The present invention provides novel methods for preparing a moisture-proof amino acid material. The present invention also provides novel compositions or nutritional supplements comprising the moisture-proof amino acid materials prepared by the methods of this invention.

The present invention provides novel methods for preparing a moisture-proof amino acid material. The present invention also provides novel compositions or nutritional supplements comprising the moisture-proof amino acid materials prepared by the methods of this invention.

The present invention relates to microalgal flour granules, and optionally, lipid-rich microalgal flour.

The present invention relates to microalgal flour granules, and optionally, lipid-rich microalgal flour.

Salt particles adhered to a bulk carrier of the present invention are improved over prior alternative salts by having smaller salt particles adhered to a bulk carrier are achieved through modifications of variables for production of salt adhered to carrier particles, including starting solid composition, salt-carrier slurry composition, inlet and outlet drying temperature, slurry temperature, and moisture content control. The resulting salt-carrier product of salt adhered to carrier particles can be produced with much smaller salt particles of about 100 nanometers to less than 2 microns adhered to a carrier, which in turn improves electrostatic forces that help the salt-carrier product better adhere to and coat a food product than salts not adhered to a carrier particle.

Salt particles adhered to a bulk carrier of the present invention are improved over prior alternative salts by having smaller salt particles adhered to a bulk carrier are achieved through modifications of variables for production of salt adhered to carrier particles, including starting solid composition, salt-carrier slurry composition, inlet and outlet drying temperature, slurry temperature, and moisture content control. The resulting salt-carrier product of salt adhered to carrier particles can be produced with much smaller salt particles of about 100 nanometers to less than 2 microns adhered to a carrier, which in turn improves electrostatic forces that help the salt-carrier product better adhere to and coat a food product than salts not adhered to a carrier particle.

The present invention provides a coconut sap inflorescence powder compositions to provide symptomatic or prophylactic treatment of human disorder that has enriched vitamins, minerals, fat, carbohydrates and proteins. The invention also provides a process for producing such powders by spray drying or freeze drying. The powdered compositions and dosage forms are useful in the treatment of drug induced nephrotoxicity, alcoholic liver damage, and performance enhancement when administered orally.

The present invention provides a coconut sap inflorescence powder compositions to provide symptomatic or prophylactic treatment of human disorder that has enriched vitamins, minerals, fat, carbohydrates and proteins. The invention also provides a process for producing such powders by spray drying or freeze drying. The powdered compositions and dosage forms are useful in the treatment of drug induced nephrotoxicity, alcoholic liver damage, and performance enhancement when administered orally.

The invention relates to self-assembling microparticles comprising a solid matrix and probiotic bacteria, wherein the solid matrix comprises soybean protein and a divalent or trivalent metal, and wherein the probiotic bacteria are distributed throughout the solid matrix; said matrix protects said probiotic bacteria during processing, storage, as well as during transit through the gastrointestinal tract, thus prolonging their lifetime and facilitating release into the intestine and improving their probiotic effect. The present invention also relates to the method for obtaining the self-assembling microparticles and to the products and compositions incorporating them.

The invention relates to self-assembling microparticles comprising a solid matrix and probiotic bacteria, wherein the solid matrix comprises soybean protein and a divalent or trivalent metal, and wherein the probiotic bacteria are distributed throughout the solid matrix; said matrix protects said probiotic bacteria during processing, storage, as well as during transit through the gastrointestinal tract, thus prolonging their lifetime and facilitating release into the intestine and improving their probiotic effect. The present invention also relates to the method for obtaining the self-assembling microparticles and to the products and compositions incorporating them.