Physical Chemistry of Cheese Texture.- 1. Overview: Cheese Chemistry and Rheology.- 2. Rheology of Reduced-Fat Mozzarella Cheese.- 3. Rheology of Reduced-Fat Cheese Containing Fat Substitute.- 4. Factors Affecting the Functional Characteristics of Unmelted and Melted Mozzarella Cheese.- Chemical Origins of Cheese Flavor.- 5. Chemical Species in Cheese and Their Origin in Milk Components.- 6. Biogenesis of Flavour Compounds in Cheese.- 7. Cheddar Cheese Flavour and Chemical Indices: Changes During Maturation.- 8. Assessment of Accelerated Cheese Ripening by Reverse-Phase HPLC.- 9. Time-Temperature Effects on Microbial, Chemical, and Sensory Changes During Cooling and Aging of Cheddar Cheese.- Proteolysis during Ripening.- 10. Methods for Assessing Proteolysis During Maturation.- 11. Contribution of Milk-Clotting Enzymes and Plasmin to Cheese Ripening.- 12. Contribution of Lactic Acid Bacteria to Cheese Ripening.- 13. Maturation Profiles of Cheddar-Type Cheese Produced from High Heat Treatment Milk to Incorporate Whey Protein.- 14. Inhibition of Proteolysis in Mozzarella Cheese Prepared from Homogenized Milk.- Molecular and Ultrastructure of Cheese.- 15. Practical Aspects of Electron Microscopy in Cheese Research.- 16. Immunolocalization and Microstructure of Milk Proteins and Fat Mimetics.- 17. Microstructure Studies of Reduced Fat Cheeses Containing Fat Substitute.- 18. Influence of Casein Peptide Conformations on Textural Properties of Cheese.- 19. Electron-Density Patterns in Low-Fat Mozzarella Cheeses During Refrigerated Storage.- 20. Applications of Confocal Microscopy to Fat Globule Structure in Cheese.- Technological and Nutritional Aspects of Reduced-Fat Cheese.- 21. Technology of Manufacturing Reduced-Fat Cheddar Cheese.- 22. Nutritional Aspects of Reduced-Fat Cheese.- 23. Microbiology and Biochemistry of Reduced-Fat Cheese.- 24. Whey Protein in Cheese - An Overview.- 25. Reduced-Fat Cheese: Regulations and Definitions.- 26. Improving the Sensory Characteristics of Reduced-Fat Cheese.- Contributors.

The contributions in this volume were first presented at a symposium organized by the editors and held at the 214th National Meeting of the American Chemical Society in Las Vegas in September, 1997. The symposium was sponsored by the ACS Division of Agricultural and Food Chemistry and covered recent developments of interest in food analysis. Many changes have occurred since the standard textbooks on food analysis were published: E. coli 0 157: H7 has leaped into prominence, requiring new and rapid methods of detection; MALDI-MS was developed and used in food analysis for the first time; elec tron microscopy, fluorescence spectroscopy, and electrorheology have been applied to cheese, bread, meat, and chocolate, new methods for monitoring and predicting shelf life have been introduced; new techniques for determining the composition of food have evolved. This book includes many emerging approaches which food scientists may find useful and probably will not find in a textbook. The editors thank the authors whose work is presented in these chapters, the Divi sion of Agricultural and Food Chemistry for agreeing to hold the symposium, and our edi tors at Kluwer Academic I Plenum Publishers whose assistance made our task easier. Michael H. Tunick Samuel A. Palumbo Pina M. Fratamico v CONTENTS Physical Properties I. Transmission Electron Microscopic Imaging of Casein Submicelle Distribution in Mozzarella Cheese . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Michael H. Tunick, Peter H. Cooke, Edyth L. Malin, Philip W. Smith, and V. H. Holsinger 9 2. Confocal Microscopy of Bread . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ."

