ESTIMATION OF LEAD AND CADMIUM LEVELS IN FLESH OF SOME IMPORTED SALTED CANNED FISH

Document Type : Research article

Authors

1 Department of Food Hygiene, Fac. of Vet. Med., Sohag University, Sohag, Egypt

2 Department of Forensic Medicine and Toxicology Fac. of Vet. Med., Assiut Univerisity, Assiut, Egypt

Abstract

Fish accumulates substantial amounts of metals in their tissues especially muscles and thus, consider one of major dietary sources of these metals for humans. The objective of the present study is to determine the concentration of lead and cadmium levels in flesh of some imported salted canned fish (Sardine, Salmon and Anchovies) by Atomic Absorption Spectrophotometer with Graphite furnace. Fourty five imported canned salted fish were collected from different supermarkets in Sohag city produce during 2014.  Samples were divided into three groups (15 for each) according to the geographic areas of production (G1 from Thailand, G2 from Morocco and G3 from Spain). Each group was subdivided into three (5 each) subgroup (Sardine, Salmon and Anchovies). Our results revealed that lead mean± SE (wet weight) levels were 2.495± 0.013, 2.320±0.010, 0.271±0.047 ppm in sardine, 0.298±0.158, 0.452±0.127 ppm and 0.275±0.132  in salmon and 6.939±2.370, 2.060±0.061 and 2.691±0.473 ppm in anchovies flesh in G1, G2 and G3 respectively. For cadmium mean levels±SE (wet weight) were 0.063±0.011, 0.098±0.025 and 0.066±0.021 in sardine flesh, 0.037±0.009, 0.053±0.010 and 0.061±0.020 in salmon flesh and 1.007±0.093, 0.464±0.055 and 1.908±0.540 in Anchovies ppm, in G1, G2 and G3 respectively. According to data presented in this study, it can be concluded that lead levels in flesh of salted canned fish collected from Sohag city were above the Egyptian Organization for Standardization and Quality Control EOSQC. (1993) recommended limit in sardine and anchovies and below this limit in salmon. Cadmium values were below the established values in all samples except G2 of anchovies. It recommended that more research and assessments of seafood quality is needed to provide more data and help safeguard the health of consumers. 

Keywords


ESTIMATION OF LEAD AND CADMIUM LEVELS IN FLESH OF SOME IMPORTED SALTED CANNED FISH

 

NAHED M. ABDELAZIZ* and Z.M. ZAKY**

 

*Department of Food Hygiene, Fac. of Vet. Med., Sohag Univerisity, Sohag, Egypt.

** Department of Forensic Medicine and Toxicology Fac. of Vet. Med., Assiut Univerisity, Assiut, Egypt.

 

Email:  nahedvet2012@yahoo.com                                                        Assiut University web-site: www.aun.edu.eg

 

 

ABSTRACT

 

 

 

Fish accumulates substantial amounts of metals in their tissues especially muscles and thus, consider one of major dietary sources of these metals for humans. The objective of the present study is to determine the concentration of lead and cadmium levels in flesh of some imported salted canned fish (Sardine, Salmon and Anchovies) by Atomic Absorption Spectrophotometer with Graphite furnace. Fourty five imported canned salted fish were collected from different supermarkets in Sohag city produce during 2014.  Samples were divided into three groups (15 for each) according to the geographic areas of production (G1 from Thailand, G2 from Morocco and G3 from Spain). Each group was subdivided into three (5 each) subgroup (Sardine, Salmon and Anchovies). Our results revealed that lead mean± SE (wet weight) levels were 2.495± 0.013, 2.320±0.010, 0.271±0.047 ppm in sardine, 0.298±0.158, 0.452±0.127 ppm and 0.275±0.132  in salmon and 6.939±2.370, 2.060±0.061 and 2.691±0.473 ppm in anchovies flesh in G1, G2 and G3 respectively. For cadmium mean levels±SE (wet weight) were 0.063±0.011, 0.098±0.025 and 0.066±0.021 in sardine flesh, 0.037±0.009, 0.053±0.010 and 0.061±0.020 in salmon flesh and 1.007±0.093, 0.464±0.055 and 1.908±0.540 in Anchovies ppm, in G1, G2 and G3 respectively. According to data presented in this study, it can be concluded that lead levels in flesh of salted canned fish collected from Sohag city were above the Egyptian Organization for Standardization and Quality Control EOSQC. (1993) recommended limit in sardine and anchovies and below this limit in salmon. Cadmium values were below the established values in all samples except G2 of anchovies. It recommended that more research and assessments of seafood quality is needed to provide more data and help safeguard the health of consumers. 

