The present invention relates to a novel process for preparing an isolate of cationic whey proteins containing high purity lactoferrin.

The present invention relates to a novel process for preparing an isolate of cationic whey proteins containing high purity lactoferrin.

The invention relates to a method of obtaining vegetable and/or fruit pulp crisp which is easy to eat any time and does not comprise any additive. The invention is a production method of vegetable-fruit pulp crisp, characterized by comprising the process steps of: squeezing fruits-vegetables and thus dewatering the same and obtaining the pulp thereof; adding a concentrated milk product into the obtained pulp; mixing all the contents; shaping the mixture; spreading the shaped products on the tray; freezing the products on the trays; and lyophilization of the frozen products under vacuum.

The invention relates to a method of obtaining vegetable and/or fruit pulp crisp which is easy to eat any time and does not comprise any additive. The invention is a production method of vegetable-fruit pulp crisp, characterized by comprising the process steps of: squeezing fruits-vegetables and thus dewatering the same and obtaining the pulp thereof; adding a concentrated milk product into the obtained pulp; mixing all the contents; shaping the mixture; spreading the shaped products on the tray; freezing the products on the trays; and lyophilization of the frozen products under vacuum.

A novel method for freeze-related separations, involving the combination of water with a selected concentration of biogenic ice nucleation proteins, freezing the combination, and separating the ice, potentially via centrifugation or sublimation. In some instances, the freezing conditions and the concentration of the at least one biogenic ice nucleation protein are selected such that the aqueous solution, upon freezing, forms a lamellar ice crystal structure having at least one property selected from the group consisting of a solute inclusion volume at least 30% smaller than in the first material alone, a hydraulic diameter at least 30% larger than in the first material alone, an inclusion width that is less than 10% of a crystal dimension, a hydraulic diameter that is less more than 1.5 times that of an inclusion width, a deviation of crystal orientation angle in the transverse direction of less than 45 degrees, an ice crystal length in the transverse direction that is at least 10% larger than in the first material alone, and a length of the ice crystal structure in the longitudinal direction that is at least 10% larger than in the first material alone. The use of these structures result in a significant efficiency improvement and energy savings.

A novel method for freeze-related separations, involving the combination of water with a selected concentration of biogenic ice nucleation proteins, freezing the combination, and separating the ice, potentially via centrifugation or sublimation. In some instances, the freezing conditions and the concentration of the at least one biogenic ice nucleation protein are selected such that the aqueous solution, upon freezing, forms a lamellar ice crystal structure having at least one property selected from the group consisting of a solute inclusion volume at least 30% smaller than in the first material alone, a hydraulic diameter at least 30% larger than in the first material alone, an inclusion width that is less than 10% of a crystal dimension, a hydraulic diameter that is less more than 1.5 times that of an inclusion width, a deviation of crystal orientation angle in the transverse direction of less than 45 degrees, an ice crystal length in the transverse direction that is at least 10% larger than in the first material alone, and a length of the ice crystal structure in the longitudinal direction that is at least 10% larger than in the first material alone. The use of these structures result in a significant efficiency improvement and energy savings.

Apparatus and associated methods relate to lyophilizing a solid phase composition (SPC). In an illustrative example, the SPC is received in a frozen state in a first packaging. The SPC may be, for example, transferred into a second packaging having a thermally conductive layer, mechanically distributed to a predetermined maximum thickness to form a block having at least one homogenous dimension, and provided with a heat source configured to communicate substantially all thermal energy to the SPC via the thermally conductive second layer. In some embodiments, the SPC may be maintained in the frozen state. For example, the lyophilized SPC may be transferred to a third packaging. Various embodiments may limit physical contacts with the SPC to the first packaging, the second packaging, and the third packaging. Various embodiments may advantageously maintain sanitation, retain nutrients of the SPC, and/or promote consistent results from the lyophilization process.

A preparation method of a low-lactose dairy product rich in honey pomelo fiber includes the following steps: washing, cutting and debitterizing peels of honey pomelos to obtain honey pomelo fiber pieces; sterilizing and cooling milk solution, performing the first-round fermentation by inoculating lactic acid bacteria, centrifuging the fermented milk after curding, collecting precipitates, adding water to the precipitates, and performing homogenizing treatment to obtain the first-round fermented milk; mixing the honey pomelo fiber pieces with the first-round fermented milk, and performing the second-round fermentation by inoculating the lactic acid bacteria; or performing the second-round fermentation by inoculating the first-round fermented milk with the lactic acid bacteria, and then mixing the second-round fermented milk with the honey pomelo fiber pieces; and prefreezing the treated honey pomelo fiber pieces treated in the previous step and then performing vacuum freeze-drying to obtain low-lactose dairy products rich in honey pomelo fiber.

A preparation method of a low-lactose dairy product rich in honey pomelo fiber includes the following steps: washing, cutting and debitterizing peels of honey pomelos to obtain honey pomelo fiber pieces; sterilizing and cooling milk solution, performing the first-round fermentation by inoculating lactic acid bacteria, centrifuging the fermented milk after curding, collecting precipitates, adding water to the precipitates, and performing homogenizing treatment to obtain the first-round fermented milk; mixing the honey pomelo fiber pieces with the first-round fermented milk, and performing the second-round fermentation by inoculating the lactic acid bacteria; or performing the second-round fermentation by inoculating the first-round fermented milk with the lactic acid bacteria, and then mixing the second-round fermented milk with the honey pomelo fiber pieces; and prefreezing the treated honey pomelo fiber pieces treated in the previous step and then performing vacuum freeze-drying to obtain low-lactose dairy products rich in honey pomelo fiber.

The present invention comprises a freeze-dried, dairy or dairy-substitute composition comprising a dairy or dairy-substitute ingredient and an emulsifier and methods of using same to promote and/or improve child development.