Next Article in Journal
Dam Sustainability’s Interdependency with Climate Change and Dam Failure Drivers
Previous Article in Journal
Does Low-Carbon City Construction Promote Integrated Economic, Energy, and Environmental Development? An Empirical Study Based on the Low-Carbon City Pilot Policy in China
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Sustainability
Volume 15
Issue 23
10.3390/su152316242
sustainability-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Detection of Arsenic, Chromium, Cadmium, Lead, and Mercury in Fish: Effects on the Sustainable and Healthy Development of Aquatic Life and Human Consumers

by
Athanasia K. Tolkou
1,*,
Dimitra K. Toubanaki
2 and
George Z. Kyzas
1
1
Hephaestus Laboratory, Department of Chemistry, International Hellenic University, GR-65404 Kavala, Greece
2
Immunology of Infection Group, Department of Microbiology, Hellenic Pasteur Institute, GR-11521 Athens, Greece
*
Author to whom correspondence should be addressed.
Sustainability 2023, 15(23), 16242; https://doi.org/10.3390/su152316242
Submission received: 29 September 2023 / Revised: 21 November 2023 / Accepted: 22 November 2023 / Published: 23 November 2023
Browse Figures
Versions Notes

Abstract

:
Heavy metals are among the most important pollutants that threaten the aquatic environment when their concentrations exceed certain limits. Some of these metals and metalloids are beneficial and necessary for fish, but others, such as arsenic (As), chromium (Cr), cadmium (Cd), lead (Pb) and mercury (Hg), are non-essential and toxic. In reviewing the recent relevant literature, 4 different continents, 13 different countries, and more than 50 different fish species were analyzed in terms of As, Cr, Cd, Pb and Hg concentrations. According to the comparative results, it was found that in Tercan Dam Lake, Turkey, the highest concentration of Cr was detected in Capoeta umbla (2.455 mg/kg), and of As in Ctenopharyngodon idella (0.774 mg/kg) species. Greater values than the permissible limits of FAO/WHO in terms of As were also found in Andalusia, Southern Spain, in Mullus surmuletus (0.427 mg/kg), and Sardina pilchardus (0.561 mg/kg) and in Sprattus sprattus (0.636 mg/kg) in the Baltic Sea, but a remarkably high content of As (8.48 mg/kg) was determined in Penaeus notialis, found in Guinea, Africa. Moreover, Cd concentration was low to nil in almost all cases, with the exception of Amblyceps mangois species collected from the Dhaleshwari River in Bangladesh, which showed the highest value (0.063 mg/kg). Finally, extremely high levels of Pb were found in Plectropomus pessuliferus (5.05 mg/kg) and Epinephelus summana (2.80 mg/kg) in Jeddah, Saudi Arabia. The Hg content in fish was under the permissible limit in almost all cases, with megrim and red mullet from the Andalusian Sea exhibiting a relatively higher content (0.091 and 0.067 mg/kg). In general, the sequence of accumulation of toxic elements in fish was As > Cr > Pb > Cd > Hg.

1. Introduction

Heavy metals are one of the most important pollutants that threaten the aquatic environment and the living organisms in it when their concentrations exceed the permissible limits [1]. Although these metals are not always harmful or toxic to aquatic life, they can affect human health through the food chain [2]. The growing pollution of water resources by heavy metals poses a threat both to public water supplies and to consumers of fish and seafood in general [3]. Furthermore, heavy metals and metalloids have been shown to cause fish toxicity due to their non-biodegradability and long-term existence in the environment [4]. The study of the bioaccumulation of contaminants in fish is significant in order to determine the content of trace elements in different fish species, which are due both to their metabolic capacity and to their eating habits [5].
The early developmental stages of fish, namely embryos and larvae, are more sensitive to contaminants such as heavy metals than juvenile and adult fish, and are widely used as model organisms for biomarkers that define the toxicity of such chemicals to water bodies [3].
Although some heavy metals such as zinc (Zn), iron (Fe), cobalt (Co), and copper (Cu) are necessary for fish at very low levels (for their enzyme activity and other biological processes), they can become toxic when they exceed certain limits. On the contrary, other metals such as lead (Pb), cadmium (Cd), chromium (Cr), mercury (Hg), and arsenic (As) do not have an essential role in living organisms and are toxic even in very low concentrations, which is why they are dangerous both for fish and for humans (through the food chain) [2].
In this short review, five of these toxic heavy metals and metalloids, As, Cr, Cd, Pb and Hg, were selected to further analyze their effect on various fish species and therefore on humans through a review of the recent relevant literature. Fish bodies mainly consist of muscle tissues, which is their most-consumed part [6]; for this reason, in this review, the values of heavy metals and metalloids contained and reported were found mostly in muscle tissues (Figure 1). The particularity of this short review is that it includes different case studies from a large proportion of the planet, summarizing the main values of heavy metals found, and comparing the quality of water environments.
The heavy metals and metalloids evaluated in this commentary are elaborated upon below:
  • Arsenic (As): As is released into the aquatic environment from various anthropogenic and agricultural sources, and has two oxidation stages; As(III) (arsenites) is more toxic than As(V) (arsenates) [7]. Arsenic from contaminated water and food is rapidly absorbed into fish tissues through the gills and skin, and can contaminate them. Exposure of freshwater fish to arsenic results in its bioaccumulation, mainly in liver and kidney tissues, showing a histopathological modification in the gills and liver tissues of these fish [4]. In addition, the presence of As affects fish reproduction by inhibiting spermatogenesis and oogenesis, thus reducing the fertilization rate [3].
  • Chromium (Cr): Cr appears in water as Cr(III) and Cr(VI,), with the latter being more toxic and more soluble in water [8]. The concentration of Cr in water bodies, such as in rivers and lakes, usually ranges from 1 to 10 mg/L, but in seawater, the values are much lower, i.e., <0.1, and in some cases can reach 5 mg/L. Cr(VI) prevails in well-oxygenated marine waters, while Cr(III) appears mainly in coastal areas [9]. In addition, Cr(III) is an essential metal for humans and animals, and plays an important role in improving glucose tolerance [10], but Cr(VI) causes acute and chronic effects in humans [11].
  • Cadmium (Cd): Cd is a non-essential but very toxic metal with a chronic effect on human health due to its accumulation mainly in the liver, but also in the blood, bones, muscles, and kidneys [12]. Numerous studies carried out in several countries have shown that most foods have a Cd content between 0.005–0.1 mg/kg, but some foods like seafood may contain higher concentrations. Industrial waste, some fertilizers, etc., are responsible for about 50% of the Cd that reaches the sea. Mollusks tend to accumulate Cd in a higher amount than other organisms, as it is necessary for the responsiveness of metallothionein and hemocyanin genes [13].
  • Lead (Pb): Pb is one of the most highly toxic metals that appears and threatens aquatic environments [14]. Fish are the most sensitive to the toxic effects of Pb exposure, which affects physiological and biochemical functions and is mainly caused by bioaccumulation [15]. Chronic exposure to Pb causes high accumulation of it, mainly in liver and kidney tissues [14]. The relative FAO and WHO limits for Pb are 2 and 0.5 mg/kg, respectively [16].
  • Mercury (Hg): Hg belongs to the class of heavy metals that are harmful to all organisms even in extremely low concentrations, and can be found in both freshwater and marine ecosystems [17]. According to the FAO/WHO, the permissible concentration for Hg is 0.5 mg/kg for humans [16]. Hg is present as Hg0, Hg+, Hg2+, and harmful organic mercury, especially MeHg (methyl) [18]. Moreover, the levels of Hg in fish brain are generally higher after MeHg exposure than after the Hg2+ exposure. Thus, MeHg in fish is the main source of mercury contamination, and there is high potential risk for consumers [19].
In Table 1 are listed the foremost sources of heavy metals and metalloids in aquatic environments. Industrial and geogenic sources as well as anthropogenic activities are the main sources of the contamination of water with these elements.
In aquatic environments, element concentrations within a biogeochemical area may differ between the water and land due to the nature of the environment. Therefore, the effect of the biogeochemical properties of the toxic elements studied in this review on the marine environment is crucial. Thus, the biogeochemical cycles of As, Cr, Cd, Pb and Hg are influenced by natural and anthropogenic processes that transform these elements through multiple chemical forms and environments, and are presented in Figure 2. As illustrated, these compounds originate in the environment, mainly from anthropogenic sources, in plants, soil and in water, and a chemical equilibrium between their speciation forms can exist.
Furthermore, as shown in Figure 3, the release of heavy metals in aquatic systems from natural or anthropogenic sources can cause the initial pollution of these systems by affecting the sustained and healthy development of aquatic life. Then, marine bodies, and specifically the fishes that are presented in this manuscript, can uptake these heavy metals, leading to their bioaccumulation. The bioaccumulation of heavy metals may pose great hazards to the health of humans and animals that depend on water bodies [1]. Fish not only constitute an important trophic level in aquatic ecosystems, but also serve as an important source of protein, vitamins, minerals, and polyunsaturated fatty acids for human beings [25]. Thus, seafood safety is a critical requirement for sustainable global quantitative and qualitative development. However, fish contaminated with heavy metals are capable of disrupting this balance in the food chain and causing many serious problems for humans through their consumption.
To be more specific, in Figure 4 are illustrated the serious hazardous impacts that heavy metals can have when they enter the human body, causing biological and physiological problems because they cannot be decomposed and are non-biodegradable.

