fwdarw.3)-α-D-Manp-(1.fwdarw.4)-β-D-Rhap-(1.fwdarw.].sub.5-Linker of gram-positive bacteria cell wall capsular polysaccharide. A reduction end of decose is linked with a linker to be linked with a protein to make glycoconjugates for immunological studies. The method provided by the present disclosure is simple, time-saving, labor-saving and low-cost, and the resultant derivatives of the gram-positive bacteria surface capsular polysaccharide may be used for development and preparation of medicine related to autism.

The present disclosure discloses a method for preparation of derivatives of gram-positive bacteria surface capsular polysaccharide, and belongs to the field of carbohydrate chemistry. The present disclosure takes glucose as a glycosyl donor to obtain a target β-glucosidic bond, then successfully synthesizes a disaccharide building block through a method of redox of a glucose C-2 site, and then takes the disaccharide building block as a repeat unit to synthesize a target oligosaccharide structure such as a derivative [.fwdarw.3)-α-D-Manp-(1.fwdarw.4)-β-D-Rhap-(1.fwdarw.].sub.5-Linker of gram-positive bacteria cell wall capsular polysaccharide. A reduction end of decose is linked with a linker to be linked with a protein to make glycoconjugates for immunological studies. The method provided by the present disclosure is simple, time-saving, labor-saving and low-cost, and the resultant derivatives of the gram-positive bacteria surface capsular polysaccharide may be used for development and preparation of medicine related to autism.

A process for producing maltitol includes at least: producing a maltose syrup, by hydrolysis of a granular starch, in a first stage of liquefaction of granular starch to form a liquefied starch, followed by a stage of saccharification of the liquefied starch to which an aqueous solution of beta-amylase has been added, to form the maltose syrup; hydrogenating the maltose syrup to form an aqueous maltitol composition; and recovering the maltitol composition. The aqueous solution of beta-amylase also includes potassium sorbate, glycerol, and sodium carbonate.

A process for producing maltitol includes at least: producing a maltose syrup, by hydrolysis of a granular starch, in a first stage of liquefaction of granular starch to form a liquefied starch, followed by a stage of saccharification of the liquefied starch to which an aqueous solution of beta-amylase has been added, to form the maltose syrup; hydrogenating the maltose syrup to form an aqueous maltitol composition; and recovering the maltitol composition. The aqueous solution of beta-amylase also includes potassium sorbate, glycerol, and sodium carbonate.

The present disclosure provides methods for generating sugars from a cellulosic biomass. The methods combine treatment of the biomass using a high-shear milling device and saccharification of the biomass to partially hydrolyze the biomass. The biomass can be saccharified either after or simultaneously with the high-shear milling treatment. The partially hydrolyzed biomass is then separated into a solids stream with saccharification enzymes, and a liquid stream with sugars. The solids stream and associated enzymes are further incubated under saccharification conditions to produce additional sugars, or are recycled and added to fresh biomass, which is saccharified under high-shear milling conditions. The methods result in improved conversion of cellulosic biomass to glucose.