Search Results (1,247)

The objective of this study was to evaluate the protective effect of curcumin (Cur) on reproductive toxicity induced by fumonisin B₁ (FB₁) in laying ducks during the peak egg-laying period. A total of seventy-two 50-week-old Cherry Valley ducks were randomly assigned to four groups: control, FB₁ (30 mg/kg), Cur (200 mg/kg), and Cur + FB₁ (200 mg/kg + 30 mg/kg). The experiment lasted for 35 days. Our results showed that cur supplementation effectively restored the reductions in final body weight (p = 0.005) and oviduct length (p = 0.020) induced by FB₁ exposure. Residual FB₁ concentrations in serum, liver, and ovaries were markedly increased in the FB₁-treated group, while Cur significantly decreased the FB₁ residual in duck liver (p < 0.05). Meanwhile, Cur supplementation markedly counteracted the FB₁-induced reductions in serum total protein, albumin, triglycerides, and high-density lipoprotein induced by FB₁ exposure. Cur supplementation effectively regulated FB₁-induced oxidative stress, inflammation, and endocrine disruption. Specifically, Cur lowered FB₁-induced malondialdehyde levels (p < 0.010), attenuated interleukin-1β increase (p = 0.083), and reversed the reduction in immunoglobulin G levels. FB increased the levels of hormones associated with duck reproduction, including estradiol, follicle-stimulating hormone, and luteinizing hormone; in contrast, curcumin supplementation decreased the levels of these hormones (p < 0.010). Histopathological analysis revealed that Cur significantly alleviated the inflammation and necrosis in the liver, kidneys, ovaries, and oviducts induced by FB₁. In conclusion, dietary Cur supplementation effectively alleviated FB₁-induced reproductive toxicity in laying ducks by enhancing antioxidant capacity, improving lipid metabolism, and restoring hormonal homeostasis. Full article

Seasonal fluctuations in the chemical composition of fine particulate matter (PM_2.5) are known to influence its toxicological properties; however, their integrated biological effects remain incompletely understood. In this study, PM_2.5 was continuously collected over two consecutive years at a single urban site in Japan and classified by season. The samples were comprehensively characterized for ionic species, metals, carbonaceous fractions, and polycyclic aromatic hydrocarbons (PAHs), and their pulmonary effects were evaluated in vivo following intratracheal administration in mice. Seasonal PM_2.5 exhibited pronounced compositional differences, with higher levels of secondary inorganic aerosol components in summer and enrichment of PAHs and mineral-associated components in winter. These seasonal differences translated into distinct biological responses. Reactive oxygen species (ROS) production (1.6–2.7-fold increase) and bronchoalveolar lavage (BAL) neutrophil infiltration were strongly associated with PAH-rich PM_2.5, whereas interleukin-1α (IL-1α) showed robust positive correlations with mineral components, including K⁺, Ca²⁺, and Mg²⁺, which were predominantly enriched in winter PM_2.5. In contrast, secondary inorganic aerosol species displayed a limited capacity to induce IL-1α. Compared with summer samples, winter PM_2.5 induced significantly higher levels of ROS production and IL-1α (approximately 1.5–2.6-fold increase). Using TLR2- and TLR4-deficient mice, we further demonstrated that PM_2.5-induced increases in BAL cell counts, ROS, IL-6, and TNF-α were partially attenuated in TLR4 knockout mice, indicating a contributory but not exclusive role for TLR4 signaling in PM_2.5-driven pulmonary inflammation. Collectively, these findings demonstrate that seasonal variations in PM_2.5 composition, not particle mass alone, critically shape oxidative stress and innate immune responses in the lungs. In particular, winter PM_2.5 enriched in mineral-associated components preferentially activates IL-1α-mediated alarmin pathways, underscoring the importance of the particle composition in determining seasonal air pollution toxicity. Full article

Efficient mixing in stirred tanks is essential for chemical and biochemical processes. Tubular baffles offer potential energy savings and multifunctionality (e.g., as heat exchangers); however, their interaction with common impeller types is not well understood. This study uses computational fluid dynamics (CFD) simulations to evaluate the hydrodynamic performance of a novel tubular baffle design compared to conventional flat baffles with three impellers: a Rushton turbine (RT), a pitched blade turbine (PBT), and a hydrofoil (HE3). Dimensionless analysis (power number, N_P; and pumping number, N_Q), flow visualization, and vorticity dynamics were employed. The results show that, by attenuating large-scale recirculation, tubular baffles reduce power consumption by 64%, 13%, and 23% for the HE3, PBT, and RT, respectively. However, the HE3 impeller experienced a 30% decrease in pumping capacity, which confined the flow to the lower tank. The PBT showed a 10% increase in N_Q and intensified bottom circulation. The RT uniquely generated distributed, high-intensity turbulence along the baffle height while maintaining its characteristic dual-loop structure. The analysis critiques the local pumping efficiency metric and advocates for a global flow assessment. The HE3 is optimal for efficient bulk blending at low power; the PBT is optimal for strong bottom circulation processes; and the RT is optimal for applications requiring enhanced interfacial processes, where baffles serve a dual function. This work provides a framework for selecting energy-efficient agitation systems by coupling impeller performance with global tank hydrodynamics. Full article

