Search Results (183)

Modern agriculture faces the critical need to develop sustainable, safe, and effective strategies for enhancing productivity, protecting plants and animals, and ensuring food security. Challenges posed by antibiotic resistance and the adverse environmental and consumer health impacts of chemical agents are driving the search for eco-friendly alternatives. In this context, bacteriocins—naturally occurring antimicrobial peptides synthesized by diverse bacteria—represent a promising alternative to traditional chemical compounds. This article reviews the potential and current advances in bacteriocin applications across agricultural sectors, with particular focus on their targeted antagonistic activity, structural diversity, commercial bacteriocin-based products, and their utilization in livestock farming, crop production, poultry farming, and aquaculture. Key findings demonstrate that bacteriocins, particularly nisin and pediocin PA-1, exhibit potent activity against major agricultural pathogens including Listeria monocytogenes, Staphylococcus aureus, Clostridium perfringens, and Escherichia coli, with efficacy rates reaching 90% in mastitis treatment and significantly reducing pathogen loads in poultry and aquaculture systems. Commercial products such as Nisaplin, Wipe Out, and ALTA 2431 have been successfully implemented in veterinary medicine and food production. In aquaculture, bacteriocins effectively control Lactococcus garvieae, Aeromonas spp., Vibrio spp., and Pseudomonas aeruginosa, contributing to sustainable disease management with minimal environmental impact. It can be suggested that bacteriocins may play an essential role in combating pathogens and offer viable alternatives to conventional antibiotics across primary food production systems, though optimization of production methods and regulatory frameworks remains essential for broader commercial adoption. Full article

To evaluate the optimal substitution ratio of organic fertilizer for chemical nitrogen fertilizer and its underlying mechanisms, a pot experiment was conducted in the rhizosphere soil of oat (Avena sativa) on the Qinghai–Tibet Plateau. Five treatments were established: CK (control), T1 (chemical fertilizer alone), T2 (100% organic fertilizer substitution for chemical nitrogen fertilizer), T3 (30% organic fertilizer substitution for chemical nitrogen fertilizer), and T4 (60% organic fertilizer substitution for chemical nitrogen fertilizer). We analyzed soil carbon fractions, microbial community structure, carbon-cycling enzyme activities, and yield responses and applied partial least squares–structural equation modeling (PLS-SEM) to identify key regulatory pathways. The results showed that 30% organic substitution (T3) was associated with optimized soil carbon pools, improved microbial community composition, and enhanced carbon-cycling enzyme activities, while reducing the abundance of potentially harmful fungi. Structural equation modeling indicated that β-glucosidase activity and the relative abundance of Proteobacteria were the primary drivers of yield, together explaining 76% of its variation. The ecosystem multifunctionality index (EMF) was significantly and positively correlated with yield. In summary, under the conditions of this experiment, 30% organic fertilizer substitution achieved a favorable balance between soil ecological functions and crop yield, providing a valuable reference for sustainable nutrient management in oat production in high-altitude cold regions. Full article

Continuous potato monoculture leads to yield decline, soil degradation, and increased soil-borne disease incidence. This study evaluated the potential of crop rotation to mitigate these issues by examining its effects on potato performance, soil chemical properties, and soil microbial communities. A two-year field experiment (2023–2024) in southern Shanxi, China, compared three treatments: continuous potato planting (CK, control), potato rotated with summer maize (with maize straw incorporation, T1), and potato rotated with summer soybean (with soybean straw incorporation, T2). The results demonstrated that both T1 and T2 rotations significantly increased tuber yield by 18.39% and 20.69%, respectively, and improved the potato commodity rate by 19.67% and 10.39%, compared to CK. Rotations also enhanced tuber quality, significantly increasing the content of nitrogen (5.24–28.20%), phosphorus (14.68–34.86%), potassium (23.61–52.42%), crude protein (5.14–28.11%), vitamin C (6.67–20.0%), starch (20.0–28.82%), and dry matter (4.55–12.88%), while reducing sugar content. In addition, the soil quality markedly improved under rotation. The soil organic matter, available phosphorus, available potassium, and total nitrogen increased by 27.77–31.92%, 10.48–12.38%, 4.44–28.42%, and 3.98–16.13%, respectively. Proteobacteria, Actinobacteriota, Acidobacteriota, Chloroflex, Firmicutes, and Myxococcota were the predominant bacterial phyla and Ascomycota, Mortierellomycota, Basidiomycota, and Chytridiomycota were the predominant fungal phyla. Microbial community analysis revealed that T1 rotation affected the Chao1 index and the ACE, measures of the diversity of the soil fungal community, and the rotations altered community structure. The abundance of pathogenic fungi, including Fusarium, Alternaria, and Lectera, was significantly reduced. Redundancy analysis (RDA) revealed that pH and total nitrogen (TN) were the primary factors shaping soil bacterial and fungal community structure. In conclusion, rotating potato with summer maize or soybean, combined with straw incorporation, is an effective strategy for enhancing tuber yield and quality, improving soil fertility, suppressing soil-borne pathogens, and promoting sustainable potato production in southern Shanxi. Full article

