Heavy Metal Levels in Muscle Tissues of Solea solea, Mullus barbatus, and Sardina pilchardus Marketed for Consumption in Mersin, Turkey

Korkmaz, Cengiz; Ay, Özcan; Çolakfakıoğlu, C.; Cıcık, Bedii; Erdem, Cahit

doi:10.1007/s11270-017-3503-5

Cited by 39 publications

(34 citation statements)

References 34 publications

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“…The environmental health risk was assessed by comparing the environmental status, as represented by the concentrations of the metals in mussels, and threshold values likely to cause adverse effects in human consumers. In this context, a risk quotient can be calculated as follows (based on Jovic et al, 2012;Yap et al, 2016;Korkmaz et al, 2017): 1 is the direct comparison of concentrations in soft tissues (wet weight basis) with seafood safety guidelines based on established maximum permissible limits (MPLs); 2 is the characterization of the amount of mussel meat (maximal provisional consumption rate MPCR, kg/week) that would need to be consumed per week by a 70-kg average adult to reach the provisional tolerable weekly intake (PTWI) established by the JECFA or related reference limits; 3 is the assessment of differences between estimated daily intakes (EDI) with RfD and calculation of risk quotient (RQ), which corresponded to the ratio between estimated weekly intakes (EWI) and prescribed PTWI values of the element; 4 is the estimation of target hazardous quotient (THQ) and total hazardous index (HI) which corresponded to the sum of all quotients from elements as its combinations for each station for the local coastal population…”

Section: Human Health Risk Assessmentmentioning

confidence: 99%

Trace elements risk assessment for consumption of wild mussels along South Africa coastline

Nekhoroshkov

Bezuidenhout

Frontasyeva

et al. 2021

Journal of Food Composition and Analysis

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The study aimed to contribute to the scarce data on concentrations in the soft tissue of wild mussels growing in coastal cities of South Africa. The intake of 26 micro and macroelements was estimated. The mass fractions of sample sets from 8 sites along the South African coast from the West (Port Nolloth) to the East (Durban) were studied by neutron activation analysis at the Joint Institute for Nuclear Research (Russia). The following elements were identified as potentially hazardous due to high consumption risks: Al, Cr, Co, Zn, As, and I at stations in the Cape Town area (Waterfront, Hout Bay) and Durban. The mean concentrations of these elements among all individuals were 208, 0.8, 0.46, 60, 2.6, and 11 ppm of wet weight, respectively. In the studied mussels, the concentrations of Cr, Zn, As, and Se (ranging between 0.2− 2.8, 14-290, 1.6− 4.6, and 0.31− 2.4 ppm of wet weight, respectively) exceeded maximum permissible levels for fish products. The weekly consumption of more than 250 g of fresh mussels per person could increase the risk for human health by potential intake of such elements as Al, As, and I.

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Section: Human Health Risk Assessmentmentioning

confidence: 99%

Trace elements risk assessment for consumption of wild mussels along South Africa coastline

