Search Results (1,847)

Background/Objectives: Telomeres are critical biomarkers of biological aging, with shortened leukocyte telomere length strongly linked to all-cause mortality and age-related disease risk. Although exercise modulates telomere dynamics, the field’s evolution from descriptive measurements to mechanistic inquiries involving redox biology and epigenetics remains incompletely mapped. This study systematically characterized the global research landscape of telomere–exercise science over 25 years to establish a strategic evidence base for precision exercise prescription. Methods: A bibliometric analysis was conducted on 858 publications from the Web of Science Core Collection (2000–2025). CiteSpace and VOSviewer were used for keyword co-occurrence analysis, strategic thematic mapping, and citation burst detection to visualize global research trends and identify emerging frontiers. Results: Annual publication volume grew from 2 (2000) to 71 (2025), with a compound annual growth rate of 15.4%. China emerged as one of the leading global contributors. Thematic analysis revealed a paradigm shift from descriptive leukocyte telomere length studies toward mechanistic investigations of oxidative stress, mitochondrial homeostasis, and epigenetic clocks. Keyword network analysis confirmed oxidative stress and inflammation as central hubs, mediating telomere protection via redox regulation and non-canonical telomerase functions. Conclusions: Exercise preserves telomere integrity primarily through redox–mitochondrial homeostasis, hormesis-driven antioxidant upregulation, and non-canonical telomerase activation. For aging populations and individuals at metabolic risk, aerobic training and high-intensity interval training (HIIT) are recommended as first-line non-pharmacological interventions for healthspan extension. Leukocyte telomere length and telomerase activity should be integrated as biomarkers in preventive medicine practice. Future large-scale randomized controlled trials incorporating multi-omics approaches and sex-stratified analyses are warranted to establish individualized dose–response guidelines for precision exercise prescription. Full article

Background/Objectives: Diabetic cardiomyopathy (DCM) is largely driven by severe oxidative stress and calcium dyshomeostasis. We examined the targeted antioxidant and therapeutic effects of zinc sulfate (ZnSO₄) on contractile dynamics, oxidative damage, calcium turnover, and apoptosis/fibrosis in aged female rats with type 2 diabetes. Methods: Thirty-two aged female Wistar rats were divided into Control, Control + ZnSO₄, Diabetes (DM), and DM + ZnSO₄ groups. DM was induced via high-fat diet and 30 mg/kg streptozotocin. After a 4-week complication period, treatment groups received 10 mg/kg/day ZnSO₄ (i.p.) for 6 weeks. Left ventricular papillary muscle contraction, oxidative/antioxidant markers (MDA/GSH), and gene expressions (SIRT1, GLUT4, SERCA2a, RyR2, Cav1.2, PLN) were evaluated. Myocardial architecture, fibrosis, and apoptosis were analyzed immunohistochemically. In DM rats, contractile force (CF) and velocities (±dF/dtmax) significantly declined. Results: Concurrently, SIRT1, GLUT4, SERCA2a, RyR2, Cav1.2, and antioxidant GSH decreased, while oxidative lipid damage (MDA), PLN, Caspase-3 activity, Collagen I, and fibrosis increased (p < 0.001). ZnSO₄ treatment in diabetic rats acted as a potent antioxidant modulator; it restored redox balance, activated the SIRT1/GLUT4 pathway, protected calcium-handling proteins from oxidative degradation, and significantly improved contractile dynamics. It also preserved myocardial architecture by reducing apoptosis and fibrosis. In healthy rats, ZnSO₄ caused mild stress and early fibrosis. Conclusions: In conclusion, while inducing mild stress in healthy myocardium, zinc supplementation provides robust antioxidant protection in diabetic hearts. It activates SIRT1, suppresses oxidative damage, maintains calcium homeostasis, and restores contractile dynamics, demonstrating strong antioxidant therapeutic potential against DCM. Full article