The vibration compaction behavior of fully graded fresh concrete differs fundamentally from that of conventional two-graded concrete. Based on measured vibration responses of an internal vibrator and sinking-ball tests, an energy transfer model for fully graded concrete was established by incorporating the effects of aggregate-specific surface area, paste–aggregate ratio, dynamic damping, and natural frequency, and the spatiotemporal attenuation of vibration energy in fresh concrete was systematically analyzed. Experimental results indicate that fully graded concrete exhibits a higher energy absorption capacity during the early stage of vibration, with a maximum energy absorption rate of 423 W and a peak energy transfer efficiency of 76.3%, both of which are significantly higher than those of two-graded concrete at the same slump. However, as a dense aggregate skeleton rapidly forms, the energy absorption efficiency of fully graded concrete decreases more rapidly during the middle and later stages of vibration, showing a characteristic pattern of “high initial absorption followed by rapid attenuation.” Through segregation assessment and porosity analysis, a safe vibration energy range for fully graded concrete was quantitatively determined, with lower and upper energy thresholds of 159.7 J·kg⁻¹ and 538.5 J·kg⁻¹, respectively. In addition, the experiments identified recommended vibration durations of 30–65 s and effective vibration influence radii of 22–85 mm for fully graded concrete under different slump conditions. These findings provide a quantitative basis for the control of vibration parameters and energy-oriented construction of fully graded concrete. Full article

Influenza A virus (IAV) continues to present a threat to public health, highlighting the need for safe and multi-target antivirals. In this study, anti-influenza activity, airborne transmission blocking capacity, and immunomodulatory effects of Cnidium monnieri polysaccharides (CMP) were evaluated. Cytotoxicity in A549 cells was assessed by CCK-8 (CC₅₀ = 8.49 mg/mL), antiviral efficacy against A/California/04/2009 (CA04) by dose–response (EC₅₀ = 1.63 mg/mL), and the stage of action by time-of-addition assays (pre-, co-, post-treatment). A guinea pig model infected with CA04 was used for testing the effect of pre-exposure CMP on transmission, with readouts including nasal-wash titers, seroconversion, lung index, and tissue titers (EID₅₀). RT-qPCR was employed to quantify the mRNA expression levels of proinflammatory cytokines, including TNF-α, IL-1β, and IL-6, in lung tissue, while Western blot analysis was performed to assess the expression and phosphorylation status of key proteins involved in the NF-κB signaling pathway. CMP suppressed viral replication in vitro within non-cytotoxic ranges, and pre-treatment—rather than co- or post-treatment—significantly reduced titers and cytopathic effect, consistent with effects at pre-entry steps and/or host priming. In vivo, pre-exposure CMP lowered nasal shedding, reduced aerosol transmission (3/6 seroconverted vs. 6/6 controls), decreased lung indices, and diminished tissue viral loads; IAV was undetectable in trachea at 7 days post-infection in pre-exposed animals, and nasal-turbinate titers declined relative to infection controls. Moreover, during in vivo treatment in mice, CMP significantly suppressed the levels of inflammatory cytokines (TNF-α, IL-1β, and IL-6) in lung tissue. This effect was mechanistically associated with CMP-mediated regulation of the NF-κB signaling pathway, leading to attenuation of inflammatory responses. These data indicate that CMP combines a favorable in vitro safety and efficacy profile with inhibition of airborne spread in vivo, supporting further mechanistic, pharmacokinetic, and fractionation studies toward translational development. Full article

