Search Results (10,778)

Recycling agricultural residues is a promising strategy to enhance soil organic carbon (SOC) and improve soil quality. This study investigated the effects of exogenous organic carbon (EOC) amendments—straw and hydrochar—on SOC, its labile fractions, and the carbon pool management index (CPMI, an indicator of soil carbon quality and management efficiency) under flooding (FI) and controlled irrigation (CI) in a two-year pot experiment using paddy soil under field conditions. CI improved the soil average readily oxidizable organic carbon (ROC), dissolved organic carbon (DOC), and microbial biomass carbon (MBC) by 6.37–12.19%, 18.70–26.00% (p < 0.05), and 11.95–17.97% (p < 0.05), compared to FI. Similarly, EOC addition increased average ROC, DOC, and MBC during the entire rice growth period by 12.33–22.95%, 4.50–24.35%, and 6.24–21.51%, respectively, compared to the unamended controls. Additionally, CI increased soil carbon lability (L), carbon pool activity index (LI), carbon pool index (CPI), and CPMI by 3.39–14.01%, 3.65–8.84%, 1.75–2.58%, and 6.19–16.01%, respectively, although some of these increases were not statistically significant. Notably, the combination of CI and EOC application significantly increased CPMI by 19.45–20.29% (p < 0.05), with the highest values observed in CI treatments amended with either straw or hydrochar. Hydrochar application had a smaller effect on increasing soil active OC fractions compared to straw incorporation, but demonstrated a greater potential for long-term SOC sequestration. These findings demonstrate the potential of hydrochar as a waste-derived amendment for long-term carbon sequestration and provide insights for optimizing water–carbon management strategies in sustainable rice cultivation. Full article

14-3-3 proteins are highly conserved regulatory molecules that play a central role in plant responses to salt stress. These proteins modulate the activity, stability, and localization of diverse target proteins. This review summarizes current advances in understanding the multifaceted roles of 14-3-3 proteins in salt stress signaling. Specifically, it details how 14-3-3 proteins interact with and regulate diverse components, including protein kinases, phosphatases, ion channels and transporters, proton pumps, metabolic enzymes, and transcription factors. These interactions are predominantly phosphorylation-dependent and often involve calcium (Ca²⁺) and other second messengers. Additionally, 14-3-3 proteins themselves are subject to post-translational regulation, such as phosphorylation and ubiquitination, which fine-tune their stability and activity under stress conditions. This review highlights 14-3-3 proteins as versatile molecular switches in salt stress signaling, integrating diverse signals to orchestrate stress tolerance mechanisms. It also identifies critical knowledge gaps and outlines future research directions aimed at leveraging these proteins for improving crop resilience to salinity stress, an ongoing challenge in modern agriculture. Full article

Nitrogen (N₂), constituting the majority of Earth’s atmosphere, remains indispensable for biological systems and underpins modern agriculture and industry. Traditionally, the Haber–Bosch process has been essential for synthesizing ammonia (NH₃) from N₂ under high temperature and pressure, but it contributes significantly to global CO₂ emissions. Recently, carbon-free electrocatalytic nitrogen reduction (e-NRR) has emerged as a promising, eco-friendly, and cost-effective approach for green NH₃ production under mild conditions using renewable energy, offering a sustainable alternative to the fossil fuel dependent Haber–Bosch process. This work explores NRR by contrasting the limitations of Haber–Bosch with the advantages of electrocatalysis. Despite progress, electrochemical N₂ reduction to NH₃ production remains challenging due to low activity, poor selectivity, stability, efficiency, and detection issues. Developing efficient e-NRR electrocatalysts is crucial to enhance activity, suppress hydrogen evolution reaction (HER), boost NH₃ yield, and improve Faradaic efficiency. This review highlights the role of layered double hydroxide (LDH) catalysts in e-NRR, summarizing the fundamental process, reaction pathways, and synthesis strategies. Ammonia detection methods, key metrics, and potential contamination issues are compared to inform standard NRR measurement protocols. Lastly, we summarize key findings to synthesize and improve LDH electrocatalysts for NH₃ production and a sustainable, carbon-free N₂ economy. Full article

