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9780849318221

Functional Food Carbohydrates

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  • ISBN13:

    9780849318221

  • ISBN10:

    084931822X

  • Edition: 1st
  • Format: Hardcover
  • Copyright: 2006-10-10
  • Publisher: CRC Press

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Summary

Historically, most of the research into carbohydrates as functional ingredients focused on the improvement of appearance, taste, mouth-feel, and stability. The growing interest in functional foods, however, is demanding a critical look at the beneficial nonnutritive effects of carbohydrates on human health. Furthermore, there is a need to establish definitive relations among the structure, physical property, and physiological function of these bioactive compounds. As more of the benefit and functional versatility of carbohydrates is revealed, it is clear that any future research and recommendation must be based on a solid synthesis of multidisciplinary findings including epidemiological, metabolic, and clinical nutritional data.Through clinical and epidemiological studies, Functional Food Carbohydrates addresses the specific classes of carbohydrates that seem to exert health-enhancing effects. The text begins with in-depth treatments of the chemistry, physical properties, processing technology, safety and health benefits of a variety of carbohydrates including cereal beta-glucans, microbial polysaccharides, chitosan, arabinoxylans, resistant starch, and other polysaccharides of plant origin. The authors then discuss the physiological and metabolic effects that a variety of carbohydrates have on specific chronic diseases such as cancer, diabetes, cardiovascular disease, obesity, and various gastrointestinal disorders. The final chapters discuss the regulatory and technological aspects of using carbohydrates as functional foods. Specifically, the authors consider the safety and efficacy of pre-, pro-, and synbiotics, and the potential use of carbohydrates as delivery vehicles for other bioactive compounds.With contributions from experts specializing in food chemistry and technology, as well as human nutrition and physiology, this text illuminates the link between the behavior of carbohydrate compounds and their beneficial end-result on human health.