Co-incorporating rice straw and Chinese milk vetch (CMV) residues can enhance soil organic carbon (SOC) sequestration and productivity. However, limited information exists regarding its effects on SOC and nitrogen (N) pools as well as the sustainability of rice production in the middle and lower reaches of the Yangtze River Basin. A 3-year field experiment was conducted to assess the effects of co-incorporating rice and CMV residues into paddy soils with chemical-N reduction on SOC and total N (TN) sequestration, SOC and N fractions, grain yields and the sustainable yield index (SYI) in Ma’anshan City, Anhui Province. The treatments included winter fallow–rice rotation without or with both rice straw incorporation and fertilization, as the control (CK and WF-IF, respectively), and rice-CMV rotation with the co-incorporation of rice and CMV residues under 100%, 80%, and 70% recommended N fertilization (CMV-IF, CMV-MIF and CMV-LIF, respectively). Compared with the CK, the CMV-IF significantly increased the rice grain yield and the SYI by 82.1% and 90.4%, respectively. The SOC and TN stocks under CMV-IF were significantly enhanced by 6.3% and 26.4%, respectively, relative to the CK. The CMV-IF exhibited the highest soil active organic C (AOC) and active total N (ATN) contents, followed by CMV-MIF, CMV-LIF, WF-IF, and CK. Microbial biomass C and microbial biomass N were the primary components of soil AOC and ATN, respectively, and linked more explicitly to the SYI than other soil C and N parameters. Therefore, the co-incorporation of rice and CMV residues, coupled with 70~80% recommended N fertilization, might represent an environmentally friendly field management practice for rice production in the middle and lower reaches of the Yangtze River Basin. Full article

The primary goal of this study was to improve the rheological properties of water-based drilling mud using a combination of TiO₂-coated ZnO nanoparticles and activated carbon (AC) from banana peels. The TiO₂/ZnO nanocomposites were prepared using polyvinyl alcohol (PVA) as a binder under magnetic stirring and ultrasonic sonication to ensure uniform coating, followed by washing and controlled thermal treatment. NaOH-assisted chemical activation of banana peel produced activated carbon with better porosity and surface functionality than raw banana peel. The base water-based mud used in this study had different concentrations of both additives mixed in, and rheological parameters such as mud density, plastic viscosity (PV), yield point (YP), and gel strength were measured according to standard API methods. X-ray diffraction (XRD) and scanning electron microscopy (SEM) were used for structural and morphological characterization, which proved the successful coating and uniform dispersion of TiO₂ on ZnO nanoparticles. The use of mixed additives resulted in a significant improvement in mud properties, such as viscosity, gel strength, and yield point, proving to be more effective in suspension capacity and overall rheological stability. The use of this hybrid bio-nanocomposite mud system is a very economical and eco-friendly way of enhancing the drilling fluid performance, thus proving to be a supporting factor in conducting drilling operations that are both safe and efficient. Additionally, this study provides a sustainable hybrid TiO₂-ZnO and activated carbon additive that results in synergistic improvement of drilling-mud rheology and stability. Full article

Male infertility has emerged as a significant global concern, with male factors accounting for approximately 30% to 50% of infertility cases. Oxidative stress is recognized as the primary pathological mechanism affecting sperm structure and function. The development and application of chemically synthesized drug therapies are limited by lengthy research and development processes and significant adverse effects. Conversely, Traditional Chinese Medicine (TCM) compounds offer promising clinical applications for enhancing male reproductive function, attributed to their distinctive advantages of multi-target coordination and holistic regulation. This paper systematically reviews classical TCM compounds, such as those that tonify the kidney and benefit essence, warm and invigorate kidney Yang, and replenish Qi and nourish blood. It also examines the molecular mechanisms of active natural ingredients, including flavonoids, polyphenols, terpenes, alkaloids, and polysaccharides. These compounds improve male fertility by modulating oxidative stress-related signaling pathways. Furthermore, this review anticipates future research trajectories and potential applications within this domain, with the objective of establishing a theoretical basis for the clinical treatment of idiopathic male infertility and the development of novel pharmacological interventions. Full article

