Phthalate esters delivery to the largest European lagoon: Sources, partitioning and seasonal variations

Tracing the influence of seasonal variation on bioaccumulation and trophodynamics of phthalate esters (PAEs) in marine food web: A case study in Bohai Bay, North China

The ubiquity of phthalate esters (PAEs) leads to public concerns about the safety of seafood consumption. However, their bioaccumulation and trophodynamics in marine food webs remain unclear, especially in different seasons. Herein, we collected 18 species (n = 135) in summer and 17 species (n = 146) in winter from Bohai Bay (BHB). ∑6PAEs in organisms in summer were significantly higher than those in winter. Di-(2-ethylhexyl) phthalate (DEHP) was the predominant PAE with a mean of 1112 ng·g-1 lipid weight (lw) and 375 ng·g-1 lw in summer and winter, respectively. The bioaccumulation factors (BAFs) and biota-sediment accumulation factors (BSAFs) of DEHP in summer were significantly higher than those in winter. A parabolic relationship was found between log Kow and log BAFlw or BSAFlw of PAEs. Food webs in two seasons were constructed based on the δ15N of each organism. Except for diethyl phthalate (DEP), other PAEs underwent biodilution and the biodilution of these PAEs was more obvious in summer compared to winter. Non-carcinogenic risks of 6 PAEs were negligible, but DEHP could pose incremental lifetime carcinogenic risks in some marine samples, especially in summer. This study provides insights into the seasonal variation of bioaccumulation and trophodynamics of PAEs.

Phthalic acid esters as an ecological hazard to the coral reef ecosystems: A case study from the coral reef waters of the Lakshadweep Archipelago, Arabian Sea

Information regarding the sources, distribution and ecological implications of organic contaminants in the coral reef ecosystems is limited. Phthalic acid esters (PAEs) are toxic contaminants due to their endocrine-disrupting and carcinogenic properties. This study investigated the sources, distribution and ecological risk of PAEs (15 PAE congeners) in dissolved and particulate matter-bound forms present in the coral reefs of the Lakshadweep Archipelago. Samples (water and suspended particulate matter) collected from 24 stations of 4 coral islands (Perumal Par, Bangaram, Agatti and Kavaratti) during January and December 2022 were analysed for 15 PAE congeners. The concentration of PAEs was generally lower in coral reef waters than those reported worldwide. The dissolved PAEs (TDPAEs) ranged from 9.23 to 820.85 ng/L, and the particulate PAEs (TPPAEs) ranged from 642.90 to 28,315.45 ng/g. Principal component analysis (PCA) identified three major clusters: one cluster representing low molecular weight PAEs (cosmetic products), while the other two represented medium to high molecular weight PAEs (plastic products). The study region's risk quotient (RQ) values indicated a moderate to high ecological risk caused by di-isobutyl phthalate (DIBP) and di-n-butyl phthalate (DnBP) to crustaceans and fish and indirectly to human health. Therefore, this study strongly recommends regular, systematic monitoring and pollution assessment to avoid the environmental degradation of these fragile ecosystems. This baseline data on PAEs and their source apportionment can help develop mitigative measures for reducing organic contaminants in the coral reef environment.

Tire-derived compounds, phthalates, and trace metals in the Kiel Fjord (Germany)

Concerns about pollutants in the environment are increasing, with substances such as plastic additives drawing particular concern due to their potential harmful effects on organisms. This study investigates current levels of several contaminants in the Kiel Fjord. Some pose serious health risks to aquatic life. In September 2022, water and sediment samples were collected from fifteen stations across the inner and outer Kiel Fjord. The concentrations of selected phthalates, tire-derived compounds, and heavy metals were measured. Results indicate that the outer fjord has minimal contamination, while the inner fjord contains several hotspots with significant pollutant concentrations. For example, the highest levels of heavy metals were detected near Laboe and in deeper sediment layers (>6 cm) at Wik. The maximum concentrations of phthalates were observed near Laboe, with elevated levels also found near the city of Kiel and the Nord-Ostsee-Kanal. This study highlights the substantial anthropogenic impact on the region.

