Search Results (351)

This study investigates the antioxidant and anticorrosive properties of Mentha pulegium L. essential oil (MP EO) as a sustainable and eco-friendly alternative to synthetic oxidation inhibitors. The antioxidant activity of MP EO was evaluated using the ferric reducing antioxidant power (FRAP) assay, which demonstrated a strong electron-donating capacity and effective reduction of ferric ions, indicating promising antioxidant potential. The anticorrosive performance was assessed on mild steel in 0.5 M H₂SO₄ using potentiodynamic polarization and electrochemical impedance spectroscopy (EIS). The results showed inhibition efficiencies of up to 75.8% at a concentration of 2 g/L. Molecular docking simulations revealed favorable binding interactions between the key oil components (pulegone and menthone) and the ROS-generating enzyme model (PDB ID: 2CDU), providing complementary mechanistic insight into their potential role in oxidative stress modulation. Additionally, quantum chemical calculations highlighted electronic properties favoring adsorption on metallic surfaces. Surface morphology analysis using SEM/EDX confirmed the formation of a protective film on steel in the presence of MP EO. These combined findings position Mentha pulegium essential oil as a potent, biodegradable candidate for both antioxidant applications and corrosion prevention in acidic environments. Full article

Background: The dorsal raphe nucleus (DRN) produces and distributes serotonin, while the hypothalamus (HYP) uses serotonergic signals to regulate physiological processes in chickens. Coconut oil (COCO), rich in medium-chain fatty acids, is rapidly absorbed without re-esterification. Methods: Day-old broilers (Ross 708 male, n = 160) were distributed into two dietary treatments with five replicates of 16 birds each. The birds were fed a corn–soybean meal (SBM) basal diet supplemented with 3% of poultry fat (CON) or coconut oil (COCO). The body-weight gain (BWG), feed intake (FI), and feed conversion ratio (FCR) were recorded over a 3-week period, and the data were subjected to a t-test. Untargeted metabolomic analysis by high-performance liquid chromatography (HPLC-MS) was used to evaluate the influence of the type of dietary fat on metabolite profiles in the DRN, HYP, and plasma of broiler chickens. Principal component analysis (PCA) was used to identify unique metabolites, and ANOVA was used to identify the metabolites that were significantly abundant (p < 0.05). The metabolites were then annotated using the KEGG and HMDB databases. Results: Birds in the COCO treatment gained more weight on average (0.8446 kg/bird) than birds in the CON group (0.8132 kg/bird; p = 0.0496). Five metabolites associated with multiple significant cellular processes, such as brain function, energy metabolism, and neurotransmission, showed similar differential expression patterns, while two metabolic pathways (butanoate metabolism and alanine, aspartate and glutamate metabolism) were identified. Conclusions: The dietary inclusion of COCO improves BWG in poultry and enhances their overall well-being by modulating metabolite profiles, supporting neurotransmission, and enriching the metabolic pathways essential for growth and brain function. Full article

Endometriosis is characterized by enhanced cellular proliferation, migration, and resistance to apoptosis, contributing to lesion persistence and progression. Targeting cellular plasticity and mesenchymal-associated functions may therefore represent a promising therapeutic strategy. Here, we investigated the effects of Pelargonium graveolens essential oil (PGEO) on proliferation, apoptosis, migration, cytoskeletal organization, transcriptional regulation, and metabolic alterations in human endometriotic 12Z cells. PGEO treatment suppressed proliferative capacity in a concentration-dependent manner and significantly impaired cell migration, accompanied by reduced β-tubulin expression and decreased levels of mesenchymal-associated markers CD73 and CD105. Increased GRP78 expression together with ultrastructural alterations, including cytoplasmic vacuolization and mitochondrial and endoplasmic reticulum changes, indicated activation of cellular stress responses. Although transcriptional analysis revealed increased CCND1 and PIK3CA mRNA levels, these changes did not parallel the observed suppression of proliferation, suggesting compensatory regulatory responses. Untargeted metabolomic profiling revealed alterations in energy metabolism characterized by increased levels of glycolysis-related metabolites, reduced levels of several amino acids including glutamine and histidine, and changes in lipid-associated metabolites. Collectively, these findings demonstrate that PGEO suppresses proliferative and migratory behavior in endometriotic cells while modulating cytoskeletal, transcriptional, and metabolic pathways, highlighting its potential as a candidate for further investigation in endometriosis-targeted therapeutic strategies. Full article

