Table 2.
Studies assessing the possible synergetic/antagonistic effect of persistent organic compounds (POPs) combined with MPs.
| MP Type | MP Size | Chemical Sorbate | Exposure Concentrations | Exposure Time |
Organism | Toxicological Assessment | Highlight Results | Ref. |
|---|---|---|---|---|---|---|---|---|
| PS-divinilbenzene | 97 μm | Pyrene |
Pyrene alone [Pyrene] = 0.1 µM MPs alone [MPs] = 100 particles/L MPs + Pyrene 100 nM pyrene + 100 particles/L MPs |
24 h | Tropical fish juveniles (Lates calcarifer) |
Mortality rate Juveniles behaviour Predatory performance Size differences |
Individuals exposed to both pollutants were the most affected group, but the negative impact was relatively small | [126] |
| PE | < 100 µm | Pyrene |
MPs alone [MPs]= 20 g/L MPs + pyrene Before the experiment, a solution of PE or PS were incubated with pyrene (50 µg/L) for 6 days |
7 days | Marine mussel (Mytilus galloprovincialis) | Histological analysis (gills and digestive glands) Gene transcription analyses Genotoxic effects Immunological alterations Neurotoxic responses Oxidative stress Antioxidant defences |
Clear separation between control and MPs exposed mussels Biological variations were influenced by the typology of polymer (PE vs PS) Only genotoxic responses separated virgin from pyrene- contaminated polymers |
[107] |
| PS | ||||||||
| PE | 1–5 µm | Pyrene |
Pyrene alone [Pyrene]= 20 and 200 µg/L MPs alone [MPs]= 0, 18.4 and 184 µg/L MPs + Pyrene 0 µg/L pyrene-18.4 µg/L MPs 200 µg/L pyrene-184 µg/L MPs 200 µg/L pyrene-184 µg/L MPs |
96 h | Juveniles of the common Goby (Pomatoschitus microps) | Protein content AChE, IDH, GST activities - LPO levels Bile samples were analysed for pyrene metabolites |
The presence of MPs was found to delay the pyrene-induced mortality Enhanced concentration of pyrene-metabolites was detected in co-exposure treatments Results suggest toxicologically relevant interactions between both pollutants |
[130] |
| PE | 10–90 µm | Fluoranthene (Flu.) |
Flu. alone [Flu]= 100 µg/L MPs alone [MPs]= 1000 particles/mL MPs + Flu. Flu – PE/PHB co-exposure or incubation at the same concentrations tested in single exposures (incubation during overnight) |
96 h | Blue Mussel (Mytilus edulis) |
Protein content in the cytosol The cytosolic concentration of GSH SOD, CAT, GPx and SeGPx activities |
In co-exposure and incubation treatments, biochemical responses were generally comparable with those exerted MPs only Apparent absence of combined effects of MPs with the pollutant. |
[5] |
| PHB | 10–90 µm | |||||||
| PE | 10–90 µm | Fluoranthene (Flu.) |
Flu. alone [Flu]= 50 and 100 µg/L MPs alone [MPs]= 100 and 1000 particles/mL MPs+ Flu. 50 µg/L Flu.-100 particle/mL 100 µg/L Flu.-1000 particle/mL (For both mixtures, co-exposure and incubation experiments (incubation during overnight)) |
96 h | Blue mussel (Mytilus edulis) |
Total GSH + 2GSSG levels SOD, CAT, GPx and SeGPx activities |
No synergistic or antagonistic effect was seen in the co-exposure or the incubation experiments | [131] |
| PS | Mix of 2 and 6 µm | Fluoranthene (Flu.) |
Flu. alone [Flu]= 30 µg/L day MPs alone [MPs]= 32 mg/L day MPs + Flu. 30 µg/L day Flu.-32 mg/L day PS |
7 days (+ 7 days of depuration) |
Marine mussel (Mytilus spp.) |
Morphological and functional analyses of hemocytes Hemocyte mortality Circulating hemocytes concentration Phagocytosis activity Histopathological assessment (digestive tract and intestine) ROS production Levels of LPO SOD, CAT, GR and GST activities Gene expression analysis |
Increase in the total histopathological lesions/ abnormalities was demonstrated in co-exposure treatments After depuration, a higher fluoranthene concentration was detected in mussels exposed to the mixture of MPs and Flu Results suggested that MPs led to modulated fluoranthene kinetics and toxicity in marine mussels. |
[132] |
| PS | 500 nm 30 µm |
Benzo[a]pyrene (B[a]P) 17β-estradiol (E2) |
B[a]P alone [B[a] P] = 5 and 50 mg/L E2 alone [E2] = 0.1 and 1 mg/L MPs alone [MPs]= 1 mg/L MPs + Pollutant Combination of individual concentrations of MPs of both sizes and the organic contaminants |
4 days | Bivalve specie (Tegillarca granosa) |
Analysis of total counts, cell-type composition, and phagocytic activity of haemocytes ROS and Ca2+ concentration from haemocytes LZM content and activity Gene expression of three major types of genes |
POPs toxicity was aggravated by smaller MPs and mitigated by larger MPs The deleterious impacts of B[a]P or E2 were mitigated by the presence of larger sized MPs and aggravated smaller ones |
[8] |
| LD-PE | 20–25 µm | Benzo(a)pyrene (B[a]P) |
B[a]P alone [B[a] P] = 150 µg/L MPs alone [MPs]= 10 mg/L MPs+ B[a]P 15 µg/g B[a]P-10 mg/L MPs (To reach this B[a]P sorbed concentration, 2 days of incubation was performed) |
