Search Results (5,672)

The rhizosphere is a critical interface linking plants and soil; however, the mechanisms by which parasitic plants affect host growth through rhizosphere microecological changes remain unclear. This study systematically elucidates how Monochasma savatieri, a hemiparasitic plant, promotes blueberry growth by reshaping rhizosphere microecology. Pot experiments showed that parasitism significantly enhanced urease, sucrase, and soil nitrate reductase activities, improving organic matter decomposition and nutrient transformation efficiency. Concurrently, soil total nitrogen (TN), total phosphorus (TP), and total potassium (TK), along with alkali-hydrolyzable nitrogen (AN) and available potassium (AK), decreased, suggesting enhanced nutrient absorption by roots. At the microbial level, parasitism altered community composition and diversity, enriching functional taxa such as Nitrosomonas, OLB5, and Serendipita. Functionally, pathways related to stress resistance (necroptosis and glutamatergic synapses) were activated, whereas those linked to pathogen colonization (Pseudomonas aeruginosa biofilm formation and tryptophan metabolism) were suppressed. These modifications reduced harmful microbial competition, optimized nutrient cycling and signaling networks, and established a favorable rhizosphere microenvironment for root health. By integrating soil enzyme activity, nutrient dynamics, and microbial functions, M. savatieri systemically improves the rhizosphere microenvironment, ultimately enhancing blueberry growth. This study provides theoretical support for intercropping and management of parasitic plants with blueberries. Full article

Background: The escalating spread of drug-resistant bacteria is intensifying the antibiotic resistance crisis, necessitating the urgent development of novel antimicrobial agents to address the resulting high global mortality rates and significant socioeconomic burden. Objectives: This study aimed to aminate the C-6 position of β-carboline and investigate the antibacterial activity and mechanism of action of the derivatives. Results: For the first time, 16 derivatives with various nitrogen-containing moieties, including aliphatic- and phenyl-amino, imidazolium, pyridinium, and quinolinium, were synthesized via amination at the C-6 position of β-carboline. These compounds exhibited moderate to good activity against Gram-positive methicillin-resistant Staphylococcus aureus (MRSA) and Bacillus subtilis, with minimum inhibitory concentration (MIC) values ranging from 1.56 to 100 μg/mL. The study reveals that elongating an alkyl chain, incorporating a cationic scaffold, and expanding a π-delocalized system can enhance antibacterial activity. The most potent derivative from each series was selected for further mechanistic investigation against MRSA. All studied compounds demonstrated low hemolytic activity and low cytotoxicity. Studies on the antibacterial mechanism indicated that the compounds exert their antibacterial effects by disrupting bacterial cell walls and membranes. Additionally, two of the compounds were found to potentially disrupt the secondary structure of DNA. All tested compounds exhibited antibiofilm activity. Conclusions: Our findings demonstrate that amination modification at the C-6 position of β-carboline can enhance antibacterial activity by disrupting the cell wall membranes and interacting with bacterial DNA. These results provide a basis for further optimization of antibacterial agents based on β-carboline. Full article

Vortex generators (VGs) are considered in this study as an effective means of controlling the boundary-layer structure and suppressing flow separation on the suction sides of wind turbine blades. An original geometry of a surface-mounted VG has been developed and experimentally investigated, providing a stable modification of the near-wall flow over a wide range of incoming flow velocities. The aerodynamic effect is attributed to the formation of spatially diverging vortex structures that enhance momentum transfer from the outer flow region toward the near-wall layer, thereby increasing the energy level of the boundary layer. This results in an extension of the attached-flow region and an increase in the mean flow velocity over the suction side of the airfoil by up to 6.5%. The proposed configuration enables a 15% increase in the installation spacing of surface-mounted VGs without loss of control efficiency. Experimental investigations were carried out in a subsonic aerodynamic facility using the Particle Image Velocimetry (PIV) method at free-stream velocities of up to 30 m/s. The obtained data will be used for the development and validation of a mathematical model intended for parametric studies of the influence of surface-mounted VGs on various wind turbine blade airfoils under a wide range of atmospheric turbulence conditions. Full article

