Search Results (961)

The effects of ambient storage (A), cold storage (C), and frozen storage (F) on the quality, metabolomic characteristics, and sulfur-related aroma of red onion ‘Kewei Red 10’ (R10) and yellow onion ‘Kewei Yellow 14’ (Y14) were investigated using integrated non-targeted and volatile metabolomics. Ambient storage accelerated shrinkage, firmness loss, and sensory deterioration in both cultivars, whereas low-temperature storage effectively delayed quality decline. R10 exhibited better tolerance to frozen storage, while Y14 performed better under cold storage. Metabolomic analysis revealed that amino acids and lipid-related metabolites were closely associated with onion senescence in both cultivars. In contrast, flavonoids were enriched in preservation-associated subclasses in R10, whereas organic acids and their derivatives were more strongly associated with delayed senescence in Y14. Volatile metabolomic analysis identified sulfur compounds and heterocyclic sulfur compounds as the major contributors to onion aroma. Sulfur-related volatiles showed distinct cultivar-dependent accumulation patterns, with many sulfur compounds accumulating prominently in ambient-stored R10-A, whereas cold-stored Y14-C maintained relatively higher levels of characteristic onion-like aroma compounds. These findings demonstrate distinct metabolic adaptation strategies between red and yellow onions during storage and suggest that cultivar-specific storage conditions are required to optimize both shelf life and flavor quality. Full article

Chilling injury is a major problem limiting the postharvest storage and marketability of mango fruit at low temperature. The present study investigated the individual and combined effects of sodium nitroprusside (SNP), L-arginine (Arg) and salicylic acid (SA) on chilling tolerance, regulation of oxidative stress and the postharvest quality of ‘Keitt’ mango fruit stored at 5 ± 1 °C for 28 days followed by 4 days of shelf life at 23 °C. Fruits were pre-treated with 1 mM SNP, 1 mM Arg, 2 mM SA or their binary combinations before storage. The chilling injury, membrane damage, lipid peroxidation, protein oxidation and fruit softening were greatly enhanced by cold storage in untreated fruits. In contrast, all the treatments significantly ameliorated these deteriorative changes, and the combined treatments were superiorly effective. Among these, SNP + Arg was the most effective treatment, which reduced the chilling injury index from 4.05 in control fruits to 1.00 after shelf life, completely inhibiting the incidence of decay and reducing electrolyte leakage and malondialdehyde accumulation by 47.4 and 48.2%, respectively. The same treatment also maintained higher firmness, titratable acidity, visual appearance and ascorbic acid content than untreated fruits. The enhanced chilling tolerance was accompanied by increased antioxidant defense, as SNP + Arg significantly stimulated the activities of superoxide dismutase, catalase and peroxidase, but suppressed the activity of pectin methylesterase. Multivariate analyses, such as PCA, clustered heatmap and integrated stress index, demonstrated a strong negative relationship between oxidative stress markers and antioxidant metabolism. The results showed that combined SNP and Arg treatments enhanced chilling tolerance through increasing antioxidant capacity, preserving membrane integrity, and retarding ripening-related metabolism, which provides an effective way to maintain the postharvest quality of cold-stored mango fruit. Full article

Coffee is an important dietary source of bioactive antioxidant compounds contributing to the antioxidant properties of coffee beverages. While brewing affects yield of total antioxidants, it is still not really clear which individual (phenolic) compounds contribute to the antioxidant activity the most. A method combining chromatographic separation and individual antioxidant evaluation might therefore be useful. This study aimed at evaluating the antioxidant potential of the compounds in coffee beverages using a high-performance liquid chromatography approach directly coupled to the well-known trolox equivalent antioxidative capacity (TEAC) assay (HPLC-onlineTEAC). The study further evaluated the influence of different brewing methods (‘Americano’, ‘V60’, ‘French press’, and ‘cold brew’) on the bioactive compound profile and antioxidant potential of Arabica coffee beverages. The brewing method significantly affected caffeine content, chlorogenic acid composition, total phenolic content (TPC), and antioxidant activity of the analyzed beverages (p < 0.05). Cold brew samples exhibited the highest total radical scavenging activity and concentrations of major caffeoylquinic acid isomers (3-CQA, 4-CQA, and 5-CQA). In contrast, “French-pressed” beverages were characterized by the highest TPC values, while V60 samples generally showed the lowest antioxidant-related parameters. Chlorogenic acids accounted for more than 84% of the total antioxidant potential of all analyzed beverages, whereas monocaffeoylquinic acids represented the dominant fraction responsible for radical-scavenging activity. The results indicate that prolonged low-temperature extraction favors the recovery and preservation of highly reactive chlorogenic acid isomers and contributes to the enhanced antioxidant potential of coffee beverages, beyond the effect of coffee dose alone. Full article