Gully erosion poses a serious threat to soil fertility and agricultural sustainability in Northeast China’s black soil region. Accurate and efficient mapping of erosion gullies is critical for enabling targeted soil conservation and precision land management. In this study, we developed a texture-enhanced deep learning framework for automated gully extraction using high-resolution GF-1 and GF-2 satellite imagery. Key texture parameters—specifically mean and contrast features derived from the gray-level co-occurrence matrix (GLCM) under a 5 × 5 window and 32 gray levels—were systematically optimized and fused with multispectral bands. We trained and evaluated three convolutional neural network architectures—U-Net, U-Net++, and DeepLabv3+—under consistent data and evaluation protocols. Results demonstrate that the integration of texture features significantly enhanced extraction performance, with U-Net achieving the highest overall accuracy (90.27%) and average precision (90.87%), surpassing DeepLabv3+ and U-Net++ by margins of 6.06% and 9.33%, respectively. Visualization via Class Activation Mapping (CAM) further confirmed improved boundary discrimination and reduced misclassification of spectrally similar non-gully features, such as field roads and farmland edges. The proposed GLCM–CNN integrated approach offers an interpretable and transferable solution for gully identification and provides a technical foundation for large-scale monitoring of soil and water conservation in black soil landscapes. Full article

Indoor exposure to potentially toxic elements (PTEs) presents a global health concern, yet comprehensive seasonal assessments in Thailand remain limited, particularly during air pollution episodes. We assessed 15 PTEs in household dust collected across eight provinces of upper northern Thailand (UNT) during the haze and non-haze seasons to evaluate contamination levels, identify sources, and assess health risks. Five elements (Cr, Mo, Ni, Pb, and Zn) showed significantly higher concentrations during the haze season (p < 0.05), accompanied by corresponding increases in contamination indices and more diverse pollution sources being identified compared to the non-haze season, with Sb showing the highest enrichment degree (EF = 117.8). Source identification revealed potential enrichment from mixed anthropogenic sources, natural soil, industrial activities, agricultural inputs, and biomass burning. Health risk assessment showed that children faced unacceptable non-carcinogenic risks (HI = 2.51), increasing to 2.79 during the haze season, exceeding safe thresholds. Both adults and children experienced unacceptable carcinogenic risks from chromium exposure, particularly through inhalation during haze episodes. Total lifetime cancer risks increased from 1.20 × 10⁻⁴ to 1.74 × 10⁻⁴ for children and from 4.02 × 10⁻⁴ to 6.06 × 10⁻⁴ for adults during the haze season. These findings underscore the critical need for integrated pollution control strategies addressing biomass burning emissions to reduce indoor dust contamination and protect public health in biomass-burning-impacted regions. Full article

Carrot (Daucus carota L.) is a widely consumed root vegetable, yet its aerial parts, including leaves and stems, are typically discarded as agricultural by-products, despite their potential biological value. This study comparatively evaluated the antioxidant and immunomodulatory properties of carrot aerial and root parts extracted using hot water or 50% ethanol. Four extracts were prepared: aerial part hot-water (AP-W), aerial part ethanol (AP-E), underground part hot-water (UP-W), and underground part ethanol (UP-E). The total phenolic content (TPC, expressed as gallic acid equivalents; GAE) and total flavonoid content (TFC, expressed as quercetin equivalents; QE) were quantified using the Folin–Ciocalteu and aluminum nitrate colorimetric methods, respectively. Antioxidant capacities were determined by ABTS and DPPH radical scavenging assays, cytotoxicity was assessed in RAW 264.7 macrophages via the MTT assay, nitric oxide (NO) levels were measured using the Griess reaction, and cytokine (IL-6, TNF-α) concentrations were analyzed by ELISA. Among the extracts, AP-E exhibited the highest TPC (28.3 ± 0.3 µg GAE/mg extract) and TFC (18.2 ± 2.3 µg QE/mg extract), corresponding to the strongest ABTS (92.3 ± 2.5%) and DPPH (72.4 ± 7.3%) radical scavenging activities. None of the extracts demonstrated cytotoxicity below 400 µg/mL. Under basal conditions, AP-W and UP-W significantly enhanced NO production (9.5 ± 1.3 µM and 7.7 ± 1.2 µM, respectively), while co-treatment with LPS markedly reduced NO levels in AS-E (2.3 ± 0.2 µM). Consistently, AP-W and UP-W elevated cytokine secretion (IL-6: 3462.1 ± 349.7 pg/mL and 1749.4 ± 55.4 pg/mL; TNF-α: 15,245.2 ± 771.0 pg/mL and 14,719.1 ± 329.8 pg/mL), whereas AP-E (400 µg/mL) significantly suppressed IL-6 (3938.6 ± 268.7 pg/mL) and TNF-α (11,869.0 ± 721.1 pg/mL) under LPS-stimulated conditions. Collectively, these results indicate that hot-water extracts of carrot parts exert immunostimulatory activity, whereas ethanol extracts possess potent anti-inflammatory potential. The aerial parts of carrots, often regarded as waste biomass, exhibit comparable or superior bioactivities to the roots, underscoring their potential utility as promising functional food ingredients. Full article