 

 

Received at: 30/3/2015

 

Accepted: 30/4/2015

 

Key word: Lead and cadmium, Flesh, Imported salted canned fish.

 

 


INTRODUCTION

 

Fish is widely consumed in many parts of the world by humans because it has high protein content, low saturated fat and also contains omega fatty acids known to support good health (US EPA, 2004). It have been found to be good indicators of heavy metal contamination in aquatic systems (Burger et al., 2002).

 

Canned fishes in particular are well eaten in the developed world it is convenient and affordable for most working families (NOAA, 2002).

 

Fish may be contaminated by toxic elements during fish growth, transportation, and storage. Contamination may also occur during production, handling and canning process. Information on the metal content in canned fish is important to ensure that the fish consumed is safe for human consumption. The estimated weekly intakes of these metals by adults consuming different species of canned fish are also evaluated for possible human health risks (Ikem and Egiebor (2005).

 

Heavy metals are potential environmental contaminants with the capability of causing human health problems if present to excess in the food. They are given special attention throughout the world due to their toxic effects even at very low concentrations (Das, 1990). Several cases of human disease, disorders, malfunction and malformation of organs due to metal toxicity have been reported (Jarup, 2003).

 

Lead is a heavy metal that accumulates in the body and affects different systems and organs such as central and peripheral neural system, gastrointestinal tract, muscles, kidneys and hematopoietic system Ciobanu et al. (2012). Short-term exposure to high levels of lead can cause brain damage, paralysis (lead palsy), anemia and gastrointestinal symptoms. Longer-term exposure can cause damage to the kidneys, reproductive and immune systems in addition to effects on the nervous system (Rose et al., 2001).

 

Cadmium and lead are among the most abundant heavy metals and are particularly toxic. The excessive content of these metals in food is associated with etiology of a number of diseases (WHO, 1992, 1995).

 

International Agency for Research on Cancer (IARC) classified cadmium and lead as human carcinogen (IARC, 1993; Steenland and Boffetta, 2000).

 

Cadmium exposure induces bone damage, osteoporosis, and renal tubular dysfunction that leads to renal failure in long term (Ciobanu et al., 2012) and Engström et al. (2012), It is also associated with several cancers (Satarug, 2012) and Sawada et al. (2012).

 

The present study was carried out to determine the current levels of total lead and cadmium in the muscle tissue of canned salted fish samples, imported from different countries and compare with the guidelines set down by FAO/WHO (1992) and EOSQC (1993).

 

MATERIALS and METHODS

 

Sampling

A total of forty five imported salted canned fish (15 each of Sardine Salmon, and Anchovies) were collected from different markets in Sohag city, Egypt that divided according geographical areas of production during 2014 (G1, G2, G3).

 

Lead and cadmium were determined by using ZEEnit 700P Atomic Absorption Spectrophotometer with Graphite furnace (AASG) (Atomic Absorption Spectrophotometer model AnalytikjenaAG, USA) in the Central Laboratory of the Faculty of Veterinary Medicine, Assiut University, Egypt. 0.5 g was weighed into a set of digestion tubes. 10 ml of nitric acid was mixed into the sample vessels. Mixture of content of the digestion tubes were then digested by Microwave at a temperature of 60º C for 30 min. The digestion was cooling to room temperature and diluted with ultra-pure water to make a volume of 25 ml, put in clean glass vials and kept till analysis.

 

The combined stock standard (Pb and Cd (1000 ppm each) was prepared from reference standards and stored in the refrigerator until use. The method of calibration curve was used for calibration and quantification of the AAS to its effective position. The working standards were first determined to create the standard curve; this was followed by the measurement of the unknown analyses. The atomic absorption spectrophotometer was adjusted to specific wavelength corresponding to each of the metals to be measured.

 

Statistical Analysis

Statistical analysis was performed using SPSS 13.0 for Windows. Analysis of Variance (ANOVA) was used and statistical significance was set at P<0.05. Duncan Multiple Range Test was used to separate differences in treatment means.

 

 

RESULTS

 

Table 1: Mean lead levels ±SE in muscle of Sardine, Salmon, and Anchovies from Thailand (G1), Morocco (G2) and Spain (G3) and number of samples tested in each group (No).

 

Groups

      Sardine

      Salmon

     Anchovies

Mean

SE

NO.

Mean

SE

NO.

Mean

SE

NO.