Table of Contents

Chapter 1 Cereal β-Glucans: Structures, Physical Properties, and Physiological Functions 1(72)
Athina Lazaridou, Costas G. Biliaderis, and Marta S. Izydorczyk
1.1 Introduction
2(1)
1.2 Occurrence
3(2)
1.3 Extractability
5(2)
1.4 Extraction, Isolation, and Purification
7(4)
1.5 Enrichment of Cereal Grains in β-Glucan and Large-Scale Production of β-Glucan Concentrates and Isolates
11(10)
1.5.1 Dry Processing
11(6)
1.5.2 Wet Processing
17(4)
1.6 Structural Features
21(5)
1.7 Physical Properties
26(15)
1.7.1 Solubility — Solution Behavior
26(5)
1.7.2 Gelation — Cryogelation
31(6)
1.7.3 Processing Effects on Physical Properties
37(4)
1.8 Applications in Food Systems
41(5)
1.8.1 Cereal-Based Foods
41(3)
1.8.2 Applications as Fat Mimetics, Stabilizers, and Thickening Agents
44(2)
1.9 Nutritional Impact—Health Effects
46(12)
1.9.1 Hypocholesterolemic Effect
47(4)
1.9.2 Hypoglycemic Effect
51(1)
1.9.3 Determinants of Hypocholesterolemic and Hypoglycemic Effects
51(6)
1.9.4 Other Physiological Effects
57(1)
References
58(15)
Chapter 2 Resistant Starch 73(24)
Donald B. Thompson
2.1 Introduction: What Is Resistant Starch?
73(1)
2.2 In Vitro Analysis of RS
74(1)
2.3 In Vitro Isolation of RS
75(1)
2.4 The Nature of RS
76(1)
2.5 Sources of RS
76(2)
2.6 RS and Dietary Fiber
78(1)
2.7 What Is the Fate of RS in the Gut?
78(1)
2.8 Nutritional Importance of RS
79(2)
2.9 Manufacturing of RS-Containing Ingredients
81(7)
2.9.1 Type 1 RS
81(1)
2.9.2 Type 2 RS
81(3)
2.9.2.1 RS Levels in Untreated Granular Starch
81(2)
2.9.2.2 Enhancement of RS Levels in Granular Starch
83(1)
2.9.3 Type 3 RS
84(4)
2.9.4 Type 4 RS
88(1)
2.10 Conclusions
88(1)
References
89(8)
Chapter 3 Konjac Glucomannan 97(30)
K. Nishinari and S. Gao
3.1 Introduction
97(1)
3.2 Structure and Molecular Weight of Konjac Glucomannan
98(2)
3.2.1 The Man/Glc Ratio
98(1)
3.2.2 Fractionation
98(1)
3.2.3 Molecular Weight
99(1)
3.3 Solution Properties of Konjac Glucomannan
100(4)
3.3.1 Intrinsic Viscosity
100(1)
3.3.2 Zero-Shear Specific Viscosity
100(2)
3.3.3 Dynamic Viscoelasticity of KGM Dispersions
102(1)
3.3.4 Other Solution Properties
103(1)
3.4 Gelation of KGM in the Presence of Alkali
104(6)
3.4.1 Gelation Kinetics of KGM with Different Molecular Weights
104(6)
3.5 Mixture of Konjac with Other Polysaccharides
110(5)
3.5.1 Konjac—Xanthan Mixtures
110(1)
3.5.2 Konjac—K-Carrageenan Mixtures
111(2)
3.5.3 Konjac—Gellan Mixtures
113(1)
3.5.4 Konjac—Acetan Mixtures
114(1)
3.5.5 Konjac—Starch Mixtures
114(1)
3.6 Solid-State Properties of Konjac Glucomannan
115(5)
3.6.1 Dielectric, Viscoelastic, and Broad-Line NMR Studies of Konjac Glucomannan Films
115(2)
3.6.2 Biodegradable Material
117(3)
3.7 Physiological Functions of KGM
120(3)
References
123(4)
Chapter 4 Seed Polysaccharide Gums 127(40)
Steve W. Cui, Shinya Ikeda, and Michael N.A. Eskin
4.1 Introduction
128(1)
4.2 Seed Gums as Food Reserve: Galactomannans
129(9)
4.2.1 Locust Bean Gum
130(3)
4.2.1.1 Source
130(1)
4.2.1.2 Method of Production
130(1)
4.2.1.3 Chemistry and Structural Features
130(1)
4.2.1.4 Functional Properties and Applications
131(1)
4.2.1.5 Physiological Properties and Health Benefits
132(1)
4.2.2 Guar Gum
133(2)
4.2.2.1 Source
133(1)
4.2.2.2 Method of Production
133(1)
4.2.2.3 Chemistry and Structural Features
133(1)
4.2.2.4 Functional Properties and Applications
133(2)
4.2.2.5 Physiological Properties and Health Benefits
135(1)
4.2.3 Tara Gum
135(2)
4.2.3.1 Source
135(1)
4.2.3.2 Method of Production
136(1)
4.2.3.3 Chemistry and Structural Features
136(1)
4.2.3.4 Functional Properties and Applications
136(1)
4.2.3.5 Physiological Properties and Health Benefits
