Search Results (307)

This study evaluated the effects of dietary supplementation with dried Haematococcus pluvialis biomass on egg quality in laying hens using a multilevel analytical approach. A total of 100 ISA Brown hens were divided into two groups: a control group (CTRL) fed a basal diet and an experimental group (HP) receiving the same diet supplemented with 0.075% H. pluvialis. Supplementation did not significantly affect most physical egg parameters, although yolk index and yolk height were improved in the HP group. A marked increase in yolk pigmentation was observed, with values reaching 15 on the DSM color fan compared to 8.4 in CTRL (p < 0.0001). Significant enhancements in yolk nutritional quality were detected, including increased total carotenoids and the presence of astaxanthin exclusively in the HP group. Mineral composition was also markedly affected, with significant increases in essential elements such as Fe, Mg, Zn, I, and P in both albumen and yolk. The fatty acid profile was favorably modulated, showing a reduction in saturated fatty acids and an increase in monounsaturated fatty acids, along with improved nutritional indices (AI, TI, HH). Instrumental sensory analysis revealed clear discrimination between groups based on color (E-eye), while differences in volatile profiles (E-nose) were less pronounced. However, a reduction in oviposition rate and egg mass was observed in the supplemented group. Overall, the inclusion of H. pluvialis biomass represents an effective strategy for the natural biofortification of eggs, improving their nutritional and functional value. Full article

Identifying superior salt-tolerant germplasm and resistance genes is crucial, as wheat (Triticum aestivum L.) seedlings are highly vulnerable to salt stress. Here, using an optimized 150 mM NaCl treatment, we screened 137 Chinese wheat accessions via an organ-specific method. Phenotyping analysis revealed extensive organ-specific divergence, with 48.91% of accessions displaying inconsistent performance between shoot and root length. We then performed comparative transcriptomics on three representative phenotypes at the seedling stage: Gaoyou 2018, representing the salt dual-sensitive group; Huapei 5, representing the salt dual-tolerant group; and Jimai 60, representing the divergent group with higher tolerance in shoots rather than in roots. Analysis of overlapping differentially expressed genes (DEGs) across all three accessions revealed a basal stress response—characterized by induced osmotic defense and suppressed primary growth—exemplifying a classical growth–defense trade-off. Genotype-specific DEG profiling demonstrated that the divergent Jimai 60 maintains its shoot advantage by reinforcing physical barriers and inhibiting apoptosis. Conversely, transcriptomic profiling implies that the systemically tolerant Huapei 5 maintains coordinated shoot and root tolerance at the seedling stage by strongly activating below-ground Na⁺ homeostasis (efflux and compartmentalization) while simultaneously down-regulating non-essential immune responses to optimize defense energy reallocation. Collectively, our findings provide novel insights into the organ-differentiated salt tolerance of wheat, offering well-characterized elite germplasm and compelling genetic targets for future molecular breeding. Full article

Viola odorata, commonly known as sweet violet, is valued for both its fragrance and medicinal properties. However, seeds of V. odorata exhibit non-deep physiological dormancy, resulting in poor and inconsistent germination. This dormancy can be overcome through physical or chemical treatments, including scarification, stratification, and hormone application. Although mechanical scarification is effective, many commonly used approaches have notable limitations, such as reliance on corrosive chemicals and a lack of uniformity. This study presents a simple and effective mechanical scarification technique using rat-tooth tweezers to gently crack the seed coat tip of V. odorata ‘Empress Augusta’ (EA). This method significantly improved germination. When combined with cold stratification at 4 °C, germination further increased, reaching 70% within 8 weeks. Germination was enhanced even further on Murashige and Skoog (MS) basal salt medium supplemented with 10 mg/L gibberellic acid (GA₃), achieving 97.5% germination by day 54. These findings suggest that this simple mechanical scarification method, when combined with cold stratification and GA₃ treatment, could provide a reliable and practical strategy for breaking dormancy and facilitating seed germination in V. odorata. Full article

