Search Results (9,099)

In addition to its well-recognized roles in immunomodulation and calcium phosphate homeostasis, growing evidence shows that Vitamin D (Vit. D) presents a wide range of other properties, including antioxidant and anticancer effects. However, the action of Vit. D is not fully recognized in pancreatic cancer (PC) cells exposed to oxidative stress. Therefore, the aim of the present study was to investigate whether vitamin D₃ (Vit. D₃) protects PC cells from death induced by oxidative stress. PC cells are suggested to be resistant to oxidative stress since they demonstrate overexpression of superoxide dismutase (SOD) 1–3. The study measured PC cell viability, DNA damage level, the mRNA and protein expression of antioxidant enzymes, reactive oxygen species (ROS) level and activity of antioxidant enzymes after exposure to H₂O₂, Vit. D₃ and their combinations. N-Acetyl-L-Cysteine (NAC), a well-known direct ROS scavenger, was used as a positive control. Vit. D₃ exposure alone had no effect on PC cell viability, ROS level and DNA damage. Its impact on the mRNA and protein expression of antioxidant enzymes was also scarce. However, Vit. D₃ protected PC cells against H₂O₂-induced death, similarly to NAC. It also diminished the increase in ROS and DNA damage caused by H₂O₂. In addition, Vit. D₃ enhanced the mRNA expression of catalase (CAT), SOD 1–3 and glutathione peroxidase (Gpx)3, but did not affect their protein levels in PC cells exposed to oxidative stress. Interestingly, Vit. D₃ increased CAT activity after 24 h in 1.2B4 cells and elevated the activity of both CAT and Gpx after 2 h in PANC-1 cells, which could contribute to the observed reduction of H₂O₂-induced ROS level. To conclude, our findings show that antioxidant properties of Vit. D₃ may protect PC cells from oxidative stress-induced death. Therefore, further studies are needed to understand the action of Vit. D₃ in PC cells. Full article

Breast cancer remains the most prevalent cancer among women worldwide and a major contributor to cancer-related mortality. Among its subtypes, triple-negative breast cancer (TNBC) is particularly aggressive, with limited therapeutic options and poor survival outcomes. In this study, we investigated the cytotoxic effects of hyperthermia in combination with the chemotherapeutic agents paclitaxel (PTX) and doxorubicin (DOX) in the TNBC cell line MDA-MB-231. Hyperthermia combined with PTX or DOX significantly reduced cell viability compared to the isolated treatments (p < 0.05). The combination with DOX was the most effective, with a 30% greater inhibition of viability compared to DOX alone. Notably, cells treated with 0.04 µM DOX plus hyperthermia (43 °C, 60 min) achieved 47.1 ± 6.8% viability, whereas 0.2 µM DOX alone at 37 °C reduced viability to 52.4 ± 5.0%, representing a fourfold lower drug dose for similar efficacy (Dose reduction index of 5.7). Mechanistic studies revealed that combined treatments impaired cell cycle progression, increased reactive oxygen species (ROS) production, and induced apoptosis. Overall, our findings demonstrate that hyperthermia is a promising adjuvant to enhance the efficacy of PTX and DOX in TNBC cells, potentially reducing required drug doses and associated side effects. Full article

Roxadustat (ROX) is an orally active inhibitor of hypoxia-inducible factor prolyl hydroxylase (HIF-PHI) that exerts erythropoietic, cardioprotective, and metabolic regulatory effects. Approved for the treatment of anemia associated with chronic kidney disease, ROX promotes endogenous erythropoietin production and improves iron homeostasis, providing a non-injectable alternative to conventional erythropoiesis-stimulating agents (ESAs). Its ability to enhance oxygen transport and facilitate muscle recovery has, however, led to its misuse in sports, where it is classified as a banned substance by the World Anti-Doping Agency. This review provides a comprehensive overview of the pharmacological properties of ROX, its approved and investigational clinical applications, and its chemical synthesis strategies. Particular emphasis is placed on the analytical methodologies employed for ROX detection in anti-doping settings. Techniques such as liquid chromatography–tandem mass spectrometry (LC–MS/MS), ultraviolet–visible (UV–Vis) spectroscopy, Fourier-transform infrared spectroscopy (FT-IR), and high-performance thin-layer chromatography (HPTLC) are critically assessed for their efficacy in detecting ROX and its metabolites in biological matrices. Given the increasing incidence of ROX misuse among athletes, ongoing optimization of detection protocols and longitudinal monitoring approaches, are essential to uphold both sports integrity and public health. Full article