Nekhoroshkov

Bezuidenhout

Frontasyeva

et al. 2021

Journal of Food Composition and Analysis

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“…Lead damages and destroys erythrocytes; reduces resistance; weakens the bones; blocks the nervous system; inhibits the absorption of iodine, necessary for correct functioning of the thyroid gland; forms toxic deposits in the organism, causing numerous disorders and diseases, [41]; 0.053-0.7396, 0.0195-0.0489 [18]; 0.07-0.22 [72]; <LOQ-1.14 [17]; 0.0001-0.0003 [52]; 0.0378-0.5243 [73]; 0.60-0.62 [74]; 0.088-0.410, [43]; 0.005-1.17 [39], * 0.140-0.327 in d.w. [75], * 0.094-0.466 [76], * 0.16-0.53 [77] 0.50 and 1.0 (tuna) [26] As Cd 0.0033-0.0754 0.0046-0.0720 [16]; 0.002-0.07 [78]; 1.00-1.80 [66]; 0.08-0.66 [41]; 0.0-53.9 [18]; 0.019 [79]; <LOQ-0.09 [17]; 0.08 [36]; 0.0032-0.0834 [73]; 0.020-0.025 [74]; <LOQ-0.007 [39]; 0.03-0.12 [37]; <LOQ-0.18 [40]; 0.19-17.05 [80], * 0.008-0.191 in d.w. [75], * 0.021-0.082 [76], * 0.01-0.21 [77] 0.050 and 0.10 (sardine, tuna) [26] Pb 0.011-0.296 0.0126-0.0726 [16]; 0.007-0.51 [78]; 3-4.60, 3.60-4.00 [66]; 0.14-0.92 [41]; 0.02-1.37 [35]; 0.0-31.1 [18]; 0.11 [79]; <LOQ-4.13 [17]; 0.10 [36]; <LOQ-3.19, 0.35-2.10, 0.25-1.51 in d.w. [42]…”

Section: Comparison With Reported Literature Values and Withmentioning

confidence: 99%

“…e recommended daily intake of manganese should not exceed levels from 3.0 to 9.0 mg [34]. According to the literature, Cr and Mn contents in canned fish were found to be as follows: in the muscles of fish from Turkey, 0.19-2.80 and 0.08-3.88 mg·kg −1 [35]; in canned tuna and mackerel from the USA, Cr 0.0-0.067 and 0.01-0.30 mg·kg −1 , Mn 0.0-0.001 and 0.0-0.001 mg·kg −1 [18]; in canned tuna from Turkey, Cr 1.08 mg·kg −1 , Mn 0.90 mg·kg −1 [36]; in the canned fish samples from Iran, Cr 0.90-1.87 mg·kg −1 , Mn 1.20-2.70 mg·kg −1 [37]; in canned tuna from the Kingdom of Saudi Arabia, 0.0029 for Mn, 0.0005 for Cr [38]; in the canned tuna from Mexico, for Cr 0.02 to 0.65 mg·kg −1 , 0.07 to 0.38 mg·kg −1 in the fresh fish samples [39]; in canned fish from China, Cr 0.08-1.28 mg·kg −1 [40]; in canned tuna from the Kingdom of Saudi Arabia, Cr 0.10-0.57 mg·kg −1 [41]; in muscles of fresh fish from Iraq, Mn 0.11-1.86 mg·kg −1 dry weight, in the muscles of frozen fish species 0.13-4.50 mg·kg −1 dry weight, and in canned fish 0.13-0.81 mg kg −1 dry weight [42]; in canned tuna from Ghana, Mn 0.001-0.057 mg·kg −1 [43]. Cr content in Bangladesh fish ranged from 2.09 to 7.18 mg·kg −1 , and Mn from 23.23 to 25.65 mg·kg −1 [44].…”

Section: Comparison With Reported Literature Values and Withmentioning

confidence: 99%

“…In humans, the levels of nickel absorption are very low, of the order of over ten mg·kg −1 . According to the literature data, the level of Ni in canned fish was as follows: in canned tuna from the Kingdom of Saudi Arabia, 0.09-0.48 mg·kg −1 [41]; in the muscles of fish from Turkey, 0.03-0.63 mg·kg −1 [35]; in canned fish from Iraq, 0.0001 to 0.0003 mg·kg −1 [52]; in muscles from Iraq, 0.11-0.31 mg·kg −1 dry weight, in fresh fish 0.37-2.30 mg·kg −1 dry weight, in the muscles of frozen fish species and in canned fish 0.33-1.96 mg·kg −1 dry weight [42]; in canned tuna from the Kingdom of Saudi Arabia, 0.0018 mg·kg −1 for Ni [38]; in the canned fish samples, 0.58-1.04 mg·kg −1 [37]. In a study conducted in the USA, the content of Ni in canned fish was in the range from <LOQ to 0.783 mg·kg −1 [18].…”