2. Analytical Methods for the Determination of Heavy Metals and Metalloids

Several methods with digestion protocols were assessed for fish samples’ preparation for heavy metal and metalloid analysis. The methods mentioned in the literature, which were optimized to achieve the best results, are as follows:
  • Digestion of fish tissue with a combination of hydrogen peroxide/hydrochloric acid, coupled with solid-phase purification of the digested solid [26].
  • Microwave-assisted digestion and extraction, which showed good recovery and extraction efficiency [27].
  • Addition of hydrogen peroxide (30%) and subsequent digestion using a microwave digestion unit [28].
Milli-Q water was used for the dilution of the digest for the following analysis.
In general, various advanced analytical techniques can be used to detect heavy metals and metalloids in environmental and biological samples. These include inductively coupled plasma coupled with optical emission spectrometry or mass spectrometry, X-ray absorption spectroscopy, and molecular spectroscopy [29]. However, it is worth noting that the appropriateness of the applied technique also depends on the specific sample and the research question, and the disadvantages that may exist must also be taken into account. For instance, expensive equipment and operational costs, complex sample pretreatment, and long detection time, which make in situ measurement difficult, are among the drawbacks [30]. Compared with the above heavy metal(loid) detection methods, electrochemical techniques are a promising point-of-care testing method due to their advantages of low cost, simple equipment, fast speed analysis, and dependability, and can offer transferability and fast responses for on-site analysis [31].
In most of the studies referenced in this short review, Cr, As and Cd in fish were analyzed using inductively coupled plasma–mass spectrometry (ICP-MS), high-performance liquid chromatography–inductively coupled plasma–dynamic reaction cell–mass spectrometry (hPlC/ICP-DRC-MS), inductively coupled plasma–optical emission spectrometry (ICP-OES) and atomic absorption spectrophotometry (AAS) equipped with a graphite furnace (GFAAS), or with direct flow injection analysis through a hydride generation system (FIAS) [28,32,33,34]. Pb content was measured using electrothermal atomic absorption spectrometry (ETAAS) [35] or atomic absorption spectrophotometry (AAS) [36], and Hg concentration was determined using a single-purpose atomic absorption spectrometer AMA-254 [35].

3. Biomarkers of Heavy Metal and Metalloid Toxicity in Fishes

Biomarkers are measurable indicators of a biological condition. There are numerous biomarkers of heavy metal poisoning in freshwater fishes at several research levels [37].
Among the most important biomarkers, stress proteins such as metallothionein have shown delayed expression when exposed to sublethal chromium concentrations. Moreover, heat shock protein 70 (HSP-70) has been reported to be overstimulated in different fish species after exposure to excessive amounts of chromium [38]. In addition, integrated biomarker response index (IBRv2) has been applied to shorten biomarker response interpretation [39], as IBRv2 could differentiate fish organs according to biomarker responses. According to this index, a higher IBRv2 value indicates that an organ is affected, possibly due to some association with the level of accumulation of heavy metals and metalloids. Oxidative stress biomarkers reflecting the presence of heavy metals and metalloids have also been reported as indicators of environmental pollution due to the modification of antioxidant enzymes, the glutathione system, and the induction of lipid peroxidation in fish organs [40].
Furthermore, the handling of fish as a heavy metal assessment tool (according to behavioral responses, hepatocyte variation, and enzymatic reactions) has proved to be very valuable in environmental pollution monitoring [41]. The monitoring of hematological and biochemical biomarkers can provide information on fish health [42]. Some of the biomarkers associated with ecotoxicology in the aquatic environment apart from the most common heat shock protein (HSP 70), metallothionein, and oxidative stress are triglyceride level, vitellogenin (yolk proteins), cytochrome P4501A (CYP1A), circulating hormone levels, 17 beta estradiol hormone, etc. [37].

4. Discussion

There are many case studies in the literature examining existing concentrations of heavy metals and metalloids, such as As, Cr, Cd, Pb and Hg, and these are analyzed in this review. Table 2, Table 3, Table 4 and Table 5 summarizes these cases by listing the water body in which they were detected, as well as the fish species tested and the maximum concentrations of these metals found. In addition, in Figure 5 are illustrated some of the sampling regions of fish that are analyzed in this review.