Liver fibrosis is characterized by an excessive accumulation of extracellular matrix (ECM) proteins as a wound-healing response to chronic liver injury, leading to tissue scarring and organ dysfunction. Natural compounds, including phytonutrients and polyphenols, have been shown to exert protective effects by reducing profibrotic biomarkers in vitro and in vivo models. Here, we provide the first evidence that the polyphenol hesperidin (HE) can counteract the onset of fibrotic responses in an ex vivo mouse liver fibrosis model induced by Transforming Growth Factor-β1 (TGF-β1) (5 ng/mL). Notably, HE drives early ECM remodeling in the fibrotic mouse liver tissue. Fibrosis-related parameters were assessed at both the transcriptional and translational levels after treatment with HE at increasing concentrations of 50, 75, and 100 µg/mL. Interestingly, HE at 75 µg/mL exerted the strongest beneficial effect, significantly decreasing the gene expression of α-SMA, SERPINH-1, FN-1, VIM and COL1A1 and counteracting the TGF-β1-induced upregulation of key fibrotic markers, including α-SMA, COL1A2, and VIM, reflecting its capacity to attenuate myofibroblast activation and ECM production and modulating membrane lipid peroxidation. Furthermore, HE inhibited SMAD2 phosphorylation, suggesting that its antifibrotic activity may involve the modulation of the TGF-β/SMAD signaling pathway. Moreover, it promoted an anti-inflammatory response, due to a decrease in IL-1β and IL-6 expression. Our study highlights the potential of the ex vivo model as a platform for evaluating the antifibrotic efficacy of natural molecules, and it suggests significant translational implications and new opportunities for developing innovative therapeutic strategies. Full article

The global transition towards sustainable energy has accelerated the development and deployment of offshore wind turbines. Jacket foundations, commonly installed in intermediate to deep water depths to access available space and higher load capacities, are built to withstand intensified hydrodynamic loads. Due to their structural complexity near the seabed, however, they are prone to local and global scour, which can compromise stability and increase maintenance costs. While extensive research has addressed scour protections around monopiles, limited attention has been given to complex foundation geometries or even hybrid configurations that combine energy-harvesting devices with structural support. These hybrid systems introduce highly unsteady flow fields and amplified turbulence effects that current design frameworks appear to be unable to capture. This study provides an experimental characterisation of scour damage in riprap-protected jackets as well as additional tests for a hybrid jacket foundation. A novel adaptation of a high-resolution overlapping sub-area methodology was employed. For the first time, it was successfully applied to quantify the damage to riprap protections for a complex offshore foundation. Results revealed that, although hybrid jackets showed the capacity to attenuate incident waves, the scour protection experienced damage numbers (S_3D) two to six times higher than conventional jackets due to flow amplifications. The findings highlight the need for revised design guidelines that can account for the complex hydrodynamic-structural interactions of next-generation marine harvesting technologies integrated into complex foundations. Full article

Periodontitis is a chronic non-communicable inflammatory disease in which oxidative stress plays an important role in tissue destruction and alveolar bone loss. Excessive production of reactive oxygen species disrupts redox homeostasis, activates inflammatory signaling pathways, and promotes regulated cell death processes such as pyroptosis and ferroptosis. The Nrf2/Keap1 pathway is a key regulator of antioxidant defense and cellular adaptation to redox imbalance. Impaired Nrf2 signaling has been associated with enhanced oxidative injury, NF-κB and NLRP3 inflammasome activation, osteoclast-driven bone resorption, and reduced regenerative capacity in periodontal tissues. Experimental studies suggest that Nrf2 activation can restore the redox balance and attenuate inflammation and bone destructive responses in a periodontal model. Moreover, therapeutic approaches involving phytochemicals, microbial-derived metabolites, and redox-responsive biomaterials have been reported to influence Nrf2-related signaling in experimental settings. However, the majority of the available evidence is derived from in vitro or animal studies, and the relevance of these findings to clinical periodontitis remains to be established. This review summarizes the current advances linking oxidative stress, redox signaling, cell death pathways, and bone remodeling with Nrf2 dysfunction in periodontitis and outlines the key mechanistic insights while highlighting the existing knowledge gaps. Full article

The primary objective of this work is to provide new solutions to increase impact protection, using a three-dimensional textile imbibed with a shear-thinning fluid. An extensive analysis showed a scarcity of research papers related to the damping capacity of deformable porous materials imbibed with non-Newtonian fluid. No studies were found for shear-thinning fluid flow inside highly compressible foams or other soft, porous materials. The damping capacity of the imbibed material was evaluated using impact with a dropping weight. Polyvinyl alcohol solution mixed with water was used for imbibition of a three-dimensional textile. Hydrophilized carbon nanofibers were also added to the solution to augment the shear-thinning behavior. The measured impact force for imbibed samples showed an important reduction compared to the impact force for the dry material. This research does not focus on flow phenomena at the microstructural level but instead aims to highlight the macroscopic attenuation effect that occurs during the compression of the imbibed material. Full article

