Described are compositions and methods relate to stable, high-payload, non-porous enzyme-containing coated granules with improved resistance to activity loss during steam pelleting.

The present invention relates to an enzyme granulate comprising a carrier and an enzyme, and wherein the granulate comprises from 0.015 to 0.4 wt % of vegetable oil, and a process for preparing an enzyme granulate, comprising mixing a carrier with an enzyme and adding a composition comprising a vegetable oil, wherein the enzyme granulate comprises from 0.015 wt % to 0.4 wt % of the vegetable oil. The invention further relates to the use of the enzyme granulate in the preparation of a food or feed product.

The present invention relates to an enzyme granulate comprising a carrier and an enzyme, and wherein the granulate comprises from 0.015 to 0.4 wt % of vegetable oil, and a process for preparing an enzyme granulate, comprising mixing a carrier with an enzyme and adding a composition comprising a vegetable oil, wherein the enzyme granulate comprises from 0.015 wt % to 0.4 wt % of the vegetable oil. The invention further relates to the use of the enzyme granulate in the preparation of a food or feed product.

Enzymes tend to be inactivated during wash by a bleach catalyst in combination with a source of organic peroxyacids. The risk of enzyme inactivation by active bleach catalyst is reduced when the release of the enzyme into the wash solution is delayed. The enzyme stability during washing together with a bleach catalyst can be improved by applying a delayed-release coating to cores which comprise the enzyme.

Enzymes tend to be inactivated during wash by a bleach catalyst in combination with a source of organic peroxyacids. The risk of enzyme inactivation by active bleach catalyst is reduced when the release of the enzyme into the wash solution is delayed. The enzyme stability during washing together with a bleach catalyst can be improved by applying a delayed-release coating to cores which comprise the enzyme.

Enzymes tend to be inactivated during wash by a bleach catalyst in combination with a source of organic peroxyacids. The risk of enzyme inactivation by active bleach catalyst is reduced when the release of the enzyme into the wash solution is delayed. The enzyme stability during washing together with a bleach catalyst can be improved by applying a delayed-release coating to cores which comprise the enzyme.

Enzymes tend to be inactivated during wash by a bleach catalyst in combination with a source of organic peroxyacids. The risk of enzyme inactivation by active bleach catalyst is reduced when the release of the enzyme into the wash solution is delayed. The enzyme stability during washing together with a bleach catalyst can be improved by applying a delayed-release coating to cores which comprise the enzyme.

The storage stability of enzyme granules for detergents can be improved by incorporating a polyamine having a molecule with at least 10% w/w of nitrogen wherein at least 50% of the N atoms are present as amines.

The storage stability of enzyme granules for detergents can be improved by incorporating a polyamine having a molecule with at least 10% w/w of nitrogen wherein at least 50% of the N atoms are present as amines.

The present invention provides a microcapsule composition produced by crosslinking of a polybranched polyamine and a small amine, which is used for stabilizing detergent components.