Search Results (928)

Microplastics (MPs) are emerging contaminants that have been detected in human blood and tissues, raising concerns regarding systemic exposure and potential health effects. Internal MP burden mitigation techniques, nevertheless, are yet largely unexplored. We evaluated whether oral administration of chitosan derived from Procambarus clarkii (PCC) could reduce circulating MPs in humans via gastrointestinal sequestration in this pilot-controlled study. 11 healthy adults received PCC supplementation (0.8 g/day) for 15 days, while 10 matched controls received a placebo. Using stereomicroscopy, scanning electron microscopy (SEM), and micro-Fourier transform infrared spectroscopy (µFTIR), blood MP concentrations were quantified and characterised according to size, shape, and polymer type. At baseline, MPs were found in every subject. Following PCC supplementation, mean MP concentrations decreased from 1.84 ± 0.28 µg/mL to 1.34 ± 0.20 µg/mL (−26.3%, p < 0.01, paired analysis). The control group observed no significant differences. While polymer-resolved analysis consistently indicated reductions across major polymer classes, size-resolved analysis indicated preferential reductions in intermediate particle fractions (11–50 µm). The circulating MPs’ estimated mean residence time (MRT) was 58 ± 28 days. These findings provide preliminary evidence that chitosan-based gastrointestinal sequestration could potentially reduce the systemic MP burden in humans. Full article

Emerging contaminants (ECs) encompass a wide spectrum of pollutants, from endocrine disruptors and persistent organic pollutants to microplastics and pharmaceutical residues. These contaminants often exhibit distinct chemical and physical properties compared with traditional pollutants and potentially pose risks to human health, especially as they have become pervasive in environmental and biological systems. ECs can also pose a significant threat to cardiovascular health, as they may target the ion channels that are critical to regulating cardiac excitability and contraction. However, the impact of ECs on the cardiovascular system, particularly on cardiac ion channels, remains elusive. In this review, we aim to provide an overview of the knowledge base concerning the impact of emerging contaminants on cardiac ion channels, with an emphasis on the effects of these compounds on cardiac excitability, contractility, and overall cardiovascular function. We first outline the structural and functional characteristics of ion channels, along with how these transmembrane proteins regulate cardiac physiology. Subsequently, we detail how typical ECs directly or indirectly interact with various ion channels—including sodium, calcium, potassium channels, as well as ion transporters and exchangers. Special attention is given to studies that have demonstrated cell-level responses or examined how pollutant concentration and chemical structure affect the modulation of ion channels. This review compiles recent research reports to elucidate the mechanisms by which EC exposure disrupts cardiac ion channels, potentially leading to cardiotoxicity. Moreover, the insights gathered herein illuminate critical research gaps and outline essential directions for future investigations. Full article

This paper systematically reviews losartan, a hypertension pharmaceutical compound that is one of many newly identified emerging contaminants in water. Worldwide use of pharmaceuticals continues to grow, and losartan has been identified as a contaminant that frequently accumulates in aquatic systems as a result of this global increase in use. The paper presents systematic reviews on the environmental occurrence, physicochemical characteristics, analytical methods of detection, and remediation techniques associated with losartan contamination. Losartan is often detected at levels of ng L⁻¹–µg L⁻¹ in wastewater systems, surface water and marine ecosystems, very effectively demonstrating the inadequacies of existing conventional wastewater treatment facilities, which are typically capable of removing only 20–70% of the contamination, with this variability largely attributed to differences in hydraulic/solids retention times, operational conditions, influent organic load, and the limited microbial acclimatization to recalcitrant pharmaceutical compounds. Emerging remediation technologies demonstrate the potential for removal efficiencies of >90% include hybrid systems, advanced electrochemical processes, new improved adsorption systems, and novel material for adsorption. However, there are still considerable barriers to progress, including excessive energy use, high operating costs, and perhaps most concerning, potentially toxic transition products generated by partial degradation. Furthermore, the literature review identified key literature gaps: lack of specific regulations, absence of full-scale studies, and inconsistencies in by-product toxicity assessments. The conclusion of this review is that to achieve worldwide water security and sustainability of aquatic resources, effective mitigation of the environmental risks associated with losartan requires combined approaches comprising innovative technologies, comprehensive ecotoxicological investigations, and improved collaboration between scientists, policymakers, and industry. Full article