Co-combustion in a refuse incinerator is a primary method for treating aged refuse (AR). Given the high contents of heavy metals and chlorine in AR, it is crucial to investigate their release and fate during co-combustion to achieve environmentally sound treatment. This study investigated the release and volatilization of heavy metals (Cd, Cr, Zn, Ni, Cu, Pb) and HCl during the co-combustion of AR and municipal solid waste (MSW) through chemical thermodynamic equilibrium analysis. The effects of several parameters on the volatilization of heavy metals and HCl were analyzed, including incineration temperature, the N₂/O₂ ratio, the degree of refuse classification, the blending ratio of AR, and the effects of conventional calcium-based additives. The results showed that high temperature promoted the volatilization of Cd, Pb, Cu, Ni, and HCl. A lower N₂/O₂ ratio suppressed Zn and HCl volatilization. A higher degree of MSW classification (with lower proportions of kitchen and wood waste) and an increased AR blending ratio enhanced Zn fixation. CaO at high temperature only suppressed HCl volatilization, with a minor effect on heavy metals. Two modified calcium-based additives (CaBSiO₄OH and CaB₅SiO₉(OH)₅) with strong high-temperature Cu removal capabilities were explored, and their risk index was analyzed. Full article

Sugar beet (Beta vulgaris L.) is an important economic crop and a primary source of sugar in northern China, characterized by strong stress tolerance and high nutritional value. Microbial inoculants can promote crop growth by regulating soil enzyme activities, enriching dominant beneficial bacterial genera in rhizosphere soil, and improving the availability of soil nutrients. This study aimed to investigate the role of microbial inoculants in sugar beet production and their potential to replace chemical fertilizers and put forward the scientific hypothesis that microbial inoculants can increase soil nutrients and improve the soil microenvironment. A two-year field experiment was conducted: in 2022, treatments with different application rates of Bacillus subtilis and Trichoderma spp. inoculants were set up to screen the optimal inoculant and its dosage (M1); in 2023, based on this optimal inoculant (M1), treatments with reduced chemical fertilizer input were established to explore the mechanisms underlying the maintenance of sugar beet yield and quality. The results showed that the M1N2 (75 kg/ha fertilizer and 20% less nitrogen fertilizer) treatment significantly increased nitrogen, phosphorus, and potassium agronomic use efficiencies by 91.48%, 51.94%, and 53.50%, respectively, compared with the control (CK). Soil urease, catalase, and sucrase activities were significantly enhanced by 14.57%, 66.84%, and 222.46%, respectively. The treatment also significantly increased the relative abundance of beneficial bacterial genera such as JG30-KF-CM45 and KD4-96, while sugar beet yield was significantly increased by 5.53% relative to the CK. This study provides a theoretical basis for the application of microbial inoculants and the reduction in chemical fertilizers in sugar beet production. Full article

Bacterial biofilms pose significant challenges in clinical, industrial, and environmental settings due to their inherent resistance to antimicrobial agents and host immune responses. Encased within a self-produced extracellular polymeric substance (EPS) matrix, these structured microbial communities demonstrate exceptional resilience, resisting conventional antimicrobial treatments and adapting to, as well as recovering from, environmental and therapeutic stresses, necessitating the development of novel anti-biofilm strategies. This review provides a comprehensive synthesis of biofilm formation, resistance mechanisms, and current and emerging approaches for controlling biofilms, with a primary focus on advancements made over the last decade. Chemical, physical, and biological strategies, including enzymatic degradation, natural compounds, chelating agents, nanoparticles, photodynamic therapy, and probiotics, have demonstrated promising antibiofilm activity. Additionally, combination therapies and targeted drug delivery systems have emerged as viable solutions to enhance the eradication of biofilms. Despite these advancements, challenges such as cytotoxicity, bacterial adaptation, and clinical applicability remain. Addressing these hurdles requires interdisciplinary research to refine existing strategies and develop innovative solutions for effective biofilm management. Full article

