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Food Microbiology
Martin R Adams, Maurice O Moss, Peter McClure
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eBook - ePub
Food Microbiology
Martin R Adams, Maurice O Moss, Peter McClure
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Food Microbiology by Adams and Moss has been a popular textbook since it was first published in 1995. Now in its fourth edition, Peter McClure joins the highly successful authorship in order to bring the book right up to date.
Maintaining its general structure and philosophy to encompass modern food microbiology, this new edition provides updated and revised individual chapters and uses new examples to illustrate incidents with particular attention being paid to images. Thorough and accessible, it is designed for students in the biological sciences, biotechnology and food science as well as a valuable resource for researchers, teachers and practising food microbiologists.
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CHAPTER 1
The Scope of Food Microbiology
Outlines the content of the book and puts the chapters into context. The foods that we eat are rarely if ever sterile, they carry microbial associations whose composition depends upon which organisms gain access and how they grow, survive and interact in the food over time. The micro-organisms can cause spoilage, foodborne illness or can transform a food’s properties in a beneficial way – food fermentation; all of which are discussed in later chapters.
Microbiology is the science which includes the study of the occurrence and significance of bacteria, fungi, protozoa and algae which are the beginning and ending of intricate food chains upon which all life depends. Most food chains begin wherever photosynthetic organisms can trap light energy and use it to synthesize large molecules from carbon dioxide, water and mineral salts forming the proteins, fats and carbohydrates which all other living creatures use for food.
Within and on the bodies of all living creatures, as well as in soil and water, micro-organisms build up and change molecules, extracting energy and growth substances. They also help to control population levels of higher animals and plants by parasitism and pathogenicity.
When plants and animals die, their protective antimicrobial systems cease to function so that, sooner or later, decay begins liberating the smaller molecules for re-use by plants. Without human intervention, growth, death, decay and regrowth would form an intricate web of plants, animals and micro-organisms, varying with changes in climate and often showing apparently chaotic fluctuations in populations of individual species, but inherently balanced in numbers between producing, consuming and recycling groups.
In the distant past, these cycles of growth and decay would have been little influenced by the small human population that could be supported by the hunting and gathering of food. About 10 000 years ago however, the deliberate cultivation of plants and herding of animals started in some areas of the world. The increased productivity of the land and the improved nutrition that resulted led to population growth and a probable increase in the average lifespan. The availability of food surpluses also liberated some from daily toil in the fields and stimulated the development of specialized crafts, urban centres, and trade – in short, civilization.
1.1 MICRO-ORGANISMS AND FOOD
The foods that we eat are rarely if ever sterile, they carry microbial associations whose composition depends upon which organisms gain access and how they grow, survive and interact in the food over time. The micro-organisms present will originate from the natural microflora of the raw material and those organisms introduced in the course of harvesting/slaughter, processing, storage and distribution (see Chapters 2 and 5). The numerical balance between the various types will be determined by the properties of the food, its storage environment, properties of the organisms themselves and the effects of processing. These factors are discussed in more detail in Chapters 3 and 4.
In most cases this microflora has no discernible effect and the food is consumed without objection and with no adverse consequences. In some instances though, micro-organisms manifest their presence in one of several ways:
- (i) they can cause spoilage;
- (ii) they can cause foodborne illness;
- (iii) they can transform a food’s properties in a beneficial way – food fermentation.
1.1.1 Food Spoilage/Preservation
From the earliest times, storage of stable nuts and grains for winter provision is likely to have been a feature shared with many other animals but, with the advent of agriculture, the safe storage of surplus production assumed greater importance if seasonal growth patterns were to be used most effectively. Food preservation techniques based on sound, if then unknown, microbiological principles were developed empirically to arrest or retard the natural processes of decay. The staple foods for most parts of the world were the seeds – rice, wheat, sorghum, millet, maize, oats and barley – which would keep for one or two seasons if adequately dried, and it seems probable that most early methods of food preservation depended largely on water activity reduction in the form of solar drying, salting, storing in concentrated sugar solutions or smoking over a fire.