The paper systematically investigated the flotation behavior and interaction mechanisms of andalusite and quartz under sodium dodecyl sulfonate (SDS) through integrated experimental and computational approaches, including zeta potential measurements, Fourier-transform infrared (FTIR) spectroscopy, Materials Studio (MS)-based quantum chemical calculations, and single-mineral flotation tests. The results of zeta potential and infrared spectroscopy analysis indicated that SDS underwent strong chemical adsorption on the surface of andalusite, while the adsorption effect on the surface of quartz was not obvious. MS calculations showed that the {100} surface energy of andalusite was the lowest, and it was the most important dissociation surface. After SDS was adsorbed on the {100} surface of andalusite, the aluminum atoms on the surface of andalusite lost electrons, resulting in a significant increase in the number of positive charges they carried. The activity of oxygen atoms was enhanced, while the number of charges carried by silicon atoms changed relatively little. It was indicated that SDS adsorbed the active sites of Al atoms on the surface of andalusite. The results of the pure mineral flotation test further verified the accuracy of the previous test results, indicating that andalusite and quartz had a good flotation separation effect under the SDS system. Full article

The industrial potential of Clostridium beijerinckii for acetone–butanol–ethanol (ABE) fermentation is limited by oxygen sensitivity and suboptimal solvent productivity. Peroxide repressor (PerR), a key negative regulator protein, is reported to suppress the oxidative stress defense system in anaerobic clostridia, leading to poor survival of bacteria under aerobic conditions. However, the regulatory mechanism underlying this phenomenon remains unclear. This study demonstrates that targeted deletion of perR (Cbei_1336) in the solvent-deficient strain C. beijerinckii DS confers robust oxygen tolerance and enhances ABE fermentation performance. The engineered perR mutant exhibited unprecedented aerobic growth under atmospheric oxygen (21% O₂), achieving a (3.79 ± 0.09)-fold increase in biomass accumulation, a (2.84 ± 0.12)-fold improvement in glucose utilization efficiency, a (57.23 ± 0.01)-fold elevation in butanol production, and a (32.78 ± 0.02)-fold amplification in acetone output compared to the parental strain. Transcriptomic analysis revealed that perR knockout simultaneously upregulated oxidative defense systems and activated ABE pathway-related genes. This genetic rewiring redirected carbon flux from acidogenesis to solventogenesis, yielding a (9.64 ± 0.90)-fold increase in total solvent titer (15.61 ± 0.89 vs. 1.62 ± 0.12 g/L) and a (2.71 ± 0.04)-fold rise in volumetric productivity (0.19 ± 0.01 vs. 0.07 ± 0.01 g/L/h). Our findings establish PerR as a master regulator of both oxygen resilience and metabolic reprogramming, providing a scalable engineering strategy for industrial oxygen-tolerant ABE bioprocessing toward low-cost biobutanol production. Full article

Candida albicans (C. albicans) biofilms exhibit enhanced resistance to conventional antifungal agents; however, the underlying pathogenic mechanisms warrant deeper exploration. Protein phosphatase 2A (PP2A), especially its catalytic activity, is crucial for maintaining physiological balance. This study focused on the role of the PP2A catalytic subunit coding gene PPH21 in biofilm formation and drug resistance of C. albicans. The mutant strain (pph21Δ/Δ) was generated and identified. The oxidative stress was detected by the reactive oxygen species (ROS) and mitochondrial membrane potential (MMP). The autophagic activity was evaluated, and the autophagosomes were observed by transmission electron microscopy (TEM). The biofilm formation was measured by XTT reduction assay, crystal violet (CV) staining, and scanning electron microscopy (SEM). The susceptibility to antifungal agents was examined by XTT reduction assay and spot assay. Additionally, the antioxidant N-acetylcysteine (NAC) was applied to clarify the regulatory effect of C. albicans autophagy on oxidative stress. The pathogenicity of PPH21 in oral C. albicans infection was evaluated through in vivo experiments. We found that PPH21 deletion led to increased oxidative stress and autophagic activities, but it can be reversed by the application of NAC. Moreover, PPH21 deletion also impaired the biofilm formation ability and reduced resistance to antifungal agents. Our findings revealed that PPH21 is involved in both virulence and stress adaptation of C. albicans. Full article

