Search Results (37,835)

Cardiovascular disease (CVD) remains a leading cause of morbidity and mortality worldwide, arising from complex interactions among metabolic, genetic, and environmental factors. Nicotinamide N-methyltransferase (NNMT) has recently emerged as a key metabolic regulator in CVD pathogenesis. By consuming nicotinamide and methyl groups, NNMT perturbs epigenetic, metabolic, and redox pathways that are critical for cardiovascular health. NNMT-mediated NAD⁺ depletion impairs mitochondrial function, sirtuin (SIRT) activity, redox balance, and energy metabolism, thereby creating a pro-atherogenic environment. NNMT and its product 1-methylnicotinamide (1-MNA) show a complex duality: they modulate SIRT activity—particularly SIRT1 and SIRT3—to influence gluconeogenesis, cholesterol synthesis, lipogenesis, and mitochondrial antioxidant defenses. NNMT upregulation also elevates homocysteine levels, activating pro-inflammatory and pro-oxidative cascades (e.g., TLR4–NF-κB and STAT3–IL-1β). Growing evidence links NNMT to major CVD risk factors, including hyperlipidemia, hypertension, diabetes mellitus, and obesity. Thus, NNMT has a multifaceted role in cardiovascular health: while its enzymatic activity is often pathogenic (via NAD⁺/SAM consumption and homocysteine production), its metabolite 1-MNA can exert protective effects (via NRF2 activation and anti-thrombotic mechanisms). This duality highlights the need to delineate the molecular processes that balance these opposing actions. Experimental studies using small-molecule NNMT inhibitors and RNA interference have shown promising cardiometabolic benefits in preclinical models, including improved insulin sensitivity, reduced atherosclerosis, and attenuated cardiac dysfunction. However, no clinical trials have yet targeted NNMT specifically in CVD. Future research should clarify the tissue-specific functions of NNMT and translate these insights into novel therapeutic strategies. Full article

Trochoidea caroni (Gastropoda, Geomitridae) is a land snail previously found only in Sicily and Capri (Naples), but it has recently been found in other regions of the Italian peninsula. In this study, we performed karyological and molecular analysis on T. caroni from different sites across this regional range. Karyological analysis was performed on specimens from Palermo (Sicily), Capri (Campania), and Terracina (Lazio) using standard staining and NOR-FISH methods; the latter method was also performed on samples of T. elegans from Rome (Lazio). All T. caroni specimens had 2n = 48 chromosomes, but the 8th and 17th pairs differed morphologically between specimens from Capri and Terracina and those from Sicily. The mitochondrial 16S rRNA analysis grouped Sicilian and non-Sicilian populations of T. caroni in distinct subclades. Superimposing karyological data on their phylogenetic tree suggests that possible chromosomal rearrangements occurred during the diversification of Trochoidea. Our findings provide karyological and molecular evidence for a diversification between Sicilian and non-Sicilian populations of T. caroni. Furthermore, NOR-FISH revealed hybridisation signals on the 16th chromosome pair in both T. caroni and T. elegans (tribe Trochoideini). Similar NOR localisation has also been identified in Cernuella virgata (tribe Cernuellini), suggesting that it was inherited from the common ancestor of Trochoideini and Cernuellini. Full article