4.1. Case Studies in Asia

In brief, in the case of Dhaleshwari River in Tangail, Bangladesh [43], six fish species were examined, and the relative concentrations of Cd, Cr, As, Pb and Hg were found to vary between 0.002–0.019, 0.046–0.159, 0.016–0.128, 0.091–0.234 and 0.004–0.012 mg/kg, respectively. The sequence of accumulation of heavy metals and metalloids in fish was Pb > As > Cr > Cd > Hg, but in almost all species, the concentrations were found to be below permissible limits [43], proving that there is practically no heavy metal pollution in this river, and the fish can be consumed. Some exceptions are the concentrations of Cd in Amblyceps mangois, of Cr in Mastacembelus armatus, and of As, Pb, and Hg in Metapenaeus tenuipes (syn. Spinulatus), which were found to be higher than the limits, possibly because of the agricultural use of various insecticides and pesticides in the area. In Puntius puntio, the As content was found to be 0.061 mg/kg; in Amblyceps mangois, the relative Cd concentration was 0.063 mg/kg; and in Mastacembelus armatus, the Cr content was found to be 0.159 mg/kg, as these were the most contaminated species found [43]. Furthermore, in another river of Bangladesh, Buriganga River in Dhaka, which is the most polluted river in the country, fish samples such as Heteropneustes fossilis were collected to evaluate the presence of Cd, Pb and Cr. According to the results of this study [44], higher values than those permitted by the FAO/WHO of Cd (0.040 mg/kg), Pb (1.040 mg/kg), and Cr (0.33 mg/kg) were observed, making this river hazardous to human health. Determination of As, Cr, Cd, and Pb contents in fish from Shitalakshya River, located also in Dhaka, Bangladesh, and the potential threat to human health as a result of their consumption were also studied. Systomus sarana (Olive barb), Pethia ticto (Ticto barb), and Mastacembelus armatus (Tire-track Spiny eel) were the three species that were used for examination. In the study of Hasan et al. [45], in order to quantify the impact of public health risk, the target hazard quotient (THQ) and carcinogenic risk (TCR) were calculated. According to their results, As, Cr, Cd, and Pb concentrations were over the considered allowable limits, and the found TCR values demonstrated an increased risk of cancer from eating the fish selected for study; for this reason, continuous monitoring of these polluted rivers is suggested. Moreover, in the study of Resma et al. [33], three different fish species highly consumed by the people of the southern region of Bangladesh were evaluated for their content of toxic metals As, Cr, and Cd. According to these results, the order in which the highest concentrations appear is Cr > As > Cd. Maximum concentrations of Cr were recorded in Labeo rohita (0.623 mg/kg), and Pangasius pangasius contained the slightly higher concentrations of As and Cd (0.045 and 0.006 mg/kg, respectively). In the muscle tissues of Coilia dussumieri and Sardinella fimbriata, in the Bay of Bengal in Bangladesh [46], concentrations of Cr, As, and Cd were also determined. The relative values were 0.63, 1.33 and 0.13 mg/kg for Coilia dussumieri, and 1.57, 3.93, 0.06 mg/kg, respectively, for Sardinella fimbriata; the As content in Sardinella fimbriata was found to be very high.
Furthermore, three categories of fish from the Tibetan Autonomous Region of China were also examined [28]: i.e., big-headed carp, grass carp, and tilapia. As concluded, arsenic concentration in the tilapia (0.286 mg/kg) was higher than that in big-headed and grass carp (~0.034 mg/kg), and exceeded more than twice the maximum established limit. Another case study took place in Tercan Dam Lake, Erzincan, Turkey [5], and aimed to determine As, Cr, and Pb contents in some fish species. The highest concentrations of As and Cr were detected in the gill tissues and the liver of the fish, and were significantly higher than acceptable levels. In Table 2, the mean values of mg/kg determined in the liver of the fish are reported; apparently, the Capoeta umbla species far exceeded the limits of Cr and Pb, with found values of 2.455 and 2.074 mg/kg, respectively, followed by Cyprinus carpio (0.918 and 0.534 mg/kg, respectively). In the case of As, Ctenopharyngodon idella (0.774 mg/kg) and Cyprinus carpio (0.383 mg/kg) exhibited higher values. Thus, Cyprinus carpio is considered to be the most contaminated species, as it contains concentrations of the metals that exceed permissible limits [47].
Moreover, in China, and particularly in Hangzhou, a recent study [48] assessed the bioaccumulation of metals in commercially important fishes (six different species), and calculated the potential hazard to human health resulting from their consumption. Each species has a precise bioaccumulative susceptibility to various metals. Thus, the decreasing order of metal concentration in organisms was as As > Cr > Cd > Pb > Hg. Apart from the Cd (with Harpadon nehereus, at 0.070 mg/kg, having the highest concentration) and As (Cynoglossus joyneri, at 0.350 mg/kg, having the highest concentration) levels found in all tested fish, the metal concentrations did not exceed national and international guideline values. The carcinogenic risk (CR) index values indicated that children were vulnerable to carcinogenic risk from As and Cd consumed through fish. Therefore, thorough examination of all aquatic organisms consumed by humans is highly recommended, including metal concentrations in various organs [48].
In the Coastal Area (Tam Hung and Minh Duc) of Hai Phong City in Northern Vietnam, two species, snake-headed fish (Channa argus) and catfish (Pangasianodon hypophthalmus), were selected in order to evaluate the concentrations of four heavy metals and metalloids (As, Cr, Cd and Pb) [49]. As found in this study, the concentration of Cr in catfish (2.250 mg/kg) exceeded the levels suggested by the FAO/WHO. In addition, the concentration of Cd (2.300 mg/kg) was higher in snake-headed fish, and in particular, the order was Cd > Cr > As > Pb. The level of As was similar in both fish. These results indicate that consumption of these fish may endanger human health.
Moreover, a study contacted in Jeddah, Saudi Arabia, which examined five fish samples [50], showed that the values of most identified metals were within permissible limits, as shown in Table 2. An exception is the high As values found in Lethrinus nebulosus (0.23–0.26 mg/kg), Plectropomus pessuliferus (0.21–0.26 mg/kg), and Epinephelus summana (0.21–0.23 mg/kg). On the other hand, Cd was not found in these species. In addition, higher Pb levels were found in Plectropomus pessuliferus (5.050 mg/kg) and Epinephelus summana (2.800 mg/kg) compared to the permissible standard limits. Therefore, in this study, it is proposed that the residual concentrations of heavy metals and metalloids should be detected and recorded before these fish are available for consumption, in order to ensure public health.
Pakistan is a country facing many environmental issues, mainly due to increasing pollution from human activities. One of the most critical environmental issues in Pakistan is heavy metal pollution, due to which the Karachi Coast in Pakistan is a degraded aquatic environment [20]. The effect of heavy metals on two fish on the Karachi Coast, focusing on those discussed in this brief review, were as follows: Cd > Cr > Pb > Hg > As for Thunnus spp and Cr > Pb > Cd > Hg > As for Rastrelliger kanagurta. In this coastal area, fish are used as a biomarker for assessing the health of aquatic ecosystems, particularly around industrial, agricultural, municipal, and domestic contaminated sites [20].
In addition, in the East Kolkata Wetlands, India, the presence of toxic metals such as Cr, Pb, Cd and Hg was investigated in the muscle tissues of fishes [51]. Three different species were examined, i.e., Rohu (Labeo rohita), Tilapia (Oreochromis niloticus), and Catla (Catla catla), and according to the results, the bioaccumulation of toxic heavy metals in fish follows the order of Tilapia > Rohu > Catla; the pattern of bioaccumulation of toxic metals shows the trend Pb > Cd > Cr > Hg in all seasons and years.
Table 2. Bioaccumulation of As, Cr, Cd, Pb, and Hg in fish species in Asia, according to the literature.
Table 2. Bioaccumulation of As, Cr, Cd, Pb, and Hg in fish species in Asia, according to the literature.
LocationFish SpeciesAs *
(mg/kg)		Cr *
(mg/kg)		Cd *
(mg/kg)		Pb *
(mg/kg)		Hg *
(mg/kg)		Ref.
Scientific NameCommon Name
AsiaDhaleshwari River, Tangail, BangladeshChanna punctataSpotted snakehead0.0160.0460.0190.1330.005[43]
Mastacembelus armatusZig-zag eel0.0270.1590.0100.0910.011
Mystus vittatusstriped dwarf catfish0.0330.1160.0120.2340.005
Puntius puntioPuntio barb0.0610.1240.0020.1740.006
Amblyceps mangoisIndian torrent catfish0.0350.1030.0630.1830.004
Metapenaeus tenuipes (syn. Spinulatus)Shrimp0.1280.1120.0050.2310.012
Southern region, BangladeshOreochromis niloticusNile tilapia0.0420.590 ***0.004nd **nd **[33]
Pangasius pangasiusPangas catfish0.0450.577 ***0.006nd **nd **
Labeo rohitaRohu0.0350.623 ***0.004nd **nd **
Buriganga River, Dhaka, BangladeshHeteropneustes fossilisAsian stinging catfish nd **0.3300.0401.040nd **[44]
Shitalakshya River, Dhaka, BangladeshSystomus saranaOlive barb0.0010.0040.0010.001nd **[45]
Pethia tictoTicto barb0.0010.0030.0010.003nd **
Mastacembelus armatusZig-zag eel 0.0040.0010.0010.005nd **
Bay of Bengal, BangladeshCoilia dussumieriGold-spotted grenadier anchovy1.3300.6300.1300.230nd **[46]
Sardinella fimbriataFringescale sardinella 3.9301.5700.0600.930nd **
Coastal Area (Tam Hung and Minh Duc) Hai Phong, N. VietnamChanna argusNorthern snakehead1.1802.1202.3000.080nd **[49]
Pangasianodon hypophthalmusIridescent shark catfish1.6602.2501.0600.100nd **
Jeddah, Saudi ArabiaLethrinus nebulosusSpangled Emperor0.245nd **0.0001.510nd **[50]
Scomberomorus commersonNarrow-barred Spanish mackerel0.170nd **0.0000.890nd **
Plectropomus pessuliferusRoving coral grouper0.235nd **0.0005.050nd **
Pampus argenteusSilver pomfret0.165nd **0.0001.690nd **
Epinephelus summanaSumman grouper0.220nd **0.0002.800nd **
Lhasa, Tibetan Autonomous Region, China(Mean values of five species)Tilapia0.2860.0030.0040.021nd **[28]
(Mean values of six species)Big-head carp0.0340.0180.0000.004nd **
(Mean values of five species)Grass carp0.0330.0050.0030.024nd **
Hangzhou Bay, ChinaCoilia nasusJapanese grenadier anchovy0.2200.0900.0200.0600.020[48]
Collichthys lucidusBighead croaker0.2100.0700.0600.0600.010
Cynoglossus joyneriRed tongue sole0.3500.0500.0100.0600.003
Harpadon nehereusBombay duck0.1500.0700.0600.0700.010
Lophiogobius ocellicaudaLophiogobius0.2000.0600.0400.0500.010
Miichthys miiuyBrown croaker0.1900.0900.0400.0300.010
Tercan Dam Lake, Erzincan, TurkeyLuciobarbus capitoBulatmai barbel0.1240.398nd **0.090nd **[5]
Capoeta umblaTigris scraper0.1862.455nd **2.074nd **
Ctenopharyngodon idellaGrass carp0.7740.049nd **0.455nd **
Cyprinus carpioCommon carp0.3830.918nd **0.534nd **
Karachi Coast, PakistanThunnusTunand **0.3500.7100.270nd **[20]
Rastrelliger kanagurtaIndian mackerelnd **0.3700.3100.320nd **
* WHO/FAO standard values: As 0.1; Cr 0.15; Cd 0.05; Pb 0.5/2.0; Hg 0.5 mg/kg [38,47]. ** nd = not determined. *** Cr 1.0 mg/kg in drinking water [33,52].