Insulin (Ins) regulates multiple intracellular signalling pathways involved in cell survival, oxidative stress responses, and tau phosphorylation. Dysregulation of these pathways has been implicated in neurodegenerative disorders, including Alzheimer’s disease (AD). The present study evaluated the effects of insulin on protein kinase B/glycogen synthase kinase-3 beta (AKT/GSK-3β) signalling, tau phosphorylation, and oxidative stress-related markers in SH-SY5Y neuroblastoma cells. Cell metabolic activity was assessed using the (diphenyltetrazolium bromide) MTT assay, while cell number and viability were evaluated by Trypan Blue exclusion, necrosis by lactate dehydrogenase (LDH) release, and apoptosis by Caspase-3 activity. Western blot analysis was performed to evaluate the expression of phosphorylated AKT (p-AKT), phosphorylated GSK-3β (p-GSK-3β Ser9), phosphorylated TAU (pTAU), nuclear factor erythroid 2-related factor 2 (NRF2), manganese superoxide dismutase (Mn-SOD), and copper/zinc superoxide dismutase (Cu/Zn-SOD). Lipid peroxidation was determined by measuring malondialdehyde (MDA) levels using a colorimetric/fluorometric assay. Insulin treatment increased MTT reduction (31.25%) and cell metabolic activity (119.15%) while reducing LDH release (19.2%) and Caspase-3 activity (31.26%). In addition, insulin significantly increased p-AKT (34.2%) and p-GSK-3β (Ser9) (19.9%) levels. A reduction in pTAU levels (53.39%) was also observed following insulin treatment. Furthermore, insulin increased NRF2 expression (18.77%), Cu/Zn-SOD (37.29%), and Mn-SOD (50.16%) and reduced MDA levels (13.95%). These findings indicate that insulin modulates signalling pathways associated with tau phosphorylation and cellular redox regulation in SH-SY5Y cells. Insulin treatment was associated with increased AKT and GSK-3β phosphorylation, reduced tau phosphorylation, and changes in oxidative stress-related markers in SH-SY5Y neuroblastoma cells. These findings support a role for insulin in the modulation of molecular pathways implicated in cellular stress responses and tau regulation. Further studies using differentiated neuronal models and disease-relevant conditions are required to determine the relevance of these observations to neurodegenerative disorders. Full article

Coordinated responses of intestinal epithelial and immune cells are essential for maintaining barrier integrity and immune homeostasis in dogs, yet our mechanistic understanding of probiotic-derived metabolites remains limited due to reliance on non-canine experimental models, highlighting the need for studies in canine-derived systems. Here, we investigated the effects of metabolites derived from Limosilactobacillus reuteri strain ATCC PTA6127 (Lr6127), delivered as a cell-free supernatant (CFS), on canine epithelial MCA-B1 cells and macrophage-like DH82 cells subjected to lipopolysaccharide (LPS)-induced inflammatory stress. Lr6127 CFS significantly reduced epithelial permeability, decreasing FITC–dextran leakage to 94.9 ± 1.9% (normalized relative to LPS-treated control, which was set as 100%) (p < 0.001), despite no detectable transcriptional changes in tight junction, adherens junction, or mucin genes. Barrier effects were instead associated with changes in markers of cellular stress responses, with heme oxygenase expression decreasing from 0.9 ± 0.1 to 0.7 ± 0.1 (p < 0.05). In DH82 immune cells, Lr6127-derived metabolites altered LPS-induced stress- and inflammation-related gene expression patterns; enhanced anti-apoptotic responses, as reflected by the increased BCL2 expression (1.4 ± 0.1 vs. 1.0 ± 0.0; p < 0.01) and elevated BCL2/BAX ratios (p < 0.01); and reduced expression of pro-inflammatory mediators including IL-6 and CCL2 (p < 0.05–0.001). Proteomic analysis corroborated that Lr6127-derived metabolites reduced the abundance of inflammatory and STAT-associated signaling proteins under LPS challenge, while indicating context-dependent changes in immune-related protein profiles under resting condition. Collectively, these results suggest that Lr6127-derived metabolites improved epithelial barrier function, which was accompanied by coordinated changes in cellular stress-related and inflammatory pathways, highlighting their potential to positively influence host responses. Full article

