Search Results (1,579)

Sweat, which contains a rich array of biomarkers, serves as a vital biological fluid for non-invasive biosensing. Wearable sweat sensors have garnered significant interest owing to their portability and capacity for continuous monitoring. However, there are safety concerns regarding the direct contact of sweat sensors with the skin during the detection process. The chemical substances in the sensor patches may cause contamination of the epidermis when in contact with the skin, leading to skin allergic reactions. Sample collection and biosafety isolation are critical issues in wearable sweat detection. To address this, we develop a cactus-inspired biomimetic Janus membrane capable of unidirectionally transporting and concentrating sweat toward a designated detection zone. Through unidirectional transport from the hydrophobic layer to the hydrophilic layer of the Janus membrane, sweat droplets are enriched at the designated detection point of the conical hydrophilic pattern via Laplace pressure. The bionic osmosis-enrichment sensing patch effectively inhibits direct contact between indicators and skin, eliminating potential epidermal contamination. This achieved the effect of in situ perspiration collection under the premise of biosafety isolation. To rapidly and accurately analyze sweat biomarkers, we employ a deep learning (DL)-assisted fluorescence sensor for efficient and precise detection of biomarker concentrations. A dataset of 4500 fluorescence images are constructed and used to evaluate two DL and seven machine learning (ML) algorithms. The convolutional neural network (CNN) model could easily and accurately classify and quantitatively analyze the total concentration of the amino acid mixture, Ca²⁺ and Cl⁻, with 100% classification accuracy. The consistency between the detection results of actual sweat by the DL-assisted fluorescence method and fluorescence spectroscopy was 91.4–96.0%. This approach demonstrates high reliability in sweat collection and analysis, offering a practical tool for clinical health monitoring, early disease intervention, and diagnosis. Full article

The pervasive environmental contamination by microplastics (MPs) and per- and polyfluoroalkyl substances (PFAS) represents a critical challenge of the Anthropocene. While historically studied in isolation, a growing body of evidence confirms that these pollutants interact to form a complex and dynamic MP-PFAS Nexus. This review synthesizes current knowledge to elucidate the multifaceted mechanisms of this interaction, where MPs act as vectors, concentrators, and secondary sources for PFAS. We detail how environmental aging and water chemistry modulate adsorption and transport, fundamentally altering the fate of both contaminants. Crucially, the review consolidates evidence demonstrating that co-exposure often leads to synergistic toxicity, disrupting physiological processes from photosynthesis in algae to lipid metabolism and neurogenesis in animals, with significant implications for trophic transfer. The nexus also presents formidable challenges for water treatment and soil remediation, while simultaneously offering opportunities for targeted destructive technologies like pyrolysis. Furthermore, we explore the emerging threats of this complex to human health via seafood and water, and the amplifying feedback of climate change. Finally, we argue that current regulatory frameworks, which assess pollutants individually, are inadequate and must evolve to account for combined effects. This review underscores the imperative to reframe MPs and PFAS as an interconnected pollutant system, necessitating integrated research and policy for effective environmental risk assessment and management. Full article

Cadmium (Cd) contamination in agricultural soils poses a significant risk to crop production and food safety. This study explored the role and mechanisms of manganese (Mn) in mitigating Cd toxicity using two rice genotypes: ZS97B (Cd-tolerant) and MY46 (Cd-sensitive). A hydroponic experiment was conducted under two Mn levels (0 and 100 µM) and three Cd levels (0, 5, 10 µM). Exposure to 10 µM Cd significantly inhibited plant growth and induced physiological disorders, with more severe effects observed in MY46 than in ZS97B. The addition of Mn markedly alleviated Cd toxicity, as reflected by increased antioxidant enzyme activities and reduced malondialdehyde (MDA) and hydrogen peroxide (H₂O₂) contents in both roots and shoots. Gene expression analysis showed that Mn addition up-regulated genes related to antioxidant enzymes and down-regulated key Cd uptake and transport genes, including OsNramp1, OsYSL2, OsMTP9, and OsHMA3. These changes contributed to enhanced antioxidant capacity and reduced Cd accumulation in rice plants under Cd stress. Our findings demonstrate that appropriate Mn application can effectively reduce Cd accumulation and alleviate toxicity in rice grown in Cd-contaminated environments. Full article

