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Food products and their raw materials undergo
testing to ensure they meet food safety regulations. |
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Food Safety Testing |
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The information presented on this page is intended
to assist food processors with the identification of the analysis
that can be performed on their products. This information is by no
means complete. More information on food safety official analytical
methods could be found at AOAC website
aoac.org
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Most of the rapid allergen test kits are
enzyme-linked immunosorbent assay or ELISA-based tests that detect
and measure a specific allergen in food samples. For example, this
test could be use to screen for the presence of cross-contaminants
in food products due to allergen residues. The test kits compare
samples against known levels of allergen by a colorimetric reaction.
Results are obtained within 2 to 3 hours and they can be quantified
using optical instrumentation. Also, allergen strip tests screen
samples for food allergen at specific concentration in a few minutes
(10-20 min). Both the ELISA test kits and the strip tests require a
minimal amount of training and equipment and are commonly used.
Commercial testing for egg (ovalbumin, ovomucoid),
peanuts (Ara h1, Ara h2), wheat (gliadin), hazelnut, milk (casein,
b-lactoglobulin), crustacean (tropomyosin), and soy residues are
available through several manufacturers (e.x. Biotrace
International, Neogen Corporation, R-Biopharm, Elisa Systems, etc).
Food allergen methodologies (Health Canada)
Food allergen test kits - AOAC performance
tested
List of test kits for allergen detection reviewed by AOAC Research
Institute and found to perform according to the manufacturer’s
specifications. |
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Microbial testing provides the detection and
quantification of pathogens and spoilage microorganisms in a variety
of products. Not only do these analyses allow processors to address
food safety issues if pathogenic bacteria are detected, but they
also predict the shelf life of a product when evaluating spoilage
microorganisms.
A list of suppliers of microbial rapid tests
is provided on the ‘Analytical
Testing’- supplier section.
Culture techniques,
which are commonly used in microbiology, rely on the growth of
microorganisms under specific conditions (e.x. time, temperature,
oxygen content, pH and pressure) in liquid or on solid media
containing nutrients. Culture methods using standard media require
between 1 to 7 days for detecting the presence of microorganisms.
Often, an enrichment step and/or a confirmation procedure is
required before and after microbial detection, respectively. |
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Biochemical and enzymatic methods
Rapid methods for microbial testing assess the
microbial population through the metabolic activity of the cells.
Such techniques include chromogenic media, colorimetry, ATP
(adenosine triphosphate) determination, protein detection and
biochemical kits.
- Chromogenic media for culture
techniques. This method
relies on the detection of enzymatic activities of target
microorganisms by the addition of dyes or organic compounds.
Microorganisms growing in the presence of these compounds may
fluoresce under UV light or produce distinctive colours.
Compared to a standard media analysis, this method enables more
sensitivity and rapid analysis (1)(within 24 hours). Chromogenic
media to identify Listeria monocytogenes and E. coli
are commercially available (e.x. Bio-Rad, Weber Scientific,
etc).
- Colorimetry
or optical systems measure microbial
growth by monitoring pH and other biochemical reactions that
generate a color change as microorganisms grow and metabolize in
a culture broth. Test for the detection of coliforms, E. coli,
yeast, molds, lactic acid bacteria, Listeria spp., and Enterobacteriaceae are commercially available (e.x. Neogen
Corporation).
- ATP Bioluminescence.
ATP, which is the energy source in all living cells, produces
light in the presence of luciferin-luciferase, oxygen and
magnesium. It is believed that the amount of light generated is
related to the amount of ATP, and therefore biomass. However,
ATP technique measures all organic matter on the surface,
instead of only microbial contaminants (2). In other word, ATP
systems could detect ATP on a food contact surface but does not
identify the source. This is why this method is more used as a
hygienic indicator than bacteria quantification system. ATP
swaps are commercially available (e.x. BioTrace Bev-Trace;
Cogent MLS; Millipore Milliflex; Celsis CellScan).
- Protein detection
is used to evaluate in real time (within minutes) if the
cleaning operation in a food plant has been carried out to a
satisfactory standard. These hygiene indicators can be used as a
tool to help improve the sanitation performance in your plant.
Results are evident with a change in color. Minimal training is
required. (e.x. BioTrace provides several kits for protein
detection).