Impaired wound healing arises from interacting biological and material challenges, including persistent infection, biofilm formation, oxidative stress, unresolved inflammation, impaired angiogenesis, defective epithelialization, hemorrhage, and insufficient real-time assessment of wound status. Quantum dot (QD) and nanodot nanosystems have emerged as a versatile class of bioactive wound interfaces capable of addressing these barriers through functions that extend beyond passive coverage. This review synthesizes the design rationale, material composition, validation strategies, functional outcomes, mechanistic interpretation, and translational relevance of QD-enabled platforms for precision wound repair. Across the reviewed literature, carbon dots, graphene QDs, black phosphorus QDs, metal and metal oxide QDs, transition-metal nanodots, and hybrid nanocomposites were incorporated into hydrogels, films, sponges, nanofibers, microneedles, scaffolds, membranes, sprays, and injectable matrices. Their major precision-enabling attributes include localized antimicrobial and antibiofilm activity, redox-adaptive behavior, photothermal and photodynamic activation, inflammatory and macrophage modulation, hemostasis, controlled therapeutic delivery, angiogenic and epithelial support, and fluorescence-based monitoring. The strongest conceptual advance is the transition from static wound dressings toward adaptive biointerfaces that can sense, respond to, or compensate for local wound state abnormalities. Nevertheless, the field remains largely preclinical, with important gaps in long-term safety, standardized characterization, clinically predictive models, manufacturing reproducibility, regulatory alignment, and human validation. Future progress will depend on rationally simplified multifunctional platforms, rigorous comparative testing, wound state-specific evaluation frameworks, and translation-oriented safety and usability studies. QD nanosystems therefore represent a promising foundation for precision wound repair, provided that their multifunctionality is matched by equally rigorous evidence of safety, reproducibility, and clinical relevance. Full article

Cutaneous squamous cell carcinoma (cSCC) is one of the most common non-melanoma skin cancers worldwide. Although surgery and adjuvant therapies are often effective, the treatment of high-risk or advanced lesions remains challenging due to recurrence, resistance, toxicity, and limited long-term control. Natural compounds have, therefore, gained interest as multi-target agents for cancer prevention and treatment. This systematic review aimed to evaluate the antitumoral activity of natural compounds against cSCC. A systematic literature search was conducted following PRISMA 2020 guidelines. Sixty studies met the inclusion criteria and were analyzed using a conservative, mechanism-based classification framework. The included studies evaluated purified compounds, crude extracts, essential oils, formulations, photodynamic agents, and combination treatments. Despite chemical diversity, antitumoral activity converged on defined biological processes, including apoptosis, non-apoptotic regulated cell death, redox modulation, oncogenic signaling inhibition, cell-cycle arrest, epigenetic regulation, photodynamic ROS generation, and chemopreventive or immune-mediated mechanisms. Mechanistic specificity was higher among purified compounds, while complex extracts showed broader, context-dependent effects. Several agents demonstrated consistent in vitro and in vivo activity, which supports their translational relevance. Natural compounds target shared biological vulnerabilities in cSCC through mechanistically convergent pathways. The framework presented here supports mechanism-guided prioritization and may facilitate the translation of promising compounds into clinically relevant strategies. Full article

Ischemic stroke triggers a severe redox disequilibrium that critically shapes cell survival within the penumbra. Although oxidative DNA damage arises from excessive ROS production, the capacity to repair such lesions is tightly constrained by cellular metabolic status. Growing evidence indicates that astrocytes, key metabolic regulators of the neurovascular unit, modulate neuronal susceptibility to genomic injury through redox buffering, NAD⁺ maintenance, and metabolic support. In the metabolically impaired yet structurally preserved penumbra, astrocytic control of glutathione turnover, mitochondrial function, and lactate shuttling may determine whether oxidative DNA lesions are efficiently repaired or progress toward energetic collapse. Poly(ADP-ribose) polymerase 1 activation following DNA strand breaks couples genomic stress to NAD⁺ depletion and bioenergetic failure, forming a critical interface between redox biology and metabolism. This framework posits that astrocytes preserve genomic integrity not by directly altering DNA repair pathways but by sustaining the energetic capacity required for an effective DNA damage response. Elucidating this astrocyte-centered redox–metabolic axis may reveal therapeutic strategies to stabilize penumbral tissue and improve stroke outcomes. Full article