The efficient utilization of industrial waste (containing alkaline compounds, especially Ca-based species) for flue gas desulfurization (FGD) is of great importance for both environmental protection and resource recovery. In this study, paper industry white mud was modified with Ca(OH)₂ to develop a cost-effective sorbent with enhanced SO₂ removal performance. Optimization experiments identified the best preparation conditions as a 1:1 Ca(OH)₂/white mud ratio, 60 °C modification temperature, 6 h reaction time, and a liquid-to-solid ratio of 3:1. Under these conditions, the sorbent achieved nearly 100% SO₂ removal in the first 6 h and maintained >90% efficiency after 10 h, significantly outperforming raw white mud and Ca(OH)₂ alone. Characterization revealed that the superior performance originated from structural stability and abundant active sites. BET analysis showed a high surface area (24.8 m²·g⁻¹) and pore volume (0.160 cm³·g⁻¹), which were largely preserved after desulfurization, indicating resistance to pore blockage. SEM images confirmed a transition from porous aggregates to densified product layers, consistent with a shrinking-core/product-layer mechanism. XRD identified CaSO₄·2H₂O as the dominant product, while in situ FTIR demonstrated that O₂ promotes sulfite oxidation and H₂O accelerates hydrated sulfate formation, enhancing activity but causing faster pore blocking. The presence of NO extended sorbent durability by catalyzing continuous sulfite oxidation through NO/NO₂ redox cycling. Overall, Ca(OH)₂-modified white mud combines high reactivity, durability, and structural stability, offering a promising alternative to conventional sorbents. This work provides a viable route for the resource utilization of paper industry waste and practical insights for designing efficient and sustainable materials for industrial FGD systems. Full article

Background/Objectives: Cardiac rehabilitation (CR) is a cornerstone of secondary prevention, traditionally delivered through supervised center-based models. However, significant logistical barriers and high healthcare costs necessitate a paradigm shift. This review aims to assess the impact of emerging digital frontiers, specifically telerehabilitation (CTR) and artificial intelligence (AI), on overcoming these challenges and improving clinical outcomes. Methods: This study is a narrative, clinically oriented review informed by a structured search of PubMed/MEDLINE and EMBASE for literature published between January 2015 and January 2026. Results: Evidence indicates that CTR is non-inferior to center-based programs in terms of exercise capacity and quality of life (QoL). Digital tools, such as wearable devices and mobile health (mHealth) applications, have significantly increased program participation and improved adherence to lifestyle modifications. Furthermore, the integration of AI facilitates early detection of cardiac events and personalized exercise prescription, while prehabilitation models have been shown to reduce postoperative hospital stays. Conclusions: Digitalization of CR may represent a cost-effective alternative that bridges the gap in global access. While technology serves as an essential diagnostic partner, a robust regulatory and privacy framework is required to protect data sovereignty. Ultimately, multidisciplinary synergy between human expertise and digital innovation is important for providing an equitable and personalized pathway to recovery. Full article