Freezing stress is one of the major abiotic factors limiting plant growth and productivity. This study evaluates the effects of diatomite (DTM) as a natural silicon-rich amendment on growth performance, physiological responses, and cold stress tolerance in barley (Hordeum vulgare L.). Seed priming and substrate application of DTM at different concentrations (5–20%) were used to assess morphological, biochemical, and ultrastructural changes under normal and low-temperature conditions. Results showed that DTM significantly enhanced root growth and biomass accumulation, with the most pronounced effect at 10% concentration. Treated plants exhibited improved survival under freezing stress, along with better preservation of leaf cellular structure and photosynthetic pigments. Biochemical analyses revealed reduced proline accumulation and decreased activity of key antioxidant enzymes, indicating alleviation of oxidative stress and improved redox balance. Electron microscopy confirmed the integration of diatomite particles into seed and tissue structures, providing physical reinforcement and thermal protection. Overall, diatomite acts as a multifunctional, environmentally safe soil amendment that enhances plant growth and improves tolerance to cold stress through combined physical and physiological mechanisms. Full article

Nanoemulsion (NEM) is an effective adjuvant and delivery system for vaccines and nucleic acids, capable of inducing immune responses against diverse pathogens. Background/Objectives: Conventional NEM manufacture uses multi-step operations, typically high-shear homogenization and then microfluidization (HSHM), thereby increasing process complexity and contamination risk. As water-rich colloidal dispersions, NEM is prone to microbial proliferation and droplet coalescence; freezing further disrupts microstructure, causing phase fusion and separation, so NEM adjuvants are often stored separately from antigens in multi-vial formats. Lyophilization could reduce cold-chain dependence and enable single-vial products, but there is no systematic study on lyoprotectants comparation and process optimization of lyophilized NEM. Methods: An impingement jet mixing (IJM) process was evaluated as a simplified, scalable route for NEM production. Key IJM parameters, including flow ratio, total flow rate, preparation temperature, microchannel type, and shear mode—were examined to match attributes of conventional HSHM. Lyophilized and reconstituted NEM were characterized by dynamic light scattering, scanning electron microscopy, transmission electron microscopy, differential scanning calorimetry and/or in vitro potency to inform lyoprotectant selection, and Taguchi Design of Experiment (DOE) methodology guided lyophilization processes. Results: IJM yielded NEM with droplet size, polydispersity index (PDI) and morphology comparable to HSHM, with higher throughput and fewer unit operations. Optimized lyophilization technique with designed lyoprotectant and process formed closed structures to prevent the easy-to-flow monolayer of the emulsion from fusing, producing robust and stable NEM. Conclusions: Coupling IJM with targeted lyophilization establishes a scalable, lower-risk manufacturing paradigm for NEM that preserves critical quality attributes, reduces cold-chain reliance and enables single-vial adjuvanted vaccine formats with tangible industrial and clinical benefits. Full article

Reusing wastewater in agriculture is essential due to water scarcity but requires treatment technologies that preserve soil biological integrity. This study evaluated the impact of irrigation with wastewater treated by cold atmospheric plasma (CAP; 60 min exposure) on the soil microbiome during Festuca rubra L. and Sinapis alba L. cultivation. The experimental design included various CAP-wastewater dilutions evaluated in two replicates (n = 2), with microbial shifts assessed via 16S rRNA gene sequencing. CAP treatment reduced non-purgeable organic carbon (NPOC) while enriching the water with nitrogen, which significantly stimulated S. alba root growth. Metagenomic analysis confirmed high microbiome stability. Dominant phyla (Proteobacteria and Actinobacteriota) remained stable, and beta-diversity indices showed no statistically significant ecological shifts (R² = 0.420, p = 0.121). Furthermore, CAP-treated irrigation promoted beneficial taxa, specifically the genus Bacillus. These findings demonstrate that CAP wastewater treatment is a safe, environmentally responsible strategy for wastewater reclamation. It successfully supports nutrient cycling and agricultural production without compromising soil microbial homeostasis or health, offering a viable solution aligned with the principles of a circular economy. Full article

