Abstract

Levels of sixteen polycyclic aromatic hydrocarbons (PAHs) in 30 edible tissues of selected frequently-consumed fish and seafood collected from three coastal waters of Niger Delta, namely, Sime, Kporghor and Iko were investigated in 2014. Gas chromatographic analysis were employed for PAHs determination. Observed mean PAHs levels in the samples ranged from below detection limit (BD) of analytical instrument to 22.400 ± 0.050 μg kg−1 wet wt. in Littorina littorea, BD to 87.400 ± 0.030 μg kg−1 wet wt. in Crassostrea virginica and from BD to 171.000 ± 0.430 μg kg−1 wet wt. in Periophthalmus koeleuteri. The highest average concentration of 171.000 ± 0.430 μg kg−1 wet wt. was recorded for Indeno [1,2,3-cd]pyrene from Sime water. High molecular weight PAHs (HMW-PAHs) were generally predominant compared to low molecular weight PAHs (LMW-PAHs). The LMW- PAH/HMW-PAH ratio was <1 for all species, indicating anthropogenic origin of PAHs in the coastal waters of Niger Delta environment. Moreover, the study of the PAHs fingerprints, using specific ratios, suggests the predominance of a pyrolytic origin for observed PAHs.

Keywords

Organic contaminants ; LMW- PAH/HMW-PAH ratio ; Nigerian waters ; Bioaccumulation ; Exposure ; Water pollution ; Specialty: Safety issues ; Water pollution ; Bioaccumulation

1. Introduction

Marine and terrestrial environments, in the recent times, have been tagged with abundance of persistent organic pollutants. This sordid situation is worsened by the emergence of densely populated industrial districts as both environmental components are important in most activities leading to economy development, and at the same time cast an ominous pall on the environment directly or indirectly. Oshineye [23] reported Nigeria’s oil reserves of about 31.5 billion barrels and crude oil production of about 2.118 million barrels per day in the post- 2000 era, underscoring the enormity or oil and related activities in Nigeria. There are 606 oil fields in the Niger Delta of which 360 are onshore and 246 are offshore [18] . Associated gas flaring, above ground pipeline leakage, oil waste dumping, sabotage and oil spills lead to environmental pollution. Pollution caused by petroleum and its derivatives is the most prevalent problem in the environment. The release of crude oil into the environment by oil spills is receiving worldwide attention [17] . Crude oil spills of January 12, 1998 and July, 1979 at Mobil Unlimited Idoho platform (45,000 barrels) and West of Shell operated forcados terminal storage facility (560,000 barrels) respectively spilled into the Atlantic coastal line in Nigeria, its surrounding land, mangrove swamps and territorial waters. Similarly, other anthropogenic activities in coastal areas contributing to PAHs contamination of coastal environments could include use of creosote—treated wood in aquaculture, bush burning, industrial effluent discharge, dense vehicular emissions, artisanal refining of petroleum products as seen in the Niger Delta among others. These activities Such impact however, is often assessed from changes in the physical, chemical [19] and biological components of the ecosystem.

Human health is largely determined by the diet and recommendable diet should be able to provide sufficient nutrients and low levels of pathogenic microorganisms, as well as chemical contaminants. Fish constitutes an important source of proteins, vitamins and unsaturated essential fatty acids (PUFA), especially omega-3 PUFAs [3] . In contrast to the potential health benefits of dietary fish intake, say in the prevention of coronary heart disease, an issue of concern related to frequent fish consumption is the risk derived from exposure to chemical pollutants. The pollution of the environment by PAHs is a major concern [20] . PAHs are large class of persistent organic pollutants containing two or more fused benzene rings. They are known to be ubiquitous in both marine and terrestrial environments [5] and are included in the EU and USEPA priority pollutant list due to their mutagenic and carcinogenic properties [28] . Predominant exposure route is dietary, excluding smokers and occupationally exposed populations. As chemically stable and lipophilic compounds [5] , they can easily cross lipid membrane and have the potential to bioaccumulate in aquatic organisms. Based on physical and biological properties, PAHs are classified into high molecular weight (HMW) and low molecular weight (LMW) types. Those consisting of 4–6 aromatic rings are termed HMW and have been shown to be less readily bio-degraded by native microorganisms and can bioaccumulate in the aquatic organisms like fish and mussels. On the other hand, LMW PAHs consists of 2–3 aromatic rings and although less carcinogenic than HMW type [6] a pose toxic to many aquatic organisms. [32] reported the possiblity of using Periwinkles and Oysters as pollution biomonitors due to the fact that they are sedentary or bottom feeders they are good accumulators of heavy. Although for most people, fish and seafood represents only a small part of the total diet, this trend may differ in the Niger Delta communities. European Union established a maximum level of 1 μg g−1 wet weight for benzo (a) pyrene in foodstuff and is used for the carcinogenic risk of PAHs in muscle meat of fish [11] but more recently, it was attributed to dibenzo(a,1) pyrene a carcinogenic potency that is about 100 times that of benzo(a) pyrene [22] .