Atherosclerosis is a progressive vascular disease characterized by lipid-rich plaque accumulation, oxidative stress, and chronic inflammation, contributing to coronary heart disease, stroke, and peripheral arterial disease. This study investigated the impact of inflammation, vascular calcification, and statin therapy on redox balance in blood and carotid artery plaques, aiming to identify potential biomarkers for disease assessment. Thirty-two patients undergoing carotid endarterectomy provided 34 plaque samples. Enzyme activities in plaque/erythrocytes and –SH group concentration in plasma/plaque were measured. Pathological analysis was performed to determine inflammation/calcification grade, the presence of mast cells and plaque composition. The results showed that mast cells were associated with reduced non-protein –SH groups, indicating selective thiol consumption and serving as a qualitative marker of oxidative burden. Reduced catalase activity in erythrocytes was associated with advanced calcification, pointing to long-standing systemic oxidative stress. Statin therapy enhanced systemic superoxide-dismutase 1 activity, increased –SH groups, and modulated plaque-specific glutathione reductase activity, attenuating sex-related differences in redox regulation. These findings highlight the complex interplay between systemic and local oxidative processes in atherosclerosis through alterations in redox-related biomarkers such as plasma –SH group concentrations and catalase activity. Full article

Carbon monoxide (CO) is a gasotransmitter generated by heme oxygenase (HO) isoforms during heme catabolism. The inducible HO-1 produces CO under conditions of redox imbalance, such as oxidative stress and inflammation. On the other hand, HO-2 constitutively generates CO, primarily during the physiological turnover of heme. Extensive evidence indicates that CO exerts autocrine effects by targeting hemoproteins, including soluble guanylyl cyclase, cyclooxygenase, and cytochromes. Furthermore, CO regulates many biological processes within the brain, including mitochondrial biogenesis, potassium channel activity, mitogen-activated protein kinase and phosphatidylinositol-3-kinase/Akt signaling. It also controls the activity of transcription factors, such as hypoxia-inducible factor-1 and peroxisome proliferator-activated receptor-γ. Through these mechanisms, CO modulates inflammatory gene expression, promotes anti-apoptotic signaling, and contributes to local stress responses. Conversely, CO produced in the hypothalamus inhibits the stress-induced release of corticotropin-releasing hormone and arginine vasopressin under pro-inflammatory conditions, resulting in reduced adrenocorticotropin hormone release and cortisol secretion from the anterior pituitary and adrenal cortex, respectively. Moreover, hypothalamic CO acts in a paracrine manner to modulate glucocorticoid release during psychological stress, including restraint or water deprivation. Together, these findings support the view that endogenous CO is a key modulator of the stress axis, exerting pleiotropic effects that integrate neuroendocrine, immune, and metabolic responses. Full article

Postoperative inflammation is a necessary response to surgical injury that supports tissue repair and regeneration. However, successful healing depends not only on the initial inflammatory response but also on its timely resolution. Failure to resolve inflammation can impair wound healing, promote fibrosis, and increase the risk of postoperative complications. Increasing evidence suggests that effective recovery is driven by the transition from inflammation to repair and regenerative processes. Diet plays an important role in this transition, as nutrients not only provide metabolic support but also regulate key pathways involved in inflammation, tissue regeneration, redox balance, and immune function. Omega-3 polyunsaturated fatty acids could serve as precursors for specialized pro-resolving mediators that actively terminate inflammation and may promote macrophage-driven tissue repair. Polyphenols and antioxidant micronutrients modulate NF-κB and Nrf2-dependent signalling, attenuating oxidative amplification of inflammatory cascades. Micronutrients and amino acids further regulate enzymatic processes governing collagen synthesis, angiogenesis, and immune competence. Concurrently, diet-driven preservation of gut barrier integrity limits endotoxin-mediated amplification of systemic inflammatory responses. By targeting interconnected molecular networks, including inflammasome activation, mitochondrial redox signalling, and metabolic programming of immune cells, anti-inflammatory dietary patterns may promote immune resolution rather than immunosuppression. This distinction is particularly relevant in the postoperative setting, where balanced inflammation is required for both host defence and regenerative healing. This review synthesizes current molecular and translational evidence linking dietary modulation to postoperative inflammatory control and tissue regeneration. By integrating insights from immunology, metabolism, and nutritional science, it positions diet as an active, biologically grounded component of perioperative management and highlights future directions for precision nutrition strategies aimed at optimizing surgical recovery. Full article

