Search Results (3,937)

The durability of the carbon fiber-reinforced polymer (CFRP)–concrete interface is a critical indicator for assessing the service life of composite structures in cold regions. This study systematically investigates the normal bond behavior under coupled deicing salt and freeze–thaw cycles through single-sided salt-frost tests on 126 specimens. The influence of surface roughness, number of freeze–thaw cycles, concrete strength grade, and CFRP material type was systematically evaluated. The results demonstrate that bond behavior is positively correlated with surface roughness, with the f₂ interface exhibiting optimal performance and increasing the ultimate capacity by up to 76.61% compared to the smooth interface. CFRP cloth showed superior bond retention compared to CFRP plates, which experienced a bond strength loss rate up to 26.90% higher than cloth specimens after six cycles. A critical performance threshold was identified between six and eight cycles, where the failure mode transitioned from cohesive adhesive failure to brittle interfacial debonding. Concrete matrix strength had a negligible effect compared to the dominant environmental damage. A two-parameter prediction model based on cycle count and roughness was established with high accuracy. SEM analysis confirmed that epoxy resin cracking, fiber–matrix debonding, and microcrack propagation in the concrete surface layer were the fundamental causes of macroscopic mechanical degradation. These findings provide a theoretical foundation for optimizing interface treatment and predicting the structural integrity of CFRP-strengthened systems in salt-frost regions. Full article

Photobioreactor-based microalgae cultivation offers an integrated approach for nutrient-rich wastewater treatment while producing valuable biomass. One of the main microalgae components is proteins, making them a biotechnological target. In this work, to develop efficient and greener extraction methodologies, aqueous two-phase systems (ATPSs) based on natural deep eutectic solvents (NADESs) were evaluated for one-step protein extraction from microalgae cultivated in swine wastewater. Six ATPSs combining two NADES—betaine:levulinic acid (Bet:2LA) and choline chloride:urea (ChCl:2Urea)—and their individual components (Bet or ChCl) with phosphate salts were compared. Systems {NADES + K₃PO₄ + water} were characterized and reported for the first time. Protein recovery yield (PRY) and selectivity (protein-to-carbohydrate mass ratio, R) were assessed for three extraction times and at room temperature. The ATPS {Bet:2LA + K₃PO₄ + H₂O} achieved a PRY of 16.4% and remarkable selectivity after 30 min (R = 2.17 g·g⁻¹), with proteins concentrated in the NADES-rich phase, and negligible recovery in the salt-rich phase. Although the maximum PRY (18.2% at 120 min) was achieved with the precursor betaine, the ATPS with Bet:2LA at 30 min offered an optimal balance between efficiency and process time. With a water content of up to 50%, these systems underscore the potential of NADES-based ATPSs as sustainable platforms for protein recovery. Full article

Synthetic gypsum (SG) is produced in massive quantities, yet hazardous impurities limit its reuse. This review summarized the impurity types in various SGs and the corresponding removal methods. Physical methods, such as washing, screening, magnetic separation, and others, exploit solubility and size/density differences to remove soluble salts and particulates. Chemical methods, including acid leaching, precipitation/solidification, and so on, can dissolve or immobilize phosphates, fluorides, and heavy metals. Flotation utilizes the differences in the physicochemical properties of solid surfaces to remove insoluble impurities. The thermal treatment is mainly used to decompose organics and improve whiteness. Microbial methods achieve environmentally friendly cleanup through metabolic leaching or microbially induced carbonate precipitation. The phase-transformation method is a recently developed method that can achieve synergistic effects of deep impurity removal and high-value utilization by reconstructing gypsum crystals to release co-crystallized impurities. Most impurity-removal methods target only a single type of impurity. At present, purifying SG requires a combination of multiple methods, which is not recommended from a cost perspective. Subsequent research on removing impurities from SG should focus on simultaneously removing multiple major impurities in a single process, as well as the synergistic effects between impurity removal and the high-value utilization of gypsum. Full article

Although salt acclimation is a recognized strategy for improving crop salt tolerance, its specific role in tomato (Solanum lycopersicum L.) remains unclear. This study investigated the effects of salt acclimation on enhancing salt tolerance in tomato seedlings through physiological and transcriptomic analyses. Here, we found that T3 acclimation treatment (irrigation with 14 mL of 7.5 g L⁻¹ NaCl solution per plant) effectively conferred enhanced salt tolerance in tomato seedlings, with plant height, stem diameter, leaf area, chlorophyll content, net photosynthetic rate, and soluble protein content increasing by 4.52, 5.13, 3.16, 10.78, 11.85, and 25.96%, respectively, compared with the control. T3 treatment also reduced oxidative damage and ionic stress, as evidenced by reduced electrolyte leakage, lower malondialdehyde content, and a decreased root Na⁺/K⁺ ratio, while simultaneously boosting antioxidant enzyme activities. Membership function analysis confirmed T3 as the optimal treatment, with a 9 d duration consistently benefiting multiple cultivars. Transcriptomic analysis revealed that salt acclimation upregulated genes associated with phenylpropanoid biosynthesis, lignin catabolic process, and peroxidase activity, suggesting that these pathways might mediate acclimation-induced salt tolerance through promoting lignin biosynthesis to reduce Na⁺/K⁺ ratio and enhancing reactive oxygen species’ scavenging capacity to maintain cellular homeostasis. Our results indicate that tomato seedlings acclimated with 14 mL of 7.5 g L⁻¹ NaCl solution per plant for 9 d significantly improves salt tolerance through coordinated physiological adjustments and transcriptional reprogramming. Full article

