Search Results (2,923)

Background/Objectives: Cerebral ischemia–reperfusion injury (CIRI) remains a major challenge in the treatment of ischemic stroke, characterized by intertwined oxidative stress and neuroinflammation. Existing monotherapies often fail to address this dual pathology effectively. We developed PLSCZ, a biomimetic nanoplatform integrating a catalytic core of imidazolate framework-8 (ZIF-8)-encapsulated superoxide dismutase (SOD) and catalase (CAT) enzymes with a hybrid platelet membrane shell. This design strategically employs metal–organic frameworks (MOFs) to effectively overcome the critical limitations of enzyme instability and provide a cascade catalytic environment, while the biomimetic surface modification enhances targeting capability, thereby enabling dual-pathway intervention against CIRI. Methods: PLSCZ was engineered by co-encapsulating SOD and CAT within a ZIF-8 core to form a cascade antioxidant system (SCZ). The core was further coated with a hybrid membrane composed of rapamycin-loaded phospholipids and natural platelet membranes. The nanoparticle was characterized by size, structure, enzyme activity, and targeting capability. In vitro and in vivo efficacy was evaluated using oxygen–glucose deprivation/reoxygenation (OGD/R) models and a transient middle cerebral artery occlusion/reperfusion (tMCAO/r) rat model. Results: In vitro, PLSCZ exhibited enhanced enzymatic stability and cascade catalytic efficiency, significantly scavenging reactive oxygen species (ROS) and restoring mitochondrial function. The platelet membrane conferred active targeting to ischemic brain regions and promoted immune evasion. PLSCZ effectively polarized microglia toward the anti-inflammatory M2 phenotype, reduced pro-inflammatory cytokine levels, restored autophagic flux, and preserved blood–brain barrier integrity. In vivo, in tMCAO/r rats, PLSCZ markedly targeted the ischemic hemisphere, reduced infarct volume, improved neurological function, and attenuated neuroinflammation. Conclusions: By synergistic ROS scavenging and anti-inflammatory action, the PLSCZ nanozyme overcomes the limitations of conventional monotherapies for CIRI. This biomimetic, multi-functional platform effectively reduces oxidative stress, modulates the phenotype of microglia, decreases infarct volume, and promotes neurological recovery, offering a promising multi-mechanistic nanotherapeutic for CIRI and a rational design model for MOF-based platforms. Full article

Apple purée is a processed food typically obtained from ground apples, where quality depends on colour, consistency, and shelf-life. Thermal treatments are commonly applied to adjust rheology and deactivate enzymes responsible for post-packaging deterioration. This study evaluated the effects of heating temperature (87–102 °C) and duration (6–17 min) on the physical and chemical properties of Golden Delicious apple purée. Three independent batches were processed to examine intra-varietal variability. Chemical analyses assessed enzyme activity and nutritional profile, while physical tests focused on rheology. Image analysis was employed to characterise colour and syneresis. Results showed that short-duration heating at higher temperatures (>100 °C, <12 min) achieved desirable rheological properties but intensified browning. No significant correlations were found between residual enzymatic activity, polyphenol content, antioxidant activity, and thermal treatment conditions. This suggests that changes in colour and texture are primarily related to the physical parameters of heating independently of the origin batch. In contrast, the batch had a significant impact on enzymatic and nutritional profiles, highlighting the need for strict monitoring of incoming fruit. Overall, the heating conditions influenced the visual and textural quality of the purée, while the variability in raw materials remained a significant factor affecting its biochemical characteristics. Full article

