Search Results (963)

Background: Plasticisers with endocrine-disrupting potential are ubiquitous and associate with obesity and type-2 diabetes (T2D), with higher levels reported in the Middle East. However, no data exist on plasticiser exposure in Bahrain where T2D affects 15% of the national population. Methods: An observational exploratory study in T2D (n = 60) and controls (n = 96), analysed for 24 h urinary plasticiser levels (liquid chromatography tandem mass spectrometry (LC-MS/MS)). Correlation and generalised linear model (GLM) analyses were employed to examine associations. Results: T2D were older (p < 0.001), had higher body mass index (BMI) (p < 0.001), body weight (p < 0.001) and glycosylated haemoglobin A1c (HbA1c) (p < 0.001). Correlation analysis revealed differences in inter-plasticiser, and plasticiser and biomarker relationships, with loss or reversal in T2D compared to controls. Mono-n-butyl phthalate (MnBP) levels were higher in T2D (p = 0.04); however, regression analysis revealed significant association with age. The GLM analyses demonstrated marked differences in the levels of mono(3-carboxypropyl) phthalate (MCPP), mono(2-ethyl-5-carboxypentyl) phthalate (MECPP), monoethyl phthalate (MEP) and bisphenol S (BPS), with lower levels in T2D versus controls (B = −3.41, p = 0.01; B = −5.28, p < 0.001; B = −8.94, p < 0.001; B = −6.09, p = 0.006, respectively); however, these contrasts appeared to be substantially confounded by BMI and/or age. Positive influence of age and negative influence of BMI when observed across the full dataset were generally reversed in T2D. Levels were complementary to those previously reported for the Middle East. Conclusions: The study indicates the phthalate levels in Bahrain are elevated though complementary to studies of phthalates in the Middle East; within those levels, the study indicates differential exposure–response relationships with plasticisers, influenced by age and BMI, in those with T2D compared to healthy controls. Full article

This study produces high-purity nano-silica from corn straw ash (biomass power plants) using an alkaline fusion-derived sodium silicate solution. CO₂ replaces traditional acids in the carbonation reaction, enabling high extraction yield (93.11%). The process addresses the gap in directly utilizing combustion ash for such high-purity silica. Key optimal conditions identified were 5 M aq. HCl concentration, NaOH fusion reagent, 1:1.2 mixing ratio, 3 M aq. NaOH solvent, and 12 h ripening. The resulting nano-silica achieved 92.73% purity, 10–50 nm particle size, 270 × 10⁻⁵ m³/kg dibutyl phthalate (DBP) absorption, 55.9916 m²/g specific surface area, 6.38% loss on drying (LOD), and 6.69% loss on ignition (LOI). These properties meet national standards for premium, loosely structured nano-silica. This method provides an economical and effective silicon source, reducing costs and offering economic-environmental benefits. Full article

Di-2-ethylhexyl phthalate (DEHP) is a widely used plasticizer with recognized sex-dependent neurotoxicity. However, research on adult neurotoxicity is scarce, especially in females. In this study, adult female rats were exposed to a high-dose experimental model of DEHP (500 mg/kg/day) for 28 days to systematically evaluate hippocampal neurotoxicity. We found that DEHP exposure significantly impaired spatial learning and memory. Transcriptomics revealed enrichment in oxidative stress, complement activation, and neurodegenerative pathways. Specifically, cellular and molecular analyses showed that DEHP induced mitochondrial structural defects and elevated markers of oxidative damage (8-OHdG and 3-NT). While the upregulation of mitochondrial and antioxidant proteins (COX4I1, SOD2, and NQO1) indicated an attempted compensatory response, it remained inadequate to restore redox homeostasis. Under this neurotoxic microenvironment, DEHP triggered early neurogenesis, marked by the upregulation of SOX2 and DCX; however, NeuN levels remained unchanged, suggesting that this compensatory effort failed to expand the mature neuronal population. Ultimately, these pathological processes culminated in neurodegeneration, as evidenced by reduced synaptic proteins, suppressed Olig1/2 expression, and increased tau phosphorylation. Collectively, this study provides a comprehensive neurotoxic profile of DEHP in adult female rats, filling a research gap in this field. Full article

