Determination of Pb and Cd in Garlic Herb (Allium sativum) Planted in Gilan and Khuzestan Provinces Using Graphite Furnace Atomic Absorption Spectrometry

Zahra Ramezani; Nasrin Aghel; Negar Amirabedin

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Determination of Pb and Cd in Garlic Herb (Allium sativum) Planted in Gilan and Khuzestan Provinces Using Graphite Furnace Atomic Absorption Spectrometry

Zahra Ramezani ^1, ^3, ^* ; Nasrin Aghel ^2, ³ ; And Negar Amirabedin ³

¹ Toxicology Research Center, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, IR Iran

² Plant Research Center, Faculty of Pharmacy, Jundishapur University of Medical Sciences, Ahvaz, IR Iran

³ Faculty of Pharmacy, Jundishapur University of Medical Sciences, Ahvaz, IR Iran

*Corresponding author: Zahra Ramezani, Toxicology Research Center, Faculty of Pharmacy, Jundishapur University of Medical Sciences, Ahvaz, IR Iran. Tel.: +98-6113738380, Fax: +98-6113738381, E-mail: zramezani@ajums.ac.ir.

Jundishapur Journal of Natural Pharmaceutical Products. 2012 May; 7(2): 41-44.

Article Type: Research Article; Received: Oct 29, 2011; Revised: Feb 12, 2012; Accepted: Mar 12, 2012; Epub: May 28, 2012; Ppub: May 28, 2012

Running Title: Cd and Pb in Gilan and Khuzestan Garlic

Abstract

Background: Foods are enriched with variety of chemical elements. Some of these elements are necessary for human health. These elements enter in liquid, the cells and other organs, certain amount of these elements are essential for body organs to work properly.

Objectives: This research was conducted to compare the level of lead and cadmium contamination in garlic species planted in Ramhormoz and Rasht and discuss about the source of this contaminations.

Materials and Methods: Twenty composite samples were collected from each province, Khozestan (Ramhormoz) and Gilan (Rasht). Each sample was burned according to instruction reported in AOAC. Then the white residue was dissolved in diluted nitric acid then the Pb and Cd contents were determined using graphite furnace atomic absorption spectrometer at 217 and 228.8 nm, respectively. No Pb level was detected in garlic cultured in both cities. The mean concentration of cadmium was 0.40 and 0.58 mg/kg in garlics planted in Ramhormoz and Rasht, respectively.

Results: Statistical analysis showed significant difference between mean concentration of cadmium in Rasht garlic and the permitted value (P < 0.001). The cadmium level in Rasht garlic is much higher than the standard level.

Conclusions: In order to test the reliability of the data obtained using this method, randomly selected samples were spiked with Pb and Cd standard solutions. The cadmium and lead recovery were reported 93.93 and 90.18 percent.

Keywords: Garlic; Metals, Heavy

1. Background

Foods are enriched with variety of chemical elements. Some of these elements are necessary for human body. These elements are enter as liquid, cells and other body organs and perhaps the existence of certain amount of these elements are necessary for body organs to work properly. Lead and Cadmium are two unnecessary elements that accumulate the living organs for which these elements are toxic (1). Lead accumulates in the bodyand interferes in Vitamin D and Calcium metabolites; it is a neurotoxin whichcauses behavioral abnormalities (1). Cadmium ion are easily absorbed by vegetables and animal food distributed in kidney and liver consequents to many health problmes (2-4) it was shown that rice wheat, oyster, mussels and the kidney cortex of animals contain the highest amount of cadmium. (5, 6) Vegetables, especially leaf vegtables may contain elevated lead level when grown near sources of lead (7-11). vegetables grown in highly contaminated soils would obviously contain a high cadmium level. Hence determination of lead and cadmium contents of vegetables and complementary pharmaceutical is an important issue which attracts scientist's attentions all over the world (12-16). Even different reliable methods have been reported in the literature (17-19). Garlic is both a spicy food additive and herbal medicine. In Iran especially in North region, high amount of raw and cooked garlic is used daily. In result, the exposure incidence of these region population that leads to health hazards are significantly high. a periodical monitor of the extent of heavy metals contaminations in garlic, or further vegetables is mandatory.

2. Objectives

This research was conducted to compare the level of lead and cadmium contamination in garlic species planted in Ramhormoz and Rasht and discus about the sources of these contaminations.

3. Materials and Methods

All chemicals used in the present study, excluding Pb and Cd standard solutions, were analytical reagent grade and purchased from Merck, Germany. Stock solutions of 1000 μg.mL^-1 of Pb²⁺ and Cd²⁺ were purchased from Chem Lab N.V., Belgium. GF/B filter papers were used for filtration purposes. Doubly distilled water was used in this study.