Conventional wastewater treatment systems cannot effectively eliminate micropollutants such as contaminants of emerging concern (CECs). These compounds, even at trace levels, are persistent or pseudo-persistent, bioaccumulative, and potentially harmful to ecosystems and human health. Advanced oxidation processes (AOPs), based on the in situ generation of highly reactive oxygen species, have emerged as promising solutions. Peroxyacetic acid (PAA) has gained attention due to its strong oxidizing capacity, broad antimicrobial activity, environmentally benign by-products, and compatibility with different activation methods. This review provides an updated and integrated synthesis of recent advances in PAA-based AOPs for the degradation of major CEC groups, including pharmaceuticals, personal care products, pesticides, and industrial chemicals, as well as for the oxidative modification of microplastics (MPs). The review discusses several strategies for PAA activation and critically discusses removal efficiency, underlying mechanisms, and current limitations, emphasizing the gap between pollutant transformation and complete mineralization. Furthermore, the article highlights a key research need, which is the assessment of the toxicity of transformation products and their validation under realistic conditions. Overall, this review provides insight into the potential and challenges of PAA-based AOPs for sustainable water treatment. Full article

Galaxolide (HHCB), a synthetic polycyclic musk widely used as a fragrance ingredient in numerous personal care and household products, has raised increasing environmental concern due to its persistence, bioaccumulation potential, and widespread occurrence in aquatic environments. In this context, the need to establish a concrete ecotoxicological risk profile, defining both the toxicity levels and the mechanisms of action, is fundamental. For this reason, in the current study, we selected the freshwater leech Hirudo verbana as a suitable in vivo model to assess the HHCB ability in inducing inflammatory response and oxidative stress. By means of morphological, immunofluorescence, and molecular analyses, HHCB was shown not only to affect the leech innate immune response by modulating angiogenesis and macrophage-like cells recruitment, but also to promote the expression of enzymes involved in the antioxidant response, such as superoxide dismutase (SOD), glutathione S-transferase (GST) and catalase (CAT). Overall, these findings indicate that HHCB could induce significant physiological alterations, with sub-lethal concentrations able to affect immune homeostasis. Furthermore, this study supports the use of alternative invertebrate models to better understand the possible harmful effects of emerging contaminants. Full article

In the Rhône-Mediterranean-Corsica (RMC) basin (130,000 km², 14 million inhabitants), groundwater intended for human consumption has been monitored for decades. These data, stored in the SISE-EAUX database, were cross-referenced with information from the CORINE Land Cover (CLC) database, which describes human land use, in order to identify potential relationships between pollutant pressure and water quality at the basin scale, as well as the mechanisms specific to each geographical area. Data processing was carried out in three stages. The 27,741 water samples from 2825 abstraction points were assigned to the 224 groundwater bodies (GWBs), and average values for each physicochemical and bacteriological parameter were calculated for each GWB. At the same time, the percentage of surface area covered by each land use type was also extracted at the scale of each GWB. This information was subjected to statistical processing, first separately and then jointly, using principal component analysis (PCA) and hierarchical clustering of parameters. A redundancy in the information carried by the quality parameters, previously observed at the scale of administrative regions (four to five times smaller), is confirmed at this new analysis scale, paving the way for data consolidation and a more synthetic representation. Fecal contamination primarily concerns areas with crystalline lithology and, secondarily, a few karst sectors, with other livestock farming regions being less contaminated. Higher nitrate concentrations are observed in cereal-growing regions and areas of intensive row cropping, while metal concentrations are lower in the drier Mediterranean climate zone than under the more humid continental climate. Structuring factors, notably altitude and climate, emerge at the RMC basin analysis scale, which was not the case at the scale of administrative regions. These structuring factors influence land use, soil type, and hydrological regimes alike, which explains the correlations between the information contained in the CLC and SISE-EAUX databases. Full article

