Distribution and importance of microplastics in the marine environment: A review of the sources, fate, effects, and potential solutions

Combined exposure of polystyrene nanoplastics and silver nanoparticles exacerbating hepatotoxicity in zebrafish mediated by ferroptosis pathway through increased silver accumulation

Silver nanoparticles (AgNPs) are extensively utilized for their antibacterial properties, leading to their release into the environment and subsequent bioaccumulation and biomagnification within the food chain. Polystyrene nanoplastics (PSNPs), as emerging pollutants, act as carriers for contaminants and alter their transformation processes. However, the toxicological effects and underlying mechanisms associated with the coexistence of these pollutants remain largely unexplored. Herein, the hepatotoxic effects and underlying mechanisms of acute combined exposure to PSNPs and AgNPs were explored using zebrafish as a model organism. After exposed to PSNPs and AgNPs, the larvae (120 hours post-fertilization) exhibited lipid metabolism disorders, increased oxidative stress, hepatomegaly, and liver dysfunction, with these effects being more pronounced than those observed with AgNPs exposure alone. This increase in hepatic toxicity may be due to the enhanced accumulation of AgNPs under combined exposure. Mechanistic investigations revealed that co-exposure led to a significant elevation in malondialdehyde and Fe2 + levels, a loss of mitochondrial cristae and a decrease in membrane potential, along with the abnormal expression of ferroptosis-related genes, which are hallmark indicators of ferroptosis. Furthermore, the introduction of the ferroptosis inhibitor deferoxamine alleviated all observed hepatotoxic phenotypes, thereby confirming that PS+AgNPs co-exposure induced liver injury through the ferroptosis pathway.

Adsorption of benzophenone-3 and octocrylene UV filters on polyethylene: analysis by HPLC-MS/MS and voltammetry with screen-printed electrodes

Microplastics (MPs) are persistent pollutants that can adsorb contaminants, facilitating their accumulation in aquatic ecosystems. The presence of UV filters (UVFs) such as benzophenone-3 (BP3) and octocrylene (OC), exacerbates this issue, particularly in coastal areas. This study presents an innovative dual-method approach combining high-performance liquid chromatography tandem mass spectrometry (HPLC-MS/MS) and differential pulse adsorptive stripping voltammetry (DPAdSV) to assess the adsorption of UVFs on polyethylene (PE), a widely found polymer in aquatic environments. Adsorption kinetics were analysed using pseudo-first-order (PFOM) and pseudo-second-order (PSOM) models, revealing a higher equilibrium sorption capacity for OC due to its stronger hydrophobic interactions with PE. A central composite design (CCD) was employed to enhance resources efficiency in experimentation and controlled experiments exposed the materials to both pure fresh water and synthetic seawater. The results indicate a higher adsorption affinity of OC on PE than BP3, attributed to its high octanol-water partition coefficient (log Kow 6.88) and stronger hydrophobic interactions. Exposure time was the most influential variable across both media, while pH and temperature had a significant effect on BP3 adsorption in synthetic seawater. Hydrophobic partitioning, aided by van der Waals forces, was identified as the dominant interaction mechanism for both UVFs, with π-π and electrostatic interactions playing minimal roles due to the nature of the polymer. The study provides new insights into how polymer-pollutant interactions vary across environmental conditions and offers a novel voltammetric alternative for in-situ UVFs monitoring.

COVID-19 related personal protective equipment (PPE) litter in salt marsh habitats: Degradation and microplastic emission

The use of personal protective equipment (PPE) has increased significantly since the onset of the COVID-19 pandemic in late 2019. Face masks, gloves, and sanitizing wipes are common types of PPE that have been used during the pandemic, all of which can be comprised of plastic polymers. PPE items have been shown to generate microplastic fibers and fragments, but their degradation in the natural environment is understudied. The objective of this study was to quantify the degradation and microplastic emission of common plastic PPE items in a salt marsh, which serve a vital role in maintaining the health and resilience of coastal ecosystems and have been shown to be vulnerable to pollutants. Four types of PPE items (face masks, gloves, compostable and conventional sanitizing wipes) were deployed in an intertidal salt marsh for up to 16 weeks. Changes in weight, biofilm formation, surface area, and microplastic emissions were measured at 0, 2, 4, 8, and 16 weeks. All PPE degraded in the environment and emitted particles beginning at 2 weeks, and emission increased over time. Sanitizing wipes produced the highest number of microplastics at the end of 16-weeks. Compared to previous studies in the same area, these results suggest that plastic PPE items may degrade faster than other plastics. This study is one of the first to quantify PPE degradation and microplastic emission in the natural environment and supports the notion that single-use PPE litter has the potential to be a source of microplastic pollution in coastal environments.

Microplastics in the marine environment: Challenges and the shift towards sustainable plastics and plasticizers

The United Nations (UN) estimate that around 75-199 million tons of plastic is floating in the world's oceans today. Continuous unintentional disposal of plastic waste in marine environments has and continues to cause significant biological impacts to various marine organisms ranging from mild difficulties in swimming or superficial damage to critical organ malfunctions and mortality. Over time, plastics in these environments degrade into microplastics which are now acknowledged as a pervasive harmful pollutant found in the cryosphere, atmosphere and hydrosphere. In response to this issue, the production of bespoke biodegradable bioplastics derived from renewable resources, such as vegetable oils, starch and plant fibres, is emerging to mitigate our reliance on environmentally persistent conventional fossil fuel-based plastics. While bioplastics degrade more readily than conventional plastics, they present new challenges, including leaching of toxic chemical additives and plasticizers into the environment. Consequently, various techniques have been explored in the search for sustainable plasticizers, from cheap, non-toxic compounds, such as vegetable oils and sugars to hyperbranched structures with limited migration. This article seeks to explain the intricate relationship between the problem of microplastics in marine environments and the strategies that have been investigated to address it thus far.

Baseline assessment of microplastics pollution in beach sediments along tropical coastline (Kuala Langat, Malaysia)

This study examines the occurrence, physical characteristics (size, colour, and shape), and polymer compositions of microplastics (MPs) in beach sediments along the Kuala Langat coastline impacted by tourism and fishing activities. Microplastics particle were isolated using density separation, characterized using microscopy and Spectroscopy technique. Microplastic concentrations ranged from 0.01 to 0.21 particles/g in tourist sites and 0.01 to 0.03 particles/g in non-tourist sites, indicating significantly higher MP pollution in tourism-affected areas. The longest MP particle (4951.5 μm) was found in a non-tourist area, while the shortest (84.7 μm) was detected on a tourist beach. Fragment-shaped MPs (82.40 %) were the most dominant, exhibiting a variety of colors and diverse plastic sources. Polypropylene, polyethylene, and polystyrene comprised 80 % of the detected polymers, suggesting that single-use plastics contribute substantially to MP pollution in both sampling sites. These findings provide critical insights for targeted strategies for plastic waste management in tropical coastal areas.

Algal bloom-mediated microplastic dispersion in coastal areas of West Africa: Integrated insights and risk projections from molecular models and remote-sensed evaluations

Algal blooms along the West African coast threaten ecosystems and human health due to nutrient enrichment and rising temperatures. This remote-sensing study examined the relationships between chlorophyll-a concentrations, environmental variables, and the potential for microplastic retention in blooms using molecular docking models for predictive insights. Correlation analyses revealed region-specific associations, with moderate positive correlations between chlorophyll and temperature along the southwest Nigeria-Togo coastline and near Liberia and Sierra Leone (r = 0.2-0.4) and strong correlations with particulate carbon across most regions (r = 0.6-0.8). Chlorophyll fluorescence correlations were generally low (r = 0.2), except for higher correlations in the Senegal-Gabon and Côte d'Ivoire-Ghana stretches, indicating that localized factors influence bloom dynamics. Molecular docking results predict that polycarbonate microplastics have the strongest binding affinities with algal proteins, particularly flagellin (-11.3 kcal/mol), suggesting significant retention potential within bloom matrices. In contrast, ethylene plastics displayed weaker interactions (up to -2.2 kcal/mol) and a high dissociation constant (Kd = 0.079 M), indicating minimal retention potential. The low Kd values for polycarbonateprotein interactions (e.g., 5.15e09 M for flagellin) predict a concerning scenario where microplastics become increasingly integrated into algal biomass, increasing exposure risks for marine life. Warm, nutrient-rich conditions along the West African coast, especially from southwest Nigeria to Togo and Côte d'Ivoire to Sierra Leone, are expected to increase the frequency and severity of algal blooms. This proliferation disrupts biodiversity and water quality while straining local fisheries by altering marine food webs. To mitigate microplastic entrapment from algal blooms and protect vulnerable marine ecosystems, targeted monitoring and intervention strategies are essential.