100 μg.mL^-1 of lead and cadmium solution: 10 mL of lead and cadmium stock solutions were transferred to two seprate 100 mL volumetric flasks and disolved in distilled water. Working standard solutions identified in the instrument cook book and AOAC methods were prepared by successive dilutions of these intermediate solutions.

3.1. Sample Collection

Garlic samples were randomly collected in March and April 2007 from Rasht/Gilan and Ramhormoz/Khozestan farms to this purpose, 10 farms were randomly selected at six different locations in each agricultural area, and a total of 60 samples for each province were collected. Samples from each farm were divided into two group of three. Samples in each group were mixed together to compound composite samples. Consequently two composite samples from, each farm and an overall of 20 composite samples for each cultivated area were collected. The samples were dried in a clean dark place and were ground into powder. Powders were reserved in clean plastic vessels for further analysis.

3.2. Apparatus

Analytical Jena graphite furnace atomic absorption spectrometer (GFAAS), 5EA, Germany with D₂ background correction was used for all assessments. Samples were burned in an Electrical Furnace EX 1200-6L (Iran). All glassware used in this experiment was soaked in 10% nitric acid for 24 hours, rinsed thoroughly in double distilled water, dried in an oven and cooled before use.

3.3. Sample Preparation

Samples were digested by the use of two following methods, dry ashing and wet digestion, which previously described in references 20 and 21. In wet digestion a precise amount of garlic powder (1g) were transferred to the Teflon beaker, 15ml of concentrated HNO₃ and 5ml %40 HF were added and heated on a heater till no gas was evolved that was an indication of complete digestion (never let samples to become dry). Dry ashing was performed as described in AOAC (20). Briefly, before 2 g of sample powder were burned at 450°C for about 8 hours (a white ash was obtained). This residue dissolved in minimum amount of diluted HNO₃. After filtration the resulting solution was transferred to 10 mL volumetric flask and diluted to the mark with diluted HNO₃. This solution was immediately subjected to graphite furnace AAS analysis.

3.4. Graphite Furnace Atomic Absorption Determination

20 microliter of sample solution was transferred to the graphite tube then 5µl %1 orthophosphoric acid was added as modifier. Finally the program was run and the data was reported (20). The Pb and Cd analyzing Furnace programs are shown in (Table1).

Table 1

Temperature Programs Set on the Graphite Furnace AAS for the Determination of Pb and Cd in Garlic Samples

3.5. Recovery

In order To determine the analysis accuracy, exact amounts of standards were added separately to two randomly selected samples prepared by dry ashing and wet digestion methods. The recovered standards were calculated from the difference and reported in (Table 2).

Table 2

Comparisons of Wet Digestion and Dry Ashing Reliability during Sample Preparation

4. Results

In order to select more reliable and easy digestion methods for preparing garlic samples two standard preparation methods (wet digestion and dry ashing) (20, 21) were selected, the accuracy of the data obtained by these two methods were evaluated by spiking certain amounts of standards in both prepared garlic samples. Table 2 showed that the extent of matrix effects were higher in wet digestion according to AOAC suggestion, dry ashing was chosen for the present study analyzes (20).

The analysis results of 20 composite samples collected from the two cultivated areas shown in (Table 3)and confirmed the availability of No Pb. This is consistent with the results obtained from root vegetables by other researchers (13). the same results were obtained from onion samples in our research group (22). Formation of insoluble Pb compounds with some anions especially phosphate, immobilizes the metal in soil and water a (23, 24) and reduces lead bioavailability consequently vegetables mostly arecontaminated with atmosphere Pb. The Mean Cd contents of cultivated garlics in both provinces were higher than standard level of 0.2 mg/kg, reported by Codex (25) as it is graphically illustrated in (Figure 1). The mean Cd contents were compared with permitted level using student t-test. The results showed that there was a significant differences between cadmium contents of Rasht garlic and permitted value (P < 0.001), but there was no significant differences between those of Ramhormoz (P = 0.388). Students t-test also showed significant differences between cadmium contents of the both cultivated areas (P = 0.037). Consequently it was concluded that Rasht garlic is contaminated.