The cell surface proteome of polarized epithelial cells plays a central role in barrier function, signaling, and vectorial transport, yet the quantitative characterization of their surface proteins remains technically challenging. We developed an optimized chemoproteomic strategy specifically tailored to studying the surface proteins of polarized cells while keeping membrane integrity intact. By applying a disulfide-linked membrane-impermeable biotin reagent, labeling was restricted to extracellular regions of transmembrane proteins (TMPs) and secreted proteins, thereby minimizing contributions from intracellular contaminants. Following biotinylated peptide-level or protein-level enrichment and mass spectrometric analysis, we systematically compared data-dependent (DDA) and data-independent acquisition (DIA) approaches, showing that while DIA increases proteome coverage, DDA more reliably identifies biotinylated peptides in our studies. To ensure robustness, we established replicate-based normalization and contaminant-aware quality control metrics that minimize biases from proteins in cell culture medium and damaged cells. The application of the workflow to Madin–Darby canine kidney (MDCK) II epithelial monolayers enabled the large-scale quantification of apical versus basolateral domains, yielding over 2100 proteins, with 235 showing significant polarized distribution, in agreement with known biology. This method offers high specificity for the extracellular labeling and quantitative resolution of cell surface protein (CSP) polarization, providing a powerful platform for studying epithelial biology and identifying extracellular epitopes relevant to diagnostics and therapeutic targeting. Full article

Chlorinated solvents, common groundwater contaminants, can cause coexistence of the original contaminant and its degradation products during the transport process. Practically applicable analytical models for reactive transport are essential for simulating the plume migration of chlorinated solvent contaminants and their degradation products within a complex chemical mixture. Although several analytical models have been developed to solve advection–dispersion equations coupled with a series of decay reactions for simulating transport of the coexisting chlorinated solvent contaminants, the majority assume static, time-invariant inlet boundary conditions. Such time-invariant inlet boundary conditions may fail to adequately represent the temporal evolution of dissolved source discharge concentration concerning mass reduction, especially in the context of diverse DNAPL source remediation strategies. This study seeks to derive analytical models for three-dimensional reactive transport of multiple contaminants, specifically addressing the challenges posed by dynamical, time-varying inlet boundary conditions. The model development incorporates two distinct inlet functions: exponentially decaying and piecewise constant. Analytical solutions are obtained using three integral transform techniques. The accuracy of the newly developed analytical models is verified by comparing them with solutions derived from existing literature using multiple illustrative examples. By incorporating two distinct time-varying inlet boundary conditions, the models exhibit strong capabilities in capturing the complex transport dynamics and fate of contaminants within groundwater systems. These features make the models valuable tools for improving the understanding of subsurface contaminant behavior and for quantitatively evaluating and optimizing a range of remediation strategies. Full article

Approximately 1.1% of global soils exceed the safety thresholds. Yinchuan is one of the key grain production bases, and the quality of its agricultural soil directly impacts the quality of agricultural products. To investigate the heavy metal contamination status of surface agricultural soil in Yinchuan, this study collected 325 agricultural soil samples from the city to analyze the concentrations of five heavy metal elements—As, Hg, Pb, Cd, and Cr—and conducted a risk assessment and quantitative source apportionment of soil heavy metal contamination. The results indicate that the majority of the study area is classified as having a lightly polluted level with moderate ecological risks. The order of the over-standard rates is Hg > Cd > Pb > Cr > As. The soil in the study area is generally weakly alkaline, which has a relatively low impact on the migration and transformation of heavy metal elements. High-value areas of heavy metals are all located near the Yellow River floodplain. They are significantly affected by the agricultural and industrial wastewater discharge from the upper reaches of the Yellow River. The Absolute Principal Component Score-Multiple Linear Regression (APCS-MLR) model analysis identified the sources of soil heavy metal pollution as natural sources (37.29%), agricultural sources (25.50%), coal combustion sources (20.18%), and industrial-transportation sources (17.04%). The positive matrix factorization (PMF) model explained that the sources of heavy metals in the soil were natural sources (22.42%), agricultural activities (24.46%), coal combustion sources (26.70%), and traffic sources (26.42%). Overall, the results indicate that there is a certain degree of metal pollution in the agricultural soil of Yinchuan, which is significantly influenced by human activities. Full article

