A low-mineral quark matrix is suggested, which is obtainable by (a) subjecting raw milk to heat treatment, separating the cream, (b) subjecting the skimmed milk such obtained to an ultrafiltration step and/or a reverse osmosis step, producing a retentate R1, which represents a dairy protein concentrate, and a permeate P1, (c) subjecting the permeate P1 to an electrodialysis step, producing a salt-depleted diluate D1, (d) combining the diluate D1 with the retentate R1, (e) subjecting the combination product such obtained to heat treatment until denaturation sets in, (f) fermenting the denaturation product such obtained by the addition of starter cultures and rennet, and (g) adjusting or standardising the fermentation product such obtained to defined dry matter and protein contents.

A quark matrix having improved taste characteristics is suggested, which is obtainable by (a) subjecting raw milk to heat treatment, separating the cream, (b) subjecting the skimmed milk such obtained to a microfiltration step, obtaining a first retentate R1, which represents a first dairy protein concentrate, and a first permeate P1, (c) subjecting the permeate P1 to an ultrafiltration step and/or a reverse osmosis step, obtaining a second retentate R2, which represents a second dairy protein concentrate, and a second permeate P2, (d) subjecting the permeate P2 to an electrodialysis step, obtaining a salt-depleted diluate D1, (e) combining the diluate D1 with the retentate R1, (f) subjecting the combination product such obtained to heat treatment until denaturation sets in, (g) fermenting the denaturation product such obtained by adding starter cultures and rennet, and (h) adjusting the fermentation product such obtained to defined dry matter and protein contents.

A quark matrix having improved taste characteristics is suggested, which is obtainable by (a) subjecting raw milk to heat treatment, separating the cream, (b) subjecting the skimmed milk such obtained to a microfiltration step, obtaining a first retentate R1, which represents a first dairy protein concentrate, and a first permeate P1, (c) subjecting the permeate P1 to an ultrafiltration step and/or a reverse osmosis step, obtaining a second retentate R2, which represents a second dairy protein concentrate, and a second permeate P2, (d) subjecting the permeate P2 to an electrodialysis step, obtaining a salt-depleted diluate D1, (e) combining the diluate D1 with the retentate R1, (f) subjecting the combination product such obtained to heat treatment until denaturation sets in, (g) fermenting the denaturation product such obtained by adding starter cultures and rennet, and (h) adjusting the fermentation product such obtained to defined dry matter and protein contents.

A process and system is shown for obtaining a dry milk formula, having (a-i) ultrafiltration of an animal skim milk composition having 70-90 wt % casein and 10-30 wt % whey proteins, based on total protein, and (a-ii) ultrafiltration of an animal whey composition having 0-25 wt % casein and 75-100 wt % whey proteins, based on total protein; or (a-iii) ultrafiltration of a mixture of the compositions of (a-i) and (a-ii), (b) removing polyvalent ions from the UF permeate originating from step (a-i) and/or (a-ii) or (a-iii) to obtain at least one softened UF permeate; (c) combining the at least one softened UF permeate with a UF retentate to obtain a combined product; and (d) drying the combined product to obtain a dry milk formula.

A process and system is shown for obtaining a dry milk formula, having (a-i) ultrafiltration of an animal skim milk composition having 70-90 wt % casein and 10-30 wt % whey proteins, based on total protein, and (a-ii) ultrafiltration of an animal whey composition having 0-25 wt % casein and 75-100 wt % whey proteins, based on total protein; or (a-iii) ultrafiltration of a mixture of the compositions of (a-i) and (a-ii), (b) removing polyvalent ions from the UF permeate originating from step (a-i) and/or (a-ii) or (a-iii) to obtain at least one softened UF permeate; (c) combining the at least one softened UF permeate with a UF retentate to obtain a combined product; and (d) drying the combined product to obtain a dry milk formula.

A system for modifying dairy protein functionality can include a milk protein input, a treatment process, and a milk protein output. A controller can be in communication with the treatment process and can be configured to receive one or more input parameters. The controller can generate one or more treatment parameters based on the one or more input parameters. The controller can then initiate the treatment process based on one or more of the treatment parameters. The modified dairy protein functionality can be selected or optimized based on a target functionality of the milk protein output.

A system for modifying dairy protein functionality can include a milk protein input, a treatment process, and a milk protein output. A controller can be in communication with the treatment process and can be configured to receive one or more input parameters. The controller can generate one or more treatment parameters based on the one or more input parameters. The controller can then initiate the treatment process based on one or more of the treatment parameters. The modified dairy protein functionality can be selected or optimized based on a target functionality of the milk protein output.

The present invention pertains to an improved process for production of nutritional products, such as e.g. infant formulas, containing milk protein and milk saccharide. The invention is particularly useful for the production of demineralized nutritional products and provides both the final nutritional product as well as milk saccharide-containing milk protein serum ingredients useful for the production of such nutritional products.

The present invention pertains to an improved process for production of nutritional products, such as e.g. infant formulas, containing milk protein and milk saccharide. The invention is particularly useful for the production of demineralized nutritional products and provides both the final nutritional product as well as milk saccharide-containing milk protein serum ingredients useful for the production of such nutritional products.

The invention generally relates to a system for isolating or separating a target from a sample. In certain aspects, processes performed by the target capture system include introducing a plurality of magnetic particles, in which a plurality of the particles include at least one binding moiety specific to a target, into a sample to form at least one target/particle complex and applying a magnetic field to isolate the magnetic particle/target complexes from the sample. The process starts at inputting a sample into the system and ends at delivering a capture target or nucleic acids of the target into a container for further analysis.