Zooplankton assemblage and microplastics associated with a coastal sandspit (Tubará, Atlántico)

Zooplankton, as a foundational component of the food chain, plays an important role in the bioaccumulation and biomagnification of contaminants, including microplastics (MPs). This study focused on the structure of the marine zooplankton community and the presence of MPs in the surface waters of Tubará (Atlántico Department, Colombian Caribbean), establishing baseline data to assess the potential ingestion of MPs by zooplanktivorous organisms. Four sampling events were conducted at the Puerto Velero sandspit during the second half of 2023. The zooplankton assemblage comprised 11 phyla, with an average density of 633.18 individuals per cubic meter (indv/m3) ± 350.5 indv/m3. The community was predominantly composed of copepods (54.66 %), mollusk larvae (15.17 %), chaetognaths (10.29 %), and appendicularians (9.35 %). A total of 614 MPs were identified, corresponding to a density of 5.43 MPs/m3 ± 2.9 MPs/m3. These MPs were classified into three types and ten colors. Fibers accounted for 93.49 % of the MPs, whereas fragments and films constituted 5.86 % and 0.65 %, respectively. The most prevalent colors were red (36 %), black (33.7 %), and blue (16.9 %). Additionally, an average numerical ratio of 0.0086 MPs per zooplankton individual was recorded. This research represents the first report on the zooplankton community structure in the Atlántico Department and is also the first study in Colombia to quantify the MP-to-individual ratio. These findings are essential for guiding conservation and management strategies for marine fauna and emphasize the critical need to monitor both the plankton community and MPs in systems significantly impacted by discharges from the Magdalena River.

Omaveloxolone Prevents Polystyrene Microplastic-Induced Ovarian Granulosa Cell Apoptosis via the Keap1/Nrf2/HO-1 Pathway in Rats

Microplastics (MPs) are persistent environmental pollutants that enter the circulatory system and subsequently reduce sperm quantity and quality. However, the influence of polystyrene MPs (PS-MPs) on the ovary and relevant mechanisms remain elusive. Herein, we aimed to examine the impact of PS-MPs on oxidative disorders in ovarian tissues and elucidate the underlying mechanisms. Healthy female rats were treated with different concentrations of 0.5 µm PS-MPs (diluted in deionized H2O) for 90 days. Upon examination of hematoxylin-eosin-stained ovarian tissue sections, the number of growing follicles was reduced in PS-MP-treated rats when compared with that in control rats. Enzyme-linked immunosorbent assays revealed that PS-MP exposure markedly reduced anti-Müllerian hormone (AMH) levels. Treatment with PS-MPs downregulated superoxide dismutase, glutathione, and catalase activities in ovarian tissues while upregulating malondialdehyde levels. Furthermore, exposure to PS-MP blocked the Keap1/Nrf2/HO-1 signal transduction pathway. PS-MPs also triggered apoptosis in the ovarian tissue, as evidenced by increased TUNEL staining and expression levels of cleaved caspase-9, Bax, and Bcl-2. To reactivate the Keap1/Nrf2/HO-1 pathway, rats were co-administered PS-MPs and omaveloxolone (Oma), an Nrf2 activator, for 1 week. We found that Oma could counteract the PS-MP-mediated effects on oxidative disorder, apoptosis, AMH production, and follicle number in rat ovarian tissues. To develop an in vitro model, granulosa cells (GCs) were treated with 10 μM H2O2 for 12 h to induce oxidative stress. H2O2-stimulated GCs exhibited attenuated cell growth and upregulated apoptosis and oxidative stress. Oma administration could ameliorate the H2O2-induced effects in terms of regulating cell viability, apoptosis, and oxidative stress in GCs. In summary, PS-MPs could induce apoptosis and oxidative stress via the Keap1/Nrf2/HO-1 signaling pathway in both rats and GCs.

Exploring the toxicology, socio-ecological impacts and biodegradation of microplastics in Africa: Potentials for resource conservation

Achieving upcycling and circularity in the microplastic economy predominantly depends on collecting and sorting plastic waste from the source to the end-user for resource conservation. Microplastics, whether from packaging or non-packaging materials, pose a significant environmental challenge as they are often not prioritized for collection or recycling initiatives. The presence of additives impedes the quality of plastic recyclates and the persistence of microplastics as shredded resultants remain a threat to the aquatic and terrestrial ecosystem and its biodiversity. Despite the increasing global research on microplastics, the success of plastic and microplastic waste management in Africa is yet to be fully attained. Considering the improper disposal, limited recycling and upcycling intervention, lack of policy, and strict laws against plastic waste management defaulters, the ecosystems in Africa remain immensely impacted by several socio-ecological factors leading to the loss of aquatic organisms through reducing fertility and increasing stress. As a ripple consequence, the disruption of economic activities, toxic effects on animal/human health, and climate crisis are among their impact. This review therefore provides comprehensive detail of microplastic production and challenges in Africa, the toxicology concerns, socio-ecological issues associated with microplastic waste management, and insight into approaches to mitigate plastic pollution through recycling, upcycling, bioprocessing and their biodegradation with social insects and microorganisms which may form the basis for adoption by policymakers and researchers, thereby minimizing the consequences of plastic pollution in Africa.

A global assessment of microplastic abundance and characteristics on marine turtle nesting beaches

Sandy coastal beaches are an important nesting habitat for marine turtles and a known sink for plastic pollution. Existing methodologies for monitoring the spatiotemporal patterns of abundance and composition of plastic are, however, disparate. We engaged a global network of marine turtle scientists to implement a large-scale sampling effort to assess microplastic abundance in beach sediments on marine turtle nesting beaches. Sand samples were collected from 209 sites spanning six oceans, microplastics (1-5 mm) were extracted through stacked sieves, visually identified, and a sub-sample verified via Fourier-transform infrared spectroscopy. Microplastics were detected in 45 % (n = 94) of beaches and within five ocean basins. Microplastic presence and abundance was found to vary markedly within and among ocean basins, with the highest proportion of contaminated beaches found in the Mediterranean (80 %). We present all data in an accessible, open access format to facilitate the extension of monitoring efforts and empower novel analytical approaches.

Correcting microplastic pollution and risk assessment in Chinese watersheds

Microplastics (MPs) are emerging pollutants that are attracting attention because of their potential threats posed and their widespread presence in the environment. MP pollution in Chinese watersheds requires assessment; however, existing risk models face data-scale biases. By compiling 2,474 samples from 165 articles, we constructed a national dataset on MPs and propose a novel framework that integrates rescaled MP concentrations with MP characteristics to recalibrate MP pollution and ecological risks. The results showed that MP concentrations show substantial variability across seven orders of magnitude, and corrected data offered a more accurate representation of environmental concentrations. MP shapes, polymers, and colors differed among river basins, and population density and precipitation were important drivers of variations in MP concentrations. MP shapes, colors, and sizes that were not previously considered are now included in the risk assessment of MPs. Furthermore, 50 % of the sampling sites were in the dangerous and extremely dangerous ecological risk classes. The concentrations measured at 16.98 % of the sampling sites exceeded the risk threshold, therefore posing ecological and toxicological risks. The assessment framework may provide overall insights into the differences in MP pollution in river basins.

Man-made polymers of natural compounds out weight microplastics in Australian seafood: Are we fixating on the wrong thing?

Pollution from synthetic microparticles such as microplastic (MPs) is of global concern. Semi-synthetic microparticles, also known as manufactured natural polymers (MNPs), have received much less scientific attention, despite their morphological similarity to MPs, comparable chemical additives, and the shared potential to act as vector for chemical substances and microorganisms. This study assessed MP and MNP levels in five popular seafood species: sand whiting (Sillago cillata), squids (Loligo spp.), eastern king prawns (Melicertus plebejus), blue swimmer crabs (Portunus armatus), and flatheads (family Platycephalidae) sold fresh in local fish markets from the Gold Coast, Australia. Samples from three tissue types (gill, gut, and muscle) were digested with 10 % KOH and filtered through 5-micron stainless steel filter meshes. Visual microscopic screening was carried out for isolated microparticles, and size, shape, and colour were recorded; then, isolated suspected microparticles were analysed by μ-FTIR to identify the polymer type. Our results show that 88.6 % of seafood available in local fish markets on the Gold Coast was contaminated with at least one particle of MP or MNP. Pelagic species contained a higher particle concentration (0.630 ± 0.064 particles/g) compared to demersal species (0.130 ± 0.019 particles/g. Non-edible tissues exposed to the external environment (gill and gut) contained significantly higher concentrations (0.545 ± 0.046 particles/g) of microparticles compared to edible tissue (muscle) (0.203 ± 0.025 particles/g). There was 1.1-3.2 time more MNPs than MPs in all tissue samples except in prawn muscle and flathead gill tissues, indicating that MNPs may pose a greater threat than previously recognised.