Perfluorooctanesulfonic acid (PFOS) and perfluorooctanoic acid (PFOA) pose significant health risks through various exposure pathways, including ingestion of contaminated food and water, as well as dermal absorption. Aquatic organisms are especially at risk, as water bodies serve as primary pathways for the transport and transformation of these chemicals. While the biodegradation study was previously performed using a bacterial consortium from the activated sludge compartment at Zeekoegat WWTP, the ecotoxicological implications of the treated effluents remained unclear, particularly given the potential presence of degradation products. To address this gap, the present study used bioassays to evaluate the acute toxicity and endocrine-disrupting potential of PFOS and PFOA. For this purpose, PFOS and PFOA concentrations ranged from 58 ng/L to 1050 ng/L, and two types of bioassays were used: the Daphnia magna acute toxicity test, which examined the short-term lethal effects of the samples on a small freshwater organism (Daphnia magna), and the Yeast Estrogen Screen (YES), which measured estrogenic activity, an important indicator of potential endocrine disruption. Results revealed detectable estrogenic activity at environmentally relevant concentrations, with PFOS showing higher activity than PFOA. The estradiol equivalency (EEQ) values in samples containing PFOA ranged from 0.23 ± 0.029 ng/L to 3.15 ± 0.056 ng/L and from 0.43 ± 0.036 ng/L to 1.96 ± 0.086 ng/L in samples containing PFOS. Daphnia magna bioassays showed 100% mortality in samples containing PFOS at concentrations ≥ 62 ng/L and in samples containing PFOA at concentrations ≥ 142 ng/L, classifying them as ‘Very High Acute Hazard’ falling into Hazard Class V (100% mortality) according to the classification system proposed in 2003 by Persoone and co-workers. These bioassays helped to determine whether the degradation products were more toxic compared to the parent compounds, thereby supporting the objective of this study to assess environmental safety post-treatment. Full article

In order to investigate the current status of soil heavy metal pollution, ecological risk, and risk sources in the black soil area of the Eastern Inner Mongolia Province, topsoil (0–20 cm) samples from farmland in the black soil area (N = 163) were collected to determine the contents of seven heavy metals. The levels of soil heavy metal pollution and ecological risk in the study area were evaluated by combining the geo-accumulation index, potential ecological risk index, and static environmental carrying capacity; the positive matrix factorization (PMF) model was used to identify the pollution sources and contributions of heavy metals in the soil and analyze the risk levels to adults and children. The soil was predominantly weakly acidic, with mean values of Cr, Ni, Cu, As, Cd, Pb, and Zn of 61.77, 26.77, 17.07, 12.11, 0.08, 12.61, and 85.71 mg·kg⁻¹. The mean concentrations of heavy metals exceeded the background values, except for Pb, the mean concentration of which was lower than the soil background. Ni concentrations of 6.21% at the sampling sites exceeded the risk screening value for agricultural soils. The geo-accumulation index showed that Cr (55.15%) and As (54.00%) were mainly mild pollutants; the static environmental carrying capacity indicated that the soils were slightly polluted by Ni, As, and Zn; and the potential ecological risk indices of Cd, Ni, and As were at moderate levels. The PMF model analyzed three pollution sources: mixed agricultural practice–transportation sources (39.46%), mineral-related activity sources (27.01%), and pesticide–fertilizer agricultural practices (33.53%). The human health risk assessment indicated that 46.58% of sampling sites posed a carcinogenic risk to children, with Ni as the main carcinogenic element. In conclusion, the potential contamination of As, Cd, Ni, Cr, and Zn in the Eastern Inner Mongolia farmland black soil area should be further studied. Full article

