Search Results (144)

Cancer and multidrug-resistant microbial infections remain major global health challenges, underscoring the need for multifunctional, biocompatible, and environmentally sustainable therapeutic platforms. Herein, selenium–hyaluronic acid nanoconjugates (Se/HA NPs) were synthesized through an eco-friendly ascorbic acid-mediated reduction approach to improve the bio-functional stability and therapeutic performance of selenium-based nanomaterials. The formation of Se/HA NPs was confirmed by transmission electron microscopy (TEM), X-ray diffraction (XRD), energy-dispersive X-ray spectroscopy (EDX), and Fourier-transform infrared spectroscopy (FTIR). FTIR analysis supported the involvement of ascorbic acid- and hyaluronic acid-associated functional groups in nanoparticle formation and stabilization. TEM revealed well-dispersed, predominantly spherical nanoparticles with diameters ranging from 29.72 to 80.38 nm, while XRD confirmed their crystalline nature with an average crystallite size of 31.2 nm. Biologically, Se/HA NPs exhibited strong antibacterial activity against Enterococcus faecalis (21 mm), Staphylococcus aureus (24 mm), Escherichia coli (25 mm), and Klebsiella pneumoniae (27 mm), outperforming hyaluronic acid alone and showing activity comparable to standard antibiotics, with a minimum inhibitory concentration (MIC) of 15.62 µg/mL. Notably, Se/HA NPs showed pronounced antifungal activity against Candida albicans, with an inhibition zone of 34 mm and an MIC of 7.8 µg/mL. In MG-63 osteosarcoma cells, Se/HA NPs demonstrated potent cytotoxicity, with a half-maximal inhibitory concentration (IC₅₀) of 8.36 µg/mL compared with 746.37 µg/mL for hyaluronic acid. Moreover, Se/HA NPs enhanced wound closure to 73.41% and showed strong anti-inflammatory activity, with an IC₅₀ of 5.37 µg/mL, demonstrating multifunctional bioactivity. Full article

Selenium plays a crucial role in estuarine biogeochemistry, balancing essential nutrient functions with potential environmental toxicity. This study examines the seasonal distribution of dissolved Se species, including volatiles, in the Adour estuary in relation to anthropogenic influences. To characterize major Se inputs from upstream watersheds to downstream tributaries, water samples were collected at low tide during three different seasons in upstream freshwaters, industrial/urban effluents and downstream estuarine waters. A tidal-cycle sampling campaign was conducted under low discharge conditions to assess Se dynamics during downstream estuarine mixing. Total dissolved Se (TDSe) concentrations ranged from 71 (pristine river) to 656 ng L⁻¹ (industrial/urban-impacted tributaries). TDSe correlated strongly with nitrate (r = 0.84) in upstream waters, indicating significant agricultural and livestock contributions at the watershed scale. Selenate was the dominant species, followed by Se(-II+0) fraction and selenite. Volatile Se compound concentrations varied from 51 to 2757 pg L⁻¹. Seasonal changes suggest that Se speciation is mainly controlled by watershed inputs derived from land use (agricultural and livestock practices) rather than downstream estuarine inputs. This speciation study further indicates that Se reactivity/bio-availability in estuarine systems can be largely influenced by anthropogenic activities, although further characterization of the aqueous reduced Se fraction is still needed. Full article