4.2. Case Studies in Europe

In Europe, across the coast of the Adriatic Sea [9], six fish species were collected and examined for Cd, Cr, and Pb content. The highest values were observed for Engraulis encrasicolus (Cd: 0.020, Cr: 0.083 and Pb: 0.046 mg/kg), for Mullus barbatus (Cd: 0.003, Cr: 0.031 and Pb: 0.036 mg/kg), and for Scomber scombrus (Cd: 0.008, Cr: 0.028 and Pb: 0.012 mg/kg), but the determined values were lower than FAO/WHO limits. Moreover, in Slovakia, Cd, Pb, and Hg contents were analyzed in a sample of common carp fish (Cyprinus carpio) from Žitava River, Nitra, Slovakia, where only 0.06 mg/kg Cd, 0.14 mg/kg Pb and 0.02 mg/kg Hg were found [6]. Further north, specifically in the Baltic Sea (area of Gdansk) [53], the As concentration in the muscle tissues of Gadus morhua callarias L (0.390 mg/kg), Sprattus sprattus (0.636 mg/kg), Clupea harengus membras (0.460 mg/kg), and Platichthys flesus (0.588 mg/kg) was determined. European sprat muscle (Sprattus sprattus) had the highest content of total As.
In addition, fresh fish species in Andalusia, Southern Spain, were examined for their toxic As, Cd, Pb, and Hg contents [54]. As presented in Table 3, the Cd concentration was low to nil, in contrast to the concentration of As, which was relatively higher. Particularly, sardines, with 0.561 mg/kg, and red mullet, with 0.427 mg/kg, showed the highest contents of As. Cuttlefish provided the highest Pb concentration (0.117 mg/kg), and megrim and red mullet the relative highest Hg content (0.091 and 0.067 mg/kg).
Table 3. Bioaccumulation of As, Cr, Cd, Pb, and Hg in fish species in Europe, according to the literature.
Table 3. Bioaccumulation of As, Cr, Cd, Pb, and Hg in fish species in Europe, according to the literature.
LocationFish SpeciesAs *
(mg/kg)		Cr *
(mg/kg)		Cd *
(mg/kg)		Pb *
(mg/kg)		Hg *
(mg/kg)		Ref.
Scientific NameCommon Name
EuropeAndalusia, Southern SpainSolea soleaCommon sole0.233nd **0.0010.0520.019[54]
Sepia officinalisCommon cuttlefish0.172nd **0.0000.1170.032
Scomber scombrusAtlantic mackerel0.190nd **0.0010.0040.022
Lepidorhombus bosciiFour-spotted megrim0.066nd **0.0000.0040.091
Mullus surmuletusStriped red mullet0.427nd **0.0000.0040.067
Sardina pilchardusEuropean pilchard0.561nd **0.0020.0040.034
Adriatic Sea coast, ItalyEngraulis encrasicolusEuropean anchovynd **0.0830.0200.046nd **[9]
Lophius piscatoriusEuropean anglernd **0.0070.0010.011nd **
Merluccius merlucciusEuropean hake,nd **0.0100.0060.005nd **
Scomber scombrusAtlantic mackerelnd **0.0280.0080.012nd **
Mullus barbatusRed mulletnd **0.0310.0030.036nd **
Solea soleaCommon solend **0.0620.0010.015nd **
Žitava River, Nitra, SlovakiaCyprinus carpioCommon carpnd **nd **0.0600.1400.020[6]
Baltic Sea, Gdansk, PolandGadus morhua callarias LBaltic cod0.390nd **nd **nd **nd **[55]
Sprattus sprattusEuropean sprat0.636nd **nd **nd **nd **
Clupea harengus membrasBaltic herring0.460nd **nd **nd **nd **
Platichthys flesusEuropean flounder0.588nd **nd **nd **nd **
* WHO/FAO standard values: As 0.1; Cr 0.15; Cd 0.05; Pb 0.5/2.0; Hg 0.5 mg/kg [38,47]. ** nd = not determined.