An efficient and precise (micro)plastic identification method: feature infrared spectra extraction based on EIS-VIP-CARS and ANN modeling

Understanding microplastics' (MPs) ecological impact necessitates their precise identification. To address the issue of the competitive adaptive reweighted sampling (CARS) algorithm extracting numerous feature wavenumber points (FWPs) that often miss transmittance peaks (TPs), resulting in high computational load and low accuracy in artificial neural network (ANN) models, this study introduces a novel approach. Initially, the equal interval sampling (EIS) method is employed to capture the main information of the full spectra. Subsequently, the variable importance in projection (VIP) is innovatively integrated into the CARS to formulate the EIS-VIP-CARS method for extracting feature spectra (FS). Using 20 typical MPs as the subjects, this study compares the identification performance of ANN models using full-spectra, EIS, CARS, EIS-CARS, VIP-CARS, and EIS-VIP-CARS. The results show that VIP-CARS extracts 128 FWPs, a reduction of 49.41 % compared to CARS. Moreover, the distribution of these FWPs is more concentrated around the TPs and their vicinity. The accuracy of MPs by the ANN model based on VIP-CARS is generally higher than that of CARS. EIS-VIP-CARS extracts 55 FWPs, representing a reduction of 58.65 % and 57.03 % compared to EIS and VIP-CARS, respectively. The overall distribution of these points closely aligns with the distribution of functional groups. The ANN model based on EIS-VIP-CARS can achieve a similar accuracy for MPs as the model based on EIS, both greater than 99 %, demonstrating good generalization ability. The accuracies of the MNN and convolutional neural network (CNN) models are higher than those of the SNN model, but the modeling time is longer. The ANN model established using the EIS-VIP-CARS is an efficient and precise approach for the identification of MPs in infrared spectroscopy. This study provides technical references for the research on the environmental behavior of MPs and is also of significant importance for the classification and management of plastic waste.

Responses of Microcystis aeruginosa to polystyrene microplastics: Growth dynamics and implications for water treatment

The understanding of microplastics (MPs) has advanced significantly with their accumulation in aquatic environments, but their potential impact on cyanobacterial blooms remains inadequately understood. Herein, the dynamic fluctuating effects of polystyrene (PS) on Microcystis aeruginosa were investigated throughout its growth cycle, as well as the action of algal organic matter in the disinfection by-products formation. The maximum inhibition of algal cell growth and phycobiliprotein content by PS during the adaptation phase reached 56.3 % and 76.3 %, respectively. With the extension of exposure time, the inhibitory effect gradually transitions into promotive effect. PS exposure increased the content of extracellular organic matter and enhanced the THMs formation during chlorination, with trihalomethanes concentrations of 62.8 and 101.9 μg/L in the control and PS treatment groups, respectively. Moreover, the reactive oxygen species levels in PS-exposed algal cells were only 71.5 % of those in the control group, and total antioxidant capacity levels, superoxide dismutase and catalase activities were also lower. However, the microcystin content exposed PS was increased to 1.2 times that of the control group. The presence of PS in aquatic environments increases the levels of algal organic matter and microcystin, potentially threatening water quality. This study provides new insights into the combined effects of microplastics on freshwater algae and valuable data on potential risk associated with MPs.

Acute and partial life-cycle toxicity of a tri-polymer blend of microplastics in the copepod Acartia tonsa

Microplastics are a prolific environmental contaminant that pose a risk to marine organisms. Ecotoxicological studies have identified microplastics can cause sub-lethal harm to aquatic biota. However, prior studies often lack comparability and environmental relevance, for example focussing upon monodisperse beads at extremely high concentrations. Copepods are keystone marine taxa that play vital roles in the marine food web and biogeochemical cycling. In this study, we adapted ISO methods to conduct acute and partial life-cycle toxicity tests exposing adult and juvenile life stages of the copepod Acartia tonsa to a fully characterised tri-polymer microplastic blend comprising cryoground polyethylene, polypropylene, and nylon particles (5-100 μm) at concentrations ranging 0-1000 μg L-1. The tests considered the toxicity of microplastics on a wide number of endpoints including adult survival, algal ingestion rates, egg production and size, larval development ratio and juvenile survival. Mortality, egg size and larval development ratio proved to be the most sensitive endpoints. The tri-polymer blend had an LC5072h value of 182 μg L-1 providing a baseline for future toxicity testing using this method.

Biodegradation of low-density polyethylene LDPE by marine bacterial strains Gordonia alkanivorans PBM1 and PSW1 isolated from Mediterranean Sea, Alexandria, Egypt

Plastic has become an essential part of daily human activity. Nonetheless, its over-utilization has resulted in environmental accumulation, leading to marine contamination. Biodegradation is the most effective approach for managing synthetic plastic waste. It encompasses various biological processes that depolymerize polymeric compounds into oligomers or monomers that can enter the biogeochemical cycle. Although research on microplastic biodegradation is abundant and increasing, studies on the biodegradation of low-density polyethylene (LDPE) by marine microorganisms remain scarce and underexplored. In the present study, a total of 17 bacterial isolates were isolated from plastic-contaminated sites in Abu Qir Bay, Alexandria, Egypt. Two bacterial strains demonstrated the highest LDPE biodegradation potential and were identified using 16 S rRNA sequencing, exhibiting 100% and 99.87% sequence identity to Gordonia alkanivorans. Biodegradation of LDPE was confirmed through dry weight loss, with G. alkanivorans strains PSW1 and PBM1 achieving reductions of 0.88 ± 0.658% and 0.66 ± 0.508%, respectively. Biodegradation was further confirmed through the formation of cracks and cavities observed through scanning electron microscopy (SEM). Infrared analysis indicated significant changes in LDPE functional groups and a decrease in the carbonyl index. Biodegradation of LDPE films was also demonstrated through gas chromatography-mass spectrometry (GC/MS) via the release of metabolites, correlating with LDPE utilization. The findings highlight the ability of marine bacteria G. alkanivorans strains PSW1 and PBM1 to biodegrade LDPE.

Plastic Smell: A Review of the Hidden Threat of Airborne Micro and Nanoplastics to Human Health and the Environment

Airborne micro and nanoplastics (MPs/NPs) are a growing issue due to their possible health hazards. Since the current bibliography lacks a thorough evaluation, this review examines the sources, environmental dynamics, and health impacts of airborne MPs/NPs. Through atmospheric transport processes, these neo-pollutants spread around the world after being released, potentially settling in urban and remote areas. This review is the first to compare active and passive aerosol sampling methods, and microscopy, thermochemical, and spectroscopy analytical techniques, with a focus on their limitations in precisely quantifying micro-nanoscale plastic particles. It also draws attention to the potential toxicological effects of inhaled MPs/NPs, which can lead to oxidative stress, respiratory inflammation, and other negative health consequences. This review concludes by examining how airborne MPs/NPs may worsen their ecological impact by serving as carriers of hazardous chemicals and microbial pollutants. Despite growing awareness, there still are many unanswered questions, especially about the impact of long-term exposure and how atmospheric conditions affect the spread of MPs/NPs. The aim of this review was to bring attention to the issue of airborne MP/NP effects and to promote the development of advanced monitoring systems, a new multidisciplinary scientific field for the study of these novel pollutants, and global regulatory frameworks.

Microplastics indirectly affect soil respiration of different-aged forest by altering microbial communities and carbon metabolism

This study explored how microplastics impact soil respiration processes in forests of varying ages by modulating the structure of microbial communities and carbon metabolic functions. The findings indicated that the abundance of microplastics in different aged forests was approximately 600-3858 items∙kg-1. The 10-year-old Pinus massoniana forest exhibited the lowest, and the 60-year-old forest had the highest microplastic abundance. The microplastics mainly consisted of fibers (26.57-38.38 %), particles sized 0-0.1 μm (40.28-70.19 %), and black particles (6.92-43.46 %). The soil respiration rate decreases with increasing forest age. However, the microplastics indirectly modified soil respiration by influencing total organic carbon (TOC) and soil pH. The functional prediction analysis showed that metabolic pathways such as formaldehyde assimilation, ribulose monophosphate pathway, and the hydroxypropionate-hydroxybutylate cycle, were significantly correlated with microplastic abundance. Structural equation model (SEM) results suggested that microplastics affected microbial carbon metabolic demands by altering microbial community structure (0.44) or directly influencing carbon metabolic pathways (0.68). Consequently, this impacts soil CO2 emissions. The findings provide new insights into the critical role of forest soils in mitigating carbon emissions caused by microplastics.