In recent years, sprouts and microgreens from Brassicaceae species have been increasingly recognized for their nutritional value and bioactive compounds. Camelina sativa (L.) Crantz has emerged as a promising candidate for functional food production due to its exceptional chemical composition. This study evaluated the effects of pre-harvest UV-B radiation on the growth, biochemical traits, and stress-related responses in sprouts and microgreens from three camelina cultivars (‘Alan’, ‘Calena’, and ‘Pearl’). UV-B exposure moderately reduced germination, growth and productivity, but it strongly enhanced the phenolics, flavonoids and antioxidant capacity in sprouts. These increases in protective secondary metabolites reflect metabolic reprogramming triggered by such treatment. UV-B exposure in fact determined a reallocation of metabolic resources from primary growth toward accumulation of defensive compounds, including increased proline accumulation and enhanced non-enzymatic antioxidant systems. This adaptive response was effective in managing UV-B-induced oxidative stress in the next growth stage, as demonstrated by the reduced lipid peroxidation markers in microgreens. In microgreens, UV-B similarly stimulated secondary metabolite accumulation while reducing biomass productivity, with antioxidant systems effectively managing oxidative stress over the extended 14-day growth period. The cultivar-specific responses revealed genetic variation in stress responsiveness, with ‘Pearl’ showing slight superior secondary metabolite accumulation. Overall, controlled UV-B irradiation enhances health-promoting compounds through metabolic reallocation toward protective compound accumulation, demonstrating its potential as an eco-friendly strategy to improve the functional quality of camelina sprouts and microgreens. Full article

The dynamic response of soil bacterial communities to fertilization throughout the entire crop growth cycle remains inadequately characterized. To address this, we conducted a long-term field experiment in Jiangle County, Fujian Province, China, and collected soil samples across four rice growth stages (tillering, elongation, filling and maturity) under five fertilization regimes: no fertilization (CK); chemical fertilizer (NPK); and NPK supplemented with extra nitrogen (NPKN), extra phosphorus (NPKP) and rice straw (NPKS). Bacterial communities were analyzed by high-throughput sequencing. Our results revealed that soil bacterial diversity decreased progressively throughout the growth stages, with fertilization exerting only a minor influence. Structural equation modeling (SEM) identified daily mean temperature (DMT) as the factor with the strongest direct and total effects on the diversity. In contrast, fertilization regimes were the primary determinant of the community structure. Mantel test and redundancy analysis (RDA) indicated that soil pH was the most important factor shaping the community structure. Soil bacterial network attributes also varied mainly with fertilization: fertilizer addition reduced the complexity but enhanced stability, with NPK and NPKS showing the greatest stability. Regarding rice yields, all fertilized treatments were comparable but considerably higher than CK. In conclusion, rice growth stages primarily influenced soil bacterial diversity, while fertilization regimes predominantly shaped the community structure and network attributes. Further, we recommend NPK and NPKS as optimal strategies for balancing crop production, agroecosystem sustainability and environmental health. Full article

Hepatocellular carcinoma (HCC) represents the predominant type of primary liver cancer and remains a major global health concern. Current therapeutic strategies—such as surgical resection, radiation, and chemotherapy—provide clinical benefits but are frequently accompanied by considerable adverse effects. Consequently, identifying alternative treatment modalities and developing strategies that allow the use of lower drug doses without compromising therapeutic outcomes are essential goals in HCC management. Among emerging nanoscale platforms, metal–organic frameworks (MOFs) have attracted exceptional interest as promising candidates for targeted drug delivery in cancer therapy. Their inherent characteristics, including highly ordered porosity, large surface area, tunable cavities, adjustable chemical functionality, and remarkable drug-loading capacity, set them apart from conventional porous nanomaterials. Owing to their hierarchical architecture, MOFs are especially suitable for multimodal and synergistic anti-cancer treatments. MOF-based systems have demonstrated the ability to reinforce the performance of several therapeutic modalities, including photodynamic therapy (PDT), photothermal therapy (PTT), chemodynamic therapy (CDT), and sonodynamic therapy (SDT), while also serving as efficient carriers for targeted drug release. Their structural versatility further enables improved drug stability, enhanced solubility, and controlled-release behavior. This review provides an overview of recent progress in MOF-enabled therapeutic strategies and discusses their potential applications in the treatment of HCC. Full article