G1

2.495

0.013

5

0.298

0.158

5

6.939

2.370

5

G2

2.320

0.010

5

0.452

0.127

5

2.060

0.061

5

G3

0.271

0.047

5

0.275

0.132

5

2.691

0.473

5

 

Figure (1) lead concentration (ppm) in tested (sardine, salmon and anchovies) samples

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Letters on bars (a, b, c) denote the significant differences among groups (P<0.05).

 

Table 2: Mean values ±SE of cadmium levels in muscle of Sardine

Salmon, and Anchovies from Thailand (G1), Morocco (G2), and Spain (G3) and number samples tested in each group (No).

 

Groups

        Sardine

     Salmon

      Anchovies

Mean

SE

NO.

Mean

SE

NO.

Mean

SE

NO.

G1

0.063

0.011

5

0.037

0.009

5

1.007

0.093

5

G2

0.098

0.025

5

0.053

0.010

5

0.464

0.055

5

G3

0.066

0.021

5

0.061

0.020

5

1.908

0.540

5

 

Figure (2) Cadmium concentrations (ppm) in fish species; Sardine, Salmon and Anchovies samples.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

NS means non-significant differences.

 

 

 


DISCUSSION

 

The average values of lead in G1, G2 and G3 in sardine showed were 2.495±0.013, 2.320±0.010, 0.271±0.047 ppm respectively which higher than (0.1 ppm) that recommended by EOSQC (1993)  while G3 had lower lead level than the limit of (0.5 ppm) that reported by FAO/WHO (1992). These result are similar to result recorded by Rafael (1975), 0.13-2.15 ppm in Spanish sardine, Olga Marta et al.(1991) recorded the levels of lead as 0.29-0.72 ppm in Costa Rica, also as Ashraf et al. (2006) 0.84 ±0.46 ppm in Saudi Arabia and Tarley et al. (2001), 0.77-2.15 ppm in Brazil.

 

Lead levels in salmon were 0.298±0.158, 0.452±0.127 and 0.275±0.132 ppm in G1, G2, and G3 respectively. These levels are higher than the permissible limit recorded by EOSQC (1993) and lower than that recorded by FAO/WHO. (1992). Ashraf et al. (2006) recorded a same level value of lead in salmon (0.31±0.11) ppm in Saudi Arabia.

 

In anchovies the lead levels were 6.939±2.370, 2.060±0.061, 2.691±0.473 ppm in G1, G2, and G3, respectively. These values are higher than the limits recommended by EOSQC (1993) and FAO/WHO (1992). Similar result were obtained with Türkmen    et al. (2008) ( 0.87±0.40 ppm in samples collected from Black sea and Tüzen (2009) 0.30 ± 0.02 ppm in Turkey but the result recorded by Gilmartin and Revelante (1974) from Adriatic sea  were lower than our result >0.01.

 

The mean values of cadmium in sardine were 0.063±0.011, 0.098±0.025 and 0.066±0.021 ppm, while in salmon were 0.037±0.009, 0.053±0.010 and 0.061±0.020 ppm, in anchovies were 1.007±0.093, 0.464±0.055 and 1.908±0.540 ppm, in G1, G2 and G3, respectively. In all samples the cadmium levels are lower than (0.1 ppm) that recommended by EOSQC (1993) and also lower than (0.5 ppm) that recommended by FAO/WHO (1992) except the third group in anchovies was higher than the permissible limits.

 

A similar results of cadmium levels in sardine were reported by Suppin et al. (2005) in Austria was (0.012 ppm), Olga Marta et al. (1991) in Costa Rica (0.06-0.16 ppm), Ashraf et al. (2006) in Saudi Arabia (0.18 ±0.19 ppm) and Gilmartin and Revelante (1974) from Black sea recorded lower levels than our result >0.01.

 

REFERENCE

 

Ashraf, W.; Seddigi, Z.; Abulkibash, A. and Khalid, M. (2006): Levels of selected metals in canned fish consumed in Kingdom of Saudia Arabia, Envirpnmental Monitoring and Assessment V(117) issue 1-3, pp 271-279.

Burger, J.; Gaines, K.F.; Shane Boring, C.; Stephens, W.L.; Snodgrass, J.; Dixon, C.; McMahon, M.; Shukla, S.; Shukla, T. and Gochfeld, M. (2002): Metal levels in fish from the Savannah river: potential hazards to fish and other receptors. Environmental Research 89, 85–97.

