Toxicity of tire particle leachates on early life stages of keystone sea urchin species

Effects of long-term exposure to tire wear particle leachate on life-cycle chronic toxicity and potential toxic mechanisms in the marine copepod Tigriopus japonicus

As a potential source of microplastic pollution, tire wear particles (TWPs) will persist for a long time and accumulate in coastal areas, which can lead to adverse effects to marine organisms. However, there is little information on the long-term toxicity of TWP constituents entering the ocean. In this study, the marine copepod Tigriopus japonicus was used as a model species to investigate the multigenerational toxicity and potential toxic mechanisms of TWPs. The results of the long-term chronic toxicity test showed that the TWP leachate could affect the growth, reproduction and sex ratio of copepods. Compared to the control group, after exposure to 0.85 g/L TWP leachate, the survival rates of T. japonicus were decreased to 73.3 % for F-1 generation and no animal of F-2 generation could survive. In addition, the average number of nauplii and the spawning frequency decreased by 60 % and 66 % for F-1 generation, respectively. As for sexual development, in the 0.85 g/L TWP leachate exposure group, the female proportion in the F-1 generation decreased to 22.6 %, and not a single female was even recorded in the F-2 generation. TWP caused significant differences in transcriptome and enzyme activity. A total of 3022 differential expressed genes were identified in T. japonicus exposed to the TWP leachate, among which 145 genes were up-regulated and 2877 genes were down-regulated. These genes were mainly related to oxidative stress, protein digestion and absorption, stratum corneum production, and oviposition ability. In addition, the decrease of estrogen and its receptor enzyme activity could affect the sex ratio of copepods. These toxic effects eventually resulted in a decrease of the intrinsic rate of increase (rm) for T. japonicus. The rm value decreased to 0 at the concentration of 0.868 g/L. The information obtained in this study filled the knowledge gap regarding the chronic toxicity of TWP leachate to T. japonicus and would be helpful to understand the potential mechanisms of toxicity.

Impacts of spilled debris from the X-Press Pearl disaster in Sri Lanka on marine plankton

Accidents of ships carrying diverse hazardous chemicals and plastics can lead to complex spills of pollutants in marine ecosystems. One such incident was the catastrophic fire on the container ship X-Press Pearl which sank off the Sri Lankan coast in 2021. Explosions and fire resulted in plastic pellets and burnt clumps of melted plastic and combustion residues washing ashore. In this study, we analyzed the acute toxicity of the leached chemicals from this debris on various planktonic organisms: phytoplankton (Rhodomonas salina), meroplankton (Paracentrotus lividus larvae) and holoplankton (Acartia tonsa nauplii and adults). Acute exposures were conducted with a range of leachate dilutions for 72 h. The growth of R. salina was slightly affected by the leachates. Larvae of P. lividus showed a concentration-dependent reduction in growth and normal development (EC50 0.56 g L-1), with 94% of larvae showing malformations in the highest concentration. The hatching of A. tonsa decreased from 89% in the control to 29% at 0.75 g L-1. Nauplii mortality reached 46% and there was a trend of decreased growth. Mortality of the adults increased with concentration, reaching 51% in the highest concentration. Our results show that the complex mixture of spilled chemicals and debris from the X-Press Pearl accident can potentially harm the planktonic food web, particularly zooplankton. These findings highlight the urgent need for effective mitigation strategies and response measures to reduce impacts of accidental spills in sensitive and ecologically relevant areas, especially those located in major shipping lanes, such as the Sri Lankan coastal waters.

Environmental concentrations of fluoxetine antidepressant affect early development of sea urchin Paracentrotus lividus

Fluoxetine (FLX), one of the most widely prescribed selective serotonin reuptake inhibitors, is frequently detected in the aquatic environment. In this study we assessed the ecotoxicological effects of FLX on the early life-stages of the sea urchin Paracentrotus lividus, a key species in the Mediterranean Sea. Fertilization rate, developmental anomalies and behavioural alterations were evaluated up to 72 h by exposing gametes, zygotes, and embryos (gastrula) to environmental (0.001, 0.01 mg/L) and high concentrations (0.1, 1, 10 mg/L). Further, the different types and frequency of morphological anomalies at larval level were classified to estimate the Index of Contaminant Impact (ICI) at relevant and high concentrations. The ICI was applied to predict which FLX concentrations may pose a risk to sea urchins. Although FLX did not affect fertilization, significant skeletal anomalies and behavioural alterations were found in plutei from each exposed stage. Based on EC50 values, the sensitivity level ranks as follows: zygote > gastrula > sperm. The ICI values indicated high and moderate impacts only at high concentrations. However, a slight impact was also found in plutei from zygote exposure at relevant environmental concentrations, highlighting a potential risk for sea urchin early development. Considering increasing FLX consumption, we suggest to include this PC in monitoring plans, to not exceed levels that may impair and severely affect the early developmental stages of echinoderms. In addition, our findings promote the use of ICI as a novel tool for FLX impact assessment.

