Search Results (11,495)

Acute coronary syndrome patients undergoing percutaneous coronary intervention remain at high risk for major adverse cardiovascular events (MACE: cardiovascular mortality, non-fatal myocardial infarction, and stroke). Inflammatory–oxidative stress biomarkers are potential prognostic tools; however, the influence of sampling timing—pre-procedural versus post-procedural—remains unclear. This meta-analysis evaluated six biomarkers: sST2, GDF-15, OPG, sLOX-1, H-FABP, and Galectin-3. Pooled Hazard Ratios (HRs) for time-to-event outcomes and Standardized Mean Differences (SMDs) between event and non-event groups were synthesized using random-effects models involving 40 studies (18,933 patients). Elevated pre-procedural levels of sST2 (HR = 3.32, p < 0.0001), GDF-15 (HR = 3.00, p < 0.0001), sLOX-1 (HR = 2.61, p = 0.0023), and OPG (HR = 1.79, p = 0.0206) significantly predicted MACE. Notably, pre-PCI sST2 strongly predicted heart failure hospitalization (HR = 6.30, p < 0.0001). Additionally, pre-PCI H-FABP demonstrated a moderate significant effect on adverse outcomes (SMD = 0.67, p < 0.0001). While pre-PCI Galectin-3 was not significant, its post-procedural levels showed a large significant effect (SMD = 1.15, p < 0.0001). In conclusion, inflammatory and oxidative stress biomarkers, particularly sST2 and GDF-15, demonstrate consistent associations with adverse outcomes in ACS patients undergoing PCI, offering more reliable baseline risk stratification than post-procedural measurements. Full article

Oxidative catalytic fractionation (OCF) under the lignin-first strategy has emerged as a critical technological approach for biomass refining. To address the inevitable carbohydrate degradation and lignin condensation in conventional OCF, this study designed a cobalt-doped layered double hydroxide oxide (Co-LDO) catalyst compatible with non-alkaline (without Brønsted bases) organic systems, which exhibits excellent performance in poplar biomass OCF. With a straightforward preparation process, the Co-LDO catalyst yields high-content oxidized lignin oligomers while efficiently retaining carbohydrates, providing feedstock rich in carbohydrates (cellulose and hemicellulose) for the subsequent production of bioenergy and biomass-based chemicals. Under optimized conditions screened via systematic reaction condition investigation and metal-doped LDO catalyst evaluation, the process achieved a 94.01 wt% delignification rate, with 72.19 wt% of lignin converted into lignin oligomer oil, supported by detailed product composition and structural characterization. Meanwhile, 74.14 wt% hemicellulose and 98.23 wt% cellulose were recovered in solid residues, with structurally intact hemicellulose retention being 2.3 times higher than in traditional OCF. Mass balance calculation confirmed a total poplar refining yield of 81.58 wt%. In summary, this Co-LDO-catalyzed OCF strategy provides a high-activity non-precious metal system, effectively suppressing lignin condensation while preserving high-yield carbohydrates, realizing the efficient full-component refining of poplar biomass. Full article

Chronic social isolation (CSIS) is a form of psychosocial stressor strongly associated with the development of depression. Preclinical studies demonstrated that CSIS induces behavioral phenotypes resembling human depression, including anhedonia, behavioral despair and anxiety. This review summarizes proteomic-driven discoveries characterizing hippocampal non-synaptic mitochondria (NSM) and synaptosomal fractions containing synaptic mitochondria from adult male rats exposed to six weeks of CSIS, an animal model of depression, compared to controls. The compartment-specific proteomic alterations reveal mechanisms underlying mitochondrial dysregulation, providing molecular insights into the depression-like phenotype. Hippocampal NSM exhibit changes in energy metabolism-related proteins, including components of the tricarboxylic acid cycle and oxidative phosphorylation, as well as mitochondrial transport proteins and alterations in chaperones, structural and translational proteins, and monoamine oxidase, further elucidating how these proteomic changes contribute to mitochondrial dysregulation. In contrast, synaptosomal proteomics reveal predominantly increased protein abundance associated with energy metabolism, signaling, cytoskeletal organization, protein quality control, and vesicle trafficking, suggesting compensatory adaptations. Together, these findings highlight compartment-specific mitochondrial proteomic changes that may underlie depression-like behaviors and represent potential targets for therapeutic intervention. Full article

