MONITORING OF ALUMINUM RESIDUES IN COOKED MEAT

Author

Dept. of Food Hygiene, Animal Health Research Institute, Dokki, Giza.

Abstract

Effect of kitchen aluminum utensils on aluminum content of meat (cooked in different methods) during cooking and holding at 40 C for different periods were studied. The result indicated that the migration of aluminum from aluminum pan into meat was great. The aluminum content of meat samples were determined before and after the samples were cooked and stored in aluminum pan at 40 C for different periods. Highest concentrations were found in meat cooked with onion and tomato .Low concentrations were found in meat cooked by boiling without adding any ingredients. The aluminum migration seems to depend on several factors, such as the chemical constituents of food, the duration and the temperature of cooking and storage, the addition of any other substances and complexing reactions that result in dissolution  of the complexed metal

Keywords


Dept. of Food Hygiene,

Animal Health Research Institute, Dokki, Giza. 

 

Monitoring of Aluminum residues

in cooked meat

(With 4 Tables)

 

By

Omaima M. Diab

(Received at 20/2/2005)

 

تقدير بقايــا الآلومنيوم فى اللحوم المطبوخة

 

أميمة محمود دياب

 

يهدف هذا البحث إلى دراسـة تأثير نوع  أوعية المطبخ المصنوعة من الآلومنيوم المستخدمة فى طهى اللحوم على محتوى الألومنيوم فى اللحوم المطبوخة وذلک خلال عمليات طبخ مختلفة - لحوم مسلوقة ، لحوم مطبوخة بالبصل ، لحوم مطبوخة بالبصل والطماطم – وحفظها على درجة حرارة الثلاجة (4م) لمدة 72 ساعة. أوضحت النتائج احتواء  اللحوم التى تم طهيها بالاوانى الالومنيوم على نسبة عالية من عنصر الالومنيوم. کذلک وجد أن اضافة البصل والطماطم أدى إلى زيادة هجرة عنصر الآلومنيوم من الأوعية إلى اللحوم خلال الطبخ أو الحفظ على درجة حرارة الثلاجة بينما أدى سلق اللحوم بدون اضافات إلى تقليل نسبة الألومنيوم الموجودة فى اللحوم. هجرة عنصر الألومنيوم من الأوانى إلى الأغذية تعتمد على بعض المؤثرات مثل التکوين الکيميائى للأغذية، فترة ودرجة حرارة الطهى والحفظ وأيضا الأضافات التى تضاف إلى الأغذية ودرجة جودة الأوانى نفسها.

 

Summary

 

Effect of kitchen aluminum utensils on aluminum content of meat (cooked in different methods) during cooking and holding at 40 C for different periods were studied. The result indicated that the migration of aluminum from aluminum pan into meat was great. The aluminum content of meat samples were determined before and after the samples were cooked and stored in aluminum pan at 40 C for different periods. Highest concentrations were found in meat cooked with onion and tomato .Low concentrations were found in meat cooked by boiling without adding any ingredients. The aluminum migration seems to depend on several factors, such as the chemical constituents of food, the duration and the temperature of cooking and storage, the addition of any other substances and complexing reactions that result in dissolution  of the complexed metal.                                     

 

Key words: Aluminum residues, cooked meat, aluminum utensils.

 

Introduction

 

Environmental pollution represents a major problem in both developed and under eveloped countries. Egypt is one country which suffers from high biosphere pollution (air, soil, and water). Many ecological changes occur in water as a result of human activities, including agricultural and municipal wastes (Atta,  et al., 1997).

There is an international concern about human intake of toxic trace elements, such as cadmium, lead, mercury, aluminum and others. Intake of relatively low doses of these elements over a long period of time can cause malfunction of organs and chronic toxicity.

Aluminum (AL) is the third most abundant element in the lithosphere and the aluminum resources are considerable. During the last 100 years of industrialization, the importance of aluminum has strongly increased. Because of its favorable physical characteristics, aluminum has become indispensable in many industrial areas, e.g. the packaging industry, as well as in daily life.