With emerging viruses and drug resistance on the rise, the discovery and development of innovative antiviral substances and agents are necessary for the effective treatment and control of viral outbreaks. Surrogate viruses are safer alternatives used in research to mimic dangerous or hard-to-culture viruses. They enable efficient, ethical, and cost-effective screening of antiviral compounds. In this study, we used a recombinant viral hemorrhagic septicemia virus (rVHSV) expressing enhanced green fluorescent protein as a surrogate for RNA viruses for the high-throughput screening of antiviral agents. An optimized mixture of viruses and EPC host cells was distributed in 96-well plates containing chemical compounds or plant extracts for screening. Using this system, 44,642 chemical compounds and 8104 plant and marine organism extracts were tested; 140 candidates were selected from primary screening, and 8 compounds and 5 plant extracts were further selected based on the selectivity index (SI), representing the ratio of the cytotoxic concentration (CC₅₀) to the inhibition concentration (IC₅₀). Among these, compound 3, which had the highest SI value of 1046, was further tested, considering in vitro activity against VHSV and another fish rhabdovirus, snakehead rhabdovirus (SHRV). Full article

(1) Background: Glioblastoma is the most common and aggressive primary brain tumor in adults, with a median survival time for patients treated with standard chemotherapy often of less than 1 year. Potential anticancer activity against glioblastoma is demonstrated by flavonoids, including fisetin (FIS). Although, its clinical application is limited by poor solubility and chemical instability. This study aimed to conduct a preliminary evaluation of fisetin’s suitability for intravenous delivery by developing and characterizing FIS-loaded poly(lactic-co-glycolic acid) nanoparticles (FIS-PLGA-NPs) and assessing their in vitro cytotoxic potential against glioblastoma. (2) Methods: Six FIS-PLGA nanoparticle formulations were prepared via the emulsification–solvent evaporation method and evaluated for key physicochemical properties. The biological activity of fisetin was examined through cell cycle analysis and apoptosis assays, and the most promising formulation was further assessed using an MTT assay in U-138 MG glioblastoma cells. In parallel, pure fisetin was exposed to ionizing radiation, including the standard sterilization dose of 25 kGy, to evaluate its structural stability and suitability for terminal sterilization approaches. (3) Results: The selected formulation (NP4) exhibited a mean particle size of approximately 330 nm, a zeta potential of −7.2 mV, a polydispersity index of 0.25, and high encapsulation efficiency and drug loading of 83.58% and 13.93%, respectively. Despite its preliminary nature, this formulation retained cytotoxic activity in vitro. Moreover, pure fisetin maintained its structural and chemical integrity following radiation exposure, supporting the feasibility of radiation sterilization prior to nanoparticle incorporation. (4) Conclusions: These findings confirm the feasibility of combining radiosterilizable fisetin with PLGA-based nanoencapsulation and provide an initial foundation for the development of an injectable fisetin delivery system for glioblastoma treatment. Further optimization, particularly surface modification, will be required to enhance colloidal stability and systemic performance. Full article

Bovine mastitis, an inflammation of the mammary gland, is recognized as the most prevalent disease in dairy cattle, leading to significant economic losses due to the reduction in quality and yield of milk. While antibiotic treatment remains to be the primary control method but their use of antibiotics contributes to the emergence of antibiotic-resistant bacteria and possesses potential health risks to consumers. Enhancement of host immune responses represents a promising alternative strategy for combating pathogenic bacteria. This study aimed to evaluate the immunomodulatory potential of metabolites derived from lactic acid bacteria (LAB) in murine macrophage RAW264.7 cells infected with Staphylococcus haemolyticus, a causative agent of bovine mastitis. Notably, LAB-derived metabolites demonstrated significant, strain-specific immunostimulatory activity. A comparative metabolomic analysis confirmed that each strain possessed a unique metabolic profile, providing a chemical basis for these various responses. The most pronounced effects were observed with metabolites from the isolated strain Enterococcus faecalis, which markedly increased NO production. Furthermore, these metabolites upregulated the expression of key inflammatory genes, e.g., iNOS, COX-2, TNF-α, and IL-6 and enhanced the protein levels of iNOS and COX-2. These findings suggest that LAB metabolites, particularly those from E. faecalis, may offer a novel therapeutic approach for enhancing immune defenses against mastitis-causing pathogens. Full article