Ciobanu, C.; Slencu B.G. and Cuciureanu, R. (2012): Estimation of dietary intake of cadmium and lead through food consumption. Rev. Med. Chir. Soc. Med. Nat. Iasi., 116(2): 617–623.

Das, A. (1990): Metal ion induced toxicity and detoxification by chelation therapy. In: 1st(ed) A text book on medical aspects of bioinorganic chemistry, CBS, Delhi, p. 17-58. 

Engström, A.; Michaëlsson, K.; Vahter, M.; Julin, B.; Wolk, A. and Åkesson, A. (2012): Associations between dietary cadmium exposure and bone mineral density and risk of osteoporosis and fractures among women. Bone, 50:          1372–1378.

EOSQC "Egyptian Organization for Standardization and Quality Control" (1993): Maximum residue limits for heavy metals in food, Ministry of Industry No. 2360: 5, Cairo, Egypt.

FAO/WHO (1992): Codex Alimentarius Commission, standard program codex committee on food additives and contaminants 24th Session, Hague, 23-28 March.

Gilmartin, M. and Revelante, N. (1974): The concentration of mercury, copper, nicklemsilver, cadmium and lead in the northern Adriatic anchovy engraulis encrasicholus, and sardine, sardine pilchardus J. Fishery Bulletin vol. 73. no1 pp193: 201.

IARC (1993): Cadmium and cadmium compounds. In: Beryllium, cadmium, mercury and exposure in the glass manufacturing industry. IARC Monographs on the evaluation of carcinogenic risks to humans, Vol. 58., 119-23, International Agency for Research on Cancer, Lyon.

Ikem, A. and Egiebor, N. (2005): Assessment of trace elements in canned fishes (mackerel, tuna, salamon, sardines and herrings) marketed in Georgia and Alabama (United States of America), J. of Food Composition and Analysis 771-787.

Jarup, L. (2003): Hazards of heavy metal contamination. British Medical Bulletin 68: 167-182.

NOAA "National Oceanic and Atmospheric Administration" (2002): Shrimp overtakes canned tuna as top US seafood- overall seafood consumption decreases in 2001. NOAA 2002-113, available at: http://www. publicaffairs.noaa.gov/releases2002/aug02/ noaa02113.html.

Olga Marta.; Jorge Arturo, C. and Maria Elena, A. (1991): Lead, cadmium and tin content in fresh and canned Costa Riccan sardines and tuna, Ingenieriy Ciencia Quimica 13 (1), 20-24.

Rafael, E. (1975): Study of the cadmium and lead contents Spanish canned fish and mollusk, Informs Tecinos del Instituto de Investigations Pesqueras (Barcelona), pp.14-29.

Rose, M.; Knaggs, M.; Owen, L. and Baxter, M. (2001): A review of the analytical methods for lead, cadmium, mercury, arsenic and tin determination used in proficiency testing.  Journal of Analytical Atomic Spectrometry, 16, 1101-1106.

Satarug, S. (2012): Long-term exposure to cadmium in food and cigarette smoke, liver effects and hepatocellular carcinoma. Curr Drug Metab 2012, 13(3): 257–271.

Sawada, N., Iwasaki, M., Inoue, M., Takachi, R., Sasazuki, S., Yamaji, T., Shimazu, T., Endo, Y. and Tsugane, S. (2012): Long-term dietary cadmium intake and cancer incidence. Epidemiology, 23(3): 368–376.

Steenland, K. and Boffetta, P. (2000): Lead and cancer in humans. Med. 38: 295-299.

Suppin, D.; Zahlbruckner, R.; Krapfenbauer-Cermak, Hassan, CH. and Smulders, F. (2005): Mercury, lead and cadmium content of fresh and canned fish collected from Austrian retail operations Ernahrung/Nutrition/, vol 29/NR. 112.

Tarely, T.R.; Coltro, T.K.; Matsushita, M. and Souza, N. (2001): Characteristic levels of some heavy metals from Brazilian canned sardines (Sardinella brasiliensis) J. of Food Composition And Analysis 14, pp 611-617.

Türkmen, A.; Tepe, Y. and Türkmen, M. (2008): Metal levels in tissues of the European anchovy, Engraulis encrasicolus L., 1758, and picarel, Spicara smaris L., 1758, from Black, Marmara and Aegean Seas. Bulletin of enviromental contamination and toxicology, 80: 521-5. doi: 10.1007/s00128-008-9429-2.

Tüzen, M. (2009): Toxic and essential trace elemental contents in fish species from the Black Sea, Turkey. Food and Chemical Toxicology, 47:1785–1790. doi: 10.1016/j.fct.2009.04.029.