Background/Objectives: Lipid nanoparticles (LNPs) are a prominent example of delivery systems that are used to prevent the degradation of messenger ribonucleic acid (mRNA) and facilitate cell uptake. Improving LNP transfection efficiency requires careful selection of key formulation components, including the ionizable lipid and the coding sequence of the nucleic acid. Therefore, it is crucial to assess various options for the target cells, as results can differ significantly between cell types. Building on previous work investigating the effect of apolipoprotein E4 on LNP transfection of human monocyte-derived dendritic cells, we assess the impact of different ionizable lipids and compare modifications in the mRNA uridine to further optimize the delivery to these cells. Methods: LNPs containing eGFP mRNA with different uridine modifications were produced via microfluidic mixing and investigated for their in vitro transfection efficiency of human monocyte-derived dendritic cells. Transfection occurred in the presence of apolipoprotein E4 for different encapsulated mRNA concentrations. Delta mean fluorescence intensity and eGFP positive cells were measured by flow cytometry 48 h after transfection. Cell viability was assessed via AnnexinV/7-AAD staining, after comparing this method to LIVE/DEAD^TM Fixable Near-IR staining. Results: This study shows that a combination of SM-102 as the ionizable lipid with eGFP mRNA containing N1-methylpseudouridine enabled the transfection of human monocyte-derived dendritic cells with very high efficiency at low concentrations, allowed for dose sparing, and even led to the LNPs outperforming a specifically tailored electroporation protocol. Conclusions: Improvement of nucleic acid delivery to human monocyte-derived dendritic cells, known for their difficulty to be transfected, was achieved by LNP formulation tuning. Full article

Native Staphylococcus aureus protein A exhibits strong affinity to the Fc and VH regions of human IgG1, IgG2, and IgG4, making it a valuable tool for monoclonal antibody (mAb) purification. However, its low stability under conditions such as increased alkaline concentrations during cleaning-in-place (CIP), protease exposure, thermal stress, and shear forces limits its usability for large-scale industrial applications. Recombinant Protein A (rProtein A) can be modified to improve key properties, including alkaline stability. In this study, we present targeted modifications to the C domain of native Protein A, evaluating multimeric variants for structural and functional improvements. The selected variant demonstrated extremely high stability after 60 h incubation at 0.5 M NaOH by maintaining more than >90% initial dynamic binding capacity (DBC) and up to 80% DBC after 40 h in 1.0 M NaOH. However, the most impressive result obtained was the stability of the ligand in 1.5 M NaOH, retaining 80% DBC after 22 h and 60% DBC after 40 h. To the best of our knowledge, this is the first time that such high alkaline stability is reported for a rProtein A. To assess its application in monoclonal antibody purification, the optimized rProtein A ligand was immobilized on agarose resin and tested in chromatography processes. The resulting chromatography resin functionalized with the CmZmb ligand (now commercialized by Sunresin, China under the name of rProtein A Seplife Suno) exhibited a high dynamic binding capacity of 70 mg/mL, minimal ligand leaching under operational conditions (~15 ppm), and extended lifecycle performance (88% DBC retained after 120 purification cycles with 0.5 M NaOH CIP), making it well-suited for industrial-scale applications. Full article

This study aims to evaluate the use of Tectona grandis sawdust (Teak) and activated carbons (ACs) prepared from Teak and modified with urea on the removal of methylene blue (MB) from the aqueous phase. Activation is performed with potassium hydroxide (KOH), and urea is added during chemical activation to increase nitrogen content in the AC matrix and improve textural properties. ACs are physiochemically characterized by elemental and Fourier Transform Infrared (FTIR) spectroscopy analysis, with the determination of the point of zero charge (pHpzc) and nitrogen adsorption at 77 K. The addition of urea allows for obtaining ACs with a higher pHpzc and carbon and nitrogen content, with improved textural properties when compared with the original AC. The addition of urea also promotes an increase in surface area and porous volume (1246 m² g⁻¹ and 0.64 cm³ g⁻¹). The modifications slightly affect the performance of the ACs in removing MB from water. While the original AC (AC_Teak_KOH_1_2) has a maximum MB adsorption capacity of 270.2 mg g⁻¹, the modified one (AC_Teak_KOH_urea (1_2_1)) has a maximum adsorption capacity of 281.7 mg g⁻¹. MB adsorption isotherms fit well with the Freundlich equation. Kinetic data fit well with the pseudo-second-order model, and the Weber–Morris representation shows that MB adsorption is described as a succession of two diffusion steps. The results make clear that it is possible to recover Teak waste through its transformation into ACs, presenting high application in the removal of dyes from water. Full article