Background: Cultivated strawberry (Fragaria × ananassa) is one of the most valuable horticultural crops worldwide. Nevertheless, its productivity is increasingly constrained by high susceptibility to adverse environmental conditions, which are intensified by climate change. Drought represents a major limitation, often accompanied by water deficiency and elevated soil salinity. Plants counteract such abiotic stresses through complex molecular defense mechanisms involving transcription factors that regulate stress-responsive gene expression. Methods: In this study, we conducted a systematic bioinformatic analysis of the Tubby-like protein (TLP) transcription factor family in Fragaria × ananassa. RT-qPCR was used to analyze the expression patterns of FaTLP genes under different conditions to elucidate their potential roles in stress adaptation. Results: Eight FaTLP genes were identified in each of the four subgenomes, most of which retained the characteristic TUBBY and F-box domains. Gene expression profiling revealed that several FaTLP genes were differentially expressed in leaves under drought and salt stress, with FaTLP2 and FaTLP7 exhibiting strong induction. In addition, the expression of FaTLP2 and FaTLP7 under various oxidative and signaling-related treatments, as well as in different tissues of strawberry plants were analyzed. Promoter analysis identified multiple cis-regulatory elements associated with phytohormone signaling and abiotic stress responses, such as ABRE, MYB, and MYC motifs. Phylogenetic analysis showed that FaTLP2 and FaTLP7 share high sequence similarity with orthologous TLPs from other plant species known for enhanced stress tolerance, suggesting that these proteins may play conserved roles in the molecular mechanisms underlying drought and salinity resilience. Conclusions: This study provides valuable insights into the potential roles of FaTLPs in regulating environmental signal transduction and transcriptional control, contributing to abiotic stress tolerance in Fragaria × ananassa. Full article

Background/Objectives: The increasing problem of excess body weight and the resulting dyslipidemia among children and adolescents is a serious health challenge that may have long-term consequences. In this context, the search continues for an optimal diet that will support both body weight normalization and improvement in lipid parameters. In the prevention and treatment of cardiovascular diseases and lipid disorders, limiting highly processed foods and replacing them with natural, minimally processed options lower in fat, saturated fatty acids (SFA), cholesterol, sugar, and salt is recommended. This study aimed to assess the quality and nutritional value of the low-glycemic index (LGI) diet and standard (ST) diet. Methods: Both diets were based on the principal recommendation of the Cardiovascular Health Integrated Lifestyle Diet-2 (CHILD-2). The Diet Quality Index (DQI) was used to assess the diet quality. Moreover, the nutritional value of the diet was assessed before and after 8 weeks of intervention. The study included 40 patients aged 8–16 years with excess body weight and dyslipidemia who completed the entire nutritional intervention. Results: This study demonstrated that both LGI and ST diets were effective in improving diet quality. The nutritional intervention led to an almost 2-fold reduction in the mean DQI score in the LGI diet group and almost 1.5-fold reduction in the ST diet group (significant differences between groups). No participants were classified into a lower diet quality category than at baseline. The percentage of participants with minimum moderate diet quality reached 100% in the LGI diet group and 44% in the ST diet group. Changes in nutritional value were similar in the LGI and ST diet groups. Both interventions resulted in a significant increase in protein and fiber consumption, as well as a decrease in cholesterol, SFA, and sodium. A greater improvement in diet quality was significantly associated with lower fat and SFA, as well as higher vitamin C intake, in both groups; specifically, it was also associated with reduced cholesterol and sugar intake in the LGI diet group, and reduced sodium intake in the ST diet group. Conclusions: These results suggest that in the dietary therapy of children and adolescents with excess body weight and dyslipidemia, the quality of the diet is crucial, as it is associated with beneficial changes in nutritional value, which may have a positive impact on patient health. To achieve this, however, constant and consistent cooperation with a dietitian is necessary to help implement appropriate dietary recommendations in practice. Further long-term, larger-scale studies are needed. Full article