The industrial revolution which started in Britain in the late 18th century provided a new impetus to the development of food preservation techniques. It produced a massive growth of population in the new industrial centres which had somehow to be fed; a problem which many thought would never be solved satisfactorily. Such views were often based upon the work of the English cleric Thomas Malthus who in his ‘Essay on Population’ observed that the inevitable consequence of the exponential growth in population and the arithmetic growth in agricultural productivity would be over-population and mass starvation. This in fact proved not to be the case as the 19th century saw the development of substantial food preservation industries based around the use of chilling, canning and freezing and the first large scale importation of foods from distant producers.
To this day we are not free from concerns about over-population. Globally there is sufficient food to feed the world’s current population, estimated to be 7 billion in 2014, and world grain production has managed to keep pace with the increasing population. There is however little room for complacency. Despite today’s overall sufficiency, it is recognised that malnutrition affects more than 870 million people and contributes to the death of 2.6 million children each year. The principal cause of this is not insufficiency however, but poverty which leaves an estimated one-fifth of the world’s population without the means to meet their daily needs. Any long-term solution to this must lie in improving the economic status of those in the poorest countries and this, in its train, is likely to bring a decrease in population growth rate similar to that seen in recent years in more affluent countries.
In any event, the world’s food supply will need to increase to keep pace with population, projected to reach 9 billion by 2050, and this will have its own environmental and social costs in terms of the more intensive exploitation of land and sea resources. One way of mitigating this is to reduce the substantial pre- and post-harvest losses which occur, particularly in developing countries where the problems of food supply are often most acute. One study conducted on behalf of the FAO estimated that roughly a third of food produced globally is either lost or wasted, amounting to 1.3 billion tonnes per year. In low income countries losses were mostly concentrated in the earlier stages of the food chain where they were typically of the order of 20–30% for commodities such as cereals, fish, meat products, oilseeds and pulses, but were higher for root crops and tubers and up to 50% for fruits and vegetables (Global Food Losses & Food Waste, FAO 2011).
Clearly reduction in such losses can make an important contribution to feeding the world’s population. While it is unrealistic to claim that food microbiology offers all the answers, the expertise of the food microbiologist can make an important contribution. In part, this will lie in helping to extend the application of current knowledge and techniques but there is also a recognized need for simple, low-cost, effective methods for improving food storage and preservation in developing countries. Problems for the food microbiologist will not however disappear as a result of successful development programmes. Increasing wealth will lead to changes in patterns of food consumption and changing demands on the food industry. Income increases among the poor have been shown to lead to increased demand for the basic food staples while in the better-off it leads to increased demand for more perishable animal products. To supply increasingly affluent and expanding urban populations will require further extension of existing global food supply chains and will place great demands on the food microbiologist.
1.1.2 Food Safety
In addition to its undoubted value, food has a long association with the transmission of disease. Regulations governing food hygiene can be found in numerous early sources such as the Old Testament, and the writings of Confucius, Hinduism and Islam. Such early writers had at best only a vague conception of the true causes of foodborne illness and many of their prescriptions probably had only a slight effect on its incidence. Even today, despite our hugely increased knowledge, the global burden of foodborne diseases and its impact on development and trade is not known, although it is acknowledged to be substantial. In 2012, for example, diarrhoeal disease was the cause of 10–20% of the 6.6 million deaths in children under 5 in poorer countries.
The various ways in which foods can transmit illness, the extent of the problem and the principal causative agents are described in more detail in Chapters 6, 7 and 8.
1.1.3 Fermentation
Microbes can however play a positive role in food. They can be consumed as foods in themselves as in the edible fungi, mycoprotein and algae. They can also effect desirable transformations in a food, changing its properties in a way that is beneficial. The different aspects of this and examples of important fermented food products are discussed in Chapter 9.
1.2 MICROBIOLOGICAL QUALITY ASSURANCE
Food microbiology is unashamedly an applied science and the food microbiologist’s principal function is to help assure a supply of whole-some and safe food to the consumer. This must accommodate the impact of social and other changes taking place such as greater affluence, increasing consumption of food away from the home, reduced frequency of food shopping, increased international travel and the development of new food processing technologies. To do this requires the synthesis and systematic application of our knowledge of food microbiology to practical situations, to ensure the consistent production of safe, stable and affordable foods. How we attempt to do this is described in Chapter 11.