Plasticizers enhance polymer flexibility and durability, yet many leach into aquatic environments as persistent contaminants. Phthalate esters (PAEs), the most widely used plasticizers, are of particular concern due to weak polymer binding, high mobility, and documented ecological and human health risks. Conventional analytical techniques such as GC–MS and HPLC provide high accuracy but rely on expensive instrumentation and laboratory-based analysis, limiting rapid and on-site monitoring. In response, electrochemical approaches have emerged as promising alternatives for both the detection and removal of PAEs, especially when coupled with sustainable and environmentally benign materials. This review summarizes recent advances in the electrochemical sensing and treatment of PAEs, highlighting green electrode materials, eco-friendly functionalization strategies, sensing mechanisms, and analytical performance. Key challenges, including matrix effects, environmental interferences, and gaps between laboratory studies and real-sample applications, are critically discussed. Sustainable electrochemical removal strategies—such as advanced oxidation, reductive degradation, and hybrid material-based processes—are also evaluated. Overall, integrating greener materials, molecular imprinting, and data-driven signal enhancement supports the development of robust, field-deployable, and environmentally responsible PAE monitoring and mitigation technologies. Full article

As an emerging tire wear-derived environmental contaminant, 6PPD-quinone (6PPDQ) has raised significant concerns regarding its neurotoxic potential, particularly for children exposed to recycled tire crumb rubber in playgrounds. However, the molecular mechanisms by which 6PPDQ influences neurological disorders such as epilepsy remain poorly understood. In this study, we employed an integrative framework combining network toxicology, bulk analysis of human epileptic brain tissues, Mendelian randomization, and molecular dynamics simulations to elucidate these mechanisms. Our findings, validated through CETSA-WB and SPR, identify 6PPDQ as a direct ligand that binds to and stabilizes neuronal TP53. Through a synergistic double-hit mechanism, 6PPDQ directly engages the TP53 pathway while simultaneously triggering microglial interleukin-6 secretion. These converging pathways lead to the suppression of the master antioxidant regulator Nrf2, resulting in glutathione depletion, excessive reactive oxygen species accumulation, and exacerbated neuronal damage under excitotoxic stress. Experimental validation using glutamate-induced HT22 cell models and microglia–neuron crosstalk systems confirmed that targeting the TP53/Nrf2 axis or scavenging ROS significantly attenuates 6PPDQ-induced neurotoxicity. Our findings highlight critical risks to pediatric neurological health posed by tire-derived contaminants and identify the TP53/Nrf2 axis as a promising therapeutic target. Furthermore, this work provides a robust scientific basis for refining risk assessment frameworks and developing regulatory strategies to mitigate environmental exposure to 6PPDQ. Full article

Plastics are now ubiquitous in the environment, in this, the “Plasticene” era. Microplastics (MPs) and Nanoplastics (NPs) are emerging contaminants of global concern. This systematic review, registered on PROSPERO and conducted according to PRISMA guidelines, investigated the presence, distribution, and characteristics of MPs in tap water (TW) worldwide, and estimated the population’s Estimated Daily Intake (EDI) by age group, including pregnant women. A comprehensive search across PubMed, Scopus, Web of Science, and Cochrane identified 22,650 records, of which 8 studies were included. MPs were detected in treated water (TW) in the studies included in this review, although the currently available evidence remains limited. Calculated EDIs were highest in children aged 6 months to 3 years (up to 39 MPs/kg bw/day), followed by pregnant women (up to 14.96 MPs/kg bw/day), reflecting differences in water intake per body weight. These estimates must be interpreted as indicative, estimated by methodological variability among studies. The widespread presence of MPs in TW calls for standardized methods, improved treatments, and thorough monitoring to assess risks and protect public health. Full article

Klebsiella pneumoniae is a member of the six highly virulent and antibiotic-resistant bacterial pathogens group (ESKAPE) and poses a significant threat to public health due to its ability to cause both hospital and community-acquired infections. Recent health concerns have emerged about heat-tolerant bacterial contamination in hospital settings, particularly those associated with infant formula preparation. This study aims to evaluate the heat survival of 10 clinical K. pneumoniae strains in infant formula and to investigate the correlation between heat tolerance and the presence of heat shock resistance genes, particularly the clp family of ATPases. Ten strains of K. pneumoniae were exposed to heat at 55 °C for 30 min in infant formula. We assessed their survival rates and determined their D-values. Additionally, we screened for the presence of clpC family genes across representative strains. A wide variation in heat tolerance was observed among the strains. Strain 1701 (ST247, capsular antigen profile O3:K1) exhibited the highest heat tolerance, with a D-value of 12.9 min at 55 °C. The other strains exhibited moderate-to-low heat tolerance. Notably, strain 1701 was the only one that contained the clpC2 gene, suggesting a potential association between the clp gene family and heat resistance. Our results indicate that specific heat shock resistance genes, such as clpC2, may be associated with enhanced heat tolerance observed in K. pneumoniae strains. These findings highlight the potential role of heat shock proteins in bacterial persistence within neonatal healthcare environments. Full article