Background: Hyperuricemia frequently coexists with type 2 diabetes mellitus (T2DM), contributing to a heterogeneous patient population. While previous analyses compared the overall longitudinal effects of allopurinol and SGLT2 inhibitors in this cohort, it remains unclear whether baseline metabolic heterogeneity modifies treatment response. This study aimed to determine whether data-driven metabolic clustering identifies phenotypic subgroups with prognostic or predictive relevance in hyperuricemic T2DM. Methods: In a retrospective cohort of 224 patients with T2DM and hyperuricemia, model-based clustering was applied to age, diabetes duration, body mass index (BMI), serum uric acid (sUA), HbA1c, eGFR, and sex. A sensitivity analysis excluded outliers, yielding 207 patients. Longitudinal trajectories of eGFR and sUA were assessed using linear mixed-effects models and individual slopes. Effect modification by cluster was tested via three-way interactions and analysis of covariance. Results: Clustering identified two groups with weak separation: an adipose–metabolic cluster (n = 116; exclusively male, BMI 33.1 ± 5.7 kg/m², sUA 478 ± 62 µmol/L) and a lean–metabolic cluster (n = 91; exclusively female, BMI 31.3 ± 6.0 kg/m², sUA 426 ± 67 µmol/L). Treatment-agnostic analyses showed no differences in eGFR and sUA slopes or in all-cause mortality across clusters. In both clusters, SGLT2 inhibitors yielded significantly more favourable eGFR slopes than allopurinol, while sUA reductions were comparable across treatments. No significant three-way interactions were detected. Conclusions: In this cohort, although baseline metabolic characteristics differ among patients, using the selected baseline variables, no clinically actionable treatment-relevant phenotypes were identified. Full article

Background/Objectives: Although the Calvert formula has been widely used to guide carboplatin dosing, it may yield inaccurate dose predictions in certain patient populations. We aimed to evaluate the adequacy of the conventional Calvert formula and to propose structural modifications to enhance dosing accuracy in breast cancer patients with preserved renal function (CrCL ≥ 55 mL/min). Methods: A systematic review and meta-analysis were conducted to integrate published pharmacokinetic models in patients with breast cancer. Two retrospective datasets (n = 154) were combined into a single analysis dataset and used to calculate carboplatin doses based on the conventional formulas using creatinine clearance (CrCL) or estimated glomerular filtration rate (eGFR), as well as a modified formula incorporating an additional constant (α). Performance was assessed by the proportion of subjects achieving target area under the curve (AUC) attainment (4–6 mg·min/mL), underexposure (<4 mg·min/mL), and overexposure (≥7 mg·min/mL). All AUC metrics were derived from model-based predictions rather than measured carboplatin concentrations, and no clinical toxicities or efficacy outcomes were used for validation. Results: Meta-analysis yielded fixed-effect parameter estimates (CL: 131.8 mL/min, V₁: 15.39 L, K₁₂: 0.002 min⁻¹, and K₂₁: 0.003 min⁻¹) with a random effect model. The conventional CrCL-based formula yielded 66.0% target attainment, 22.1% underexposure, and 4.5% overexposure. Switching to eGFR improved attainment to 88.3%, reduced underexposure to 5.8%, and lowered overexposure to 0.65%. A modified formula with α = 1 further decreased underexposure (4.5%) while target attainment and overexposure remained unchanged. Conclusions: Replacing CrCL with Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI)-derived eGFR in the Calvert formula markedly improved dosing accuracy, while modest structural modification offered additional benefit. The incremental benefit of α = 1 should be considered hypothesis-generating and requires prospective validation with measured carboplatin concentrations and clinical outcomes before applying it in practice. These findings support adopting eGFR-based dosing in breast cancer and suggest the need for future clinical validation. Full article

