Search Results (3,860)

The pervasive contamination of microplastics and nanoplastics (MNPs) in livestock and poultry production systems represent a critical threat to animal health, productivity, and food safety. This review systematically evaluates the potential of curcumin, a natural polyphenol from Curcuma longa, to mitigate MNP-induced toxicity, drawing on evidence from 25 preclinical studies (2014–September 2025). We highlight that curcumin exerts broad-spectrum, dose-dependent protection primarily through a dual mechanism: the preventive activation of the Nrf2/ARE antioxidant pathway and the therapeutic suppression of NF-κB-driven inflammation. These actions collectively ameliorate oxidative stress, restore metabolic homeostasis (e.g., via the gut–liver axis), and reverse histopathological damage across key organs, including the liver, kidneys, and reproductive tissues. A major translational insight is the significant species-specific variation in curcumin bioavailability, which is substantially higher in poultry than in ruminants, necessitating the development of tailored delivery systems such as nanoencapsulation. While the preclinical data are compelling, translating these findings into practice requires robust clinical trials to establish standardized, safe, and effective dosing regimens for food-producing animals. This review concludes that curcumin presents a promising, sustainable phytogenic strategy to enhance the resilience of livestock and poultry systems against MNP pollution, directly contributing to the One Health goals of safeguarding animal welfare, food security, and environmental sustainability. Full article

Central lipid metabolism disorders are crucial for the development of Alzheimer’s disease (AD). Phlorizin (PHZ) improved lipid metabolism abnormalities in AD nematodes, but its mechanism of action in improving AD-related symptoms and whether it can alleviate AD cognitive impairment remain unclear. To elucidate the effects and mechanisms of PHZ on lipid metabolism disorders in an AD model, gavage administration of PHZ for 8 weeks improved cognitive dysfunction and lipid disorders in APPswe/PSEN1dE9 (APP/PS1) mice. Concurrently, in astrocytes induced by palmitic acid (PA)- mediated lipid metabolic disorder, PHZ treatment improved astrocytic lipid accumulation by upregulating the target peroxisome proliferator-activated receptor α (PPARα) and its downstream pathways, thereby promoting astrocytic fatty acid oxidation. We validated PHZ’s strong in vitro binding affinity with PPARα. Co-culture systems of lipid-metabolically disordered astrocytes and neurons further demonstrated that PHZ significantly improved neuronal cell viability and reduced intracellular lipid accumulation, thereby decreasing the expression of enzymes associated with β-amyloid protein (Aβ) production. This study demonstrates that gavage administration of PHZ for 2 months improves cognitive deficits and pathological markers in AD mice. Furthermore, at the cellular level, PHZ may exert its effects by enhancing astrocytic lipid metabolism, thereby preventing neuronal lipotoxicity and mitigating AD progression. Full article

Heavy metal (HM) contamination in agricultural soils poses a significant threat to soil health and plant productivity. This study investigates the impact of cadmium (Cd) and zinc (Zn) stress on tomato plants (Solanum lycopersicum) and explores the mitigation potential of microbial biostimulants (MBs), including arbuscular mycorrhizal fungi (AMF) and Pseudomonas fluorescens So_08 (PGPR), over a 52-day period using multi-omics approaches. Root exudate profiling revealed distinct metabolic changes under HM stress, which compromised soil–plant interactions. Cd stress reduced the secretion of phenylpropanoids (sum LogFC: −45.18), lipids (sum LogFC: −27.67), and isoprenoids (sum LogFC: −11−67), key metabolites in antioxidative defense, while also suppressing rhizosphere fungal populations. Conversely, Zn stress enhanced lipid exudation (such as sphingolipids and sterols, as sum LogFC of 8.72 and 9.99, respectively) to maintain membrane integrity and reshaped rhizobacterial communities. The MBs application mitigated HM-induced stress by enhancing specialized metabolite syntheses, including cinnamic acids, terpenoids, and flavonoids, which promoted crop resilience. MBs also reshaped microbial diversity, fostering beneficial species like Portibacter spp., Alkalitalea saponilacus under Cd stress, and stimulating rhizobacteria like Aggregatilinea spp. under Zn stress. Specifically, under Cd stress, bacterial diversity remained relatively stable, suggesting their resilience to Cd. However, fungal communities exhibited greater sensitivity, with a decline in diversity in Cd-treated soils and partial recovery when MBs were applied. Conversely, Zn stress caused decline in bacterial α-diversity, while fungal diversity was maintained, indicating that Zn acts as an ecological filter that suppresses sensitive bacterial taxa and favors Zn-tolerant fungal species. Multi-omics data integration combined with network analysis highlighted key features associated with improved nutrient availability and reduced HM toxicity under MB treatments, including metabolites and microbial taxa linked to sulfur cycling, nitrogen metabolism, and iron reduction pathways. These findings demonstrate that MBs can modulate plant metabolic responses and restore rhizosphere microbial communities under Cd and Zn stress, with PGPR showing broader metabolomic recovery effects and AMF influencing specific metabolite pathways. This study provides new insights into plant–microbe interactions in HM-contaminated environments, supporting the potential application of biostimulants for sustainable soil remediation and plant health improvement. Full article