PAHs cause tainting on seafoods, have relatively low solubility and high affinity for particles, and most PAHs can therefore be found attached to particles that have settled or are suspended in the water column [25] . European Union has stressed and recommended that PAHs be measured in as wide as possible in food products in order to obtain data on the occurrence and specific concentrations in a variety of matrices [31] .

Kporghor and Iko rivers are located in Eastern Obolo Local Government Area (LGA) of AkwaIbom state (lying by Rivers state), and have been exposed to oil spill from the Shell Petroleum Development Company (Nigeria) Ltd pipeline, artisanal refining and pipeline vandalization. Sime (Tai) water is located in Tai LGA Rivers State (a known oil polluted zone), all in the Niger Delta region of Nigeria. Map of study area is as shown in Fig. 1  as reported in a study report by UNEP (2011). Average consumption of seafood in these communities is about 370 g per week going by measured dry weight of possible number at random per meal consumed. This study seeks to assess the levels of PAHs in commonly consumed and commercially viable fish and seafood species, Periophthalmus koeleuteri (Mudskipper), Littorina littorea (Periwinkle) and Crassostrea virginica (Oyster) from Nigerian coastal waters and identify the probable sources.


Map of Ogoniland showing sampling area (UNEP, 2011).


Fig. 1.

Map of Ogoniland showing sampling area (UNEP, 2011).

2. Material and methods

2.1. Sample collection and preparation

Fresh samples of L. littorea , P. koeleuteri and C. virginica were collected from landing beaches of Kpoghor, Iko and Sime towns using harvesting buckets provided by local fishermen. At each site, ten individual Mudskippers, Periwinkles and Oysters of similar size and species were collected, cleaned and wrapped in aluminum foils, and kept frozen in an ice chest cooler for onward transportion to the laboratory for analysis.

2.2. Determination of polycyclic aromatic hydrocarbons levels

Fresh samples were well cleaned in distilled water to remove any external dirt. Dissection was performed on fresh samples, using instruments and glass dishes rinsed with solvent. Tissues were dissected and minced into smaller pieces, and a subsample was taken from the homogenate. The samples were then blended and kept in air tight containers prior to extraction process. Two grams of samples were weighed into a clean extraction container (50 ml beaker). A 10 ml analar grade extraction solvent (dichloromethane) was added into the sample and mixed thoroughly and allowed to settle. The mixtures were carefully filtered into clean solvent rinsed extraction bottle, using filter paper fitted into Buchner funnels. Transfered extracts were concentrated to 2 μl for cleanup/separation in gas chromatographic analysis (HP 5890 series II, GC apparatus, coupled with flame ionization detector (FID) HP Wilmington, DE, USA equiped with HP chemstation Rev. A 09:01 (10206) software). Elution protocol as given in instruction manual was strictly followed as in high pressure solvent extraction. Separation occured as the vapor constituent partition between the gas and liquid phase and the sample was automatically detected as it eluted from the column (at constant flow rate) by the FID detector which response is dependent upon the composition of the vapor. To determine whether analyte detection was affected by the difference between diluent used for PAHs extraction and the experimental sample matrix, prepared standard curves were used to extrapolate the amount of added analyte in each case which denoted the spike recovered. There were no discrepancies observed. This was done by an addition of evenly spaced four (4) aliquots of spike to samples and these spiked aliquots were used to generate a calibration line and amount in the sample was calculated.

2.3. Statistical analysis

Means of ten replicates were subjected to ANOVA using Excel windows 10 and Duncan Multiple Range Test was employed for comparisons.