Heatwave conditions increase the toxicity of phthalates in marine organisms

Climate change- driven marine heatwaves are major risk for marine organisms already facing other anthropogenic hazards, such as chemical contamination in coastal areas. In this study we analyzed the impacts of marine heatwaves and phthalic acid esters (PAEs) pollution as single and combined stressors on development of the sea urchin Arbacia lixula. We tested whether the temperature suggested as optimal for development (24 °C) of this thermophilus species would enhance tolerance to PAEs pollution compared to that showed under ambient temperature (18 °C). Embryo-larval bioassays were conducted in exposures to two temperatures (control: 18 °C, heatwave condition: 24 °C) and ten PAEs concentrations (control: 0 mg L-1; treated: range 0.1-50 mg L-1) in all combinations. Ecotoxicological responses were investigated at three functional levels: i) exposure-response relationships, finding that heatwave exposure increased PAEs- induced toxicity and mortality rates with an EC50 lower by 76 %; ii) morphological, finding combined temperature and PAEs increased abnormality and stunted skeleton growth; iii) biochemical, showing that temperature was the main driver for the modulation of activity of stress response enzymes (alkaline phosphatase, esterase and peroxidase). We show that heatwave conditions negatively impacted sea urchin embryos facing pollution and decreased their tolerance to PAEs. Our results indicate that 24 °C is not the optimal temperature for development of A. lixula from the southwestern Mediterranean and highlight that assays based on just one biological level or single stressor can be misleading to deduce health risks to marine organisms and their thermal optimum, indicating the need for more integrative approaches.

Co-exposure of TMPs and antibiotics in zebrafish: The influence of additives on the risk of hepatotoxicity

Co-exposure of tire microplastics (TMPs) and antibiotics has been confirmed to pose toxic risks to aquatic organisms. However, the contributions of TMP additives to these risks and the underlying mechanisms remain underreported. In this study, factor analysis and molecular docking and molecular dynamics simulations were employed to investigate the differential additive-related hepatotoxicity risks associated with TMP-antibiotic exposure in zebrafish. The differential hepatotoxicity risks of five types of TMPs and six antibiotics were simulated in the presence of additives. Zebrafish exposed to different TMPs showed significant differences in hepatotoxicity risks, with styrene-butadiene rubber (SBR) exhibiting the most pronounced toxic effects. The additive contribution analysis revealed that in the presence of SBR additives, TMPs-antibiotics posed higher toxicity risks to the cytochrome P 17A2 (CYP17A2) isoenzymes CYP2K19, CYP1A, CYP3A65, and CYP2K22 in zebrafish, showing synergistic effects primarily driven by plasticizers. Furthermore, the hepatotoxicity risks of TMPs-antibiotics in zebrafish in the presence of additives were significantly mitigated by the selection of alternative plasticizers. The micromechanisms by which additives affected the TMP-antibiotic hepatotoxicity risks in zebrafish were elucidated through mechanistic analysis. This study aimed to characterize the additive-influenced hepatotoxicity risks of TMPs-antibiotics, providing micro-level insights and theoretical support for ecological risk assessments in aquatic environments.

Multigenerational toxic effects in Daphnia pulex are induced by environmental concentrations of tire wear particle leachate

Microplastic pollution has emerged as the second most significant scientific issue in environmental science and ecology. Similarly, the biological effects of tire wear particles (TWPs) have garnered considerable research attention; however, studies on chronic TWP leachate toxicity at environmentally relevant concentrations remain sparse. Here, we investigated the effects of TWP leachate at environmentally relevant concentrations (0.3 mg/L and 3 mg/L) on multigenerational and transgenerational Daphnia pulex for 21 days/generation, spanning three generations (F0-F2). Growth and reproductive indices (body length, growth rate, time to first clutch, number of clutches, and total offspring/female) across generations were analyzed. Multigenerational exposure to TWP leachate did not cause D. pulex death, but impaired growth and development, prolonged sexual maturity time, and reduced reproductive capacity. The transgenerational exposure group (3 mg/L) also exhibited some sub-lethal effects, such as delayed reproduction, suggesting a transgenerational impact. Gene transcription analyses and weighted gene co-expression network analysis showed that the most impacted pathways were associated with lysosome function, apoptosis, and glutathione metabolism, indicating that TWP leachate exposure compromised immune defense mechanisms and disrupted APs, CTSB, GST, DUSP1, and ERN1 gene expression. These findings underscore multigenerational toxicity effects and TWP leachate transmission patterns on aquatic organisms at realistic environmental concentrations.