A novel xylanase gene (RuXyn854) was identified from the rumen metagenome and was heterologously expressed in Escherichia coli to produce xylo-oligosaccharides (XOSs) as a prebiotic in this study. RuXyn854, a member of glycosyl hydrolase family 10, demonstrated peak enzymatic activity at pH 7.0 and 50 °C. RuXyn854 retains more than 50% of its activity after treatment at 100 °C for 10 min, highlighting the enzyme’s excellent heat resistance. RuXyn854 showed a preferential hydrolyzation of xylan, especially rice straw xylan. RuXyn854 activity was significantly increased in the presence of 15 mM Mn²⁺, 0.25% Tween-20, and 0.25% Triton X-100 (125%, 20%, and 26%, respectively). The reaction temperature (30, 40, and 50 °C), dosage (0.20, 0.27, and 0.34 U), and time (90, 120, and 150 min) of RuXyn854 affected the XOS yield and composition, with a higher yield at 0.27 U, 50 °C, and 120–150 min. Xylobiose, xylotriose, and xylotetraose were characterized as the predominant XOS products resulting from the enzymatic hydrolysis of wheat straw xylan by RuXyn854, with xylose present at a mere 0.49% of the total yield. The prebiotic potential of XOSs was assessed through in vitro fermentation with established probiotic strains of Bifidobacterium bifidum and Lactobacillus brevis. The results showed that, regardless of incubation time, XOSs stimulated the growth and xylanolytic enzyme secretion of the two probiotics compared to the controls. These results demonstrate that the feature of RuXyn854 to withstand temperatures up to 100 °C is impressive, and its ability to hydrolyze wheat xylan into XOSs promotes the growth of probiotics. Full article

The tropical gar (Atractosteus tropicus) has significant ecological, economic, and cultural importance in southeast Mexico, where aquaculture is increasing and fish are frequently exposed to stress. In this sense, feed additives such as sage (Salvia officinalis) strengthen organisms’ growth, immune systems, antioxidant capacities, and digestive capabilities. A 30-day experiment was conducted on larvae to determine the effect of different concentrations of sage essential oil (0%, 0.5%, 1%, 1.5%, and 2% treatments) supplemented in balanced diets. Significant differences (p < 0.05) between 0.5% and 2% sage oil supplement treatments for average weight were found. The highest acid and alkaline proteases, chymotrypsin, leucine aminopeptidase, amylase, and lipase activities were obtained for the sage oil-supplemented treatments. In contrast, trypsin showed the highest activity for treatment 0%, followed by diets with 0.5% and 2% sage oil. Regarding the antioxidant enzymatic activity for GPx, CAT and SOD, the highest activity was obtained in the diet with 1% sage oil, while in PEROx, the highest activity was recorded in the treatment with 0%, 1.5% and 2% S. officinalis supplementation. On the other hand, for relative gene expression, the highest expression was observed in sage-supplemented treatments for the nod, zo-1, zo-2, and occ genes. In contrast, the lowest expression was found in supplemented treatments for the il-10 and muc2 genes. These findings suggest that incorporating sage essential oil into the diets of tropical gar larvae, particularly at concentrations of 1.66% and 1.77%, holds potential for enhancing aquaculture practices for this important species. Full article

Postharvest losses in onion (Allium cepa L.) bulbs constitute a major economic challenge globally, primarily driven by fungal pathogens and premature sprouting during long-term storage. Addressing these issues with effective preharvest strategies is critical for market stability and supply chain integrity. This study evaluated the effects of two preharvest fungicide strategies, i.e., T1 (dimethomorph + pyraclostrobin) and T2 (metalaxyl + mancozeb + copper oxychloride), on the crop yield, postharvest quality, and sprouting behavior of dried onion bulbs. Both treatments significantly reduced the incidence of foliar disease in the field and improved the crop yield of commercial bulbs compared to the control in two consecutive seasons. T1 achieved the highest yield (~76 and 88 t ha⁻¹ in ‘Mata Hari’ and ’Recas’ onions). During storage at 20 °C for 84 days, in the ‘Mata Hari’ cultivar, the T1 bulbs exhibited the lowest weight loss and respiration rate, the lowest sprouting incidence (1%), and superior firmness retention and higher total soluble solids. In contrast, control bulbs exhibited accelerated weight loss and tissue degradation, with up to 95% sprouting. Pyruvic acid content, an indicator of pungency, was highest in T1 bulbs and increased significantly in sprouted controls, likely due to internal enzymatic activation and tissue senescence. The fungicides indirectly delayed dormancy release by delaying sprouting and internal stem axis formation. Overall, T1 was the most effective strategy for preserving onion quality during storage without using synthetic sprout inhibitors. These findings support the integration of specific fungicide programs into preharvest management to improve onion storability, reduce postharvest losses, and maintain commercial value in intermediate-dormancy dried onion cultivars, such as ‘Mata Hari’. Full article