The system analysis method is suitable for detecting the optimal pathways for regional sustainable (e.g., green, low carbon) socioeconomic development. This study develops an inexact fractional energy–output–water–carbon nexus system planning model to minimize total carbon emission intensity (CEI, total carbon emissions/total economic output) under a set of nexus constraints. Superior to related research, the model (i) proposes a CEI considering both sectoral intermediate use (indirect) and final use (direct); (ii) quantifies the dependencies among energy, output, water, and carbon; (iii) restricts water utilization for carbon emission mitigation; (iv) adopts diverse mitigation measures to achieve carbon neutrality; (v) handles correlative chance-constraints and crisp credibility-constraints. A case in Fujian province (in China) is conducted to verify its feasibility. Results disclose that the total CEI would fluctuate between 45.05 g/CNY and 47.67 g/CNY under uncertainties. The annual total energy and total output would, on average, increase by 0.58% and 2.82%, respectively. Eight mitigation measures would be adopted to reduce the final carbon emission into the air to 0 by 2060. Compared with 2025, using water for carbon emission mitigation would increase 17-fold by 2060. For inland regions, authorities should incorporate other unconventional water sources. In addition, the coefficients of embodied energy consumption and water utilization are the most critical parameters. Full article

Chamazulene (CHA) is a brilliant blue compound present in Artemisia sieversiana Ehrhart ex Willd. essential oil (AEO). We have previously reported that both CHA and AEO can shield the skin from UVB damage, exhibiting significant anti-photoaging effects. However, the molecular mechanisms underlying CHA’s photoprotective properties are still unclear. Herein, we integrated transcriptomics, targeted fatty acid profile, and untargeted metabolomics analyses on the dorsal skin of mice exposed to UVB with or without 0.4% CHA topical treatment. The results showed that CHA upregulated key genes involved in fatty acid metabolism, including two peroxisome proliferator-activated receptor (PPAR) subtypes, i.e., PPARα and PPARγ, in mouse skin. The CHA treatment elevated levels of various saturated, monounsaturated, and polyunsaturated fatty acids, and it especially restored n-3/n-6 polyunsaturated fatty acid homeostasis and downregulated the p38 MAPK/COX-2 pathway. Additionally, CHA enhanced skin non-essential amino acid metabolism, likely via PPARα. In conclusion, our study indicates that CHA may mitigate UVB-induced photoaging by inducing metabolic reprogramming and suppressing inflammation, and the findings suggest that the activation of PPARα/γ may play a vital role in these observed effects, thereby establishing CHA as a promising topical agent against UVB-induced photoaging. Full article

Clear cell renal cell carcinoma (ccRCC), accounting for 80–90% of renal malignancies, is frequently driven by VHL inactivation—either through mutation or promoter hypermethylation—resulting in constitutive HIF2$\alpha$ activation and pseudohypoxic signaling. VHL gene inactivation is a hallmark of von Hippel–Lindau syndrome, a hereditary disorder predisposing patients to ccRCC and other tumors, underscoring its central role in disease pathogenesis. While VHL dysfunction promotes aggressive tumor phenotypes, the therapeutic potential of VHL restoration remains underexplored. Here, using the Cas9 induced VHL-mutation in the Caki-1 cell line model, we demonstrate that VHL inactivation augments hypoxia-like pathways and enhances anaerobic glycolysis. Rescue of functional VHL reversed these activation patterns and modulated the expression of genes associated with angiogenesis. Using single cell transcriptomics, we show that the VHL-positive and -negative Caki-1 cells are characterized with different proportions of benign and aggressive cells as seen by analysis of specific gene expression. Furthermore, the identified angiogenesis-related genes were linked to affect clinical outcomes in ccRCC patients, suggesting that VHL restoration may mitigate high-risk molecular features. Full article