Aluminum compounds used as food additives are an additional source of this element in food in many countries. Such additives are not permitted. Food pollution with aluminum may, to some extent, be augmented by use of aluminum cutlery and kitchen utensils, equipment used in food industry, as well as packaging (Shaalan, 2002). 

Many possible sources of aluminum intake by the human body exist, e.g. drugs, foods, drinking water and, industrial exposure. Food is the main route by which the normal daily intake of aluminum occurs. The total aluminum content arises from food containers such as cans, cookware, utensils and food wrappings. It has been established that cooking of acidic and low acidic foods in aluminum saucepans or foil causes leaching of the metal (Liukkonen- Lilja and Piepponen, 1992; Brunner, et al., 1999; Rajwanshi  et al., 1999; Takeda et al., 1998 a, b and 1999). Food, which were manufactured and stored in aluminum cans, showed an increased aluminum content (Aikoh and Nishio, 1996; Rajwanshi et al., 1997; Seruga et al., 1997)

High levels of aluminum in foods can be attributed to chemical corrosion by acids or alkalis during boiling for short period in aluminum vessels, electrochemical corrosion when foods are left in contact with aluminum vessels for long periods, acidic and salty food increasing concentration of complexing ions, (Mei and Yao 1994; Gramiccioni et al ., 1996  and Shuping 1996).

Aluminum ions in the human diet are non bio available from the small intestine because the hydrated charged ions are not able to penetrate the lipid protein membranes of the duodenal mucosa. But it can be assumed that at least part of the human dietary aluminum intake is in the form of chelates with natural food components such as citric and lactic acids (Shuping, 1996) In the human body aluminum ions could inhibit different metabolism processes caused by competition reactions between aluminum and other ions such as calcium, magnesium or iron (Macdonald and Martin, 1988). Therefore, aluminum has been associated with several skeletal osteomalacia           (Blumenthal and Posner, 1984; Boyce et al., 1982; Bushinsky, et al., 1995) and neurological disorders e.g Alzheimer’s disease (Armstrong et  al., 1996 and Lamb, 1995).

In recent years aluminum is responsible for another neurological disorder: encephalopathy or dialysis dementia (Alfery, 1997; Meiri et al., 1992) in uremic patients on dialysis.       

The extent of the increase of aluminum is dependent on factors such as temperature, pH value, duration of contact or heating, presence of sugar, organic acids, salt and other ions (Ranau et al., 2001)

The average daily intake of aluminum for adult men, women, 6-11 month old infants and  14-16 years old males is 8-9, 7, 0.7 and 11.5 mg/day respectively (Becker, et al., 1990).

Food cooked in aluminum utensils is widely consumed in Egypt consquently the aim of the present work is to measure the aluminum content of these foods (meat cooked in aluminum utensils with different methods and stored in refrigerator for different times).

 

Materialsand Methods

 

           Thirty samples of meat cooked in aluminum utensils with different methods (boiling in water, boiling in water with onion, and boiling in water with onion and tomato, each 10) analyzed for aluminum content by the wet oxidation method, according to  AOAC (1990) by using a Perkins Elmer 2380 Atomic Absorption Spectrophotometer at wave length 309, temp. 2900-3000oC with nitrous oxide and acetylene.

All samples were cooked until complete cooking in aluminum utensils, cooled, stored at frigidaire in aluminum pan for 72 hr. and analyzed for their aluminum. content after 0, 12, 24, 36, 48, 60 and     72 hr.

            Tomato and onion used in cooking were, analyzed for aluminum content, before cooking. Each sample was minced and homogenized and subjected to aluminum determination.

 

Results

 

Table 1: Levels of aluminum content (mg/kg wet weight) in raw meat, onion and tomato.

 

Sample

Mean ±SD

Min.

Max.

Raw meat

34.039 ± 0.98

11. 279

36.069

Raw onion

0.129 ±0.24

0.063

0.236

Raw tomato

0.147± 0.45

0.097

0.155

 

Table 2: levels of aluminum(mg/kg wet weight) in cooked meat in boiling water in aluminum pan.

