Search Results (35,590)

Phenolic-rich extracts from Satureja montana were evaluated before and after diazomethane treatment to determine how chemical derivatization influences their antioxidant capacity. Native and modified extracts were compared experimentally by measuring total phenolic content, ferric reducing antioxidant power (FRAP), and Fe²⁺-chelating ability. EN1 exhibited the highest concentration of phenolic compounds, reaching 1278.54 mmol/g, whereas EM2 retained only 1.99 mmol/g. In the FRAP assay, reducing power followed the order EN1 (9.36) > EN2 (3.72) > EM2 (2.08), with EM2 still exceeding caffeic, chlorogenic, and ferulic acids. In contrast, the modified extracts showed superior metal chelating capacity, with EM1 and EM2 displaying IC₅₀ values of 0.70 and 0.82 mg/mL, respectively, both markedly lower than those of the native extracts and the pure standards. To rationalize these differences, a DFT study was performed at the B3LYP/6-311++G(d,p) level, examining 18 proposed phenolic acids and their methylated derivatives associated with the extracts. All methylation reactions were thermodynamically favorable, particularly for compounds 18 (−57.10 kcal/mol), 16 (−53.96), 6 (−53.34), and 3, 9, and 11 (−52.71). Solvent effects were found to be structure-dependent: caffeic acid showed BDE values of 72.29, 73.59, and 74.43 kcal/mol in the gas phase, water, and benzene, respectively, whereas syringic acid displayed values of 80.44, 77.09, and 80.65 kcal/mol under the same conditions. Likewise, the ionization potential of caffeic acid decreased from 180.09 kcal/mol in the gas phase to 133.26 kcal/mol in water and 154.22 kcal/mol in benzene. Among all analyzed species, methyl 3,4-dihydroxycinnamate exhibited the lowest BDE (71.60 kcal/mol) as well as the most favorable ΔG°r toward HOO• (−11.06 kcal/mol). Full article

The phytochemical variability in Cannabis sativa L. chemovars represents an underexplored factor in environmentally sustainable nanomaterial production. In this study, three distinct chemovars, (i) High-Δ⁹-Tetrahydrocannabinol (THC) (89% THC), (ii) Balanced (60% Cannabidiol (CBD)), and (iii) High-CBD (89% CBD), were comparatively evaluated to determine their suitability for the green synthesis of silver nanoparticles (AgNPs). Ethanolic inflorescence extracts were used to recover bioactive secondary metabolites; among them, the High-CBD extract exhibited the highest total phenolic (3.34 mg gallic acid equivalent/g) and flavonoid (29.49 mg quercetine equivalent/g) contents, together with superior antioxidant capacity (53.16% 2,2-diphenyl-1-picrylhydrazyl free radical (DPPH) inhibition), indicating enhanced redox potential for nanoparticle formation. The terpene profile of High-CBD showed a dominance of myrcene (21.4%), contributing to the stabilization of the system. Using the High-CBD extract, predominantly spherical nanoparticles of 5 ± 0.9 nm were synthesized and confirmed by UV–vis, EDS, and TEM. The biogenic AgNPs demonstrated significant dose-dependent antibacterial activity, with minimum bactericidal concentration (MBC) of 1.0 mg/mL against Staphylococcus aureus and 4.5 mg/mL against Escherichia coli. These findings highlight the critical role of chemovar-dependent phytochemical composition and support a phytochemistry-guided approach for developing silver nanoparticles with potential biomedical applications. Full article