Abalone is among the most highly prized seafoods, valued for its delicate flavor and texture. As abalone aquaculture continues to expand, addressing its environmental impacts has become increasingly important. Although aquaculture is recognized as a contributor to greenhouse gas (GHG) emissions, the specific mechanisms and pathways of GHG emissions—particularly in abalone farming—remain poorly understood. To clarify the patterns and drivers of GHG emissions in abalone (Haliotis discus) culture systems, this study was conducted in three aquaculture ponds located in Gongliao District, New Taipei City, Taiwan. We measured CO₂, CH₄, and N₂O fluxes along with key environmental parameters to assess variation across sampling locations, times, and seasons. The results showed that sampling time had no significant effect on GHG flux variations, whereas seasonal changes influenced all three gases, and sampling location significantly affected N₂O flux only. During the culture period, average fluxes were 2.19 ± 10.83 mmol m⁻² day⁻¹ for CO₂, 2.11 ± 2.81 µmol m⁻² day⁻¹ for CH₄, and 1.65 ± 2.73 µmol m⁻² day⁻¹ for N₂O, indicating that the abalone ponds served as net sources of these GHGs. When converted to CO₂-equivalents (CO₂-eq), the total average CO₂-eq flux from the ponds was 0.02 ± 0.09 mg CO₂-eq m⁻² day⁻¹, calculated using global warming potential (GWP₂₀ and GWP₁₀₀) metrics. This study provides the first comprehensive assessment of GHG emissions in abalone pond systems and offers valuable insights into their emission dynamics. The findings contribute to the scientific basis needed to improve aquaculture GHG inventories. Full article

The Sanqi–pine agroforestry (SPA) system is considered a sustainable agroforestry model. However, empirical studies that clearly elucidate the impact of Sanqi cultivation on soil fertility and the heavy metal content within the SPA system are still lacking. This study established monoculture Pinus armandii (MPA) and SPA systems to conduct a comparative analysis of dynamic changes in soil physicochemical properties and the heavy metal content of Sanqi and pine over one year (with semi-monthly sampling), followed by a comprehensive evaluation of soil fertility and heavy metal pollution. Following the land use conversion from MPA to SPA, there was a notable increase in soil moisture (SM), total nitrogen (TN), and nitrate nitrogen (NO₃⁻-N) levels within Sanqi soil. Conversely, total potassium (TK), ammonium nitrogen (NH₄⁺-N), plumbum (Pb), and chromium (Cr) levels experienced a significant reduction. In the case of pine soil, soil moisture (SM), pH levels, and ammonium nitrogen (NH₄⁺-N) content exhibited an increase. However, soil organic carbon (SOC), total phosphorus (TP), total potassium (TK), zinc (Zn), manganese (Mn), plumbum (Pb), and chromium (Cr) contents all significantly decreased. The Technique for Order Preference by Similarity to Ideal Solution (TOPSIS) demonstrated that Sanqi cultivation not only significantly enhanced soil fertility for Sanqi rather than pine but also reduced the heavy metal content in the soil of both Sanqi and pine within the SPA system. Furthermore, the Nemerow pollution index for both Sanqi and pine soils has decreased, transitioning the pollution status from relatively safe to safe. This suggests that the introduction of Sanqi promotes the sustainable development of the SPA system. Full article

Background: COVID-19 has limited pregnant and postpartum women’s access to mental health services, leading to the introduction of online interventions. Objectives: This study aims to compare the effectiveness of telepsychotherapy (i.e., psychotherapy provided through digital technology supporting real-time interactivity in the audio or audiovisual modality) with the one yielded by face-to-face interventions in treating perinatal depression and anxiety and to assess the therapist’s perceived alliance in both interventions. Methods: We collected anamnestic information and obstetrical risk factors for 61 women. We evaluated the effectiveness of face-to-face (N = 31) vs. telepsychotherapy (N = 30) interventions on depressive and anxiety symptoms at baseline (T0) and the end of treatment (T1) using the Edinburgh Postnatal Depression Scale (EPDS) and the State-Trait Anxiety Inventory (STAI-Y 1 and 2). We assessed the degree of alliance perceived by therapists with the Working Alliance Inventory (WAI-T). Results: Both groups showed significant decreases in depressive (EPDS face-to-face: T0 12.65 ± 5.81, T1 5.77 ± 4.63, p < 0.001; EPDS remote: T0 11.93 ± 5.24, T1 5.70 ± 4.46, p < 0.001; effect size: 0.002) and state anxiety (STAI-Y 1 face-to-face: T0 51.19 ± 13.73, T1 40.23 ± 12.86, p < 0.001; STAI-Y 1 remote: T0 51.10 ± 11.29, T1 38.00 ± 10.90, p < 0.001; effect size: 0.007//STAI-Y 2 face-to-face: T0 43.13 ± 12.11, T1 41.03 ± 13.06, p = 0.302; STAI-Y 2 remote: T0 44.20 ± 8.70, T1 39.30 ± 9.58, p = 0.003; effect size: <0.001) symptoms by the end of treatment. Women treated remotely also experienced a significant reduction in trait anxiety at T1 (p = 0.003). We found no significant differences in either symptomatology (EPDS; STAI-Y) between the two interventions at baseline or in the therapist-perceived alliance. Conclusions: Synchronous telepsychotherapy for perinatal depression and anxiety showed comparable treatment response to face-to-face interventions, with both modalities associated with significant symptom reduction and the establishment of a working alliance. These findings support the potential of telepsychotherapy as a valuable alternative when in-person services are not accessible, especially during emergency contexts. Full article