Background/Objectives: Regular physical exercise is strongly recommended for individuals with type 1 diabetes mellitus (T1DM) because of its beneficial effects on cardiovascular fitness, insulin sensitivity, metabolic control, and overall health. Nevertheless, participation in physical activity remains limited, largely due to the fear of exercise-induced hypoglycemia and glycemic instability. Glycemic responses to exercise in T1DM are influenced by the interaction between exercise modality, circulating insulin levels, nutritional status, and diabetes technologies. Continuous aerobic exercise, resistance training, high-intensity interval exercise, and mixed intermittent activities elicit distinct metabolic and hormonal responses, resulting in heterogeneous glycemic trajectories. This narrative review aimed to provide a clinically oriented synthesis of the physiological mechanisms underlying exercise-related glycemic fluctuations in T1DM and to discuss integrated insulin- and carbohydrate-based strategies to support safer participation in physical activity in the context of modern diabetes technologies. Methods: A structured narrative review was conducted using PubMed/MEDLINE, Scopus, and complementary searches in Google Scholar to identify experimental studies, observational studies, systematic reviews, consensus statements, and clinical guidelines focused on exercise-related glycemic responses in individuals with T1DM. Only articles published in English were considered. Evidence was selected and synthesized according to relevance to exercise modality, insulin therapy strategies, carbohydrate management, and diabetes technologies, including continuous glucose monitoring, continuous subcutaneous insulin infusion, and automated insulin delivery systems. The final narrative synthesis was based on 44 selected studies, reviews, consensus statements, and guidance documents considered most relevant to the objectives of this narrative review. Results: Available evidence indicates that continuous moderate-intensity aerobic exercise is most consistently associated with progressive glucose declines and increased risk of hypoglycemia, particularly when performed in the presence of elevated insulin on board. In contrast, resistance exercise and short-duration high-intensity or anaerobic exercise more frequently induce stable glycemia or transient hyperglycemia through adrenergic stimulation and increased hepatic glucose output. Mixed and intermittent exercise modalities often produce more variable responses depending on exercise sequencing, nutritional status, and insulin exposure. Across studies, integrated adjustment of basal and prandial insulin doses together with individualized carbohydrate supplementation emerged as the most effective strategy to reduce exercise-related glycemic instability. Continuous glucose monitoring and insulin pump technologies improved glucose trend awareness and management flexibility; however, physical exercise remains a challenging condition for current automated insulin delivery algorithms and still requires active user-driven decision-making. Conclusions: Exercise management in T1DM should be based on an individualized interpretation of exercise modality, glucose trends, insulin exposure, and nutritional context rather than on fixed glucose thresholds alone. Combining anticipatory insulin adjustments, tailored carbohydrate strategies, and appropriate use of diabetes technologies may substantially reduce glycemic variability and improve confidence toward physical activity participation. Structured education and individualized clinical guidance remain essential to translate physiological knowledge into effective real-world exercise management. Full article

Background: Chronic obstructive pulmonary disease (COPD) is associated with systemic alterations in body composition, including muscle mass loss and fat redistribution, which may influence patient-reported outcomes. However, the independent contribution of bioimpedance-derived parameters, particularly phase angle, to quality of life (QoL) remains unclear. Methods: This exploratory pilot study included 75 clinically stable patients with moderate-to-severe COPD (GOLD stages II–III). Body composition was assessed using segmental multi-frequency bioelectrical impedance analysis with the InBody 770 system. Evaluated parameters included fat-free mass (FFM), skeletal muscle mass (SMM), percent body fat (PBF), visceral fat area (VFA), extracellular water-to-total body water ratio (ECW/TBW), bone mineral content (BMC), and phase angle (PhA). Quality of life was assessed using the WHOQOL-BREF questionnaire. Associations between body composition parameters and QoL domains were analyzed using Spearman correlation analysis and multivariable linear regression models. Results: Despite a median body mass index (BMI) within the normal range (23.4 kg/m²), body fat mass exceeded reference values in both men and women. Fat-free mass and skeletal muscle mass were located near the lower range of expected values. Correlation analysis demonstrated predominantly weak associations between body composition parameters and QoL domains. Significant positive correlations were identified between the psychological QoL domain and fat-free mass (ρ = 0.238, p = 0.041), skeletal muscle mass (ρ = 0.240, p = 0.040), basal metabolic rate (ρ = 0.236, p = 0.043), and bone mineral content (ρ = 0.249, p = 0.033). In multivariable regression models, fat-free mass and skeletal muscle mass demonstrated consistent positive associations with both physical and psychological QoL domains. Whole-body and segmental phase angle parameters did not demonstrate significant associations with QoL outcomes. Conclusions: In patients with COPD, BMI alone may inadequately reflect underlying alterations in body composition. Muscle-related parameters, particularly fat-free mass and skeletal muscle mass, demonstrated more consistent associations with physical and psychological aspects of quality of life than obesity-related indicators. These findings suggest that bioelectrical impedance analysis may provide additional clinically relevant information beyond BMI when assessing body composition and quality of life in patients with COPD. Full article