Responses of natural plastisphere community and zooplankton to microplastic pollution: a review on novel remediation strategies

The ubiquitous presence of microplastics (MP) in different environments has been well documented. Microplastic contamination has rapidly become a serious environmental issue, threatening marine ecosystems and human health. MP has been reported to accumulate organic pollutants associated with various microbial communities. The MP hazard is specifically serious in urban lakes, near-shore beaches, and benthic sediments. To prevent the further spread of MP and mitigate the increasing level of MP contamination, along with its associated environmental and economic concerns, it is essential to address mitigation strategies and their negative impacts. Contributed by low degradability, hydrophobicity, and sorption potential, the plastic surface acts as an important substrate colonized by several microorganisms known as the plastisphere community. Adaptive responses of the plastisphere community, MP ingestion, and surface modifications by the zooplankton provide insight into novel remediation strategies based on integrated natural community-level approaches. Zooplankton studies are extensive and encompass assessments of their abundance, biomass, distribution, and DNA meta-barcoding. Additionally, zooplankton has been utilized as an indicator in various freshwater environmental policies. Overall, employing zooplankton as an indicator in environmental policies is a vital tool for assessing the health of aquatic ecosystems and can assist in guiding management and conservation efforts. This review summarizes (i) the current literature on the estimation of MP distribution in aquatic environments, (ii) the effects of MP accumulation on the environment and its inhabitants, i.e., the interactions with marine microbiota,, (iii) addresses the bioremediation strategies with an emphasis on microbial degradation, ecological functioning and adaptive responses of marine microbes and finally, (iv) the directions of further research aiming to in situ mitigation of MP pollution. Recent advancements have focused on innovative methods such as membrane bioreactors, synthetic biology, organosilane-based techniques, biofilm-mediated remediation, and nanomaterial-enabled strategies. Nano-enabled technologies show substantial potential to enhance microplastic removal efficiency. Further investigation is necessary to develop advanced treatment technologies that can enhance the removal efficiency of microplastics (MPs) in drinking water. Additionally, more research is needed to understand the toxic impacts of MPs on marine ecosystems, including coral reefs, seagrass beds, mangroves, and other important habitats.

Microplastic occurrence, distribution, and zonation at Paraná's beaches-South of Brazil

Microplastics are emerging pollutants that are increasingly reported on beaches and potentially impacting the environment and ecosystems. This study presents the first assessment of microplastic (MP) abundance and distribution on oceanic beaches of Paraná, South Brazil. Surface sediments samples retrieved from different beach zones across four beaches were analyzed for their MP (in the 1 to 5 mm size fraction-large microplastics) abundance, morphotype, and polymer composition. MP were found on all the studied beaches, totaling 846 particles, with mean concentrations of 51.9 MP/m2 or 2.3 MP/kg dw. The most common morphotypes were fragments (40%), styrofoam (28%), and foams (10%), mainly composed of polyethylene (35%) and polypropylene (29%). MP concentration distribution significantly differed between beach zones, and morphotype distribution showed differences between beaches. MP distribution followed a cross-shore pattern, with the backshore as a main accumulation area. Our study suggests that natural environmental factors such as grain size and beach slope primarily control MP distribution and accumulation along sandy shores. At the same time, the proximity of potential MP sources influences morphotype variation among beaches.

Microplastic contamination in green mussels (Perna viridis Linnaeus, 1858) from traditional seafood markets in Jakarta, Indonesia, and an evaluation of potential hazards

Marine organisms, especially mussels, can efficiently take up microplastics (MPs) through their filtration processes. This study evaluated the characteristics of MPs in green mussels (Perna viridis) sold at traditional seafood markets in Jakarta, Indonesia. The polymers of MPs were examined using Fourier Transform Infrared spectroscopy, while the chemical components of MPs in green mussels were analyzed using Gas Chromatography-Mass Spectrometry. The MPs identified in green mussels sold at traditional seafood markets in Jakarta are predominantly of fiber type, display a black coloration, and measure <100 μm in size. The density of these microplastics in green mussels is uniform across all traditional markets. The concentration of microplastics in green mussels correlates positively with the length of the green mussel shell. The average annual consumption of mussel products by people in Jakarta was 11,170 items/year/person. Green mussels from Jakarta exhibited a significantly elevated polymer hazard index (III), indicating the presence of polymers categorized as high risk. Certain plasticizers (phthalates) and specific additive chemicals (phenol, butylated hydroxytoluene, and hexadecanamide) were also present in green mussels sourced from traditional markets in Jakarta. These substances are toxic and have a negative impact on both aquatic life and humans.

Turning the tide on microplastic pollution: Leveraging the potential of geopolymers for mitigation

Microplastic pollution represents a significant environmental challenge due to its persistence and role as a vector for harmful contaminants. Conventional mitigation strategies, such as filtration, oxidative degradation, and microbial treatments, often exhibit limitations in efficiency, scalability, or result in the generation of secondary pollutants. This review examines the emerging potential of geopolymers as sustainable materials for microplastic remediation. Owing to their high porosity, chemical stability, tunable surface chemistry, and regenerative properties, geopolymers demonstrate considerable promise as both adsorbents and membrane materials. Extensive research has validated the efficacy of geopolymers in the removal of various environmental contaminants, including heavy metals and organic pollutants. For example, fly ash-based geopolymers modified with cetyltrimethylammonium bromide (CTAB) achieved a 98.2% removal efficiency for anionic acid blue 185 (AB185), while porous amorphous geopolymers synthesized from fly ash and iron ore tailings exhibited a copper (Cu2+) uptake capacity of 113.41 mg/g at 40 °C. These findings underscore the versatility of geopolymers in complex wastewater treatment applications. To date, only one direct study has explored geopolymer application in microplastic removal, demonstrating that silane-modified superhydrophobic geopolymer foam achieved up to 99% removal efficiency for polyethylene microspheres in wastewater. While this result highlights the feasibility of geopolymer-based microplastic remediation, dedicated research in this area remains sparse. This review consolidates existing knowledge on geopolymer interactions with other environmental pollutants to inform potential mechanisms for microplastic remediation. By drawing parallels between the removal of heavy metals and organic pollutants, this work identifies transferable principles and outlines research gaps necessary to advance geopolymer-based solutions for microplastic pollution. Overall, the findings affirm geopolymers' transformative potential in addressing microplastic contamination, while underscoring the urgent need for further experimental and field-based studies in this domain.

Microplastic contamination in the mangroves of Piraquê-Açu and Piraquê-Mirim rivers, Aracruz (Brazil): An analysis in sediment, water, and biota

Mangroves are transitional ecosystems between terrestrial and marine environments, typical of tropical and subtropical regions. They contribute to socio-economic development by providing fisheries resources, which are essential for income generation and a significant source of animal protein. Thus, the consumption of marine organisms, particularly contaminated bivalves, represents a potential route for human exposure to microplastics (MPs). This study evaluated the presence, spatiotemporal distribution, and characterization of microplastics in sediment, surface water, and two bivalve species used for human consumption. Samples were collected from five distinct sites across the Aracruz mangrove (ES) to ensure a comprehensive representation of the study area. A total of 7806 microplastic particles were detected in the analyzed matrices, with the highest concentrations found in sediments, corroborating existing literature that identifies sediments as sinks for MPs. Filament-type microplastics predominated in all matrices, aligning with previous studies that report this form as prevalent in mangrove sediments. Blue microplastics were the most frequently observed across all matrices, potentially associated with discarded or abandoned fishing gear, a common practice in fishing zones. Crassostrea rhizophorae exhibited a higher concentration of MPs compared to Mytella strigata. Analysis of dry and wet periods revealed higher MP concentrations during the dry season, potentially explained by reduced dilution and increased accumulation of pollutants, while rainy seasons promoted MP transport to larger water bodies. A positive correlation between MPs in bivalves and those in surface water suggests that waterborne MPs are a significant contamination source for filter-feeding organisms.

Key adsorbents and influencing factors in the adsorption of micro- and nanoplastics: A review

Microplastics and nanoplastics (MNPs) are emerging contaminants in drinking water sources that pose serious risks to human health and ecosystems. Several removal strategies, such as adsorption, exist but present challenges for their industrial scalability. This review provides a concise overview of MNP adsorption mechanisms and highlights the limited but critical exploration of column adsorption in the literature, emphasizing its importance for large-scale applications. Special attention is given to carbon-based materials due to their cost-effectiveness, environmental friendliness and sustainability. Other adsorbents (e.g., metal-organic frameworks, clays) are also discussed for their promising performance in realistic water matrixes. To predict and optimize the efficiency of adsorbents, leading simulation models are reviewed. Taken together, this work provides a comprehensive overview of the fundamental factors, such as adsorption mechanisms, adsorbent selection and experimental conditions, to optimize MNP adsorption. By highlighting the underexplored area of column-based processes, it provides valuable information to advance adsorption as a viable industrial-scale solution for MNP contamination.