Table 3

Analysis Results of Cd Contents of Garlic Cultivated in Ramhormoz and Rasht (Results are Mean of Two Measurements)

Figure 1

Graphical Comparison of Mean Concentration of Cadmium in Garlic Samples Collected from Ramhormoz and Rasht

5. Discussion

According to primary investigations of the regions, farmers commonly use organo phosphorous fertilizers, especially simple super phosphate and triple super phosphate. Fertilizers contain high amount of Cadmium and Lead. But Pb bioavailability reduced via complexion of pb ions by anions such as hydroxide, carbonate, sulphate, sulfide, and especially phosphates. In comparison to the Ramhormoz’s farmers, the farmers of Rash use uncontrolled amount of these fertilizers, which is closely related to the higher amount of Cd detected in the collected garlic samples. The results show the mean concentration of cadmium in Gilan garlic is higher than those of Khozestan. It may be due to higher oregano phosphorous fertilizer consumption rate. Since daily garlic consumption as food and medicine is routine in this regions, an alternative fertilizer with less hazards is of an essence. Soil heavy metal contamination and irrigation water are other concerns, which should be prevented by heavy metal analyzes and cultivated area controls before growing any plant.

Acknowledgments

Authors gratefully acknowledge the financial support of research council of Jundishapur University of medical sciences for this Pharm D thesis under grant number u-86002.

Footnotes

Implication for health policy/practice/research/medical education: This study determine the heavy metal contamination levels of the garlic products of Gilan and Khozestan provinces.

Please cite this paper as: Ramezani Z, Aghel N, Amirabedin N. Determination of Pb and Cd in Garlic Herb (Allium sativum) Planted in Gilan and Khuzestan Provinces Using Graphite Furnace Atomic Absorption Spectrometry. Jundishapur J Nat Pharm Prod. 2012:7(2);41-4.

Financial Disclosure: Financial support of Research council of Jundishapur University of medical sciences under grant no. u-86002.

Funding/Support: None declared.

References

1. Mottram RF. Human Nutrition. 3rd Revised edition ed. Hodder & Stoughton General Division; 1979.
2. D'Mello JPF. Food safety: contaminants and toxins. Oxon, UK, Cambridge,: MA: CABI publishing, Wallingford; 2003. [DOI]
3. Gupta UC, Gupta SC. Trace Element Toxicity Relationship to Crop Production and Livestock and Human Health:Implications for Management. Commun Soil Sci Plant Anal. 1998;29:1491-522. [DOI]
4. Sharma RK, Agrawal M, Marshall FM. Heavy metals in vegetables collected from production and market sites of a tropical urban area of India. Food Chem Toxicol. 2009;47(3):583-91. [DOI] [PubMed]
5. Järup L. Hazards of heavy metal contamination. British Med Bull. 2003;68(1):167. [DOI]
6. Sathawara NG, Parikh DJ, Agarwal YK. Essential Heavy Metals in Environmental Samples from Western India. Bull Environ Contam Toxicol. 2004;73(4):756-61. [DOI] [PubMed]
7. Kachenko AG, Singh B. Heavy metals contamination in vegetables grown in urban and metal smelter contaminated sites in Australia. Water, Air, & Soil Pollution. 2006;169(1):101-23. [DOI]
8. Al Jassir MS, Shaker A, Khaliq MA. Deposition of heavy metals on green leafy vegetables sold on roadsides of Riyadh City, Saudi Arabia. Bull Environ Contam Toxicol. 2005;75(5):1020-7. [DOI] [PubMed]
9. Khairiah T, Zalifae MK, Yin YH, Aminath A. The uptake of heavy metals by fruit typevegetables grown in selected agricultural areas. Pak G Biol Sci. 2004;7(8):1438-42. [DOI]
10. Sharma RK, Agrawal M, Marshall FM. Atmospheric deposition of heavy metals (Cu, Zn, Cd and Pb) in Varanasi City, India. Environ Monit Assess. 2008;142(1-3):269-78. [DOI] [PubMed]
11. Temmerman LD, Ruttens A, Waegeneers N. transfer of atmospheric arsenic, cadmium, and lead to various vegatables, veterinary and agrochemical research center-Leuvensesteeweg.17. .
12. Banerjee D, Kuila P, Ganguly A, Ray L. Market basket survey for chromium, copper, lead and cadmium in some vegetables from different shopping malls in Kolkata, India Elect. J Environ Agri and Food Chem. 2010;9(7):1190-5.
13. Lisiewska Z, Gebczynski P, Kmiecik W, Skoczen-Slupska R. Effect of vegetable freezing and preparation of frozen products for consumption on the content of lead and cadmium. Polish J Environ. 2007;16(4):579-85.
14. Radwan MA, Salama AK. Market basket survey for some heavy metals in Egyptian fruits and vegetables. Food Chem Toxicol. 2006;44(8):1273-8. [DOI] [PubMed]
15. Kumar Sharma R, Agrawal M, Marshall F. Heavy metal contamination of soil and vegetables in suburban areas of Varanasi, India. Ecotoxicol Environ Saf. 2007;66(2):258-66. [DOI] [PubMed]
16. Maleki A, Zarasvand MA. Heavy metals in selected edible vegetables and estimation of their daily intake in Sanandaj, Iran. Southeast Asian J Trop Med Public Health. 2008;39(2):335-40. [PubMed]
17. Crosby NT. Determination of metals in foods. Analyst. 1977;102(1213):225-68. 327849 [PubMed]
18. Aleixo PC, Junior DS, Tomazelli AC, Rufini IA, Berndt H, Krug FJ. Cadmium and lead determination in foods by beam injection flame furnace atomic absorption spectrometry after ultrasound-assisted sample preparation. Analytica chimica acta. 2004;512(2):329-37. [DOI]
19. Li YC, Jiang SJ, Chen SF. Determination of Ge, As, Se, Cd and Pb in plant materials by slurry sampling-electrothermal vaporization-inductively coupled plasma-mass spectrometry. Analytica chimica acta. 1998;372(3):365-72. [DOI]
20. Chemists AoOA, Horwitz W. Official methods of analysis. 14th ed. Arlington, Virginia, USA: Association of Official Analytical Chemist; 2000.
21. Temminghoff EJM, Houba VJG. Plant Analysis Procedures. 2 ed. 2004.
22. Ramezani Z, Aghel N, Shiralipoor R, Zadeh Dabbagh R. Determination of Lead and Cadmium Content of Dill (Anethum graveolens) and Onion (Allium Cepa L.) Cultivated in Khozestan/Iran. Iran J Pharm Sci. 2011;7(3):197-203.
23. Cao X, Ma LQ, Singh SP, Zhou Q. Phosphate-induced lead immobilization from different lead minerals in soils under varying pH conditions. Environ Pollut. 2008;152(1):184-92. [DOI] [PubMed]
24. Cao X, Wahbi A, Ma L, Li B, Yang Y. Immobilization of Zn, Cu, and Pb in contaminated soils using phosphate rock and phosphoric acid. J Hazard Mater. 2009;164(2-3):555-64. [DOI] [PubMed]
25. FAO/WHO Food Standars. CODEX alimentarius. 2011; [Updated updated 2011; cited 2011]; Available from: www.codexalimentarius.net.