7, 14 and 28 days | Marine mussel (Mytilus galloprovincialis) | Immunological alterations of hemocytes Neurotoxic responses in hemocytes and gills Oxidative stress Antioxidant defences, Genotoxic effects Transcriptional responses |
The overall evaluation provided a clear separation between times and typologies of exposure Significant alterations measured on the immune system Results suggested that the toxicological risk of MPs for marine organisms is probably low, but not negligible |
[133] |
| PE | 212–250 µm | Phenanthrene (Phe.) Anthracene |
Phe. alone [Phe.] = 0.12 µM Anthracene alone [Anthracene] = 0.14 µM MPs alone [MPs]= 0.02 and 0.2 g/g sediment MPs + Phe. / Anthracene Lower dose of PE combined with pollutants preloaded for 96h |
2 weeks | Bacterial community of sediments | Gene expression assessment | The presence of MP reduced the effect of the two PAHs on microbial community composition and the degradation of these organic compounds | [134] |
| LD-PE non-uniformly shaped | < 60 µm | Phenanthrene (Phe.) |
Phe. alone [Phe.] = 10 and 100 µg/L MPs alone [MPs]= 50 and 500 µg/L MPs + Phe. Combination of individual concentrations of MPs the organic contaminant |
96 h | African catfish (Clarias gariepinus) | Histopathological analysis (liver and gill) Glycogen stores of the liver Biomarkers responses of AST, ALT, LDH, ALP, γGT Contents of total protein, total albumin, lipase, glucose, lactate, direct bilirubin, HDL, LDL, TG and cholesterol Gene expression analysis |
Changes in biomarker responses of co-exposure treatment might be due to the facilitated transportation of Phe into the fish body Findings suggested toxicologically relevant interactions between MPs and Phe |
[135] |
| PE | 50 nm 500nm 5 µm 10 µm 15 µm |
Phenanthrene (Phe.) |
Phe. alone [Phe.] = 0, 0.05, 0.1, 0.2, 0.4, 0.8 and 1.2 mg/L MPs alone [MPs]= 0, 2.5, 5, 10 and 50 mg/L NPs alone [NPs]= 0, 2.5, 5, 8.5, 11 and 14.5 mg/L MPs/NPs + Phe. Combination of the individual concentrations tested for both pollutants |
48 h | Daphnia magna | Immobilization rate of the daphnids | Enhanced immobilization of daphnia was observed in co-exposure treatments (especially for NPs) The presence of NPs inhibited the dissipation of phenanthrene of the environment |
[61] |
| LD-PE | 125–250 µm | α-HBCD 2,4,6-tribromophenol PBDEs mix (PBDE 47, 99, 153, 154) PCB congeners (28, 52, 101, 118, 138, 153, 180) methyl mercury PFOS PFOA PFOSA PFNA |
Feed A: Basic feed (control) Feed B: Basic feed + contaminants sorbed to MPs before the incorporation of 2% into pellets (incubation for overnight) Feed C: Basic feed + contaminants without MPs Feed D: Basic feed + contaminants and clean MPs |
80 days (+ 51 days of depuration) |
European seabass (Dicentrarchus labrax) | Growth factors Feeding rates Gene expression analysis |
Results indicated that MPs inhibit or induce detoxification in the liver and influence the lipid distribution Gene expression results also indicated that MPs might indeed potentiate the adverse effect of some chemical contaminants |
[105] |
| LD-PE | 125–250 µm | Methylmercury Perfluoroctanesulfonate Perfluorooctanoat PFOSA PFNA α-HBCD 2,4,6-Tribromphenol PBDE 47 PBDE 99 PBDE 153 PBDE 154 PCB 28 PCB 52 PCB 101 PCB 118 PCB 138 PCB 153 PCB 180 |
Feed A: Basic feed Feed B: Basic feed + 4% of clean MPs Feed C: Basic feed + 2% of MPs with sorbed POPs Feed D: Basic feed + POPs |
3 weeks | Zebrafish (Danio rerio) |
Visual observation (microscopic level and Hispathological analysis) Evaluation of differential gene expression of some selected biomarkers |
Feed C produced the most evident effects, especially on the liver Combined effects of MPs and chemicals significantly altered the homeostasis in greater manner respect both pollutants alone |
[136] |
| LD-PE | marine exposition: 3 mm feed exposition: 0.5 mm |
PAHs, PCBs and PBDEs congeners | Feed A: Basic feed Feed B: Basic feed + virgin LD-PE Feed C: Basic feed + marine-plastic treatment (LDPE deployed in San Diego Bay for 3 months) |
2 months | Japanese medaka (Oryzias latipes) |
Histopathological analysis (gonads) Gene expression analysis on selected liver’s genes and biomarkers for endocrine disruption |
Results show early- warning signs of endocrine disruption in fish exposed to a mixture of plastic and sorbed contaminants | [127] |
| LD-PE | marine exposition: 3 mm feed exposition: 0.5 mm |
PAHs, PCBs and PBDEs congeners | Feed A: Basic feed Feed B: Basic feed + virgin LD-PE Feed C: Basic feed + marine-plastic treatment (LDPE deployed in San Diego Bay for 3 months) |
2 months | Japanese medaka (Oryzias latipes) |
Histopathological analysis (gonads) Gene expression analysis on selected liver’s genes and biomarkers for endocrine disruption |
Hepatic stress in medaka exposed to the combination of plastic and sorbed contaminants was demonstrated No significant differences in the expression of CYP1A were found between treatments |
[31] |
* Shadowed cells represent environmental relevant concentrations.