The growing consumer trend toward plant-based diets is prompting the food industry to seek alternatives to animal protein. Chickpea protein (CPP) stands out for its high protein content (14.9–24.6%) and represents a sustainable alternative. Therefore, this study evaluated and compared the techno-functional performance of CPP and whey protein isolate (WPI), with a focus on their emulsifying capabilities for plant-based food development. CPP was extracted via alkaline extraction and isoelectric precipitation. The techno-functional properties were evaluated, including solubility index (%), foaming capacity (%), emulsion activity index (EAI), gelling, and interfacial properties. Additionally, CPP was used as an emulsifier in plant-based emulsions, and the emulsion stability was compared with WPI for two months. Although CPP exhibited a lower solubility index (60 ± 1.0%) than WPI (95 ± 0.3%), its foaming capacity was identical (CPP: 57 ± 6%; WPI: 58 ± 4%) and exhibited a significantly higher emulsion activity index (22 ± 0.3 m²/g) than WPI (15 ± 0.8 m²/g). In terms of gelation, WPI formed stronger gels (1.2–2.1 N) than CPP (0.05–0.06 N), at the same concentrations. Interfacial tension measurements showed that, while CPP exhibited a higher interfacial saturation concentration (0.055 g/L vs. 0.023 g/L), it was more effective at reducing equilibrium interfacial tension than WPI. Finally, emulsion stability over two months was similar when using CPP or WPI as emulsifiers. CPP demonstrates a competitive functional profile; however, its implementation as a sustainable ingredient will require physical or chemical modifications to improve its functional properties for complex food matrices. Full article

Background: Protein A resins are indispensable for monoclonal antibody (mAb) production, yet their condition and performance are traditionally assessed using indirect or qualitative methods. In this study, the multi-attribute method (MAM), previously applied to therapeutic protein characterization, is systematically adapted for the first time as a unified liquid chromatography–mass spectrometry (LC-MS) platform for Protein A resin analysis. Method: Four Cytiva Protein A resins, MabSelect™, MabSelect SuRe™, MabSelect SuRe™ LX, and MabSelect™ PrismA, were evaluated by MAM for resin identity, Protein A ligand integrity, fouling by impurities, and cleaning performance. Results: MAM enables resin-specific peptide fingerprinting and quantitative monitoring of Protein A ligand post-translational modifications (PTMs), including deamidation, isomerization, and fragmentation induced by repeated clean-in-place (CIP) cycles. Comparative analysis of virgin and used resins revealed ligand degradation and fouling despite engineered alkaline stability, with MabSelect™ showing the greatest susceptibility. Importantly, residual monoclonal antibodies (mAbs) and host cell proteins (HCPs) were directly detected and quantified from the resin matrix, providing a molecular-level assessment of resin cleaning effectiveness not achievable with conventional approaches. Conclusions: This work establishes MAM as a novel, sensitive, and comprehensive strategy for Protein A resin lifecycle management, delivering actionable insight for resin selection, cleaning optimization, and downstream process development. Full article

Aqueous zinc-ion batteries (AZIBs) are promising for large-scale grid storage due to inherent safety, low cost, environmental compatibility, high theoretical capacity (820 mAhg⁻¹), and suitable redox potential (−0.763 V vs. SHE). However, practical deployment is hindered by coupled challenges at the zinc anode–hydrogen evolution, dendrite growth, and corrosion/passivation, which severely limit cycle life and coulombic efficiency. This review systematically summarizes key advances in AZIB research. It first elucidates working principles and four cathode energy storage mechanisms: Zn²⁺ insertion/extraction, H⁺/Zn²⁺ co-insertion, chemical conversion, and dissolution/deposition. Second, it examines four mainstream cathodes (manganese-based, vanadium-based, Prussian blue analogs, and organic compounds), analyzing performance bottlenecks and corresponding optimization via structural modification. Third, it explores functional mechanisms of advanced separators (polymer, inorganic/ceramic composite, MOF-based, and cellulose-based) in regulating uniform Zn²⁺ deposition and suppressing dendrites. Fourth, it summarizes anode optimization strategies: artificial protective layers for interface stabilization, electrolyte additives to modulate Zn²⁺ solvation/deposition, and 3D porous structures to reduce local current density and provide nucleation sites. Finally, key scientific challenges and future directions are discussed—multi-strategy synergy, in situ characterization, practical battery construction, and sustainable technological development, offering theoretical guidance for advancing AZIBs toward large-scale applications. This review aims to provide a comprehensive perspective spanning from materials to systems, and from mechanisms to applications. Its core objective is not merely to list the types of cathode materials, but to establish a logical bridge directly connecting “key challenges” to “optimization strategies,” with a particular emphasis on the issues and solutions related to the cathode side. Full article

