Search Results (6,751)

Prenatal ozone (O₃) exposure may trigger systemic inflammation and oxidative stress. These effects could contribute to adverse pregnancy outcomes. We conducted a prospective cohort study involving 235 pregnant women in Ningxia, China. Maternal O₃ exposure during pregnancy and prior to conception was assessed using high-resolution spatiotemporal models. Multivariable logistic and linear regression analyses were employed to evaluate the associations between O₃ exposure and adverse pregnancy outcomes. Mediation and interaction models were further applied to examine the potential modifying roles of gestational diabetes mellitus (GDM) and inflammatory biomarkers. In multivariable analyses adjusted for maternal and environmental covariates, higher prenatal O₃ exposure was significantly associated with an increased risk of preterm birth (PTB) (OR = 1.24, 95% CI: 1.05~1.45, p = 0.010) and low birth weight (LBW) (OR = 1.29, 95% CI: 1.09~1.54, p = 0.004). Similarly, elevated maternal SAA and CRP levels were positively associated with these adverse pregnancy outcomes (p < 0.05). Notably, higher TNF-α levels were inversely associated with the risks of PTB (OR = 0.15, 95% CI: 0.03~0.85, p = 0.032) and LBW (OR = 0.05, 95% CI: 0.01~0.39, p = 0.005). IL-17A levels were inversely associated with neonatal length-for-age Z scores (β = −0.28, 95% CI: −0.55~−0.01, p = 0.043). Our findings suggest that prenatal O₃ exposure is associated with increased risks of PTB and LBW. Alterations in systemic inflammatory markers and metabolic dysfunction during pregnancy were related to adverse pregnancy outcomes and fetal growth deficits, but they did not mediate these associations, with O₃ remaining an independent predictor after adjustment. Full article

Tropospheric ozone (O₃) pollution is a major concern in urban environments because of its toxicity for both people and vegetation. This paper review provides an overview of atmospheric mechanisms, as well as the potential and best management practices of urban greening for reducing O₃ pollution in cities. Urban greening has often been proposed as a cost-effective solution to reduce O₃ pollution, but its effectiveness depends on careful species selection and integration with broader air quality management strategies. Ozone is a secondary pollutant and the volatile organic compounds emitted by vegetation (BVOCs) can play a prominent role in O₃ formation. A list of recommended and to-avoid species is given here to drive future planting at city scale. Planting low BVOC-emitting species and combining greening with reductions in anthropogenic emissions are key to maximizing benefits and minimizing unintended increases in O₃. Public and non-public institutions should carefully select plant species in consultation with expert scientists from the early stages, e.g., by considering local conditions and pollutant dynamics to design effective greening interventions. Collaborative planning among urban ecologists, atmospheric scientists, and municipalities is thus crucial to ensure that greening interventions contribute to overall air quality improvements rather than inadvertently enhancing O₃ formation. Such improvements will also translate into plant protection from O₃ stress. Therefore, future directions of research and policy integration to achieve healthier, O₃-resilient urban ecosystems are also provided. Full article

Downy mildew, caused by Plasmopara halstedii, is a major threat to sunflower production worldwide, leading to severe yield losses. Since resistance in sunflower hybrids can be easily broken by the pathogen, it is important to find alternative and sustainable control methods against this disease. This study investigated the potential use of NeemAzal^®-T/S (a neem-based biopesticide formulation) to induce antioxidant defense responses in sunflower seedlings inoculated with P. halstedii (pathotype 704). Its effects, alone, or in combination with a reduced dose of Mefenoxam, were evaluated under controlled conditions. Plant height, sporulation, antioxidant enzyme activities (SOD, CAT, APX, POX, and PPO), lipid peroxidation (MDA), and hydrogen peroxide (H₂O₂) contents were measured. Our results indicate that the antioxidant responses of seedlings varied according to the treatment. MDA levels decreased even when NeemAzal^®-T/S was applied alone, while H₂O₂ production only decreased when both treatments were applied combined. Overall, NeemAzal^®-T/S can be a valuable alternative strategy to help control sunflower downy mildew, since it reduced sporulation and MDA content, and increased APX, POX, and PPO activities even at a later stage of infection in susceptible seedlings. These findings indicate that NeemAzal^®-T/S can activate defense mechanisms associated with oxidative stress reduction in sunflower, offering a promising strategy to help manage downy mildew in a more sustainable manner. Full article