Fusarium verticillioides, a hemibiotrophic pathogen, infects a range of important crops and contaminates grains with fumonisin B1 (FB1) toxins, posing serious threats to yield, quality, and food safety. Secreted proteins containing Common Fungal Extracellular Membrane (CFEM) domains are known to contribute to the pathogenicity of several fungi, yet their functions in F. verticillioides remain poorly understood. In this study, we first identified the truncated protein FvCfem7^ΔSP without signal-peptide-triggered host immune responses in tobacco. The knockout mutant ΔFvcfem7 exhibited significantly enhanced virulence, while the constitutive overexpression of the FvCFEM7-OE strain showed reduced pathogenicity. Notably, foliar spraying of recombinant FvCfem^ΔSP protein suppressed fungal infection. FvCfem7 accumulated specifically in haustorium-like structures during early infection of maize leaves and onion. However, heterologous expression of FvCfem^ΔSP in Nicotiana benthamiana leaves and maize protoplasts can be localized in their cytoplasm and nucleus, although its potential transport mechanism remains to be elucidated. Further analysis revealed that FvCfem7 interacts with specific members of ZmPR5, as well as ZmPR1 and ZmPR4. The ΔFvcfem7 mutant suppressed ZmPR1 induction while enhancing ZmPR5 expression at 24 hpi, which suggests that FvCfem7 modulates the expression of PR proteins at the early invasion stage. In summary, FvCfem7 was identified as a CFEM effector that is recognized and hijacked by PR proteins, thereby triggering immune defenses, while its host-targeting function was also characterized. Full article

Poly- and perfluoroalkyl substances (PFASs) are persistent environmental pollutants widely used in industrial applications due to their thermal stability and chemical resistance. However, their persistence in the environment and potential health risks, including developmental and immunological issues, have raised significant concerns. This review highlights the industrial uses, environmental fate, and bioaccumulation of PFASs, emphasizing their widespread presence in air, water, soil, and biota. Major sources of PFAS contamination include industrial discharges, wastewater treatment, and military sites. The atmospheric transport of PFASs contributes to their deposition in remote ecosystems, while aquatic and soil contamination stems from both point and nonpoint sources. Bioaccumulation studies reveal that PFASs accumulate in organisms, leading to potential human exposure through food, water, and consumer products. This review calls for further research to address knowledge gaps in PFAS detection, behavior, and health impacts, while advocating for improved regulations to limit their release and exposure. Full article

Oil sands drilling frequently contaminates water-based xanthan gels with highly viscous asphaltenes, collapsing their three-dimensional network and causing barite sag, high fluid loss and poor cuttings transport. Nitrogen-functionalized carbon quantum dots (N-CQDs) were hydrothermally synthesised from citric acid and 1-hexadecylamine and characterised by means of FT-IR, TEM and TGA. The concentration-dependent influence of N-CQDs (0–1.2 wt%) on gel viscoelasticity, microstructure and filtration properties was evaluated through rheometry, API and fluid-loss tests. At 0.01 wt% N-CQDs, the viscosity of the adsorbed oil phase dropped by 50% and the mean droplet diameter decreased from 247.7 µm to <100 µm. Consequently, the xanthan gel exhibited a significant enhancement in its mechanical strength and fluid loss performance. Wax-crystal growth was simultaneously inhibited, lowering the pour point by 6 °C. N-CQDs act as nanospacers that disrupt π-stacking of asphaltenes and hydrogen-bond to the polymer backbone, thereby restoring gel strength and sealing capacity. The work provides a sustainable, low-toxicity route to rejuvenate gel-based drilling fluids contaminated by heavy oil and facilitates their reuse in oil sands reservoirs. Full article

Groundwater contaminated with organic chemicals can be treated by raising the subsurface temperature, thereby enhancing the rate of microbial degradation. This process requires careful monitoring through space and time to ensure that heat is being delivered to the most contaminated regions of the groundwater system. Here, we demonstrate the effectiveness of a fiber-optic distributed temperature sensing (DTS) system as a high spatial and temporal resolution monitoring strategy. The DTS sensing system required the installation of fiber optic cable in the subsurface. Boreholes were drilled with hollow casings, a fiber optic cable was inserted into the casings, and then, the casings were withdrawn to allow the formation to collapse around the fiber. The fiber was then fusion-spliced into a single continuous fiber that could be interrogated by a Raman-based DTS unit. Temperature measurements were collected at 30 min intervals over a 575 m span with 0.25 m spatial sampling, resulting in over 110,000 temperature data points per day. With this high resolution monitoring the development of thermal plumes emanating from solar-heated borehole heat exchangers could be closely monitored. The pseudo-3D monitoring network showed the lateral and upward migration of the induced thermal plumes over time. This information was valuable for assuring the heated groundwater was contacting the intended treatment zone. Full article