Basil essential oil (BEO) has emerged as a promising natural alternative to antibiotic growth promoters in poultry production. BEO has shown antimicrobial, antifungal, anticoccidial, antioxidant, and insecticidal properties. BEO exhibits broad antimicrobial activity against Gram-positive and Gram-negative pathogens, and modulates gut microbiota by decreasing Escherichia coli and Staphylococcus spp. Anticoccidial effects include reduced oocyst shedding, improved intestinal morphology, and downregulation of pro-inflammatory cytokines. Antifungal activity reduces fungal load and inhibits Aspergillus spp., with implications for control spoilage and aflatoxin risk. BEO at a concentration of 40 ppm was effective in preventing E. tenella invasion, showing an average reduction in invasion by 36% in primary chicken epithelial cells. Antioxidant benefits include enhanced intestinal and systemic antioxidant status. Advanced nanoformulation technologies, particularly nano-encapsulation, have substantially overcome several limitations for BEO application in poultry. Further research is still required to assess the efficacy of nano-encapsulated BEO for enhancing overall poultry industry productivity. This review synthesizes current evidence on BEO integration in the poultry production sections, from nutrition and disease control to product preservation and farm hygiene, and evaluates technological solutions that address formulation barriers. Moreover, it discusses critical research gaps and proposes future directions for enhancing BEO applications in sustainable poultry production systems. Full article

Climate change has adversely affected grain production and quality of canola, the second-largest oilseed crop, which contributes 13–16% of total vegetable oil. Multiple biotic and abiotic stresses significantly limit canola production due to rapid climate change, and conventional breeding alone is insufficient to meet global demand. Therefore, several advanced biotechnologies have been developed to cope with this change. Among these, genetic modification, gene editing, and RNA interference are particularly significant for rapid cultivar development in a cost-effective, efficient, and convenient way. Recent findings in gene editing applications have revealed “prospective sites”, highlighting regions amenable to precise editing without compromising canola plant growth or development. Pan-genome analyses have further guided gene editing target selection, enabling the validation of key stress-resilience genes across diverse canola cultivars, while the CRISPR-epigenetic regulatory connection enables targeted control of gene expression and trait modulation. A hypothetical application of genomic selection is also suggested, which could complement gene editing to accelerate the development of superior cultivars. Accordingly, this review focuses on the latest studies of genetic modification, gene editing, and RNA interference to strengthen canola resilience under rapid climate change and discusses the major concerns. Taken together, these genome-editing strategies offer precise approaches for improving biotic and abiotic stress tolerance, although careful consideration of both off-target effects and regulatory compliance remains essential for their practical implementation in canola improvement. Full article