 

Time for storage

Mean ±SD

Min

Max

0

11 . 34 ± 4.2

6. 79

14.11

12

13 .15 ±1.45

10.09

17.99

24

18.06± 2.50

14.76

20.12

36

24.31±15.91

15.45

27.11

48

26.22±16.22

15.65

33.32

60

29.40± 8.46

20.74

37.32

72

32.13 ± 1.69

20.98

41.64

 

Table 3:  Levels of aluminum (mg/kg wet weight) in cooked meat with

onion in aluminum pan.

 

Time for storage

Mean SD

Min

Max

0

48.15 ± 8.25

35.94

50.174

12

52.09±5.12

50.346

60.95

24

61.86±4.05

60.12

67.00

36

63.74±8.94

62.89

70.54

48

79.35±3.72

72.68

82.66

60

83.04± 1.94     

80.09

86.33

72

92.18± 2.17      

85.34

98.77

 

Table 4: Levels of aluminum (mg/kg wet weight) in cooked meat with onion and tomato in aluminum pan.

 

Time for storage

Mean SD

Min

Max

 0

120.24±  25.73

100.29

129.35

12

135.19±  16.44        

130.76

140.49

24

146.36±  7.51          

135.81

150.12

36

169.05±  4.69          

154.00

182.86

48

195.78±  0.81          

190.55

198.81

60

219.31±  11.93        

208.63

231.05

72

237.73±  8.65          

220.75

266.17

 

Discussion

 

In this investigation the aluminum content of meat cooked in aluminum pan with different cooking methods (boiled in water, cooked with onion and cooked with onion and tomato) was determined. Table (1) represents the aluminum contents of raw meat, onion and tomato. All values are given in mg Al\kg (ppm) wet weight. Additionally the proportional increase are given in Tables (2, 3 and 4).

For cooked meat with boiling in water in aluminum pan, table 2 showed the aluminum level of meat during storage where time “0” is the time of complete meat cooked while 12, 24, 36, 48, 60, 72 hr are times of storage of meat in refrigerator in aluminum pan. The mean values were 11.34, 13.15, 18.60, 24.31, 26.22, 29.40 and 32.13 mg Al/kg respectively. When compared with raw meat (34.o34 mg Al/kg), a decrease in the level of aluminum was observed, this because migration of aluminum from aluminum pan into food simulating solvents. All parameters, the type of solvent,  the temperature and the time of storage affected the magnitude of aluminum dissolution. The aluminum migration into acidic solvents when heated (at temp 95oC for 30 min), was higher than that into tap water (Takeda et al.,1998 b).

Table (3) showed the levels of aluminum content in meat cooked with onion in aluminum pan and stored at different times in refrigerator when compared with raw meat, we found that all samples increased in its aluminum content after cooking and storage. On the basis of these data, it could be concluded that acidic and salted foods increased the migration of aluminum into foods as the result of enhancing chemical and /or electrochemical corrosion. These data are in accordance with those reported by Gramiccioni et al. (1996) who reported the highest release of aluminum into acidic and salted foods from cookware. Also, Mei and  Yao (1994) reported that aluminum concentration increased due to chemical corrosion by acids and alkalis during boiling and storage for short periods.

Table (4) showed the levels of aluminum content in meat cooked with onion and tomato in aluminum pan and stored at different times in refrigerator when compared with raw meat, we found all samples increased in aluminum content. These data are in agreement with those reported by Gavgominy and Astier (1995) who reported that the acidity of tomatoes results in great migration of aluminum into the product. Shuping (1996) also found that increasing concentration of complexing ions (organic acids, fluoride ion, OH) significantly enhanced the release of aluminum Takeda et al. (1998, a) have reported aluminum migration from aluminum pan into foods and the effect of food components on the migration. The migration level in all heat (30 min at 95oC) and acidic foods (including orange and tomato juice, yoghurt and different types of pickles and vinegars) were less than that in 4% acetic acid. Dissolution of aluminum was enhanced by the addition of sodium chloride but was reduced by the presence of proteins, amino acids, sugar or cholesterol.