Plastics and their derivatives are impacting animal ecophysiology: A review

Nowadays, plastic pollution is one of the most significant issues affecting the environment, posing a serious threat to marine biodiversity, ecosystem stability, and human health. Millions of tons of plastic waste enter the oceans every year, and the impact of microplastics (MPs) is much more worrying than visible contamination. The presence of these particles puts a strain on ecological dynamics, causing a significant impact on the health of marine organisms and affects humans due to the interconnection existing with the environment and the food chain. This review article examines the different ways in which MPs interact with marine life, the mechanisms that drive this pollution, and the cascading consequences for the health of organisms and ecosystems. It also highlights the critical links between plastic pollution and human health and underlines the urgency of a global and coordinated approach to address this growing crisis. Only through deeper understanding, increased awareness and collective action can we hope to mitigate the significant impacts of plastic pollution and ensure a sustainable future for oceans and our planet.

First Evidence of Microplastics Burden in Surface Waters of Budhabalanga Estuary, Chandipur, Eastern India: Potential Threat to Aquatic Ecosystem

Microplastic pollution has emerged as a new global concern because of its ubiquitous and persistent nature. Due to the rising use of plastics and discharge of plastic waste into coastal water bodies from point and non-point sources, the occurrence of microplastics along coastal ecosystems has become very prevalent. The current study is the first of its kind to evaluate the presence of microplastics in the surface water of river estuary along the coast of Odisha. Six GPS-fixed locations were used to collect the surface water samples from the Budhabalanga river estuary in Chandipur, Odisha, India. The samples were then subjected to further investigation to determine the types of microplastics present. The average microplastic abundance, according to our findings, ranged from 9.33 ± 2.11 items L-1 to 28.50 ± 2.77 items L-1. Microplastics come in a variety of colours and shapes, but the most prevalent kind is fibre-shaped and black in colour. The pollution load index of the sampling area was calculated to be 4.25 which is categorized under ecological risk level I. FE-SEM images clearly showed the topology of microplastics and ATR-FTIR analysis confirmed the presence of polyethylene, polypropylene, polyvinyl chloride (PVC), nylon, polycarbonate (PC), ethylene vinyl acetate (EVA) and polystyrene (PS) at sampling stations. Our investigation provides useful information that helps to reduce the ecological risk in habitats connected with contaminated sites, including both aquatic and terrestrial habitats.

Overview of monitoring methods and environmental distribution: Microplastics in the Indian Ocean

Microplastics are ubiquitous globally, posing a significant threat to human health. Notably, the Indian Ocean ranks second in microplastic contamination, emerging as a major source of pollution. In response to this risk, neighboring countries are actively addressing severe plastic pollution and deficiencies in waste management. Research on microplastics in Indian Ocean seawater commenced in 2016. This paper reviews the research status and trends, detailing sampling, extraction, and identification methods. We categorize 43 studies by trawl sampling and other techniques, summarizing microplastic abundance, size, shape, color, and polymer types. Microplastic distribution varies widely in the Indian Ocean, peaking in the East, West, and along the Indian coast. Fiber and debris microplastics are the most, the main colors are black, blue, white and transparent, and the polymer types are mainly PE, PP and PS. Oceanic convergence intensity affects microplastic distribution globally, intensifying accumulation. This study highlights the need for standardized microplastic sampling and analysis in Indian Ocean countries. Collaborative surveys and investigations are crucial to addressing pollution.

An Atmospheric Chemistry Perspective on Airborne Micro- and Nanoplastic Particles

Micro- and nanoplastic particles (MNPPs) are emerging pollutants with significant environmental impacts due to their persistence, increasing concentrations, and potential health risks. Most MNPP studies have focused on identifying, quantifying, and assessing their ecotoxicological impacts in water or soil. However, the atmosphere is crucial in transporting and chemically transforming MNPPs. Further, well-established aerosol particle characterization techniques are underutilized and inconsistently applied in existing atmospheric MNPP studies. This perspective synthesizes the existing literature and addresses future research needs unique to atmospheric MNPPs, highlighting the need to bridge the microplastics and atmospheric aerosol communities to better understand their sources, chemical transformations, transport mechanisms, as well as their health effects and ecological impacts, which differ from those in soil and water. Advancing research in these areas requires standardized methods and a multidisciplinary approach to comprehensively assess MNPP interactions across environmental compartments, providing essential insights into their environmental fate and risks.

Decoding the Plastic Patch: Exploring the Global Microplastic Distribution in the Surface Layers of Marine Regions with Interpretable Machine Learning

The marine environment is grappling with microplastic (MP) pollution, necessitating an understanding of its distribution patterns, influencing factors, and potential ecological risks. However, the vast area of the ocean and budgetary constraints make conducting comprehensive surveys to assess MP pollution impractical. Interpretable machine learning (ML) offers an effective solution. Herein, we used four ML algorithms based on MP data calibrated to the size range of 20-5000 μm and considered various factors to construct a robust predictive ML model of marine MP distribution. Interpretation of the ML model indicated that biogeochemical and anthropogenic factors substantially influence global marine MP pollution, while atmospheric and physical factors exert lesser effects. However, the extent of the influence of each factor may vary within specific marine regions and their underlying mechanisms may differ across regions. The predicted results indicated that the global marine MP concentrations ranged from 0.176 to 27.055 particles/m3 and that MPs in the 20-5000-μm size range did not pose a potential ecological risk. The interpretable ML framework developed in this study covered MP data preprocessing, MP distribution prediction, and interpretation of the influencing factors of MPs, providing an essential reference for marine MP pollution management and decision making.

Understanding the structure, distribution, and retention of nanoplastics in montmorillonite nanopore by multi-scale computational simulations

The interfacial adsorption, aggregation and deposition processes of nanoplastics (NPs) on clay mineral surfaces critically regulate their environmental mobility, transformation pathways, and ecotoxicological risks in aquatic ecosystems. A quantitative understanding of the nanoscale interfacial processes is essential. This study employs molecular dynamics (MD) simulations and density functional theory (DFT) calculations to elucidate the aggregation and deposition mechanisms of three types of NPs in their pristine and aged states in the nanopore solution of montmorillonite (Mt). In the wet environment, NPs tend to form aggregates in the nanopore and migrate in solution, increasing environmental risk, while in the dry environment, NPs are more likely to deposit on the basal surface to form larger aggregates, consequently reducing their mobility. Results show hydrophobic interactions play as the primary driving force for the aggregation of pristine NPs, and both hydrophilic and hydrophobic interactions contribute to the aggregation of aged NPs. Aged NPs exhibit stronger binding affinity to Mt through mechanism such as Ca²⁺ bridging and hydrogen bonding, compared to their pristine counterparts. DFT calculations further reveal the formation of hydrogen bonds between the hydroxyl groups of aged NPs and the tetrahedral oxygen atoms in Mt. Through atomic-level characterization of interfacial processes, this work establishes a predictive framework for NP environmental behavior by resolving migration dynamics and retention processes in nanopore water.

Unraveling the Impact of Microplastic-Tetracycline Composite Pollution on the Moon Jellyfish Aurelia aurita: Insights from Its Microbiome

Microplastics have emerged as a pervasive marine contaminant, with extreme concentrations reported in deep-sea sediments (e.g., 1.9 million particles/m2) and localized accumulations near Antarctic research stations. Particular concern has been raised regarding their synergistic effects with co-occurring antibiotics, which may potentiate toxicity and facilitate antibiotic resistance gene dissemination through microbial colonization of plastic surfaces. To investigate these interactions, a 185-day controlled exposure experiment was conducted using Aurelia aurita polyps. Factorial combinations of microplastics (0, 0.1, 1 mg/L) and tetracycline (0, 0.5, 5 mg/L) were employed to simulate environmentally relevant pollution scenarios. Microbiome alterations were characterized using metagenomic approaches. Analysis revealed that while alpha and beta diversity measures remained unaffected at environmental concentrations, significant shifts occurred in the relative abundance of dominant bacterial taxa, including Pseudomonadota, Actinomycetota, and Mycoplasmatota. Metabolic pathway analysis demonstrated perturbations in key functional categories including cellular processes and environmental signal transduction. Furthermore, microplastic exposure was associated with modifications in polyp life-stage characteristics, suggesting potential implications for benthic-pelagic population dynamics. These findings provide evidence for the impacts of microplastic-antibiotic interactions on cnidarian holobionts, with ramifications for predicting jellyfish population responses in contaminated ecosystems.