Toxicity of tire rubber-derived pollutants 6PPD-quinone and 4-tert-octylphenol on marine plankton

The impacts of tire wear particles and their associated chemicals on the aquatic systems are a major environmental concern. In this study, we investigated the acute toxicity of two pollutants derived from tire rubber, 6PPD-quinone and 4-tert-octylphenol, on marine plankton. Specifically, we determined the acute effects of these pollutants on various organisms within the plankton food web: the microalgae Rhodomonas salina, the adult copepod Acartia tonsa, and the early life stages of the echinoderms Arbacia lixula and Paracentrotus lividus and the fish Sparus aurata. Exposure to 6PPD-quinone did not affect the microalgae growth, copepod survival, or fish embryo viability after 48 h of exposure at concentrations up to 1000 µgL-1. However, 6PPD-quinone significantly inhibited the growth of early developmental stages of both echinoderm species, with median effective concentrations of 7 and 8 µgL-1. Conversely, 4-tert-octylphenol was toxic to all studied organisms, with median lethal and effective concentrations ranging from 21 to 79 µgL-1 depending on the species and endpoints. The most sensitive planktonic organisms to 4-tert-octylphenol were echinoderm embryos and copepods, which exhibited negative effects at concentrations as low as 1 and 25 µgL-1, respectively. Our results demonstrate that acute exposure to 6PPD-quinone and 4-tert-octylphenol can cause harmful effects on key planktonic organisms at environmentally relevant concentrations. Overall, our findings highlight the need for develop ecologically safer tire rubber additives and reduce traffic-related tire particle emissions to mitigate their entry and potential impacts on aquatic ecosystems.

Impact of tire particle leachates on microplankton communities in the Canary Islands

Tire wear particles (TWP) are a major source of microplastics in the environment. Despite their prevalence, the effects of tire particle leachates on marine microplankton communities remains poorly understood. In this study, we assessed the acute impacts of tire particle leachates on the structure of coastal microplankton assemblages from the Canary Islands. Five laboratory experiments were conducted, exposing microplankton to a range of leachate dilutions over 72 h, with TWP leachates prepared from an initial concentration of 1 g L⁻¹ .Our results revealed that the abundances of diatoms, most dinoflagellates, and ciliates were significantly reduced following exposure to leachates, with median effective concentrations (EC50) ranging from 30 to 660 mg L-1 depending on the plankton community. Interestingly, Ostreopsis cf. ovata, a harmful algal bloom (HAB)-forming species, exhibited relatively high tolerance to tire particle leachates compared to other microplankton. Compared to other marine biota, ciliates appear to be most vulnerable plankton group to tire particle leachates (EC50 = 30 and 146 mg L-1). The higher tolerance of O. cf. ovata to pollution compared to other phytoplankton species (resource competitors), in combination with other factors, may contribute to the rise of HABs in polluted coastal areas. Although field data on TWP are limited, the observed negative effects on microplankton occurred at environmentally relevant concentrations. Our results indicate that TWP pollution can significantly impact marine planktonic communities, highlighting the urgent need to reduce TWP emissions and develop less toxic tire rubber additives.

Research trends in nano- and microplastic ingestion in marine planktonic food webs

Over the past decade, microplastic research on ingestion and impacts in marine biota has received significant attention. Zooplankton has become a subject of interest due to their crucial role in marine food webs. This review focuses on trends in nano- and microplastics (NMPs) ingestion studies in marine zooplankton. Four groups of organisms were considered: protozoans, holoplankton, meroplankton and ichthyoplankton. Of 120 reviewed articles, holoplankton was the most studied group, with laboratory experiments dominating over field studies. Although NMPs sizes and polymer types are diversifying in laboratory experiments, their characteristics are still far from representing the complexity of NMPs found in nature. Polystyrene (as polymer type) and beads (as shape) are overrepresented in laboratory experiments (54% and 79%, respectively). Furthermore, most NMPs concentrations used in the laboratory exceed those found in the field. The units used to report ingestion of NMPs in zooplankton vary greatly, with "microplastics per individual" being the most frequently used. In addition, certain planktonic groups (e.g., protozoans and ichthyoplankton) and behavioral traits, such as ambush feeding, have been poorly investigated. This variability hampers comparisons between studies and thus mechanistic insights into NMPs ingestion in marine zooplankton. This review identifies research gaps and it highlights the ongoing disparity between environmental and laboratory conditions in zooplankton ingestion studies. We encourage the scientific community to harmonize the reporting units for NMPs ingestion and focus on more environmentally realistic studies with a trait-based approach. Transitioning towards more hypothesis-driven experiments is crucial to clarify the mechanistic importance of environmentally relevant microplastic features.