136(1)
4.2.4 Fenugreek Gum
137(1)
4.2.4.1 Source
137(1)
4.2.4.2 Method of Production
137(1)
4.2.4.3 Chemistry and Structural Features
137(1)
4.2.4.4 Functional Properties and Applications
137(1)
4.2.4.5 Physiological Properties and Health Benefits
138(1)
4.3 Seed Gums as Cell Wall Materials
138(7)
4.3.1 Xyloglucan from Tamarind Seed
138(5)
4.3.1.1 Source
138(1)
4.3.1.2 Methods of Production
139(1)
4.3.1.3 Chemistry and Structural Features
139(2)
4.3.1.4 Functional Properties and Applications
141(1)
4.3.1.5 Physiological Properties and Health Benefits
142(1)
4.3.2 Soluble Soybean Polysaccharides (Soya Fiber)
143(2)
4.3.2.1 Source
143(1)
4.3.2.2 Method of Production
143(1)
4.3.2.3 Chemistry and Structural Features
143(1)
4.3.2.4 Functional Properties and Applications
143(2)
4.3.2.5 Physiological Properties and Health Benefits
145(1)
4.4 Gums from Seed Coat: Mucilage
145(12)
4.4.1 Psyllium Mucilage
145(3)
4.4.1.1 Source
145(1)
4.4.1.2 Method of Production
146(1)
4.4.1.3 Chemistry and Structural Features
146(1)
4.4.1.4 Functional Properties and Applications
146(1)
4.4.1.5 Physiological Effects and Health Benefits
147(1)
4.4.2 Flaxseed Gum
148(4)
4.4.2.1 Source
148(1)
4.4.2.2 Method of Production
148(1)
4.4.2.3 Chemistry and Structural Features
149(1)
4.4.2.4 Functional Properties and Applications
150(1)
4.4.2.5 Physiological Properties and Health Benefits
151(1)
4.4.3 Yellow Mustard Gum
152(16)
4.4.3.1 Source
152(1)
4.4.3.2 Method of Production
152(1)
4.4.3.3 Chemistry and Structural Features
152(1)
4.4.3.4 Functional Properties and Applications
153(3)
4.4.3.5 Physiological Properties and Health Benefits
156(1)
4.5 Conclusions
157(1)
References
158(9)
Chapter 5 Microbial Polysaccharides 167(48)
Ioannis Giavasis and Costas G. Biliaderis
5.1 Introduction
167(1)
5.2 Types and Sources of Functional Polysaccharides
168(9)
5.2.1 Glucans
168(5)
5.2.2 EPS from Lactic Acid Bacteria
173(1)
5.2.3 Other Microbial Polysaccharides
174(3)
5.3 Production
177(11)
5.3.1 Biosynthesis
177(4)
5.3.2 Bioprocess Conditions
181(5)
5.3.2.1 Composition of the Process Medium
182(1)
5.3.2.2 Temperature
183(1)
5.3.2.3 pH
184(1)
5.3.2.4 Agitation, Aeration, and Dissolved Oxygen
185(1)
5.3.3 Isolation and Purification
186(2)
5.4 Physiological Functions
188(6)
5.4.1 Antitumor—Immunomodulatory Effects
188(4)
5.4.2 Antimicrobial—Antiviral Effects
192(1)
5.4.3 Hypocholesterolemic—Hypoglycemic and Other Effects
193(1)
5.5 Structure—Activity Relationships
194(5)
5.6 Future Perspectives
199(1)
References
200(15)
Chapter 6 Chitosan as a Dietary Supplement and a Food Technology Agent 215(34)
Riccardo A.A. Muzzarelli and Corrado Muzzarelli
6.1 Introduction
215(2)
6.2 Chitin as a Food Component
217(1)
6.3 Characteristics of Dietary Chitosans
218(1)
6.4 Modern Applications of Chitosan in Food Sciences
219(6)
6.4.1 Antibacterial Activity
220(1)
6.4.2 Antifungal Activity
221(2)
6.4.3 Edible Films and Textural Agents
223(1)
6.4.4 Control of Enzymatic Browning in Fruits
224(1)
6.4.5 Clarification and De-acidification of Fruit Juices
224(1)
6.4.6 Recovery of Solids from Food Processing Wastes
224(1)
6.5 Chitosan as a Nutraceutical
225(12)
6.5.1 Hypercholesterolemi a
225(4)
6.5.1.1 Cholesterol Lowering in Animals
226(1)
6.5.1.2 Cholesterol Lowering in Humans
227(1)
6.5.1.3 Mechanism of Cholesterol Lowering
227(2)
6.5.2 Current Views on Side Aspects
229(1)
6.5.3 Overweight
230(1)
6.5.4 Osteoarthritis
231(21)
6.5.4.1 Depolymerization of Chitosan
233(1)
6.5.4.2 Chitosan Depolymerization Products
234(1)
6.5.4.3 Mechanism of Action
235(2)
6.5.4.4 Product Quality
237(1)
6.6 Conclusions
237(1)
Acknowledgments