Microplastics (MPs) are considered to be dominant agents responsible for serious contamination in environmental and biological systems. Despite a huge increase in research on these contaminants, there are still considerable uncertainties and progress to be made on the exposure pathways of biological systems, modes of detection, and toxicity assessments. Therefore, developing a critical review of MPs is crucial due to growing evidence of their harmful effects on human health. In the current review, we aim to emphasize the potential toxic effects of MPs on different biological systems in humans, the mechanisms of their toxic effects, and gaps in our knowledge on risk assessment. Importantly, we focus on the risks posed by MPs for fetuses and child health. To ensure methodological rigor, the current review follows the PRISMA guidelines, explicitly detailing the literature search strategy and inclusion/exclusion criteria. The present review summarizes potential sources of MP generation, exposure pathways, quantitative analyses of dietary exposure, estimated daily intake, particle/leachate toxicity evidence, detection in different human organs, and potential toxic effects. MPs cause toxicity in several biological systems in humans, such as the gastrointestinal, nervous, hepatic, endocrine, respiratory, and reproductive systems. In addition, these particles are known to cause oxidative stress, alter metabolism, and affect gut microflora and gastrointestinal functions. Importantly, the current review also discusses the challenges encountered in conducting risk assessments for MPs and the approaches for counteracting these challenges. Finally, the review concludes by recommending future research directions in terms of counteracting the toxic effects of MPs on human health. Full article

Endocrine-disrupting chemicals (EDCs), widespread in aquatic environments, interfere with endocrine function in organisms and threaten ecosystem stability. Rotifers, critical live feed for marine fish, shrimp, and crab larvae, link EDC-induced reproductive impairment to marine ecosystem stability and aquaculture sustainability. This PRISMA-compliant review synthesizes key findings, consequences, and gaps in EDC–rotifer reproductive toxicity research. Traditional EDCs (heavy metals, per- and polyfluoroalkyl substances (PFASs), phenols, phthalate esters, polybrominated diphenyl ethers (PBDEs), and steroid hormones) and emerging EDCs (disinfection byproducts, microplastics, pharmaceutical metabolites) induce distinct reproductive harm—e.g., Hg²⁺ shows extreme toxicity (24 h LC₅₀ = 4.51 μg L⁻¹ in Brachionus plicatilis), BDE-47 damages ovaries, and microplastics cause transgenerational delays. Rotifer species and exposure duration affect sensitivity (e.g., BDE-47: 96 h LC₅₀ = 0.163 mg L⁻¹ vs. 24 h LC₅₀ > 22 mg L⁻¹ in B. plicatilis). Oxidative stress is a universal mechanism, and combined EDC exposure produces context-dependent synergistic/antagonistic effects. EDC-induced impairment reduces rotifer population density, alters structure, and propagates through food webs, threatening aquaculture and biodiversity; transgenerational toxicity (e.g., 4-nonylphenol: F₁ inhibition 28% vs. 12% in F₀) weakens resilience. This review supports EDC risk assessment, with gaps including long-term low-concentration data, transgenerational mechanisms, EDC–microbiome interactions, and emerging PFAS toxicity—priorities for future research. Full article

Over the last 15 years, mixture risk assessment for food xenobiotics has evolved from conceptual discussions and simple screening tools, such as the Hazard Index (HI), towards operational, component-based and probabilistic frameworks embedded in major food-safety institutions. This review synthesizes methodological and regulatory advances in cumulative risk assessment for dietary “cocktails” of pesticides, contaminants and other xenobiotics, with a specific focus on food-relevant exposure scenarios. At the toxicological level, the field is now anchored in concentration/dose addition as the default model for similarly acting chemicals, supported by extensive experimental evidence that most environmental mixtures behave approximately dose-additively at low effect levels. Building on this paradigm, a portfolio of quantitative metrics has been developed to operationalize component-based mixture assessment: HI as a conservative screening anchor; Relative Potency Factors (RPF) and Toxic Equivalents (TEQ) to express doses within cumulative assessment groups; the Maximum Cumulative Ratio (MCR) to diagnose whether risk is dominated by one or several components; and the combined Margin of Exposure (MOET) as a point-of-departure-based integrator that avoids compounding uncertainty factors. Regulatory frameworks developed by EFSA, the U.S. EPA and FAO/WHO converge on tiered assessment schemes, biologically informed grouping of chemicals and dose addition as the default model for similarly acting substances, while differing in scope, data infrastructure and legal embedding. Implementation in food safety critically depends on robust exposure data streams. Total Diet Studies provide population-level, “as eaten” exposure estimates through harmonized food-list construction, home-style preparation and composite sampling, and are increasingly combined with conventional monitoring. In parallel, human biomonitoring quantifies internal exposure to diet-related xenobiotics such as PFAS, phthalates, bisphenols and mycotoxins, embedding mixture assessment within a dietary-exposome perspective. Across these developments, structured uncertainty analysis and decision-oriented communication have become indispensable. By integrating advances in toxicology, exposure science and regulatory practice, this review outlines a coherent, tiered and uncertainty-aware framework for assessing real-world dietary mixtures of xenobiotics, and identifies priorities for future work, including mechanistically and data-driven grouping strategies, expanded use of physiologically based pharmacokinetic modelling and refined mixture-sensitive indicators to support public-health decision-making. Full article

