Search Results (9,047)

Bordetella petrii is an environmentally versatile Gram-negative bacterium with hydrocarbon-degrading capabilities, yet its genetic and metabolic characteristics remain poorly characterized. This study investigated the genomic features of a PAH-degrading Bordetella petrii strain P003 isolated from contaminated oil in Kuwait using bioinformatic approaches. The genome of B. petrii P003 was sequenced and analyzed for genomic islands, comparative genomics, and PAH degradation pathways. The draft genome assembly of B. petrii P003 was 5,011,660 bp with 49 contigs and 68.67% GC content. It contained 4687 coding sequences, 5 rRNAs, and 56 tRNAs. Prediction of genomic islands (GIs) revealed that strain P003 possessed 99 GIs, whereas the reference B. pertii DSM 12,804 had 58 unique GIs. Comparative genomics showed 279 locally collinear blocks with the reference strain. The P003 genome encoded multiple genes involved in PAH, naphthalene, and benzoate degradation pathways, including an 8-gene PAH operon (pht4, ph2, pht5, pht3, pcaG, pcaH, nahAb/nagAb/ndoA/nbzA). We found that pcaG and pcaH encode the enzymes responsible for the breakdown of PAH, protocatechuate 3,4-dioxygenase, alpha and beta subunits (EC: 1.13.11.3). The genomic analysis of B. petrii P003 provides insights into its PAH degradation capabilities and potential for bioremediation applications. The strain possesses an expanded repertoire of aromatic compound degradation genes compared to reference strains, suggesting enhanced metabolic versatility for degrading environmental pollutants. Full article

In recent years, accelerated industrialization has made water pollution a major challenge, bisphenol pollutants being one of the most typical examples. Advanced oxidation processes (AOPs) based on peroxymonosulfate (PMS) activation have been applied in environmental remediation due to their broad applicability and high pollutant removal efficiency. The key to AOPs lies in developing low-cost, highly active catalysts. This study utilized waste biomass of baijiu distillers’ grains (DSGs) as precursor to prepare biochar materials for bisphenol pollutant removal. Through high-temperature pyrolysis at 900 °C for 2 h in the presence of NaCl and KCl as activator, biochar-based materials (BC-x) were prepared, which possessed advantageous features of large specific surface area and high nitrogen doping content. When applied for typical bisphenol pollutant removal, the selected BC-900 biochar exhibited almost 100% bisphenol AF (BPAF) removal efficiency after a 30 min adsorption and following a 5 min PMS activation process under reaction conditions of 200 mg L⁻¹ of BC-900, 200 mg L⁻¹ of PMS, and 20 mg L⁻¹ of BPAF. Reactive species of sulfate radicals (SO₄⦁⁻), hydroxyl radicals (⦁OH) and singlet oxygen (¹O₂) were responsible for BPAF degradation, among which ¹O₂ played the major role. Further toxicity prediction of the BPAF degradation intermediate products implied the low ecological risk of the constructed BC-900/PMS catalytic system for BPAF removal. The findings in this study may provide useful guidance for waste biomass conversion and organic contamination remediation in water. Full article

Humans spend a substantial proportion of their time indoors, where exposure to environmental pollutants such as radon gas and particulate contaminants in household dust is common. While radon is a well-established risk factor for lung cancer, household dust may serve as a reservoir for a complex mixture of indoor and outdoor pollutants. However, the biological effects of such exposures, particularly under sequential conditions, remain incompletely understood. This study aimed to investigate the cytotoxic and genotoxic effects of sequential exposure to household dust extract followed by indoor radon using human lung adenocarcinoma (A549) cells as an in vitro model. Household dust samples from upper northern Thailand were extracted and applied to cells, followed by controlled radon exposure. Cellular responses were evaluated using cell viability assays, cytokinesis-block micronucleus (MN) formation assays, and Western blot analysis of oxidative stress-related (Nrf2/HO-1), DNA damage-related (γ-H2AX), autophagy-related (LC3), and inflammatory-related (IL-6) protein expression. Exposure to household dust extract was associated with reduced cell viability and increased MN formation, while radon exposure alone produced relatively modest effects under the present conditions. Sequential exposure to household dust extract followed by indoor radon was associated with increased oxidative stress-related responses and elevated DNA damage than either treatment alone under the present experimental conditions. A trend toward autophagy-related responses was also observed, and the overall findings may indicate possible combined biological responses under sequential exposure conditions. These findings suggest that sequential exposure may be associated with changes in oxidative stress-related pathways, DNA damage responses, and autophagy-related processes in this in vitro model. However, the results should be interpreted with caution as they are derived from a single cancer cell line and there are limitations to the in vitro exposure model. Further studies using additional cell models and in vivo systems are warranted to further clarify the potential biological and human health relevance of these findings. Full article