Introduction: The upper Arlanza River (Duero Basin, Burgos, Spain) hosts a genetically distinct local lineage of brown trout (Salmo trutta fario), the “Arlanza strain”, largely free from hatchery-derived introgression, alongside other native cyprinids of conservation concern, including the Iberian chub (Achondrostoma arcasii, Vulnerable—IUCN). The river also supports the Iberian desman (Galemys pyrenaicus, Endangered—IUCN) and Eurasian otter (Lutra lutra). Despite these values, the study reach presents multiple transverse obstacles limiting longitudinal connectivity and degraded riparian cover in critical sections due to livestock erosion, compromising habitat quality for all species. Objective: This study aimed to design engineering interventions to improve fluvial and riparian habitat in a 4 km reach of the upper Arlanza River, restoring longitudinal connectivity and thermal refuge availability while strictly preserving the genetic integrity of the native Arlanza trout strain. Methodology: The reach was characterised through electrofishing surveys, riparian quality assessment (modified RQI index), hydraulic refuge evaluation (IR index), and hydrological analysis based on a 30-year flow record. Brown trout population dynamics were modelled using dimP 1.0 software, with a comparative analysis between upstream (Quintanar de la Sierra village) and downstream (Vilviestre del Pinar village) sampling points to identify connectivity bottlenecks. Engineering works were scheduled to avoid reproductive periods of all target species. Results: The upstream population showed a rejuvenated age structure (density: ~1.40 ind/m; mean length: 12.0 cm), consistent with good spawning conditions but limited growth capacity due to cold temperatures and low summer flows. The downstream point exhibited a severely reduced population (~0.10 ind/m), indicating marked loss of connectivity and habitat degradation. Priority intervention zones were identified in the Camping and lower Prado Mayor sub-reaches. Proposed measures included weir notching to restore fish passage, livestock watering points to reduce bank erosion, and riparian restoration by planting native species (Populus tremula, Betula alba, Salix spp.) protected with fences. Conclusions: Restoring longitudinal connectivity and riparian cover in the upper Arlanza River are essential to protect the genetically valuable Arlanza trout strain, the endangered G. pyrenaicus, and other native fish species, providing a transferable framework for headwater fluvial restoration that jointly addresses biodiversity conservation and genetic resource protection. Full article

The main causes of lemon fruit senescence and deterioration are fungal diseases and postharvest quality loss. Edible coatings have been proposed to delay quality loss in fresh produce by reducing moisture loss and helping preserve external appearance. Natural functional coatings are increasingly being investigated as potential alternatives to synthetic waxes and preservatives due to environmental and consumer safety concerns. The effect of a natural edible coating based on Opuntia ficus-indica mucilage on extending the shelf-life of lemons during cold storage was investigated. Lemon fruits were treated with the mucilage-based edible coating and subsequently stored under controlled cold conditions. Coated and uncoated lemon fruits were evaluated for their physicochemical properties, including weight loss, total soluble solids, pH, titratable acidity, color, and microbiological analysis, as well as total polyphenol content and antioxidant activity, over a 60-day storage period at 5 ± 0.5 °C and 95% relative humidity. The results showed that the mucilage-based coating improved lemon fruit storage performance, effectively preserving key physicochemical and microbiological parameters over 60 days of cold storage (p ≤ 0.05). In particular, the treatment maintained fruit firmness, reduced weight loss (up to 45%), increased juice content (up to 1.8-fold), and delayed microbial decay compared to control samples. Coated fruits also exhibited higher total polyphenolic content and antioxidant activity than control samples at the end of storage. In addition, using mucilage extracted from cactus pear cladode waste provides a sustainable way to add value to the product, with promising industrial applications as an alternative to synthetic fruit coatings. Full article

Background: Fresh frozen tissues are considered the gold standard for proteomic analyses due to their superior preservation of protein integrity; however, their use is limited by the logistical and financial requirements of long-term cold storage. Formaldehyde-fixed paraffin-embedded (FFPE) tissues provide a practical alternative, owing to their stability and widespread availability in clinical settings. A critical step in FFPE proteomics is deparaffinization, which traditionally relies on organic solvents such as xylene, along with the efficient reversal of formaldehyde-induced crosslinks. Methods: In this study, we evaluated multiple FFPE protein extraction and digestion workflows including chaotropic, surfactant-based, and detergent-free approaches in combination with xylene-free deparaffinization strategies, using label-free data-independent acquisition (DIA) LC-MS/MS. Results: Among the tested methods, a chaotropic, reductant, and surfactant-free in-solution digestion workflow demonstrated robust protein and peptide recovery. A modified version of this protocol further improved peptide coverage while maintaining comparable protein depth. The applicability of the optimized workflow was assessed using FFPE needle biopsy samples from control, hepatic steatosis, and liver fibrosis groups. Exploratory proteomic patterns were observed across conditions, with hepatic steatosis associated with early activation of stress-response pathways, while fibrosis showed evidence suggesting altered lipid metabolism. Conclusions: Overall, this study presents a simple, xylene-free, and MS-compatible workflow for FFPE proteomics that is suitable for low-input clinical samples and may support broader application of archival tissues in proteomic research. Full article