As anodized aluminum components are increasingly deployed in high-power optical and precision industrial systems operating in non-vacuum environments, their outgassing behavior has emerged as a critical material reliability concern. In contamination-sensitive optical assemblies, released volatiles can accumulate on nearby surfaces, leading to haze formation, scattering, and progressive optical degradation. The porous anodic oxide layer retains water, hydrogen, dyes, and processing residues that are released under thermal, photonic, and environmental stresses typical of industrial operation. While most qualification data remain vacuum-centric, equivalent evaluation frameworks for ambient environments are limited. This review analyzes surface-driven desorption mechanisms relevant to non-vacuum systems and provides practical guidance for material and process engineers by evaluating mitigation strategies across the anodizing process chain, including fine-grain substrate selection, controlled anodizing with nickel acetate sealing, post-bake stabilization, and alternative dense coatings such as electroless nickel, sol–gel films, and Acktar. The analysis underscores the need for non-vacuum-specific qualification standards to support reliable material selection and long-term system performance. Full article

Nanocoating technology has emerged as a transformative strategy for enhancing the functional properties of food materials, packaging substrates, and food contact surfaces. This review explores the role of biopolymers as coating materials in nanocoating applications, with a particular focus on the food sector. Inorganic nanomaterials such as silver, titanium dioxide, zinc oxide, and silicon dioxide have been extensively studied for their antimicrobial, photocatalytic, and barrier-enhancing properties; however, concerns regarding toxicity and regulatory compliance continue to limit their direct food contact applications. Biopolymer-based nanocoatings present a safer and more sustainable alternative, offering biodegradability, biocompatibility, and GRAS (Generally Recognized as Safe) status. Key application areas reviewed include edible coatings for fresh and minimally processed fruits, vegetables, meat, cheese, and mushrooms; nanocoating of paper-based and polymeric packaging materials to improve gas barrier, mechanical, moisture resistance, and antimicrobial properties; nanocoating of glass or metal containers and active packaging systems, and nanocoating of food contact surfaces to prevent biofouling and microbial contamination. Recent studies confirm that biopolymer-based nanocoatings, particularly those based on chitosan, cellulose nanofibers, and alginate, can significantly extend shelf life, reduce weight loss, retard oxidation, and maintain sensory quality. Migration of nanomaterials from coatings into food systems is identified as a key safety concern. Challenges including scalability, coating durability, substrate compatibility, and incomplete toxicological profiling are critically discussed. This review underscores the need for standardized testing protocols, comprehensive regulatory frameworks, and continued research into durable, food-grade biopolymer nanocoatings as viable replacements for conventional synthetic coating systems in food preservation and packaging. Full article

Plastic-derived chemical additives, including bisphenols, phthalates, perfluoroalkyl substances (PFAS) and microplastic-associated contaminants, are now recognised as widespread environmental toxins that measurably affect endocrine signalling, oxidative balance, inflammation and metabolic homeostasis. Continuous exposure through food contact materials, consumer products, and environmental media raises concerns about long-term health effects. An increasing number of epidemiological and experimental studies are linking these exposures to metabolic disorders, reproductive dysfunction, neurodevelopmental alterations, and increased disease susceptibility throughout the lifespan. This narrative review summarises the latest evidence on the toxicological mechanisms of these compounds, with a focus on endocrine disruption, redox imbalance, reproductive impairment, thyroid hormone dysregulation and epigenetic modifications induced by plastic-derived chemicals. Literature was identified through searches of major scientific databases, including PubMed, Scopus, and Web of Science. Reference screening was also employed to complement these searches and ensure comprehensive coverage of vertebrate and invertebrate models. The inclusion criteria encompassed studies published within the last 10 years, focusing on experimental, experimental, and translational research. The review evaluates phytochemicals such as polyphenols, flavonoids, isoflavones, catechins, sulforaphane, and chlorogenic acid as natural agents that can mitigate the biological effects of plastic-derived toxicants. These compounds exhibit antioxidant, anti-inflammatory, and receptor-modulating properties that counteract pathways disrupted by BPA, phthalates, and PFAS. Experimental studies have demonstrated that phytochemicals can modulate oestrogen receptor activity, enhance detoxification systems, reduce oxidative biomarkers and mitigate epigenetic and metabolic alterations induced by micro- and nanoplastics. Emerging nutritional evidence suggests that diets high in polyphenols may reduce the biological impact of plastic-derived contaminants within the body, rather than reducing exposure itself. This effect appears to be especially relevant during sensitive developmental periods, such as the prenatal, early postnatal and adolescent stages. Full article