The efficient conversion of methane into hydrogen-rich syngas is essential for sustainable energy; however, integrating methane partial oxidation (POM) with the water–gas shift (WGS) reaction remains a significant challenge due to thermal and kinetic mismatches. This research presents a spatially decoupled dual-bed reactor configuration, utilizing Ni/GDC and Cu/GDC catalysts, to achieve synergistic hydrogen production. Unlike conventional physically mixed systems, which suffer from thermal hotspots and the unintended promotion of the endothermic Reverse Water–Gas Shift (RWGS) reaction, the dual-bed architecture effectively segregates the reaction zones. Advanced characterization, including O₂-TPO and Raman spectroscopy, reveals that the GDC support acts as a critical oxygen buffer via the Mars-van Krevelen mechanism, modulating the dynamic redox state of the active metal sites to prevent deep oxidation and carbonaceous deactivation. Furthermore, macroscopic performance and carbon–oxygen mass balance analyses confirm that this rational architectural design facilitates a seamless integration of POM and WGS pathways, resulting in significantly maximized H₂ yield. From a broader engineering perspective, this dual-bed strategy offers a practical, low-complexity alternative to intensive integrated technologies such as sorption-enhanced reforming (SER) or chemical looping, providing a robust and scalable framework for durable, high-efficiency hydrogen production. Full article

L-carnitine plays a central role in mitochondrial fatty acid transport and cellular energy regulation; effects on the biochemical phenotype of brain cancer cells remain insufficiently characterized. Here, we applied confocal Raman spectroscopy and imaging to investigate the biochemical alterations induced by L-carnitine supplementation—administered as its tartrate salt—in human astrocytoma cells. Raman spectral analysis revealed distinct changes in lipid-, protein-, nucleic acid-, and cytochrome-associated vibrational features following 24 h of treatment, suggesting alterations in mitochondrial activity and cellular energy-related processes. Principal component analysis identified PC1 (93.87%) as representing the intrinsic biochemical composition of the cells, whereas PC2 (1.19%) and PC3 (0.59%) captured subtle yet consistent variations in lipid organization, protein conformation, and redox-sensitive vibrational features associated with L-carnitine exposure. Pearson correlation analysis of Raman cluster spectra indicated biochemical differences across cellular compartments, with the most pronounced changes observed in lipid droplets, supporting modifications in lipid-associated cellular processes. These findings demonstrate that Raman imaging provides a sensitive, label-free platform for resolving L-carnitine-induced biochemical heterogeneity at the single-cell level. Overall, this study highlights vibrational spectroscopy as a powerful tool for characterizing cellular responses to metabolic modulators and provides insight into the biochemical impact of exogenous L-carnitine in brain cancer cells. Full article