Background: Diabetes mellitus is a metabolic disturbance characterized by chronic hyperglycemia, which stems from defective secretion and/or action of insulin. D-Limonene has been studied for the confirmation of its antidiabetic and antioxidant effects. This paper aims to investigate the antidiabetic and antioxidants effects of D-Limonene in an experimental model of DM1. Methods: Female Wistar rats (180–250g) received streptozotocin (STZ, 45 mg/kg) intraperitoneally. Animals with capillary glycemia ≥ 250 mg/dL were considered diabetic. D-Limonene at oral doses of 12.5 mg/kg, 25 mg/kg and 50 mg/kg was administered during 28-day treatment. Water and food intake, weight gain and capillary glycemia were evaluated. At the end of the treatment, the following biochemical parameters were assessed: serum glucose, HbA1c, urea, creatinine, AST, ALT, GGT, ALP and albumin. The oxidative stress markers were determined in plasma, erythrocytes, and aortic homogenates: malondialdehyde, nitrite, myeloperoxidase, superoxide dismutase and catalase. Results: D-Limonene (25 and 50 mg/kg) significantly reduced serum glucose, HbA1c, AST, ALT, GGT and ALP when compared to DC, as well as plasma MDA and nitrite concentrations. Interestingly, D-Limonene (25 and 50 mg/kg) decreased both plasma and aortic myeloperoxidase activities, as well as increased both erythrocytic and aortic catalase activities. Conclusions: These findings, besides a marked D-Limonene-induced hypoglycemic effect, pave the way for further studies comprising a multi-target treatment by providing benefits on hepatic and vascular complications related to the diabetic condition. Full article

Corrosion damage is an important factor causing structural failure in offshore structures. In order to study the effect of local corrosion on the bearing property of H-shaped steel used in offshore structures, the rig substructure on an offshore platform was taken as the research object. Considering both local damage and the overall structural characteristics of the substructure, the main load-bearing H-shaped steel component was determined through testing. Based on the macroscopic characterization analysis of random pitting corrosion such as morphology, depth, diameter and location, a random pitting damage model was established by combining a regular cylindrical pit model with a MATLAB-based random number generation method. The influence of random pitting position on the bearing property of H-shaped steel is obtained by the simplified beam model and the multi-scale model embedded into the global substructure system respectively. The results show that pitting located at the flange end region produces the most severe stress concentration and results in the greatest degradation in bearing capacity, and corrosion on the upper flange leads to higher equivalent stress levels than that on the lower flange. The research results can provide some reference value for structural safety performance assessment. Full article

This study addresses the imperative need to extend the shelf life of the cape gooseberry (Physalis peruviana L.), a highly perishable yet nutritionally valuable fruit, through the development and optimization of active edible coatings (ECs). The synergy between cassava starch (Manihot esculenta Crantz) and lemon verbena essential oil (Aloysia citrodora), both bioactive components, was investigated for the formulation of protective coatings. A 2² factorial design explored the impact of cassava starch concentrations (8% and 10% w/v) and lemon verbena essential oil (LVEO) (1% and 3% v/v) on the sensory acceptability of coated cape gooseberries. Through binomial logistic regression analysis, it was determined that the formulation with 10% cassava starch and 3% LVEO (T4) exhibited significantly superior sensory acceptability, optimizing the perception of color, odor, flavor, texture, and overall appearance. This optimized formulation (T4) demonstrated a significant improvement in extending the shelf life of cape gooseberries up to 27 days at 10 °C, which is comparable to or exceeds values reported in previous studies on starch–based coatings in similar fruits (e.g., 15–21 days depending on formulation and storage conditions). This performance also exceeded the storage periods observed at 6 °C (6 days) and 8 °C (20 days). Physicochemical analyses revealed remarkable stability of pH and titratable acidity, as well as effective control of moisture loss and the maturity index, even at higher temperatures. Crucially, T4 exhibited superior antimicrobial activity, with a significant reduction in molds, yeasts, and total aerobes, particularly at 10 °C, suggesting an optimal synergistic interaction between the coating and the LVEO under slightly warmer storage conditions. These findings contribute to the advancement of sustainable preservation strategies of cape gooseberries, offering a sustainable solution that reconciles efficient shelf-life extension with consumer acceptability and optimizes storage conditions, with significant implications for reducing food waste and enhancing the global marketability of this fruit. Full article