Background: Intestinal barrier dysfunction is a hallmark of inflammatory bowel disease (IBD), yet the clinical significance of tight junction (TJ) remodeling remains unclear. We investigated whether alterations in the expression and localization of key TJ proteins are associated with disease activity and clinical outcomes in IBD. Methods: This retrospective, single-center study included patients with Crohn’s disease (CD; n = 100), ulcerative colitis (UC; n = 120), and healthy controls (n = 80). Immunohistochemistry was used to assess the expression and subcellular localization of occludin and claudin-1 separately in surface (SE) and crypt epithelium (CR), with staining classified as predominantly membranous (regular) or cytoplasmic (irregular). The primary endpoint was IBD-related hospitalization. Secondary endpoints included surgery, initiation of biologic therapy, and clinical relapse. Logistic and Cox regression models were applied, and longitudinal changes were assessed in paired biopsies. Results: Both occludin and claudin-1 were dysregulated in active disease, showing increased expression and cytoplasmic redistribution compared with remission and controls. TJ alterations were more pronounced in the CR and correlated with clinical, endoscopic, and histological activity. In CD, occludin CR overexpression was independently associated with hospitalization (aOR 1.010; p = 0.05) and surgery (aHR 1.013; p = 0.005), while irregular occludin CR staining was associated with initiation of biologic therapy (aOR 3.48; p = 0.03). In UC, increased occludin CR levels and irregular CR staining were associated with IBD-related hospitalization in multivariable analyses (aOR 1.014; p = 0.035 and aOR 2.78; p = 0.032, respectively). Higher occludin CR levels identified UC patients at increased risk of clinical relapse (aHR 1.012; p = 0.002). In paired biopsies (n = 127), TJ architecture—particularly in the CR—improved over time, with reduced expression and a shift toward membranous localization, most prominently in bio-experienced patients. Conclusions: TJ remodeling, particularly crypt-level occludin dysregulation, is associated with disease activity and clinical outcomes, capturing a clinically relevant dimension of epithelial barrier dysfunction in IBD. Full article

Selenium nanoparticles (SeNPs) represent promising bioactive agents due to their reduced toxicity and multifunctional biological properties. In this study, SeNPs were synthesized via an eco-friendly phytosynthesis approach using Curcuma longa extract, yielding curcumin-functionalized selenium nanoparticles (cur–SeNPs). The composites (cur–SeNPs), either in native extract form or isolated, were incorporated into siloxane hybrid matrices prepared by the sol–gel method from tetraethyl orthosilicate: dimethyldimethoxysilane precursors, with polyvinylpyrrolidone (PVP) as a structural modifier. The host matrices were differentiated by the ratios between the precursors of the siloxane network, 3:1 for CS0–CS4, respectively, 1:1 for CS5, modified with PVP in the case of CS2 and CS3. These were loaded with cur–SeNPs–T in the cases of CS1, CS2, CS5 or with cur–SeNPs for CS3 and CS4. FTIR, XRD, SEM, and EDX analyses confirmed the formation of amorphous siloxane networks with well-dispersed SeNPs (up to ~12 wt%). PVP incorporation generated ordered mesoporous structures, increasing total pore volume sixfold and enlarging the average pore diameter to 9.26 nm. Studies about selenium ion release demonstrate that mesoporosity significantly enhances diffusion-controlled release. Antimicrobial assays against Staphylococcus aureus, Escherichia coli, and Candida albicans reveal a synergistic effect between curcuminoids and SeNPs, particularly in matrices with higher nanoparticle loading. The sol–gel technique for obtaining hybrid materials is very versatile regarding the supports on which the resulting materials or the compounds hosted in these host networks can be deposited. The dynamics of the development of hybrid materials is also reflected in the multitude of applications in various fields such as bio-medical, electronics, agriculture or food. Results obtained in this work highlight the potential of the developed systems for antimicrobial coatings on glass substrates and targeted delivery applications. Full article

With the rise of telecommunication systems in recent decades, the implications for human health have prompted a search for ways to reduce the impact of electromagnetic waves in buildings when necessary. A viable and promising solution to realize electromagnetic shielding could be the use of drywall panels coated with a biochar paste, as proposed in this study. Biochar (bio-charcoal), a low-cost and carbon-based material, can be obtained by the thermochemical conversion of different biomass sources. A commercial wood-based biochar thermally treated at 750 °C is considered in this work. Transmission coefficients of several gypsum board elements with a biochar coating are measured in the frequency K-band (18–27 GHz). In addition, the SE of a double panel configuration, obtained by joining two coated boards to form a multilayer structure, is evaluated. The results show that the biochar coating significantly enhances the SE compared to uncoated drywall. At the highest biochar loading investigated (0.20 g/cm²), the shielding effectiveness consistently exceeds 27 dB for single panels and 46 dB for double panels across the entire frequency band. These findings indicate that biochar-coated drywall systems offer a practical and sustainable solution for integrating electromagnetic shielding into building envelopes, paving the way for innovative applications in indoor exposure control. Full article