Ultraviolet (UV) irradiation induces complex skin damage, including hyperpigmentation, oxidative stress, and alterations in proteins related to keratinocyte differentiation and epidermal barrier-associated status. This study investigated the multifunctional protective effects of Padina arborescens ethanolic extract (PAEE) against skin damage in melanocytes, keratinocytes, and zebrafish. In alpha-melanocyte-stimulating hormone (α-MSH)-stimulated B16F10 cells, PAEE effectively suppressed the protein kinase A (PKA)/cyclic adenosine monophosphate (cAMP) response element-binding protein (CREB) signaling pathway, which was associated with reduced expression of microphthalmia-associated transcription factor (MITF) and tyrosinase, leading to decreased melanin synthesis. PAEE also exhibited photoprotective properties by reducing reactive oxygen species (ROS), inhibiting interleukin-1 beta (IL-1β), and attenuating matrix metalloproteinase-1 (MMP-1) upregulation associated with UVB (ultraviolet B)-induced photodamage in HaCaT keratinocytes. Notably, PAEE restored the UVB-reduced expression of filaggrin and involucrin, representative markers of keratinocyte differentiation and epidermal barrier-associated status, in HaCaT keratinocytes. In zebrafish embryos, PAEE suppressed α-MSH-induced melanin accumulation and UVB-induced ROS generation at non-toxic concentrations. Taken together, these results suggest that PAEE exerts anti-melanogenic and photoprotective effects in cellular and zebrasfish models and may serve as a promising marine-derived ingredient for cosmeceutical applications targeting UVB-related skin damage. Full article

Hemostatic biomaterial agents are widely used during surgery and trauma care to control bleeding, yet their effects on wound healing remain incompletely understood. This study evaluated the impact of oxidized non-regenerated cellulose (ONRC), oxidized regenerated cellulose (ORC), and a gelatin-based hemostat (GELA) on wound healing at 14 and 30 days in a mouse model. Full-thickness wounds were created in C57BL/6J mice (n = 192) and compared to sham controls. Tissue samples were analyzed histologically, supported by immunohistochemistry for Ki-67 and α-SMA and qPCR for VEGF, TGF-β, and FGF-2. Histology demonstrated preserved tissue architecture across groups with progressive resorption of cellulose-based materials, whereas GELA showed localized fibrous structures and enhanced extracellular matrix formation. At day 14, no significant differences were observed in proliferation, contraction, VEGF, or FGF-2 expression; however, TGF-β was significantly reduced in the ORC group. By day 30, GELA significantly increased epidermal proliferation, while contraction markers were elevated in both GELA and ORC. VEGF expression was reduced in GELA and ORC, whereas ONRC showed increased TGF-β expression. FGF-2 remained unchanged across groups. All investigated hemostatic materials were well tolerated during the early postoperative phase (up to day 14), indicating short-term biocompatibility within the scope of this model. In contrast, material-specific differences in cellular activity and growth factor expression became apparent during the later remodeling phase (day 30). These findings suggest differential effects on cellular and molecular aspects of tissue remodeling; however, no conclusions can be drawn regarding overall healing quality or clinical safety, as no quantitative macroscopic or functional outcome measures were assessed. Full article

Background/Objectives: Oxidative stress plays an important role in the pathophysiology of endometriosis, contributing to inflammation, immune dysregulation, and lesion progression. This has led to growing interest in antioxidant-based strategies as potential supportive interventions. Methods: A literature search was conducted using PubMed, Scopus, and Web of Science databases, covering studies published from database inception until the end of January 2026. The review focused on clinically relevant endpoints, including pain intensity, markers of inflammation and oxidative stress, reproductive parameters, and quality of life. Results: Among the analyzed interventions, the most consistent clinical effects were observed with melatonin, with randomized controlled trials indicating a moderate reduction in pain. N-acetylcysteine shows potentially beneficial effects; however, the available clinical data remain limited and heterogeneous. For other supplements, the evidence is inconsistent or insufficient to support clear clinical conclusions, and in many cases relies on indirect or mechanistic findings rather than well-established clinical outcomes. Conclusions: Current evidence does not support the use of non-mineral antioxidant supplements as standalone therapy for endometriosis. They may be considered as adjunctive strategies, although their clinical effectiveness remains uncertain and requires confirmation in well-designed randomized clinical trials. Full article

