Food microbiology is the study of the
microorganisms that inhabit, create, or
contaminatefood. This includes the study of microorganisms causing food spoilage;
pathogens that may cause disease (especially if food is improperly cooked or stored); microbes used to produce
fermented foods such as
cheese,
yogurt,
bread,
beer, and
wine; and microbes with other useful roles, such as producing
probiotics.[1][2][3][4]
Subgroups of bacteria that affect food
In the study of bacteria in food, important groups have been subdivided based on certain characteristics. These groupings are not of taxonomic significance:[5]
Lipolytic bacteria hydrolyze
triglycerides by production of extracellular
lipases. This group includes bacteria species from the Micrococcus, Staphylococcus, Pseudomonas, Alteromonas and Flavobacterium genera.
Saccharolytic bacteria hydrolyze
complex carbohydrates. This group includes bacteria species from the Bacillus, Clostridium, Aeromonas, Pseudomonas and Enterobacter genera.
Osmophilic bacteria, while less osmophilic than yeasts and molds, can tolerate a relatively higher osmotic environment.
Aerobes require oxygen, while anaerobes are inhibited by it. Facultative anaerobes can grow with and without oxygen.
Some bacteria can produce gases during metabolism of nutrients, others produce slime by synthesizing polysaccharides.
Spore producing bacteria are further divided into subgroups of aerobic, anaerobic, flat sour, thermophilic and sulfide-producing.
Coliforms, including
fecal coliforms (such as e.coli) are used as a measure of sanitation. Enteric pathogens can cause gastrointestinal infection and may be included in this group.
Food safety
Food safety is a major focus of food microbiology. Numerous agents of disease and
pathogens are readily transmitted via food which includes
bacteria and
viruses. Microbial
toxins are also possible contaminants of food; However,
microorganisms and their products can also be used to combat these pathogenic microbes.
Probiotic bacteria, including those that produce
bacteriocins can kill and inhibit
pathogens. Alternatively, purified
bacteriocins such as
nisin can be added directly to food products. Finally,
bacteriophages, viruses that only infect bacteria can be
used to kill bacterial pathogens.[6] Thorough preparation of food, including proper
cooking, eliminates most bacteria and viruses. However, toxins produced by contaminants may not be liable to change to non-toxic forms by heating or cooking the contaminated food due to other safety conditions.[citation needed]
To ensure
safety of food products, microbiological tests such as testing for
pathogens and spoilage organisms are required. This way the risk of contamination under normal use conditions can be examined and
food poisoning outbreaks can be prevented. Testing of food products and ingredients is important along the whole
supply chain as possible flaws of products can occur at every stage of production.[10] Apart from detecting spoilage, microbiological tests can also determine germ content, identify yeasts and molds, and Salmonella. For Salmonella, scientists are also developing rapid and portable technologies capable of identifying unique variants of Salmonella.[11]
Polymerase chain reaction (PCR) is a quick and inexpensive method to generate numbers of copies of a DNA fragment at a specific band ("PCR (Polymerase Chain Reaction)," 2008). For that reason, scientists are using PCR to detect different kinds of viruses or bacteria, such as HIV and anthrax based on their unique DNA patterns. Various kits are commercially available to help in food pathogen nucleic acids extraction,[12] PCR detection, and differentiation.[13] The detection of bacterial strands in food products is very important to everyone in the world, for it helps prevent the occurrence of food borne illness. Therefore, PCR is recognized as a DNA detector in order to amplify and trace the presence of pathogenic strands in different processed food.[citation needed]
^Rehm BHA, ed. (2009). Microbial Production of Biopolymers and Polymer Precursors: Applications and Perspectives. Caister Academic Press.
ISBN978-1-904455-36-3.
^Remminghorst & Rehm (2009). "Microbial Production of Alginate: Biosynthesis and Applications". Microbial Production of Biopolymers and Polymer Precursors. Caister Academic Press.
ISBN978-1-904455-36-3.
^Shih & Wu (2009). "Biosynthesis and Application of Poly(gamma-glutamic acid)". Microbial Production of Biopolymers and Polymer Precursors. Caister Academic Press.
ISBN978-1-904455-36-3.