3. Results

From the results obtained, mean levels (μg kg−1 wet wt.) of the sixteen PAHs distribution in L. littorea, C. virginica and P. koeleuteri collected from Sime, Kporghor and Iko coastal waters are as shown in Tables 1, 2 and 3 respectively. Also, low molecular weight: high molecular weight PAHs, LMW-PAH/HMW-PAH and Benzo(a) anthracene divided by the sum of Benzo(a) anthracene and Chrysene, BaA/(BaA + Chry) ratios [24] for all samples were shown. Average levels of individual PAHs ranged from below detection limit (BD) of analytical instrument to 22.400 ± 0.050 μg kg−1  wet wt. with the highest (22.400 ± 0.050 μg kg−1 wet wt.) recorded for carcinogenic Indeno[1,2,3-cd]pyrene for L. littorea from Kporghor coastal water. Similarly, total PAHs levels were 7.150 ± 0.040, 35.800 ± 0.100 and 30.100 ± 0.090 μg kg−1  wet wt. for Sime, Kporghor and Iko samples respectively (Fig. 2 ) and were statistically significant for L. littorea . Presence of Seriously carcinogenic B[a]P was observed ( Fig. 3 ) for all samples. LMW-PAH/HMW-PAH ratios for samples from Iko waters (0.001 and 0.004) were markedly lower relative to the ratios found in Sime (0.002 and 0.010) and Kporghor (0.010 and 0.500) for L. littorea and C. virginica respectively. LMW-PAH/HMW-PAH ratios for L. littorea species from all the sites were <1 indicating anthropogenic contributions. Attempted classifications of constituent PAHs based on carcinogenicity are also discussed.

Table 1. PAHs levels (μg kg−1  wet wt.) for Littorina littorea from the study areas (Sime, Kporghor and Iko coastal waters).
PAHs Sime Tai Kpoghor Iko
Naphthalene BD BD BD
Acenaphthylene BD BD BD
Acenaphthene BD BD BD
Fluorene BD 0.040±0.004 BD
Phenanthrene 0.030±0.004 0.010*±0.002 0.020±0.003
Anthracene 0.020±0.002 0.010*±0.000 0.020±0.003
Fluoranthene 0.010±0.000 0.030±0.004 0.030±0.004
Pyrene 0.030±0.004 0.040±0.004 0.040±0.003
Benzo[a]anthracene 0.050±0.004 0.002*±0.004 0.080±0.004
Chrysene 0.080*±0.004 BD 0.010*±0.002
Benzo[b]fluoranthene 4.240*±0.010 13.300±0.030 16.800±0.040
Benzo[k]fluoranthene 0.004.001 BD 0.040*±0.004
Benzo[a]pyrene 0.010*±0.000 0.010*±0.000 0.020*±0.003
Indeno[1,2,3-cd]pyrene 2.650*±0.010 22.400*±0.050 13.100*±0.020
Dibenzo[a,h]anthracene 0.010*±0.002 0.002±0.000 0.002±0.000
Benzo[g,h,i]perylene 0.020*±0.002 0.010±0.002 0.010±0.002
Total 7.150*±0.040 35.800*±0.100 30.100*h±0.090
LMW-PAH/HMW-PAH 0.010*±0.001 0.002*±0.000 0.001*±0.000
BaA/(BaA+Chry) 0.380±0.001 1.000*±0.003 0.890±0.001

Means with superindices (*) across rows are significantly different (P  < 0.05), values are mean ± S.E.M (n  = 10). BD = below detection limit of 0.0001.

Table 2. PAHs levels (μg kg−1  wet wt.) for Crassostrea virginica from the study areas (Sime, Kporghor and Iko coastal waters).
PAHs Sime Tai Kpoghor Iko
Naphthalene BD BD BD
Acenaphthylene BD 0.002±0.00 0.010±0.002
Acenaphthene BD 0.003±0.00 0.060±0.004
Fluorene BD 0.04±0.004 0.120±0.010
Phenanthrene 0.060*±0.004 0.01*±0.00 0.130*±0.010
Anthracene 0.050±0.010 0.05±0.004 0.020±0.002
Fluoranthene 0.090*±0.004 0.490±0.010 0.230±0.010
Pyrene 0.050±0.010 0.030±0.002 0.050±0.004
Benzo[a]anthracene 0.030*±0.003 0.003*±0.000 0.010*±0.002
Chrysene 0.030±0.003 BD 0.090±0.004
Benzo[b]fluoranthene 2.720*±0.010 87.400*±0.030 63.90*±0.004
Benzo[k]fluoranthene 0.020±0.002 0.010±0.000 0.060*±0.010
Benzo[a]pyrene 0.070±0.004 0.010*±0.002 0.020±0.002
Indeno[1,2,3-cd]pyrene 0.010*±0.002 16.900*±0.030 32.100*±0.020
Dibenzo[a,h]anthracene 0.490*±0.004 0.050*±0.004 0.170*±0.010
Benzo[g,h,i]perylene 0.050±0.01 0.020±0.002 0.180*±0.004
TOTAL 3.670*±0.050 105.000±0.090 97.200±0.090
LMW-PAH/HMW-PAH 0.500±0.002 0.010±0.000 0.004*±0.000
BaA/(BaA+Chry) 0.500*±0.010 0.030*±0.001 0.100*±0.002