- Biochemical and enzymatic
identification kits. These
kits are capable of identifying microorganisms by combining a
series of biochemical tests and a database developed by the
kit’s manufacturer. Each media included in the test kit system
is inoculated and the color reactions of each media provide data
for the organism detection. A minimum of 24 hours is required
for reliable results. Test kits such as API system, Enterotube
II, etc are commercially available. Enterotube II (Roche
Diagnostics) was developed to identify species of the Enterobacteriaceae. Advantages of this system include speed
and ease of inoculation. On the other hand, API system (bioMérieux)
is available for Enterobacteriaceae, as well as, gram
negative non-Enterobacteriaceae, Campylobacter spp.,
Lactobacillus, Staphylococci, yeast, etc. This
system has an excellent data base and is easy to inoculate,
however, readings and interpretation of reactions require
training.
- Electrical methods,
such as the use of impedance, conductance and capacitance
determine the bacterial growth. This method relies on the fact
that metabolites produced by microbial metabolism during growth,
increase the conductivity and decrease the resistance of the
media. Results could be obtained within hours. The detection
time varies depending on a few variables: the temperature at
which the assay is conducted, the medium, the generation time of
the bacteria and the inhibition properties of the media. Systems
that measure the impedance are commercially available (e.x.
Bactometer, RABIT for Windows™, BacTrac, etc).
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Antibody-based methods
Enzyme immunoassay (EIA), also known as
enzyme-linked immunosorbent assay (ELISA), is a common technique for
antibody-based detection of microorganisms. This method ensures
sensitivity and specificity for pathogen detection. Results can be
interpreted visually (qualitatively) or using an instrumental
read-out (quantitatively). Test kits for the detection of
Salmonella, Listeria, Campylobacter, E. coli
0157:H7, Pseudomonas, Staphylococcus aureus are
commercially available (e.x. BioControl Systems, Bio Trace, etc).
Nucleic acid-based methods
Compared to antibody-based methods, there are
relatively few commercialized versions of nucleic acid-based
methods.
- Hybridization. This method is
based on the detection of target microorganisms by the
identification and binding of specific DNA sequences unique to a
particular microbial group. After the binding reaction occurs,
detection is accomplished colorimetrically (2). Commercial test
kits (GENE-TRACK®, AccuPROBE®) for the detection of
Salmonella, Listeria, E. coli,
Staphylococcus, Campylobacter and Yersinia are
available (e.x. Neogen Corporation, Gen-Probe).
- Polymerase Chain Reaction (PCR)
is
based on the identification of a very specific DNA sequence from
a target microorganism, followed by amplification of the
sequence for the detection of the microorganism (2). This
technology offers a specific and reliable detection of
pathogenic bacteria within 24 hours. Test kits for the detection
of Listeria monocytogenes, E. coli 0157:H7, and
Campylobacter jejuni are commercially available (e.x.
Applied BioSystems, BioControl).
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Related Links on Microbial Testing
Official Methods for the Microbiological
Analysis of Foods (Health Canada)
Microbiological test kits - AOAC performance
tested
List of test kits for microbial detection reviewed by AOAC Research
Institute and found to perform according to the manufacturer’s
specifications.
Mycotoxins (toxins produced by certain species
of mold) such as aflatoxin, deoxynivalenol (DON), fumonisin,
ochratoxin, T-2 toxin, zearalenone and histamine; as well as
bacterial toxins (e.x. bacillus, staphylococcus enterotoxins) can be
detected by ELISA based test kits. These kits are commercially
available. (e.x. R-Biopharm, Biotrace International, Neogen
Corporation, Elisa Technologies). A list of these suppliers is
provided in the
‘Analytical Testing Suppliers’ section.
Toxin test kits - AOAC performance tested
List of test kits reviewed by AOAC Research Institute and found to
perform according to the manufacturer’s specifications.
Antibiotic test kits - AOAC performance tested
List of test kits reviewed by AOAC Research Institute and found to
perform according to the manufacturer’s specifications.
- Downes, F.P.
Compendium of methods
for the microbiological examination of foods. 4th ed.. American
Public Health Association, Washington, DC, 2001.
- Illsley, R.A., Jackson, E.D., McRae K.B.,
and Feirtag, J.M. 2000. A comparison of commercial ATP
bioluminescence hygiene monitoring systems with standard surface
monitoring techniques in a baking facility. Dairy Food
Environmental Sanitation 20:522-526.
- McIntyre, D.A. 2004 Comparison of total
cost, method efficiency, and laboratory productivity of selected
microbiological test kits. Dairy Food Environmental Sanitation
24:398-407..
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For information on the Food Safety Program contact the
CVO/Food Safety Knowledge Centre. For technical
information, call 204-795-7968 in Winnipeg; or e-mail
foodsafety@gov.mb.ca. For general information, contact your
local GO
Centre.
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