China is the world’s leading producer of apples. However, the current classification of apple maturity is predominantly reliant on manual expertise, a process that is both inefficient and costly. In this study, we utilize a diverse array of apples of varying ripeness levels as the research subjects. We propose a lightweight target detection model, termed BGWL-YOLO, which is based on YOLOv11n and incorporates the following specific improvements. To enhance the model’s ability for multi-scale feature fusion, a bidirectional weighted feature pyramid network (BiFPN) is introduced in the neck. In response to the problem of redundant computation in convolutional neural networks, a GhostConv is used to replace the standard convolution. The Wise-Inner-MPDIoU (WIMIoU) loss function is introduced to improve the localization accuracy of the model. Finally, the LAMP pruning algorithm is utilized to further compress the model size. The experimental results demonstrate that the BGWL-YOLO model attains a detection and recognition precision rate of 83.5%, a recall rate of 81.7%, and an average precision mean of 90.1% on the test set. A comparative analysis reveals that the number of parameters has been reduced by 65.3%, the computational demands have been decreased by 57.1%, the frames per second (FPS) have been boosted by 5.8% on the GPU and 32.8% on the CPU, and most notably, the model size has been reduced by 74.8%. This substantial reduction in size is highly advantageous for deployment on compact smart devices, thereby facilitating the advancement of smart agriculture. Full article

Background: Cancer has a high mortality rate and leaves physical and mental difficulties even after treatment. When it afflicts frail elderly people, it poses a greater burden to them and society. Regular exercise helps to restore the deteriorated health of cancer survivors. The purpose of this study was to compare the effects of a short-term, high-repetition, home-based “exercise snack” program with those of a traditional, continuous, moderate-intensity exercise format on key health outcomes in elderly cancer survivors, including quality of life, cardiorespiratory fitness, and metabolic flexibility. Methods: A short-duration, high-repetition exercise snack group (ESG, n = 17) and a traditional exercise group (TEG, n = 17) were compared after 12 weeks of training. The effects of exercise on quality of life, cardiorespiratory fitness, metabolic flexibility, and blood lipids were measured. Results: Quality-of-life vitality, social functioning, cardiorespiratory fitness VO₂ peak, and high-density lipoprotein cholesterol were improved more in ESG than in TEG (p < 0.05). Metabolic flexibility showed that fat utilization increased and carbohydrate utilization decreased post-training compared to pre-training at VO₂ peak 20 and 40% in both groups (p < 0.05). Conclusions: In both groups, cardiorespiratory fitness was shown along with physical and psychological improvements in quality of life, and the efficiency of metabolic flexibility was also improved. Therefore, short-term, frequent exercise may be an appropriate exercise alternative for elderly people with difficulties. Full article