Soybean meal causes health issues in piglets due to the presence of antigenic proteins. Although enzymatic treatment can break down antigenic proteins, subsequent high-temperature drying may impair amino acid (AA) digestibility via the Maillard reaction. This study evaluated whether the air-drying temperature affects the ileal AA digestibility of a novel reduced-sugar enzyme-treated soybean meal (ESM) in 25 kg pigs, using fishmeal as a high-digestibility reference. In two trials using pigs fitted with simple T-cannulas in the terminal ileum, ileal digestibility was assessed. In trial 1, a replicated 3 × 3 Latin square design with three diets (fishmeal, ESM, and a nitrogen-free diet; two pigs per diet) and three periods were used per square. Fishmeal showed greater apparent (82.50% vs. 45.01%) and standardized (86.60% vs. 48.86%) digestibility of crude protein and all amino acids than ESM dried at 130 °C. In trial 2, eight pigs were allocated to two diets in a two-period crossover design to compare the AA digestibility of ESM dried at high (130 °C; HtESM) and low (80 °C; LtESM) temperatures. LtESM exhibited greater apparent (82.24% vs. 52.40%) and standardized (86.37% vs. 56.47%) digestibility of crude protein and more amino acids than HtESM. Collectively, the drying temperature critically determined the AA digestibility of ESM, irrespective of its reducing sugar content. Full article

The crystalline structure of cellulose plays a crucial role in its reactivity, which is particularly important in biomass processing involving enzymatic hydrolysis. This study investigates the effect of low-frequency ultrasound (40 kHz) on the efficiency of enzymatic hydrolysis of cellulose in poplar wood and its structure, with a focus on its crystallinity and susceptibility to enzymatic hydrolysis. Two experimental pathways were explored: ultrasound-assisted hydrolysis of raw wood and isolated cellulose. Structural modifications were assessed using Fourier-transform infrared spectroscopy to determine the Lateral Order Index (LOI) and Total Crystallinity Index (TCI), providing insight into the reorganisation of cellulose microstructure. To evaluate hydrolysis efficiency, glucose yields were quantified by high-performance liquid chromatography. The application of ultrasound to raw wood resulted in minimal improvement in sugar release, whereas pretreatment of extracted cellulose led to a modest acceleration of enzymatic hydrolysis. The results show that ultrasound-assisted hydrolysis of raw wood did not significantly increase glucose yield, reaching only 9.9 ± 0.3% and 10.1 ± 0.8% for two poplar hybrids. Only slight increases in TCI and no significant changes in LOI were observed after 4 h of ultrasonic exposure. It indicates limited disruption of the crystalline structure under the tested conditions. Full article