In conclusion it could be concluded after the three methods of cooking that meat cooked in boiling water appeared to be the best one because the amount of aluminum was lower than the raw meat itself.

            Regarding the body weight, present state of knowledge and the suggested provisional tolerable daily intake of l mg Al /kg body weight per day of the World Health Organization  1989, there is no evident risk to the health of the consumer from eating 200 gm daily of cooked meat prepared in aluminum pan and care should be taken when using aluminum containers for storage of food because of the health risks associated with high aluminum intake.

 

REFRENCES

 

Aikoh, H. and Nishio, M.R. (1996): Aluminum content of various canned and bottled beverages. Bulletin of Environmental Contamination and Toxicology, 56, 1-7.

Alfrey, A.C. (1997): Dialysis encephalopathy. In Yasui, M., Strong, M.J., Ota, K., Verity, M.A., Mineral and metal neurotoxicology. (pp .127-136). CRC Press Inc.

AOAC. (1990): Official Methods of Analysis, 15th. Ed. Assoc. of Official Analytic Chemists, Washington, Dc.

Armstrong, R.A.; Wins per, S.J. and Blair, J.A. (1996): Aluminum and Alzheimer's disease: Review of possible pathogenic mechanisms Dementia, 7, 1-9.

Atta, M.B.; El-Sebaie, M.A. Noaman and Kassab, H.E. (1997): The effect of  cooking on the content of heavy metals in fish          (Tilapia nilotica). Food Chemistry. Vol. 58. No.1-2 pp. 1-4.

Becker, K.; Nollke, P.; Hermann-Kunz, E.; Krause, C.; Schenker, D. and Schultz, C. (1990): Umwelt- survey 1990/91 Band 111: 1m Auftrage des Bundesministeriums fur Umwelt  Naturschutz und Reaktorsicherheit.

Blumenthal, N.C. and Posner, A.S. (1984): In vitro model of aluminum induced osteomalacia: inhibition of hydroxyapatite formation and growth. Calcified Tissue International, 36, 439-441.

 Boyce, B.F.; Elder, H.Y.; Elliot. H.L.; Fogelman, I.; Fell, G.S.; Junors, B.J.; Beastall, G. and Boyle, I.T. (1982): Hypercalcaemic osteomalacia due to Aluminum toxicity. The Lancet, 2, 1009-1013.

Brunner, B.; Arnold, R. and stolle, A. (1999): Ubergang van aluminum auf lebensmittel. Verwendung Von folien bei kuchentechnischer zubereitung Von fisch und fleisch. Fleischwirtschaft,  1/99. 110-112.

Bushinsky, D.A.; Sprague, S.M.; Hallegot, P.; Girod, C.; Chabala, J.M. and Levi-Setti, R. (1995): Effects of aluminum on bone surface ion composition. Journal of Bone and Mineral Research 10, 1988- 1997.

Gavgominy, N. and Astier, D.M. (1995): Alumini-um content of foods: raw food, canned food in steel or aluminum cans. Medecine et Nutrition. 31 (5), 253.

Gramiccioni, L.; Ingrao, G.; Milana, M.R.; Santaroni, P. and Tomassi, G. (1996):. Aluminum levels in Italian diets and in selected foods from aluminum utensils. Food Additives and Contaminants 13(7), 767.

 Lamb, B.T. (1995): Making models for Alzheimer's disease. Nature Genetics,  9, 4-6

Liukkonen–Lilja, H.  and Piepponen, S. (1992): Leashing of aluminum from aluminum dishes and packages. Food Additives and contaminants, 9, 213-223.

 Macdonald, T.L. and Martin, K.B. (1988): Aluminum ion in biological systems. Trends Biochemical Science, 13, 15-19.

