Food Stabilisers, Thickeners and Gelling Agents
eBook - ePub

Food Stabilisers, Thickeners and Gelling Agents

  1. English
  2. ePUB (mobile friendly)
  3. Available on iOS & Android
eBook - ePub

Food Stabilisers, Thickeners and Gelling Agents

About this book

Stabilisers, thickeners and gelling agents are extracted from a variety of natural raw materials and incorporated into foods to give the structure, flow, stability and eating qualities desired by consumers. These additives include traditional materials such as starch, a thickener obtained from many land plants; gelatine, an animal by-product giving characteristic melt-in-the-mouth gels; and cellulose, the most abundant structuring polymer in land plants. Seed gums and other materials derived from sea plants extend the range of polymers. Recently-approved additives include the microbial polysaccharides of xanthan, gellan and pullulan.

This book is a highly practical guide to the use of polymers in food technology to stabilise, thicken and gel foods, resulting in consistent, high quality products. The information is designed to be easy to read and assimilate. New students will find chapters presented in a standard format, enabling key points to be located quickly. Those with more experience will be able to compare and contrast different materials and gain a greater understanding of the interactions that take place during food production. This concise, modern review of hydrocolloid developments will be a valuable teaching resource and reference text for all academic and practical workers involved in hydrocolloids in particular, and food development and production in general.

