This specification discloses thermally inhibited waxy cassava starches and edible compositions made therefrom. In one aspect edible compositions have improved creaminess compared to prior art starches, independent of starch usage level and the viscosity provided by the starch. In an embodiment the edible composition comprises between 0.1% and 35.0% by weight. In various embodiments the thermally inhibited waxy cassava starch has a peak viscosity of between about 100, and 2000 Brabender units or between 500 and 1500 Brabender Units.

This specification discloses thermally inhibited waxy cassava starches and edible compositions made therefrom. In one aspect edible compositions have improved creaminess compared to prior art starches, independent of starch usage level and the viscosity provided by the starch. In an embodiment the edible composition comprises between 0.1% and 35.0% by weight. In various embodiments the thermally inhibited waxy cassava starch has a peak viscosity of between about 100, and 2000 Brabender units or between 500 and 1500 Brabender Units.

Provided is a food or beverage composition for suppressing an expression of an interleukin 7 receptor (IL-7R) gene, including a resistant starch-rich starch satisfying the following conditions (a), (b), (c) and (d) as an active ingredient: (a) having a resistant starch content of 60% or more, as determined by the AOAC Official Method 2002.02 for measuring resistant starch, (b) having a molecular weight peak more than or equal to 6×10.sup.3 and less than or equal to 4×10.sup.4, (c) having a molecular weight dispersity more than or equal to 1.5 and less than or equal to 6.0, and (d) having a gelatinization enthalpy at 50° C. to 130° C. of 10 J/g or less, as measured by differential scanning calorimetry.

Disclosed are methods relating to an extruded pregelatinized, partially hydrolyzed starch prepared by mixing at least water, non-pregelatinized starch, and acid to form a starch precursor. The acid can be a weak acid that substantially avoids chelating calcium ions or a strong acid in a small amount. In the method, pregelatinization and acid-modification of the starch precursor occurs in one step in an extruder. Also disclosed are methods of preparing board using the starch prepared according to the methods, as well as starches and boards prepared by various methods of the invention.

Disclosed are methods relating to an extruded pregelatinized, partially hydrolyzed starch prepared by mixing at least water, non-pregelatinized starch, and acid to form a starch precursor. The acid can be a weak acid that substantially avoids chelating calcium ions or a strong acid in a small amount. In the method, pregelatinization and acid-modification of the starch precursor occurs in one step in an extruder. Also disclosed are methods of preparing board using the starch prepared according to the methods, as well as starches and boards prepared by various methods of the invention.

Described herein is non-grain composition, comprising at least a thermally inhibited or HMT waxy tapioca starch having a post-retort viscosity of less than 1500 centipoise. Such composition can be used for retort food applications; shelf-stable, thermally processed food applications; canned food applications; and/or aseptic packing and ultra-heat treated process food applications.

The present disclosure relates to inhibited waxy starches and methods for using them. One aspect of the disclosure is an inhibited waxy starch based on maize, wheat, or tapioca having an amylopectin content in the range of 90-100%; and a sedimentation volume in the range of 10-50 mL/g; in which the amylopectin fraction of the inhibited waxy starch based on maize, wheat, or tapioca has no more than 48.5% medium-length branches having a chain length from 13-24 (measured by a valley-to-valley method as described herein), and the starch is not pregelatinized. Methods of using the starch materials in food products are also described.

The present disclosure relates to inhibited waxy starches and methods for using them. One aspect of the disclosure is an inhibited waxy starch based on maize, wheat, or tapioca having an amylopectin content in the range of 90-100%; and a sedimentation volume in the range of 10-50 mL/g; in which the amylopectin fraction of the inhibited waxy starch based on maize, wheat, or tapioca has no more than 48.5% medium-length branches having a chain length from 13-24 (measured by a valley-to-valley method as described herein), and the starch is not pregelatinized. Methods of using the starch materials in food products are also described.

Formation of low-crystallinity phytosterol nanoparticles via cooling-controlled supercritical carbon dioxide (SC—CO.sub.2) impregnation of phytosterols into biodegradable nanoporous starch aerogels and methods of preparing these aerogels are disclosed. The nanoporous starch aerogels increase water dissolution and bioaccessibility of the phytosterols, thereby making them available for preparation of high nutraceutical value foods.

Formation of low-crystallinity phytosterol nanoparticles via cooling-controlled supercritical carbon dioxide (SC—CO.sub.2) impregnation of phytosterols into biodegradable nanoporous starch aerogels and methods of preparing these aerogels are disclosed. The nanoporous starch aerogels increase water dissolution and bioaccessibility of the phytosterols, thereby making them available for preparation of high nutraceutical value foods.