4.3. Case Studies in Africa

In Africa (Table 4) and in particular the Gulf of Guinea, West Africa, recently, Nyarko et al. [56] detected (among others) the levels of Cd As, Pb and Hg in the muscles of four different fish: Sardinella maderensis, Dentex angolensis, Sphyraena sphyraena, and Penaeus notialis. Higher concentrations of both metals (As 8.48 and Cd 0.03 mg/kg) were found in Penaeus notialis, except Pb, which was below the detection limit in all species examined. Regarding Hg concentration, this was higher in Dentex angolensis (0.137 mg/kg) and Sphyraena sphyraena (0.063 mg/kg). The remarkably high content of As determined in this fish increases the risk of future health problems, and therefore, it should be consumed with caution.
Table 4. Bioaccumulation of As, Cr, Cd, Pb and Hg in fish species in Africa, according to the literature.
Table 4. Bioaccumulation of As, Cr, Cd, Pb and Hg in fish species in Africa, according to the literature.
LocationFish SpeciesAs *
(mg/kg)		Cr *
(mg/kg)		Cd *
(mg/kg)		Pb *
(mg/kg)		Hg *
(mg/kg)		Ref.
Scientific NameCommon Name
AfricaGulf of Guinea, West AfricaSardinella maderensisMadeiran Sardinella1.560nd **0.005nd **0.021[56]
Dentex angolensisAngola dentex1.870nd **0.006nd **0.137
Sphyraena sphyraenaEuropean barracuda0.820nd **0.002nd **0.063
Penaeus notialisSouthern pink shrimp8.480nd **0.027nd **0.026
* WHO/FAO standard values: As 0.1; Cr 0.15; Cd 0.05; Pb 0.5/2.0; Hg 0.5 mg/kg [38,47]. ** nd = not determined.

4.4. Case Studies of Latin America

In Latin America, the Bahía Blanca estuary is a coastal environment in Argentina that has one of the largest petrochemical centers, resulting in large amounts of wastewater discharge. For this reason, a recent study [34] focused on the determination of Cr and Pb in six commercial fish species, as detailed in Table 5. According to the results of this study, the species Cynoscion guatucupa and Odontesthes argentinensis showed at least one sample containing high concentrations of Cr (0.450 and 0.250 mg/kg, respectively) above permissible levels for human consumption. In contrast, the Pb concentration in all species was below the method’s detection limits.
Table 5. Bioaccumulation of As, Cr, Cd, Pb and Hg in fish species in Latin America, according to the literature.
Table 5. Bioaccumulation of As, Cr, Cd, Pb and Hg in fish species in Latin America, according to the literature.
LocationFish SpeciesAs *
(mg/kg)		Cr *
(mg/kg)		Cd *
(mg/kg)		Pb *
(mg/kg)		Hg *
(mg/kg)		Ref.
Scientific NameCommon Name
Latin AmericaBahía Blanca estuary, ArgentinaCynoscion guatucupaStripped weakfishnd **0.450nd **<mdl ***nd **[34]
Micropogonias furnieriWhitemouth croakernd **0.095nd **<mdl ***nd **
Mustelus schmittiNarrow-nose smooth-houndnd **0.047nd **<mdl ***nd **
Brevoortia aureaBrazilian Menhadennd **0.010nd **<mdl ***nd **
Odontesthes argentinensis-nd **0.250nd **<mdl ***nd **
Paralichthys orbignyanusBlack floundernd **0.030nd **<mdl ***nd **
* WHO/FAO standard values: As 0.1; Cr 0.15; Cd 0.05; Pb 0.5/2.0; Hg 0.5 mg/kg [38,47]. ** nd = not determined. *** <mdl = below the method detection limits.

4.5. Statistical Comparison

Considering the analysis made in Table 2, Table 3, Table 4 and Table 5 and the concentrations of the various toxic substances studied in this manuscript, Figure 6 compares the percentage (%) of concentrations exceeding permissible limits, depending on continent. As can be observed, Asia presents a major problem in As, Cr, Cd and Pb, which in the case of As exceeds the permitted limits in more than 50% of studies. On the contrary, in the case of Europe and Africa, the main problem appears in increased As contents, in relation to toxic heavy metals, with the continent of Africa accounting for 100% of the detected contamination. On the other hand, Latin America seems mainly to have excessive levels of Cr, which are beyond permissible values. Finally, in all continents and case studies, the levels of Hg were found not to exceed permissible limits, and this is the reason why its bar does not appear in Figure 6 (green bar).
Furthermore, in Figure 7, a comparison is made between the percentage (%) of cases found to exceed permissible limits for As depending on the water type of the study area. Specifically, an evaluation of excesses in fresh and marine water was carried out, and as it turned out, the fish species studied for the determination of As in Europe and Africa, and that exceed permissible levels, are seawater fish. In Asia, As appears slightly more increased in freshwater fish.

5. Conclusions

The objective of this commentary was to review heavy metal and metalloid concentrations of elements such as arsenic (As), chromium (Cr), cadmium (Cd), lead (Pb), and mercury (Hg) in the tissues of freshwater and marine fish, according to recent relevant literature. Therefore, 4 different continents (Europe, Asia, Africa, and Latin America), 13 different countries (Spain, Italy, Slovakia, Poland, China, India, Pakistan, Turkey, Bangladesh, Vietnam, Saudi Arabia, Guinea and Argentina), and 50 different fish species were discussed in terms of Cd, As, Cr, Pb and Hg concentrations. As observed, in Tercan Dam Lake, Turkey, the highest concentration of Cr and Pb was detected in the Capoeta umbla-Tigris scraper (2.455 and 2.074 mg/kg, respectively) and of As in Ctenopharyngodon idella-Grass carp (0.774 mg/kg) species. The highest content of As was determined in Gulf of Guinea in Africa, providing 8.48 mg/kg for Penaeus notialis. Values above the permissible levels of FAO/WHO for human consumption were also found in Andalusia, Southern Spain, in the species Mullus surmuletus (striped red mullet) (0.427 mg/kg), Sardina pilchardus (European pilchard (0.561 mg/kg), Sprattus sprattus (European sprat) (0.636 mg/kg), and Platichthys flesus (European flounder) (0.588 mg/kg) in the Baltic Sea. For Cd concentration, Amblyceps mangois (Indian catfish), collected from the Dhaleshwari River in Bangladesh, showed the highest value of 0.063 mg/kg; a Pb concentration of 5.050 mg/kg was found in Plectropomus pessuliferus, and of 2.800 mg/kg in Epinephelus summana in Jeddah, Saudi Arabia. On the other hand, Hg content in fish was under the permissible limit in almost all cases. The order of accumulation of heavy metals and metalloids in fish was As > Cr > Pb > Cd > Hg. According to statistical comparisons, Asia presents the major problem regarding As, Cr, Cd and Pb; in the case of As, levels exceeded the permitted limits in more than 50% of the studies reviewed. In addition, the fish species with increased levels of As in Asia are freshwater fish, and in Europe and Africa, the fish that exceed permissible levels of As are seawater fish. In most of the considered studies, the analytical methods used for the determination of As, Cr, and Cd were ICP-MS, HPLC/ICP-DRC-MS, ICP/OES, GFAAS, and FIAS, and several digestion protocols were considered for fish samples’ preparation for heavy metals analysis.