To clarify the effects of hydrogen peroxide (H₂O₂) seed soaking on the germination and stress resistance of different edible bean seeds, seeds of mung bean (Vigna radiata L. ‘Keda Green No. 2’), cowpea (Vigna unguiculata L. ‘Keda Cowpea No. 1’), and red bean (Vigna umbellata Thunb. ‘Jihong 352’) were soaked in a 50 mmol/L H₂O₂ solution. The study examined the germination and growth-related physiological indices of seeds after soaking. The results showed that hydrogen-peroxide-primed seeds of mung bean (GBH), cowpea (CBH), and red bean (RBH) exhibited significant improvements in germination performance and physiological activity compared with their respective controls (GBCK, CBCK, and RBCK). The results indicated that H₂O₂ soaking significantly improved the germination ability of the seeds, with the germination rate of mung beans, cowpeas, and red beans increasing by 48.89%, 21.11%, and 18.89%, respectively, and the germination percentage increasing by 31.11%, 24.45%, and 17.77%. Additionally, H₂O₂ soaking enhanced the activity of α-amylase, protease, and the antioxidant enzymes peroxidase (POD), superoxide dismutase (SOD), and catalase (CAT); increased the soluble sugar and soluble protein content in the seeds; and reduced the malondialdehyde (MDA) content. The experiment demonstrated that H₂O₂ promotes the germination of mung bean, cowpea, and red bean seeds by influencing antioxidant enzyme activity, the breakdown of storage substances, and the regulation of germination-related substances, thereby improving seedling adaptation to environmental stress. This study aims to improve the germination rate of legume seeds using H₂O₂ treatment, providing a theoretical basis for techniques to enhance seed vigor, especially for seeds that perform poorly in germination under normal conditions. Full article

Two Ni-AlSi12 coatings were prepared using mechanical alloying (MA) and mechanical alloying followed by laser cladding (LC), respectively. Phase composition and microstructure variations caused by powder weight ratio and laser-specific energy were thoroughly analyzed in this study. Mechanical properties and oxidation behavior are markedly improved by subsequent laser cladding. The MA-LC coating, characterized by high densification and crack-free properties, presents a homogeneous microstructure with refined features. Microhardness testing reveals a marked superiority of the MA-LC coating over the conventional MA coating. The nano-hardness of MA-LC coating is 9.79 GPa, exhibiting that it is 6.84 times the nano-hardness of the MA sample. Owing to metallurgical bonding, the MA-LC coating possesses excellent scratch bonding performance. The MA-LC coating shows favorable oxidation behavior, due to the following three reasons: Firstly, oxygen diffusion can be effectively blocked by the compact Al₂O₃ oxide layer developed on the MA-LC coating surface, which reduces the oxidation velocity. Secondly, the coating’s mean grain dimensions demonstrate an increasing tendency after oxidation, which reduces the grain boundary serving as the oxygen diffusion channel. This enhancement significantly improves the coating’s oxidation resistance. Thirdly, analysis of the coating’s respective kernel average misorientation (KAM) map revealed a significant release of internal stress following 100 h oxidation, which can improve the coating’s resistance to spallation. Full article

Background/Objectives: Copper-based wood preservatives are widely used to protect timber from fungal decay; however, the emergence of copper-tolerant fungi reduces their long-term effectiveness. This study aimed to elucidate the molecular mechanisms underlying copper resistance in Saccharomyces cerevisiae through adaptive evolution and transcriptomic profiling. Methods: A copper-resistant mutant was developed via stepwise exposure to CuSO₄·5H₂O, and its gene expression profile was compared to the wild-type strain under copper stress and non-stress conditions using Affymetrix GeneChip Yeast Genome 2.0 arrays. Results: Differential expression analysis revealed upregulation of key genes involved in copper transport (ATX1 and CTR1), the oxidative stress response (RCK1 and SOD1), and metal ion detoxification (FRE3 and SLF1). Functional enrichment analysis highlighted the significant activation of pathways related to protein folding, mitochondrial function, and transcriptional regulation. Conclusions: These findings provide insights into the adaptive strategies employed by S. cerevisiae to tolerate copper stress and suggest potential gene targets for the development of more effective wood preservatives capable of mitigating fungal resistance. Full article