Zeolitic imidazolate framework-8 (ZIF-8) is one of the most extensively studied metal–organic frameworks due to its high surface area, tunable porosity, chemical stability, and intrinsic antimicrobial activity. Recent research has focused on engineering ZIF-8 through metal doping and surface functionalization to enhance its physicochemical performance and expand its applications in food safety and environmental systems. Metal-doped ZIF-8 incorporating Cu²⁺, Fe²⁺/Fe³⁺, Ag⁺, or Mn²⁺ improves reactive oxygen species generation, enables controlled metal-ion release, and promotes synergistic bactericidal mechanisms against both Gram-positive and Gram-negative pathogens. In parallel, surface modification using biopolymers such as hyaluronic acid, chitosan, alginate, and polyethylene glycol enhances colloidal stability, reduces cytotoxicity, modulates surface charge, and improves adhesion to food-contact surfaces, thereby enhancing coating stability and sustained antimicrobial activity. These combined strategies support the development of multifunctional nanoplatforms with improved dispersibility, controlled release behavior, and compatibility with food packaging, sanitization, and water treatment applications. From a sustainability perspective, ZIF-8-based systems offer the potential to reduce reliance on conventional chemical disinfectants, minimize chemical residues, and enable the integration of biodegradable polymer matrices for safer and more environmentally responsible antimicrobial solutions. This review summarizes recent advances in synthesis strategies, structure–property relationships, antimicrobial and antibiofilm mechanisms, and environmental safety considerations. Key challenges, including scalability, regulatory acceptance, stability, and long-term ecotoxicological impact, are discussed, along with perspectives on stimuli-responsive systems, essential oil encapsulation, and smart antimicrobial coatings. Full article

The increasing demand for different value-added products from natural seaweeds requires a sustainable cultivation method for the regular supply of biomass and to safeguard the natural ecosystem from overexploitation. This study evaluated laboratory acclimatization of the green seaweed Acrosiphonia orientalis (DGR: 2.71 ± 0.21%; GPP: 12.55 ± 0.1 mg O₂ L⁻¹ day⁻¹), followed by a comparative evaluation of its physicochemical and biochemical characteristics, metabolite profile, and antiproliferative activity compared with naturally harvested seaweed. Metabolite profiling identified 47 compounds exhibiting differential accumulation patterns, with the natural specimens enriched in omega-3 polyunsaturated fatty acids, including docosahexaenoic acid, and the laboratory-acclimatized specimens exhibited elevated arachidonic acid levels. Amino acid profiling revealed higher concentrations of essential and non-essential amino acids in the natural specimens, with prominent levels of phenylalanine and aspartic acid, while the lab-acclimatized specimens were enriched in isoleucine, methionine, proline, and cysteine. The lab-acclimatized specimens exhibited significantly enhanced water absorption (WSC: 6 ± 0.25 mL/g DW; WHC: 2.68 ± 0.11 g/g DW) and higher total sugar (47.11 ± 0.52% Glc eq. DW) and phenolic contents (51.28 ± 0.54 mg GAE g⁻¹ extract), while the natural specimens had a superior oil-holding capacity (OHC: 1.8 ± 0.12 g/g DW); higher total flavonoid (123.62 ± 2.97 mg Q g⁻¹ extract), protein (5.11 ± 0.36 µg BSA eq/mg DW), and chlorophyll contents (8.82 ± 0.58 mg/L); and higher antioxidant activities (ABTS-EC₅₀: 67.33 ± 0.97 μg/mL extract). The mineral analysis revealed distinct elemental profiles, with enrichment of sodium, magnesium, and calcium in the lab-acclimatized specimens and a more favorable Na/K ratio (0.14 vs. 0.78) in the natural specimens. Of note, extracts from both seaweeds exhibited significant dose-dependent antiproliferative activity against HeLa cervical cancer cells (Wild EC₅₀: 118.63 ± 14.14 µg/mL extract; lab EC₅₀: 153.35 ± 10.18 µg/mL extract), suppressed colony formation in soft agar assays, induced nuclear condensation (based on Hoechst staining), and modulated the expression of key oncogenes (upregulating NDRG1, TP53, and CASP3 and downregulating BCL2, MYC, and CCND1). Collectively, this study provides an approach to acclimatize A. orientalis that may be utilized for developing a cultivation method. Moreover, this green seaweed has a great potential to be used for nutraceutical and functional food applications. Full article