237(1)
References
238(11)
Chapter 7 Arabinoxylans: Technologically and Nutritionally Functional Plant Polysaccharides 249(42)
Marta S. Izydorczyk and Costas G. Biliaderis
7.1 Introduction
250(1)
7.2 Arabinoxylans as Constituents of Agricultural Crops
250(2)
7.3 Extraction, Isolation, and Purification of Arabinoxylans
252(7)
7.3.1 Aqueous Extraction
252(1)
7.3.2 Strategies to Extract Arabinoxylans from Agricultural By-Products
253(3)
7.3.3 Arabinoxylan-Enriched Fractions Obtained by Physical Grain Fractionation
256(2)
7.3.4 Production of Xylooligosaccharides
258(1)
7.4 Molecular Structure of Arabinoxylans
259(9)
7.4.1 Monosaccharide Residues and Glycosidic Linkages in Arabinoxylan Structures
259(2)
7.4.2 Ferulic Acid Residues and Intermolecular Cross-Linking
261(3)
7.4.3 Structural Heterogeneity and Polydispersity of Arabinoxylans
264(3)
7.4.4 Molecular Weight
267(1)
7.5 Biosynthesis of Arabinoxylans
268(2)
7.6 Physicochemical Properties of Arabinoxylans
270(5)
7.6.1 Conformation of Arabinoxylan Chains in Solids and Solutions
270(1)
7.6.2 Viscosity of Arabinoxylan Solutions
271(1)
7.6.3 Oxidative Cross-Linking
272(2)
7.6.4 Physicochemical Properties of Arabinoxylan Gels
274(1)
7.7 Arabinoxylans as Technologically Functional Food Ingredients
275(2)
7.8 Arabinoxylans as Nutritionally Functional Food Ingredients
277(6)
References
283(8)
Chapter 8 Carbohydrates and the Risk of Cardiovascular Disease 291(30)
Gunilla Önning
8.1 Introduction
291(1)
8.2 Cardiovascular Diseases
292(4)
8.2.1 Blood Lipids, Apolipoproteins, Blood Pressure, and Hemostatic Factors
293(3)
8.3 Diet and Cardiovascular Diseases
296(15)
8.3.1 Mono- and Disaccharides
296(1)
8.3.2 Oligosaccharides
297(1)
8.3.3 Polysaccharides: Dietary Fiber
298(25)
8.3.3.1 Observational Studies
298(2)
8.3.3.2 Intervention Studies
300(8)
8.3.3.3 Cholesterol-Lowering Mechanisms of Dietary Fiber
308(1)
8.3.3.4 Cholesterol-Lowering Effects of Dietary Fiber in Comparison with Other Food Components
309(2)
8.4 Health Claims Related to Carbohydrates and CVD
311(1)
8.5 Summary and Conclusions
312(1)
References
313(8)
Chapter 9 Carbohydrates and Obesity 321(50)
Gail Woodward-Lopez, Dana E. Gerstein, Lorrene D. Ritchie, and Sharon E. Fleming
9.1 Introduction
322(1)
9.2 Mechanisms by Which Dietary Carbohydrates Affect Energy Balance
323(6)
9.2.1 Satiation and Satiety
323(1)
9.2.2 Energy Density
324(1)
9.2.3 Palatability and Taste Preference
325(2)
9.2.4 Dietary Fat: Carbohydrate Ratio
327(1)
9.2.5 Metabolic Fuel Partitioning
327(1)
9.2.6 Glycemic Index
328(1)
9.2.7 Summary of Mechanisms
329(1)
9.3 Secular Trends: Changes in Carbohydrate Intake during the Time Period That Obesity Rates Have Risen
329(3)
9.3.1 Total Carbohydrates
329(1)
9.3.2 Sugars and Refined Carbohydrates
329(1)
9.3.3 Fiber
330(2)
9.4 Observational Studies: The Relationship between the Intake of Carbohydrates and Overweight
332(10)
9.4.1 Longitudinal Studies
332(3)
9.4.2 Cross-Sectional Studies
335(7)
9.4.3 Summary of Observational Studies (Longitudinal and Cross-Sectional)
342(1)
9.5 Treatment Studies: The Role of Dietary Carbohydrates in Weight Loss and Prevention of Weight Regain
342(6)
9.5.1 Low- vs. High-Carbohydrate Diets for Weight Loss
343(2)
9.5.2 Low- vs. High-Carbohydrate Diets for Prevention of Weight Regain
345(1)
9.5.3 Type of Carbohydrate for Weight Loss
346(1)
9.5.4 Other Health Considerations of a High-Carbohydrate Diet
347(1)
9.5.5 Other Health Considerations of a Low-Carbohydrate Diet
347(1)
9.6 Prevention Studies: The Role of Dietary Carbohydrates in Preventing Weight Gain
348(13)
9.6.1 Low- vs. High-Carbohydrate Diet for Prevention of Weight Gain