Assessing microplastic and nanoplastic contamination in bird lungs: evidence of ecological risks and bioindicator potential

Microplastics (MPs, 1 µm-5 mm) and nanoplastics (NPs, < 1 µm), collectively termed micro(nano)plastics (MNPs), are pervasive airborne pollutants with significant ecological risks. Birds, recognized as bioindicators, are particularly vulnerable to MNP exposure, yet the extent and risks of MNP pollution in bird lungs remain largely unexplored. This study assessed MP exposure in bird lungs of 51 species and NP exposure in the lungs of five representative species using laser direct infrared (LDIR) and pyrolysis gas chromatography-mass spectrometry (Py-GC-MS) techniques, respectively. The LDIR analysis revealed different degrees of MP contamination in bird lungs, with an average abundance of 221.20 items per species and 416.22 MP particles per gram of lung. Among 32 identified MP types, chlorinated polyethylene (CPE) and butadiene rubber (BR) predominated, with particles primarily in film and pellet forms, concentrated in the 20-50 μm size range. The polymer hazard index (PHI) indicated elevated ecological risks (levels Ⅲ or Ⅳ) in most bird lungs. Py-GC-MS detected nylon 66 (PA66), polyvinyl chloride (PVC), and polypropylene (PP) NPs at varying concentrations. Terrestrial, carnivorous, and larger-bodied birds exhibited higher MNP burdens. This study provides the first evidence of MNP contamination in bird lungs, highlighting their potential as bioindicators of airborne MNP pollution.

Impact of Heterosigma akashiwo on the environmental behavior of microplastics: Aggregation, sinking, and resuspension dynamics

Aggregation processes of microalgae have significant effects on the vertical distribution of microplastics (MPs) in the marine environment. This study explored how the harmful microalga Heterosigma akashiwo affects the aggregation and sinking characteristics of four types of MPs: low and high-density polyethylene (PE) spheres, and small and large polypropylene (PP) fragments. The aggregation of MPs was primarily driven by extracellular polymeric substances (EPS) rather than direct attachment to the cells, contributing to their sinking. The sinking of low-density PE spheres followed a logistic function, saturating at 28 % with a half-saturation time of 9 days. In contrast, small PP fragments sank minimally (under 2 %) and large PP fragments showed almost no sinking, indicating the varying impacts of MP density and size. The sinking velocity of the MP aggregates was significantly lower for low-density PE spheres (0.63 mm∙s-1) than for high-density PE spheres (0.81 mm∙s-1), despite no significant differences in aggregate size or MP particle number. This result may suggest that low-density MPs could potentially affect marine carbon cycle. Furthermore, no clear evidence was found for the resuspension of the settled aggregates due to bacterial decomposition under dark and cold conditions. As the first experimental study to explore the aggregation, sinking, and resuspension of different MPs in the presence of H. akashiwo, these findings, when integrated with field observations and modeling studies, provide valuable insights for predicting MP distribution in marine environments.

Significant microplastic accumulation and burial in the intertidal sedimentary environments of the Yellow River Delta

Estuarine intertidal habitats provide a dynamic and distinctive environment for the transport of microplastics, yet their migration and accumulation in these areas remain poorly understood. Herein, the spatial distribution patterns of microplastics in the estuarine sedimentary environment of the Yellow River Delta were investigated across elevation and depth gradients. Compared to the subtidal and supratidal zones, the estuarine intertidal zone exhibited the highest microplastic abundance in sediment (1027 ± 29 items/kg). Sediment cores revealed that the highest microplastic abundance occurred at a depth of 5-10 cm. The evolution of microplastic size and morphology characteristics with sediment depth indicates vertical transport of microplastics in estuarine sediments. The strong correlations between organic matter, silt content, and microplastics abundance in estuarine sediments suggested significant impacts of tidal hydrodynamics and sediment characteristics on microplastic migration processes. Estimates indicated that microplastic burial in the deeper sediments (638.7 tons in the 5-30 cm layer) was 1.96 times greater than that in the upper layers. Distinct variations in the carbonyl index across habitats suggested that tidal-induced dynamic redox conditions in the intertidal zone promoted both biotic and abiotic aging processes of microplastics. This study provides new insights into the environmental behavior and long-term fate of microplastics in estuarine intertidal sedimentary environments.

Molecular-level insights of microplastic-derived soluble organic matter and heavy metal interactions in different environmental occurrences through EEM-PARAFAC and FT-ICR MS

The interactions between microplastic-derived dissolved organic matter (MPs-DOM) and heavy metals (Cu, Pb, and Cd) regulate the complex environmental transport behavior of pollutants in terrestrial and aquatic environments. In this study, fluorescence excited emission matrix spectroscopy combined with parallel factor analysis (EEM-PARAFAC) and electrospray ionization coupled Fourier transform ion cyclotron resonance mass spectrometry (ESI FT-ICR MS) were employed to investigate the complexation mechanism of MPs-DOM with heavy metals, as well as the effects of different environmental occurrences of MPs-DOM on the transport behaviors of heavy metals in saturated porous medium. The findings demonstrated that MPs-DOM, particularly humic-like substances containing aromatic structures and various oxygen functional groups, could form stable complexes with heavy metals. This interaction significantly altered the transport capacity of Pb and Cu in saturated porous media. It is noteworthy that MPs-DOM in the free and deposited states in the environment may have markedly disparate effects on heavy metal transport. MPs-DOM in the free state may facilitate the co-migration of heavy metal ions in porous media, thereby enhancing the mobility of heavy metals. In contrast, sedimentary-state MPs-DOM can retain heavy metals in porous media and inhibit their migration through complexation with them.

Non-degradable microplastic promote microbial colonization: A meta-analysis comparing the effects of microplastic properties and environmental factors

Microplastics serve as favorable substrates for microbial colonization, promoting biofilm formation, which consequently facilitates the accumulation of pollutants and aids in the degradation of microplastics. Hence, obtaining a thorough comprehension of the factors that influence the development of microplastic biofilms is imperative. Nevertheless, there have been conflicting responses concerning biofilm formation in conjunction with microplastic characteristics and environmental conditions. As a result, a meta-analysis was conducted to quantitatively evaluate the impact of microplastic properties and environmental factors on biofilm formation. The findings indicated that the type and size of microplastics significantly influence biofilm growth on their surfaces. Non-degradable microplastics, particularly polyvinyl chloride (PVC) and polystyrene (PS), exhibited higher surface biomass and biodiversity in microplastic-attached biofilms compared to degradable microplastics. Furthermore, it was observed that smaller microplastics were more conducive to microbial colonization. Model selection and correlation analysis further indicated that the environment acts as a substantial predictor of biofilm formation, with prolonged exposure significantly enhancing microbial diversity within biofilms as opposed to short-term exposure. Moreover, meta-regression analysis illustrated a positive correlation between biofilm biomass and alpha-diversity with temperature, while salinity exhibited a negative correlation in diverse aquatic settings. Notably, the ease of biofilm formation on microplastics was observed to be greater in oceans compared to lakes, yet biofilms exhibited a higher diversity increment in lakes than their oceanic counterparts. In the long-term growth of biofilms, initial biomass and diversity are influenced by microplastic characteristics and the surrounding environment, although environmental influences may assume more significance as time progresses.

An analysis of human impact on sandy coasts of the Costa Rican Pacific

Increased human activities on sandy beaches have significantly impacted ecosystems. This study aims to determine whether beaches with higher tourism and human activities exhibit greater impact on various ecological indicators compared to less-visited beaches. Ecological monitoring was performed across three sandy beaches, where sand samples were collected during three visits. Sediment characteristics, macrofauna presence, crab burrows abundance, and solid waste were analyzed. Fourteen benthic macrofauna taxa, 1209 crab burrows, and 7645 intertidal organisms were recorded. Notably, 98.8 % of the solid waste consisted of plastic items. Differences in organic matter, carbonates, the number of crab burrows, and macrofauna were observed, indicating that increased tourism and human activity influence these ecological indicators. These findings represent an initial step toward more rapid and comprehensive ecological monitoring of beaches, contributing to coastal environmental management and decision-making.

A Pan-European study of the bacterial plastisphere diversity along river-to-sea continuums

Microplastics provide a persistent substrate that can facilitate microbial transport across ecosystems. Since most marine plastic debris originates from land and reaches the ocean through rivers, the potential dispersal of freshwater bacteria into the sea represents a significant concern. To address this question, we explored the plastisphere on microplastic debris (MPs) and on pristine microplastics (pMPs) as well as the bacteria living in surrounding waters, along the river-sea continuum in nine major European rivers sampled during the 7 months of the Tara Microplastics mission. In both marine and riverine waters, we found a clear niche partitioning among MPs and pMPs plastispheres when compared to the bacteria living in the surrounding waters. Across this large dataset, we found that bacterial community structure varied along the river salinity gradient, with plastisphere communities exhibiting almost complete segregation between freshwater and marine ecosystems. We also described for the first time a virulent human pathogenic bacterium (Shewanella putrefaciens), capable of infecting human intestinal epithelial cells, detected exclusively on MPs in riverine environments. Our findings indicate that salinity is the main driver of plastisphere communities along the river-to-sea continuum, helping to mitigate the risk of pathogens transfer between freshwater and marine systems.