Although the art of making cheese can be traced to prehistoric times, it has continued to evolve as modern civilization progressed. The advent of new technologies and instrumentation has brought exponential growth in the understanding of cheese components and their function. Even more recently, the evolution of cheesemaking has accelerated, driven by economic factors such as the establishment of the European Economic Community, the changing diet of developed countries, and the environmental and economic concerns associated with whey disposal. Molecular biology has revolutionized the development of starter and adjunct cultures as well as rennets, and genetics will make it possible to maintain ideal milk components for cheesemaking. The ability to accelerate traditional ripening procedures has altered the production of certain cheeses, and the emphasis on decreasing the intake of dietary fat, especially in the United States, has prompted the development of technology for producing low-fat cheeses with traditional texture and flavor. In assembling a distinguished group of participants for the symposium, "Chemistry of the Structure/Function Relationships in Cheese," we hoped to review the interplay of these trends and forecast the direction of future research. Contributors evaluated the current status of cheesemaking and highlighted the information that will be essential for new developments. They also focused the attention of agricultural and food chemists on the opportunities in cheese research and the potential contributions they might make to the future of cheese, a most valuable food product. We are indebted to Dr. Patrick Fox, Dr. Mark Johnson, Dr. Milos Kalab, Dr.

The contributions in this volume were first presented at a symposium organized by the editors and held at the 214th National Meeting of the American Chemical Society in Las Vegas in September, 1997. The symposium was sponsored by the ACS Division of Agricultural and Food Chemistry and covered recent developments of interest in food analysis. Many changes have occurred since the standard textbooks on food analysis were published: E. coli 0 157: H7 has leaped into prominence, requiring new and rapid methods of detection; MALDI-MS was developed and used in food analysis for the first time; elec tron microscopy, fluorescence spectroscopy, and electrorheology have been applied to cheese, bread, meat, and chocolate, new methods for monitoring and predicting shelf life have been introduced; new techniques for determining the composition of food have evolved. This book includes many emerging approaches which food scientists may find useful and probably will not find in a textbook. The editors thank the authors whose work is presented in these chapters, the Divi sion of Agricultural and Food Chemistry for agreeing to hold the symposium, and our edi tors at Kluwer Academic I Plenum Publishers whose assistance made our task easier. Michael H. Tunick Samuel A. Palumbo Pina M. Fratamico v CONTENTS Physical Properties I. Transmission Electron Microscopic Imaging of Casein Submicelle Distribution in Mozzarella Cheese . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Michael H. Tunick, Peter H. Cooke, Edyth L. Malin, Philip W. Smith, and V. H. Holsinger 9 2. Confocal Microscopy of Bread . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ."

In an engaging tour of the science and history of cheese, Michael Tunick explores the art of cheese making, the science that lies underneath the deliciousness, and the history behind how humanity came up with one of its most varied and versatile of foods.
Dr. Tunick spends his everyday deep within the halls of the science of cheese, as a researcher who creates new dairy products, primarily, cheeses. He takes us from the very beginning, some 8000 years ago in the Fertile Crescent, and shows us the accidental discovery of cheese when milk separated into curds and whey. This stroke of luck would lead to a very mild, and something akin to cottage, cheese-deemed delicious enough by our traveling cheese maker that he or she did it again another day.
Today we know of more than 2,000 varieties of cheese from Gorgonzola, first noted in year 879, to Roquefort in 1070 to Cheddar in 1500. But Tunick delves deeper into the subject to provide a wide-ranging overview that begins with cows and milk and then covers the technical science behind creating a new cheese, milk allergies and lactose intolerance, nutrition and why cheese is a vital part of a balanced diet. The Science of Cheese is an entertaining journey through one of America's favorite foods.

Edited and authored by world experts, this book covers the newest areas of research into cheese manufacture and engineering, as well as the latest developments concerning properties and structure. Information dealing with cheese manufacture includes starter and adjunct cultures, nonstarter lactic acid bacteria, coagulants, novel processing techniques, and ripening. The chapters on cheese properties explain rheology, microscopy, flavours, and other topics. Comparisons of cheese made from milk of various mammals and of artisanal and large-scale cheese manufacturing including vegan cheeses are included. Providing a useful source of facts and information for scientists, cheesemakers, and students, the book covers the ever-expanding field of cheese production, technology, and analysis. Cheesemakers large and small must respond to changing consumer demands and interests. This book informs the knowledge base in cheese chemistry and scientific advances in these areas.