This study aimed to elucidate the impact of environmental factors on the efficacy of epigallocatechin gallate (EGCG) in inhibiting acrylamide formation and to clarify the role of the 3-aminopropionamide (3-APA) pathway in this process. Asparagine–glucose and 3-APA model systems were employed for the investigation. The results revealed that EGCG exerted a pronounced, condition-dependent inhibitory effect on acrylamide formation during the Maillard reaction. The maximum inhibition rate of 91% was observed at 180 °C and pH 6.0 without metal ions, while alkaline conditions, excessive heating, and Fe³⁺ markedly weakened the inhibitory capacity of EGCG. In the 3-APA model, a positive correlation (R² = 0.9111) was found between acrylamide generation and EGCG oxidation, and the key o-quinone-derived adduct was identified as an indirect evidence for EGCG oxidation. Collectively, the redox state of EGCG, which is highly susceptible to food processing conditions, may modulate its anti-acrylamide activity. These findings provide valuable mechanistic insights for the rational application of EGCG to mitigate acrylamide contamination in thermally processed foods. Full article

Contamination of soils by petroleum hydrocarbons is a long-standing environmental and public-health issue in oil-producing areas. This study compared natural attenuation and biostimulation using date palm waste for the remediation of crude-oil-contaminated soil collected near the North Oil Company facilities in Kirkuk, Iraq (0–10 cm). The experiment was conducted as an outdoor semi-field, pot study under a rain shelter over 160 days, using 2 kg of soil per pot; palm waste (<5 mm) was added at 500 g per pot in the biostimulation treatment. This study provides preliminary semi-field evidence from Iraq using locally available date palm waste under semi-arid outdoor conditions. Gas chromatography with flame ionization detection (GC–FID) was used to measure total petroleum hydrocarbons (TPH; C8–C40), while gas chromatography–mass spectrometry (GC–MS) was used to measure 18 priority polycyclic aromatic hydrocarbons (PAHs), grouped into 2–3- and 4–6-ring categories; the microbial number was measured as colony-forming units (CFU). Biostimulation reduced TPH from 38,751 mg kg⁻¹ at day 0 to 9205 mg kg⁻¹ by day 40 (76.2% reduction), which was later sustained to 4717 mg kg⁻¹ by day 160 (87.8% reduction). Natural attenuation showed relatively slower and smaller reductions over the same period. Full article

Micro- and nanoplastics (MNPs) are ubiquitous environmental contaminants detected in numerous human tissues, yet epidemiological evidence on MNPs exposure and neurodevelopmental outcomes in children has not been systematically evaluated. We aimed to systematically identify, appraise, and synthesize observational evidence on this association in children aged 0–18 years. Six databases were searched on 19 February 2026 following the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) 2020 guidelines (PROSPERO: CRD420261328979). Risk of bias and certainty of evidence were assessed using Joanna Briggs Institute (JBI) checklists and the Grading of Recommendations, Assessment, Development and Evaluations (GRADE) framework. Three studies met the inclusion criteria (all published in 2025, China; n = 30–5670; two studies with probable population overlap), addressing behavioral, cognitive, and neurological outcome domains, encompassing 56 associations across 14 outcomes. Each study showed a uniform direction of association (higher MP exposure was associated with poorer outcomes); however, probable population overlap between Dong and Zheng precludes interpretation of this pattern as independent cross-study replication. All outcomes were rated Very Low certainty under GRADE; meta-analysis was not performed. Although experimental evidence supports biological plausibility, no causal inferences can be drawn in the absence of independent replication, and the field remains at the stage of hypothesis generation. Future studies should prioritize prospective longitudinal designs, spectroscopic exposure confirmation, and standardized neurodevelopmental outcomes. Full article