Author Contributions

Conceptualization, A.K.T. and G.Z.K.; methodology, A.K.T., D.K.T. and G.Z.K.; validation, G.Z.K.; formal analysis, A.K.T., D.K.T. and G.Z.K.; investigation, A.K.T., D.K.T. and G.Z.K.; resources, A.K.T., D.K.T. and G.Z.K.; data curation, A.K.T. and D.K.T.; writing—original draft preparation, A.K.T. and D.K.T.; writing—review and editing, A.K.T., D.K.T. and G.Z.K.; visualization, A.K.T., D.K.T. and G.Z.K.; supervision, A.K.T. and G.Z.K. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

All data analyzed during this study are included in this published article.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Sonone, S.S.; Jadhav, S.; Sankhla, M.S.; Kumar, R. Water Contamination by Heavy Metals and Their Toxic Effect on Aquaculture and Human Health through Food Chain. Lett. Appl. NanoBioSci. 2020, 10, 2148–2166. [Google Scholar] [CrossRef]
  2. Oancea, S.; Foca, N.; Airinei, A. Effects of Heavy Metals on Fish. Roum. Biotechnol. Lett. 2005, 11, 3–6. [Google Scholar]
  3. Taslima, K.; Al-Emran, M.; Rahman, M.S.; Hasan, J.; Ferdous, Z.; Rohani, M.F.; Shahjahan, M. Impacts of Heavy Metals on Early Development, Growth and Reproduction of Fish—A Review. Toxicol. Rep. 2022, 9, 858–868. [Google Scholar] [CrossRef]
  4. Garai, P.; Banerjee, P.; Mondal, P.; Saha, N.C. Effect of Heavy Metals on Fishes: Toxicity and Bioaccumulation. J. Clin. Toxicol. 2021, 11, 1. [Google Scholar]
  5. Güneş, M.; Sökmen, T.; Kirici, M. Determination of Some Metal Levels in Water, Sediment and Fish Species of Tercan Dam Lake, Turkey. Appl. Ecol. Environ. Res. 2019, 17, 14961–14972. [Google Scholar] [CrossRef]
  6. Tóth, T.; Andreji, J.; Tóth, J.; Slávik, M.; Árvay, J.; Stanovič, R. Cadmium, Lead and Mercury Contents in Fishes–Case Study. J. Microbiol. Biotechnol. Food Sci. 2012, 1, 837–847. [Google Scholar]
  7. Tolkou, A.K.; Kyzas, G.Z.; Katsoyiannis, I.A. Arsenic(III) and Arsenic(V) Removal from Water Sources by Molecularly Imprinted Polymers (MIPs): A Mini Review of Recent Developments. Sustainability 2022, 14, 5222. [Google Scholar] [CrossRef]
  8. Tolkou, A.K.; Vaclavikova, M.; Gallios, G.P. Impregnated Activated Carbons with Binary Oxides of Iron-Manganese for Efficient Cr(VI) Removal from Water. Water. Air. Soil Pollut. 2022, 233, 343. [Google Scholar] [CrossRef]
  9. Sepe, A.; Ciaralli, L.; Ciprotti, M.; Giordano, R.; Funari, E.; Costantini, S. Determination of Cadmium, Chromium, Lead and Vanadium in Six Fish Species from the Adriatic Sea. Food Addit. Contam. 2003, 20, 543–552. [Google Scholar] [CrossRef]
  10. Lipko, M.; Debski, B. Mechanism of Insulin-like Effect of Chromium(III) Ions on Glucose Uptake in C2C12 Mouse Myotubes Involves ROS Formation. J. Trace Elem. Med. Biol. 2018, 45, 171–175. [Google Scholar] [CrossRef]
  11. OMS Chromium in Drinking-Water. In WHO Guidelines for Drinking-Water Quality; WHO/HEP/ECH/WSH/2020.3; WHO: Geneva, Switzerland, 1996.
  12. Järup, L.; Berglund, M.; Elinder, C.G.; Nordberg, G.; Vahter, M. Health Effects of Cadmium Exposure—A Review of the Literature and a Risk Estimate. Scand. J. Work. Environ. Health 1998, 24, 1–51. [Google Scholar]
  13. Pedrini-Martha, V.; Schnegg, R.; Schäfer, G.G.; Lieb, B.; Salvenmoser, W.; Dallinger, R. Responsiveness of Metallothionein and Hemocyanin Genes to Cadmium and Copper Exposure in the Garden Snail Cornu Aspersum. J. Exp. Zool. Part A Ecol. Integr. Physiol. 2021, 335, 228–238. [Google Scholar] [CrossRef] [PubMed]
  14. Lee, J.W.; Choi, H.; Hwang, U.K.; Kang, J.C.; Kang, Y.J.; Il Kim, K.; Kim, J.H. Toxic Effects of Lead Exposure on Bioaccumulation, Oxidative Stress, Neurotoxicity, and Immune Responses in Fish: A Review. Environ. Toxicol. Pharmacol. 2019, 68, 101–108. [Google Scholar] [CrossRef] [PubMed]
  15. Collin, M.S.; Venkatraman, S.K.; Vijayakumar, N.; Kanimozhi, V.; Arbaaz, S.M.; Stacey, R.G.S.; Anusha, J.; Choudhary, R.; Lvov, V.; Tovar, G.I.; et al. Bioaccumulation of Lead (Pb) and Its Effects on Human: A Review. J. Hazard. Mater. Adv. 2022, 7, 100094. [Google Scholar] [CrossRef]
  16. Hossain, M.B.; Tanjin, F.; Rahman, M.S.; Yu, J.; Akhter, S.; Noman, M.A.; Sun, J. Metals Bioaccumulation in 15 Commonly Consumed Fishes from the Lower Meghna River and Adjacent Areas of Bangladesh and Associated Human Health Hazards. Toxics 2022, 10, 139. [Google Scholar] [CrossRef] [PubMed]
  17. Zulkipli, S.Z.; Liew, H.J.; Ando, M.; Lim, L.S.; Wang, M.; Sung, Y.Y.; Mok, W.J. A Review of Mercury Pathological Effects on Organs Specific of Fishes. Environ. Pollut. Bioavailab. 2021, 33, 76–87. [Google Scholar] [CrossRef]
  18. Zheng, N.; Wang, S.; Dong, W.; Hua, X.; Li, Y.; Song, X.; Chu, Q.; Hou, S.; Li, Y. The Toxicological Effects of Mercury Exposure in Marine Fish. Bull. Environ. Contam. Toxicol. 2019, 102, 714–720. [Google Scholar] [CrossRef] [PubMed]
  19. Pereira, P.; Korbas, M.; Pereira, V.; Cappello, T.; Maisano, M.; Canário, J.; Almeida, A.; Pacheco, M. A Multidimensional Concept for Mercury Neuronal and Sensory Toxicity in Fish—From Toxicokinetics and Biochemistry to Morphometry and Behavior. Biochim. Biophys. Acta—Gen. Subj. 2019, 1863, 129298. [Google Scholar] [CrossRef]
  20. Yousif, R.; CHOUDHARY, M.I.; AHMED, S.; AHMED, Q. Review: Bioaccumulation of Heavy Metals in Fish and Other Aquatic Organisms from Karachi Coast, Pakistan. Nusant. Biosci. 2021, 13, 73–84. [Google Scholar] [CrossRef]
  21. De Francisco, P.; Martín-González, A.; Rodriguez-Martín, D.; Díaz, S. Interactions with Arsenic: Mechanisms of Toxicity and Cellular Resistance in Eukaryotic Microorganisms. Int. J. Environ. Res. Public Health 2021, 18, 12226. [Google Scholar] [CrossRef]
  22. Cheema, A.I.; Liu, G.; Yousaf, B.; Abbas, Q.; Zhou, H. A Comprehensive Review of Biogeochemical Distribution and Fractionation of Lead Isotopes for Source Tracing in Distinct Interactive Environmental Compartments. Sci. Total Environ. 2020, 719, 135658. [Google Scholar] [CrossRef] [PubMed]