In this pilot study, we investigate the psychological and attentional impact of biophilic urban interventions using an immersive virtual reality (VR) framework integrated with real-time eye-tracking. Specifically, it examines whether bio-esthetic enhancements can mitigate perceptual inequalities across neighborhoods of varying socioeconomic status (SES). Sixteen participants viewed original and digitally enhanced fixed-viewpoint 360° videos of Low-, Medium-, and High-SES environments while a comprehensive suite of oculomotor dynamics and psychometric responses were recorded. Results confirmed a significant Condition × SES interaction across both subjective preference (Liking) and esthetic evaluation (η²p = 0.41), suggesting a role for biophilic design as a “socio-perceptual equalizer”: while baseline ratings consistently favored High-SES areas, interventions in Low-SES contexts yielded the highest marginal gains, effectively bridging the gap with privileged environments. Eye-tracking metrics revealed that this convergence was associated with active visual engagement, with Enhanced Low-SES scenes eliciting the highest fixation counts and visual coverage. However, a critical dissociation emerged between immediate affective improvement and self-reported stress reduction. Elevated saccadic velocities in Enhanced Low-SES scenes are consistent with a state of “hard fascination” or novelty-induced arousal. This pattern implies that while biophilia elements boost positive affect, physiological restoration may be a dose-dependent process, requiring sufficient exposure duration to transition from curiosity-driven scanning to the “soft fascination” linked to stress recovery. These findings provide preliminary evidence for integrated XR analytics as a tool for evidence-based urban design and are discussed in the context of the equigenesis hypothesis. Full article

Background: Pathogenic ST3GAL3 variants cause neurological and cognitive impairment, defining a distinct congenital disorder of glycosylation (ST3GAL3-CDG). Nonetheless, limited enzyme characterization exists due to the lack of a non-radiochemical assay. Methods: Here, we developed an LC-MS/MS-based method using the artificial substrate para-nitrophenyl-lacto-N-biose (LNB-pNP; Galβ1,3GlcNAcβ1-O-C6H4NO2) to measure ST3GAL3 activity in vitro. Results: A peak corresponding to sialyl-LNB-pNP was detected in reactions with homogenate from HEK-293T cells transfected with pCDNA3 ST3GAL3 plasmid, but was virtually absent in mock-transfected cells. A substrate dependence curve provided an apparent Km value for the substrate (0.40 mM) and closely matched values from prior radiochemical methods. No activity was detected with homogenates from cells expressing pathogenic ST3GAL3 variants, except p.A13D, which is known to retain about 10% of residual activity. Compared to ST3GAL4 and ST3GAL6, ST3GAL3 showed markedly higher specificity toward LNB-pNP, lactotetraosylceramide (Lc4) and asialo-GM1, which are rather specific substrates. Instead, neo-lactotetraosylceramide (neoLc4) was processed by all three ST3GALs. Conclusions: These findings suggest that ST3GAL4 or ST3GAL6 cannot compensate for ST3GAL3 loss in the biosynthesis of gangliosides sialyl-Lc4 and GM1b, but may do so for sialyl-neoLc4. This non-radiochemical assay enables screening and diagnostic evaluation of novel ST3GAL3 variants potentially associated with ST3GAL3-CDG. Full article

This study systematically compared the growth performance, nutrient composition, accumulation and speciation of selenium (Se), and in vitro bioaccessibility in yellow mealworm (Tenebrio molitor L.) larvae, which were reared on substrates supplemented with selenite (Se⁴⁺) and selenate (Se⁶⁺) at concentrations of 0, 5, 10, and 20 mg/kg over 28 days. The results showed that high Se concentrations (≥10 mg/kg) significantly reduced larval biomass, with Se⁶⁺ having a slightly stronger inhibitory effect than Se⁴⁺. The mealworms effectively accumulated Se in a dose- and form-dependent manner. Peak total Se concentrations were observed on day 14, after which there was a decline, suggesting the presence of potential elimination mechanisms, such as moulting. The bioaccumulation factors (BAFs) were all below 1, indicating its limited enrichment capacity for both Se⁴⁺ and Se⁶⁺. Nutrient composition was altered, with both Se forms stimulating crude protein and polysaccharide synthesis while inhibiting fat accumulation. Mineral content (Mg, Fe, Zn) was also modulated, with differences observed between the Se⁴⁺ and Se⁶⁺ treatments. Notably, mealworms exhibited a remarkable ability to biotransform inorganic Se into organic forms, with organic Se proportions exceeding 79% in all treatments. Selenate was more efficiently bio-converted, yielding a higher proportion of organic Se. In vitro gastrointestinal digestion revealed significantly higher Se bioaccessibility from Se⁶⁺-treated mealworms (up to 85.12%) than from Se⁴⁺-treated ones (up to 60.67%). Analysis of the bioaccessible fraction by Se speciation identified SeCys₂ as the dominant compound (>92% of the detected species), with much lower levels of SeMet. Trace amounts of unmetabolised Se⁶⁺ were only detected in the Se⁶⁺-exposed groups. These findings highlight T. molitor as an efficient bioreactor for producing bioaccessible, organically bound Se, primarily as SeCys₂, with Se⁶⁺ being the more favourable precursor for generating a high-quality, bioavailable source of Se for potential use in feed or food. Full article