This study develops a two-dimensional numerical model to investigate the hydrodynamic performance of a floating breakwater coupled with flexible wave-dissipating structures (FWDS). The model integrates the immersed boundary method with a finite element structural solver, enabling accurate simulation of fluid–structure interactions under wave excitation. Validation against benchmark cases, including cantilever beam deflection and flexible vegetation under waves, confirms the model’s reliability. Parametric analyses were conducted to examine the influence of the elastic modulus and height of the FWDS on wave attenuation efficiency. Results show that structural flexibility plays a crucial role in modifying wave reflection, transmission, and dissipation characteristics. A lower elastic modulus enhances energy dissipation through large deformation and vortex generation, while higher stiffness promotes reflection with reduced dissipation. Increasing the height of the FWDS improves overall wave attenuation but exhibits diminishing returns for long-period waves. The findings highlight that optimized flexibility and geometry can effectively enhance the energy-dissipating capacity of floating breakwaters. This study provides a theoretical basis for the design and optimization of hybrid floating breakwaters integrating flexible elements for coastal and offshore wave energy mitigation. Full article

Pseudomonas aeruginosa is a well-studied bacterium, recognized as a primary infectious agent due to its capacity to form multi-resistant biofilms. Various strategies to inhibit the pathogenic activity and biofilm formation of Pseudomonas aeruginosa are under investigation. This study examines the interaction between these pathogenic biofilms and the antibiotic Tobramycin, both in the presence and absence of supernatants from the probiotic organism, Lactiplantibacillus plantarum, using Fourier transform infrared (FTIR) spectroscopy. A Universal Attenuated Total Reflection accessory enabled rapid acquisition of infrared spectra from Pseudomonas aeruginosa biofilms grown on Teflon membranes and subsequently exposed to antibiotic and/or probiotic agents. Spectral changes induced by these agents were analyzed using deconvolution procedures, difference spectra, and ratiometric analysis. The results show that antibiotic treatment modifies the lipid, protein, nucleic acid, and carbohydrate components of bacterial biofilms. Specifically, the spectral analysis suggests that antibiotic treatment alters membrane structural organization, inhibits protein synthesis, and affects sugar and polysaccharide production. Additional treatment with a probiotic agent further changes the characteristics of the bacterial biofilm. FTIR spectroscopy with the Attenuated Total Reflection spectra collection geometry is confirmed as an effective method for rapid spectral acquisition and the use of Teflon membranes further facilitates the application of this vibrational technique in microbiology. Full article

Background: Humulus lupulus (Hops) possesses a diverse array of bioactive compounds with reported antioxidant, anti-inflammatory, antibacterial, and neuroprotective properties. However, most studies have focused on isolated components, whose purification is costly and yields limited quantities. Objective: In this study, we aimed to evaluate whether a complete Hops extract could exert antioxidant and neuroprotective effects. Methods: First, the ability of Hops extract’s free radical scavenging capacity against superoxide, hydroxyl radical, and peroxynitrite was discovered using combinatorial chemical assays. Moreover, the used Hops extract prevented both DNA and protein degradation induced by hydroxyl radicals. Next, rats were orally administered with three different doses of Hops extract (10, 15, and 20 mg/kg/day) for 7 consecutive days. Results: Ex vivo analyses of brain tissues revealed that Hops pre-treatment attenuated FeSO₄-induced lipid peroxidation, increased the GSH/GSSG ratio and downregulated both glutathione peroxidase and reductase activities. Additionally, the expression of the nuclear factor erythroid 2-related factor (Nrf2) gene was significantly elevated in the striatum of Hops-treated animals. To further explore neuroprotection, we evaluated the effect of Hops (15 mg/kg/day) in an in vivo model of excitotoxicity induced by quinolinic acid (QUIN). Pre-treatment with the Hops extract reduced QUIN-induced circling behavior, increased the translocation of NRF2 to the nucleus and decreased apoptosis in the striatum. Conclusion: These findings suggest that the whole Hops extract enhances redox resilience in the brain and confers protection against oxidative and excitotoxic insults. Full article