Chemiresistive gas sensors are extensively employed in environmental monitoring, disease diagnostics, and industrial safety due to their high sensitivity, low cost, and miniaturization. However, the high cross-sensitivity and poor selectivity of gas sensors limit their practical applications in complex environmental detection. In particular, the mechanisms underlying the selective response of certain chemiresistive materials to specific gases are not yet fully understood. In this review, we systematically discuss material design strategies and system integration techniques for enhancing the selectivity and sensitivity of gas sensors. The focus of material design primarily on the modification and optimization of advanced functional materials, including semiconductor metal oxides (SMOs), metallic/alloy systems, conjugated polymers (CPs), and two-dimensional nanomaterials. This study offers a comprehensive investigation into the underlying mechanisms for enhancing the gas sensing performance through oxygen vacancy modulation, single-atom catalysis, and heterojunction engineering. Furthermore, we explore the potential of emerging technologies, such as bionics and artificial intelligence, to synergistically integrate with functional sensitive materials, thereby achieving a significant enhancement in the selectivity of gas sensors. This review concludes by offering recommendations aimed at improving the selectivity of gas sensors, along with suggesting potential avenues for future research and development. Full article

Oxidative stress is a factor implicated in chronic diseases and aging, motivating the search for natural antioxidants. Over the past ten years, food-derived peptides have been recognized as potent antioxidants. Carp, a globally farmed fish, is a protein-rich raw material for producing antioxidant peptides and hydrolysates. This review summarizes the current knowledge on these antioxidant peptides and hydrolysates, including their production, bioactivity, and applications. We discuss how enzymatic hydrolysis of carp by-products (e.g., skin, scales, and swim bladders) represents a strategy for waste valorization. Cellular and in vivo findings demonstrate the effectiveness of carp peptides and hydrolysates in tackling oxidative stress by reducing reactive oxygen species and enhancing cellular antioxidant enzymes. In addition to their antioxidant properties, these peptides and hydrolysates also possess anti-inflammatory, anti-melanogenic, and wound-healing properties. Potential applications of carp peptides and hydrolysates include their use as natural food preservatives and as active ingredients for skincare, nutraceuticals, and sports nutrition. Future research should focus on validating the in vivo bioavailability and assessing the long-term safety of carp peptides and hydrolysates to support their potential application in health. Carp-derived peptides are a valuable resource for developing functional foods and health products, which can contribute to a more sustainable food industry. Full article

Earthen final covers (EFCs) are widely used to mitigate environmental impacts from landfills, particularly in controlling methane emissions and groundwater contamination. In this study, a one-dimensional numerical model was built to simulate the interactions of liquid water, water vapor, landfill gas, and heat, incorporating the biochemical process of methane oxidation. Parametric studies revealed that both atmospheric and waste temperatures significantly influence the soil temperature and evaporation, thereby affecting methane oxidation. Oxidation efficiency increased from 8.7% to 55.3% as atmospheric temperature rose from 5 °C to 35 °C. High waste temperatures enhanced oxidation by up to 2.9 times under cold conditions. An increase in atmospheric pressure (950–990 mbar) promoted oxygen diffusion into the cover and improved oxidation efficiency from 0.8% to 77.1%. Atmospheric relative humidity also played a critical role by affecting surface evaporation, with higher humidity promoting better water retention but limiting oxygen diffusion. The methane oxidation performance of the cover declined by 12.0% to 68.5% compared to pre-rainfall conditions. Rainfall temporarily inhibited oxidation due to moisture-induced oxygen limitation, with partial recovery after rainfall ceased. This study provided valuable insights into the complex interactions between ambient conditions and EFC performance, contributing to the optimization of landfill cover designs and methane mitigation strategies. Full article

In this study, we optimize the kitchen waste fermentation process by adjusting the fermentation time and temperature to prepare high-efficiency carbon sources to enhance nitrogen and phosphorus removal during sewage treatment. Simulated kitchen waste fermentation experiments were performed, and the impact on the pollutant removal efficiencies was analyzed using a sequence batch reactor (SBR). The results showed that the volatile fatty acid (VFA) concentration peak occurred on the first day of fermentation, the maximum increment was 543.19 mg/L, and the maximum soluble chemical oxygen demand/total nitrogen (COD/TN) ratio was 40.49. However, the highest total nitrogen (TN) removal efficiency was 70.42% on the second day of fermentation. An increase in temperature promoted organic matter release, with the highest soluble COD concentration of 22.69 g/L observed at 45 °C. Further, the maximum VFAs production (935.08–985.13 mg/L) occurred from 25 to 35 °C. In addition, the fermentation products in this temperature range also showed the optimal removal efficiencies for total phosphorus (TP) and TN at 91.50% and 79.63%, respectively. Although 15 °C and 45 °C were beneficial for COD reduction, they were not conducive to nitrogen and phosphorus removal. The energy consumption and the synergistic pollutant removal showed that the optimal fermentation conditions were 2 days at 35 °C. Under these conditions, the kitchen waste-derived carbon source achieved efficient TN and TP removal, as well as COD reduction. Therefore, these conditions provide a feasible solution for the “reduction and sustainability” of kitchen waste. Full article

