Disclosed herein are processing methods for producing a physically modified starch and for producing a physically modified flour and/or starch flour mixture. The starch process comprises adding at least one salt or additive to a starch, adjusting the pH of the starch to alkaline, and dewatering the starch using a filter to obtain filtered solids. The process further comprises drying the filtered solids, spreading a layer of dried filtered solids on a surface, and heating the dried filtered solids while on the surface to a temperature of about 100° C. to 190° C. to obtain the physically modified starch. In an embodiment, the flour and/or starch/flour mixture process comprises preparing a thermally inhibited flours and/or starch/flour mixtures starting with or without additives, pH adjustment, followed by heat treating the flour and/or starch/flour mixtures directly to obtain the physically modified flour and/or starch flour mixture.

Disclosed herein are processing methods for producing a physically modified starch and for producing a physically modified flour and/or starch flour mixture. The starch process comprises adding at least one salt or additive to a starch, adjusting the pH of the starch to alkaline, and dewatering the starch using a filter to obtain filtered solids. The process further comprises drying the filtered solids, spreading a layer of dried filtered solids on a surface, and heating the dried filtered solids while on the surface to a temperature of about 100° C. to 190° C. to obtain the physically modified starch. In an embodiment, the flour and/or starch/flour mixture process comprises preparing a thermally inhibited flours and/or starch/flour mixtures starting with or without additives, pH adjustment, followed by heat treating the flour and/or starch/flour mixtures directly to obtain the physically modified flour and/or starch flour mixture.

The present invention relates to a modified starch and a method for obtaining the modified starch by using a debranching enzyme, such as isoamylase, pullulanase, limit dextrinase and the like. The debranching enzyme modified starch of present invention exhibits excellent film-forming capacity, film strength, and gelation ability, so as to be used as a material for making hard capsules without the use of coagulants and plasticizers.

Described herein is a composition used for shelf-stable, wet pet food applications, comprising a blend of a first starch or flour and a second starch or flour, wherein the blend makes up 1-10 wt % of the composition and wherein the first starch or flour is a TI or HMT starch or flour and a salt component making up 0.1-5 wt % of the composition; wherein the composition has a post-retort viscosity of less than 1500 centipoise measured at 165° F.

A baked good includes a gelatinized component comprising a starch and having a total starch content, the baked good having a slowly digestible starch content of at least 15 grams per 100 grams of ready-to-eat baked good, and at least 20% of the total starch content of the baked good being gelatinized.

The invention relates to a method for producing a heat-modified starch, comprising the steps consisting in: (i) preparing a starch milk having a solids content of between 30 and 40%, preferably between 35 and 37% by weight, (ii) adding a solution of an alkaline agent at a weight concentration of between 25 and 35%, preferably of 30%, so as to obtain a conductivity on the milk of between 4 and 7 mS/cm, (iii) ensuring a contact time of between 0.5 and 2 hours, (iv) filtering and drying the starch milk such that the conductivity of the dried starch resuspended at 20% by weight of solids is between 0.7 and 2.5 mS/cm, (v) heating said dried starch so as to bring it to a temperature of more than 180° C. for a residence time of between 10 and 40 minutes, even more preferentially between 15 and 35 minutes.

A process for producing thermally inhibited starch, specifically thermally inhibited non-pregelatinized granular starch is described, resulting in a viscostable starch product. The process comprising providing an alkaline starch, specifically an alkaline non-pregelatinized granular starch, having a pH of at least 8; subjecting the starch to a hydrothermal treatment, specifically to obtain a hydrothermally treated non-pregelatinized granular starch, said hydrothermal treatment being at a temperature of 45-200° C. with steam at a steam pressure of 0.1-15 bar or a gas mixture comprising water vapor at a partial water vapor pressure of 0.1-15 bar; dehydrating the starch, specifically the hydrothermally treated non-pregelatinized granular starch, to a moisture content of 2 wt % or lower and subjecting the starch to a thermal treatment by heating the starch to a temperature of 120-190° C. to obtain viscostability, cooling and optionally further processing the starch.

A process for producing thermally inhibited starch, specifically thermally inhibited non-pregelatinized granular starch is described, resulting in a viscostable starch product. The process comprising providing an alkaline starch, specifically an alkaline non-pregelatinized granular starch, having a pH of at least 8; subjecting the starch to a hydrothermal treatment, specifically to obtain a hydrothermally treated non-pregelatinized granular starch, said hydrothermal treatment being at a temperature of 45-200° C. with steam at a steam pressure of 0.1-15 bar or a gas mixture comprising water vapor at a partial water vapor pressure of 0.1-15 bar; dehydrating the starch, specifically the hydrothermally treated non-pregelatinized granular starch, to a moisture content of 2 wt % or lower and subjecting the starch to a thermal treatment by heating the starch to a temperature of 120-190° C. to obtain viscostability, cooling and optionally further processing the starch.

The instant application provides methods to improve the total starch yield and/or gluten yield from corn kernels in a wet milling process, the method comprising admixing corn kernels or a fraction of the corn kernels with an enzyme composition comprising an effective amount of one or more hydrolytic enzymes, wherein at least one of said hydrolytic enzymes is selected from the group consisting of a GH30 polypeptide, a GH5 polypeptide or a combination thereof.

The instant application provides methods to improve the total starch yield and/or gluten yield from corn kernels in a wet milling process, the method comprising admixing corn kernels or a fraction of the corn kernels with an enzyme composition comprising an effective amount of one or more hydrolytic enzymes, wherein at least one of said hydrolytic enzymes is selected from the group consisting of a GH30 polypeptide, a GH5 polypeptide or a combination thereof.