The widespread use of antibiotics, combined with pervasive exposure to diverse environmental media, has intensified the global challenge of antibiotic resistance. Accumulating evidence reveals that beyond direct antibiotic pressure, residual non-antibiotic chemicals—despite lacking intrinsic antibacterial activity—can significantly promote the enrichment and spread of antibiotic resistance genes (ARGs) in farmland soils through indirect mechanisms such as inducing oxidative stress, altering microbial community structure, and enhancing both vertical and horizontal gene transfer. To address this issue, the present study investigates the influence of representative non-antibiotic contaminants commonly detected in agricultural environments—including pesticides (e.g., Omethoate, imidacloprid, and atrazine), industrial pollutants (e.g., PCB138, BDE47, benzo [a] pyrene, 2,3,7,8-tetrachlorodibenzo-p-dioxin [TCDD], and benzene), plastic-associated compounds (e.g., Polyethylene trimer, phthalates, and tributyl acetylcitrate), and ingredients from personal care products (e.g., triclosan and bisphenol A)—on ARG transmission dynamics. Leveraging bioinformatics resources such as the CARD database, PDB, AlphaFold, and molecular sequence analysis tools, we identified relevant small-molecule ligands and macromolecular receptors to construct a simulation system modeling ARG transfer pathways. Molecular docking and molecular dynamics (MD) simulations were then implemented, guided by a Plackett–Burman experimental design, to systematically evaluate the impact of individual and co-occurring pollutants. The resulting data were processed using advanced analytical tools, and MD trajectories were interpreted at the molecular level across three scenarios: an unperturbed (blank) system, single-pollutant exposures, and dual-pollutant combinations. By integrating computational simulations with machine learning approaches, this work uncovers the “co-selection” effect exerted by non-antibiotic chemical residues in shaping the environmental resistome, thereby providing a mechanistic and scientific basis for comprehensive risk assessment of agricultural non-point source pollution and the development of effective soil health management and antimicrobial resistance containment strategies. Full article

Microplastics and nanoplastics (<5 mm and <1 μm, respectively) are emerging contaminants now ubiquitous across environmental matrices and increasingly recognized for their impacts on human health. These particles commonly adsorb or contain endocrine-disrupting chemicals—such as bisphenol-A and phthalate additives—that together trigger complex biological responses. This review examines the central role of oxidative stress in mediating the toxicity of microplastics and associated endocrine disruptors across multiple organ systems. We discuss mechanisms including cellular uptake, reactive oxygen species generation, mitochondrial dysfunction, impairment of antioxidant defenses, and activation of key signaling pathways. Organ-specific effects on reproductive health, cardiovascular function, hepatic metabolism, gut barrier integrity, and neurological systems are highlighted. Current evidence strongly supports oxidative stress as a pivotal mechanism linking microplastic exposure to systemic toxicity, underscoring important implications for public health policy and clinical intervention strategies. Full article

