BLBS102-c43 BLBS102-Simpson March 21, 2012 14:30 Trim: 276mm X 219mm Printer Name: Yet to Come
830 Part 8: Food Safety and Food Allergens
levels in fish because at the reduced temperatures, both enzy-
matic and microbial activities are considerably reduced, so the
rates of formation of the biogenic amines and their accumulation
in the products are correspondingly reduced.
Salting
Salting can effectively inhibit biogenic amine formation partic-
ularly at high levels. In general, a higher salt content results in a
reduced biogenic amine formation. This is because the high salt
lowers theAwof the milieu, and this can inhibit both the micro-
bial and enzymatic activities that are required for the biogenic
amine formation.
Smoking
Smoking is a traditional method used to preserve fish. The fish
is smoked, then frozen, and transported. Histamine content is
found to increase during the smoking process and continues
to accumulate during subsequent freezing (Zotos et al. 1995).
Even though smoking may induce histamine production and
nitrosamines formation, the high temperature applied in smoking
can also curtail the growth and proliferation of harmful and/or
spoilage microorganisms (Martuscelli et al. 2009).
REGULATIONS
Since high level of biogenic amines, for example, histamine and
tyramine, are associated with food poisoning, their intake has to
be limited. Even though not all amines are equally toxic, and tox-
icological levels are hard to ascertain due to synergetic effects be-
tween amines, permissible limits have still been proposed. Thus,
fermented products that are prepared using good manufacturing
practices may be expected to contain histamine, tyramine, and
β-phenylethylamine concentrations of 50–100 , 100–800, and
30 mg/kg, respectively, and still considered safe and accept-
able for human consumption (Nout 1994). Levels of histamine,
cadaverine, putrescine, tyramine, andβ-phenylethylamine in
sauerkraut must not exceed 10, 25, 50, 20, and 5 mg/kg, respec-
tively, and the total amount of biogenic amines in fish, cheese,
and sauerkraut must be less than 300 mg/kg (Shalaby 1996).
Furthermore, biogenic amine intake greater than 40 mg in a
meal is potentially toxic.
As biogenic amines are not extremely toxic or associated with
many fatal incidences, there are few general regulations con-
trolling their concentration. Histamine, however, is a common
concern and different countries have set up their own standards
for these compounds in foods. For example, a level of 10 mg
histamine for every liter of wine is considered as acceptable in
Switzerland. In the United States, 20 mg histamine per 100 g
canned fish is considered unsafe for human consumption, and
50 mg histamine per 100 g canned fish is considered as a health
hazard by the Food and Drugs Administration (FDA 2001); the
European Economic Community has set the acceptable level of
histamine content in fish as 10–20 mg/100 g (Shalaby 1996);
the Canadian Food Inspection Agency, has set the action level
of histamine as 20 mg/100 g in fermented products and 10 mg/
100 g in scombroid fish products (CFIA 2005, Moret et al. 2005).
CONCLUSION
Biogenic amines are important food components found in many
fermented and non-fermented food production. They are present
as by-products of microbial activity in foods. The microorgan-
isms are either present naturally, added for fermentation pur-
poses, or are introduced through contamination. It is desirable
to minimize the formation of biogenic amines due to their ad-
verse effects on human health and their contribution to food
spoilage and food losses. In particular, the levels of tyramine
and histamine need to be below a certain threshold level in order
to prevent toxic responses.
The study of biogenic amines is an ongoing field of research,
with several foci. Analytical methods are constantly being de-
veloped and/or improved in order to quantify their presence
more rapidly and accurately. Further studies are needed to gen-
erate the basic knowledge on the effects of ingestion, toxic lim-
its, and interactions with other biological molecules, to facili-
tate the rationalization and formulation of more useful recom-
mendations and regulations regarding their safe levels in food
products.
REFERENCES
Ababouch L et al. 1991. Quantitative changes in bacteria, amino
acids and biogenic amines in sardine (Sardina pilchardus) stored
at ambient temperature (25–28◦C)andinice.Int J Food Sci
Technol26: 297–306.
Adamson RH, Thorgeirsson UP. 1995. Carcinogens in foods: hete-
rocyclic amines and cancer and heart disease.Adv Exp Med Biol
369: 211–220.
Aston-Jones G et al. 2002. Prominent projections from the orbital
prefrontal cortex to the locus coeruleus in monkey.Soc Neurosci
Abstr28: 86–89.
Attaran RR, Probst F. 2002. Histamine fish poisoning: a common but
frequently misdiagnosed condition.Emerg Med J19: 474–475.
Aygun O et al. 1999. Comparison of ELISA and HPLC for the
determination of histamine in cheese.J Agric Food Chem47:
1961–1964.
Balamatsia CC et al. 2006. Correlation between microbial flora,
sensory changes and biogenic amines formation in fresh chicken
meat stored aerobically or under modified atmosphere packaging
at 4◦C: possible role of biogenic amines as spoilage indicators.
Antonie van Leeuwenhoek89: 9–17.
Battcock M, Azam-Ali S. 1998.Fermented Fruits and Vegetables:
A Global Perspective. Food and Agruiculture Organization of the
United Nations, Rome.
Becker K et al. 2001. Histamine poisoning associated with eating
tuna burgers.J Am Med Assoc285: 1327–1330.
Berger M et al. 2009. The expanded biology of serotonin.Annu Rev
Med60: 355–366.
Bodemer S et al. 1999. Biogenic amines in foods: histamine and
food processing.Inflamm Res48: 296–300.
Borade PS et al. 2007. A fishy case of sudden near fatal hypotension.
Resuscitation72: 158–160.