In terrestrial environments, nest site selection by birds and mammals is often related to the physical attributes of surrounding vegetation. Similarly, some elasmobranchs use different habitats, including kelps, as oviposition sites. However, habitat features that drive oviposition site selection remain poorly understood. We examined the relationship between kelp morphology (holdfast diameter, number of stripes, and total length) and kelp forest configuration (density, size structure, predator density) with egg presence to identify the factors influencing oviposition choice in the redspotted catshark (Schroederichthys chilensis). We conducted surveys over a latitudinal gradient (19° S to 39° S), encompassing much of the overlap between the kelp, Lessonia trabeculata and S. chilensis in Chile. Eggs were exclusively attached between the upper stipe and basal fronds of Lessonia trabeculata in all sites. At the individual scale, S. chilensis selected larger kelps within a patch, independent of the general population size structure. The number of eggs and clutches was positively associated with stipe length and holdfast diameter. Across all sites, egg-bearing kelps were consistently clustered at a similar depth in the kelp forest rather than being randomly distributed. At the site scale, egg number had a negative correlation with their main predator abundance, Taliepus dentatus, and juvenile kelp density. These results suggest that S. chilensis shows low plasticity in substrate use, as evidenced by non-random, consistent oviposition in kelp morphology along a latitudinal gradient. Our results underscore the need to incorporate kelp size thresholds and the protection of egg-bearing aggregations into harvesting regulations, as overexploitation of L. trabeculata directly threatens the reproductive viability of S. chilensis. Full article

Stand-level canopy base height (Cbh) is a key variable controlling crown fire initiation, yet it is commonly computed as the mean of tree height to the base of the crown (hbc), which does not reflect the lower portion of the hbc distribution governing the transition from surface to crown fire. This study investigates the relationship between physically based Cbh definitions and the hbc distribution. We develop a general multi-percentile modeling framework to estimate hbc percentiles at the stand level. Using a dataset of Pinus pinaster Aiton trials in Portugal, percentile-specific models (5th to 50th) were fitted and synthesized into a nonlinear multi-percentile formulation. Results show that the height at which canopy bulk density exceeds the critical threshold does not match mean hbc, but instead corresponds to lower percentiles, typically around the 10th percentile, varying with stand structure and age. Mean-based Cbh tends to overestimate the lower canopy boundary, reflecting its inability to capture structural variability. The final model predicts hbc at any percentile and incorporates effects of stand height, basal area, tree density, and age, ensuring positive predictions and high predictive accuracy (adjusted R² = 0.9770; RSE = 0.4073 m; PRESS R² = 0.9769). The framework provides a consistent representation of canopy base height for fire behavior modelling. Full article