Particulate matter is a significant component of air pollutants, especially PM_2.5-bound polycyclic aromatic hydrocarbons (PAHs), due to multiple toxicological effects on organisms. In this study, the concentrations of PM_2.5-bound PAHs at the two most important ports in Mexico (Veracruz and Manzanillo) were determined to identify emission sources and evaluate potential health impacts. Average PM_2.5 concentrations were higher in Veracruz (12.90 ± 4.77 μg/m³) than in Manzanillo (10.96 ± 3.99 μg/m³), although both were below Mexico’s current air quality standards. Total PAH concentrations were also higher in Veracruz (22.14 ± 16.76 ng/m³) compared to Manzanillo (11.65 ± 9.04 ng/m³). The identified PAHs and diagnostic ratios indicated different emissions patterns: in Manzanillo, concentrations were associated with high-temperature pyrogenic sources, while in Veracruz, greater contributions from mixed sources were observed. The ILCR assessment was 4.61 × 10⁻⁷ for Manzanillo and 8.77 × 10⁻⁷ for Veracruz, both below the accepted risk threshold. Despite relatively low health risk estimates, the presence of carcinogenic PAHs, such as benzo[a]pyrene, highlights the need for continuous monitoring and mitigation strategies in port environments. These results provide pioneering, highly valuable insights into the dynamics of air pollution in these Mexican ports and their potential health implications. Full article

This study investigated the bactericidal effect and examined the associated cellular damage of low temperature plasma (LTP) combined with slightly acidic electrolyzed water (SAEW) against Listeria monocytogenes. Single-factor experiments were conducted to assess the bactericidal efficacy under individual treatment conditions, followed by the evaluation of three different combination sequences. An orthogonal experimental design was performed to optimize the key parameters, and the optimal treatment conditions were determined as LTP at 45 W with an electrode spacing of 1 mm for 2 min, combined with SAEW at an available chlorine concentration (ACC) of 30 mg/L. Under these conditions, confocal laser scanning microscopy (CLSM) with SYTO 9/PI staining confirmed that the combined treatment caused cell death, as indicated by loss of membrane integrity in treated cells. A resuscitation assay further ruled out the viable but non-culturable (VBNC) state, as no bacterial growth was detected after 48 h of enrichment. The leakage of intracellular proteins and nucleic acids was measured using the Coomassie Brilliant Blue method combined with a microplate reader, and changes in cellular morphology were observed by scanning electron microscopy (SEM). The results demonstrated that SAEW+LTP treatment exerted a distinct effect, significantly disrupting bacterial cell membrane integrity, inducing the leakage of intracellular contents, and causing obvious morphological damage to the bacterial cells. In conclusion, the combined treatment of LTP and SAEW significantly improved the bactericidal efficiency against L. monocytogenes, which may be due to the combined disruptive effects on membrane integrity and subsequent structural and functional damage to the cells. Future investigations are needed to unravel the precise mechanisms, establish the efficacy against a wider panel of strains, and explore the potential for practical application in food matrices. Full article

Gold nanoparticles (AuNPs) have numerous applications in science and industry. Therefore, their potential phytotoxicity should be investigated. Garden cress (Lepidium sativum L.) is a useful model plant for assessing the effects of chemicals released into the environment. The aim of this study was to prepare alginate gels containing AuNPs for plant exposure experiments, evaluate their physicochemical properties, and determine their effects on selected biochemical parameters of garden cress seedlings. Gold nanoparticles were synthesized in sodium alginate at an initial concentration of 50 mg/L, using xylose and maltose as reducing agents. The gels were diluted with distilled water to obtain AuNP concentrations of 5 and 25 mg/L. Garden cress seeds were placed on filter paper soaked with the tested formulations, while distilled water and sodium alginate solutions without AuNPs served as controls. After 5 days of incubation at 20 °C under light conditions, the plant material was collected and selected bioactive compounds were determined. AuNP-containing gels significantly affected the biochemical status of the seedlings. In particular, AuNPs synthesized with xylose at 25 mg/L significantly increased the contents of photosynthetic pigments and total polyphenolic compounds. All tested AuNP formulations increased the antioxidant activity of seedlings, suggesting the activation of abiotic stress-related defense responses, however, direct markers of oxidative damage were not assessed in the present study. Overall, the results indicate that alginate-based AuNPs can modify selected biochemical parameters in garden cress seedlings, and these effects depend on nanoparticle concentration and reducing sugar used during synthesis, which may be relevant for the future development of plant-targeted nanomaterials for agricultural applications. Full article