Background/Objectives: Gestational diabetes mellitus (GDM) prevalence in Australia has increased from 5.6% (2010) to 19.3% (2022), coinciding with the introduction of mandatory folic acid (FA) food fortification and increased supplementation. Animal studies show that high FA intake in pregnancy impairs maternal glucose regulation, but the underlying mechanisms are unknown. We investigated whether fortification has altered maternal folate status to increase GDM risk, and whether key hormones that regulate maternal glucose homeostasis are affected following FA fortification. Methods: Serum folate, red cell folate (RCF), prolactin (PRL), human placental lactogen (hPL) and placental growth hormone (GH2) were measured in early pregnancy samples from women enrolled in prospective cohorts: SCOPE (N = 1164; pre-fortification) and STOP (N = 1300; post-fortification). Associations with GDM were assessed. Results: Compared to pre-fortification, women post-fortification had a higher GDM incidence (5.0% vs. 15.2%), serum folate (↑ 18%), RCF (↑ 259%), hPL (↑ 29%), and GH2 (↑ 13%) concentrations. RCF concentrations above the clinical reference range were found in 57.6% of women post-fortification. Causal mediation analysis suggests that higher RCF contributed to increased GDM risk. Women with RCF excess had 48% more GDM cases, and higher PRL (↑ 24.2%) and hPL (↑ 12.7%) levels compared to those within the reference range. Conclusions: Maternal folate excess is likely contributing to the rising prevalence of GDM in Australia. These findings highlight the need to evaluate excess FA/folate safety in pregnancy, particularly in countries with mandatory fortification. Placental hormones may represent a mechanistic link between excess folate and GDM, warranting further investigation. Full article

Organic fertilization management for vegetable transplant production is challenging to growers due to the slow and unpredictable release nature of organic fertilizers. Nutrients in organic fertilizers, particularly nitrogen (N), often fail to meet the demands of rapidly growing transplants in soilless substrate. This study aimed to develop fertilization guidelines for organic bell pepper (Capsicum annuum L.) transplants by evaluating the performance of one conventional fertilizer, two organic fertilizers (Drammatic, Pre-Empt), and one naturally derived fertilizer (Bio-Matrix) at a range of N rates in supporting transplant growth. Bell pepper transplants were grown in an indoor growing chamber for 28 days with weekly fertilizer application. We found that the initial nitrate-N concentration in the fertilizer solution was the sole predictor of shoot dry weight (R² = 0.62), confirming that N availability was the primary limiting factor for transplant growth. The conventional fertilizer produced the largest transplants (370.9 mg/plant in shoot dry weight) while Drammatic resulted in the lowest maximum shoot growth (196.6 mg/plant), likely due to its high salinity and the accumulation of ammonium in the substrate. Bell pepper transplants exhibited low nutrient uptake capability and resulted in low N recovery efficiency, especially with the two organic fertilizers, Drammatic and Pre-Empt (15.6% and 23.8%, respectively). Furthermore, we found no carryover effects of the fertilizer treatments during the transplant stage on bell pepper growth after being transplanted to the greenhouse for 18 days. The final shoot dry weight only correlated with transplant shoot dry weight at the time of transplanting (R² = 0.87) but not with fertilizer type (p = 0.2849). Overall, Pre-Empt emerged as the most effective fertilizer for organic bell pepper transplant production. It is cost-effective, has low electrical conductivity, and is associated with low ammonium accumulation in the substrate. Therefore, it can be applied at high N rates to meet the N demand of bell pepper transplants. Based on our growing conditions, we recommend 23.1 g/L substrate of Pre-Empt for organic bell pepper transplant production. Full article

Background: Radiation-induced salivary gland (SG) hypofunction is mediated via microvascular dysfunction and radical oxygen species. N-acetylcysteine amide (NACA) has shown antioxidant properties with low toxicity. We explored NACA’s potential as a radioprotector of SG function. Methods: Bovine aortic endothelial cells (BAECs) were treated with NACA before irradiation with a single 10 Gy dose. Apoptosis was assessed by bis-benzimide staining and quantified via fluorescence microscopy. In vivo, NACA was administered to mice prior to a single 15 Gy head and neck irradiation. Eight weeks post-irradiation, saliva production was measured using pilocarpine stimulation; lysozyme levels were analyzed by ELISA. SGs were collected for immunohistochemistry. Results: BAEC apoptosis was substantially lower in NACA-treated cells vs. radiation-only (10% vs. 23%). In vivo, mice lost significant weight and developed severe hair loss eight weeks post-irradiation—attenuated by NACA pretreatment. Saliva production was reduced by 72% post-radiation, with a corresponding drop in lysozyme. NACA increased salivary flow by 42% and prevented lysozyme reduction. Post-radiation decline in microvessel density was also prevented by NACA. Conclusions: These outcomes suggest NACA may serve as a radioprotector of SG function in patients undergoing radiotherapy for head and neck cancer. Full article