Background: Cisplatin (CP) use is associated with testicular toxicity. Cuproptosis-related genes are associated with dysfunctional spermatogenesis. Additionally, the HMGB1/NF-κB axis has been involved in cuproptosis-mediated inflammation. The aim of the current study was to investigate the effect of CP toxicity on the HMGB1/NF-κB axis and cuproptosis in the rat testis. The effect of thymol was also explored. Methods: Four groups of male Wistar rats were used: control, thymol (60 mg/kg P.O. daily for 2 weeks), CP (8 mg/kg i.p single injection), and CP+thymol. Results: CP induced a significant decrease in serum testosterone and LH. CP-induced oxidative stress was evident by the modulation of oxidative stress markers. The expressions of IL-8, NF-κB, and HMGB1 were induced by CP treatment, accompanied by increased expression of cuproptosis genes, including SLC31A1, FDX1, and DLAT. On the other hand, thymol antagonized CP testicular injury. Thymol’s effect was associated with reduced expressions of IL-8, NF-κB, HMGB1, and cuproptosis markers. Conclusions: Collectively, this study provides evidence of the possible potential role of the HMGB1/NF-κB axis and cuproptosis in CP-induced testicular injury and illustrates the protective effects of thymol against testicular damage, which are attributed, at least in part, to blunting HMGB1 and cuproptosis-related genes expression. Full article

In order to investigate the impact of drought and saline–alkaline stress on the growth and metabolic components of wheat, as well as to identify advantageous components of wheat under saline–alkaline conditions, metabolomics analysis was conducted separately on wheat cultivated in saline–alkaline soil at Zhong Jie Industrial Park (AAW) and generally grown wheat at Xian Huanyuan Village (GW). The results revealed that AAW exhibited higher levels of accumulated metabolites compared to GW. Specifically, under drought and saline–alkaline stress, alkaloids, flavones, amino acids, and derivatives were significantly up-regulated, while phenolic acids and terpenoids were down-regulated. Notably, 29 differential metabolites, including vitexin-2″-O-glucoside, N-feruloyl agmatine, apigenin-8-C-glucoside, and L-alanyl-L-phenylalanine, showed significant differences between AAW and GW. Flavone and flavonol biosynthesis, apigenin C-glycosides biosynthesis, and metabolic pathways were identified as key pathways contributing to the observed differences in metabolite production. Apigenin-8-C-glucoside and vitexin-2″-O-glucoside emerged as reliable biomarkers for distinguishing between AAW and GW. These findings suggest that metabolites unique to wheat grown in saline–alkaline soil may serve as biomarkers for developing stress-resistant varieties, warranting further study of their functional components in food products. Full article

Polyvinyl chloride (PVC), owing to its excellent electrical properties and low cost, is widely applied in the inner insulation and outer sheath of cables. To achieve early fault warning based on characteristic gases, this study integrates experimental testing with molecular simulations to systematically reveal the decomposition and gas generation characteristics of different PVC layers under electrical and thermal stresses. The results indicate that inner-layer PVC under electrical stress predominantly generates small-molecule olefins and halogenated hydrocarbons, while outer-layer PVC during thermal decomposition mainly produces hydrogen chloride, alkanes, and fragments of plasticizers. The surrounding atmosphere significantly regulates the gas generation pathways: air promotes the formation of CO₂ and H₂O, whereas electrical discharges accelerate the release of unsaturated hydrocarbons such as acetylene. By employing TG-FTIR, ReaxFF molecular dynamics, and DFT spectral calculations, a normalized infrared spectral library covering typical products was established and combined with the non-negative least squares method to realize quantitative deconvolution of mixed gases. Ultimately, a diagnostic system was constructed based on the concentration ratios of characteristic gases, which can effectively distinguish the failure modes of inner and outer PVC layers as well as different stress types. This provides a feasible approach for early detection of cable faults and supports intelligent maintenance strategies. Full article

The Muji Fault Zone (MJF) in the northeastern Pamir Plateau hosts a well-developed non-volcanic geothermal system, characterized by widespread hot springs and mud volcanoes—where core processes of geothermal fluids, including atmospheric precipitation recharge, shallow crustal circulation, carbonate-driven water–rock interactions, and CO₂-rich fluid discharge, are tightly coupled with regional intense crustal deformation and frequent seismic activity. We collected and analyzed 22 geothermal water samples and 8 bubbling gas samples from the MJF periphery, finding that the geothermal waters are predominantly of the HCO₃-Ca·Mg hydrochemical type, with hydrogen (δD: −103.82‰ to −70.21‰) and oxygen (δ¹⁸O: −14.89‰ to −10.10‰) isotopes indicating atmospheric precipitation as the main recharge source. The Na-K-Mg ternary diagram classified the waters as immature, reflecting low-temperature water–rock interactions in the shallow crust (<3 km), while noble gas isotopes (³He/⁴He: 0.03–0.09 Ra, Ra = 1.43 × 10⁻⁶) and carbon isotopes (δ¹³C-CO₂) confirmed fluid origin from crustal carbonate dissolution; SiO₂ geothermometry estimated thermal reservoir temperatures at 67–155 °C. Long-term monitoring (May 2019–April 2024) of Tahman (THM) and Bulake (BLK) springs revealed significant pre-seismic anomalies: before the 2023 Tajikistan Ms7.2 and 2024 Wushi Ms7.1 earthquakes, Na⁺, Cl⁻, and SO₄²⁻ concentrations showed notable negative anomalies (exceeding 2σ of background values) with synchronous trends between the two springs. Integrating these findings, a “Fault-Spring-Mud Volcano-Earthquake” fluid response model was established, providing direct evidence of deep-shallow fluid coupling in mud volcano–geothermal fluid interactions. This study enhances understanding of the dynamic evolution of non-volcanic geothermal systems under tectonic stress and clarifies the mechanisms of hydrogeochemical variations in fault-controlled geothermal systems, offering a robust scientific basis for advancing research on tectonic–fluid interactions in active fault zones of the northeastern Pamir Plateau. Full article