Means with superindices (*) across rows are significantly different (P  < 0.05), values are mean ± S.E.M (n  = 10). BD = below detection limit of 0.0001.

Table 3. PAHs levels (μg kg−1  wet wt.) in Periophthalmus koeleuteri from the study areas (Sime, Kporghor and Iko coastal waters).
PAHs Sime Tai Kpoghor Iko
Naphthalene BD BD BD
Acenaphthylene BD 0.002±0.000 BD
Acenaphthene BD 0.001±0.000 BD
Fluorene 0.010±0.000 0.003±0.000 BD
Phenanthrene 0.030±0.004 0.240*±0.040 BD
Anthracene BD 0.040±0.003 BD
Fluoranthene 0.060*±0.004 2.460*±0.010 0.010*±0.002
Pyrene 0.050±0.010 0.090±0.004 0.010±0.000
Benzo[a]anthracene 0.003*±0.000 0.002*±0.000 0.030*±0.010
Chrysene BD BD 0.090±0.004
Benzo[b]fluoranthene 0.860*±0.004 10.400*±0.040 49.300*±0.050
Benzo[k]fluoranthene 0.001±0.000 0.001±0.000 0.001±0.002
Benzo[a]pyrene BD BD 0.002±0.000
Indeno[1,2,3-cd]pyrene 171.000*±0.430 32.700*±0.030 3.670*±0.010
Dibenzo[a,h]anthracene 0.002±0.000 BD 0.001±0.002
Benzo[g,h,i]perylene 0.001±0.000 BD 0.004±0.000
TOTAL 171.900*±0.450 45.900±0.120 53.100±0.070
LMW-PAH/HMW-PAH 0.000*±0.000 0.010*±0.000 5.310*±0.090
BaA/(BaA+Chry) 0.100*±0.004 1.000*±0.020 0.430*±0.050

Means with superindices (*) across rows are significantly different (P  < 0.05), values are mean ± S.E.M (n  = 10). BD = below detection limit of 0.0001.


Mean total PAHs level (mean±SEM) in study samples from Sime, Kporghor and Iko ...


Fig. 2.

Mean total PAHs level (mean ± SEM) in study samples from Sime, Kporghor and Iko coastal waters. Means with same alphabets are not significantly different ( < 0.05). Sime, Kporghor and Iko are various coastal water locations to show sample source.


Distribution of PAHs by type in study samples: BDL, SC, WC, C and NC represent ...


Fig. 3.

Distribution of PAHs by type in study samples: BDL, SC, WC, C and NC represent below detection limit of the analytical instrument, Strongly carcinogenic, Weakly carcinogenic, Carcinogenic and Not carcinogenic PAHs, respectively. Iko, Kporghor and Sime appended to sample names (scientific) are various coastal water locations to show source.

4. Discussion

Useful ratio, BaA/(BaA + Chry) (Benzo(a) anthracene divided by the sum of Benzo(a) anthracene and Chrysene), was adopted to analyse possible sources of polycyclic aromatic hydrocarbons in study samples. L. littorea from Kporghor and Iko waters gave mean value >0.890 while that from Sime water was markedly below. BaA/(BaA + Chry) ratios for L. littorea samples were 0.380, 1.000 and 0.890 from Sime, Kporghor, and Iko waters respectively. The BaA/(BaA + Chry) ratio for L. littorea from Kporghor is, however, markedly higher relative to the ratios found for Sime and Iko samples. This implies more of pyrogenic sources of PAHs as [21] reported that a BaA/(BaA + Chry) ratio >0.350 indicates pyrogenic or combustion sources while those < 0.200 has been attributed to petrogenic sources. These sources are however indistinguishable for ratios in the range 0.200–0.350 [21] . Carcinogenic Benzo[b]Fluoranthene levels in L. littorea samples from Kporghor and Iko waters exceeded the European Union (EU) limit of 12.000 μg kg−1  wet wt. while those from Sime were below. Collectively, bioaccumulation of strongly and weakly carcinogenic (Fig. 3 ) PAHs was not expressed in P. Koeleuteri samples harvested from Kpoghor and Sime water bodies. Non-carcinogenic types however, were more in abundance of the total 16 PAHs observed.