In order to investigate the effects of bentonite and glass fiber on the macroscopic mechanical properties and microscopic mechanisms of cement soil in dry environments, a series of laboratory tests were conducted in this study, including drying tests under controlled environments (30 °C, 50% humidity), unconfined compressive strength (UCS) tests, digital image processing technology, and scanning electron microscopy (SEM) analyses. The moisture evaporation law, surface crack development process, UCS variation, and microstructure evolution of cement soil with different mix proportions (bentonite content: 0–9%; glass fiber content: 0–0.5%) were systematically analyzed. The results show that bentonite can significantly enhance the water retention capacity of cement soil, reduce the water evaporation rate, and increase the unconfined compressive strength by filling internal pores to densify the microstructure. Glass fibers form a three-dimensional network structure in the matrix, exerting a bridging effect to inhibit crack initiation and propagation, and optimize the mechanical properties. The unconfined compressive strength increases significantly with an increase in bentonite content (3–9%), and the optimal fiber content for strength improvement is determined as 0.3%. The synergistic effect of bentonite and fibers optimizes the interfacial bonding force between fibers and the matrix, which remarkably improves the anti-cracking performance of cement soil. Specifically, when the bentonite content is 6–9% and the fiber content is 0.3–0.5%, the cement soil maintains complete integrity after drying, with no obvious cracks on the surface. SEM analysis reveals that the addition of bentonite and fibers inhibits the expansion and connection of internal voids, avoiding the cycle of “void enlargement–stress concentration–crack propagation”. This study provides a scientific basis for the engineering application of cement soil in a dry environment. Full article

Marine organisms that episodically aggregate near coastal nuclear power plant water intakes pose a substantial risk to cooling water security. Predicting the spatial distribution of such high-risk species remains challenging because their occurrence is shaped not only by environmental conditions but also by complex trophic interactions. In this study, we model the habitat distribution of three high-risk nektonic species, Dotted gizzard shad (Konosirus punctatus), Japanese swimming crab (Charybdis japonica) and squid (Loligo sp.), in the cooling water intake area of a coastal nuclear power plant in eastern Liaodong Bay using generalized linear models (GLMs) and joint species distribution models (JSDMs). Based on summer surveys conducted in 2024–2025, we explicitly incorporated trophic linkages among target species, their prey, and predators within JSDMs. Model performance was evaluated using cross-validation based on AUC, RMSE, and coefficient of determination (R²). Our results indicate that water depth was the dominant environmental driver for all three species, while chlorophyll-a concentration and distance to the intake exerted species-specific effects. By incorporating interspecific trophic associations and environmental responses, JSDMs showed consistently improved predictive performance relative to GLMs, with approximately 1.5-fold higher R² values and 10–30% lower RMSE, while offering enhanced ecological interpretability. The models revealed strong positive associations between target species and both lower-trophic prey and higher-trophic predators, suggesting that top–down and bottom–up processes jointly regulate aggregation dynamics. This study demonstrates that integrating trophic interactions into species distribution modeling substantially improves predictions of high-risk marine species near coastal infrastructure and provides an ecological basis for proactive management of cooling water intake systems. Full article