Although cancer biology has advanced considerably, the impact of environmental toxins on carcinogenesis remains underrecognized and scattered across disciplines. Evidence increasingly shows that chronic exposure to a broad range of toxins—including persistent organic pollutants, heavy metals, pesticides, phthalates, microplastics, and fine particulate matter (PM2.5), which significantly contributes to cancer initiation, progression, and treatment resistance. This review synthesizes mechanistic, molecular, and epidemiological findings from 2015 to 2025, identified through systematic searches of PubMed, Scopus, Web of Science, and MeSH. Key pathways include oxidative stress-mediated DNA damage, epigenetic reprogramming (DNA methylation, histone modifications, miRNA dysregulation), hormone receptor modulation, chronic inflammation, immune evasion, and tumor microenvironment remodeling. Case studies of benzene, arsenic, aflatoxins, pesticides, and microplastics detail exposure routes, molecular targets, and associated cancers, highlighting significant public health risks. Ongoing debates persist regarding safe exposure thresholds, latency periods, and the effects of mixed toxin exposures. The review also highlights recent innovations in environmental oncology, including AI-based predictive models, CRISPR screens for susceptibility genes, organoid/3D models, green chemistry interventions, and real-time exposure monitoring, which provide mechanistic insight and inform early detection and personalized prevention strategies. Additionally, regional data gaps, particularly in low- and middle-income countries, indicate the need for stronger interdisciplinary collaboration. By integrating molecular mechanisms, epidemiology, and technological advances, this review offers a comprehensive framework for understanding toxin-induced carcinogenesis and guiding future research, public health policy, and preventive strategies. Full article

Associations between prenatal exposure to phthalates, bisphenols and their mixtures and early childhood allergic conditions and asthma were examined. Five hundred and fifty-six mother–child pairs from the Alberta Pregnancy Outcomes and Nutrition (APrON) cohort participated. Urine samples collected from mothers during the second trimester of pregnancy were analyzed for phthalates and bisphenols. A child health questionnaire, completed by mothers when children were 12, 24, and 36 months, asked whether children had experienced allergic conditions (i.e., food allergies, eczema, rash) or asthma. In single-chemical models, associations varied with child age. Higher prenatal concentrations of mono-benzyl phthalate (MBzP) were associated with lower odds of eczema at 12 months. At 36 months, higher mono-methyl phthalate (MMP) was associated with increased odds of eczema, whereas higher mono-carboxy-octyl phthalate (MCOP) was associated with reduced odds. Higher prenatal MCOP was also associated with higher odds of rash at 12 months, and higher MMP was associated with higher odds of rash at 36 months. Higher bisphenol S (BPS) was associated with increased odds of asthma at 12 months but decreased odds of eczema and rash at 36 months. Sex-specific effects were also noted. In multi-chemical exposure least absolute shrinkage and selection operator (LASSO) models, several phthalate metabolites and BPS were selected as the best predictors of eczema and rash at 36 months of age. Bayesian kernel machine regression (BKMR) mixture models suggested that BPS was the most important chemical in predicting eczema in children at 36 months, while MMP and BPS were the most important chemicals in predicting rash at 36 months. Prenatal exposure to certain phthalate metabolites and BPS predicted allergic conditions and asthma in young children, with patterns varying by age and sex. Prenatal exposure to these chemicals may differentially influence immune development and contribute to the development of early-life allergic conditions, with potentially sex-specific susceptibility. Full article

The rubber industry uses phthalates as plasticizers in technical rubber goods due to their excellent compatibility, low volatility and cost-effectiveness. Growing concerns over their environmental and health impact have driven the search for sustainable alternatives. Bio-based plasticizers offer a promising solution due to their renewable nature, non-toxicity and biodegradability. This study explores the feasibility of replacing a conventional petroleum-based Di-Iso-Nonyl Phthalate (DINP) with a bio-based phthalate-free plasticizer, Aurora PHFree, in Nitrile Butadiene Rubber (NBR) compounds filled with semi-reinforcing carbon black N660. Aurora PHFree achieves similar processing behavior, cure characteristics, and mechanical properties as well as aging performance by using only half of the amount by weight of DINP. This efficiency is attributed to the improved plasticizing effects, which enable polymer chain mobility, without altering the overall crosslink density, as well as the enhanced dispersion of the carbon black (CB) fillers of the rubber compounds. This research supports the development of more sustainable rubber materials and contributes to reducing the dependence on fossil-based materials while maintaining high-quality standards. Full article