 Mei, L. and Yao, T. (1994): Aluminum contamination of food from using aluminum ware. International J. Environ. Anal. Chem. 50 (1), 1.

Meiri, H.; Banin, E.; Roll, M. and Rousseau, A. (1992): Toxic effects of Aluminum on nerve cells and synaptic transmission. Progress in Neurobiology, 40, 89-121.

 Rajwanshi, P.; Singh, V.; Gupto, M.K. and Dass, S. (1997): Leaching of aluminum from cook wares – a review. Environmental Geochemistry and Health, 19, 1-18.

Rajwanshi, P.; Singh, V.; Gupta, M.K.; Shrivastav, R.; Subramanion, V.; Prakash, S. and Dass, S. (1999): Aluminum leaching from surrogate aluminum food containers under different pH and fluoride concentration. Bulletin of Environmental Contamination and Toxicology 63, 271-276.

Ranau. R.; Oehlen schlager, J. and Steinhart, H. (2001): Aluminum levels of fish fillets baked and grilled in aluminum foil. Food Chemistry 73, 1-6.

 Seruga, M.; Grgic, J.; Grgic, Z. and Seruga, B. (1997) Aluminum content of beers. Zeitschrift fur lebensmittel – Unter suchung und – For schung, 204, 221-226.

Shaalan, S.H. (2002): Effect of copper, zinc and vitamin E on aluminum   toxicity. Egypt. J. Zool., 37: 111-124, December.

 Shuping, B. (1996): A model describing the complexing effect in the leaching of aluminum from cooking utensils. Environ. Poll. 92(1), 85.

Takeda, Y.; Kawamura, Y. and Yamada, T. (1998 a): Dissolution of aluminum from aluminum foil into foods and effect of food components on the dissolution. Journal of the Food Hygienic Society of Japan, 39, 266- 271.

Takeda, Y.; Kawamura, Y. and Yamada, T. (1998 b): Dissolution of aluminum from aluminum foils products in food–simulating solvents. Journal of the Food Hygienic Society of Japan, 39, 178-183.

Takeda, Y.; Kawamura, Y. and Yamada, T. (1999): Migration of aluminum from disposable aluminum foils vessels into foods Journal of the Food Hygienic Society of Japan, 40, 172-177.

World Health Organization (1989): Toxicological evaluation of certain food additives and contaminants. Food additives series (Vol. 24, 116- 117) University Press, Cambridge.

        