US EPA "United States Environmental Protection Agency" (2004): What you need to know about mercury in fish and shellfish. EPA-823-F- 04-009, 2pp, availableat: http://www.epa.gov/ waterscience/fish/MethylmercuryBrochure.pdf.

WHO (1992): Cadmium. Environmental Health Criteria, Vol. 134, Geneva.

WHO (1995): Lead. Environmental Health Criteria, Vol. 165, Geneva.

 

 

 

تقدير مستويات الرصاص والکادميوم فى بعض الأسماک المعلبة المملحة المستوردة

 

ناهد محمود عبد العزيز ، زکريا  مختار زکى

 

Email:  nahedvet2012@yahoo.com            Assiut University web-site: www.aun.edu.eg

 

تمثل انسجة الاسماک احد المصادر الرئيسية لتعرض الانسان للعديد من المعادن من خلال تناول تلک الأسماک وتهدف الدراسة الى تحديد مستوي بعض المعادن الثقيلة (الرصاص والکادميوم) فى انسجة بعض الاسماک المملحة المعلبة المستوردة من الخارج (سردين – سلمون – انشوجة) وذالک باستخدام جهاز الامتصاص الطيفى الذرى.تم جمع خمسة واربعون عينة من الاسماک المعلبة المملحة من بعض السوبر مارکت بمدينة سوهاج وقسمت العينات الى ثلاث مجموعات (15) لکل منهما وفقا لمناطق الانتاج المجموعة الاولى من تايلاند , المجموعة الثانية من المغرب والمجموعة الثالثة من اسبانيا وکل مجموعة تم تقسيمها الى ثلاث مجموعات فرعية (5 لکل منهما) (سردين – سلمون – انشوجة ) وقد اظهرت النتائج ان متوسط ترکيز الرصاص في عينات السردين: المجموعة الاولى  والثانية والثالثة کانت 2.495±0.013 ,2.320±0.010 ,0.271± 0.047 ملجم/کجم (وزن رطب) على التوالى وللسلمون  0.298±0.158 , 0.452±0.127 و 0.275± 0.132 ملجم/کجم (وزن رطب) على التوالى وللانشوجة 6.939±2.370 , 2.0 ±0.061 و2.691±0.473 ملجم/کجم (وزن رطب) على التوالى بينما کان متوسط ترکيز الکادميوم فى المجموعة الاولى , الثانية والثالثة للسردين 0.063±0.011  ,0.098±0.025 و0.066± 0.021 ملجم/کجم (وزن رطب) على التوالى وللسلمون ,0.037±0.009 ,0.053±0.010 و0.061±0.020 ملجم/کجم (وزن رطب) على التوالى وللأنشوجة 1.007±  0.464و093,0± 0.055 و 1.908±0.540 ملجم /کجم (وزن رطب) على التوالي أظهرت النتائج ان ترکيز الرصاص کان في اغلب العينات التي تم جمعها اعلى من المستويات المسموح بها وفقا للمواصفات المصرية وکذا العالمية بينما کان ترکيز الکادميوم اقل من المستويات المسموح بها عدا فى الانشوجة کانت اعلى من تلک المستويات ، لذلک يجب عمل مسوحات دورية لهذه المنتجات.                                                  

                                

 

 