Up to 171.900 μg g−1  wet wt. of PAHs was obtained for P. koeleuteri and far exceeded highest amount of 70.440 ng g−1  wet wt. obtained among five species of fish samples collected along the harbor line, Mumbai [9] and 3.365 ppm in edible fishes of the Gomti river, Lucknow, India [15] .

After reviewing the available data on occurrence and toxicity of the 15 PAHs identified by SCF in 2002 and additionally BF which had been suggested by the Joint FAO/WHO Expert Committee on Food Additives (JECFA) in 2005, the CONTAM Panel [10] recommended that groups of PAHs termed PAH4 (Benzo (a) pyrene, Chrysene, Benzo (a) anthracene and Benzo (b) fluoranthene) were better indicators of PAHs occurrence than Benzo (a) pyrene on its own in food. From this study P. koeleuteri samples (49.420 μg kg−1 ) from Iko coastal waters far exceeded the EU regulatory limits of Maximum levels of 30 μg kg−1 wet wt. for PAH4 in Commission Regulation (EU) No 835/2011. In the same vein, samples of C. virginica from Kporghor and Iko coastal waters gave PAH4 values of 87.410 μg kg−1 and 63.930 μg kg−1 respectively and could be highly implicated in their potentials as carcinogens.

The sources of PAHs in coastal environment are described as either petrogenic (if the source is derived from petroleum, e.g. natural oil seepage and oil spills) or pyrogenic (if the source is derived from the incomplete combustion of organic matter and fossil fuel [1] and the ratio of low molecular weight PAHs (LMW-PAHs) to high molecular weight PAHs (HMW-PAHs) has been used to characterize the origin of PAHs in the environment [29]  and [26] . Results gave global distribution pattern characterized by an abundance of heavy compounds illustrated by a median LMW-PAH/HMW-PAH ratio value of 0.002 (Table 1 ). This high concentration of heavy molecular weight PAHs indicates a predominant pyrolytic origin for the PAH pollution. This approach has been used to characterize the sources of PAHs in sediments and was adopted to characterize the sources of PAHs in the fish and seafoods analysed. Combustion processes, therefore appear as the main formation mechanism for the PAHs bioaccumulated in study species. Predominance of the pyrolytic origin may be linked to intense illegal refining in the region and other linear and diffused sources may be linked to the great number of linear and diffuse combustion sources.

Samples of C. virginica gave mean PAHs distribution in Sime, Kporghor and Iko coastal waters as shown in Table 2 . A total of sixteen PAHs were detected of which 10%, 15% and 15% distribution pattern were seen in Sime, Kporghar and Iko water samples respectively. Average levels of these PAHs ranged from BD to 87.400 ± 0.030 μg kg−1  wet wt. The highest average individual concentration of 87.400 ± 0.030 μg kg−1  wet wt. was recorded for carcinogenic Benzo[b]Fluoranthene from Kporghor. Fig. 3 illustrates the uniform clear distribution of strongly carcinogenic PAHs in C. virginica samples across locations. The LMW-PAH/HMW-PAH ratios in Iko samples were markedly lower relative to those of Sime and Kporghor and were < 1 for C. virginica species from all the sites ( Table 1 , Table 2  and Table 3 ). The BaA/(BaA + Chry) ratios for C. virginica from Sime was, however, markedly higher relative to the ratios found in C. virginica from Kporghor and Iko waters. The BaA/(BaA + Chry) ratios for C. virginica from Sime and Iko waters were >0.03 as against that of Kpoghor. Indeno[1,2,3-cd]pyrene levels in C. virginica from Iko and Kporghor locations exceeded the European Union (EU) limit of 5 μg kg−1  wet wt. B[a]P recommended allowable daily intakes range from 0.04 to 0.42 g day−1 in Italy [14] for different foodstuffs and had its lower limit exceded for C. virginica in this study and could imply danger. Several carcinogenic PAHs have been reported in water and food samples [33] . As a result, the accumulation in the environment has become an issue of global health concern, the principal route of exposure to man, being the consumption of contaminated water, foods and marine products most especially fish [13]  and [2] .