There is growing interest in utilising urban parks as nature-based solutions to mitigate the effects of climate change and rising temperatures by improving thermal comfort. Nonetheless, understanding remains limited on how different park configurations influence summer thermal comfort, particularly under future warming scenarios. This novel study evaluates park configurations across different neighbourhood layouts within Perth’s Mediterranean climate under both present and future conditions. Study precincts were modelled and simulated using ENVI-met version 5.5 for an average current summer day, based on 25 years of local weather data and climate projections for 2090 under the Representative Concentration Pathway 8.5 scenario, representing the worst-case scenario. Results showed that park surfaces were consistently cooler than surrounding streets based on LST; however, this did not always translate into improved thermal comfort, as exposed grass areas often exhibited high Physiological Equivalent Temperature (PET) values. PET has been confirmed as the most suitable outdoor human thermal comfort index. Canopy cover and vegetation type, particularly tall trees and bushland, were more influential than park size or configuration in enhancing thermal comfort. These findings provide evidence-based insights, highlighting the importance of strategies that prioritise tree canopy coverage to enhance urban cooling and resilience to climate change. Full article

Diabetic retinopathy (DR), a major complication of diabetes, is driven by chronic inflammation in which retinal microglial cells play a central role. The Hippo pathway kinases NDR1/2 regulate macrophage function, but their role in microglia and DR remain unknown. This study investigates the function of the NDR2 kinase in microglial cells under high-glucose (HG) conditions. Using CRISPR-Cas9, we partially knocked out the Ndr2/Stk38l gene in BV-2 mouse microglial cells and analyzed metabolic activity, phagocytosis, migration, and cytokine release. We confirmed NDR2 expression in microglia and observed increased levels under HG, suggesting a role in hyperglycemia-induced stress. Ndr2/Stk38l (hereafter referred to as Ndr2) downregulation impaired mitochondrial respiration and reduced metabolic flexibility, indicating defective stress adaptation. Functionally, microglia with a partial downregulation of Ndr2 displayed reduced phagocytic and migratory capacity—both dependent on cytoskeletal dynamics. Moreover, Ndr2 downregulation altered the secretory profile, elevating pro-inflammatory cytokines (IL-6, TNF, IL-17, IL-12p70) even under normal glucose levels. These findings identify NDR2 protein kinase as a key regulator of microglial metabolism and inflammatory behavior under diabetic conditions. By modulating immune and metabolic responses, NDR2 may contribute to the neuroinflammatory processes underlying DR. Targeting NDR2 function in microglia may offer novel therapeutic strategies to mitigate retinal inflammation and progression of DR. Full article

Background/Objectives. Preterm birth (PTB), affecting approximately 11.1% of pregnancies globally, often results from inflammation at the maternal–fetal interface triggered by microbial or immune dysregulation. This study investigates the efficacy of cell-free supernatant derived from Bifidobacterium longum subsp. infantis CECT 7210 and Lacticaseibacillus paracasei CECT 30660 in mitigating inflammation-induced PTB in a murine model. Methods. Lipopolysaccharide (LPS) was administered to induce preterm labor and systemic inflammation, mimicking infection-related PTB. Results. The results demonstrated that combined administration of CECT 7210 and CECT 30660 cell-free supernatants reduced preterm deliveries from 85.6% to 42.8% in mice and significantly attenuated systemic and intrauterine proinflammatory cytokines, including TNF-α and IL-6, in maternal plasma and myometrial tissues. Importantly, this anti-inflammatory effect was independent of maternal progesterone or oxytocin levels, suggesting a direct modulation of immune responses in this animal model. The cell-free supernatant combination also inhibited the growth of pathogenic bacteria, including Streptococcus agalactiae, highlighting its antimicrobial potential. Conclusions. This study underscores the potential of CECT 7210 and CECT 30660 cell-free supernatants as a therapeutic strategy to reduce the risk of PTB by targeting inflammation pathways. The findings pave the way for further preclinical and clinical research to validate the efficacy of these cell-free supernatants in preventing PTB and associated complications, offering a promising alternative to traditional probiotic approaches. Full article