Frequently asked questions

Yes, you can cancel anytime from the Subscription tab in your account settings on the Perlego website. Your subscription will stay active until the end of your current billing period. Learn how to cancel your subscription.
At the moment all of our mobile-responsive ePub books are available to download via the app. Most of our PDFs are also available to download and we're working on making the final remaining ones downloadable now. Learn more here.
Perlego offers two plans: Essential and Complete
  • Essential is ideal for learners and professionals who enjoy exploring a wide range of subjects. Access the Essential Library with 800,000+ trusted titles and best-sellers across business, personal growth, and the humanities. Includes unlimited reading time and Standard Read Aloud voice.
  • Complete: Perfect for advanced learners and researchers needing full, unrestricted access. Unlock 1.4M+ books across hundreds of subjects, including academic and specialized titles. The Complete Plan also includes advanced features like Premium Read Aloud and Research Assistant.
Both plans are available with monthly, semester, or annual billing cycles.
We are an online textbook subscription service, where you can get access to an entire online library for less than the price of a single book per month. With over 1 million books across 1000+ topics, we’ve got you covered! Learn more here.
Look out for the read-aloud symbol on your next book to see if you can listen to it. The read-aloud tool reads text aloud for you, highlighting the text as it is being read. You can pause it, speed it up and slow it down. Learn more here.
Yes! You can use the Perlego app on both iOS or Android devices to read anytime, anywhere — even offline. Perfect for commutes or when you’re on the go.
Please note we cannot support devices running on iOS 13 and Android 7 or earlier. Learn more about using the app.
Yes, you can access Food Stabilisers, Thickeners and Gelling Agents by Alan Imeson in PDF and/or ePUB format, as well as other popular books in Technology & Engineering & Food Science. We have over one million books available in our catalogue for you to explore.
1
Introduction
Dennis Seisun
ABSTRACT
Food stabilisers, thickeners and gelling agents are obtained from a wide range of natural raw materials including microorganisms, land and sea plants and animal connective tissues. They control moisture and provide structure, flow, stability and eating qualities to food products. Approvals for food use and purity criteria are closely controlled by regulation. Commercial applications are determined by the combination of properties provided by these materials including the current significant market drivers of price and availability coupled with consumer and retailer preferences. Future developments with hydrocolloids will recognise the value of nutritional and therapeutic benefits in addition to the functional attributes.
1.1 INTRODUCTION
‘Little known and yet ubiquitous in virtually all processed foods’. This statement summarises the role of stabilisers, thickeners and gelling agents in today’s food industry. It is virtually impossible to list the multitude of functions that these additives have in making foods look, feel and taste like they do. Such a list is virtually impossible, not only because it is so long and all encompassing, but also because it is changing and growing all the time. New uses and functions for these unique ingredients are constantly being found.
1.1.1 Scope
Within the food industry, stabilisers, thickeners and gelling agents are often more simply referred to as food hydrocolloids. The hydrocolloids traditionally used in food thickening and gelling include, but are not limited to, the following: agar, alginates, arabic, carrageenan, cassia tora, carboxymethyl cellulose, gelatin, gellan, guar, karaya, konjac, locust bean gum, methyl cellulose, hydroxypropylmethyl cellulose, microcrystalline cellulose, pectin, starches, tara, tragacanth and xanthan.
This book deals with all of these materials in a structured fashion starting with raw materials, followed by the production process and ending with application-related information. Chemical structure and conformation, viscosity and gelation charts and many food formulations are included for each ingredient in separate chapters. Readers will obtain a good overview of scientific, technical and commercial aspects for each material.
1.1.2 Definition
All the stabilisers, thickeners and gelling agents covered in this book are also known and described as ‘food hydrocolloids’ implying that functional properties are obtained by mixing them with water. A strict definition of a hydrocolloid is, however, difficult. Ask ten scientists what is a hydrocolloid and it is likely that ten different answers will be obtained. These could include statements as follows:
  • A colloidal substance obtained from…
  • A material that hydrates in water…
  • A colloid forming a suspension and not a true solution in water…
  • A synonym for gum (e.g. guar gum, locust bean gum, gum arabic…)
  • A macromolecule, such as a carbohydrate polymer or a protein, that is water soluble…
Many of these ingredients are carbohydrates but at least one important hydrocolloid, gelatin, is a protein. Most are agricultural derivatives but some are biotechnology derived, and gelatin, of course, is an animal product. This volume presents some scientific information but focuses more on the ‘real world’ of application-related data that will be of most benefit to food technologists and food formulators. Issues of functional properties, synergy, production and raw materials are most relevant to readers, but molecular structure and chemical definition have also been covered.
1.1.3 Classification