Polycyclic aromatic hydrocarbons (PAHs) are ubiquitous combustion-derived contaminants that represent a significant cross-cutting threat to human, animal, and environmental health. Viewed through an explicit One Health lens, this review shows how the shared combustion sources, evolutionarily conserved toxicological mechanisms, and food-web linkages connecting environmental contamination to wildlife and human exposure justify an integrated, cross-domain approach to PAH risk assessment and management. PAHs are generated predominantly through incomplete combustion of organic materials and are globally distributed through atmospheric transport, aquatic runoff, and food-web transfer, persisting in soils and sediments for decades. The present review synthesizes current knowledge on PAHs through an explicit One Health lens, examining shared sources, environmental fate, and convergent health effects across species and health domains, while also highlighting the need to move beyond the classical US EPA priority PAHs to include high-molecular-weight PAHs (>302 Da), alkylated homologues, and transformation products such as oxy- and nitro-PAHs. Common pathways such as dietary intake of grilled and smoked foods, inhalation of contaminated air, and occupational exposure create parallel toxicological burdens in both human and wildlife populations, particularly through genotoxic mechanisms mediated by aryl hydrocarbon receptor (AhR) activation and CYP1A1/CYP1B1-catalyzed bioactivation to reactive diol epoxides. The resulting DNA adduct formation links environmental PAH exposure to carcinogenicity, reproductive toxicity, immunosuppression, and developmental impairment across vertebrate species with remarkable mechanistic consistency. Wildlife, especially fish, marine mammals, and seabirds, serve as critical sentinels for environmental PAH contamination, while simultaneously facing direct health impacts on immune function, reproduction, and population viability. Vulnerable human populations, including children, subsistence communities, occupational workers, and residents near combustion-intensive industries, bear disproportionate burdens reflecting underlying environmental justice concerns. Integrated intervention strategies encompassing source control, dietary exposure reduction, site remediation, and coordinated biomonitoring are urgently needed. By incorporating emerging PAH classes with distinct persistence, trophic behavior, and toxicological potency, the One Health paradigm provides a more comprehensive conceptual framework for modern environmental surveillance, food safety, and integrated risk assessment, recognizing that the health of terrestrial and aquatic ecosystems is inseparable from that of the animals and humans within them. Full article

Several issues about the quality of urban surface waters, such as the Detroit River, are becoming a concern due to the increasing detection of emerging contaminants. Although the emerging contaminants are present in low concentrations—ranging from nanograms per liter (ng/L) to micrograms per liter (µg/L)—these raise serious concerns about long-term effects on human health and aquatic ecosystems, particularly when left unregulated. Municipal wastewater effluent has been reported as one of the major pathways for these emerging contaminants. Most treatment plants are not equipped to effectively remove many emerging contaminants, allowing them to enter surface waters. To assess the presence of these emerging contaminants, water samples were collected during the summer from sites near the upstream and downstream of the Detroit wastewater treatment plant. Among the sixteen emerging contaminants analyzed were pharmaceuticals, personal care products, and pesticides. Ten of these, such as sucralose, caffeine, acetaminophen, and bisphenol A, were detected at both locations, with concentrations ranging from 42 to 4100 ug/L. Elevated contaminant levels found downstream can come from various sources, such as agricultural runoff, leachate from landfills, overland flow, and Combined Sewer Overflows (CSOs). Furthermore, local pharmaceutical usage patterns and the effectiveness of our treatment facilities play significant roles in the contaminant concentrations we see. Tracking emerging contaminants both upstream and downstream of treatment plants is crucial for pinpointing vulnerable watersheds. This vital information enables us to establish a solid baseline and craft effective strategies to lower contaminant levels. Full article