Table 1

Temperature Programs Set on the Graphite Furnace AAS for the Determination of Pb and Cd in Garlic Samples

Step	Pb ^a			Cd ^a
Step	Temperature, °C	Ramp, Degree/S	Hold, S	Temperature, °C	Ramp, Degree/S	Hold, S
Drying1	105	7	25	105	5	10
Drying2	-	-	-	110	10	10
Pyrolysis	450	100	2	650	20	10
Auto Zero	450	0	4	650	0	4
Atomize	2000	2200	2	1300	400	5
Clean out	2500	1000	4	2500	200	3

^a Abbreviations: Cd: Cadmium; Pb: Lead

Table 2

Comparisons of Wet Digestion and Dry Ashing Reliability during Sample Preparation

Method	Metal	Standard Added, ng	Standard Recovered, ng	Recovered,%
Wet Digestion	Pb	17	4.27	25.11
Wet Digestion	Cd	1	6.60	660.00
Dry Ashing	Pb	0.66	0.60	90.18
Dry Ashing	Cd	0.50	0.47	93.93

Table 3

Analysis Results of Cd Contents of Garlic Cultivated in Ramhormoz and Rasht (Results are Mean of Two Measurements)

Ramhormoz, mg/kg	Rasht, mg/kg
0.16	0.37
0	0.51
0.6	0.28
0.2	0.23
1.15	0.72
0.19	0.17
0.28	1.45
0.03	0.21
0.42	0.82
0.75	0.63
0.77	0.58
0.32	0.69
0	0.61
0.23	0.75
0	0.68
1.37	0.68
0.26	0.42
0.06	0.38
1.14	0.75
0.07	0.68
0.03 ^a	0.17 ^a
1.37 ^b	1.45 ^b
0.40 ± 0.38 ^c	0.58 ± 0.29 ^c

^a Minimum
^b Maximum
^c Mean ± SD

Figure 1

Graphical Comparison of Mean Concentration of Cadmium in Garlic Samples Collected from Ramhormoz and Rasht

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Determination of Pb and Cd in Garlic Herb (Allium sativum) Planted in Gilan and Khuzestan Provinces Using Graphite Furnace Atomic Absorption Spectrometry

Abstract

1. Background

2. Objectives

3. Materials and Methods

3.1. Sample Collection

3.2. Apparatus

3.3. Sample Preparation

3.4. Graphite Furnace Atomic Absorption Determination

3.5. Recovery

4. Results

5. Discussion

Acknowledgments

Footnotes

References

Table 1

Table 2

Table 3

Figure 1

Table 1

Table 2

Table 3

Figure 1