Botrytis cinerea and Plasmopara viticola, the causal agents of grey mold and downy mildew, respectively, are two major grapevine pathogens whose control largely relies on synthetic fungicides, raising environmental and health concerns. Plant-derived secondary metabolites, particularly flavonoids involved in plant defense, represent promising sustainable alternatives. Among them, sakuranetin, a flavanone aglycone known for its antifungal activity in rice, remains poorly explored for grapevine protection. In this study, sakuranetin was purified from cherry branches (48 mg) and structurally characterized using UHPLC-ESI-QTOF-MS and NMR analyses. Its antifungal activity against B. cinerea and P. viticola was evaluated through in vitro, in vivo and in planta assays. For B. cinerea, our results showed a significant in vitro inhibition of mycelium growth, with EC₅₀ values of 16.43 mg·L⁻¹, while no protection of detached berries was observed. Against P. viticola, sakuranetin has no effect on the release of zoospores, but there is a total inhibition of spore germination at 1 mg·L⁻¹ in vitro, confirmed in vivo on a foliar disc. In planta, no significant protection is observed at 25 mg·L⁻¹, even if some targeted defense genes are induced. Further studies are needed to determine the best concentration of sakuranetin to use to manage B. cinerea and P. viticola in planta. Full article

Fluoroquinolone antibiotics, like danofloxacin, are considered as crucial veterinary drugs due to their high antibacterial potential, a broad spectrum of activity and good pharmacological properties. However, owing to the widespread use of this group of pharmaceuticals, microbial resistance to them is becoming a serious worldwide concern. In the present study, novel silver and copper complexes of danofloxacin were prepared and characterized using ¹H NMR, ¹⁹F NMR and IR spectroscopy, ESI-MS spectrometry, and elemental analysis. The antimicrobial properties of the obtained complexes were determined against selected bacterial and fungal strains, including yeast and conidia-forming fungi. Additionally, toxicities of danofloxacin metal-based complex solutions were assessed toward eukaryotic cells. The obtained results indicate that silver(I) and copper(II) complexes of danofloxacin exhibit good antimicrobial activity against bacteria that are important from the veterinary point of view, like Listeria monocytogenes or Campylobacter jejuni, in concentrations which are not cytotoxic. The MBC values of metal-based danofloxacin complexes for the mentioned strains were 1.5 times lower than those obtained for danofloxacin. Additionally, the solution of the novel silver–danofloxacin complex was found to have a fungicidal effect against the studied Candida and Aspergillus strains. Full article

Background/Objectives: To evaluate ocular disease and eye care utilization among adults with vitamin A deficiency (VAD) in a high-resource healthcare setting, with particular emphasis on nutritional etiologies, clinical nutrition oversight, and outcomes associated with severity of deficiency. Methods: A retrospective chart review was conducted at Dartmouth Hitchcock Medical Center (DHMC) from 1 January 2019 through 31 December 2022. Adults (>18 years) with measured serum retinol concentrations were identified, and data were extracted on retinol concentration, diagnosis, referring service, and vital status. Patients with VAD (serum retinol <32.5 µg/dL per our laboratory threshold) underwent detailed chart review, including social determinants of health and documented nutritional risk factors. For patients with VAD who received an ophthalmologic evaluation, slit lamp findings, ocular symptoms, duration of deficiency, and vitamin A treatment were assessed. Results: VAD was identified in 752 of 2725 patients (27.7%) tested for VAD, and 330 patients had concentrations below the World Health Organization (WHO) threshold for VAD (<20 µg/dL). Hepatic, nutritional, and malabsorptive conditions were prominent contributors, including cirrhosis related to alcohol use or hepatitis C virus (30%), malnutrition or malabsorption following bariatric surgery (24%), and pancreatic insufficiency (20.1%). Food insecurity data were incomplete but showed no significant association with vitamin A concentration. Despite biochemical evidence of deficiency, only 72 patients with VAD (9.6%) underwent ophthalmologic evaluation, and only three were referred specifically due to VAD. Clinical signs or symptoms consistent with xerophthalmia were observed in 21% of those evaluated, and 18% demonstrated corneal findings. Vitamin A supplementation was documented in just over half of symptomatic patients, with objective or symptomatic improvement noted in three cases. VAD was explicitly acknowledged in only 9.7% of ophthalmology notes. Increasing severity of VAD was strongly associated with mortality (p < 0.001), independent of food insecurity, which showed no association with serum retinol concentrations. Conclusions: In this high-resource clinical setting, VAD is common in an at-risk population and largely driven by nutrition-related disease states affecting absorption, metabolism, and hepatic storage. Despite clear biochemical deficiency and associated mortality risk, VAD is underrecognized, undertreated, and infrequently linked to ocular evaluation, highlighting a critical gap in nutrition-focused screening, interdisciplinary communication, and proactive vitamin A assessment in medically complex adults. Full article