Background: The persistently low 5-year survival rate for pancreatic cancer (PC) underscores the critical need for early detection. However, population-wide screening remains impractical. Artificial Intelligence (AI) models using electronic health record (EHR) data offer a promising avenue for pre-symptomatic risk stratification. Objective: To systematically review and meta-analyze the performance of AI models for PC prediction based exclusively on structured EHR data. Methods: We systematically searched PubMed, MedRxiv, BioRxiv, and Google Scholar (2010–2025). Inclusion criteria encompassed studies using EHR-derived data (excluding imaging/genomics), applying AI for PC prediction, reporting AUC, and including a non-cancer cohort. Two reviewers independently extracted data. Random-effects meta-analysis was performed for AUC, sensitivity (Se), and specificity (Sp) using R software version 4.5.1. Heterogeneity was assessed using I² statistics and publication bias was evaluated. Results: Of 946 screened records, 19 studies met the inclusion criteria. The pooled AUC across all models was 0.785 (95% CI: 0.759–0.810), indicating good overall discriminatory ability. Neural Network (NN) models demonstrated a statistically significantly higher pooled AUC (0.826) compared to Logistic Regression (LogReg, 0.799), Random Forests (RF, 0.762), and XGBoost (XGB, 0.779) (all p < 0.001). In analyses with sufficient data, models like Light Gradient Boosting (LGB) showed superior Se and Sp (99% and 98.7%, respectively) compared to NNs and LogReg, though based on limited studies. Meta-analysis of Se and Sp revealed extreme heterogeneity (I² ≥ 99.9%), and the positive predictive values (PPVs) reported across studies were consistently low (often < 1%), reflecting the challenge of screening a low-prevalence disease. Conclusions: AI models using EHR data show significant promise for early PC detection, with NNs achieving the highest pooled AUC. However, high heterogeneity and typically low PPV highlight the need for standardized methodologies and a targeted risk-stratification approach rather than general population screening. Future prospective validation and integration into clinical decision-support systems are essential. Full article

Soybean wax is a sustainable alternative to synthetic polymeric coatings in packaging due to its renewable, environmentally benign, and hydrophobic properties. In order to be effectively applied, however, soybean wax must be emulsified in water. The present work compares two stabilization approaches for soybean wax emulsions: a conventional surfactant-based emulsion (SE) using a mixture of nonionic surfactants (Span-80 and Tween-80), and a Pickering emulsion (PE) using cellulose nanocrystals combined with sodium alginate (CNC-SA) as an anionic stabilizer. The SE produced stable emulsions at 6 wt% Span-80/Tween-80 (at a HLB_mix value of 10) with a mean droplet size of 449 nm but limited storage stability (approximately 7 days under ambient conditions), while the PE achieved superior stability (approximately 1 month) at 1 wt% CNC-SA with a mean droplet size of 740 nm. The stabilized SE and PE were subsequently applied as coatings on three different types of paper substrates: northern bleached kraft (NBK) paper, copy paper, and cellulose nanofiber (CNF)-coated NBK paper. When applied to northern bleached kraft (NBK) paper, the SE coatings provided minimal improvements in barrier performance. The Cobb 60 value decreased slightly from 125 g/m² (control-no coating) to 86 g/m², indicating a negligible water barrier with immediate water absorption upon contact. In contrast, the Cobb 60 value of the PE-coated NBK paper decreased markedly from 125 g/m² to 39 g/m², confirming that the PE coating substantially enhances water resistance. The SE coating displayed a significant loss of water contact angle (WCA) from 85° to 0° within 20 s, showing limited water holdout capacity, whereas PE-coated NBK paper demonstrated strong water holdout, with the WCA decreasing only from 94° to 85° over 5 min. The SE coating achieved only a 14% reduction in water vapor transmission rate (WVTR), while the PE coating provided a greater reduction of 30%. In terms of oil resistance, both emulsion systems significantly enhanced the kit rating of the papers tested, e.g., from kit number 0 to 6–9 (paper dependent). The SE coating, however, experienced a substantial reduction in barrier integrity after folding, while the PE coating largely retained its oil barrier properties. Furthermore, the SE coating reduced the tensile strength of NBK paper by 41%, whereas the PE coating reduced it by only 7%. Overall, the comparative findings indicate that although the SE generated a smaller mean particle size, it offered minimal improvement in the water and oil barrier performance of paper and had a limited storage life. In contrast, the PE generated a larger mean particle size, but provided substantially greater water and oil resistance, and enhanced mechanical strength retention. In addition, the PE displayed an effective storage life of at least one month. The Pickering emulsion, formulated with all biologically derived components, therefore represents a viable, sustainable, bio-based alternative to synthetic polymeric coatings for packaging applications. Full article