Background: Respectful maternity care (RMC) prioritizes dignity, privacy, and autonomy during childbirth. In low-resource primary health centers (PHCs), the lack of delivery gown availability compromises these aspects, leading to discomfort and reduced patient satisfaction in PHCs. This study on Maathru Samman Pants (MSPs), a culturally sensitive garment designed with functional flaps, aims to enhance privacy, comfort, and dignity during labor, as well as assess the satisfaction, acceptability, and demand for MSPs among pregnant women and their birth companions in PHC settings across four Indian regions. Methods: A cross-sectional study was conducted across eight PHCs in North, South, East, and West India. A total of 80 pregnant women and 60 birth companions participated. Data were collected through structured questionnaires and in-depth interviews. The quantitative data covered satisfaction, acceptability, and demand using Likert scales, yes/no, and open-ended formats. The qualitative data were analyzed thematically. Results: Most PW (pregnant women) were aged 21–30 years, mainly Hindu, 34 (42.5%), or Christian, 27 (33.75%), with 71.25% homemakers. PW highly rated MSPs for covering the body, preventing cold, comfort, and ease of use. They felt cared for and respected, with a mean ± SD of 4.47 ± 0.57, and agreed that MSPs maintained privacy and cultural norms. Demand was strong, with 76 (95%) supporting the introduction of MSPs and 74 (92.5%) willing to use them again. Most PW, 66 (82.5%), and BCs (birth companions), 49 (81.67%), accepted MSPs positively, with a few reporting discomfort or changes. Conclusions: MSPs demonstrated high satisfaction, strong acceptability, and future demand among PW. This study addresses key gaps in respectful maternity care at the PHC level by enhancing privacy, preserving cultural norms, and improving comfort. Integrating MSPs into maternal health protocols could significantly improve birthing experiences in resource-limited settings. Full article

The skin microbiome is essential for epidermal barrier integrity and immune homeostasis. This review explores the therapeutic shift in dermo-cosmetics toward probiotic, prebiotic, synbiotic, and postbiotic strategies for managing wound healing, “inflammaging”, and chronic dermatoses like acne, atopic dermatitis (AD), psoriasis, and rosacea. Mechanisms include gut–skin axis modulation, competitive pathogen exclusion, and the suppression of inflammatory pathways (e.g., NF-κB). While live probiotics demonstrate high clinical efficacy, their formulation is severely hindered by standard cosmetic preservatives and manufacturing thermal stress. Consequently, evidence suggests inanimate postbiotics have emerged as promising, stable alternatives, which may offer antimicrobial and tissue-repairing benefits without strict cold-chain requirements. However, the industry faces significant regulatory ambiguity and “probiotic-washing”, with most commercial products mislabeling postbiotic lysates as live cultures. Advancing this field requires standardized sampling protocols and transparent labeling. Ultimately, precision dermatology is likely to be driven by AI-assisted microbiome profiling, synthetic biology, and advanced delivery matrices (e.g., electrospun nanofibers, alginate microencapsulation), transforming skincare from reactive treatments into proactive, targeted ecological management. Full article

The rapid proliferation of Narrowband Internet of Things (NB-IoT) devices necessitates robust, privacy-preserving intrusion detection systems. While Federated Learning (FL) mitigates data privacy risks through localized training, it introduces vulnerabilities to model poisoning and computational bottlenecks on edge devices. To address these challenges, we propose a secure, hardware-optimized Blockchain-Federated Learning (BC-FL) framework. Deploying a lightweight Hybrid CNN-RNN model on Edge Gateways, we relieve end-sensors of heavy computational tasks. To overcome the ‘cold-start’ problem, we introduce a Domain-Adaptive Transfer Learning strategy, dynamically adapting a pre-trained binary classifier to a multi-class task (Normal, Mirai, Bashlite). Furthermore, a lightweight blockchain ledger provides an immutable audit trail and a reputation-based isolation mechanism to penalize malicious nodes. Evaluated on the N-BaIoT dataset, the proposed 3-class CNN-RNN model achieves 95.62% overall accuracy, with precision/recall/F1-scores of 0.99/0.91/0.95 for Mirai and 0.93/0.99/0.96 for Bashlite attacks. The framework reduces communication bandwidth by 96% compared to centralized learning. During simulated Byzantine attacks, the reputation mechanism successfully banned malicious nodes, maintaining a robust 95.62% global accuracy. This framework offers a highly scalable, secure, and computationally feasible solution for real-time anomaly detection in resource-constrained IoT edge environments. Full article