Mixed cropping may positively affect soil fertility and soil biological activities, such as those related to mycorrhizal colonization intensity (M%), which plays a vital role in the plant nutrient cycle and can improve tolerance to drought and pathogens. This plant and soil fungi symbiosis helps to reduce dependency on chemical fertilizers, promotes sustainable agricultural practices, and minimizes environmental impacts. However, field studies that clearly assess the effects of cereal/legume intercropping on mycorrhizal intensity and relate it to plant productivity, yield quality, and plant adaptation to climate change are lacking. This field experiment was conducted to assess the effects of cereals/legume intercropping on mycorrhizal colonization, and to explore its interaction with physical cereal root parameters and crop yield. Three main crops, spring barley, oat, and field pea, were grown as monocultures. For the spring barley and oat, the study also included two different fertilization levels (with and without organic fertilizers) and legume intercropping (field pea and red clover). The intercropping had a significant impact on spring barley and oat root length, diameter, and specific root length. The general average of root length and diameter was higher in oat–pea and barley–pea cropping systems. The most significant effect in root architecture parameters observed in red clover was when it was intercropped with barley or oat. The establishment of field pea intercrop significantly increased M% in spring barley and had a positive effect on the grain yields of both spring barley and oat. Meanwhile, red clover intercropping enhanced M% and grain yield in oats but had no such effect in barley. In both spring barley and oat, M% was positively correlated with grain yield. Full article

This study presents the optimisation of an alkali-activated binder produced from ground granulated blast furnace slag (GGBFS) and potassium-rich sunflower husk ash (SHA), by varying SHA content, curing regime, and mixing procedure. Both materials are locally available in the Republic of Serbia. The influence of SHA content (15%, 25%, and 35% by mass of GGBFS) and curing conditions (ambient and 65 °C) on hydration products, workability, and compressive strength was examined. The water-to-binder ratio and GGBFS content were kept constant, and a one-part alkali activation approach was employed using untreated SHA. Fourier-transform infrared spectroscopy (FTIR) and thermogravimetric analysis (TGA) were performed on paste samples, after 2, 7 and 28 days of curing, while workability and compressive strength of mortars were measured after 7 and 28 days. Increasing SHA content enhanced the formation of C-S-H and C-A-S-H gels, resulting in a consistent rise in compressive strength, from 26.6 MPa to 36.2 MPa after 7 days and from 46.2 MPa to 55.1 MPa after 28 days of ambient curing. Workability was slightly reduced with increasing SHA content, resulting in flow diameters of 156.04 mm (15% SHA), 154.10 mm (25% SHA) and 152.76 mm (35% SHA). Curing at 65 °C accelerated early strength gain for 33% to 39% but produced lower 28-day strengths than ambient curing. Additionally, for the optimal mix, SHA was also pre-immersed in water for varying durations to assess its effect on workability, compressive strength, and potassium ion leaching. This pretreatment increased compressive strength by up to 14.7%, depending on immersion time, but reduced workability by up to 15.5%. The novelty of the research is reflected in attaining the highest 28-day compressive strength of 55 MPa (for 25% SHA by mass of GGBFS), under ambient curing, without SHA pretreatment or immersion, highlighting the potential for low-energy, sustainable binder systems using agricultural and industrial by-products. Full article