CHAPTER 2
Micro-organisms and Food Materials
Foods, by their very nature, need to be nutritious and metabolizable and it should be expected that they will offer suitable substrates for the growth and metabolism of micro-organisms. Before dealing with the details of the factors influencing this microbial activity, and their significance in the safe handling of foods, it is useful to examine the possible sources of micro-organisms in order to understand the ecology of contamination. In this chapter the authors describe some of the major sources of microorganisms which may contaminate food and cause problems of spoilage or create health risks when the food is consumed.
Foods, by their very nature, need to be nutritious and metabolizable and it should be expected that they will offer suitable substrates for the growth and metabolism of micro-organisms. Before dealing with the details of the factors influencing this microbial activity, and their significance in the safe handling of foods, it is useful to examine the possible sources of micro-organisms in order to understand the ecology of contamination.
2.1 DIVERSITY OF HABITAT
Viable micro-organisms may be found in a very wide range of habitats, from the coldest of brine ponds in the frozen wastes of polar regions, to the almost boiling water of hot springs. Indeed, it is now realized that actively growing bacteria occur at temperatures in excess of 100 °C in the thermal volcanic vents, at the bottom of the deeper parts of the oceans, where boiling is prevented by the very high hydrostatic pressure (see Section 3.2.5). Micro-organisms occur in the acidic wastes draining away from mine workings or the alkaline waters of soda lakes. They can be isolated from the black anaerobic silts of estuarine muds or the purest waters of biologically unproductive, or oligotrophic, lakes. In all these, and many other, habitats microbes play an important part in the recycling of organic and inorganic materials through their roles in the carbon, nitrogen and sulfur cycles (Figure 2.1). They thus play an important part in the maintenance of the stability of the biosphere.
Figure 2.1 Micro-organisms and the carbon, nitrogen and sulfur cycles.
The surfaces of plant structures such as leaves, flowers, fruits and especially the roots, as well as the surfaces and the guts of animals all have a rich microflora of bacteria, yeasts and filamentous fungi. This natural, or normal flora may affect the original quality of the raw ingredients used in the manufacture of foods, the kinds of contamination which may occur during processing, and the possibility of food spoilage or food associated illness. Thus, in considering the possible sources of micro-organisms as agents of food spoilage or food poisoning, it will be necessary to examine the natural flora of the food materials themselves, the flora introduced by processing and handling, and the possibility of chance contamination from the atmosphere, soil or water.
2.2 MICRO-ORGANISMS IN THE ATMOSPHERE
Perhaps one of the most hostile environments for many micro-organisms is the atmosphere. Suspended in the air, the tiny microbial propagule may be subjected to desiccation, to the damaging effects of radiant energy from the sun, and the chemical activity of elemental gaseous oxygen (O2) to which it will be intimately exposed. Many micro-organisms, especially Gram-negative bacteria, do indeed die very rapidly when suspended in air and yet, although none is able to grow and multiply in the atmosphere, a significant number of microbes are able to survive and use the turbulence of the air as a means of dispersal.
2.2.1 Airborne Bacteria
The quantitative determination of the numbers of viable microbial propagules in the atmosphere is not a simple job, requiring specialized sampling equipment, but a qualitative estimate can be obtained by simply exposing a Petri dish of an appropriate medium solidified with agar to the air for a measured period of time. Such air exposure plates frequently show a diverse range of colonies including a significant number which are pigmented (Figure 2.2).
Figure 2.2 Exposure plate showing air flora. Photo S. Park.
The bacterial flora can be shown to be dominated by Gram-positive rods and cocci unless there has been a very recent contamination of the air by an aerosol generated from an animal or human source, or from water. The pigmented colonies will often be of micrococci or corynebacteria and the large white-to-cream coloured colonies will frequently be of aerobic sporeforming rods of the genus Bacillus. There may also be small raised, tough colonies of the filamentous bacteria belonging to Streptomyces or a related genus of actinomycetes. The possession of pigments may protect micro-organisms from damage by both visible and ultraviolet radiation of sunlight and the...