Physics-based simulation of debris flows over complex terrain is essential for hazard assessment, but repeated numerical integration is costly when many scenarios must be explored. We develop a general deep-learning surrogate modelling framework for two-dimensional (2D) debris-flow propagation, here applied to the Morino–Rendinara area (central Italy) using a three-dimensional (3D) Fourier Neural Operator (FNO) trained on synthetic simulations generated by a validated in-house finite-volume shallow-water solver. The solver reproduces debris-flow propagation over complex terrain and is specifically developed for artificial intelligence (AI) applications. It is based on a depth-averaged 2D formulation using the Harten–Lax–van Leer–Contact (HLLC) approximate Riemann solver, hydrostatic reconstruction, positivity-preserving wet–dry treatment, and Voellmy-type basal friction, and was verified through analytical benchmarks, numerical tests, and back-analyses of real events. The dataset was built from four site-specific release settings derived from real topography, combining different released volumes and bulk densities while preserving local geomorphological and rheological characteristics. Each simulation was stored as a full spatio-temporal tensor and used to train an FNO conditioned on coordinates, topography, friction parameters, bulk density, and initial release thickness. Training used a novel loss to emphasize active-flow areas and improve velocity reconstruction, and was performed using a graphics processing unit (GPU). The surrogate shows effective generalization to within-distribution validation samples, with global relative mean squared errors of 5.49% for flow thickness, 5.34% for velocity component u, and 2.60% for v, and mean $R^2$ values of 0.95, 0.94, and 0.97. For a representative sample, the surrogate predicts the full spatio-temporal solution in $0.52$ s, versus about 47 s for the first-order finite-volume solver, corresponding to a speed-up of about $91\times$, with an even larger gap expected for higher-order solvers, since, whilst the computation time of the solver increases as its complexity increases, the computation time of the FNO remains essentially unchanged. These results indicate that the proposed FNO is a reliable site-specific surrogate for rapid approximation of 2D debris-flow dynamics over real terrain, with potential for uncertainty propagation, Monte Carlo analysis, large-ensemble simulation, and hazard-oriented scenario assessment. Full article

Mitochondrial dysfunction is a hallmark of aging and age-related physical decline in people living with HIV (PLWH) who experience accelerated aging. This pilot study investigated the relationships between platelet mitochondrial function, physical performance, and body composition in older, sedentary PLWH compared with older, sedentary HIV-negative controls. Platelets have the potential to act as minimally invasive and easily accessible biomarkers for systemic mitochondrial bioenergetics and may serve as a practical biomarker in aging-related research. We analyzed correlations between mitochondrial parameters, protein levels, and measures of physical performance and body composition in a cohort of predominantly African American men (n = 7 PLWH, n = 7 controls). Body composition was assessed using dual-energy X-ray absorptiometry (DXA), and exercise capacity through VO₂ peak and strength tests. Platelet mitochondrial bioenergetic parameters were measured by oxygen consumption rates (OCR) and extracellular acidification rates (ECAR). Key mitochondrial proteins SIRT3, COXII, DRP1, and OPA1 were evaluated by Western blotting. The PLWH and HIV-negative control groups were similar in age and cardiorespiratory fitness. In PLWH, basal OCR and ATP-linked respiration showed strong positive correlations with VO₂ peak (r = 0.874, p < 0.05 and r = 0.862, p < 0.05, respectively) and negative correlations with BMI (r = −0.856, p < 0.05 and r = −0.849, p < 0.05, respectively). SIRT3 emerged as a potential key player, demonstrating strong positive correlations with basal OCR (r = 0.804, p < 0.05), ATP-linked respiration (r = 0.787, p < 0.05), and VO₂ peak (r = 0.970, p < 0.001), and negative correlations with BMI (r = −0.830, p < 0.05) and fat mass (r = −0.827, p < 0.05) in PLWH. Analyses focused on within-group associations in PLWH because bioenergetic measures were obtained using different Seahorse platforms in PLWH and controls, precluding valid direct quantitative comparisons between groups. Our findings provide evidence for significant associations between platelet mitochondrial bioenergetics, specific mitochondrial proteins (particularly SIRT3), and key physical attributes in older, sedentary PLWH. These preliminary findings suggest that platelets may serve as minimally invasive biomarkers of systemic mitochondrial health, contribute to our understanding of mitochondrial function in HIV-associated accelerated aging, and inform future interventions to enhance mitochondrial function and improve health outcomes in this vulnerable population. However, results should be interpreted cautiously given the small sample size and exploratory design and should be considered hypothesis-generating rather than definitive. Larger, demographically more diverse studies that include HIV-negative controls are needed to validate these associations and determine their clinical relevance. Full article