Group A rotaviruses (RVAs) remain the leading cause of acute gastroenteritis (AGE) in young children in low- and middle-income countries. In Brazil, the oral attenuated RVA vaccine (Rotarix^®), monovalent genotype G1P[8], is distributed by the national immunization program and has drastically reduced morbidity and mortality associated with RVA etiology. In this study, Rotarix^® G1P[8] was detected using specific qRT-PCR from the fecal shedding of children living in the Amazon region, and 18.3% (29/158) were positive and 75.8% (22/29) presented with AGE. The VP4 (VP8*) gene of these sheddings, submitted to Sanger nucleotide sequencing, showed an occurrence of mutations, including the silent mutation at 144C > G (one child) and the following missense mutations— 499T > C (F167L) (two children), 644G > C (C215S) (one child), and 787G > A (E263K) (one child). These mutations had no impact on the protein model structure in silico deduced from the VP4 (VP8*) mutants. The in silico protein model deduced from the VP4 (VP8*) nucleotide sequences, bound to type 1H sugar antigens (H1) and its precursor Lac-para-N-biose (LNB), had a stronger binding to the G1P[8] genotype, when compared to G3P[8]. Rotarix^® shedding was higher in HBGA secretors than in non-secretors (79.3%; 23/29). A total of 11.4% (18/158) of children with Rotarix^® G1P[8] shedding were unvaccinated, indicating the occurrence of indirect protection. Stability evidence of Rotarix^® VP4 (VP8*) spike protein from samples collected in vivo is presented. Full article

An increasing number of different types of dielectric liquids are appearing on the market. This is undoubtedly related to sustainable development goals. This paper presents comparative studies of the lightning impulse breakdown voltage (LIBV) of six dielectric liquids with different chemical compositions: naphthenic uninhibited mineral oil (UMO), naphthenic inhibited mineral oil (IMO), natural ester (NE), synthetic ester (SE), bio-based hydrocarbon (BIO), and an inhibited liquid produced using gas-to-liquids technology (GTL). Tests were conducted in a point-to-sphere electrode configuration with a 5 mm thick pressboard barrier placed between them. This configuration was designed to more closely replicate the actual configuration found in transformers, where the oil channels are separated by pressboard barriers. Tests were performed for two inter-electrode gap distances of 25 mm and 40 mm, and for both lightning impulse voltage polarities. The pressboard barrier was placed so that the distance between point electrode and the barrier was always the same (10 mm). Measurements were performed using the step method. Before measurements began, the pressboard barrier was impregnated with the dielectric liquid being tested. The obtained measurement results were compared with previous studies conducted by the authors, which used a similar electrode system but without the pressboard barrier. The results confirmed that inserting the pressboard barrier between the electrodes effectively inhibits development of discharges and significantly increases the electrical strength of the entire insulation system. Full article