REFERENCE
 
Ashraf, W.; Seddigi, Z.; Abulkibash, A. and Khalid, M. (2006): Levels of selected metals in canned fish consumed in Kingdom of Saudia Arabia, Envirpnmental Monitoring and Assessment V(117) issue 1-3, pp 271-279.
Burger, J.; Gaines, K.F.; Shane Boring, C.; Stephens, W.L.; Snodgrass, J.; Dixon, C.; McMahon, M.; Shukla, S.; Shukla, T. and Gochfeld, M. (2002): Metal levels in fish from the Savannah river: potential hazards to fish and other receptors. Environmental Research 89, 85–97.
Ciobanu, C.; Slencu B.G. and Cuciureanu, R. (2012): Estimation of dietary intake of cadmium and lead through food consumption. Rev. Med. Chir. Soc. Med. Nat. Iasi., 116(2): 617–623.
Das, A. (1990): Metal ion induced toxicity and detoxification by chelation therapy. In: 1st(ed) A text book on medical aspects of bioinorganic chemistry, CBS, Delhi, p. 17-58. 
Engström, A.; Michaëlsson, K.; Vahter, M.; Julin, B.; Wolk, A. and Åkesson, A. (2012): Associations between dietary cadmium exposure and bone mineral density and risk of osteoporosis and fractures among women. Bone, 50:          1372–1378.
EOSQC "Egyptian Organization for Standardization and Quality Control" (1993): Maximum residue limits for heavy metals in food, Ministry of Industry No. 2360: 5, Cairo, Egypt.
FAO/WHO (1992): Codex Alimentarius Commission, standard program codex committee on food additives and contaminants 24th Session, Hague, 23-28 March.
Gilmartin, M. and Revelante, N. (1974): The concentration of mercury, copper, nicklemsilver, cadmium and lead in the northern Adriatic anchovy engraulis encrasicholus, and sardine, sardine pilchardus J. Fishery Bulletin vol. 73. no1 pp193: 201.
IARC (1993): Cadmium and cadmium compounds. In: Beryllium, cadmium, mercury and exposure in the glass manufacturing industry. IARC Monographs on the evaluation of carcinogenic risks to humans, Vol. 58., 119-23, International Agency for Research on Cancer, Lyon.
Ikem, A. and Egiebor, N. (2005): Assessment of trace elements in canned fishes (mackerel, tuna, salamon, sardines and herrings) marketed in Georgia and Alabama (United States of America), J. of Food Composition and Analysis 771-787.
Jarup, L. (2003): Hazards of heavy metal contamination. British Medical Bulletin 68: 167-182.
NOAA "National Oceanic and Atmospheric Administration" (2002): Shrimp overtakes canned tuna as top US seafood- overall seafood consumption decreases in 2001. NOAA 2002-113, available at: http://www. publicaffairs.noaa.gov/releases2002/aug02/ noaa02113.html.
Olga Marta.; Jorge Arturo, C. and Maria Elena, A. (1991): Lead, cadmium and tin content in fresh and canned Costa Riccan sardines and tuna, Ingenieriy Ciencia Quimica 13 (1), 20-24.
Rafael, E. (1975): Study of the cadmium and lead contents Spanish canned fish and mollusk, Informs Tecinos del Instituto de Investigations Pesqueras (Barcelona), pp.14-29.
Rose, M.; Knaggs, M.; Owen, L. and Baxter, M. (2001): A review of the analytical methods for lead, cadmium, mercury, arsenic and tin determination used in proficiency testing.  Journal of Analytical Atomic Spectrometry, 16, 1101-1106.
Satarug, S. (2012): Long-term exposure to cadmium in food and cigarette smoke, liver effects and hepatocellular carcinoma. Curr Drug Metab 2012, 13(3): 257–271.
Sawada, N., Iwasaki, M., Inoue, M., Takachi, R., Sasazuki, S., Yamaji, T., Shimazu, T., Endo, Y. and Tsugane, S. (2012): Long-term dietary cadmium intake and cancer incidence. Epidemiology, 23(3): 368–376.
Steenland, K. and Boffetta, P. (2000): Lead and cancer in humans. Med. 38: 295-299.
Suppin, D.; Zahlbruckner, R.; Krapfenbauer-Cermak, Hassan, CH. and Smulders, F. (2005): Mercury, lead and cadmium content of fresh and canned fish collected from Austrian retail operations Ernahrung/Nutrition/, vol 29/NR. 112.
Tarely, T.R.; Coltro, T.K.; Matsushita, M. and Souza, N. (2001): Characteristic levels of some heavy metals from Brazilian canned sardines (Sardinella brasiliensis) J. of Food Composition And Analysis 14, pp 611-617.
Türkmen, A.; Tepe, Y. and Türkmen, M. (2008): Metal levels in tissues of the European anchovy, Engraulis encrasicolus L., 1758, and picarel, Spicara smaris L., 1758, from Black, Marmara and Aegean Seas. Bulletin of enviromental contamination and toxicology, 80: 521-5. doi: 10.1007/s00128-008-9429-2.
Tüzen, M. (2009): Toxic and essential trace elemental contents in fish species from the Black Sea, Turkey. Food and Chemical Toxicology, 47:1785–1790. doi: 10.1016/j.fct.2009.04.029.
US EPA "United States Environmental Protection Agency" (2004): What you need to know about mercury in fish and shellfish. EPA-823-F- 04-009, 2pp, availableat: http://www.epa.gov/ waterscience/fish/MethylmercuryBrochure.pdf.
WHO (1992): Cadmium. Environmental Health Criteria, Vol. 134, Geneva.
WHO (1995): Lead. Environmental Health Criteria, Vol. 165, Geneva.