Background/Objectives: This research aims to offer significant insights into the prospective application of bioactive hydrogels composed of alginate, gelatin, and grape skin extract from Serbia (GSE) for treating diabetic wounds, supporting the circular economy and environmental protection. Methods: An acute dermal irritation study was conducted according to OECD guidelines, revealing no visible signs of erythema or edema, confirming the hydrogel’s dermal safety. Afterwards, male Wistar rats were divided into four groups: untreated control (NC), silver sulfadiazine-treated (PC), hydrogel without extract (HG), and hydrogel with GSE (HG + GSE). Wound healing was assessed through a comprehensive approach that included macroscopic wound contraction; biochemical assessment of hydroxyproline content and oxidative stress markers (TBARS, SOD, CAT, GSH); quantification of inflammatory cytokines (TNF-α, IL-6); and histological examination of skin samples using hematoxylin–eosin (H&E) and Masson’s trichrome staining. Results: Daily HG+GSE application over 15 days accelerated wound closure, reaching 99.3% by day 15, surpassing PC (91.2%) and HG (87.7 ± 2.1%). Hydroxyproline levels followed a treatment-dependent pattern, with HG+GSE achieving the highest values throughout, reaching 6.78 ± 0.1 µg/mg dry tissue by day 15—more than double NC. The HG+GSE reduced lipid peroxidation while enhancing enzymatic and non-enzymatic antioxidant defenses and markedly lowered pro-inflammatory cytokine levels, indicating systemic anti-inflammatory activity. Histological analysis revealed faster re-epithelialization, increased collagen deposition, and more organized tissue architecture in the HG+GSE group. These outcomes are attributed to the sustained release of bioactive polyphenols such as naringin, caffeic acid, and epicatechin. Conclusions: Overall, this GSE-based hydrogel presents a multifunctional, biocompatible, sustainable, and effective strategy for diabetic wound care. Full article

The convergence of nanotechnology and bioaerogels has paved the way for the development of multimodal nanostructured bioaerogels with remarkable potential in smart drug delivery systems. These advanced biomaterials integrate multiple functionalities, including sensing, targeting, and therapeutic actions, to enhance drug efficacy, minimize systemic side effects, and enable real-time monitoring of therapeutic responses. This review provides a comprehensive analysis of the structural design, physicochemical properties, and fabrication strategies of multimodal bioaerogels. It further explores their role in responsive drug delivery, emphasizing stimuli-responsive mechanisms such as pH, temperature, and enzymatic triggers. The incorporation of nanomaterials, including metallic nanoparticles, carbon-based nanostructures, and polymeric nanocarriers, has endowed bioaerogels with tunable porosity, controlled drug release, and bioactive functionalities. Additionally, their application in precision medicine, particularly for cancer therapy, antimicrobial treatments, and tissue engineering, is critically examined. Challenges related to scalability, biocompatibility, and regulatory compliance are also discussed, alongside future perspectives on advancing these bioaerogels toward clinical translation. By integrating interdisciplinary insights, this review underscores the transformative potential of multimodal nanostructured bioaerogels in the next generation of intelligent drug delivery systems. Full article

Extracellular glutathione (GSH) is degraded on the cell surface, in which the γ-glutamyl residue is removed to generate cysteine–glycine (Cys–Gly) dipeptides that are subsequently transported to the cytoplasm. Carnosine dipeptidase 2 (CNDP2) is a cytoplasmic enzyme that hydrolyzes Cys–Gly and plays an important role in maintaining intracellular cysteine (Cys) homeostasis. CNDP2-mediated hydrolysis of Cys–Gly promotes Cys mobilization and contributes to the replenishment of intracellular GSH levels. CNDP2 is frequently overexpressed in various cancers and has been implicated in tumor cell proliferation and progression. This mechanism may enhance cancer cell survival by causing resistance to oxidative stress, which indicates that CNDP2 is a potential therapeutic target for cancer treatment. Although bestatin (BES) has been identified as a CNDP2 inhibitor, its limited specificity and suboptimal drug-like properties have limited its therapeutic potential. In this study, we performed an in silico screen of a small-molecule compound library and identified KKL-35 as a novel CNDP2-binding molecule. Molecular dynamics (MD) simulations suggested that KKL-35 interacts within the catalytic pocket. Biochemical assays confirmed that it inhibits CNDP2 enzymatic activity, albeit with lower potency compared with BES. Despite its modest intrinsic activity, KKL-35 exhibits favorable physicochemical and pharmacokinetic properties, which are characterized by a low topological polar surface area (TPSA), reduced molecular flexibility, and well-balanced lipophilicity. This positions it as an attractive and tractable starting point for lead optimization. Taken together, these findings establish KKL-35 as a validated CNDP2 inhibitor and a promising lead compound for the development of more selective therapeutics targeting CNDP2-mediated cancer cell metabolism. Full article