  23. Javed, M.T.; Tanwir, K.; Akram, M.S.; Shahid, M.; Niazi, N.K.; Lindberg, S. Phytoremediation of Cadmium-Polluted Water/Sediment by Aquatic Macrophytes: Role of Plant-Induced PH Changes. In Cadmium Toxicity and Tolerance in Plants; Academic Press: Cambridge, MA, USA, 2019; pp. 495–529. [Google Scholar] [CrossRef]
  24. Kumar, V.; Umesh, M.; Shanmugam, M.K.; Chakraborty, P.; Duhan, L.; Gummadi, S.N.; Pasrija, R.; Jayaraj, I.; Dasarahally Huligowda, L.K. A Retrospection on Mercury Contamination, Bioaccumulation, and Toxicity in Diverse Environments: Current Insights and Future Prospects. Sustainability 2023, 15, 13292. [Google Scholar] [CrossRef]
  25. Mehana, E.S.E.; Khafaga, A.F.; Elblehi, S.S.; Abd El-Hack, M.E.; Naiel, M.A.E.; Bin-Jumah, M.; Othman, S.I.; Allam, A.A. Biomonitoring of Heavy Metal Pollution Using Acanthocephalans Parasite in Ecosystem: An Updated Overview. Animals 2020, 10, 811. [Google Scholar] [CrossRef]
  26. Meucci, V.; Laschi, S.; Minunni, M.; Pretti, C.; Intorre, L.; Soldani, G.; Mascini, M. An Optimized Digestion Method Coupled to Electrochemical Sensor for the Determination of Cd, Cu, Pb and Hg in Fish by Square Wave Anodic Stripping Voltammetry. Talanta 2009, 77, 1143–1148. [Google Scholar] [CrossRef]
  27. Komorowicz, I.; Sajnóg, A.; Barałkiewicz, D. Total Arsenic and Arsenic Species Determination in Freshwater Fish by ICP-DRC-MS and HPLC/ICP-DRC-MS Techniques. Molecules 2019, 24, 607. [Google Scholar] [CrossRef] [PubMed]
  28. Jiang, D.; Hu, Z.; Liu, F.; Zhang, R.; Duo, B.; Fu, J.; Cui, Y.; Li, M. Heavy Metals Levels in Fish from Aquaculture Farms and Risk Assessment in Lhasa, Tibetan Autonomous Region of China. Ecotoxicology 2014, 23, 577–583. [Google Scholar] [CrossRef]
  29. Jin, M.; Yuan, H.; Liu, B.; Peng, J.; Xu, L.; Yang, D. Review of the Distribution and Detection Methods of Heavy Metals in the Environment. Anal. Methods 2020, 12, 5747–5766. [Google Scholar] [CrossRef]
  30. Arjomandi, M.; Shirkhanloo, H. A Review: Analytical Methods for Heavy Metals Determination in Environment and Human Samples. Anal. Methods Environ. Chem. J. 2019, 2, 97–126. [Google Scholar] [CrossRef]
  31. Meng, R.; Zhu, Q.; Long, T.; He, X.; Luo, Z.; Gu, R.; Wang, W.; Xiang, P. The Innovative and Accurate Detection of Heavy Metals in Foods: A Critical Review on Electrochemical Sensors. Food Control 2023, 150, 109743. [Google Scholar] [CrossRef]
  32. Nasrollahzadeh, M.; Sajjadi, M.; Iravani, S.; Varma, R.S. Carbon-Based Sustainable Nanomaterials for Water Treatment: State-of-Art and Future Perspectives. Chemosphere 2021, 263, 128005. [Google Scholar] [CrossRef]
  33. Resma, N.S.; Meaze, A.M.H.; Hossain, S.; Khandaker, M.U.; Kamal, M.; Deb, N. The Presence of Toxic Metals in Popular Farmed Fish Species and Estimation of Health Risks through Their Consumption. Phys. Open 2020, 5, 100052. [Google Scholar] [CrossRef]
  34. La Colla, N.S.; Botté, S.E.; Oliva, A.L.; Marcovecchio, J.E. Tracing Cr, Pb, Fe and Mn Occurrence in the Bahía Blanca Estuary through Commercial Fish Species. Chemosphere 2017, 175, 286–293. [Google Scholar] [CrossRef]
  35. Mielcarek, K.; Nowakowski, P.; Puścion-Jakubik, A.; Gromkowska-Kępka, K.J.; Soroczyńska, J.; Markiewicz-Żukowska, R.; Naliwajko, S.K.; Grabia, M.; Bielecka, J.; Żmudzińska, A.; et al. Arsenic, Cadmium, Lead and Mercury Content and Health Risk Assessment of Consuming Freshwater Fish with Elements of Chemometric Analysis. Food Chem. 2022, 379, 132167. [Google Scholar] [CrossRef] [PubMed]
  36. Ishak, A.R.; Zuhdi, M.S.M.; Aziz, M.Y. Determination of Lead and Cadmium in Tilapia Fish (Oreochromis niloticus) from Selected Areas in Kuala Lumpur. Egypt. J. Aquat. Res. 2020, 46, 221–225. [Google Scholar] [CrossRef]
  37. Kadim, M.K.; Risjani, Y. Biomarker for Monitoring Heavy Metal Pollution in Aquatic Environment: An Overview toward Molecular Perspectives. Emerg. Contam. 2022, 8, 195–205. [Google Scholar] [CrossRef]
  38. Bakshi, A.; Panigrahi, A.K. A Comprehensive Review on Chromium Induced Alterations in Fresh Water Fishes. Toxicol. Rep. 2018, 5, 440–447. [Google Scholar] [CrossRef]
  39. El-Agri, A.M.; Emam, M.A.; Gaber, H.S.; Hassan, E.A.; Hamdy, S.M. Integrated Use of Biomarkers to Assess the Impact of Heavy Metal Pollution on Solea Aegyptiaca Fish in Lake Qarun. Environ. Sci. Eur. 2022, 34, 74. [Google Scholar] [CrossRef]
  40. Farombi, E.O.; Adelowo, O.A.; Ajimoko, Y.R. Biomarkers of Oxidative Stress and Heavy Metal Levels as Indicators of Environmental Pollution in African Cat Fish (Clarias gariepinus) from Nigeria Ogun River. Int. J. Environ. Res. Public Health 2007, 4, 158–165. [Google Scholar] [CrossRef]
  41. Sabullah, M.K.; Ahmad, S.A.; Shukor, M.Y.; Gansau, A.J.; Syed, M.A.; Sulaiman, M.R.; Shamaan, N.A. Heavy Metal Biomarker: Fish Behavior, Cellular Alteration, Enzymatic Reaction and Proteomics Approaches. Int. Food Res. J. 2015, 22, 435–454. [Google Scholar]
  42. Ullah, S.; Li, Z.; Hassan, S.; Ahmad, S.; Guo, X.; Wanghe, K.; Nabi, G. Heavy Metals Bioaccumulation and Subsequent Multiple Biomarkers Based Appraisal of Toxicity in the Critically Endangered Tor Putitora. Ecotoxicol. Environ. Saf. 2021, 228, 113032. [Google Scholar] [CrossRef]
  43. Aminul Ahsan, M. Analysis of Physicochemical Parameters, Anions and Major Heavy Metals of the Dhaleshwari River Water, Tangail, Bangladesh. Am. J. Environ. Prot. 2018, 7, 29. [Google Scholar] [CrossRef]
  44. Real, M.I.H.; Azam, H.M.; Majed, N. Consumption of Heavy Metal Contaminated Foods and Associated Risks in Bangladesh. Environ. Monit. Assess. 2017, 189, 651. [Google Scholar] [CrossRef] [PubMed]
  45. Anwarul Hasan, G.M.M.; Satter, M.A.; Das, A.K.; Asif, M. Detection of Heavy Metals in Fish Muscles of Selected Local Fish Varieties of the Shitalakshya River and Probabilistic Health Risk Assessment. Meas. Food 2022, 8, 100065. [Google Scholar] [CrossRef]
  46. Mamun, A.-A.; Bhowmik, S.; Sarwar, M.S.; Akter, S.; Pias, T.; Zakaria, M.A.; Islam, M.M.; Egna, H.; Evans, F.; Wahab, M.A.; et al. Preparation and Quality Characterization of Marine Small Pelagic Fish Powder: A Novel Ready-to-Use Nutritious Food Product for Vulnerable Populations. Meas. Food 2022, 8, 100067. [Google Scholar] [CrossRef]