Burn wounds are complex injuries that require timely and accurate assessment to guide treatment decisions and improve healing outcomes. Traditional clinical evaluations are largely subjective, often leading to delays in intervention and increased risk of complications. Imaging technologies have emerged as valuable tools that enhance diagnostic accuracy and enable objective, real-time assessment of wound characteristics. This review aims to evaluate the range of imaging modalities currently applied in burn wound care and assess their clinical relevance, diagnostic accuracy, and cost-effectiveness. It explores how these technologies address key challenges in wound evaluation, particularly related to burn depth, perfusion status, bacterial burden, and healing potential. A comprehensive narrative review was conducted, drawing on peer-reviewed journal articles, NICE innovation briefings, and clinical trial data. The databases searched included PubMed, Ovid MEDLINE, and the Cochrane Library. Imaging modalities examined include Laser Doppler Imaging (LDI), Fluorescence Imaging (FI), Near-Infrared Spectroscopy (NIR), Hyperspectral Imaging, Spatial Frequency Domain Imaging (SFDI), and digital wound measurement systems. The clinical application and integration of these modalities in UK clinical practice were also explored. Each modality demonstrated unique clinical benefits. LDI was effective in assessing burn depth and perfusion, improving surgical planning, and reducing unnecessary procedures. FI, particularly the MolecuLight i:X device (MolecuLight Inc., Toronto, ON, Canada), accurately identified bacterial burden and guided targeted interventions. NIR and Hyperspectral Imaging provided insights into tissue oxygenation and viability, while SFDI enabled early detection of infection and vascular compromise. Digital measurement tools offered accurate, non-contact assessment and supported telemedicine use. NICE recognized both LDI and MolecuLight as valuable tools with the potential to improve outcomes and reduce healthcare costs. Imaging technologies significantly improve the precision and efficiency of burn wound care. Their ability to offer objective, non-invasive diagnostics enhances clinical decision-making. Future research should focus on broader validation and integration into clinical guidelines to ensure widespread adoption. Full article

Acute Myeloid Leukemia (AML) is a genetically and clinically heterogeneous malignancy marked by poor prognosis and limited therapeutic options, especially in older patients. While conventional treatments such as the “7 + 3” chemotherapy regimen and allogeneic stem cell transplantation remain standard care options, the advent of next-generation sequencing (NGS) has transformed our understanding of AML’s molecular complexity. Among the emerging hallmarks of AML, metabolic reprogramming has gained increasing attention for its role in supporting leukemic cell proliferation, survival, and therapy resistance. Distinct AML subtypes—shaped by specific genetic alterations, including FLT3, NPM1, and IDH mutations—exhibit unique metabolic phenotypes that reflect their underlying molecular landscapes. Notably, FLT3-ITD mutations are associated with enhanced reactive oxygen species (ROS) production and altered energy metabolism, contributing to disease aggressiveness and poor clinical outcomes. This review highlights the interplay between metabolic plasticity and genetic heterogeneity in AML, with a particular focus on FLT3-driven metabolic rewiring. We discuss recent insights into how these metabolic dependencies may be exploited therapeutically, offering a rationale for the development of metabolism-targeted strategies in the treatment of FLT3-mutated AML. Full article