We investigatewhether a finite local information capacity of spacetime can account for the gravitational phenomena commonly attributed to cold dark matter. Starting from a covariant effective-field-theory description, we modelcoarse-grained entropy deposition as a dynamical scalar field $S\left(x\right)$ whose stress–energy tensor contributes to structure formation. The macroscopic action contains a single dimensionless coupling λ multiplying the canonical kinetic term, ensuring ghost-free dynamics and conservation of the associated stress–energy tensor. In a slow-roll regime, defined by a covariant source term $\Gamma \equiv \ddot{S}+3H\dot{S}=0$, where H is the Hubble parameter and overdot denotes derivative with respect to cosmic time, and $|\ddot{S}|\ll H|\dot{S}|$, the entropy sector behaves as pressureless dust at background and in linear order. Implemented in a modified Cosmic Linear Anisotropy Solving System (CLASS) Boltzmann solver, the entropy component fits Planck satellite 2018 cosmic microwave background (CMB) data, baryon acoustic oscillation (BAO) measurements, and the Pantheon + Type Ia supernova sample for $0.5\lesssim \lambda \lesssim 2$, while preserving the linear growth factor to within 0.2% over Euclid space telescope scales. To regulate ultraviolet contributions, we introduce a holographically motivated prescription in which gravitationally active entropy deposition is confined to causal two-surfaces, yielding a $\rho \propto r^{-2}$ halo envelope with a finite-density core determined by local entropy saturation. Fixing the flux scale $\mathcal{A}$ from astrophysical entropy budgets reproduces Milky-Way-mass halos without introducing fine-tuned length scales. Pilot N-body simulations that evolve the entropy field on a staggered grid reproduce the halo mass function down to ${10}^{10.5}{M}_{\odot }$, mitigate the cusp–core and missing-satellite tensions, and remain consistent with cluster lensing constraints. On linear scales, the model predicts percent-level, scale-dependent deviations in the lensing convergence and matter power spectra, testable by Euclid space telescope, the Roman Space Telescope High Latitude Survey, and the CMB-S4 experiment. Full article

Ethyl formate (EF) is a promising alternative to methyl bromide for postharvest disinfestation, but berry export chains require efficacy under refrigerated handling without loss of marketable quality. Using spotted-wing drosophila (Drosophila suzukii) in blueberries as a cold-chain model, we compared stage-specific tolerance at 5 to 15 °C and identified 1-day-old eggs as the most tolerant stage, with mortality strongly temperature dependent. Egg-stage concentration to mortality relationships were quantified under 4 h exposures at 5, 10, and 15 °C to nominate temperature-specific intensities within EF flammability safety limits. Candidate schedules (69, 83, and 94 mg·L⁻¹ for 4 h at 5, 10, and 15 °C) were confirmed by verification-scale zero-survivor tests under simulated cold-chain conditions, achieving complete control of the most tolerant egg stage. Post-treatment quality was assessed after 1, 7, and 14 days of cold storage. Weight loss, firmness, total soluble solids, titratable acidity, sucrose, and proanthocyanidins were driven mainly by storage time and temperature. EF effects were limited to transiently elevated respiration early in storage, with no detectable injury, decay, or adverse changes in appearance or other physicochemical attributes. Overall, EF provides a cold-chain compatible processing window integrating efficacy, operational safety, and quality preservation for refrigerated blueberry export logistics. Full article

The environmental impact of food waste and agro-industrial by-products has promoted the development of circular economy strategies for food applications. In this study, edible films were developed from biopolymers extracted from avocado peel and seeds (hemicellulose, pectin, lignin, and starch), incorporating ethyl lauroyl arginate (LAE^®) as an antifungal agent. The activity of LAE^® was evaluated against Colletotrichum gloeosporioides on inoculated avocados stored at 12 °C and 22 °C. Fruit shelf life was assessed through physiological, physicochemical and sensory parameters during cold storage and subsequent shelf life. Films containing 10% LAE^® exhibited strong antifungal activity, and their efficacy was higher at 12 °C than at 22 °C. Coated fruits exhibited a ripening delay of up to 2 days compared to controls. These findings highlight the potential use of avocado by-product-based LAE^® coatings as a sustainable strategy for preserve postharvest avocado quality. Full article