Fibromyalgia (FM) is a complex chronic syndrome marked by widespread musculoskeletal pain, neurocognitive dysfunction (“fibro-fog”), and autonomic disturbances. Clinical management remains challenging due to subjective symptom reporting and the lack of definitive diagnostics. Emerging evidence points to a multifactorial origin involving central sensitization, neuroendocrine imbalance, and systemic immune-inflammatory alterations. A wide array of candidate biomarkers has been reported in FM, encompassing neurotransmitters (serotonin, norepinephrine), excitatory and inhibitory amino acids, metabolic and glycolytic enzymes, stress-related proteins, autoantibodies, oxidative stress markers and pro-inflammatory cytokines. This molecular heterogeneity reflects the systemic and multidimensional nature of FM. However, most of these biomarkers have been primarily investigated in serum or plasma, where analytical validation and reference ranges are more established. In contrast, the exploration of salivary biomarkers—although highly attractive due to its non-invasive, stress-free, and repeatable collection—remains comparatively limited. Saliva contains a reduced concentration range of many systemic markers and is strongly influenced by circadian rhythms, stress, flow rate, and oral health conditions. While promising candidates such as α-amylase, cortisol, calgranulins, and selected metabolic enzymes have shown potential in saliva, many proposed FM-related biomarkers lack full analytical validation, standardized protocols, and clinically defined reference intervals in this matrix. In this context, non-invasive electrochemical biosensors represent a transformative technological approach. Advanced electrode architectures incorporating nucleic acid probes, redox reporters, and nanostructured materials offer high sensitivity in low-volume and low-concentration biofluids such as saliva. The integration of multiplexed biomarker panels into portable platforms could enable real-time, longitudinal monitoring of FM pathophysiology, supporting phenotype stratification, personalized therapeutic adjustment, and objective disease activity tracking. Full article

Background/Objectives: Trace metal homeostasis is regulated by nutritional status and is crucial for maintaining redox balance, vascular function, and neuroinflammation. Dysregulation of systemic copper (Cu) metabolism, especially an elevated level of non-ceruloplasmin-bound copper (NCC), has been linked to oxidative stress and early cognitive decline. However, the nutritional and molecular pathways that connect Cu imbalance to mild cognitive impairment (MCI) are not well understood. Methods: We compared the serum Cu and zinc levels of individuals with normal cognition (NC; n = 116) and MCI (n = 184). An exploratory serum proteomic analysis using pooled samples was conducted to investigate patterns related to Cu dysregulation. We identified proteins using pattern correlation analysis and then performed a protein–protein interaction analysis using STRING and functional annotation and biological and Kyoto Encyclopedia of Genes and Genomes pathways. Results: The individuals with MCI had higher NCC levels than those with NC, indicating disrupted Cu metabolism influenced by nutrition and metabolism. The proteomic analysis revealed changes in proteins related to lipid transport, metal balance, and inflammation, including transthyretin, transferrin, apolipoprotein A-I, alpha-1 antitrypsin, antithrombin III, and alpha-2-macroglobulin, which respond to oxidative stress and vascular injury. Conclusions: In this cross-sectional analysis of baseline data, NCC levels were associated with cognitive status and specific circulating proteomic profiles. These findings suggest a potential relationship between copper-related biomarkers and mild cognitive impairment; however, longitudinal studies are required to clarify temporal relationships and potential mechanistic pathways. Full article