Microplastic pollution and risk assessment around coral reefs of the Eastern Part, Thailand

Microplastic pollution, driven by widespread plastic use and poor management, poses a growing threat to marine ecosystems, particularly coral reefs. This study examined microplastic pollution and risk assessment in the surface waters around coral reefs in the Eastern Economic Corridor (EEC) in Eastern Part, Thailand. Microplastics were widespread, with concentrations ranging from 0.05 to 0.54 items/m3 and an average of 0.22 ± 0.16 items/m3. The distribution varied among the reefs, with over 80% of the microplastics exceeding 3 mm in size. The most common shapes were fibers and sheets, with polypropylene (31.25%), polyethylene (19.35%), and PET (18.45%) being the predominant polymers. Si-Chang Island had the highest microplastic abundance, likely due to pollution from residential, industrial, and tourism activities. Risk assessments indicated that Lan Island faced a higher risk of microplastic contamination compared to other areas. While the overall abundance of microplastics was relatively low, the potential impact on coral reefs warrants concern. Periodic monitoring, removal, and mitigation efforts are recommended to address this issue.

Assessing the efficacy of electrocoagulation process for polypropylene microplastics removal from wastewater: Optimization through TOPSIS approach

Emerging contaminants, microplastics in particular, pose a substantial risk to human health and the environment. Conventional treatments fail to incorporate focused approaches to eliminate them. This research comprehensively evaluated the effectiveness of electrocoagulation as a techno-economic method for removal of microplastics from water. The research meticulously investigated the effects of various electrode combinations composed of SS (stainless steel) and Al (aluminium) with possible combination as Al-Al, Al-SS, SS-Al and SS. Out of the various combinations considered, it was discovered that the Al-Al coupling demonstrated exceptional efficacy of 95.54% in the elimination of microplastics, with a concurrent reduction in energy consumption. The initial pH value was found to be a crucial parameter, as evidenced by the highest removal efficacy of 92.80% observed at a near neutral alkaline pH of 8. However, in order to determine economic efficacy, it is necessary to consider additional variables including energy consumption, electrode utilisation, and post-treatment conductivity. In order to address the intricacy presented by a multitude of parameters and criteria, it is critical to employ multi-criteria decision-making tools such as Technique for Order of Preference by Similarity to Ideal Solution (TOPSIS), which has demonstrated efficacy in real-world scenarios. The optimal electrolyte concentration, as determined by TOPSIS analysis, is 0.5 g/L. Furthermore, the TOPSIS analysis underscored the superior performance of punched hollow cylindrical electrode. The investigation conducted a thorough assessment of the impact of time period and concluded that a 100-min interval offers the highest efficacy in removing microplastics. At an input concentration of 2 g/L, this enhanced optimized system demonstrated outstanding competence in removing microplastics of three different sizes 45-90 μm, 90-180 μm, and 180-355 μm, with the removal efficiencies of 89.80%, 93.12%, and 94.08%, respectively. The current study introduces a pragmatic and exceptionally efficient approach to tackle the urgent problem of microplastic pollution in aquatic ecosystems.

Exposure to polystyrene nanoplastics induces lysosomal enlargement and lipid droplet accumulation in KGN human ovarian granulosa cells

Given the ubiquitous presence of plastic products in daily life, human exposure to nanoplastics (NPs) is inevitable. Previous studies have suggested that exposure to polystyrene nanoplastics (PSNPs) may contribute to reproductive disorders; however, the underlying mechanism remains elusive. The goal of this study was to investigate the impact of PSNPs on KGN human ovarian granulosa cells. KGN cells were exposed to varying concentrations of PSNPs (0-400 μg/mL) for 48 h; alterations in cell survival and morphology were assessed to elucidate potential toxic effects. PSNPs were shown to enter KGN cells. Exposure to PSNPs did not induce significant changes in cytotoxicity, Calcein intensity, or active mitochondria levels in KGN cells. However, PSNP exposure did induce a dose-dependent increase in cytoplasmic vacuoles and an increase in total lysosome area and in the numbers of lipid droplets in KGN cells. Our findings provide compelling evidence that PSNPs can penetrate cell cytoplasm and induce toxicity, resulting in an elevation in the numbers of lysosomes and lipid droplets. This may represent one mechanism by which PSNPs exert damage on the reproductive system.

Adsorption of emerging pollutants utilizing chitosan derivatives: Recent advances and future perspective

Globalization resulted in technological advancement, and urban population growth. Consequently, pollution emerged as an imminent risk to the survival of all species on Earth. Consequently, on a worldwide basis, sustainability become a major issue for legislators. Inconsistent impacts on both human and animal growth and wellness triggered health issues associated with water contamination through the chronic toxicants. Micropollutants' pollution prompted severe concerns due to their malignant, indestructible, and accumulative properties. The elimination of these toxins from industrial processes has become one of the most significant ecological challenges. A variety of both organic and simulated sorbents are available, and each of these have unique benefits. In the recent years, chitosan and its composite materials have been attempted and have been proven to be applicable for the resolution of many challenging issues related to water pollution. Among various notable benefits of adsorption processes, economic viability, ease of access, and adherence to environmental regulations are notable. Considering the above-mentioned issues, the article targets the assessment of chitosan and its composite materials for relevant environmental applications. Accordingly, the article aims to examine the performance, advantages, and disadvantages of chitosan as an adsorbent.

Microplastics in freshwater and marine ecosystems: Occurrence, characterization, sources, distribution dynamics, fate, transport processes, potential mitigation strategies, and policy interventions

Most of the literature on microplastics (MPs) focuses on freshwater or terrestrial ecosystems, frequently overlooking their interconnections with the marine environments. This oversight is worrying given that both ecosystems serve as primary pathways for the introduction of MPs into marine environments. This review synthesizes existing literature on MPs in both freshwater and marine ecosystems across all six continents. The most commonly produced plastic polymers in industry are polyethylene (36 %) and polypropylene (21 %), and studies revealed that these two materials are the most abundant in aquatic ecosystems. Primary and secondary MPs originate from a range of sources including land-based disposal, the ocean, airborne deposition, wastewater treatment facilities, automobiles, pharmaceuticals and personal care products, synthetic textiles, and insect repellents. Notably, secondary MPs, which are formed from the breakdown of larger plastic items comprise approximately 69-81% of marine debris, especially in urbanized, densely populated areas. The inconsistencies of the methodologies (sampling, extraction, and quantification) and the units employed for result presentations are part of the major limitations in MPs research. Environmental phenomena such as heteroaggregation, weathering, adsorption, leaching, and fragmentation are the major factors influencing the behavior, fate, and degradation process of plastic particles. The physicochemical properties of plastic polymers, such as density, crystallinity, as well as bioturbation, meteorological forces, and wind actions, including currents, waves, and tides, are responsible for biofouling, aggregation, sinking into the bottom sediment, resuspension, and the vertical, horizontal, and spatiotemporal distributions and transport of MPs. The potential solutions to mitigate plastic pollution are grounded in the 3Rs framework, which includes reducing production and consumption, advancing the biotechnological, chemical and microbial development of degradable polymers, promoting reusable plastic products with lower environmental impacts over their lifetimes, and recycling waste into new products. The regulatory policies on single-use plastics commonly involve permanent bans and financial penalties for violators. In addition, nations such as the United States, the Netherlands, and northern Europe have introduced economic incentives to encourage the return of reusable materials to reduce plastic waste and the resulting envrionmental pollution.

Influence of anthropogenic pressures on the microplastic distribution in the riverine-estuarine environment: A source-apportioning approach

In this study, the influence of anthropogenic pressures, namely fishing practices and illicit and unregulated wastewater and solid waste discharge, on the microplastic distribution in India's Kallada River - Ashtamudi riverine-estuarine environment was investigated. To better characterize microplastic pollution in the Estuary, it was subdivided into cage farming, open fishing, solid waste dumping, and other zones that receive wastewater from residential areas. A source-apportioning approach was utilized to delineate the possible sources of pollution and conducted a risk assessment attributed to exposure to microplastic pollution. The results suggest that the solid waste dumping zone exhibited the highest microplastic abundance, followed by the cage farming zone. Fiber-shaped microplastic particles were abundant in cage farming and open fishing zones, while films dominated the solid waste dumping zone. FTIR analysis revealed that polyamide and polyester, widely used for regional fishing nets, were dominant in cage farming and open fishing zones, while polyamide, polystyrene, and polyethylene were dominant in solid waste dumping zones. Other zones impacted by the unregulated discharge of domestic wastewater exhibited an abundance of polyester and polyethylene microplastics. Source apportionment studies using a modified approach incorporating morphological and chemical characteristics of microplastics revealed that fishing nets/ropes contributed to 35.48 % of microplastic pollution, followed by single-use plastics and plastic bags/covers (19.35 % each), textile fabrics (16.13 %) and personal care products (9.68 %). A risk assessment analysis considering microplastic abundance and polymer hazard revealed that the solid waste dumping zone and the cage farming zone pose a medium risk to microplastic pollution. These findings highlight the role of fishing practices and solid waste dumping on the microplastic pollution in the riverine-estuarine environment.