Background/Objectives: Glioblastoma, the most common primary tumor of the central nervous system, is characterized by high malignancy and poor prognosis. One of the main challenges in neurological disorders is to develop an effective treatment modality that can cross the blood–brain barrier. Nanoparticles are revolutionary for neurodegenerative diseases due to their targeted delivery and ability to overcome biological barriers. Cerium oxide (Ce₂O₃) nanoparticles are suitable for use as drug delivery systems. Methods: In our study, we investigated the anticancer mechanism using SN-38, lithium, and Ce₂O₃, a powerful agent used in GBM treatment. We evaluated their anticancer activities separately and in combination with U373 cell lines. GBM cell line U373 cells were cultured. Then, all groups except the control group were treated with different doses of SN-38 and lithium combination therapy with SN-38, lithium, and Ce₂O₃ combination therapy. The results were evaluated using MTT and ELISA tests. Results: When the results were examined, anticancer activity was detected at PTEN, AKT, mTOR, and BAX/Bcl-2 levels in the SN-38 + NPs 25 µg/mL + Lithium 50 µg/mL and SN-38 + NPs 50 µg/mL + Lithium 50 µg/mL dose groups. In addition, findings that inflammation markers were correlated with the apoptosis mechanism were obtained. Conclusion: This study is the first to report that combining lithium with SN-38 and NPs increased oxidative stress more than lithium with SN-38, leading glioblastoma cells to apoptosis and its potential anticancer activity. These results provide a basis for further investigation of its clinical application in cancer treatment. Full article

Our understanding of Ghrelin, an endogenous ligand of the growth hormone secretagogue receptor 1a (GHSR1a), has expanded from considering it to be a “hunger hormone” to a pleiotropic regulator of whole-body physiology. This review synthesizes the current advances spanning ghrelin biogenesis, signaling, and systems biology. Physiologically, preproghrelin processing and O-acylation by ghrelin O-acyltransferase (GOAT) generate acyl-ghrelin, a high-potency GHSR1a agonist; des-acyl ghrelin predominates in circulation and exerts context-dependent, GHSR1a-independent, or low-potency effects, while truncated “mini-ghrelins” can act as competitive antagonists. The emergence of synthetic ligands, agonists, antagonists, and reverse-agonists has provided the necessary tools to decipher GHSR1a activity. Recent cryo-EM structures of GHSR1a with peptide and small-molecule ligands reveal a bipartite binding pocket and provide a framework for biased signaling, constitutive activity, and receptor partner selectivity. Beyond the regulation of feeding and growth-hormone release, ghrelin modulates glucose homeostasis, gastric secretion and motility, cardiovascular tone, bone remodeling, renal hemodynamics, and innate immunity. Ghrelin broadly dampens pro-inflammatory responses and promotes reparative macrophage phenotypes. In the emerging scholarship on ghrelin’s activity in the central nervous system, ghrelin has been found to influence neuroprotection, stress reactivity, and sleep architecture, and has also been implicated in depression, Alzheimer’s disease, and substance-abuse disorders. Practical and transitional aspects are also highlighted in the literature: approaches for ghrelin stabilization; recent GHSR1a agonists/antagonists and inverse agonists findings; LEAP-2-based strategies; and emerging GOAT inhibitors. Together, structural insights and pathway selectivity position the ghrelin system as a druggable axis for the management of inflammatory diseases, neuropsychiatric and addiction conditions, and for obesity treatment in the post-GLP-1 receptor agonist era. Full article