Porous, crystalline gamma-Al₂O₃ coatings with a thickness of (6 ± 0.5) μm and a uniform distribution of rare earth (RE) dopants are synthesized by plasma electrolytic oxidation of aluminum at a current density of 150 mA/cm² in a boric acid and borax (BB) solution containing added RE oxide particles (Ho₂O₃, Tb₄O₇, and Pr₆O₁₁) at concentrations of 1, 2, and 4 g/L. The concentration of RE oxide particles in the BB solution determines the amount of RE elements incorporated into the coatings but does not significantly affect their surface morphology, crystal structure, or light absorption properties. The coatings exhibit high absorption in the middle/near-ultraviolet region, characteristic of Al₂O₃. Typical 4f-4f transitions of Ho³⁺, Tb³⁺, and Pr³⁺ are observed in the photoluminescence spectra. Photocatalytic evaluations using methyl orange degradation under simulated solar irradiation show that RE doping significantly enhances photocatalytic efficiency. Peak degradation efficiencies are achieved at a concentration of 4 g/L for all RE oxides. After 8 h of irradiation, maximum degradation reaches 88%, 92%, and 85% with pseudo-first-order rate constants (k_app) of about 0.274 h⁻¹, 0.339 h⁻¹, and 0.232 h⁻¹ for coatings synthesized in BB with 4 g/L Ho₂O₃, Tb₄O₇, or Pr₆O₁₁, respectively. In comparison, the pristine Al₂O₃ coating achieves only about 50% degradation (k_app ≈ 0.087 h⁻¹). Photoluminescence indicates that RE³⁺ ions serve as effective charge-carrier traps, suppressing electron–hole pair recombination. RE-doped Al₂O₃ coatings demonstrate exceptional structural stability and reusability over six cycles, highlighting their potential for sustainable wastewater remediation. Full article

This study developed a dual-antigen enzyme-linked immunosorbent assay (ELISA) based on σB protein and genotype 5-specific σC protein of avian reovirus (ARV). First, σB and σC proteins were expressed and purified using recombinant technology. Through optimization of coating conditions, the optimal antigen combination was determined to be a mixture of the two proteins at a 1:3 molecular ratio (total concentration: 0.8 μg/mL). Key parameters of the indirect ELISA were optimized via checkerboard titration. Validation confirmed that the dual-antigen ELISA exhibited a sensitivity of 1:3200 against genotype 5 ARV-positive sera, with no cross-reactivity and a coefficient of variation of 2.9–8.6%, demonstrating excellent reproducibility. In application testing, the method specifically detected serum antibodies against genotype 5 ARV variant strains, achieving a 100% positive detection rate in experimental chickens within the first week post-challenge and effectively monitoring dynamic antibody changes in infected flocks. Furthermore, the detection rate for genotype 5-positive serum samples (100%) was significantly higher than that of a commercial kit (75%). This dual-antigen indirect ELISA overcomes the sensitivity limitations associated with conventional genotype 5 ARV detection methods and provides a reliable tool for epidemiological surveillance and infection monitoring. Full article