Additive manufacturing (AM), also known as 3D printing, is a rapidly growing field in industry. AM technologies include sintering, melting, and stereolithography. With steadily rising utilization, evaluating the environmental impact of AM materials has become essential, as these materials may act as emerging pollutants. Photopolymerizing resins (PRs) used in stereolithography can enter terrestrial ecosystems in polymerized and unpolymerized forms due to improper disposal. Insects are likely to be among the first organisms exposed to these contaminants in land ecosystems. This study evaluates the physiological effects of photopolymerizing resin particles (PRPs) produced via sanding on tropical house crickets (Gryllodes sigillatus) that were fed PRPs-contaminated agarose gels for 10 days. Effects were evaluated through mortality observations and enzymatic activity assays of cell transport mediating enzymes, digestive enzymes, and antioxidative stress enzymes. PRPs exposure caused sex-dependent differences in survival; an increase in amylase, alanine aminotransferase, aspartate aminotransferase, and trypsin; and a decrease in alkaline phosphatase, glutathione peroxidase, and superoxide dismutase activity, indicating molecular and cellular damage. PRPs’ toxicity might be enhanced due to a sex-dependent pulverization capability exhibited by G. sigillatus. These findings underscore the potential ecological risks associated with PRPs in terrestrial environments and the need for further research on their environmental impact. Full article

The common carp Cyprinus carpio L. is a cornerstone aquaculture species, yet transcriptome interpretation is complicated by its paleotetraploid genome and extensive alternative splicing. A species-tailored oligonucleotide microarray was developed to deliver reproducible, gene-level expression profiling. Probe design was anchored to the SPL01 reference and implemented on an Agilent platform using a gene-level strategy that collapsed transcripts to genes, selected the longest isoform, and placed 3′-anchored 60-mer probes. The workflow incorporated embedded technical controls and a standardized two-color pipeline to ensure stable measurements across arrays. Baseline functional organization of the head kidney was defined using 614 C. carpio L. -Danio rerio orthologs and complementary enrichment tools. Coherent signatures emerged for hemoglobin-mediated oxygen transport, heme and porphyrin metabolism, antioxidant defense driven by peroxiredoxin and thioredoxin systems, including hydrogen peroxide detoxification, protease regulation through SERPIN, SPINK, and WFDC families, and elements of innate and humoral immunity. Targets bearing c-Myc motifs showed a modest positive bias consistent with ongoing hematopoiesis. These resolved baseline modules provide a reference against which infection- or exposure-induced programs such as interferon-stimulated genes, chemokines and chemotaxis, complement activation, and degranulation can be detected and quantified. The platform complements RNA-seq by offering cost-efficient, rapid, and comparable measurements suited to large cohorts and longitudinal designs. Anticipated applications include host–pathogen studies for viral and bacterial agents and the assessment of chemical contaminants in aquaculture surveillance, supporting standardized, cross-study decision-making in research and health monitoring. Full article

The development of urban areas and the proliferation of impervious surfaces have significantly altered natural hydrological cycles, resulting in an increase in stormwater runoff and substantial risks to groundwater quality. This review synthesizes current research on the transport mechanisms of stormwater contaminants, including toxic elements, nutrients, pathogens, and emerging pollutants such as microplastics and pharmaceuticals, into aquifers. This study analyzes the physicochemical and biological processes that affect pollutant mobility and retention in urban soils, emphasizing the vulnerability of groundwater systems, particularly in areas with permeable soils and shallow water tables. The article evaluates a range of green infrastructure (GI) and low-impact development (LID) strategies—including rain gardens, bioswales, infiltration basins, constructed wetlands, and urban forestry—to assess how effectively they can mitigate stormwater pollution and improve groundwater protection. Case studies from North America illustrate the practical implementation and performance of GI systems, emphasizing the importance of site-specific design, monitoring, and adaptive management. The review also discusses global policy frameworks and community engagement strategies that support sustainable stormwater management. Ultimately, it advocates for an integrated, multidisciplinary approach that combines engineering, ecological science, and public policy to safeguard groundwater resources in the face of climate variability and urban expansion. Full article