Methacrylate-POSS (M-POSS) is a novel organic–inorganic additive shown to reinforce dental composites and reduce polymerization shrinkage. This study aimed to evaluate the influence of M-POSS addition (0.5, 2, 10, or 15 wt.%) on the mechanical properties of an experimental polymer matrix (bis-GMA/UDMA/TEGDMA/HEMA = 35/35/20/10 wt.%) and a dental resin composite (45 wt.% silanized silica as filler). Vickers hardness (HV), three-point bending strength (FS), diametral tensile strength (DTS), and shrinkage stress generated during polymerization were studied. The results show HV values between 16 and 18 compared to 15 ± 1 in the control group. Hardness in the control composite was 34 ± 4, and after modification, it showed similar or slightly lower values between 32 and 35. FS increased from 90 ± 4 MPa before modification to 100 ± 5 MPa for 2 wt.% M-POSS, and then decreased to 78 ± 5 MPa for materials containing 15 wt.% M-POSS. FS of composites were within the range of 61–77 MPa, with a similar tendency in variation to that of matrices. DTS values decreased after M-POSS addition, from 37 ± 4 MPa before modification to 31–33 MPa after modification. Flexural modulus decreases after modification, both for matrices and composites. The morphology of composites with >10 wt. % M-POSS showed visible surface irregularities. In conclusion, M-POSS affects matrix hardness, resulting in an increase in HV. The addition of M-POSS also increases FS values of the matrix, but only up to a certain concentration. However, the introduction of M-POSS does not significantly affect the HV or bending strength of the composites. Although DTS values decreased, this change was not statistically significant. Finally, contraction stress was significantly reduced for groups containing 2 wt.% and 10 wt.% M-POSS, representing an anticipated and promising improvement. Full article

With the rapid development of electrified railways in high-altitude regions, section insulators in catenary systems frequently experience gap breakdown and surface flashover under low atmospheric pressure conditions, posing serious threats to safe train operation. This paper investigates the discharge mechanisms of section insulators in high-altitude environments and conducts research on discharge characteristics under extremely non-uniform electric fields, along with structural optimization. First, the physical mechanisms of gap discharge and surface flashover in section insulators are analyzed. A three-dimensional electric field simulation model of the section insulator is established, and numerical analysis is performed to reveal the electric field distribution characteristics. The results indicate that the electric field is predominantly concentrated at the junction between metal electrodes and insulators, as well as at the tip of the arcing horn. The local maximum field strength reaches 3.84 × 10⁵ V/m, exceeding the corona inception field strength of air, which readily induces discharge. Subsequently, power frequency and lightning impulse discharge tests are conducted in both plain region and regions at an altitude of 4300 m. The results show that under high-altitude conditions, the power frequency breakdown voltage decreases by 28%, and the 50% lightning impulse breakdown voltage decreases by 42%. The discharge voltages under standard atmospheric conditions are obtained through correction. Finally, optimization schemes involving arcing horn structural modification and surface coating application are proposed. Adjusting the arcing horn angle to 55° and adding a grading ring structure with a radius of 70 mm reduces the local maximum field strength by 26%. After applying an RTV insulating coating, the field strength at the junction decreases by 35.9%, effectively enhancing the insulation performance of section insulators in high-altitude regions. Full article