Glucose transporter type 4 (GLUT4), encoded by the SLC2A4 gene, is the final effector of insulin-stimulated glucose uptake in insulin-sensitive tissues: skeletal muscle, adipose tissue, and cardiac muscle. Its dynamic localization, retained intracellularly under basal conditions and extensively translocated to the plasma membrane upon stimulation, makes it a master regulator of glycemic homeostasis. While the canonical insulin pathway (PI3K/Akt/TBC1D4) is the most potent and specific mechanism in the postprandial state, its dysfunction is centrally associated with insulin resistance and type 2 diabetes mellitus (T2DM). Crucially, robust alternative signaling networks function completely independently of insulin to regulate GLUT4 synthesis and translocation. Prominent among these are contraction-mediated pathways in skeletal muscle, which employ calcium signaling (via CaMKII), mechanical/metabolic stress sensors (via p38 MAPK γ/δ), and AMP-activated protein kinase (AMPK). This review critically integrates current knowledge, linking the molecular architecture and post-translational modifications of GLUT4 to the complex, tissue-specific signaling networks that govern its vesicular trafficking. We emphasize the hierarchy, redundancy, and interdependence of these pathways, highlighting differences between acute translocation and chronic transcriptional adaptations. Finally, we discuss how deciphering insulin-independent mechanisms offers promising therapeutic opportunities, particularly in identifying pharmacological targets that mimic the metabolic benefits of physical exercise. Full article

The fall armyworm (Spodoptera frugiperda) is a major global migratory pest. Its increasing insecticide resistance poses a severe threat to food security. Developing biopesticides such as SfMNPV is critical for sustainable control. Nevertheless, the early molecular mechanisms underlying the S. frugiperda midgut response to oral SfMNPV challenge remain poorly understood. This study utilized high-throughput transcriptome sequencing to systematically characterize the dynamic transcriptional profiles of the larval midgut at 1, 12, and 24 h after oral SfMNPV inoculation. Results showed that the midgut transcriptional response to SfMNPV is time and stage-specific. During this period, the physical midgut barrier underwent remodeling, with core components of the peritrophic matrix downregulated at 1 h, followed by the basal lamina at 12 h, alongside the activation of cytoskeleton genes during 12–24 h. Concurrently, sustained endoplasmic reticulum stress, autophagy, and ubiquitin system responses occurred from 12 to 24 h. At the metabolic level, the defense system exhibited a functional succession, shifting from ABC transporters and UDP-glycosyltransferases at 1 h to glutathione S-transferases and superoxide dismutase at 12–24 h. Additionally, the midgut tissue exhibited a cascade transition from pro-apoptotic signaling at 1 h to compensatory regenerative repair mediated by the Wnt, mTOR, and Hippo pathways at 12–24 h. This study elucidates the molecular process of barrier damage, homeostatic imbalance, and tissue remodeling during early oral SfMNPV challenge. These findings provide a global perspective on baculovirus-host interactions and establish a theoretical foundation for designing novel biopesticides targeting the midgut interaction. Full article

Soil physicochemical and biochemical properties are fundamental to soil processes and ecosystem functioning in forest environments, yet their responses to dominant tree species in humid montane regions remain largely ununderstood. This study examined the effects of three widespread broadleaf species—Quercus pontica, Quercus petraea, and Fagus orientalis—on soil physical, chemical, and biochemical properties in natural forests in the Eastern Black Sea region, where these species play key ecological roles in structuring forest composition and biogeochemical processes. A total of 15 soil samples (5 per forest type) were collected under comparable climatic and geological conditions and analyzed for particle-size distribution, pH, electrical conductivity (EC), soil organic carbon, and key microbial activity indicators. Significant differences in soil properties were detected among forest types. Soils under Q. pontica were characterized by the lowest silt content and pH, but the highest sand content, soil organic carbon, microbial biomass carbon (C_mic), and microbial respiration. In contrast, soils under Q. petraea exhibited the highest clay content and pH, whereas F. orientalis soils showed lower sand content, EC, soil organic carbon, microbial biomass nitrogen (N_mic), and basal respiration. Multivariate analyses revealed that soil texture, pH, and C_mic are key factors driving soil differentiation across forest types. These patterns indicate that species-specific litter inputs and belowground processes regulate soil biochemical functioning by altering resource availability and habitat conditions. Crucially, this study sheds light on the soil-forming responses of these ecologically dominant species and their impacts on carbon cycle pathways and microbial dynamics at the regional scale. Overall, the study shows that tree species identity is a critical factor influencing soil function, with significant consequences for forest management, carbon sequestration strategies, and ecosystem resilience to changing environmental conditions. Full article