Polystyrene Microplastics and Cadmium Drive the Gut-Liver Axis Through the TLR4/MyD88/NF-κB Signaling Pathway to Cause Toxic Effects on Broilers

Nowadays, the risk of oral intake of microplastics (MPs) and cadmium (Cd) by poultry is high. In some industrially polluted areas, the chicken feed samples contain 9.60 × 102 ± 1.09 × 102 MPs per kilogram (mean ± std) in wet weight, and the Cd content in chicken feed has been detected to reach up to 5.61 mg/kg. But scholars still focus more on the toxic effects of MPs and Cd on the liver and intestines of aquatic animals. There are few studies that use poultry as research animals and consider these two organs as an integrated system to investigate the toxicity of MPs and Cd on the gut-liver axis and the mechanisms of inflammation. Therefore, in this research, broilers were used as experimental subjects, and experimental models were established by single or combined exposure of MPs (100 mg/L) and Cd (140 mg/kg) to explore the effects of MPs and Cd on the intestinal mucosae and liver of broilers, as well as the mechanisms behind these toxic effects. In this study, the degree of adverse effects (decreased expression of tight junction proteins, changes in intestinal morphology, abundance and diversity of intestinal flora, liver inflammation) caused by the single exposure group was higher than that of the combined exposure group. The results showed that MPs and Cd induced intestinal damage and liver inflammation in broilers by interfering with the TLR4/MyD88/NF-κB pathway and intestinal flora homeostasis. The toxicity of combined exposure was lower than that of single exposure.

The impact of building uses on microplastic pollution and its implications for environmental education

Rivers are major sources of marine microplastics. To investigate the influence of building use on river microplastic pollution, this study focused on the Chongqing section of the main stream of the Yangtze River. Surface water and sediment microplastic samples were collected and analyzed alongside building use data to explore the relationship between microplastic abundance and building use at different spatial scales. The results showed that: (1) The abundance of microplastics in surface water and sediment in the Chongqing section of the Yangtze River exhibited an inverse distribution pattern. In the upper reaches, the central urban area of Chongqing showed significantly higher microplastic levels in surface water (6,811 ± 3,101 n/m ³) compared to the lower reaches, confirming the direct input effect of high-intensity human activities. The accumulation of microplastics in sediment was greater in the northeastern section of Chongqing compared to the lower reaches (89.6 ± 69 vs. 45.4 ± 28 n/kg), indicating a hydrodynamic-driven sedimentation lag effect. (2) The influence of building use on microplastic abundance in surface water was significantly scale-dependent. Industrial buildings within a 2 km buffer zone explained up to 61.16% of the observed variance, suggesting cross-medium migration through atmospheric sedimentation and sewage pipe network. (3) Compared to land use types, building uses dominate the abundance distribution of microplastics in surface water at larger buffer radius (1-2 km), indicating that high-intensity human activities have a greater impact on spatial differentiation of microplastic pollution. It is recommended to implement hierarchical control measures along the Chongqing section of the Yangtze River. A 2-km ecological buffer zone is set up in industrial agglomeration areas to strictly supervise wastewater discharge from plastic products enterprises. Rainwater bioretention facilities are built within 1 km of densely populated areas to intercept microplastics from domestic sources, such as laundry fibers. This study explores the mechanism by which building use affects river microplastic pollution, providing valuable insights for microplastics control in large river basins worldwide.

Promotion of microplastic degradation on the conjugative transfer of antibiotic resistance genes in the gut of macrobenthic invertebrates

Microplastics and antibiotic resistance genes are two new pollutants in water environments, and they have potential risks to human health and ecological safety. On the basis of the accumulation of pollutants and microorganisms in sediment, macrobenthic invertebrates are considered as potential practitioners of microplastic degradation and antibiotic resistance gene (ARG) transfer. However, whether microplastic degradation can affect ARG transfer in aquatic environments, especially in the gut of macrobenthic invertebrates, remains unclear. In this study, we demonstrated that microplastics including polyethylene terephthalate (PET), polyvinyl chloride(PVC), polyamide (PA), polystyrene (PS), polypropylene (PP), polyethylene (PE), and polyurethane (PU), and ARGs including tetA, sul1, sul2, and sul3 were widely distributed in sediment and benthic invertebrates in Nansi lake. The distribution of ARGs was related to the number and size of microplastic particles. In particular, it was found for the first time that the content of ARGs corresponding to individual particles was linearly and negatively correlated with the size of microplastics. The results of animal feeding experiments showed that microplastic degradation in the gut of Chironomidae larvae could promote the conjugative transfer of ARGs. The underlying molecular mechanism was SOS response. This study provides a new method for the analysis of the interaction effect of multiple pollutants in freshwater environments.

Microplastic contaminant adsorption by graphene oxide layer

The increasing prevalence of microplastics in water sources poses significant threats to both human health and environmental sustainability. Bisphenol A (BPA) and polyethylene terephthalate (PET), two hazardous microplastic contaminants, are known to cause endocrine disruption and other health risks. This study investigates the potential of graphene oxide (GO) as an efficient adsorbent for the removal of these contaminants through detailed molecular interaction analysis. The adsorption efficiencies of GO were quantitatively assessed, demonstrating strong binding affinities of ∆G = - 9.50 kcal/mol for BPA and ∆G = - 6.90 kcal/mol for PET. The adsorption process is primarily governed by π-π stacking interactions between the aromatic structure of the microplastics and the polycyclic surface of GO, with additional contributions from hydrogen bonding and van der Waals forces. Computational simulations revealed consistent binding across specific active sites on the GO surface, indicating minimal variation in adsorption performance. These findings highlight the potential of GO-based filtration systems for large-scale water treatment applications, offering a promising approach to mitigating microplastic contamination and ensuring safer water supplies. These findings highlight the potential of GO-based filtration systems for large-scale water treatment applications, offering a promising approach to mitigating microplastic contamination and ensuring safer water supplies. Future research should focus on optimizing GO-based filtration techniques and exploring their long-term environmental impact.

Fate, source, and ecological risk of microplastic in the surface sediment of the Beibu Gulf, the Northern South China sea

A large-scale investigation of the surface sediments in the Beibu Gulf was conducted in this study to reveal the contamination characteristics of microplastics in the surface sediments of the Beibu Gulf. The results showed that the abundance of microplastics ranged from 12.91 to 251.69 items/kg, dry weigh (DW), with an average abundance of 84.34 ± 51.85 items/kg (DW). The highest abundance of microplastics was found in the estuary of northwestern Hainan, influenced by the West Guangdong Coastal Current. The overall distribution of abundance showed a decreasing trend from nearshore to offshore. Microplastics in the surface sediments were predominantly in the form of fiber (87.51%), with a predominant white color. The polymer of microplastics in surface sediment was primarily polyester (43.43%). The main sources of microplastics include household items, textile products, food packaging, fishing activities, industrial activities, sewage discharges, and biochemical materials, of which household products and textile products are the most important sources. The results of the risk evaluation showed that the sediment of Beibu Gulf was contaminated with microplastics (pollution load index >1) and the polymer risk was at low to extremely high levels. The high abundance of microplastics and highly toxic polymers resulted in increased ecological risk. These findings highlight the urgent need to implement timely and effective measures to reduce the impact of intensive human activities on microplastic pollution. At the same time, the study data provide an important reference for future ecotoxicological investigations, pollution management strategies and microplastic policy development.

Effect of chlorination and ultraviolet on the adsorption of pefloxacin on polystyrene and polyvinyl chloride

During the water treatment process, chlorination and ultraviolet (UV) sterilization can modify microplastics (MPs) and alter their physicochemical properties, causing various changes between MPs and other pollutants. In this study, the impact of chlorination and UV modification on the physicochemical properties of polystyrene (PS) and polyvinyl chloride (PVC) were investigated, and the adsorption behavior of pefloxacin (PEF) before and after modification was examined. The effect of pH, ionic strength, dissolved organic matter, heavy metal ions and other water environmental conditions on adsorption behavior was revealed. The results showed that PS had a higher adsorption capacity of PEF than PVC, and the modification increased the presence of O-containing functional groups in the MPs, thereby enhancing the adsorption capacity of both materials. Chlorination had a more significant impact on the physicochemical properties of MPs compared to UV irradiation within the same time period, leading to better adsorption performance of chlorination. The optimal pH for adsorption was found to be 6, and NaCl, sodium alginate and Cu2+ would inhibit adsorption to varying degrees, among which the inhibition caused by pH was the strongest. Chlorination and UV modification would weaken the inhibitory effect of environmental factors on the adsorption of PEF by MPs. The main mechanisms of adsorption involved electrostatic interaction and hydrogen bonding. The study clarified the effects of modification on the physicochemical properties of MPs, providing reference for subsequent biotoxicity analysis and environmental protection studies.