The induction of resistance in plants involves prior activation of physiological and biochemical systems in the face of external stimuli, promoting greater tolerance to biotic stresses. Faced with the growing challenge of emerging diseases in agricultural plants and the search for more sustainable phytosanitary practices, natural substances are promising alternatives. Xylopia frutescens, known as “pindaiba-da-folha-pequena”, native to the Brazilian Cerrado and traditionally used as an antimicrobial treatment, is still little-explored in the literature and presents potentially effective compounds for the control of plant diseases. This study characterized the chemical composition and thermal stability of the X. frutescens essential oil (XEO), while evaluating its physiological and phytotoxic effects and the potential for disease control in maize and cowpea plants. The main constituents found in X. frutescens essential oil were nopinone (13.75%), spatulenol (12.94%), myrtenal (12.47%), and β-pinene (11.02%). Thermogravimetric analysis indicated that X. frutescens is highly volatile, with a large mass loss at 94.74 °C. In bioassays, the oil preserved chlorophyll levels at adequate amounts and activated several antioxidant mechanisms, but also showed a dose-dependent phytotoxic effect. In vitro assays further confirmed its antifungal activity against key phytopathogens, supporting its potential use in disease control. A general increase in the activities of the enzymes superoxide dismutase (SOD), ascorbate peroxidase (APx) and—partially—chitinase (CHIT) was observed. Catalase (CAT) decreased in both maize and cowpea plants treated with this essential oil but was higher in untreated infected plants. Such enzymatic changes suggest that the oil acts as a natural elicitor of resistance, strengthening biochemical and physiological defenses. Finally, disease severities, as measured by AUDPCs, demonstrated significant reductions in the progress of maize “Curvularia leaf spot” (Curvularia lunata) and cowpea “Web blight” (Rhizoctonia solani). The results highlight the potential of X. frutescens essential oil as an active compound stimulating defense mechanisms for applications in sustainable agricultural systems. Full article

The young stem of rapeseed is a highly nutritional vegetable, but there is a lack of information on quality regulation by slow-release fertilizers (SRFs). This study aims to evaluate the effects of SRFs on nutritional contents, including vitamin and sugar profiles and regulatory mechanisms, using enzymatic activity and gene expression analysis. A field experiment was conducted with a split-plot design, in which treatments with two fertilizers (traditional compound fertilizer (TF) and SRF) served as the main plot and two harvesting stages (main stem harvesting (S1) and the first branch harvesting (S2)) served as the sub-plot. The results showed that vitamin E (VE) content under the SRF treatment was 48.31% and 18.44% higher than that under the TF treatment at both stages. The contents of vitamin C (Vc) at the S2 stage and vitamin B6 (VB6) at the S1 stage under the TF treatment were 7.56% and 2.95% higher than under SRF treatments. Water-soluble sugar (WSS) and glucose contents under the SRF treatment were significantly higher than under the TF treatment at both stages, while fructose, trehalose, and sorbitol contents exhibited the opposite trend. The offset effect of the activity of ascorbate oxidase (AAO) and dehydroascorbate reductase (DHAR) between the two fertilizers resulted in a non-significant difference in Vc content at the S1 stage. Under the TF treatment, sucrose phosphate synthase had greater activity as compared to the SRF treatment. The selected key genes involved in vitamin and carbohydrate metabolism were generally in agreement with the changes in enzymatic activity. This study highlights the importance of SRF for the quality formation of young stems of rapeseed as a vegetable. Full article