Strigolactones (SLs) have emerged as important regulators of plant adaptation to abiotic stress, functioning not as isolated hormones but as integrative signaling molecules. Beyond stress responses, SLs regulate key biological processes, including shoot branching, root architecture, leaf senescence, nutrient acquisition, rhizosphere communication, flowering-related development, and growth–developmental plasticity. This review synthesizes current knowledge on how SLs modulate plant responses to drought, salinity, heavy metal toxicity, high temperature, and low temperature through crosstalk with abscisic acid, auxin, cytokinin, ethylene, and gibberellin. We examine SL structural diversity, biosynthesis, transport, and signaling together with their roles in growth–stress coordination, hormonal networking, and stress-specific mitigation, while distinguishing endogenous SL functions from responses inferred from exogenous analogs such as GR24. Across stresses, SL-mediated resilience converges on adaptive modules, including water regulation, root–shoot architectural remodeling, redox protection, ion and osmotic homeostasis, photosynthetic maintenance, and rhizosphere-assisted resource acquisition. The mechanistic basis involves transcriptional reprogramming, ROS/RNS-linked redox regulation, metabolic protection, and root–microbe interactions. Translational prospects include SL analogs, genetic manipulation, and breeding for adaptive plasticity, nutrient efficiency, and stress tolerance. However, species specificity, dosage dependence, limited field validation, unclear structure–function relationships, and parasitic-weed stimulation remain major constraints. Full article

The present investigation evaluated the therapeutic potential of ethanol-derived extracts from Kadsura coccinea root (KCR) against alcohol-induced liver injury (ALI) utilizing a murine experimental system. Male Balb/c mice were administered alcohol intragastrically in a stepwise manner over 8 weeks to establish the ALI model. Experimental outcomes demonstrated that KCR administration substantially improved hepatic functional status, evidenced by marked reductions in circulating hepatic enzymes, specifically aspartate aminotransferase (AST) and alanine aminotransferase (ALT). KCR also increased glutathione (GSH) activity, reduced malondialdehyde (MDA) levels in the liver, and exerted antioxidant effects by boosting the expression of enzymes such as superoxide dismutase (SOD), catalase (CAT), and glutathione peroxidase 4 (GPX4). Additionally, metabolomic and transcriptomic analyses identified metabolites and pathways closely linked to oxidative stress, including Glutathione metabolism and the MAPK signaling pathway. Further mechanistic studies revealed that KCR could decrease the phosphorylation of p38, JNK, and ERK, while increasing the expression of Nrf2, HO-1, and NQO1. In conclusion, KCR alleviates ALI by modulating the MAPK/Nrf2 pathway, restoring redox homeostasis, enhancing antioxidant defenses, and improving metabolic disorders. Full article

Mitochondrial electron transport chain (ETC) dysfunction is a major driver of bioenergetic failure, redox imbalance, and drug toxicity, yet strategies to restore oxidative phosphorylation under ETC blockade remain limited. Redox-active small molecules could, in principle, shuttle electrons from NADH to distal ETC components and oxygen, thereby modulating both respiration and reactive oxygen species (ROS) formation. Here, we show that the enzyme-independent redox cycler phenazine methosulfate (PMS) rewires mitochondrial redox circuits and restores respiration in human glioblastoma cells and cell-free systems under ETC inhibition. At subtoxic concentrations, PMS acutely increased oxygen consumption and mitochondrial superoxide generation via NADH–PMS–O₂ redox cycling, while restoring mitochondrial membrane potential and ATP synthesis under ETC blockade, and shifting metabolism away from glycolytic lactate production. This profile is consistent with a protective redox-bypass role, distinct from the pro-apoptotic effects reported following high-dose, prolonged PMS exposure. The PMS-driven restoration of electron flow, mitochondrial membrane potential, and respiratory ATP synthesis under inhibition of Complex I (rotenone), III (antimycin A and myxothiazol), and/or IV (cyanide) is consistent with direct cytochrome c reduction, as demonstrated herein, and engagement of multiple ETC redox centers, including coenzyme Q₁₀. In metformin-treated cells, PMS reversed suppression of respiration and lactate accumulation, outperforming existing redox-bypass strategies. These findings identify PMS-driven redox cycling as a previously unrecognized chemical redox-bypass mechanism that both regenerates mitochondrial bioenergetics and reshapes ROS production, suggesting a potential approach to counteract drug- and toxin-induced mitochondrial dysfunction and to exploit redox vulnerabilities in cancer. Full article