Dysregulation of hepatic lipid metabolism constitutes a central mechanism in the pathogenesis of metabolic dysfunction-associated steatotic liver disease (MASLD). 3,3′-Diindolylmethane (DIM), a bioactive compound abundant in dietary Brassica vegetables, exhibited protective effects on hepatocellular carcinoma and metabolic/inflammatory pathologies. Nevertheless, the effects of DIM on hepatic lipid metabolism and its underlying mechanisms remain unclear. Administration of DIM (50 mg/kg bw/day) prevented oxidative stress and hepatic lipid deposition in both high-fat diet (HFD)-fed wild-type (WT) and ob/ob mice. Lipidomics revealed that DIM diminished the lipogenesis and reshaped the hepatic lipid profile. Network pharmacology analysis identified the AMPK signaling pathway as the underlying mechanistic target for DIM in treating MASLD. In both HepG2 cells and mouse primary hepatocytes (MPH), DIM attenuated palmitic acid (PA)-induced cellular lipid accumulation, ROS generation, and reduction in oxygen consumption rate (OCR). These protective effects of DIM were diminished by co-treatment with Compound C (CC), a specific AMPK inhibitor. DIM administration enhanced AMPKα phosphorylation in vivo (WT/ob/ob mice) and in vitro (HepG2/MPH), concomitant with PPARα upregulation and SREBP1/ACC1 downregulation. CC abolished all DIM-induced molecular changes in vitro. Collectively, DIM alleviates hepatic lipid accumulation and oxidative stress in MASLD models through AMPK activation, subsequently modulating PPARα and SREBP1/ACC1 pathways. Full article

The wastewater discharged from the aquaculture and textile industries often contains toxic organic dyes, such as methylene blue (MB) and malachite green (MG), which pose significant risk to public health and ecosystem stability due to their high chemical stability, bioaccumulation potential and resistance to degradation. To address these challenges, the development of an integrated system capable of both efficient degradation and highly sensitive detection of organic dyes is essential for ecological restoration and early pollution monitoring. Herein, bifunctional Fe₃O₄-Cu₂O-Ag-GO (FCA 2-GO) nanocomposites (NCs) were developed by depositing Cu₂O, Ag nanocrystals and graphene oxide (GO) onto the surfaces of Fe₃O₄ nanocrystals. This multifunctional material acted as both a photocatalyst and a surface-enhanced Raman scattering (SERS) platform, enabling simultaneous degradation and ultrasensitive detection of organic dyes. Under simulated sunlight irradiation, FCA 2-GO NCs achieved over 98% degradation of both MB and MG within 60 min, driven by the synergistic action of reactive oxygen species (·O₂⁻ and ·OH). The degradation kinetics followed pseudo-first-order behavior, with rate constants of 0.0381 min⁻¹ (MB) and 0.0310 min⁻¹ (MG). Additionally, the FCA 2-GO NCs exhibited exceptional SERS performance, achieving detection limits as low as 10⁻¹² M for both dyes, attributed to electromagnetic–chemical dual-enhancement mechanisms. Practical applicability was demonstrated in soil matrices, showcasing robust linear correlations (R² > 0.95) between SERS signal intensity and dye concentration. This work provides a dual-functional platform that combines efficient environmental remediation with trace-level pollutant monitoring, offering a promising strategy for sustainable wastewater treatment and environmental safety. Full article

This study presents a machine learning-enhanced optimization framework for proton exchange membrane fuel cell (PEMFC), designed to address critical challenges in dynamic load adaptation and thermal management for automotive applications. A high-fidelity model of a 65-cell stack (45 V, 133.5 A, 6 kW) is developed in MATLAB/Simulink, integrating four core subsystems: PID-controlled fuel delivery, humidity-regulated air supply, an electrochemical-thermal stack model (incorporating Nernst voltage and activation, ohmic, and concentration losses), and a 97.2–efficient SiC MOSFET-based DC/DC boost converter. The framework employs the NSGA-II algorithm to optimize key operational parameters—membrane hydration (λ = 12–14), cathode stoichiometry (λO₂ = 1.5–3.0), and cooling flow rate (0.5–2.0 L/min)—to balance efficiency, voltage stability, and dynamic performance. The optimized model achieves a 38% reduction in model-data discrepancies (RMSE < 5.3%) compared to experimental data from the Toyota Mirai, and demonstrates a 22% improvement in dynamic response, recovering from 0 to 100% load steps within 50 ms with a voltage deviation of less than 0.15 V. Peak performance includes 77.5% oxygen utilization at 250 L/min air flow (1.1236 V/cell) and 99.89% hydrogen utilization at a nominal voltage of 48.3 V, yielding a peak power of 8112 W at 55% stack efficiency. Furthermore, fuzzy-PID control of fuel ramping (50–85 L/min in 3.5 s) and thermal management (ΔT < 1.5 °C via 1.0–1.5 L/min cooling) reduces computational overhead by 29% in the resulting digital twin platform. The framework demonstrates compliance with ISO 14687-2 and SAE J2574 standards, offering a scalable and efficient solution for next-generation fuel cell electric vehicle (FCEV) aligned with global decarbonization targets, including the EU’s 2035 CO₂ neutrality mandate. Full article