Priorities to inform research on tire particles and their chemical leachates: A collective perspective

Concerns over the ecological impacts of urban road runoff have increased, partly due to recent research into the harmful impacts of tire particles and their chemical leachates. This study aimed to help the community of researchers, regulators and policy advisers in scoping out the priority areas for further study. To improve our understanding of these issues an interdisciplinary, international network consisting of experts (United Kingdom, Norway, United States, Australia, South Korea, Finland, Austria, China and Canada) was formed. We synthesised the current state of the knowledge and highlighted priority research areas for tire particles (in their different forms) and their leachates. Ten priority research questions with high importance were identified under four themes (environmental presence and detection; chemicals of concern; biotic impacts; mitigation and regulation). The priority research questions include the importance of increasing the understanding of the fate and transport of these contaminants; better alignment of toxicity studies; obtaining the holistic understanding of the impacts; and risks they pose across different ecosystem services. These issues have to be addressed globally for a sustainable solution. We highlight how the establishment of the intergovernmental science-policy panel on chemicals, waste, and pollution prevention could further address these issues on a global level through coordinated knowledge transfer of car tire research and regulation. We hope that the outputs from this research paper will reduce scientific uncertainty in assessing and managing environmental risks from TP and their leachates and aid any potential future policy and regulatory development.

Tracking the biogeochemical behavior of tire wear particles in the environment - A review

The environmental fate and risks associated with tire wear particles (TWPs) are closely linked to their biogeochemical behaviors. However, reviews that focus on TWPs from this perspective remain scarce, hindering our understanding of their environmental fate and cascading effects on ecosystems. In this review, we summarize the existing knowledge on TWPs by addressing five key areas: (i) the generation and size-dependent distribution of TWPs; (ii) the release and transformation of TWP-leachates; (iii) methodologies for the quantification of TWPs; (iv) the toxicity of TWPs; and (v) interactions of TWPs with other environmental processes. It has been established that the size distribution of TWPs significantly influences their transport and occurrence in different matrices, leading to the release and transformation of specific TWP-chemicals that can be toxic to organisms. By highlighting the challenges and knowledge gaps in this field, we propose critical issues that need to be addressed to enhance the risk assessment of TWPs. This review aims to provide a comprehensive framework for evaluating the environmental behavior of TWPs.

New insights into the impact of leachates from in-field collected plastics on aquatic invertebrates and vertebrates

The impact of leachates from micronized beached plastics of the Mediterranean Sea and Atlantic Ocean on coastal marine ecosystems was investigated by using a multidisciplinary approach. Chemical analysis and ecotoxicological tests on phylogenetically distant species were performed on leachates from the following plastic categories: bottles, pellets, hard plastic (HP) containers, fishing nets (FN) and rapido trawling rubber (RTR). The bacteria Alivibrio fischeri, the nauplii of the crustaceans Amphibalanus amphitrite and Acartia tonsa, the rotifer Brachionus plicatilis, the embryos of the sea urchin Paracentrotus lividus, the ephyrae of the jellyfish Aurelia sp. and the larvae of the medaka Oryzias latipes were exposed to different concentrations of leachates to evaluate lethal and sub-lethal effects. Thirty-one additives were identified in the plastic leachates; benzophenone, benzyl butyl phthalate and ethylparaben were present in all leachates. Ecotoxicity of leachates varied among plastic categories and areas, being RTR, HP and FN more toxic than plastic bottles and pellets to several marine invertebrates. The ecotoxicological results based on 13 endpoints were elaborated within a quantitative weight of evidence (WOE) model, providing a synthetic hazard index for each data typology, before their integrations in an environmental risk index. The WOE assigned a moderate and slight hazard to organisms exposed to leachates of FN and HP collected in the Mediterranean Sea respectively, and a moderate hazard to leachates of HP from the Atlantic Ocean. No hazard was found for pellet, bottles and RTR. These findings suggest that an integrated approach based on WOE on a large set of bioassays is recommended to get a more reliable assessment of the ecotoxicity of beached-plastic leachates. In addition, the additives leached from FN and HP should be further investigated to reduce high concentrations and additive types that could impact marine ecosystem health.