Mean PAHs distribution in P. koeleuteri collected from study locations are as shown in Table 3 , alongside their LMW-PAH/HMW-PAH and BaA/(BaA + Chry) ratios. A total of 16 PAHs were detected and average individual levels of these PAHs ranged from BD to 171 ± 0.430 μg kg−1 wet wt. The highest level of 171 ± 0.430 μg kg−1  wet wt. was recorded for Indeno[1,2,3-cd]pyrene from Sime. Total PAHs levels in this sample were significantly higher (171 ± 0.450 μg kg−1  wet wt.) in Sime samples (Fig. 2 ). The LMW-PAH/HMW-PAH ratios for Sime samples were markedly lower (p  ≤ 0.05) relative to the ratios found in Kporghor and Iko waters. BaA/(BaA + Chry) ratios for P. koeleuteri were 0.100, 1.000 and 0.430 for Sime, Kporghor, and Iko waters respectively. The BaA/(BaA + Chry) ratios for P. koeleuteri from Kporghor, is markedly higher relative to the ratios found for Sime and Iko samples. Carcinogenic Benzo[b]fluoranthene levels in P. koeleuteri from Iko location exceeded the European Union (EU) limit of 12 μg kg−1  wet wt. It is important to note that observed PAHs levels exceeded reported measurable but low levels in fresh fish and seafoods studied in similar communities [27] . For Sime, C. virginica accumulated significantly lower (P  < 0.05) concentrations of total PAHs than L .littorea and P. koeleuteri . This is possibly due to local physical mixing, as a result of fishing activities, exposing the fishes to PAHs irrespective of where these fishes may be found. The observed differences in PAH bioaccumulation in study species may also be attributed to differences in feeding preferences and general behavior [12] . The LMW- PAH/HMW-PAH ratios indicate that the HMW-PAHs were generally predominant compared to the LMW-PAHs. The predominance of HMW-PAHs may be due to preferential degradation during PAHs transport and burial into sediments [4] .

Levels of PAHs in L. littorea, C. virginica and P. koeleuteri reflect the state of contamination of the environment, although highest PAHs level of 171.900 μg kg−1  wet wt. for Sime samples (Table 3 ), with less distribution of carcinogenic PAHs (Fig. 3 ), illustrates the less carcinogenicity of its heterogenous components. The LMW-PAH/HMW-PAH ratios observed in in the four species from all three locations were < 1, indicating that the sources of these PAHs in study species are mainly pyrogenic. This is thus a clear indication of anthropogenic pollution of PAHs in the coastal marine environment. The observed BaA/(BaA + Chry) ratios for the three species from all the locations were >0.350 except C. virginica ( Kporghor and Iko locations) and P. koeleuteri ( Sime location). This also indicated abundant pyrogenic sources of PAHs contamination. Possible anthropogenic sources include combustion of petroleum, automobile tyre, wood and vehicle emissions. Bioaccumulation of strongly carcinogenic PAHs was least with P. koeleuteri and hence it may not constitute a good biomonitor. The coastal people who tend to consume larger quantities of fish [30] could be at a greater risk to health issues like growth reduction, endocrine alteration [16] , cancer, mutations and birth defects. Also, malformations of embryo and larvae [8] and DNA damage [7] in fish could give residual effects in man. Suitable clean-up technologies, awareness campaign and mitigation measures, are therefore recommended.

5. Conclusion

The present study demonstrated the suitability of C. virginica  > L. littorea in environmental montoring over P. koeleuteri and also underscored the need for a holistic characterization in monitoring and response as bulk conentrations could be misleading. Generally, observed elevated PAHs in fish and seafoods harvested from 3 costal waters in the Niger Delta region were implicated to be of anthropogenic origin. The investigation of the aromatic compound distributions in all of the 30 fish and seafood samples have underlined that there is a heterogeneous PAHs background pollution. All of degradative activities and their effects left an environmental footprint and needs attention.