Polystyrene microplastics (PS-MPs) are microplastic particles produced during plastic manufacturing and environmental degradation, accumulating over time and entering ecosystems through various pathways, ultimately affecting organisms and inducing toxic effects. Current research on the impact of PS-MPs on mammalian oocyte quality, along with potential preventive mechanisms and strategies to mitigate toxicity, remains limited. This study investigates the effects of antioxidant melatonin on oocyte quality in the presence of PS-MPs, focusing on their influence on oocyte meiotic maturation and embryonic developmental potential. PS-MPs at a concentration of 30 μg/mL significantly impaired first polar body extrusion and reduced the success rate of parthenogenetic activation of mature oocytes in vitro. Furthermore, exposure to PS-MPs exacerbated oxidative stress, mitochondrial dysfunction, apoptosis, and autophagy impairment. Additionally, PS-MPs exposure led to a reduction in antioxidant gene expression and an increase in apoptosis-related gene expression in porcine oocytes. Immunofluorescence assays revealed that PS-MPs may induce oxidative stress, mitochondrial damage, and inflammation through the NF-KB/Nrf2/JNK MAPK signaling pathway crosstalk. Further investigation demonstrated that melatonin supplementation alleviated the toxic effects of PS-MPs exposure, offering potential as a therapeutic approach for mitigating PS-MP-induced reproductive toxicity and preserving oocyte quality. Full article

The uptake and accumulation of nanoplastics by plants have emerged as a major research focus. Exogenous selenium nanoparticles (SeNPs) are widely used to mitigate the toxicity of abiotic stresses, such as nanoplastics (NPs) and polyethylene (PE—NPs) nanoplastics, and represent a feasible strategy to enhance plant performance. However, the molecular mechanisms by which SeNPs alleviate the phytotoxicity of microplastics and nanoplastics remain poorly defined. To address this gap, we used Pistia stratiotes L. (P. stratiotes) as a model and silicon dioxide nanoparticles (SiO₂NPs) as a comparator, integrating physiological assays, ultrastructural observations, and proteomic analyses. We found that NP stress caused ultrastructural damage in root tips, exacerbated oxidative stress, and intensified membrane lipid peroxidation. SeNPs treatment significantly mitigated NP-induced oxidative injury and metabolic suppression. Compared to the NPs group, SeNPs increased T-AOC by 38.2% while reducing MDA and ·OH by 33.3% and 89.6%, respectively. Antioxidant enzymes were also elevated, with CAT and POD rising by 47.1% and 39.2%. SeNPs further enhanced the photosynthetic capacity and osmotic adjustment, reflected by increases in chlorophyll a, chlorophyll b, and soluble sugar by 49.7%, 43.8%, and 27.0%, respectively. In contrast, proline decreased by 17.4%, indicating stress alleviation rather than an osmotic compensation response. Overall, SeNPs outperformed SiO₂NPs. These results indicate that SeNPs broadly strengthen anti-oxidative defenses and metabolic regulation in P. stratiotes, effectively alleviating NP-induced oxidative damage. Proteomics further showed that SeNPs specifically activated the MAPK signaling cascade, phenylpropanoid biosynthesis, and energy metabolic pathways, enhancing cell-wall lignification to improve the mechanical barrier and limiting NPs translocation via a phytochelatin-mediated vacuolar sequestration mechanism. SiO₂NPs produced similar but weaker alleviative effects. Collectively, these findings elucidate the molecular basis by which SeNPs mitigate NPs’ phytotoxicity and provide a theoretical foundation and practical outlook for using nanomaterials to enhance phytoremediation in aquatic systems. Full article

ESG washing, as an organizational decoupling behavior, refers to enterprises strategically disclosing environmental information to obscure their actual ESG performance, which not only elevates audit risks but also increases uncertainty in audit pricing. Based on a sample of Chinese listed companies from 2014 to 2023, this study introduces excess executive compensation and executive myopia as mediators to investigate the mechanisms through which ESG washing influences abnormal audit fees via chain mediating effects. Additionally, market structure is considered a moderating variable to examine its moderating role within the model. The empirical results demonstrate that ESG washing in listed companies significantly increases abnormal audit fees. Both excess executive compensation and executive myopia exert positive individual mediating effects as well as a chain mediating effect. Furthermore, the moderating effect of market structure attenuates the mediating role of excess executive compensation but amplifies that of executive myopia. This research proposes an integrated framework combining organizational decoupling theory and transaction cost theory, thereby clarifying the underlying pathways through which ESG washing influences abnormal audit fees. The study offers policy implications for government authorities to strengthen ESG regulations, enhance supervisory mechanisms, and promote a more sustainable business environment. In addition, it provides guidance for enterprises in mitigating ESG washing, optimizing audit-related costs, and enhancing their capacity to address ESG challenges, improve corporate governance, and strengthen competitiveness. Full article