Dioxins are highly persistent organic pollutants that exist in soil. Their hydrophobic and lipophilic characteristics facilitate long-term stability, posing high risks to the ecosystem and human health. They can be released by different sources, such as the incineration of waste materials, industrial activities, the production of pesticides, and natural or accidental events like forest fires. Dioxins accumulate in food chains and persist in the environment because dioxins are less volatile as well as chemically stable and can strongly bind to organic matter. The accumulation and persistence of dioxins in aquatic and terrestrial systems make them a significant threat to the environment, even at very low concentrations. This review explains the key sources of dioxin-contaminated soil, including industrial emissions and atmospheric deposition, and assesses the associated risks. The transport, places of contamination, and overall status of dioxins are also highlighted in this study. The review also examines the mechanisms of dioxin toxicity, focusing on their interference with hormonal functions and gene expression, as mediated through the aryl hydrocarbon receptor (AhR). This AhR activation leads to gene responses and causes immunotoxicity, endocrine disruption, and oxidative stress. Furthermore, various remediation strategies like biological, physical, and chemical remediation are discussed here as effective approaches for reducing ecological and health risks and promoting soil sustainability. Full article

Tetracycline (TC) contamination in reservoirs poses environmental and human health risks, particularly antibiotic resistance in ecosystems. Bagasse fly ash (BFA), a by-product from the sugarcane processing industry, has gained attention as an environmentally friendly adsorbent. In this study, we aimed to investigate the mechanism of TC adsorption using batch experiments to evaluate the effects of various factors. For example, pH value ranged from 4 to 10, contact time varied between 0 and 90 min, adsorbent doses were noted as 0.5–2.5 g per 50 mL, the initial concentrations of TC were 10–40 mg/L, and the temperature ranged from 293.15 to 318.15 K. To perform surface characterization of BFA, we employed the scanning electron microscopy (SEM) technique. Based on the results of Fourier transform infrared spectroscopy (FTIR) and surface area analysis (Brunauer–Emmett–Teller; BET), its structure and chemical properties are favorable for TC adsorption. Our results demonstrate that the optimal conditions for adsorption were at pH 7.0 and 60 min contact time. The adsorption capacity tended to increase with the initial concentrations of TC and reached a maximum of 0.58 mg/g when the initial concentration was 40 mg/L. Our kinetic analysis results demonstrate that the pseudo-second-order model exhibited the best fit with the experimental data (R² = 0.95638); in comparison, the results of the isotherm behavior study using the Temkin model (R² = 0.97338) indicated the complex adsorption pathway on the BFA surface. Full article

Wastewater generated during the processing of roasted coffee, including instant coffee, remains relatively unknown in the literature. However, it is characterized by a high organic load and the presence of caffeine, phenolic compounds, and melanoidins. Its properties pose significant environmental and technological challenges, limiting the effectiveness of conventional treatment methods. The research aimed to evaluate the effectiveness of an integrated, multi-stage wastewater treatment system that reflects the process of roasted coffee extraction. The developed technological sequence included biological treatment, activated carbon sorption, membrane filtration, and disinfection using ozone and UV radiation. The experiments used synthetic wastewater containing an extract of roasted coffee beans to simulate the contaminants typically found in instant coffee production and the cleaning of processing equipment. The integrated treatment system enabled the removal of total organic carbon (82.4–95.4%), ammonium nitrogen (0–77.4%), and phosphates (0–39.9%), and a reduction in turbidity of 96.3–99.8% at pH 4.02–7.25. The results confirm the system’s high efficiency and its potential for treating complex coffee wastewater, while also highlighting the need for further research into the selection of more favorable process parameters. Full article

Pyrrolizidine alkaloids (PAs), a category of naturally occurring secondary metabolites, are commonly found in various botanical sources. Accumulating evidence indicates that PAs and their biologically active metabolites can interact with cellular components and trigger a variety of toxic effects in animals and humans. Notably, PAs exhibit significant hepatotoxic potential via nutritional supplements, environmental dissemination, food chain contamination, and broader ecological pollution. In this review, we summarize PA-induced hepatotoxicity in humans and animals and the underlying molecular mechanisms. It involves oxidative stress, mitochondrial dysfunction, apoptosis, ER stress, inflammation, autophagy, and ferroptosis. Several key signaling pathways, such as nuclear factor-erythroid 2 related factor 2 (Nrf2), mitogen-activated protein kinase (MAPK), protein kinase RNA-like endoplasmic reticulum kinase (PERK), toll like receptor 4 (TLR4), nuclear factor kappa-B (NF-κB), transforming growth factor beta (TGF-β), p53, farnesoid X receptor (FXR), and pregnane X receptor (PXR), are also implicated. Furthermore, this review discusses diagnostic approaches, metabolic activation pathways, and detoxification strategies targeting PA-induced liver injury. Collectively, this review provides a comprehensive understanding of the molecular basis of PA hepatotoxicity and underscores the urgent need for improved risk assessment, early diagnosis, and effective detoxification interventions to mitigate PA-related liver diseases in humans and animals. Full article