Thermal–oxidative coking of aviation fuel remains a critical limitation for fuel-cooled aero-engine systems operating under high heat loads. This study systematically investigates the oxidative coking behavior of RP-3 aviation kerosene, focusing on the coupled evolution of deposit morphology, composition, and operating conditions. Experiments were conducted in an electrically heated stainless-steel tube while independently varying dissolved oxygen concentration, fuel temperature, temperature gradient, operating pressure, and heating duration. Deposit layers were characterized by SEM and XPS, and residual fuel chemistry was analyzed using GC/MS. The results show that dissolved oxygen governs both the extent and mechanism of coking in the autoxidation regime (150–450 °C). Normal and elevated oxygen levels promote autoxidation of straight-chain alkanes, generating oxygen-containing intermediates that form flocculent, oxygen-rich deposits, whereas near-deoxygenated conditions suppress autoxidation but sustain sulfur-dominated, needle-like deposits. Temperature primarily controls deposition rate and morphology, with steep temperature gradients inducing localized coke formation, while pressure exerts only a minor indirect influence. Prolonged operation leads to deposit densification and non-linear accumulation behavior. These findings clarify the links between fuel chemistry, thermal conditions, and deposit architecture, providing a basis for morphology-aware coking models in fuel-cooled aero-engine systems. Full article

Underutilized plant by-products are an overlooked source of natural extracts that contain antioxidant bioactive compounds and therapeutic potential. Oxidative stress significantly contributes to the development of various chronic diseases. In this context, natural extracts rich in bioactive compounds derived from underutilized plant by-products emerge as promising options for developing antioxidant-based therapies that target oxidative stress-related molecular pathways involved in the pathogenesis of chronic disease. The valorization of by-products through the recovery of antioxidant-rich extracts is particularly appealing, as non-edible plant parts often contain higher levels of bioactive compounds than their edible counterparts. This review provides a comprehensive overview of antioxidant natural extracts and their major bioactive components, including polyphenols (particularly flavonoids and phenolic acids), terpenoids, alkaloids, and other redox-active compounds. Full article

We previously demonstrated that a clinically relevant dose of pemafibrate (PEM), a selective peroxisome proliferator-activated receptor α (PPARα) modulator (SPPARMα), reduces serum triglyceride (TG) levels in mice via hepatic PPARα activation. However, the specific contribution of hepatocyte PPARα remains unclear. To address this, male Ppara-floxed (Ppara^fl/fl) and hepatocyte-specific Ppara-disrupted (Ppara^ΔHep) mice were fed a diet with or without a clinically relevant dose of PEM (0.00005%) for four weeks. In Ppara^fl/fl mice, PEM significantly reduced circulating TG and non-esterified fatty acid levels by enhancing hepatic fatty acid uptake and β-oxidation. In contrast, these effects were absent in Ppara^ΔHep mice. Notably, PEM did not activate PPARα in extrahepatic tissues, including white/brown adipose tissue, kidney, and skeletal muscle in either genotype. These findings underscore the essential role of hepatocyte PPARα in mediating the pharmacological effects of PEM at clinically relevant doses. Full article

Cellular homeostasis is a dynamic process which balances anabolic processes with catabolic and recycling processes. These processes require nutrients, which are converted to energy to fuel the complex interactions of intracellular signalling. Cellular health requires that, on average, energy input and energy requirements are matched. Cells contain a nutrient-sensing mechanism which controls the balance between anabolism and catabolism. Normal intracellular functions generate products which regulate signalling pathways, and health at a cellular level requires a fluctuation between relative nutrient abundance and relative nutrient scarcity. This allows clearance of damaged intracellular molecules and organelles. When nutrient supply exceeds cellular requirements, adaptations to intracellular signalling occur, resulting in energy being stored as glycogen in muscle and the liver and fatty acids in adipose tissue. Overfuelling and aberrant fuelling of mitochondria result in oxidative stress, which not only disrupts cellular homeostasis but can alter epigenetic expression, with intergenerational effects. If the recycling mechanisms of the cell are insufficient to clear metabolic products, apoptosis may result or expression of Damage-Associated Molecular Patterns (DAMPs) on the cell surface may occur, activating immunity and inflammation at a systemic level. Disrupted cellular signalling affects cells with different “professional” functions in different organs, and it is the mechanism which underlies the associations between chronic non-communicable diseases such as cancer, type 2 diabetes, cardiovascular disease, neurodegenerative disease, autoimmune diseases, and macular degeneration. Mitochondria are the controllers of energy production and are pivotal in cell signalling. Mitochondrial function governs health at cellular and organismal levels. This paper reviews the influence of nutrition on mitochondrial function, nutrient sensing, autophagy, insulin signalling, and apoptosis—the key pathways in cellular homeostasis. Full article