Transparency document

Acknowledgement

The authors will like to acknowledge Oboh Kingsley for assistance in the statistical analysis.

References

  1. [1] Abrajano TA, Yan B, O’Malley V., 2003. High molecular weight petrogenic and pyrogenic hydrocarbons in aquatic environments. In Environmental Geochemistry Treatise on Geochemistry. (B. Sherwood Lollar, ed.). 9: 475–509.
  2. [2] O. Ajiboye, A. Yakubu, T. Adams; A review of polycyclic aromatic hydrocarbons and heavy metal contamination of fish from fish farms; J. Appl. Sci. Environ. Manag., 15 (2001), pp. 235–238
  3. [3] K.D. Bartle; Purchase, Food Contaminant, Sources and Surveillance; C.S. Creaser (Ed.)Royal Society of Chemistry, Cambridge (1991)
  4. [4] D. Berto, F. Cacciatore, A. Ausili, G. Sunseri, G. Luca, L.G. Bellucci, M. Frignani, S. Albertazzi, M. Giani; Polycyclic Aromatic Hydrocarbons (PAHs) from Diffuse Sources in Coastal Sediments of a Not Industrialised Mediterranean Island.; Qualità del Pianeta-Contaminazione Chimica, vol. 200, Kluwer Academic Publishers (2009), pp. 199–209
  5. [5] I. Bouloubassi, L. Méjanelle, R. Pete, J. Fillaux, A. Lorre, V. Point; Transport by sinking particles in the open Mediterranean Sea: a 1 year sediment trap study; Mar. Pollut. Bull., 52 (2006), pp. 560–571
  6. [6] J. Brown, B. Peake; Sources of heavy metals and polycyclic aromatic hydrocarbons in urban storm water runoff; Sci. Total Environ., 359 (2006), pp. 145–155
  7. [7] I. Caliani, S. Porcelloni, G. Mori, G. Frenzilli, M. Ferraro, L. Marsili, S. Casini, M.C. Fossi; Genotoxic effects of produced waters in mosquito fish (Gambusia affinis )  ; Ecotoxicology, 18 (2009), pp. 75–80
  8. [8] L. Camus, G.H. Olsen; Embryo a b e r r a t i o n s i n s e a i c e a m p h i p o d (Gammaruswilkitzkii) exposed to water soluble fraction of oil; Mar. Environ. Res., 66 (2008), pp. 221–222
  9. [9] V. Dhananjayan, S. Muralidharan; Polycyclic aromatic hydrocarbons in various species of fishes from Mumbai Harbour, India, and their dietary intake concentration to human; In. J. Oceanogr., 2012 (2012), p. 6
  10. [10] European Food Safety Authority (EFSA); Polycyclic Aromatic Hydrocarbons in Food: Scientific Opinion of the Panel on Contaminants in the Food Chain. (Question N(. EFSA-Q-2007-136.); EFSA J. (2008), p. 724
  11. [11] EU., 2006. European Union. Commission Regulation (EC) No 1881/2006 of 19 December 2006 setting maximum levels for certain contaminants in foodstuffs [Official Journal L 364 of 20.12.2006] http://europa.eu/legislation_summaries/consumers/productlabellingandpackaging/l21101aen.htm . (retrieved 16.1013.).
  12. [12] S.W. Fisher; Mechanisms of bioaccumulation in aquatic systems; Rev. Environ. Contam. Toxicol., 142 (1995), pp. 87–118
  13. [13] M. Gómez-Guillén, J. Gómez-Estaca, B. Giménez, P. Montero; Alternative fish species for cold- smoking process; Int. J. Food Sci. Technol., 44 (2009), pp. 1525–1533
  14. [14] M. Lodovicci, P. Dolara, C. Casaini, S. Ciappellano, G. Testolin; Polycyclic aromatic hydrocarbons in the Italian diet; Food Add. Contam., 12 (2009), pp. 703–713
  15. [15] A. Malik, P. Ojha, K.P. Singh; Distribution of polycyclic aromatic hydrocarbons in edible fish from Gomti river: India; Bull. Environ. Contam. Toxicol., 80 (2) (2008), pp. 134–138
  16. [16] J.P. Meador, F.C. Sommers, G.M. Ylitalo, C.A. Sloan; Altered growth and related physiological responses in juvenile Chinook salmon (Oncorhynchus tshawytscha) from dietary exposure to polycyclic aromatic hydrocarbons (PAHs); Can. J. Fish. Aquat. Sci., 63 (2006), pp. 2364–2376