The aim of this research was to determine the response of white mustard (Sinapis alba L.) cultivated in 2021–2022 in Lucim (53°23′06″ N 17°50′08″ E) in Poland to the soil nitrogen doses: N₄₀—40 kg N·ha⁻¹, N₆₀—60 kg N·ha⁻¹, N₈₀—(40 + 40)-80 kg N·ha⁻¹, as well as the method of its foliar application (0%—no foliar fertilization, 50%—half of the nitrogen dose and 75%—⅔ of the nitrogen dose). The effect of mustard cultivation on the activity of soil dehydrogenase, arylsulfatase, and rhodanese was examined. The highest white mustard seed yield was obtained after application of 80 kg N·ha⁻¹ (1.577, 1.597 Mg·ha⁻¹) and after application of Multi-N_50% (1.490, 1.515 Mg·ha⁻¹). Total nitrogen (50 g·kg⁻¹) content was highest in seeds from treatments fertilized with 80 kg N·ha⁻¹. Similar total nitrogen content in seeds was obtained using a 50% dose of foliar nitrogen. Increasing nitrogen doses resulted in a decrease in the crude fat yield in seeds. However, a significant increase in this nutrient content was observed after application of 50% foliar nitrogen. Soil nitrogen fertilization increased the enzymatic activity of dehydrogenases, particularly at the N80 dose. The activity of this enzyme was positively correlated with the obtained mustard seed yield, as well as with its quality measured by total phosphorus and crude fat content. Full article

Magnetic nanomaterials with enhanced enzymatic activities have garnered significant attention from researchers worldwide. Magnetic nanomaterials, including nanozymes and immobilized enzymes, can initiate specific catalytic reactions in the diseased microenvironment for cancer treatment. In this review, we aim to present the significant advancements in synthesizing various types of magnetic nanomaterials with enhanced enzymatic activities and their antitumor therapy applications in the past five years. We first show the representative magnetic nanomaterials and elucidate their fundamental mechanisms related to magnetic properties and electromagnetic effects (such as magneto-thermal, magneto-mechanical, and magneto-electric effects). Secondly, we introduce magnetic nanozymes and magnetic immobilized enzymes and discuss the creative methods allowing the enzymatic activities of nanomaterials to be remotely enhanced by various electromagnetic effects. We also discuss some innovative magnetic nanomaterials that exhibit unique responsiveness to external energies (such as X-rays and ultrasounds) for killing cancer cells. Finally, we address future research suggestions in rationally designing advanced magnetic nanomaterials with remote increased enzymatic activities and discuss challenges and opportunities for efficient cancer therapy. Full article

Therapeutic peptides have gained significant attention due to their high specificity, potency, and safety profiles in treating various diseases. However, their clinical application via the oral route remains challenging. Peptides are inherently unstable in the gastrointestinal environment, where they are rapidly degraded by proteolytic enzymes and acidic pH, leading to poor bioavailability. Additionally, their large molecular size and hydrophilicity restrict passive diffusion across the epithelial barriers of the gastrointestinal tract. These limitations have traditionally necessitated parenteral administration, which reduces patient compliance and convenience. The oral cavity, comprising the buccal and sublingual mucosa, offers a promising alternative for peptide delivery. Its rich vascularization allows for rapid systemic absorption while bypassing hepatic first-pass metabolism. Furthermore, the mucosal surface provides a relatively permeable and accessible site for drug administration. However, the oral cavities also present significant barriers: the mucosal epithelium limits permeability, the presence of saliva causes rapid clearance, and enzymes in saliva contribute to peptide degradation. Therefore, innovative strategies are essential to enhance peptide stability, retention, and permeation in this environment. Nanoparticle-based delivery systems, including lipid-based carriers such as liposomes and niosomes, as well as polymeric nanoparticles like chitosan and PLGA, offer promising solutions. These nanocarriers protect peptides from enzymatic degradation, enhance mucoadhesion to prolong residence time, and facilitate controlled release. Their size and surface properties can be engineered to improve mucosal penetration, including through receptor-mediated endocytosis or by transiently opening tight junctions. Among these, niosomes have shown high encapsulation efficiency and sustained release potential, making them particularly suitable for oral peptide delivery. Despite advances, challenges remain in translating these technologies clinically, including ensuring biocompatibility, scalable manufacturing, and patient acceptance. Nevertheless, the oral cavity’s accessibility, combined with nanotechnological innovations, offers a compelling platform for personalized, non-invasive peptide therapies that could significantly improve treatment outcomes and patient quality of life. Full article