Global antibiotic pollution (represented by tetracycline hydrochloride, TCH) threatens water environmental safety, and resource recovery of agricultural waste remains a key challenge for sustainable development. Given that utilizing biochar for adsorption is widely recognized as a circular economy-compliant method, this study aimed to verify its applicability in TCH pollution control while recycling agricultural waste by preparing modified biochar from the Xi Zang highland barley straw via chemical activation (KOH, H₃PO₄, NaHCO₃, and ZnCl₂) and pyrolysis at 750 °C. Among the products, H₃PO₄-modified (P-BC) and ZnCl₂-modified (Zn-BC) biochars performed best: their abundant micro/mesoporous structures and surface functional groups (–OH/–COOH) enabled excellent TCH adsorption, with the mechanism involving synergy of physical adsorption (dominated by pore filling) and chemical adsorption (hydrogen bonding, electrostatic attraction, cation bridging), alongside multi-layer adsorption. Adsorption was pH-dependent—acidic conditions favored it, while Zn-BC restored efficiency at pH = 9 via Zn²⁺ bridging. The two biochars were complementary: Zn-BC had higher adsorption capacity, while P-BC showed better stability and ionic interference resistance. Thus, Zn-BC suits high-concentration, low-ionic-strength TCH wastewater, and P-BC is ideal for complex high-ionic-strength water (e.g., industrial/aquaculture wastewater). This study provides theoretical and technical support for high-value utilization of regional agricultural waste and targeted TCH pollution control. Full article

Tetracyclines are among the oldest classes of antibiotics, with broad activity against Gram-positive and Gram-negative bacteria, as well as Chlamydia, Legionella, Rickettsia, and Mycoplasma species. Widely used in human and veterinary medicine, agriculture, and aquaculture, they represent approximately 10–12% of the global antimicrobial market. Extensive use has driven the emergence and spread of antimicrobial resistance, posing ecological and public health risks. However, the full extent of these risks remains unclear due to limited data on tetracycline consumption, environmental occurrence, and resistance patterns across sectors. Recent One Health-oriented strategies have promoted the rational use of tetracyclines in medicine, veterinary practice, and agriculture. To reduce environmental accumulation, various degradation and remediation techniques have been developed, though most remain restricted to laboratory or engineered settings. This narrative review provides a comprehensive overview of global tetracycline consumption; environmental occurrence; distribution and concentration levels; resistance mechanisms and prevalence; and mitigation strategies, including antimicrobial stewardship and degradation approaches. Understanding these aspects is essential for developing evidence-based interventions to minimize the environmental and public health impacts of tetracycline use. Full article

Pleurotus giganteus, a heat-tolerant mushroom with high nutritional and medicinal value, is a promising species for tropical mushroom cultivation in Hainan, China. However, its current dependence on rubber sawdust as the primary substrate compromises environmental sustainability. In this study, we applied a “replacing wood with grass” strategy and used a simplex-lattice design to optimize substrate formulations based on agro-residues. Laboratory screening identified banana straw and chili straw as effective substitutes for rubber sawdust, supporting rapid and dense mycelial growth. Mixed formulations showed distinct advantages in mycelial growth, enzyme activity, agronomic traits (growth cycle, yield, and cap-to-stipe ratio), and nutritional composition compared to the control formulation (CF), particularly in terms of growth rate and laccase activity. Correlation analyses revealed that both individual ingredients and their interactions significantly affected mycelial growth and agronomic traits, with the magnitude and direction of effects depending on their relative proportions. Based on expected response values for key evaluation indices, an optimal formulation (9.97% rubber sawdust, 24.33% banana straw, 10.70% chili straw, 40% cottonseed hulls, 10% wheat bran, and 5% lime) was predicted and experimentally validated to outperform the CF. This study provides a sustainable basis for localized cultivation of P. giganteus in Hainan and supports the high-value valorization of agricultural residues for mushroom production. Full article

Composite flours have been increasingly introduced in bakery products, aiming to enhance their nutritional value and reduce overdependence on imported wheat. Crackers are popular snack items, with potential to affect body weight and health status. This study aimed to examine the effects of different flour types, specifically pulses (chickpea, lupin, yellow split pea and cowpea), agricultural by-products (grape seeds and olive stones) and cereals (barley), on flour functionality, dough quality and final product characteristics compared with wheat flour (control) at various substitution levels. The functional properties of the composite flours were associated with the properties of dough and the characteristics of the crackers. Barley flour produced crackers with significantly higher hardness and lightness (L*) compared to the control, whereas chickpea flour had a similar but non-significant trend for both hardness and L* value. In contrast, high-level olive stone formulations yielded softer textures and the highest total color difference (ΔE), followed by grape seed crackers, which also exhibited high ΔE values and reduced hardness. The effects of composite flours on product texture were mediated by water absorption capacity and the compositional characteristics of the added flours. Crackers prepared with composite flours generally resulted in darker and diverse color profiles as well as low water activity and moisture values. Overall, the findings indicate that variations in composite flour type and substitution level influence product quality, allowing targeted modification of specific cracker attributes. Full article

This work introduces an environmentally sustainable and cost-effective strategy for synthesizing graphene nanomaterials from agricultural residues—walnut shells and apricot stones. The synthesis pathway combines desilication, controlled pre-carbonization, chemical activation with KOH, and mild exfoliation to produce few-layer graphene with a high degree of structural order. The process, conducted at 523–573 K for pre-carbonization and 1123 K for activation, enables the formation of graphene sheets with a specific surface area of approximately 1300 m²/g, carbon content of 80–90%, and average pore diameter below 100 nm. The materials were comprehensively characterized using SEM, TEM, Raman spectroscopy, and BET analysis. Raman spectra revealed an I_G/I_2D ratio of ~1.5–2 a.u., confirming the presence of 4–5 graphene layers. Compared to conventional biomass-derived graphene routes, the developed approach ensures enhanced porosity, higher graphitic ordering, and improved purity, demonstrating its strong potential for energy storage, adsorptive purification, and environmentally benign nanotechnology applications. Full article

Prolonged application and low recycling rates of agricultural plastic films have resulted in significant accumulation of microplastics (MPs) in soils, posing a threat to soil health. However, the impacts of MPs on microbial communities and enzyme activities in Mollisols remain poorly understood. To address the key question of whether soil pH drives the responses of catalase (CAT) activity and bacterial communities to MPs—a core focus of this Mollisol-based case study—we investigated the effects of different MP concentrations (1%, 5%, and 10%) on bacterial community structure and CAT activity across three Mollisol farmlands with distinct pH levels. CAT activity was stimulated at low MP concentrations but inhibited at high levels, whereas dynamic and thermodynamic parameters displayed irregular responses. Temperature sensitivity (Q₁₀) of CAT remained stable, whereas Q₁₀ of kinetic parameters varied among soils. Correlation analysis indicated that E_a and Q₁₀ in acidic soil and V_max/K_m in neutral soil and alkaline soil governed CAT activity. MPs altered α-diversity in acidic and neutral soils, changed β-diversity only in acidic soil, and promoted deterministic assembly processes. PICRUSt functional prediction suggested that functional gene shifts were most evident in acidic and neutral soils, with soil organic matter and V_max/K_m as key drivers in acidic soils and CAT in neutral soils. In contrast, responses in alkaline soil were negligible. These findings highlight soil type-specific microbial responses to MPs and their ecological risks in agricultural soils. Full article

Plants are a valuable source of natural compounds with diverse applications. Recently, increased attention has focused on waste products from the agricultural industry, including walnut husk. Given its potential as a sustainable source of bioactives, this work characterizes the alcoholic Juglans regia “Sorrento” walnut husk extract (WHE). The extract’s phenolic content, antioxidant activity, and phytochemical composition were evaluated using spectrophotometry and UHPLC-HRMS-based untargeted metabolomics analysis. WHE exhibited a high total phenolic content (TPC = 1.45 ± 0.03 mg GAE/g dry extract) and a rich profile of phenolic acids, flavonoids, and tannins. Given this composition, WHE’s biological activity was further tested in an in vitro human keratinocyte (HaCaT) model. At the concentration of 10 μg/mL, WHE showed no cytotoxicity and displayed significant antioxidant properties by modulating detoxifying proteins such as Nrf2. WHE also influenced mitochondrial metabolism, increased maximum respiration, preserved barrier integrity, and activated pathways for epithelial homeostasis. Overall, this study highlights the bioactivity of the J. regia “Sorrento” walnut husk extract. These findings support the valorization of walnut husk as a sustainable source of bioactives for dermatological and cosmetic products. Full article