White clover (Trifolium repens L.) is known for its ability to fix nitrogen biologically, its high nutritional value, and its adaptability to livestock systems. However, excessive fertilization with synthetic nitrogen alters its symbiosis with Rhizobium and reduces the protein content of the forage. The objective of this study was to evaluate the interaction between nitrogen fertilization (0 and 60 kg N ha⁻¹), cutting time, and post-cutting evaluation on the morphology, yield, and nutritional composition of white clover. A completely randomized block experimental design with three factors, distributed in three blocks, was used. Within each block, three replicates of each treatment were assigned (six interactions), giving a total of 54 experimental units. The data were analyzed using a three-way analysis of variance and Tukey’s multiple comparison test. Exponential models and generalized additive models (GAMs) were applied to the morphology and yield data to identify the best fit. The treatment with 60 kg N ha⁻¹ and cutting at 30 days showed significant increases in plant height (47.42%), fresh weight (59.61%), dry weight (98.41%), and leaf width (27.55%) compared to the control. It also produced the highest protein content (28.44%) compared to the other treatments with fertilization, without negatively affecting digestibility. The GAMs best fit most morphological and yield parameters (except leaf height and width). All fertilized treatments had higher fresh and dry weight yields. In conclusion, applying 60 kg N ha⁻¹ after cutting at 30 days, followed by harvesting between 54 and 60 days, improved both the quality and yield of white clover, which favored sustainable pasture management and reduced excessive nitrogen use. Full article

The H9N2 virus has severely harmed the livestock and bird farming industry. Currently, it is mainly prevented through vaccination immunization. However, conventional vaccines often fail to induce durable immune responses and long-lasting immunoprotection. In this research, we used Simvastatin (Sim) and CpG as adjuvants for the H9N2 inactivated vaccine to evaluate the vaccine’s immunogenicity in chickens. We evaluate vaccine immunogenicity through antibody testing, T lymphocyte phenotyping, and RNA-sequencing analysis. The results indicated that the Sim + CpG/H9N2 formulation significantly enhanced specific IgY and hemagglutination inhibition (HI) antibody titers. It also increased the proportions of CD4⁺ T cells and CD8⁺ T cells, promoted immune organ development, and stimulated the formation of germinal centers. RNA-sequencing analysis revealed that Sim + CpG/H9N2 vaccination significantly upregulated immune-related genes, which were enriched in pathways associated with stress response activation, immune cell recruitment, and inflammatory signaling. Overall, these findings demonstrate that Sim + CpG/H9N2 markedly enhances the immunogenicity of the inactivated H9N2 vaccine and provides new insights into the application of vaccine adjuvants for improved immune protection. Full article

Background: Splenic arterial embolization (SAE) is a well-established technique in the non-operative management of splenic trauma and aneurysms. While its short-term safety and efficacy have been widely documented, medium- and long-term impacts on splenic volume and function remain under-investigated. This study aimed to evaluate volumetric changes and hematological parameters following SAE, with emphasis on its role in preserving splenic integrity and potential integration with AI-enhanced imaging technologies. Methods: We retrospectively analyzed 17 patients treated with SAE between January 2014 and December 2023. Volumetric measurements were performed using computed tomography (CT) with 3D reconstructions before and after SAE. Patients were divided into two groups based on indication: polytrauma (n = 8) and splenic artery aneurysm (n = 9). Hematological parameters including white blood cells (WBCs), red blood cells (RBCs), and hemoglobin (Hb) were evaluated in correlation with clinical outcomes. Statistical significance was assessed using Student’s t-test, and power analysis was conducted. Results: Among the trauma group, mean splenic volume decreased from 190.5 ± 51.2 cm³ to 147.8 ± 77.8 cm³ (p = 0.2158), while in the aneurysm group, volume decreased from 195.4 ± 78.9 cm³ to 143.7 ± 81.4 cm³ (p = 0.184). Though not statistically significant, these changes suggest post-procedural splenic remodeling. The technical success of SAE was 100%, with no cases of late follow-up infarction, abscess, immunological impairment, or secondary splenectomy required. Hematologic parameters remained within normal limits in follow-up assessments. Conclusions: SAE represents a safe and effective intervention for spleen preservation in both traumatic and aneurysmal conditions. Although a reduction in splenic volume has been observed, white blood cell counts, a reliable indicator of splenic function, have remained stable over time. This finding supports the preservation of splenic function following SAE. Full article