Improving nitrogen (N) use efficiency in olive cultivation is essential to address the environmental burden of N fertilizers, whose recovery efficiency rarely exceeds 55%. This study evaluates the agronomic and environmental performance of chabazite-rich zeolite as a soil amendment to enable 50% N-fertilizer reduction in olive growing. A seven-year field experiment (2017–2023) was conducted at two sites in Emilia-Romagna (Italy)—one irrigated (Brisighella) and one rainfed (Bertinoro)—comparing four autochthonous varieties under zeolite amendment (ZEO, 50% N) versus conventional fertilization (CNT, 100% N). Vegetative growth, productive parameters, oil quality and environmental impacts (Life Cycle Assessment, ISO 14040/44) were monitored. Under irrigation, ZEO maintained vegetative and productive equivalence with CNT, sustaining commercially viable yields (0.5–2.3 t ha⁻¹). Under rainfed conditions, variety-specific responses emerged: Colombina exhibited 126.2% greater trunk diameter and near-universal fruiting competence (88.9% vs. 29–35% productive plants) under ZEO, while Capolga showed treatment convergence. LCA revealed higher per-unit environmental impacts for ZEO during early orchard phases due to front-loaded extraction burdens, progressively offset by annual N-input reductions. These findings demonstrate that zeolite amendment enables agronomically viable 50% N-fertilizer reduction, with efficacy modulated by water regime and genotype. Full article

Understanding how different pre-slaughter and slaughter procedures modulate physiological and neurochemical pathways in European sea bass (Dicentrarchus labrax) remains essential for welfare-oriented aquaculture. This study comparatively evaluated six procedures: clove oil and 2-phenoxyethanol anaesthesia, percussive stunning, asphyxiation in ice slurry or on solid ice, and clove oil anaesthesia followed by ice slurry, using plasma glucose and whole-brain monoaminergic indices as integrative physiological response indicators. Ninety-six fish were analysed. Ice-based asphyxiation and 2-phenoxyethanol exposure were associated with the highest plasma glucose concentrations, whereas clove oil and percussive stunning showed comparatively lower values. Dopaminergic and serotonergic turnover ratios (DOPAC/DA; 5-HIAA/5-HT) increased sharply under ice and 2-phenoxyethanol treatments, indicating increased monoaminergic activity under these procedures. Multivariate analyses (MANOVA, PCA) distinguished anaesthetic-based treatments from ice-based methods according to their combined neurochemical profiles. Although correlations between glucose and monoaminergic indices were modest, they were statistically significant and consistent with coordinated metabolic–neurochemical adjustments. Overall, DOPAC/DA and 5-HIAA/5-HT ratios emerged as sensitive and mechanistic biomarkers capable of differentiating slaughter procedures according to their relative physiological impact. These findings support the integration of metabolic and neurochemical indicators in welfare assessment and may contribute to evidence-based refinement of humane slaughter protocols in Mediterranean aquaculture systems. Full article

Liquid infant formula has garnered increasing attention due to its mild thermal processing and superior retention of bioactive nutrients. Within such matrices, the lipid source is a critical determinant of protein digestion behavior, yet its influence on peptide bioavailability and intestinal homeostasis remains undefined. Given that efficient peptide absorption is vital for the systemic delivery of bioactivity in infants, understanding the lipid–protein synergy is essential for formula optimization. Moreover, excessive oxidative stress is closely associated with impaired intestinal health and developmental disorders in infants, making the regulation of oxidative stress crucial for maintaining intestinal function. The present study evaluated the effects of three distinct lipid sources—soybean oil (SM), bovine milk fat (BM), and goat milk fat (GM)—on the physicochemical stability, proteolytic digestion, peptide release, intestinal absorption, and oxidative stress modulation of goat-milk-based infant formula. An integrated approach combining physicochemical characterization, in vitro simulated infant digestion, and a Caco-2 intestinal epithelial cell model was employed. we demonstrate that all three lipids (3% w/w) formed stable emulsions with uniform spherical structures and mean particle diameters of 117–300 nm, as visualized by laser confocal microscopy. Following in vitro simulation of infant gastrointestinal digestion, the SM group exhibited the most extensive protein hydrolysis, yielding the highest total peptide content (4.28 ± 0.10 mg/mL) and generated the highest number of peptides identified by LC-MS/MS (474 types). Bioinformatic analysis predicted that peptides from all groups possess potential antihypertensive, hypoglycemic, and immunomodulatory activities. The Caco-2 monolayer cell model demonstrated that although the GM group produced fewer identified peptide species than the SM group (365 types), it achieved significantly higher intestinal peptide absorption rate (55.34 ± 1.05%). Furthermore, the GM digests provided superior protection against H₂O₂-induced oxidative stress in Caco-2 cells, markedly reducing reactive oxygen species levels and suppressing the expression of pro-inflammatory cytokines TNF-α and IL-6. Collectively, these findings reveal that while soybean oil promotes more extensive proteolysis, the use of homologous goat milk lipid enhances peptide bioaccessibility and confers potential cytoprotective effects on intestinal epithelial cells, underscoring its potential as a preferred lipid source in infant formula formulations. Full article