Section: Comparison With Reported Literature Values and Withmentioning

confidence: 99%

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Determination of the Level of Selected Elements in Canned Meat and Fish and Risk Assessment for Consumer Health

Kowalska

Pankiewicz

Kowalski

2020

Journal of Analytical Methods in Chemistry

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e objective of the study was to determine the content of cobalt, silver, tin, antimony, lead, mercury, cadmium, arsenic, vanadium, chromium, manganese, nickel, and uranium in canned meat and canned fish by means of ICP-MS apparatus and mercury analyzer. Also, probabilistic risk assessment (non carcinogenic) was estimated by models including target hazard quotient (THQ). It was found that Mn was the element with the highest concentration in the analyzed products, with average concentration of 0.216 mg·kg −1 in canned meat and 1.196 mg·kg −1 in canned fish. e average contents of other elements were as follows (respectively, for canned meat and fish): Co 0.018 and 0.028 mg·kg −1 , Ag 0.0386 and 0.0053 mg·kg −1 , Sn 0.059 and 0.200 mg·kg −1 , Sb 0.0268 and 0.0377 mg·kg −1 , Pb 0.202 and 0.068 mg·kg −1 , Hg 0.00003 and 0.02676 mg·kg −1 , Cd 0.00496 and 0.0202 mg·kg −1 , As 0.002 and 0.857 mg·kg −1 , V 0.0003 and 0.095 mg·kg −1 , Cr 0.244 and 0.590 mg·kg −1 , Mn 0.216 and 1.196 mg·kg −1 , Ni 0.004 and 0.088 mg·kg −1 , and U < LOQ and 0.047 mg·kg −1 . e concentration of As was the highest among other toxic elements in canned fish; therefore, the THQ value of this element revealed the highest level amounting up to 0.77576 (THQ max ).

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“…The absence of mining activities (the latter are considered as one of the major contributors of cadmium) along the courses of the rivers in the Zambezi region (MacDonald, 2007) may explain the absence of cadmium in fish in this study. Previous studies in a number of freshwater fish species did not also detect cadmium (Addo-Bediako et al 2014;Jooste et al 2015;Garcia et al 2016;Korkmaz et al 2017). It has also been reported that cadmium has a lower bioaccumulation in fish muscle, compared with kidneys and livers (Chowdhury et al 2004;Shinn et al 2009 Li 2018).…”

mentioning

confidence: 94%

Cadmium and lead levels in three freshwater fish species from the Zambezi region, Namibia

Madzingira

Lifumbela

Kandiwa

et al. 2020

African Journal of Aquatic Science

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Muscle tissue from three-spotted tilapia (Oreochromis andersonii) (n = 11), sharp tooth catfish (Clarias gariepinus) (n = 14) and tigerfish (Hydrocynus vittatus) (n = 12) were sampled from a market in the Zambezi region, Namibia in June 2018 and analysed for cadmium and lead. Cadmium was not detected in the three fish species. Mean lead levels in all three fish species (0.09-0.19 mg kg −1) were below the recommended safe level of 0.3 mg kg −1. Catfish had the highest mean lead concentrations, followed by tigerfish and tilapia in descending order. However, the differences in mean lead concentrations between the three fish species were not statistically significant (ANOVA, p = 0.18). These results show that the fish tested were safe for human consumption with respect to the metals tested. It is recommended that more metals and other contaminants, such as pesticides, be monitored robustly in water, sediment and fish, using the recommended protocols, in order to generate data that can be reliably used for human health risk assessments in the future.

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Heavy Metal Levels in Muscle Tissues of Solea solea, Mullus barbatus, and Sardina pilchardus Marketed for Consumption in Mersin, Turkey

Cited by 39 publications

References 34 publications

Trace elements risk assessment for consumption of wild mussels along South Africa coastline

Trace elements risk assessment for consumption of wild mussels along South Africa coastline

Determination of the Level of Selected Elements in Canned Meat and Fish and Risk Assessment for Consumer Health

Cadmium and lead levels in three freshwater fish species from the Zambezi region, Namibia

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