Coral reefs are integral components of tropical coastal marine ecosystems that have considerable capacity to mitigate extreme flows and marine floods caused by storms and tsunamis. However, limited studies on coral reef efficacy in reducing such flows, coupled with variable roughness coefficient characteristics, hinder their broader utilization in sustainable engineering applications for societal benefit. In this study, we conducted comprehensive experimental investigations to examine flow–coral interactions and the flow energy reduction capabilities of coral reefs. Three-dimensional-printed coral reefs were used to simulate actual coral reefs, providing a scalable and environmentally responsible approach for studying nature-based coastal protection systems. Flow characteristics within the coral reef were investigated through flow depth and velocity measurements taken at the front of, over, and behind the reef. Analysis was performed considering nondimensional parameters, i.e., the Froude number (Fr), the depth effect (DE; ratio of flow depth to coral height), and the size effect (SE; ratio of coral length to coral height), to assess the flow energy reduction under different coral combinations and flow conditions. Spatial variations in flow depth over the reef showed that fast and shallow flows exhibited a reduction gradient toward the back of the reef. The findings revealed a substantial reduction in flow depth and velocity, reaching up to 27.5% and 25%, respectively, at the back boundary of the coral. Two-layered velocity analyses showed that the velocity over the top of corals could be six times higher than that through the coral reef structure for deep flows. Manning’s roughness coefficient varied considerably from 0.03 to 0.26. Overall, this study contributes to sustainable coastal engineering by demonstrating how bio-inspired coral reef structures can be applied to reduce flow energy and enhance coastal resilience in an environmentally adaptive manner. Full article

Selenium (Se) biofortification represents a critical strategy for addressing micronutrient deficiency while enhancing fruit nutritional quality. This study investigated foliar applications of Se and Si nanoparticles (NPs) for peach Se biofortification and quality enhancement. Se NPs (95.2 nm) were synthesized and characterized using SEM, EDS, and FTIR analyses. Six treatments were applied: control (Ck), SeNPs-5, SeNPs-10, SiNPs-10, Se5Si10, and Se10Si10. SeNPs-10 achieved maximum Se biofortification (0.47 mg kg⁻¹), representing 5.4-fold increases over controls, with 85% organic Se accumulation. Combined treatments demonstrated synergistic effects on multiple quality parameters. Se5Si10 led to the highest antioxidant enzyme activities (peroxidase: 2254 U g⁻¹, catalase: 61.7 U g⁻¹) and phenolic compound enhancement (chlorogenic acid: 267 mg kg⁻¹, total phenolics: 12.8 mg GAE g⁻¹). Flavonoid biosynthesis was optimized with Se10Si10 achieving maximum rutin accumulation (53.9 mg kg⁻¹) and ascorbic acid content (60.7 mg/100 g). Physical quality improvements included enhanced firmness (100.9 N cm⁻²) and sugar accumulation (14.1% soluble solids). Combined treatments reduced oxidative stress markers (MDA: 22.11 μmol g⁻¹) while enhancing protein metabolism. These findings demonstrate that Se-Si nanoparticle combinations showed optimal biofortification with synergistic quality enhancement, establishing effective strategies for nutritionally enriched peach production. Full article

Raman spectroscopy has become an important tool for biomedical analysis due to its ability to provide label-free, non-destructive molecular fingerprints of biological samples. However, existing deep learning approaches for classifying biological Raman spectra often focus on specific datasets and lack generalizability and interpretability. In this study, BioRamanNet is presented, an interpretable and generalizable deep learning framework designed for classifying a wide range of biological Raman spectra. The model integrates adaptive one-dimensional convolutional layers and squeeze-and-excitation (SE) blocks within a residual network architecture to enhance feature extraction. BioRamanNet was evaluated using four representative Raman spectral datasets—breast cells, extracellular vesicles and particles (EVPs), viruses, and bacteria—achieving classification accuracies of 99.5%, 100%, 99.8%, and 85.3%, respectively. To improve model interpretability, a perturbation-based analysis using Voigt noise was introduced to identify key wavenumber regions influencing classification. These regions were found to correspond closely with known Raman biomarkers, validating their biological significance. The results of this work demonstrate that BioRamanNet is a powerful and interpretable tool for analyzing diverse biological Raman spectra and holds promise for advancing machine learning-assisted biomedical diagnostics. Full article