Glyphosate and its primary metabolite aminomethylphosphonic acid (AMPA) are widely detected in aquatic environments, yet their combined effects on fish remain insufficiently understood. This study used label-free blood plasma proteomic profiling to explore molecular patterns associated with 14-day exposure of juvenile common carp (Cyprinus carpio) to environmentally relevant concentrations of glyphosate (100 µg/L), AMPA (100 µg/L), and their mixture (50 + 50 µg/L). Across the three exposure groups, 41 proteins of interest showed pronounced abundance differences relative to the control based on fold-change selection criteria. These proteins were mainly associated with immune recognition, innate immune and complement-associated functions, coagulation and extracellular protease regulation, lipid/sterol transport, and extracellular matrix organization. In the mixture group, proteins of interest spanned several functional categories, suggesting that combined exposure deserves further attention in future studies of plasma-level responses to glyphosate and AMPA. Overall, these findings provide preliminary insights into blood plasma protein patterns associated with systemic responses of fish to glyphosate, AMPA, and their mixture at environmentally relevant concentrations and highlight the importance of considering parent compounds, metabolites, and their co-occurrence when assessing the potential biological effects of herbicide contamination in aquatic ecosystems. Full article

Nanocomposite materials combine diverse material properties to form multifunctional structures, enhancing the efficiency of conventional applications. Particularly in environmental monitoring, such as water analysis, nanocomposites significantly improve sensitivity and lower costs associated with standard analysis methods. The SERS method is gaining popularity due to its operational simplicity, on-site applicability, and rapid results delivery. This study focused on the development of a multifunctional metal-chitosan-based nanocomposite utilizing an economical, eco-friendly approach as an SERS substrate. The resulting composite exhibits considerable preconcentration capabilities and will provide low detection limits (LOD) for future SERS applications. Specifically, magnetic nanoparticles (MNPs) were electrostatically combined with chitosan-coated silver nanoparticles (Chi-Ag NPs) to synthesize the MNPs@Chi-Ag NPs nanocomposite. CoFe₂O₄ NPs were prepared as MNPs. The resulting nanocomposite, which demonstrated colloidal stability after optimization, was characterized using various techniques, including UV-VIS and FTIR spectroscopy, XRD, TEM, SEM, and DLS. As a SERS substrate, the MNP@Chi-Ag NPs exhibited considerable analytical enhancement factors of (1.5 ± 0.4) × 10⁶, (7.0 ± 0.3) × 10⁶, and (1.2 ± 0.5) × 10⁶ for the detection of water contaminants BCB, CV, and MP, respectively. It was demonstrated that the substrate enhances precision and exhibits preconcentration. Finally, the MNPs@Chi-Ag NP nanocomposite demonstrates remarkable antibacterial activity, with larger inhibition zones observed at higher nanocomposite concentrations, indicating a concentration-dependent effect. Full article

The modern world is confronting critical environmental and biomedical challenges, underscoring the urgent need for the development of multifunctional materials—an inherently interdisciplinary field, bridging materials science and engineering, environmental science and biomedicine. Titanium dioxide (TiO₂) is widely recognized for its photocatalytic and antiviral properties, enabling the degradation of pollutants and mitigation of viral contamination under solar irradiation. Nevertheless, it exhibits certain limitations, such as wide band gap and high recombination rate of photogenerated electron–hole pairs. To address these limitations, TiO₂ prepared by a co-precipitation method was modified with N-Doped Carbon Dots (N-CDs) via a hydrothermal treatment, which extend light absorption into the visible region and enhance charge separation. Further functionalization with silver nanoparticles (Ag NPs)—well known for their antimicrobial properties—via a simple thermal process under ambient conditions, introduced additional reactive oxygen species generation, creating a synergistic effect. The as-prepared TiO₂, TiO₂/N-CDs and TiO₂/N-CDs/Ag samples were characterized via several techniques, such as XRD, micro-Raman, FT-IR, TEM and UV-Vis. In addition, their photocatalytic and antiviral activity against methylene blue (MB) and nitrogen oxide (NO_x) pollutants, as well as SARS-CoV-2, was evaluated. Based on the results of liquid-phase photocatalysis, TiO₂, TiO₂/N-CDs and TiO₂/N-CDs/Ag presented a degradation efficiency of 78%, 85% and 95%, respectively, whereas different trends were observed under gaseous-phase conditions. The TiO₂/N-CDs/Ag hybrid material demonstrated superior antiviral activity against SARS-CoV-2 (IC₅₀: 1.24 ± 0.34 g/L), compared to both TiO₂ (IC₅₀: 1.78 ± 0.30 g/L) and TiO₂/N-CDs (IC₅₀: >2.5 g/L), highlighting its potential as an effective multifunctional material. Finally, TiO₂/N-CDs/Ag was incorporated onto a paper substrate, demonstrating antiviral activity, showing promising scalability for application across a wide range of future substrates. To the best of our knowledge, this is the first study presenting TiO₂/N-CDs/Ag with dual photocatalytic and antiviral activity. Full article