Anxiety disorders affect over 280 million people globally and are associated with cognitive impairment. University students show a particularly high susceptibility, with studies reporting prevalent daily anxiety in this population. Physical activity (PA) has demonstrated efficacy in reducing stress and anxiety, potentially enhancing cognitive function. This scoping review examines existing evidence on the relationship between PA, anxiety symptoms, and academic performance in university students while identifying research gaps. Following PRISMA-ScR guidelines and Arksey and O’Malley’s framework, we analyzed observational and experimental studies from PubMed, Cochrane, Web of Science, and Scopus. A descriptive–analytical approach assessed the effects of exercise on anxiety and academic outcomes. Out of 362 records screened, 27 met the inclusion criteria. Evidence suggests PA interventions across intensity levels may alleviate anxiety symptoms and improve academic performance. However, experimental studies specifically targeting this population remain scarce. Current findings indicate PA interventions may reduce anxiety and potentially enhance academic performance in university students. Further experimental research is required to establish causality and elucidate underlying mechanisms. Full article

The internal organs of sea cucumbers (SCV) are a byproduct of the seafood processing industry and hold untapped potential as a functional food. This study investigates the antioxidant capacity of SCV and its regulatory effects on the gut microbiota in a mouse model of oxidative stress induced by chronic cold exposure. The results indicate that SCV possesses a rich nutritional composition, containing various components such as calcium, phosphorus, and polysaccharides, and exhibit strong scavenging activity against three types of free radicals in vitro: DPPH, OH⁻, and O₂⁻. SCV significantly reduced MDA levels in both serum and liver, while activating the Keap1-Nrf2/HO-1 pathway, leading to a significant decrease in the expression of HSP70 and HSP90 genes and a marked increase in Nrf2 gene expression, thereby alleviating oxidative damage. Histological analysis revealed that SCV alleviated liver damage, reducing hepatocellular vacuolization and inflammatory cell infiltration. Additionally, SCV modulated the diversity of the gut microbiota, increasing the abundance of Allobaculum, Turicibacter, Bifidobacterium, and Akkermansia, while enriching the synthesis pathway of vitamin B12 (PWY-7377). This study is the first to repurpose sea cucumber viscera waste into a functional food, demonstrating its dual mechanism of alleviating oxidative stress by activating the Keap1-Nrf2/HO-1 antioxidant pathway and regulating the gut microbiota. These findings offer an innovative strategy for the high-value utilization of agricultural by-products and the development of multifunctional health-promoting products. Full article

Caffeoylquinic acids (CQAs), a class of phenolic acid metabolites widely distributed in plants, encompass 15 positional isomers from mono- to tetra-esters, with 5-O-caffeoylquinic acid (5-CQA) as the predominant form. The biosynthesis of 5-CQA from phenylalanine proceeds through five primary pathways, which are finely regulated by environmental, hormonal, and transcription factors from families such as MYB, WRKY, and bHLH. These regulators control 5-CQA synthesis by binding specifically to the promoter regions of key structural genes, including PAL, 4CL and HCT/HQT. Subsequently, 5-CQA serves as a central precursor for the biosynthesis of other CQAs. In terms of bioactivity, CQAs possess remarkable pharmacological activities, encompassing antioxidant, antimicrobial, anti-diabetic, anti-inflammatory and anti-tumor properties. For instance, anti-inflammatory effects are demonstrated by the ability of 5-CQA to reduce key pro-inflammatory cytokines (e.g., TNF-α and IL-1β) and downregulate the TLR4/NF-κB pathway. The synergistic action of 5-CQA with ultraviolet-A reduced succinate-coenzyme Q reductase activity by approximately 72%, highlighting its potential to disrupt bacterial metabolism and combat antibiotic resistance. Furthermore, 3,4,5-triCQA exhibits potent anti-influenza virus activity, potentially through a mechanism distinct from existing neuraminidase inhibitors. Beyond medicine, CQAs show promise in light industry. They serve as antibiotic alternatives in livestock feed to enhance gut health, extend food shelf life through their antioxidant activity, and function as active ingredients in UV-protective skincare formulations. CQAs also enhance plant stress tolerance to cold, arsenic, and pests by mechanisms such as scavenging reactive oxygen species and inhibiting pest mobility. While this review consolidates progress in the biosynthesis and bioactivity of CQAs specifically with caffeoyl substituents, future efforts should leverage modern biotechnological tools and interdisciplinary approaches to bridge critical knowledge gaps in their biosynthesis, transport, and clinical translation. Full article