Ophiobolin A is a fungal sesterterpenoid initially characterised as a phytotoxin but progressively investigated for its biomedical significance due to its potent and mechanistically characteristic cellular activities. In this review, Ophiobolin A is discussed within the wider landscape of natural products as a source of bioactive molecular scaffolds, and current knowledge on its structural features, biosynthesis, chemical synthesis, semi-synthetic modification, and in vitro biological applications is summarised. Evidence drawn from chemical, biochemical, and cell biology studies is integrated to describe the distinctive 5-8-5 tricyclic scaffold, the electrophilic dicarbonyl motif, and their roles in covalent modification of cellular components. Collectively, the reviewed evidence underscores that Ophiobolin A and its derivatives trigger both apoptotic and non-apoptotic cell death pathways. These include paraptosis-like death, which is a regulated form of cell death not associated with apoptosis that is defined by major cytoplasmic vacoulisation. This commonly occurs in apoptosis-resistant cancer models via disruption of membrane lipid homeostasis, calmodulin-dependent signalling, mitochondrial function, and proteostasis. Structure–activity relationship studies show that modulation of electrophilicity, oxidation state, and peripheral functionality enables tuning of potency, selectivity, and traceability while retaining key phenotypes. In addition to anticancer effects, antimicrobial and anti-inflammatory activities are also briefly summarised. Taken together, the literature supports Ophiobolin A as a useful molecular probe for considering cell death mechanisms and as a chemically complex yet suitable starting point for derivative development, while reinforcing the need for improved selectivity, delivery strategies, and in vivo validation to further translational potential. Full article

Port activities significantly alter local atmospheric chemistry, yet the nonlinear coupling mechanisms between nitrogen oxides (NO_x) and ozone (O₃) in these complex environments remain underexplored. In this study, MF-DFA and MF-DCCA were applied to explore the coupling dynamics between NO_x and O₃ in Hong Kong’s Kwai Chung port and Tap Mun non-port areas. Results indicate that while both pollutants exhibit multifractality, O₃ shows stronger persistence and scale-invariant complexity than NO_x (e.g., in the port area, spectral width Δα = 0.61 for O₃ vs. 0.40 for NO_x). Crucially, the non-port area demonstrates significantly stronger and more stable cross-correlations (with the cross-correlation Hurst exponent h_xy(2) = 0.85 and h_xy(q) ranging from 0.80 to 0.99) compared to the port area (h_xy(2) = 0.60, h_xy (q) ranging from 0.54 to 0.74). The weaker coupling in the port zone is attributed to the fact that intermittent factors such as ship emissions have disrupted the long-term memory of the system. The connections in non-port areas are stronger and more stable because they are less affected by local emissions and chemical processes. The cross-correlation exhibited obvious seasonal dependence, with the strongest multifractal intensity in summer (cross-multifractal Δα reaching up to 0.81) and the weakest in winter under the modulation of photochemical and meteorological conditions. These findings reveal that port-side pollution coupling is structurally more fragile and heterogeneous than the stable regional background, suggesting that effective air quality management requires strategies accounting for these cross-scale nonlinear dynamics. Full article

Alcoholic liver injury (ALI) represents a global public health crisis with limited therapeutic options. Polysaccharides from edible mushrooms have emerged as promising candidates for liver protection due to their multifaceted biological activities and low toxicity. A mouse model of ALI was established to investigate the protective effect of Agaricus subrufescens polysaccharide on liver injury. The polysaccharide exhibited a non-triple-helix structural, characterized by a rough surface morphology, crack-like features, and a wavy strip structure. The body growth, liver index, serum and liver biochemical parameters, hepatic histopathological characteristics, and hepatic mRNA levels were investigated. The results demonstrated that A. subrufescens polysaccharide significantly alleviated liver injury, decreased serum levels of ALT by 36.22% and AST by 31.65%, lowered hepatic MDA content by 33.19%, and increased the activities of antioxidant enzymes, including SOD, GSH-P_X, and Cat by 12.04%, 9.76% and 18.45%, respectively. Meanwhile, the polysaccharide also regulated the mRNA expression of key genes involved in fatty acid metabolism, oxidative stress, and inflammatory responses. These findings provide theoretical evidence for the efficacy of A. subrufescens polysaccharide against alcohol-induced liver injury. Full article