348(1)
9.6.2 Type of Carbohydrates for Prevention of Weight Gain
349(11)
9.6.3 Summary of Treatment and Prevention Studies
360(1)
9.7 Conclusions
361(2)
Acknowledgments
363(1)
References
364(7)
Chapter 10 Dietary Carbohydrates and Risk of Cancer 371(16)
Joanne Slavin
10.1 Introduction
371(1)
10.2 Carbohydrates in Foods
372(2)
10.3 Links between Cancer and Carbohydrate Intake
374(5)
10.3.1 Sugars and Digestible Carbohydrates
374(1)
10.3.2 Dietary Fiber
375(4)
10.4 Insulin and Colon Cancer
379(1)
10.5 Intervention Studies
379(1)
10.6 Breast Cancer
380(1)
10.7 Other Cancer Sites
381(1)
10.8 Addition of Carbohydrates to Functional Foods to Reduce Cancer Risk
381(1)
References
382(5)
Chapter 11 The Role of Carbohydrates in the Prevention and Management of Type 2 Diabetes 387(26)
Kaisa Poutanen, David Laaksonen, Karin Autio, Hannu Mykkänen, and Leo Niskanen
11.1 Introduction
388(1)
11.2 Glucose and Insulin Metabolism in Relation to Dietary Carbohydrates
388(1)
11.3 Pathogenesis of the Metabolic Syndrome and Type 2 Diabetes
389(2)
11.4 Glycemic Index and Glycemic Load
391(1)
11.5 Low-GI Carbohydrates in the Treatment of Diabetes
392(1)
11.5.1 Medium- to Long-Term Studies
392(1)
11.6 Low-GI Carbohydrates and Risk of Type 2 Diabetes
393(2)
11.6.1 Epidemiological Studies
393(1)
11.6.2 Postprandial Studies: Second-Meal Effects
394(1)
11.6.3 Medium- to Long-Term Studies
394(1)
11.7 Dietary Fiber in the Treatment of Hyperglycemia in Type 2 Diabetes
395(2)
11.7.1 Postprandial Studies
396(1)
11.7.2 Medium- to Long-Term Studies
396(1)
11.8 Dietary Fiber and Risk of Type 2 Diabetes
397(2)
11.8.1 Epidemiological Studies
397(1)
11.8.2 Postprandial Studies
398(1)
11.8.3 Medium- to Long-Term Studies
398(1)
11.9 Development of Carbohydrate Foods and Prevention of Type 2 Diabetes
399(4)
11.9.1 Use of Dietary Fiber
399(1)
11.9.2 Potential of Bioactive Components
400(1)
11.9.3 Use of Predictive In Vitro Methods
400(1)
11.9.4 Tailoring of Food Structure
401(2)
11.10 Conclusions
403(1)
References
403(10)
Chapter 12 Carbohydrates and Mineral Metabolism 413(22)
David D. Kitts
12.1 Introduction
413(1)
12.2 Calcium and Magnesium Homeostasis
414(2)
12.3 Carbohydrates and Mineral Bioavailability and Utilization
416(2)
12.3.1 Nonfiber Carbohydrate Sources
416(1)
12.3.2 Dietary Fiber Carbohydrate Sources
417(1)
12.4 Soluble Fiber Sources and Mineral Bioavailability
418(8)
12.4.1 Inulin and Fructooligosaccharides
418(3)
12.4.2 Resistant Starch
421(2)
12.4.3 Pectin
423(1)
12.4.4 Gums
424(1)
12.4.5 Polydextrose
425(1)
12.4.6 Psyllium
425(1)
12.5 Insoluble Fiber and Mineral Bioavailability
426(3)
12.5.1 Cellulose
426(1)
12.5.2 Wheat Bran
426(2)
12.5.3 Maillard Reaction Products
428(1)
12.6 Conclusions
429(1)
References
429(6)
Chapter 13 Dietary Carbohydrates as Mood and Performance Modulators 435(36)
Larry Christensen
13.1 Introduction
435(2)
13.2 Hypothesized Metabolic Determinants Mediating the Behavioral Effect of Carbohydrates
437(4)
13.2.1 The Relationship between Carbohydrates and Serotonin
437(3)
13.2.2 The Relationship between Carbohydrates and Endogenous Opioids
440(1)
13.3 Carbohydrates and Mood in Emotionally Distressed Individuals
441(11)
13.3.1 Carbohydrate Cravings
442(2)
13.3.2 Carbohydrates and Seasonal Affective Disorder
444(2)
13.3.3 Carbohydrates and Mood in Obese Individuals
446(2)
13.3.4 Carbohydrates, Mood, and Premenstrual Symptoms
448(2)
13.3.5 Carbohydrates and Major Depression
450(2)
13.4 The Effect of Carbohydrates on Healthy Adults
452(8)
13.4.1 Carbohydrates and Mood in Healthy Adults
452(5)
13.4.2 Carbohydrates and Performance in Healthy Adults
457(3)
13.5 Summary and Conclusions