  47. FAO/WHO. Expert Committee on Food Additives Evaluation of Certain Food Additives and Contaminants: Eightieth Report. WHO Technical Report Series. 2016. Available online: http://apps.who.int/iris/bitstream/10665/204410/1/9789240695405_eng.pdf?ua=1 (accessed on 28 September 2023).
  48. Noman, M.A.; Feng, W.; Zhu, G.; Hossain, M.B.; Chen, Y.; Zhang, H.; Sun, J. Bioaccumulation and Potential Human Health Risks of Metals in Commercially Important Fishes and Shellfishes from Hangzhou Bay, China. Sci. Rep. 2022, 12, 4634. [Google Scholar] [CrossRef] [PubMed]
  49. Ngoc, N.T.M.; Van Chuyen, N.; Thao, N.T.T.; Duc, N.Q.; Trang, N.T.T.; Binh, N.T.T.; Sa, H.C.; Tran, N.B.; Van Ba, N.; Van Khai, N.; et al. Chromium, Cadmium, Lead, and Arsenic Concentrations in Water, Vegetables, and Seafood Consumed in a Coastal Area in Northern Vietnam. Environ. Health Insights 2020, 14, 1178630220921410. [Google Scholar] [CrossRef] [PubMed]
  50. Aljabryn, D.H. Heavy Metals in Some Commercially Fishery Products Marketed in Saudi Arabia. Food Sci. Technol. 2022, 42, 1–8. [Google Scholar] [CrossRef]
  51. Dutta, J.; Zaman, S.; Thakur, T.K.; Kaushik, S.; Mitra, A.; Singh, P.; Kumar, R.; Zuan, A.T.K.; Samdani, M.S.; Alharbi, S.A.; et al. Assessment of the Bioaccumulation Pattern of Pb, Cd, Cr and Hg in Edible Fishes of East Kolkata Wetlands, India. Saudi J. Biol. Sci. 2022, 29, 758–766. [Google Scholar] [CrossRef] [PubMed]
  52. World Health Organization European Standards for Drinking-Water. Am. J. Med. Sci. 1970, 242, 56.
  53. Liu, Y.; Chen, Q.; Li, Y.; Bi, L.; Jin, L.; Peng, R. Toxic Effects of Cadmium on Fish. Toxics 2022, 10, 622. [Google Scholar] [CrossRef]
  54. Olmedo, P.; Pla, A.; Hernández, A.F.; Barbier, F.; Ayouni, L.; Gil, F. Determination of Toxic Elements (Mercury, Cadmium, Lead, Tin and Arsenic) in Fish and Shellfish Samples. Risk Assessment for the Consumers. Environ. Int. 2013, 59, 63–72. [Google Scholar] [CrossRef] [PubMed]
  55. Polak-Juszczak, L.; Szlinder Richert, J. Arsenic Speciation in Fish from Baltic Sea Close to Chemical Munitions Dumpsites. Chemosphere 2021, 284, 131326. [Google Scholar] [CrossRef] [PubMed]
  56. Nyarko, E.; Boateng, C.M.; Asamoah, O.; Edusei, M.O.; Mahu, E. Potential Human Health Risks Associated with Ingestion of Heavy Metals through Fish Consumption in the Gulf of Guinea. Toxicol. Rep. 2023, 10, 117–123. [Google Scholar] [CrossRef]
Sustainability 15 16242 g001
Figure 1. Bioaccumulation of heavy metal and metalloid toxicity in muscle tissues of fish (source: authors).
Figure 1. Bioaccumulation of heavy metal and metalloid toxicity in muscle tissues of fish (source: authors).
Sustainability 15 16242 g001
Sustainability 15 16242 g002aSustainability 15 16242 g002b
Figure 2. Biogeochemical processes of As, Cr, Cd, Pb and Hg. Reproduced with permission. (a) As [21], (b) Cr [22], (c) Cd [23], (d) Pb [22], and (e) Hg [24].
Figure 2. Biogeochemical processes of As, Cr, Cd, Pb and Hg. Reproduced with permission. (a) As [21], (b) Cr [22], (c) Cd [23], (d) Pb [22], and (e) Hg [24].
Sustainability 15 16242 g002aSustainability 15 16242 g002b
Sustainability 15 16242 g003
Figure 3. Life cycle of heavy metal pollution (source: authors).
Figure 3. Life cycle of heavy metal pollution (source: authors).
Sustainability 15 16242 g003
Sustainability 15 16242 g004
Figure 4. Effects of heavy metals on human health (source: authors).
Figure 4. Effects of heavy metals on human health (source: authors).
Sustainability 15 16242 g004
Sustainability 15 16242 g005
Figure 5. Sampling sites of fish in several continents (source: authors).
Figure 5. Sampling sites of fish in several continents (source: authors).
Sustainability 15 16242 g005
Sustainability 15 16242 g006
Figure 6. Percentage (%) of concentrations that exceed permissible limits of toxic heavy metals, depending on continent.
Figure 6. Percentage (%) of concentrations that exceed permissible limits of toxic heavy metals, depending on continent.
Sustainability 15 16242 g006
Sustainability 15 16242 g007
Figure 7. Percentage (%) of concentrations that exceed the permissible limits of As, based on the type of water (fresh water or marine water) across each continent.
Figure 7. Percentage (%) of concentrations that exceed the permissible limits of As, based on the type of water (fresh water or marine water) across each continent.
Sustainability 15 16242 g007
Table 1. Sources of As, Cr, Cd, Pb, and Hg contamination in the aquatic environment [20].
Table 1. Sources of As, Cr, Cd, Pb, and Hg contamination in the aquatic environment [20].
Heavy Metal (Loid)Sources
AsWood preservatives, mining and smelting, coal power plants, herbicides, volcanoes, petroleum refining, animal feed additives
CrElectroplating industry, sludge, solid waste, tanneries
CdGeogenic sources, metal smelting and refining, fossil fuel burning, sewage sludge
PbMining and smelting of metalliferous ores, burning of leaded gasoline, municipal sewage, industrial waste enriched with Pb, paints
HgVolcano eruptions, forest fire, emissions from industries producing caustic soda, coal, peat, and wood burning
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Tolkou, A.K.; Toubanaki, D.K.; Kyzas, G.Z. Detection of Arsenic, Chromium, Cadmium, Lead, and Mercury in Fish: Effects on the Sustainable and Healthy Development of Aquatic Life and Human Consumers. Sustainability 2023, 15, 16242. https://doi.org/10.3390/su152316242

AMA Style

Tolkou AK, Toubanaki DK, Kyzas GZ. Detection of Arsenic, Chromium, Cadmium, Lead, and Mercury in Fish: Effects on the Sustainable and Healthy Development of Aquatic Life and Human Consumers. Sustainability. 2023; 15(23):16242. https://doi.org/10.3390/su152316242

Chicago/Turabian Style

Tolkou, Athanasia K., Dimitra K. Toubanaki, and George Z. Kyzas. 2023. "Detection of Arsenic, Chromium, Cadmium, Lead, and Mercury in Fish: Effects on the Sustainable and Healthy Development of Aquatic Life and Human Consumers" Sustainability 15, no. 23: 16242. https://doi.org/10.3390/su152316242

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop