Dairy Foods logo
search
cart
facebook twitter linkedin youtube
  • Sign In
  • Create Account
  • Sign Out
  • My Account
Dairy Foods logo
  • NEWS
    • DAIRY REGULATIONS
  • PRODUCTS
    • New Products
    • Butter
    • Cheese
    • Cultured Dairy
    • Frozen Desserts
    • Ice Cream/Novelties
    • Milk
    • Non-Dairy Beverages
    • Sales Data
    • Whey, Milk Powder
    • Dairy Alternatives
  • INGREDIENTS
    • Cocoa
    • Colors/Flavors
    • Cultures/Enzymes
    • Fiber
    • Gums, Stabilizers, and Texturants
    • Inclusions
    • Omegas/Lipids
    • Prebiotics
    • Probiotics
    • Sweeteners
    • Other
  • OPERATIONS
    • SUSTAINABILITY
    • Equipment
    • Processing
    • Packaging
    • Food Safety & Sanitation
    • Membrane Technology
  • MEDIA
    • Dairy Foods TV
    • Podcasts
    • Webinars
  • DIRECTORIES
    • Buyers Guide
    • Dairy Plants USA
  • MEMBRANE FORUM
  • MORE
    • Associations
    • Dairy Foods' News & Views Newsletter
    • Blogs
    • Case Studies
    • Classifieds
    • Custom Content & Marketing Services
    • Dairy Foods Store
    • Market Research
    • Sponsor Insights
    • Supplier Spotlights
    • Tradeshows and Events
    • Strategy Guides
  • AWARDS
    • Dairy Plant of the Year Award
    • Breakthrough Award
    • Dairy Processor of the Year
  • EMAGAZINE
    • eMagazines
    • Archive Issues
    • Contact
    • Advertise
    • SIGN UP!
    • Columnists
    • Dairy 100
    • State of the Industry Report
    Dairy Foods ColumnistsCheese

    Cheese Doctor

    Boosting cheese yield: Small tweaks, big gains

    Why is protein recovery lower than casein recovery?

    By John A. Lucey Ph.D., Director, Center for Dairy Research
    A vat of milk being mixed
    Photo by Liudmila Chernetska / iStock / Getty Images Plus
    April 13, 2026
    John Lucey

    John Lucey, Ph.D., is the Owen R. Fennema Professor in Food Chemistry at the University of Wisconsin-Madison’s Center for Dairy Research.

    Cheese yield — the amount of product that you obtain from your starting milk — is vitally important for plants to understand and optimize. Even small differences in cheese yield result in a significant impact on plant revenue. Additionally, with the prevalent use of concentrated milk, monitoring plant efficiency is more important than ever.

    More than 100 years ago, Lucius van Slyke in New York analyzed the output at Cheddar cheese plants and came up with one of the first predictive yield equations to help estimate how much Cheddar cheese they should be making from their milk (this equation can be adjusted for other cheeses as well). This equation recognized that the two major milk components that are recovered in cheese are the fat and casein. Moisture content of cheese is another key factor influencing yield.

    So, when making cheese, why don’t we recover all the milk fat and casein? What causes some losses? For Cheddar cheese, typical fat recoveries are in the 90-93% range, and casein recoveries are in the 94-96% range (protein recovery values can typically range from 72-76% and are lower than casein recoveries due to the loss of whey proteins in the whey drainage step). Most of the casein loss is due to coagulant activity at clotting (i.e., loss of the glycomacropeptide) but additional loss occurs during the initial stirring process and subsequent damage to the curd particles. Higher protein recoveries are observed in cheese made from microfiltered milk as a higher proportion of the initial protein is casein.

    One of the major factors that influences fat loss is the design of the cheese vat. With older open style cheese vats, fat levels in cheese whey could often be 0.3-0.5% but in modern enclosed vats with well-optimized systems, the whey fats can be potentially as low as 0.15% (representing <5-6% of total fat losses). Homogenization of milk (not widely used for cheesemaking) can reduce whey fats. This difference in fat loss between older and modern vats seems to be due to an improved cutting process in these modern systems. Routine testing of whey fats should be performed to monitor losses.

    Why do we lose fat during the cutting step? Fat particles are very large compared to the other components in milk and they are just physically trapped within the initial rennet-induced network. These fat particles can be similar in size to the pores in the network. During the cutting process, the blades/knives expose pores/gaps on the newly cut gel surfaces and some of the fat particles fall out of the pores and are lost in the whey.

    Making a clean cut (not tearing the gel and causing more damage) and allowing the initial gel surface in these curd particles to “heal” (the outer layer to shrink and strengthen as it rapidly loses moisture), are variables that can improve fat recoveries. Excessive agitation of these initial soft/weak curd particles causes more damage to the curd particles and therefore more losses of fat and casein (these small curd particles are called fines).

    In recent years, many U.S. cheese plants have started to use concentrated milk (often increasing the total solids in milk by >5%). With an increase in the casein content of milk, the coagulation process is greatly impacted with a higher initial rate of gel firming. This results in a smaller window of opportunity for successfully completing the cutting process before the gel firms so much that cutting is hard to complete without tearing. When using higher solids cheese milk here at the Center for Dairy Research (CDR), we have found that we need to make several adjustments to the cheesemaking process. For example, reducing the coagulation temperature can slow down the initial rate of gel firming, which could provide a larger time window for completing proper cutting.

    Cheese made from concentrated milk can also have a lower moisture content so adjustments to the cooking/stirring conditions can help to retain more moisture. When the initial milk contains more fat and casein (higher solids) then obviously more cheese (i.e., yield) is produced but often there is little change/difference in the efficiency of the process (i.e., percentage fat or casein recoveries); sometimes the percentage of fat recovery is even reduced if the cutting process becomes challenging.

    Optimizing moisture levels can also help increase cheese yield. For example, if a plant is able to consistently produce high quality Cheddar at 38.0% moisture level, compared to 37.5% moisture level, they have increased their yield by around 0.8%. The challenge is that a plant must be able to consistently hit those upper-level moisture percentages, without going over specifications mandated by customers or the standards of identity. That type of compositional consistency requires an operation that has a very tightly controlled milk composition (not just protein/fat ratio but the actual concentrations as well) and a coagulation/cutting process that is similar every day.

    Finally, while the van Slyke predictive yield equation is still useful, the Center for Dairy Research (CDR) and others have developed more advanced prediction equations. Here at CDR, Dr. Mark Johnson and Dr. Rani Govindasamy-Lucey have developed a calculation method that allows plants to calculate their own percentages for protein and fat recovery without needing to do the complex mass balance experiments routinely done by scientists (e.g., in batch processes at the university). Inputs for these calculations include the detailed milk and cheese composition. This allows cheese plants to better understand the fat/casein recoveries they actually have, and if below typical levels, explore methods to improve these recoveries.

    The overall goals for many cheese plants include increasing output, maximizing efficiency and producing high-quality cheese that still has the expected shelf life. Making careful adjustments and optimization of the process can result in improved yield and better cheese quality.

    KEYWORDS: casein Cheddar cheese cheese plant equipment for cheesemaking plant operations vat whey protein

    Share This Story

    Looking for a reprint of this article?
    From high-res PDFs to custom plaques, order your copy today!

    John lucey phd

    John Lucey, Ph.D., is the Owen R. Fennema Professor in Food Chemistry at the University of Wisconsin-Madison’s Center for Dairy Research.

    Recommended Content

    JOIN TODAY
    to unlock your recommendations.

    Already have an account? Sign In

    • Lifeway Organic Kefir in different flavors inside a refrigerated grocery shelf.

      Dairy Foods names Lifeway Foods 2025 Processor of the Year

      Lifeway Foods donates $10,000 to wildfire victims,...
      Innovation
      By: Brian Berk
    • Two female farmers are standing in a field, holding a large milk canister, looking at several cows at dairy farm.

      Honoring Women Leaders Shaping the Dairy Industry

      For the fourth consecutive year, Dairy Foods is proud to...
      Dairy Foods & Beverages
      By: Barbara Harfmann
    • Main feature for State of the Industry with dairy products album cover with a gradient circular--patterned backgorund.

      2025 State of the Dairy Industry

      Welcome to the 2025 State of the Industry report. For...
      Cheese
    Manage My Account
    • eMagazine Subscription
    • Dairy Foods News & Views Newsletter
    • Online Registration
    • Manage My Preferences
    • Subscription Customer Service
    • Connect with Dairy Foods

    More Videos

    Sponsored Content

    Sponsored Content is a special paid section where industry companies provide high quality, objective, non-commercial content around topics of interest to the Dairy Foods audience. All Sponsored Content is supplied by the advertising company and any opinions expressed in this article are those of the author and not necessarily reflect the views of Dairy Foods or its parent company, BNP Media. Interested in participating in our Sponsored Content section? Contact your local rep!

       close
    • Xylem’s largest BVF reactor at a dairy farm
      Sponsored byXylem

      Preparing water systems for dairy growth in 2026

    Popular Stories

    Close up of man adding Greek yogurt while preparing healthy smoothie in the kitchen.

    An expert guide to dairy and GLP-1 receptor agonists

    Splash of milk in form of arm muscle. 3D illustration.

    Protein: The Powerhouse of Health and Wellness

    Vanila and blueberry ice cream with lavender on blue background.

    Is ice cream a healthy food?

    Nominate your product for the 2026 Dairy Foods Product of the Year!


    Food Safety webinar

    Events

    July 8, 2026

    Membrane Purification Enables Clean Beauty Actives

    The global cosmetics market is undergoing a major shift towards the use of natural bioactive ingredients as consumers grow more skeptical of traditional formulations and demand greater transparency and sustainability.

    July 22, 2026

    Food Safety Today: What Dairy Processors Need to Know

    Join the husband-and-wife team, Rich and Heather Draper, of the Ice Cream Club Inc., who have implemented food safety practices for more than 40 years, for this fascinating and educational webinar.

    View All Submit An Event

    Products

    Probiotic Ice Cream: Science and Technology

    Probiotic Ice Cream: Science and Technology

    See More Products
    health and wellness


    plant of the year

    Related Articles

    • Understanding the basics: Techniques to attain a high cheese yield

      See More
    • Powders and retentates can increase cheese yield

      See More
    • IDI boosts cheese yield with Promilk

      See More

    Related Products

    See More Products
    • GlobalData_Consumer.jpg

      Cheese (Dairy & Soy Food) Market in North America - Outlook to 2022: Market Size, Growth and Forecast Analytics

    • foods analysis.jpg

      Handbook of Dairy Foods Analysis, 2nd Edition

    • handbook.jpg

      Handbook of Dairy Foods and Nutrition, 3rd Edition

    See More Products

    Events

    View AllSubmit An Event
    • November 11, 2025

      Membranes: Innovative Approaches to Boosting Production

      On-Demand This session will explore how membrane systems work and how cleaning and sanitation can unlock new levels of production efficiency. The discussion will cover strategies to optimize operations, reduce downtime, and enhance sustainability. Expert presenter Rachel McGiness will share innovative approaches and real-world applications, offering practical insights to support improved performance. 
    View AllSubmit An Event

    Related Directories

    • Big Apple Bagels

    ×

    Stay ahead of the curve. Unlock a dose of cutting-edge insights.

    Receive our premium content directly to your inbox.

    SIGN-UP TODAY
    • RESOURCES
      • Advertise
      • Contact Us
      • Directories
      • Store
      • Want More
    • SIGN UP TODAY
      • Create Account
      • eMagazine
      • Newsletter
      • Customer Service
      • Manage Preferences
    • SERVICES
      • Marketing Services
      • Reprints
      • Market Research
      • List Rental
      • Survey/Respondent Access
    • STAY CONNECTED
      • LinkedIn
      • Facebook
      • YouTube
      • X (Twitter)
    • PRIVACY
      • PRIVACY POLICY
      • TERMS & CONDITIONS
      • DO NOT SELL MY INFORMATION
      • PRIVACY REQUEST
      • ACCESSIBILITY

    Copyright ©2026. All Rights Reserved BNP Media, Inc. and BNP Media II, LLC.

    Design, CMS, Hosting & Web Development :: ePublishing