Plasticizers: distribution and impact in aquatic and terrestrial environments

Plasticizers, essential additives for enhancing plastic properties, have emerged as significant environmental and health concerns due to their persistence and widespread use. This study provides an in-depth exploration of plasticizers, focusing on their types, structures, properties, production methods, environmental distribution, and associated risks. The findings reveal that petroleum-based phthalates, particularly di-(2-ethylhexyl) phthalate (DEHP), are prevalent in aquatic and terrestrial environments, primarily due to the gradual degradation of plastic polymers. In the analysis of 39 studies on water contamination during the period of 2022-2023, only 22 works could be extracted due to insufficient details on the numerical value of plasticizer concentrations. Similarly, soil and sediment contamination studies were fewer, with only 11 studies focusing on sediments. These studies reveal that high plasticizer concentrations, notably in industrial and urban areas, often exceed recommended environmental limits, posing risks to ecological integrity and human health through bioaccumulation. Bioaccumulation of these compounds in soil and water could negatively affect the microbial communities, nutrient cycling, and could destabilize the overall ecological integrity. Concerns about their direct uptake by plants and potential risks to human health and food safety are highlighted in this study due to the high concentrations exceeding the threshold values. The review evaluates current treatment technologies, including metal-organic frameworks, electrochemical systems, multi-walled carbon nanotubes, and microbial degradation, noting their potential and challenges related to cost and energy consumption. It underscores the need for improved detection protocols, cost-effective treatments, stricter regulations, public awareness, and collaborative research to mitigate the adverse impacts of plasticizers on ecosystems and human health.

Distribution, seasonal variation and ecological risk assessment of phthalates in the Yitong River, a typical urban watercourse located in Northeast China

Phthalates (PAEs) are a typical class of endocrine disruptors (EEDs). As one of the most commonly used plasticizers, they have received widespread attention due to their wide application in various countries and high detection rates in various environmental media. To be able to clarify the contamination status of PAEs pollutants in a typical northern cold-temperate urban river, 30 water samples from Yitong River in Changchun City, northern China were collected, during the 2023 dry season (March), normal season (May) and wet season (July). Using these samples, a total of 16 target PAEs are investigated. The resulting total PAEs concentrations are: dry season 408 to 1494 ng/L, wet season 491 to 1299 ng/L, and normal season 341 to 780 ng/L. The average concentration of the 16 PAEs over the three seasons is 773 ng/L. Di-2-ethylhexyl phthalate (DEHP) and Dibutyl phthalate (DBP) have the highest concentrations, ranging from 12 to 403 ng/L and 28-680 ng/L respectively. The ecological risks within the Yitong River Basin are evaluated based on the degree of PAEs contamination. DBP and DEHP pose higher risk assessment levels for algae, crustaceans and fish than the other target PAEs. The accurate determination of PAEs provided baseline data on PAEs for the management of the Yitong River, which is of great significance for the prediction of ecological risk assessment and the development of corresponding control measures, supported further research on PAEs in the cold-temperate zone aquatic environments, and shed light on the seasonal variations of PAEs in the Northeast region in the future. Moreover, considering the bioaccumulation and persistence of PAEs, it is necessary to continue to pay attention to the pollution status of cold-temperate zones rivers and the changes in ecological risks in the future.

Coastal wastewater treatment plants as a source of endocrine disrupting micropollutants: a case study of Lithuania in the Baltic Sea

In temperate coastal areas, the resident population often increases during holidays. As a result, this can lead to higher wastewater production and release of pollutants. The connection between micropollutants such as plasticizers and hormones with the changing resident population along the Baltic Sea coast has yet to be thoroughly studied. Therefore, we have monitored the wastewater quality and specific micropollutants before and after treatment at wastewater treatment plants (WWTPs) at small and large seaside resorts. The findings indicate a strong link between tourism indicators and wastewater production during the summer months. The rise in different micropollutants, specifically plasticizers, during the summer demonstrates a link with tourism activity. Furthermore, we have identified a non-linear association between the tourism indicators and the total estrogenic equivalent (EEQ). Overall, this research particularly emphasizes the growing importance of wastewater quality in terms of conventional nutrient pollution and various micropollutants.

Summary recommendations on "Analytical methods for substances in the Watch List under the Water Framework Directive"

The Watch List (WL) is a monitoring program under the European Water Framework Directive (WFD) to obtain high-quality Union-wide monitoring data on potential water pollutants for which scarce monitoring data or data of insufficient quality are available. The main purpose of the WL data collection is to determine if the substances pose a risk to the aquatic environment at EU level and subsequently to decide whether a threshold, the Environmental Quality Standards (EQS) should be set for them and, potentially to be listed as priority substance in the WFD. The first WL was established in 2015 and contained 10 individual or groups of substances while the 4th WL was launched in 2022. The results of monitoring the substances of the first WL showed that some countries had difficulties to reach an analytical Limit of Quantification (LOQ) below or equal to the Predicted No-Effect Concentrations (PNEC) or EQS. The Joint Research Centre (JRC) of the European Commission (EC) organised a series of workshops to support the EU Member States (MS) and their activities under the WFD. Sharing the knowledge among the Member States on the analytical methods is important to deliver good data quality. The outcome and the discussion engaged with the experts are described in this paper, and in addition a literature review of the most important publications on the analysis of 17-alpha-ethinylestradiol (EE2), amoxicillin, ciprofloxacin, metaflumizone, fipronil, metformin, and guanylurea from the last years is presented.