Background: Orange peels (OP) are rich in flavonoids, pectin, essential oils, and carotenoids that can be upcycled into functional ingredients. These bioactive compounds (BCs) have been increasingly associated with beneficial effects on gastrointestinal (GI) and cardiometabolic health. This scoping review aimed to systematically map available evidence and synthesize reported GI and cardiometabolic health outcomes of upcycled OP ingredients. Methods: Conducted in accordance with PRISMA-ScR guidelines, the literature search was performed in the Scopus database and ClinicalTrials.gov for studies published between 2014–2025 using a predefined Boolean search query. After screening, 84 studies and 14 completed clinical trials met the inclusion criteria. Results: The mapped evidence spans mechanistic (in vitro), preclinical, and clinical studies. Preclinical studies report that flavonoids, pectin, and essential oils modulate gut microbiota composition, enhance intestinal barrier integrity, and improve glycemic, lipid, and inflammatory parameters through mechanisms involving short-chain fatty acid production, antioxidant activity, and modulation of key inflammatory pathways. Clinical studies, predominantly investigating hesperidin-rich and fiber-rich extracts, report improvements in postprandial glycemic response, lipid profiles, blood pressure, and selected microbiota-related markers. Conclusions: Upcycled OP ingredients show promising biological activities relevant to cardiometabolic health and gut modulation, particularly in mechanistic and preclinical models. However, the evidence base remains largely dominated by in vitro and animal studies, with limited and heterogeneous clinical data. Key gaps include the underrepresentation of pectin and carotenoids in human trials and the absence of standardized, long-term intervention studies. Future research should prioritize well-designed clinical trials and investigate potential synergistic interactions among OP-derived bioactive fractions to support their translational application. Full article

Fungal contamination during postharvest storage causes significant food losses, particularly due to Penicillium expansum and Penicillium brevicompactum, highlighting the need for sustainable antifungal alternatives. This study evaluated the antifungal potential of clove essential oil (Syzygium aromaticum) against P. expansum and P. brevicompactum by integrating in vitro assays with in silico analyses. Minimum inhibitory concentrations (MICs) were determined, and effects on fungal growth, membrane integrity, and spore germination were assessed. Molecular docking and molecular dynamics simulations were performed to evaluate the affinity and stability of the five most abundant GC–MS compounds that met predefined ProTox-II toxicity criteria (categories 5–6; LD₅₀ ≥ 2000 mg/kg) toward chitin synthase I (CHS I), a key enzyme in chitin biosynthesis. The oil exhibited strong inhibitory activity, with MIC values of 0.156 µL/mL against P. expansum and 0.312 µL/mL against P. brevicompactum, along with significant morphological and physiological alterations. Computational analyses indicated that trans-β-caryophyllene oxide and α-humulene form stable interactions at both the active and an allosteric site of CHS I, supporting a putative dual inhibitory mechanism. These findings highlight clove essential oil as a promising ecological alternative to synthetic fungicides and underscore the value of computational approaches for elucidating antifungal mechanisms in understudied species. Full article