  17. [17] V.S. Millioli, E.L.C. Servulol, L.G.S. Sobrald, D.D. de Carvalho; Bioremediation of crude oil-bearing soil: evaluating the effect of rhamnolipid addition to soil toxicity and to crude oil biodegradation efficiency; Glob. NEST J., 11 (2009), pp. 181–188
  18. [18] Nigeria Country Analysis Brief. 2005. http://resourcedat.com/nigeria-country-analysis-brief-2005/ . (retrieved 2.09.13.).
  19. [19] E.O. Nwaichi, D.C. Belonwu, C.J. Nkomadu; Distribution of some Heavy Metals in selected Seafood and Shell from Abonnema water in rivers in State Nigeria; Int. J. Pur Appl. Biosci., 1 (2013), pp. 63–66
  20. [20] E.O. Nwaichi, E.N. Onyeike, M.O. Wegwu; Characterization and safety evaluation of the impact of hydrocarbons contaminants on ecological receptors; Bull. Environ. Contam. Toxicol., 85 (2010), pp. 199–204
  21. [21] E. Nyarko, B.O. Botwe, E. Klubi; Polycyclic aromatic hydrocarbons (PAHs) levels in two commercially important fish species from the Coastal Waters of Ghana and their carcinogenic health risks; West Afr. J. Appl. Ecol., 19 (2011), pp. 53–66
  22. [22] K.B. Okona-Mensah, J. Battershill, A. Boobis, R. Fielder; Food Chem. Toxicol., 43 (2005), pp. 1103–1116
  23. [23] A. Oshineye; The petroleum industry in Nigeria. An overview; Modern Pract. J. Finance Invest. law. Learned Publ. ltd., 4 (2000), p. 4
  24. [24] T.F. Silva, D.A. Azevedo, F.R. Aquino Neto; Distribution of polycyclic aromatic hydrocarbons in surface sediments and waters from Guanabara Bay, Rio de Janeiro; Braz. J. Braz. Chem. Soc., 18 (3) (2007), pp. 628–637
  25. [25] J. Simon, J. Sobieraj; Contributions of common sources of polycyclic aromatic hydrocarbons to soil contamination; Remediat. J., 16 (2006), pp. 25–35
  26. [26] H.H. Soclo, P. Garrigues, M. Ewald; Origin of polycyclic aromatic hydrocarbons (PAHs) in coastal marine sediments: case studies in Cotonou (Benin) and Aquitaine (France) areas; Mar. Pollut. Bull., 40 (2000), pp. 387–396
  27. [27] UNEP., 2011. United Nations Environmental Progranme Report. Environmental Assessment of Ogoniland. ISBN: 978-92-807-3130-9. 94-200.
  28. [28] USEPA., 2000. Guidance for Assessing Chemical Contaminant Data for Use in Fish Advisories, EPA/823/B-00/007, United States Environmental Protection Agency.
  29. [29] Z. Wang, M. Fingas, D.S. Page; Oil spill identification; J. Chromatogr., 843 (1999), pp. 369–411
  30. [30] S. Wei, R.K.F. Lau, C.N. Fung, G.J. Zheng, J.C.W. Lam, D.W. Connell, Z. Fang, B.J. Richardson, P.K.S. Lam; Trace organic contamination in biota collected from the Pearl River Estuary, China: a preliminary risk assessment; Mar. Pollut. Bull., 52 (2006), pp. 1682–1694
  31. [31] T. Wenzl, R. Simon, E. Anklam, J. Kleiner; Analytical methods for polycyclic aromatic hydrocarbons (PAHs) in food and the environment needed for new food legislation in the European Union; Trends Anal. Chem., 25 (2006), pp. 716–725
  32. [32] E.A. Wilson, E.N. Powell, T.L. Wader, R.J. Taylor, B.J. Presley, J.M. Brooks; Spatial and Temporal distribution of contaminant body and disease in the Gulf of Mexico oOyster Populations; Heigolander Meeresunters., 46 (1992), pp. 201–235
  33. [33] Z. Zelinkova, T. Wenzl; The Occurrence of 16 EPA PAHs in Food–a review; Polycycl. Aromat. Compd., 35 (2–4) (2015), pp. 248–284
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