The hydrocolloids are treated in alphabetical order in this book, but readers should bear in mind that there are several methods of grouping them. Raw material origin has been used to classify them, for example as seaweed extracts, seed gums, fermentation products or plant exudates. Their general functional properties may also be used to classify them as thickeners, stabilisers or gelling agents. More recently, their commercial availability and price stability have been used as a differentiating factor. Those that are commercially steady in availability and price include the cellulose derivatives and fermentation products, such as xanthan and gellan gum. On the other hand, notorious for their instability in terms of price and availability are guar gum, locust bean gum and gum arabic. More recent developments may allow a further aspect of classification and differentiation, namely nutritional and therapeutic function. Future research may uncover yet more functions for these versatile food wonders.
1.1.4 Differentiated grades
Many, if not all, of the thickening and gelling agents for food are available in a wide range of differentiated grades. Starch is a good example. There are literally hundreds of different food starches based on different raw materials and production process conditions. A doublederivatised, waxy maize starch is totally different from, for example, a pregelatinised potato starch. Cellulose derivatives, such as carboxymethyl cellulose, microcrystalline cellulose, methyl cellulose and hydroxypropylmethyl cellulose, come in a virtually limitless range of differentiated grades depending on the degree of substitution and other processing factors. A large number of ‘new’ and ‘differentiated’ properties have been and continue to be developed for hydrocolloids that fall under an ‘umbrella category’; for example methyl cellulose, hydroxypropylmethyl cellulose and microcrystalline cellulose can be produced in a multitude of grades to suit a wide range of specific functional needs. Xanthan is offered in different mesh sizes, rapidly hydrating, brine tolerant and/or as a clarified grade. New versions are constantly being developed and assure the specialty future of at least part of this market.
1.2 FUNCTIONAL PROPERTIES
The following is a brief overview of the key functional properties for which these ingredients are used. Nutritional properties are relatively new and nutraceutical or health-enhancing properties are even more recent. Further work is sure to advance the use of hydrocolloids beyond modification of the rheology of foods.
1.2.1 Viscosity
Viscosity is probably one of the most widely used properties. In this respect, hydrocolloids are often used in systems where the oil or fat content has been reduced or eliminated through substitution with water. The hydrocolloid thickens water, which, in turn, replaces the fat or oil to give a product with similar properties to the full-fat food. A typical application for this function is reduced-fat salad dressings. In other cases, the thickened water simply adds body, texture and mouthfeel to a food such as table syrups, particularly low-calorie syrups.
1.2.2 Stability
If oil or fat is partially removed from a formulation and is replaced with thickened water, an emulsion is usually formed. Often the function of the hydrocolloid is to stabilise the emulsion, to prevent separation and, in the case of frozen foods, to control ice crystal formation. New technology and new ingredients have been developed specifically to address the problem of ice crystals in frozen foods, but hydrocolloids will continue to play a role. Virtually every ice cream product sold in retail outlets is stabilised with carrageenan, locust bean gum and/or guar gum. Low-fat salad dressings, discussed above, also benefit from emulsion-stabilising properties.
1.2.3 Suspension
If insoluble particles are included in the thickened product then separation and settling should be eliminated or at least minimised. Some hydrocolloids create solutions with a ‘yield point’ that will keep particles immobilised in suspension. Salad dressing is a good example of this and xanthan gum is the typical hydrocolloid to supply this functionality.
1.2.4 Gelation
One of the key texturising aspects of hydrocolloids is the ability to gel and solidify fluid products. For example, in gelled milk desserts, even low levels of carrageenan will form a solid milk gel. Other classic gelling agents are pectin, gelatin and agar. Many others, however, will form a gel under specific conditions. Certain grades of alginates form gels with calcium ions. Xanthan and locust bean gum do not gel individually but together they display synergy and form a strong cohesive gel. Methyl cellulose and hydroxypropylmethyl cellulose are unusual in forming solutions that reversibly thicken or gel when heated. The food industry has a myriad of gelling applications ranging from soft, elastic gels to hard and brittle gels.
1.2.5 Nutritional and nutraceutical
There is already a wide use of some hydrocolloids, arabic and guar gum, for example, as sources of soluble dietary fibre. Much research has been conducted in the nutraceutical benefits of hydrocolloids. Potential benefits range from cholesterol reduction to cancer risk prevention. Their use in weight loss programmes is already widespread and likely to expand further.
1.3 REGULATORY ENVIRONMENT
1.3.1 Background
The use of hydrocolloids in food has been steadily evolving. Pectin, agar, starches and gelatin have been used for centuries. They are amongst the few hydrocolloids that are sold directly to consumers at the retail level. These are the hydrocolloids with which the consumer is most familiar and comfortable. Until the 1980s and 1990s, gelatin was amongst the preferred and most label-friendly hydrocolloids, but this changed rapidly and dramatically with the advent of bovine spongiform encephalopathy (BSE), otherwise known as mad cow disease. Gelatin provides an example of the changing fortunes for individual hydrocolloids in the marketplace.