Soybean (Glycine max (L.) Merr.) is a globally important legume crop valued as a major source of plant-based protein and edible oil. Understanding the transcriptional programs underlying tissue-specific development is essential for improving seed quality and agronomic performance. Here, we present an integrative transcriptomic analysis of soybean based on 12 samples representing key seed developmental stages—including globular, heart, cotyledon, embryo, dry seed, mid-mature, and late-mature—and vegetative and reproductive tissues, including leaf, root, stem, flower bud, and seedling at 6 days after imbibition (6 DAI). Following data preprocessing and filtering, 54,880 genes were retained for downstream analysis. Principal component analysis revealed clear separation between seed and non-seed tissues, indicating that tissue identity is the dominant driver of transcriptomic variation. Analysis of the top 100 most variable genes further highlighted distinct expression modules associated with seed maturation and vegetative growth. Differential expression analysis identified 9785 genes exhibiting significant expression differences between seed and non-seed tissues, including 1139 upregulated and 8646 downregulated genes under relaxed statistical thresholds. Functional characterization of seed-upregulated genes revealed enrichment of biological processes related to storage metabolism, embryo development, and stress protection mechanisms associated with desiccation tolerance. In addition, co-expression network and correlation analyses demonstrated strong transcriptional coherence among seed tissues and distinct clustering of vegetative organs. Together, these results provide a comprehensive systems-level overview of transcriptional organization across soybean tissues and identify candidate gene sets relevant to seed biology, functional genomics, and crop improvement. Full article

Post-weaning diarrhea (PWD) in piglets is a common multifactorial disease in global swine production. Traditional prevention and control strategies relying on high-dose zinc oxide and antibiotics face limitations due to antimicrobial resistance and environmental concerns. This review systematically elucidates the mechanisms of action of plant extracts as alternative interventions against PWD, focusing primarily on categories such as polysaccharides, polyphenols, essential oils, and alkaloids. This review discusses how plant extracts exert their effects through various mechanisms, including improving feed intake, enhancing antioxidant and immune capacities, modulating gut microbiota, repairing intestinal barrier function, and inhibiting pathogens—to alleviate diarrhea induced by weaning stress and pathogenic infections. The findings indicate that plant extracts offer advantages such as multi-target effects, natural origin, and a low propensity for inducing resistance, highlighting their promising potential as alternatives to conventional additives. However, challenges related to compositional complexity, stability, and bioavailability require further investigation and optimization. Full article

Periodontitis is a chronic inflammatory disease marked by the progressive destruction of periodontal tissues, where conventional therapies often fail to maintain adequate drug levels at the target site. This study reports the development and characterization of a thermosensitive gel containing nanostructured lipid carriers (NLC) for controlled local periodontal delivery. Apigenin (AP)-loaded NLC were prepared using AP as active agent and clove essential oil (CEO) as liquid lipid subsequently incorporated into Poloxamer 407 (5–15% w/w) hydrogels. The formulations were evaluated in relation to particle size, morphology, thermal and rheological behavior, mucoadhesion, in vitro release, antibacterial activity, and stability. Optimized nanoscale NLC showed a high entrapment efficiency, and uniform morphology. Raman analysis confirmed successful AP incorporation and homogeneous distribution in the gel without incompatibility. NLC-loaded gels exhibited sol–gel transition at physiological temperature with improved viscoelasticity and enhanced mucoadhesion. The drug release was sustained for 48 h and followed the Korsmeyer–Peppas model, indicating diffusion-based and anomalous transport. The antibacterial assessment demonstrated the pronounced inhibitory activity of the NLC formulations against key periodontal pathogens, with the formulation-dependent modulation of antimicrobial efficacy observed following the gel incorporation. Stability studies showed preserved nanoparticle structure and uniform dispersion. Overall, the thermoresponsive NLC-hydrogel system offers a promising strategy for prolonged, localized periodontal therapy. Full article