Sports-associated traumatic brain injury is emerging as an under-recognized driver of acute and chronic cardiovascular diseases. Larger population-based studies show that individuals with moderate-to-severe traumatic brain injury experience up to a two-fold excess risk of incident hypertension, coronary artery disease, myocardial infarction, and stroke that persists for at least a decade. Among former professional American-style football players, a higher lifetime concussion burden is uniquely related to a more atherogenic cardiometabolic profile and greater long-term stroke risk. Mechanistically, an acute “sympathetic storm” triggered by cerebral injury provokes catecholamine surges, endothelial dysfunction, and myocardial stunning, manifesting as neurogenic stunned myocardium or Takotsubo-like cardiomyopathy and malignant arrhythmias. Sub-acute to chronic phases are characterized by persistent autonomic imbalance, reflected by reduced heart-rate variability and impaired baroreflex sensitivity weeks to months after concussion, coupled with neuroinflammation, hypothalamic–pituitary–adrenal axis dysregulation, and lifestyle changes that accelerate atherosclerosis. The interplay of these pathways accounts for the elevated burden of cardiovascular disease observed long after neurological function has been restored. Despite robust evidence linking TBI to adverse cardiac outcomes, contemporary sports–cardiology risk stratification prioritizes hemodynamic load, genetics, and performance-enhancing substances, largely overlooking brain injury history. This review integrates epidemiological, clinical, and mechanistic data to (i) delineate acute neurocardiac complications secondary of sports-related traumatic brain injury, (ii) synthesize evidence for chronic cardiovascular risk, (iii) highlight emerging autonomic and inflammatory biomarkers, and (iv) propose surveillance and therapeutic strategies, ranging from heart-rate-variability-guided return-to-play decisions to aggressive cardiometabolic risk modification aiming to mitigate long-term morbidity in this athletic population. By framing sports-related traumatic brain injury as a modifiable cardiovascular risk factor, we aim to foster interdisciplinary collaboration among neurologists, cardiologists, and sports medicine practitioners, ultimately improving both neurological and cardiovascular outcomes across the athlete’s lifespan. Full article

Anthropogenic methane (CH₄) emissions lead to global warming and air pollution. China has recently crafted a bottom-up approach to regulate its anthropogenic CH₄ emissions; however, emissions during and after the COVID-19 lockdown have not been fully investigated using this updated method. In this study, we calculate provincial-level anthropogenic CH₄ emissions in 2022 using this official bottom-up approach, explore feasible mitigation pathways, estimate reduction potentials, evaluate the economic cost of abatement, and assess the social benefits of reductions. The results show that China’s total anthropogenic CH₄ emissions in 2022 were estimated to be 52.6 (49.8–55.6) Tg, approximately 47.6%, 39.5%, and 12.9% of which were from agricultural activities, energy utilization, and waste management, respectively; forest burning contributed 0.35 Gg. Using currently available approaches, China’s total yearly anthropogenic CH₄ emissions can be reduced by around 33%, with an average reduction cost of USD 130.9 million per Tg of CH₄. The social cost of CH₄ was estimated to be USD 231.8 per metric ton, indicating that the negative impact of annual anthropogenic CH₄ emissions was equal to 0.07% of China’s GDP. Despite the consistency between top-down inversions and our bottom-up inventory, we argue that the official guideline may underestimate China’s soil CH₄ emissions due to changes in soil substrate availability, relative humidity, and the active layer of methanogens from global warming. Methods to improve current estimation accuracy are discussed. Owing to the slow international diffusion rate of methane-targeted abatement technologies, China needs to develop relevant technologies with independent intellectual property rights. Full article

Phosphogypsum (PG) and Carbide Slag (CS) are two industrial byproducts that can be used as cementitious materials, and their synergistic effect provides excellent activation of ground granulated blast furnace slag (GGBS), which is traditionally activated by lime (LM). However, the behavior of PG-GGBS-CS ternary blended cement remains largely unexplored. In this study, the mechanical performance, hydration mechanisms, and environmental profile of PG–GGBS–CS binders in comparison with PG–GGBS–LM were evaluated by unconfined compressive strength (UCS), XRD, SEM, and TGA analyses. The optimum formulation containing 30% PG achieved 24.88 ± 1.24 MPa at 28 d, statistically comparable to 25.6 ± 1.28 MPa for PG–GGBS–LM. The synergistic activation of PG and CS/LM on GGBS has been identified as a crucial factor in the strengthening of UCS in ternary blended cement. Hydration products consisted mainly of calcium silicate hydrate (C–S–H) gels and Ettringite (AFt). Importantly, the CO₂ footprint of PG–GGBS–CS was reduced by 3.2% compared to that of PG–GGBS–LM. These findings establish CS as an effective substitute for lime in eco-binders, combining technical efficiency with carbon mitigation and offering a viable pathway for large-scale valorization of hazardous industrial residues. Full article