Microplastic and mesoplastic pollution in surface waters and beaches of the Canary Islands: A review

The Canary Archipelago is a group of volcanic islands located in the North Atlantic Ocean with high marine biodiversity. This archipelago intercepts the Canary Current, the easternmost branch of the Azores Current in the North Atlantic Subtropical Gyre, which brings large amounts of litter from remote sources via oceanic transportation. It is, therefore, particularly vulnerable to marine plastic pollution. Here, we present a review of the available studies on mesoplastics and microplastics in the Canary Islands over the last decade to evaluate the level and distribution of plastic pollution in this archipelago. Specifically, we focused on data from beaches and surface waters to assess the pollution level among the different islands as well as between windward and leeward zones, and the main characteristics (size, type, colour, and polymer) of the plastics found in the Canary Islands. The concentrations of meso- and MPs on beaches ranged from 1.5 to 2972 items/m2 with a mean of 381 ± 721 items/m2. The concentration of MPs (>200 μm) in surface waters was highly variable with mean values of 998 × 103 ± 3364 × 103 items/km2 and 10 ± 31 items/m3. Plastic pollution in windward beaches was one order of magnitude significantly higher than in leeward beaches. The accumulation of MPs in surface waters was higher in the leeward zones of the high-elevation islands, corresponding to the Special Areas of Conservation (ZECs) and where the presence of marine litter windrows (MLW) has been reported. Microplastic fragments of polyethylene of the colour category "white/clear/uncoloured" were the most common type of plastic reported in both beaches and surface waters. More studies on the occurrence of MLW in ZECS and plastic pollution in the water column and sediments, including small-size fractions (<200 μm), are needed to better assess the level of plastic pollution and its fate in the Canary Islands. Overall, this review confirms that the Canary Archipelago is a hotspot of oceanic plastic pollution, with concentrations of MPs in surface waters in the highest range reported for oceanic islands and one of the highest recorded mean concentrations of beached meso- and microplastics in the world.

Life stage-specific effects of tire particle leachates on the cosmopolitan planktonic copepod Acartia tonsa

Tire wear particles (TWP) are a major source of microplastics in the aquatic environment and the ecological impacts of their leachates are of major environmental concern. Among marine biota, copepods are the most abundant animals in the ocean and a main link between primary producers and higher trophic levels in the marine food webs. In this study, we determined the acute lethal and sublethal effects of tire particle leachates on different life stages of the cosmopolitan planktonic copepod Acartia tonsa. Median lethal concentration (LC50, 48 h) ranged from 0.4 to 0.6 g L-1 depending on the life stages, being nauplii and copepodites more sensitive to tire particle leachates than adults. The median effective concentration (EC50, 48 h) for hatching was higher than 1 g L-1, indicating a relatively low sensitivity of hatching to tire particle leachates. However, metamorphosis (from nauplius VI to copepodite I) was notably reduced by tire particle leachates with an EC50 (48 h) of 0.23 g L-1 and the absence of metamorphosis at 1 g L-1, suggesting a strong developmental delay or endocrine disruption. Leachates also caused a significant decrease (10-22%) in the body length of nauplii and copepodites after exposure to TWP leachates (0.25 and 0.5 g L-1). We tested a battery of enzymatic biomarkers in A. tonsa adult stages, but a sublethal concentration of 50 mg L-1 of tire particle leachates did not cause a statistically significant effect on the measured enzymatic activities. Our results show that tire particle leachates can negatively impact the development, metamorphosis, and survival of planktonic copepods. More field data on concentrations of TWPs and the fate and persistence of their leached additives is needed for a better assessment of the risk of tire particle pollution on marine food webs.

Leachates of weathering plastics from an urban sandy beach: Toxicity to sea urchin fertilization and early development

Plastic leachates have chemical and biological implications for marine environments. This study experimentally evaluated acute effects of weathering plastic leachates (0, 25, 50, 75 and 100 %) on fertilization and early development of the sea urchin Lytechinus variegatus. Fertilization, embryonic and larval development were drastically inhibited (~75 %) when gametes were exposed to intermediate and high leachate concentrations or delayed when exposed to the lowest concentration. Fertilization and first cleavage stages were highly affected by exposure to intermediate and high leachate concentrations. None of the cells incubated at concentrations from 50 % reached blastula stage, suggesting that embryonic development was the most sensitive stage. Abnormalities in embryos and larvae were observed in all leachate treatments. Chemical analysis detected high concentration of bisphenol A, which may induce these observed effects. Our results highlight the potential threats of plastic pollution to sea urchin populations, which may severely affect the structure and functioning of coastal ecosystems.