Cnidium monnieri is a valuable functional plant with significant potential for green pest control. However, its large-scale application is limited by its low and uneven seed germination in fields. To determine the factors that affect the germination of C. monnieri seeds, we examined its seed viability, germination percentage and germination speed index (GSI) after seed-coat treatments, water permeability, and the types and activity of endogenous inhibitory substances in C. monnieri seeds. The results indicated that the seed viability of C. monnieri is 95%, but the germination percentage was relatively low (12.60%). Seed coat removal significantly enhanced both the germination percentage and the GSI, but had no significant effect on water absorption rate. Moreover, ethyl acetate extracts completely inhibited the seed germination of the control non-dormant Brassica rapa subsp. rapa, while diethyl ether extracts showed moderate suppression, and petroleum ether extracts exhibited the weakest effect. And the three endogenous inhibitory substances, i.e., dibutyl phthalate, 2,6-di-tert-butylphenol, and 2,4-di-tert-butylphenol significantly reduced the seed germination, seedling height and root length of B. rapa, indicating their high inhibitory efficiency on seed germination. Our study demonstrates that the mechanical barrier of the seed coat and the presence of potent endogenous germination inhibitory substances are the key factors influencing the germination of C. monnieri seeds. These findings provide a theoretical basis for promoting seed germination of C. monnieri, which enhance its application value as functional plant for green pest control. Full article

Phthalic acid esters (PAEs) are ubiquitous pollutants with reported endocrine-disruption and multiplex toxic activities in a wide range of invertebrate and vertebrate animals. In the present review, the molecular and physiological effects of phthalate exposure on invertebrates, as well as less characterized vertebrates such as amphibians, reptiles, and mammals, are thoroughly examined. PAEs induce a series of adverse effects, such as reproductive toxicity, oxidative stress, immune system impairment, and neuroendocrine disruption. The effects can extensively vary depending on the species, developmental stage, and environmental conditions, ranging from impaired hormone signaling, developmental malformations, and thyroid impairment in amphibians and reptiles to lipid metabolism disturbances and epigenetic changes in mammals. This review will place particular emphasis on transgenerational effects, mixture toxicity, and chronic low-level exposure. By integrating evidence from in vivo, in vitro, and omics studies, this review defines areas of knowledge gaps and the necessity to integrate these taxa in integrated ecological risk assessments, as well as regulatory policy. Full article

This study investigates the influence of dynamic perturbation on gelation behavior in a model colloidal system composed of hydrophobic silica particles dispersed in dioctyl phthalate. Contrary to the prevailing assumption that gelation is independent of oscillatory frequency, particularly at small strain amplitudes within the linear viscoelastic regime, our results reveal a pronounced dependence of gelation dynamics on the frequency of applied shear. In contrast, variations in strain amplitude and shear rate amplitude exert minimal effects. This observed behavior deviates significantly from classical gelation theory, which typically predicts frequency-independent rheological properties at the gel point. The results uncover a previously unrecognized viscoelastic phenomenon in soft colloidal materials, wherein microstructural rearrangements near the gelation threshold appear to be modulated by the timescale of mechanical excitation. As a result, traditional criteria for identifying gelation become less effective. The liquid-to-solid transition in these colloidal systems aligns more closely with the physics of particle jamming, rather than polymer network formation. Full article

Coated fabrics featuring plasticised poly(vinyl chloride) (p-PVC) and thermoplastic polyurethane (TPU) coatings are widespread in fashion collections. These materials pose significant conservation challenges due to their production and chemical variability, coupled with issues of rapid deterioration. Despite their prevalence and instability, systematic research on their composition and ageing behaviour remains limited, as most studies rely mainly on infrared spectroscopy and cover a small number of cases, which cannot fully capture their chemical complexity. This knowledge gap represents a pressing issue, as it hampers the development of well-informed conservation strategies. This research addresses this gap by investigating a representative set of twenty-five historical and contemporary fabrics from the 1990s onwards, coated with aromatic and aliphatic polyester-based TPUs, as well as phthalate- and terephthalate-plasticised PVCs. Samples were characterised using a multi-analytical approach combining optical microscopy, infrared spectroscopy, pyrolysis–gas chromatography/mass spectrometry, and X-ray fluorescence spectroscopy. This integrated strategy provided unprecedented detail on the chemical variability of p-PVC and TPU-coated fabrics, enabling the identification of primary components, additives, degradation products, and mixed compositions. This study underscores the value of multi-technique analysis to capture the complexity of such coated fabrics, providing essential knowledge for further research and development of effective conservation strategies for fashion collections. Full article