Safe overwintering is a challenging issue in rearing management that is inevitably faced by beekeepers in high-latitude regions. Under the combined influence of multiple factors, the overwintering loss rate of Western honey bees has risen continuously, and investigating the molecular mechanisms related to safe overwintering has become key. The Hunchun bee, an Apis mellifera ecotype in Jilin Province, China, exhibits strong overwintering ability during an overwintering period of more than five months. To investigate the molecular mechanisms of its cold resistance, we conducted a comparative transcriptomic analysis between the summer breeding period (July) and different overwintering intervals (November, December, January, and February), and then systematically identified key genes and signaling pathways related to cold resistance. The results showed that the highest number of differentially expressed genes (DEGs) was found between December and July. Compared with July, the upregulated genes in Hunchun bee in December were significantly enriched in several pathways, such as ion transport and neuroactive ligand–receptor interactions, and the downregulated genes were significantly enriched in pathways related to fatty acid metabolism, glutathione metabolism, and the peroxisome. Notably, a total of 378 shared DEGs were obtained from the four comparison groups, and several candidate cold-resistant gene families, such as AFPs, HSPs, C₂H₂-ZFPs, STKs, and LRRCs, were identified among the shared DEGs of the winter season. Additionally, 749 shared DEGs related to protein modification and metabolic process regulation were identified between the four successive overwintering intervals. Four shared genes, including sensory neuron membrane protein 1 (SNMP1), were revealed by pairwise comparison of the four intervals. The above results collectively indicate that the Hunchun bee attenuates winter-induced stress responses during the overwintering process by maintaining osmotic pressure balance, reducing fatty acid metabolism, increasing antioxidant capacity, and synthesizing cold-resistant macromolecular proteins. It was also found that chemical signal perception may serve a role in maintaining the stability of the overwintering bee colony. The key genes and pathways related to cold resistance identified in this study not only provide a basis for explaining the overwintering molecular mechanism for Apis mellifera of Hunchun bee but also offer key data to improve overwintering management strategies for Western honey bees. Full article

Exercise-induced fatigue involves oxidative stress and metabolic dysregulation. While the anti-aging protein α-Klotho regulates metabolism and oxidative stress, its role in exercise fatigue is unexplored. This study investigated whether α-Klotho supplementation mitigates cumulative exercise-induced fatigue and elucidated the underlying tissue-specific mechanisms. Male C57BL/6J mice were divided into three groups (n = 10 per group), the control group, fatigue treated with saline, or α-Klotho (0.2 mg/kg, i.p. daily) group. Fatigue was induced by a 6-day exhaustive swimming protocol (5% body weight load). Tissues were collected 24h post-final exercise. Assessments included daily exhaustion time, grip strength, serum creatine kinase (CK), urea nitrogen (BUN), oxidative stress markers (H₂O₂, MDA, SOD, GSH/GSSG), tissue glycogen, and pathway protein expression (Western blot). α-Klotho supplementation prevented exercise-induced weight loss and restored grip strength. While exhaustive exercise markedly increased serum CK and BUN levels, α-Klotho selectively normalized CK without effecting serum BUN. α-Klotho attenuated oxidative damage by reducing hydrogen peroxide levels while enhancing antioxidant capacity, accompanied by activation of the NRF2/HO-1 pathway and further upregulation of PGC-1α. Notably, α-Klotho induced striking hepatic glycogen supercompensation through activation of the AKT/GS signaling pathway and upregulation of GLUT4, whereas muscle glycogen levels remained unchanged. In conclusion, α-Klotho ameliorates cumulative exercise-induced fatigue through dual recovery-phase mechanisms: NRF2/HO-1-mediated antioxidant protection in skeletal muscle and AKT/GS-triggered hepatic glycogen supercompensation, thereby facilitating oxidative stress resolution and enhancing energy reserve restoration. Full article

Water reservoirs are critical components of hydrological systems that mitigate floods and droughts, but their long-term performance under climate change and variable socioeconomic conditions remain insufficiently documented. This study examines the Bahlui River basin (northeastern Romania), where 17 reservoirs constructed mainly between the 1960s and 1980s have been operational for more than five decades. Using the most recent technical reservoir reports, land-use evolution, and present operational functions, the contribution of man-made reservoirs to flood attenuation and drought buffering over time was appraised. Flood mitigation is the most consistent and reliable function, with peak-flow reductions commonly exceeding 60–90% of design discharges at the basin scale. Engineered drought mitigation functions (irrigation and industrial water supply) have decreased significantly as a result of socioeconomic changes started in 1989. However, the gradual expansion of green infrastructure, such as wetlands and riparian vegetation, has improved passive water retention and low-flow buffering capacity. These unanticipated developments have resulted in variable levels of hybrid hydrological resilience. The findings show that, while artificial reservoirs have strong flood-control capacity over long periods of time, their contribution to drought mitigation is increasingly dependent on the integration of ecological components, emphasizing the importance of green-gray interactions in long-term reservoir management. Full article