Whey Powder

  • OverviewThe term whey refers to the greenish translucent liquid that separates from the curd after the coagulation of milk during the manufacture of cheese. Approximately 9 liters of whey can be produced from 10 liters of milk for every kilogram of cheese produced. This watery residue, or serum, is a huge reservoir of high-value milk protein. Because whey contains more than 90percentwater, it is essential to remove some or most of the water. This enables the production of various types of whey powder which are sought after for their unique functional properties. The most common types of whey powder manufactured in Canada are demineralized whey powder and lactose and delactosed whey powder.
    Whey powder is a valuable addition to the functional properties of various foods as well as a source of valuable nutrients because it contains approximately 50percentof the nutrients in the original milk.
  • Composition

    Whey powder consists primarily of carbohydrate (lactose), protein (several different whey proteins, mainly lactalbumins and globulins), various minerals and vitamins.

     

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    Typical composition of whey powder
    Total solids Lactose Total protein (n x 6.38)
    96-97% 70-75% 10-13%

     

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    Minerals
    Ash Calcium
    7-12% 4500 mg/kg

     

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    Vitamins
    Thiamin Riboflavin Pyridoxine
    0.4-0.6 mg 2.3-2.5 mg 0.4-0.6 mg

     

  • Different types of whey powder
    • Sweet whey powder: is produced by drying fresh whey from which the milkfat has been removed during the preparation of Cheddar, Mozzarella, Swiss or other cheeses manufactured principally with rennet type enzymes (casein-coagulating enzyme preparations). It contains all the constituents, except water, in the same relative proportion as in liquid whey. Its pH in a 10percentsolution should be greater than 5.6. This type of whey powder represents the majority of the Canadian production.
    • Acid whey powder: is produced by drying fresh whey obtained from Cottage, Ricotta or other fresh cheeses manufactured principally by acid coagulation (the pH of the milk is lowered by microbial fermentation process in which some of the lactose is converted to lactic acid). It is similar to sweet whey powder in composition except for its lower lactose content and its higher titratable acidity which makes its flavour slightly acidic compared to normal whey flavour found in sweet whey powder. Its pH in a 10percentsolution should be lower than 5.1.
    • Demineralized whey powder: is produced from whey by selective removal of most (70-90 percent) of the minerals.
    • Delactosed whey powder: is produced from whey by crystallizing a majority of the lactose out and recovering the primary substance.

     

    Whey powders shall contain less than 5 mg/kg of copper, 1 mg/kg of lead and 20 mg/kg of iron. They should be exempt of Salmonella, Listeria, coagulase-negative Staphylococcus and show a maximum Standard Plate Count of 50,000 colony-forming units/gram (CFU/g).

  • Various uses

    As a food additive, whey powder acts as binder and extender for many food products, such as beef preparations, chili con carne, poultry, sausage, soups and stews. Usage level is limited to 3.5percentfor sausage and 8percentfor chili con carne, pork or beef with BBQ sauce. It is widely used in bakery products, dry mixes, process cheese foods and spreads, frozen desserts, sauces, meat emulsions, salad dressings, confections, gravies, snack foods and beverages.

    Demineralized whey powder as well as delactosed whey powder are used in infant foods, diet foods formulations, prepared dry mixes and for food products in which mineral profile and concentration are critical attributes.

  • Functional properties

    Nutritional and functional characteristics of whey proteins are related to the structure and biological functions of these proteins. Native whey proteins (globulins and lactalbumins), as 11percentof constituents of whey powders, possess good functional properties related to solubility, foaming, emulsion formation and gelling. The high content of lactose plays an important role in flavour, aroma and browning reactions.

     

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    Functional property Solubility/hydration
    Mode of action Proteins bind/entrap water
    Food system Meats, beverages, breads, cakes, sausages

     

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    Functional property Gelation/viscosity
    Mode of action Protein matrix formations and setting
    Food system Salad dressings, soups, setting cheeses, baked goods, gravies, meats

     

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    Functional property Emulsification
    Mode of action Proteins stabilize fat emulsions
    Food system Sausages, soups, cakes, salad dressings, infant foods, coffee whiteners

     

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    Functional property Foaming/whipping
    Mode of action Proteins form stable film
    Food system Whipped toppings, chiffon cakes, desserts

     

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    Functional property Flavour/aroma/browning
    Mode of action Lactose undergoes caramelization reaction
    Food system Confections, meats in microwave, sauces, breads, baked goods, soups, dairy products

     

    For more information on concentrated and dried dairy products, please visit the University of Guelph's Dairy Science and Technology Web site.

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