The g-C₃N₄/ZnO nanocomposite materials were applied to degrade methylene blue (MB). The samples were characterized and evaluated to study the adsorption and photocatalytic degradation under visible light. The g-C₃N₄ was incorporated at percentages of 5%, 10%, 20%, and 40% relative to the ZnO weight. These composite materials were prepared using a solvothermal microwave technique. The structural, textural, morphological, and optical properties were investigated using XRD, FTIR, SEM, EDS, STEM, BET, UV-Vis, and XPS techniques. The XRD patterns of the samples showed the coexistence of crystalline phases of g-C₃N₄ and ZnO, while images and elemental composition analysis confirmed the formation of nanocomposite samples. The UV-Vis spectrum revealed a redshift in the absorption edge of the nanocomposites, indicating improved light-harvesting capability. The synthesized material g-C₃N₄/ZnO (20/80), with a surface area of 25 m²/g, exhibited higher photocatalytic performance, achieving 85% degradation of MB after 100 min under visible light, which corresponds to nearly three times the degradation efficiency of commercial P25-TiO₂ (31%) under the same conditions. The reusability and stability tests were conducted up to the fifth cycle, and this material showed 77% degradation, indicating good stability. This nanocomposite material has good potential as a photocatalyst for solar-driven MB. Full article

In China, most of the ancient wooden structure mortise and tenon buildings, under the long-term upper load, have columns with surface surfaces that have varying degrees of damage, which need to be repaired and strengthened urgently, but the theory related to CFRP, mortise size, and pre-damage simulation still needs to be deeply studied. To investigate the effects of CFRP reinforcement layers, cross-sectional area of concealed tenons as the projected area after installation, and tenon engagement length as the axial length after installation on the axial compressive mechanical properties of pre-damaged quad-segment spliced Pinus sylvestris var. mongolia composited wooden columns, axial compression failure tests were conducted on 10 specimens following pre-damage simulation and CFRP strengthening. The experimental program yielded comprehensive data, including observations, mechanical analyses, load-displacement curves, load-strain curves, ultimate load-bearing capacities, ductility coefficients, and stiffness values. The results demonstrate that with consistent tenon cross-sectional area and engagement length, increasing CFRP layers from 1 to 3 raises the ultimate bearing capacity from 472.3 kN to 620.3 kN and improves the ductility coefficient from 4.67 to 7.95, clearly indicating that CFRP reinforcement significantly enhances axial compressive performance while effectively mitigating brittle failure. When maintaining constant CFRP layers and tenon cross-sectional area, extending the tenon engagement length from 30 mm to 90 mm elevates the bearing capacity from 494.95 kN to 546.3 kN and boosts the ductility coefficient from 5.58 to 7.95. In contrast, with fixed CFRP layers and engagement length, expanding the tenon cross-sectional area from 360 mm² to 810 mm² produces only marginal bearing capacity improvement from 548.2 kN to 556.2 kN with ductility coefficients ranging between 4.67 and 5.56, conclusively revealing that tenon engagement length has substantially greater influence on mechanical properties than cross-sectional area. The optimal axial compressive performance configuration combines 3 CFRP layers, an 810 mm² tenon cross-section, and a 90 mm engagement length. Full article