Heavy metal pollution remains a major global environmental challenge due to persistent ecological risks and potential threats to food safety. Microbial remediation and phytoremediation represent sustainable alternatives to conventional treatments; however, their effectiveness is strongly influenced by number of factors including nutrient availability. This review critically examines how nutritional regulation governs microbial metabolism, plant physiological responses, and rhizosphere interactions to enhance heavy metal transformation and removal. Metal bioavailability depends on type, concentration, soil pH, redox potential, and microbial processes. Interventions including fertilizers, chelating agents, inoculation with arbuscular mycorrhizal fungi and plant-growth-promoting rhizobacteria enhance phytoremediation processes through regulating plant nutrient and heavy metal uptake, while selection between ammonium/nitrate changes rhizosphere pH consequently affects plant metal uptake. Similarly, nutrients, i.e., phosphate, iron, zinc and manganese competitively affect metal uptake. Organic amendments enhance phytostabilization, especially for selenium and mercury, while enhancing chromium reduction. Sulfur-reducing bacteria precipitate metals as insoluble sulfides with 90% efficiency. In addition, soil amendments including plant-growth-promoting rhizobacteria, arbuscular mycorrhizal fungi, and metal-chelating agents can be strategically used to enhance the phytoextraction from metal from contaminated soils. We suggest that the future integration of modern approaches such as multi-omics and cisgenesis supported by artificial intelligence tools can help to accurately predict the efficiency of nutrient regulation strategies and their remediation outcomes, thereby supporting evidence-based soil management Full article

A thorough understanding of the resistivity response characteristics of ethanol-contaminated soil is of great significance for the development of non-destructive geophysical detection techniques and for supporting contaminated site investigation and assessment. This experimental study aims to systematically investigate the resistivity behavior of ethanol-contaminated sandy soils, with a focus on the coupled mechanisms of multiple factors, including water content, ethanol concentration, particle size distribution, and contamination time. It is hypothesized that water content serves as the dominant factor controlling resistivity, whereas ethanol concentration and contamination time regulate resistivity by altering the physicochemical properties of the pore fluid. Under laboratory conditions, silt, fine sand, and medium sand were selected as the test materials. Resistivity was systematically measured using a Miller Soil Box with increasing water content, Wenner array configuration across varying water contents (3–24%), ethanol concentrations (40–98%), and contamination durations (0–144 h). The experimental results indicate the following: (1) Regardless of the presence of ethanol contamination, the resistivity of sandy soil decreases with increasing water content following a power-law relationship. The decrease is most pronounced at low water contents (3–9%), and gradually stabilizes at higher water contents. The results show that, at a constant water content, resistivity systematically and consistently follows the order: silt > medium sand > fine sand. (2) The influence of ethanol concentration on resistivity is constrained by water content levels, and the overall increase in resistivity is primarily attributed to ion dilution and the obstruction of conductive pathways. (3) Over time, resistivity exhibits a two-stage increasing trend, associated with ethanol volatilization and water loss. Resistivity changes in fine sand samples contaminated with ethanol at concentrations ranging from 75% to 95% follow a two-stage pattern. The initial phase of growth is characterized by a gradual increase over a period of 0–48 h, followed by a more rapid increase during the subsequent phase, which extends from 48 to 144 h. The results show that higher initial ethanol concentrations enhance the sensitivity of resistivity to temporal changes. Comprehensive analysis indicates that the resistivity variation mechanism under multi-factor coupling conditions can be summarized as follows: the water content is the dominant factor in the regulation of the conductive pathways; the particle size distribution determines pore structure and the characteristics of the particle interface; ethanol concentration and contamination time dynamically alter pore fluid properties, collectively regulating the resistivity response. Although the experiments were conducted under controlled laboratory conditions and the results have certain limitations, they provide a preliminary reference for interpreting resistivity responses in relatively homogeneous sandy contaminated sites and offer theoretical support for the application of resistivity methods in contamination identification and dynamic monitoring. Full article