460(3)
References
463(8)
Chapter 14 Carbohydrates and Gastrointestinal Tract Function 471(8)
Barbara O. Schneeman
14.1 Introduction
471(1)
14.2 Gastrointestinal Function
472(3)
14.2.1 Oral Cavity
472(1)
14.2.2 Stomach
472(1)
14.2.3 Small Intestine
473(1)
14.2.4 Large Intestine
474(1)
14.3 Emerging Areas
475(1)
References
475(4)
Chapter 15 Probiotics, Prebiotics, and Synbiotics: Functional Ingredients for Microbial Management Strategies 479(32)
G.C.M. Rouzaud
15.1 Overview
480(1)
15.2 Introduction
480(1)
15.3 Overview of Probiotic Concept
481(4)
15.3.1 Types of Probiotic Products
482(1)
15.3.2 Survival of Probiotics Strains
482(1)
15.3.3 Probiotic Persistence: Dose Effect
483(1)
15.3.4 Transfer of Antimicrobial Resistance
483(2)
15.3.5 Safety of Probiotics
485(1)
15.4 Overview of Prebiotic Concept
485(4)
15.4.1 Ease of Use of Prebiotics
488(1)
15.4.2 Side Effects
488(1)
15.4.3 Dose Effect
488(1)
15.4.4 Purity and Safety of Prebiotics
488(1)
15.4.5 GRAS Status and Persistence of Effect
489(1)
15.5 Overview of Synbiotic Concept
489(1)
15.5.1 Type of Synbiotic
489(1)
15.5.2 Synbiotic Efficacy
489(1)
15.6 Determining Efficacy
489(5)
15.6.1 In Vitro Systems
489(3)
15.6.2 Animal Models
492(1)
15.6.3 Ex Vivo Models
492(1)
15.6.4 Human Trials
492(1)
15.6.5 New Molecular Tools for Analyzing Gut Microflora (Biomarkers)
493(1)
15.7 Evidence for the Effect of Pro-, Pre-, and Synbiotics in the Maintenance of Health
494(8)
15.7.1 Infants and the Elderly
494(2)
15.7.2 Immune Function
496(1)
15.7.3 Lipid and Energy Metabolism
496(2)
15.7.4 Mineral and Vitamin Absorption
498(1)
15.7.5 Evidence for the Effect of Pro-, Pre-, and Synbiotics in Human Diseases
498(17)
15.7.5.1 Acute Disorders
498(2)
15.7.5.2 Chronic Disorders
500(2)
15.8 Conclusions
502(1)
References
502(9)
Chapter 16 Potential Use of Carbohydrates as Stabilizers and Delivery Vehicles of Bioactive Substances in Foods 511(16)
Pirkko Forssell, Päivi Myllärinen, Piia Hakala, and Kaisa Poutanen
16.1 Introduction
511(1)
16.2 Microencapsulation Technologies
512(3)
16.3 Carbohydrates as Encapsulating Matrices
515(7)
16.3.1 Functionality of Carbohydrates in Trigger Events
515(1)
16.3.2 Starch
516(2)
16.3.3 Pectins
518(1)
16.3.4 Other Polysaccharides
519(1)
16.3.5 Maltodextrins, Syrups, and Sugars
520(1)
16.3.6 Starch Derivatives
521(1)
16.4 Future
522(1)
References
522(5)
Chapter 17 Food Regulations: Health Claims for Foods Fortified with Carbohydrates or Other Nutraceuticals 527(34)
Jerzy Zawistowski
17.1 Introduction
528(1)
17.2 Definitions
529(1)
17.3 Japanese Functional Foods: Tokuho System
530(4)
17.4 U.S. Regulatory Framework for Functional Foods
534(9)
17.4.1 Food Safety: Generally Recognized as Safe (GRAS)
534(1)
17.4.2 Health Claims
535(8)
17.4.2.1 Nutrition Labeling and Education Act (NLEA)
535(6)
17.4.2.2 U.S. FDA Modernization Act
541(1)
17.4.2.3 Dietary Supplement Health and Education Act (DSHEA)
541(2)
17.5 Canadian Approach to Regulate Functional Foods
543(5)
17.5.1 Health Claims for Functional Foods
544(2)
17.5.1.1 Product-Specific Health Claims for Foods
545(1)
17.5.1.2 Foods for Special Dietary Use
545(1)
17.5.1.3 Generic Health Claims
546(1)
17.5.2 Novel Foods
546(1)
17.5.3 Natural Health Products Regulations
547(1)
17.6 European Union Regulatory Initiative for Functional Foods
548(7)
17.6.1 Novel Foods
548(5)
17.6.1.1 Novel Food Authorization in the EU
552(1)
17.6.1.2 Fast-Track Approval Procedure
552(1)
17.6.1.3 Labeling Requirements
553(1)
17.6.2 Health Claims Made on Foods: EU Proposal
553(2)
17.7 Conclusions
555(1)
References
556(5)
Index 561

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