Many of the hydrocolloids in use today were developed long before regulatory approvals and constraints were imposed on use levels or in specific applications. Alginates, agar and carrageenan, for example, were extracted from seaweeds some of which were eaten as a basic food. Red seaweeds have long been used as a food. In Ireland, ‘carrageen’ was used to gel dairy products centuries ago. Extracts from such seaweeds were therefore deemed safe for use in food. This principle of ingredients and extracts thereof that are ‘generally recognised as safe’ (GRAS) is still in use today albeit under more rigorous review. Many of the more recent texturising options offered to food technologists derive from differentiated hydrocolloids based on materials that are currently approved. Carrageenan, for example, can be modified in many ways. There is lambda, kappa and iota carrageenan. There is a refined version produced through alcohol precipitation or specific precipitation with potassium chloride (the ‘gel press’ process) and there is a semi-refined carrageenan produced through a much simpler process. Semi-refined carrageenan made its way into the texturising world only in the 1980s and 1990s, whereas refined carrageenan has been offered for 60–70 years or more.
1.3.2 Legislation
Regulatory approval of a food ingredient is critical. Without approval of the appropriate government bodies, the additive has no market or function in food. Nowadays, obtaining regulatory approval for a new ingredient is a very costly and time-consuming process. The approval process itself is evolving and has opened up opportunities for differentiated versions of existing products. This has allowed for continued improvement and innovation to be offered to food formulators.
Labelling is a key factor in marketing any food ingredient. The rules governing food label nutritional information have changed significantly. There has been little impact on hydrocolloids other than fibre claims. There are literally hundreds of differentiated food starches. On the food label, however, starches are simply segmented into modified or native starches. Dozens of grades of carboxymethyl cellulose are produced, but they are all simply called carboxymethyl cellulose or cellulose gum. In Europe, E-numbers have beene stablished for all hydrocolloids. Often, however, for marketing reasons, food processors elect to replace the E-number with the accepted name of the additive. For example, locust bean gum, guar gum and carrageenan are often declared instead of E410, E412 and E407, respectively.
Regulatory authorities strictly control the approval of food additives. Chemical modifications are generally not allowed with the exception of starches, cellulose derivatives and propylene glycol alginate. Physical and enzymatic modification, however, is allowed. Physically modified pectin, sold under the name SlendidTM by CP Kelco Division of JM Huber, is an example. Some new hydrocolloids are brought to market under the GRAS designation, such as tara gum, konjac and pullulan. Gellan gum is one of the last hydrocolloids to go through a full food additive petition on a global scale. Its approval took many years and tens of millions of dollars of research and lobbying effort. Nearly 20 years after its approval, gellan gum has not yet reached commercial volumes that justify the cost of bringing it to market. These high stakes and high risks probably mean that no new hydrocolloid will be taken through a full approval process in the foreseeable future. Cassia gum has recently been approved in France (August 2008) and more widespread approval in the EU is expected soon. Approval for human food in the USA is still pending.
Genetic engineering could offer a tremendous opportunity for new functional developments in hydrocolloids. Bio-fermentation products such as xanthan and gellan gum could be manipulated to provide specific functional properties not now available. Seaweed, seed or other agricultural raw materials could be genetically enhanced. Giant, rapidly growing kelp could be programmed to produce more than alginates. The time for a carob tree to reach maturity and give a commercially viable yield could be reduced from the required 12–15 years. All these scenarios for improved production currently have a lid tightly sealed over them by consumer concerns. This is not to say that future generations and future nutritional conditions will not radically change.
1.3.3 Consumer concerns
Readers of this book must bear in mind one fundamental concept in terms of markets for food hydrocolloids: ‘The perception of consumers is the reality of hydrocolloid producers.’ In other words, whatever the scientific facts, it is the consumers’ perceptions and resulting action or inaction that dictates the commercial future of any food ingredient, including hydrocolloids. In terms of perception and label image, pectin probably has the best and most friendly image. Seaweed extracts such as agar, carrageenan and alginates are also ‘label friendly’. Cellulose derivatives have a ‘variable’ image in the mind of consumers. Terms such as carbohydrate gum and vegetable gum, used in the USA to describe methyl cellulose and hydroxypropylmethyl cellulose, are very label friendly. On the other hand, a name such as carboxymethyl cellulose has a very chemical connotation, but its synonym, cellulose gum, is much more label friendly. This is the main reason why EU authorities were lobbied to allow cellulose gum on the label.
Until the late 1980s and early 1990s, gelatin had an excellent label image, but that changed dramatically with the advent of BSE or mad cow disease as it is more commonly known. Consumers made a perceptual link between gelatin and BSE. Gelatin consumption suffered dramatically and most large food formulators made strong efforts to replace or eliminate the use of gelatin. All the scientific evidence indicates that there is no risk of the BSE prion being found in gelatin, but consumer concerns and their effect on buying behaviour are often more emotional than rational and scientific.
1.4 COMMERCIAL ENVIRONMENT
1.4.1 Global market
The global market v...

Table of contents

  1. Cover
  2. Dedication
  3. Title page
  4. Copyright
  5. Preface
  6. Acknowledgements
  7. Contributors
  8. 1: Introduction
  9. 2: Acacia Gum (Gum Arabic)
  10. 3: Agar
  11. 4: Alginates
  12. 5: Carrageenan
  13. 6: Cellulose Derivatives
  14. 7: Gelatine
  15. 8: Gellan Gum
  16. 9: Gum Tragacanth and Karaya
  17. 10: Inulin
  18. 11: Konjac Glucomannan
  19. 12: Microcrystalline Cellulose
  20. 13: Pectin
  21. 14: Pullulan
  22. 15: Seed Gums
  23. 16: Starch
  24. 17: Xanthan Gum
  25. Colour plates
  26. Index
  27. Food Science and Technology