REFRENCES

 
Aikoh, H. and Nishio, M.R. (1996): Aluminum content of various canned and bottled beverages. Bulletin of Environmental Contamination and Toxicology, 56, 1-7.
Alfrey, A.C. (1997): Dialysis encephalopathy. In Yasui, M., Strong, M.J., Ota, K., Verity, M.A., Mineral and metal neurotoxicology. (pp .127-136). CRC Press Inc.
AOAC. (1990): Official Methods of Analysis, 15th. Ed. Assoc. of Official Analytic Chemists, Washington, Dc.
Armstrong, R.A.; Wins per, S.J. and Blair, J.A. (1996): Aluminum and Alzheimer's disease: Review of possible pathogenic mechanisms Dementia, 7, 1-9.
Atta, M.B.; El-Sebaie, M.A. Noaman and Kassab, H.E. (1997): The effect of  cooking on the content of heavy metals in fish          (Tilapia nilotica). Food Chemistry. Vol. 58. No.1-2 pp. 1-4.
Becker, K.; Nollke, P.; Hermann-Kunz, E.; Krause, C.; Schenker, D. and Schultz, C. (1990): Umwelt- survey 1990/91 Band 111: 1m Auftrage des Bundesministeriums fur Umwelt  Naturschutz und Reaktorsicherheit.
Blumenthal, N.C. and Posner, A.S. (1984): In vitro model of aluminum induced osteomalacia: inhibition of hydroxyapatite formation and growth. Calcified Tissue International, 36, 439-441.
 Boyce, B.F.; Elder, H.Y.; Elliot. H.L.; Fogelman, I.; Fell, G.S.; Junors, B.J.; Beastall, G. and Boyle, I.T. (1982): Hypercalcaemic osteomalacia due to Aluminum toxicity. The Lancet, 2, 1009-1013.
Brunner, B.; Arnold, R. and stolle, A. (1999): Ubergang van aluminum auf lebensmittel. Verwendung Von folien bei kuchentechnischer zubereitung Von fisch und fleisch. Fleischwirtschaft,  1/99. 110-112.
Bushinsky, D.A.; Sprague, S.M.; Hallegot, P.; Girod, C.; Chabala, J.M. and Levi-Setti, R. (1995): Effects of aluminum on bone surface ion composition. Journal of Bone and Mineral Research 10, 1988- 1997.
Gavgominy, N. and Astier, D.M. (1995): Alumini-um content of foods: raw food, canned food in steel or aluminum cans. Medecine et Nutrition. 31 (5), 253.
Gramiccioni, L.; Ingrao, G.; Milana, M.R.; Santaroni, P. and Tomassi, G. (1996):. Aluminum levels in Italian diets and in selected foods from aluminum utensils. Food Additives and Contaminants 13(7), 767.
 Lamb, B.T. (1995): Making models for Alzheimer's disease. Nature Genetics,  9, 4-6
Liukkonen–Lilja, H.  and Piepponen, S. (1992): Leashing of aluminum from aluminum dishes and packages. Food Additives and contaminants, 9, 213-223.
 Macdonald, T.L. and Martin, K.B. (1988): Aluminum ion in biological systems. Trends Biochemical Science, 13, 15-19.
 Mei, L. and Yao, T. (1994): Aluminum contamination of food from using aluminum ware. International J. Environ. Anal. Chem. 50 (1), 1.
Meiri, H.; Banin, E.; Roll, M. and Rousseau, A. (1992): Toxic effects of Aluminum on nerve cells and synaptic transmission. Progress in Neurobiology, 40, 89-121.
 Rajwanshi, P.; Singh, V.; Gupto, M.K. and Dass, S. (1997): Leaching of aluminum from cook wares – a review. Environmental Geochemistry and Health, 19, 1-18.
Rajwanshi, P.; Singh, V.; Gupta, M.K.; Shrivastav, R.; Subramanion, V.; Prakash, S. and Dass, S. (1999): Aluminum leaching from surrogate aluminum food containers under different pH and fluoride concentration. Bulletin of Environmental Contamination and Toxicology 63, 271-276.
Ranau. R.; Oehlen schlager, J. and Steinhart, H. (2001): Aluminum levels of fish fillets baked and grilled in aluminum foil. Food Chemistry 73, 1-6.
 Seruga, M.; Grgic, J.; Grgic, Z. and Seruga, B. (1997) Aluminum content of beers. Zeitschrift fur lebensmittel – Unter suchung und – For schung, 204, 221-226.
Shaalan, S.H. (2002): Effect of copper, zinc and vitamin E on aluminum   toxicity. Egypt. J. Zool., 37: 111-124, December.
 Shuping, B. (1996): A model describing the complexing effect in the leaching of aluminum from cooking utensils. Environ. Poll. 92(1), 85.
Takeda, Y.; Kawamura, Y. and Yamada, T. (1998 a): Dissolution of aluminum from aluminum foil into foods and effect of food components on the dissolution. Journal of the Food Hygienic Society of Japan, 39, 266- 271.
Takeda, Y.; Kawamura, Y. and Yamada, T. (1998 b): Dissolution of aluminum from aluminum foils products in food–simulating solvents. Journal of the Food Hygienic Society of Japan, 39, 178-183.
Takeda, Y.; Kawamura, Y. and Yamada, T. (1999): Migration of aluminum from disposable aluminum foils vessels into foods Journal of the Food Hygienic Society of Japan, 40, 172-177.
World Health Organization (1989): Toxicological evaluation of certain food additives and contaminants. Food additives series (Vol. 24, 116- 117) University Press, Cambridge.