Background and Objectives: Burnout syndrome is a major challenge among healthcare workers, affecting both mental and physical health. Although stress may influence physiological systems, this study does not directly assess biological mechanisms, and interpretations should remain associative. Stress-related associations may be reflected in body composition, but objective data are limited. This study aims to assess the associations between burnout, body composition, and quality of life in medical staff, using bioimpedance as the main tool. Material and methods: The cross-sectional study included 95 medical staff (36 resident doctors, 13 specialists/consultants, 31 nurses, 15 nursing assistants), 75.8% women, mean age 38 ± 10 years, conducted in the medical and surgical departments of Dr. C.I. Parhon Clinical Hospital, Iași, between January and March 2024. Burnout was assessed using the Maslach Burnout Inventory; quality of life was evaluated with SF-12; body composition was measured by bioimpedance (BMI, muscle mass, fat mass, bone mass, hydration, basal metabolism, metabolic age). Statistical analyses included ANOVA, Kruskal–Wallis, and Spearman correlations. Results: Resident physicians had higher muscle, bone mass and basal metabolism, with lower adipose tissue compared to other categories (p < 0.05). Total burnout and exhaustion were positively correlated with muscle mass (r = 0.247, p = 0.016), bone mass (r = 0.219, p = 0.033), basal metabolism (r = 0.219, p = 0.033) and negatively with QoLM (r = −0.315, p = 0.002). Other body variables, including BMI, total adipose tissue, and water level, showed no significant correlations. These associations may be influenced by age, sex, and professional category and do not imply causality. Conclusions: Age, profession, and work seniority are associated with burnout and specific changes in body composition. However, these findings are correlational, and bioimpedance-derived parameters do not reflect direct biological stress mechanisms. Full article

Background/Objectives: Obesity has a huge impact on global healthcare and economy. Consequently, the pharmaceutical industry has recently introduced novel anti-obesity drugs such as semaglutide and tirzepatide, which can yield remarkable weight reduction in patients, while also having significant cardiovascular benefits. Methods: Other weight-lowering medications are currently under investigation, and this narrative review provides an overview of the main novel drugs that are being tested. Results: These novel agents have different mechanisms of action, e.g., calorie intake reduction, increase in basal metabolism, and increase in muscle mass. Conclusions: In the future, obesity treatment is likely to become increasingly personalized, and further cardiovascular benefits could be expected. The combined use of different molecules could minimize their side effects, for instance, by minimizing muscle wasting observed during glucagon-like peptide 1 receptor agonists (GLP1-RAs) therapy. In our opinion, these highly effective drugs could represent a valuable addition to healthy lifestyle, as the evidence linking increases in muscle mass and basal metabolic rate to improved cardiovascular health is strongest when these changes are achieved through diet and regular physical activity. Full article

Future contributions to sea level rise from the Antarctic Ice Sheet due to climate change remain one of the largest uncertainties for future sea level. Improving predictions of ice mass loss is a major goal of numerical ice sheet models, but a major difficulty is that ice sheet models assume an empirical fit to modern-day observed speeds to infer sliding parameters. While this results in accurate modern-day comparisons, predictions for future or past climates that have substantially different conditions will be inaccurate if the empirical sliding law used is not appropriate. To help constrain which basal physics is most appropriate and therefore which basal parameterizations should be used in ice sheet models, here, we pursue an understanding of which physical mechanisms are most likely to explain the spatial variability in flowline speeds throughout the Antarctic Ice Sheet. Specifically, we compare observed flowline surface speeds with predictions of speeds from internal ice deformation and Weertman sliding using a conservative range of physical parameters. Despite large uncertainties, we find a number of flowlines where the predictions can be distinguished from each other and one can infer that one of the two mechanisms, or a third mechanism, Coulomb frictional failure, may likely be principally responsible. Geographic patterns in the dominant mechanism are observed. Weertman sliding appears dominant in several flowline clusters in East Antarctica, and there are regional consistencies in the estimated nearness to flotation at locations of inferred initiation of Coulomb failure. Weertman sliding at faster rates is also observed within regions of inferred Coulomb failure, consistent with theoretical expectations. The key finding that the dominant deformation mechanism varies along and between Antarctic flowlines may complicate how ice sheet models need to be parameterized if accurate predictions of future ice loss and sea level rise are to be accurate. Full article