Gitelman syndrome (GS) is a rare, autosomal recessive salt-losing tubulopathy caused by mutations in the SLC12A3 gene. It involves dysfunction of the sodium-chloride cotransporter positioned on the apical membranes of the distal convoluted tubule cells, causing sodium shortage and mimicking the use of thiazide diuretics. Hyperaldosteronism secondary to sodium depletion and hypovolemia causes hypokalaemia and metabolic alkalosis. This is associated with inhibition of the Transient Receptor Potential Cation Channel, Subfamily M, Member 6 –TRPM6 channel, which leads to urinary magnesium leakage and hypomagnesemia, subsequently stopping PTH secretion and resulting in hypocalcemia and hypocalciuria. Gitelman syndrome frequently presents later in life, as the symptoms are usually not very threatening. However, early identification, diagnosis, and urgent intervention are essential to improve patient prognosis and quality of life. Importantly, both hypomagnesemia and hypokalaemia can impair insulin secretion and sensitivity. Furthermore, hyperaldosteronism caused by the secondary activation of the R-A-A system can also lead to these disorders. Glucose metabolism problems have been shown to prevail amongst GS patients and manifest more frequently in comparison to the general population. When it comes to the treatment used to reduce hyperglycemia in GS-related T2DM, we consider which of the available drugs are the best for those patients. The article analyses the association of Gitelman syndrome with diabetes mellitus based on the available medical literature—as there are no clinical trials or meta-analyses available for this group, it is presented as a narrative review. Full article

Soil salinization and alkalinization critically constrain alfalfa (Medicago sativa L.) productivity, yet the regulatory mechanisms underlying its responses to salt–alkali stress are not fully understood. In this study, the alfalfa variety “Zhongmu No. 1” was used as experimental material. The seeds were subjected to salt stress (75 mM NaCl), alkali stress (15 mM NaHCO₃), and combined salt–alkali stress (50 mM NaCl + 5 mM NaHCO₃) in dishes, with ddH₂O serving as the control (CK). After 7 days of germination, the seedlings were transferred to a hydroponic system containing Hoagland nutrient solution supplemented with the corresponding treatments. Following 32 days of stress exposure, leaf and root tissue samples were collected for morphological and physiological measurements, as well as mRNA and miRNA sequencing analyses. Physiological assays revealed significant growth inhibition and increased electrolyte leakage under stress conditions. Transcriptome profiling identified over 5000 common differentially expressed genes (DEGs) in both leaves and roots under stress conditions, mainly enriched in pathways related to “iron ion binding”, “flavonoid biosynthesis”, “MAPK signaling”, and “alpha-Linolenic acid metabolism”. MiRNA sequencing detected 453 miRNAs, including 188 novel candidates, with several differentially expressed miRNAs (DEMs) exhibiting tissue- and stress-specific patterns. Integrated analysis revealed 147, 81, and 140 negatively correlated miRNA–mRNA pairs across three treatment groups, highlighting key regulatory modules in hormone signaling and metabolic pathways. Notably, in the ethylene and abscisic acid signaling pathways, ERF (XLOC_006645) and PP2C (MsG0180000476.01) were found to be regulated by miR5255 and miR172c, respectively, suggesting a post-transcriptional layer of hormonal control. DEM target genes enrichment pathway analyses also identified stress-specific regulation of “Fatty acid degradation”, “Galactose metabolism”, and “Fructose and mannose metabolism”. qRT-PCR validation confirmed the expression trends of selected DEGs and DEMs. Collectively, these findings reveal the complexity of miRNA–mRNA regulatory networks in alfalfa’s response to salt–alkali stress and provide candidate regulators for breeding stress-resilient cultivars. Full article

Salt stress is one of the main abiotic stresses that restrict crop production. Melatonin (MT), a signal molecule widely present in plants, plays an important role in regulating abiotic stress response. In this study, celery seedlings were used as experimental materials, and the control, salt stress, and exogenous MT treatment groups under salt stress were set up. Through phenotypic, physiological index determination, transcriptome sequencing, and expression analysis, the alleviation effects of MT on salt stress were comprehensively investigated. The results showed that exogenous MT treatment significantly reduced seedling growth inhibition caused by salt stress. Physiological measurements showed that MT significantly reduced malondialdehyde content, increased the activities of superoxide dismutase (SOD), peroxidase (POD) and catalase (CAT), promoted the accumulation of free proline and soluble protein, and increased photosynthetic parameters such as chlorophyll, ΦPSII, Fv/Fm, and ETR. Transcriptome analysis showed that MT regulates the expression of several genes associated with carbon metabolism, including β-amylase gene (AgBAM), sucrose-degrading enzyme genes (AgSUS, AgINV), and glucose synthesis-related genes (AgAG, AgEGLC, AgBGLU). The results of qRT-PCR verification were highly consistent with the transcriptome sequencing data, revealing that MT synergistically regulates starch and sucrose metabolic pathways, and effectively alleviates the damage of celery seedlings under salt stress at the molecular level. In summary, exogenous MT significantly improved the salt tolerance of celery by enhancing antioxidant capacity, maintaining photosynthetic function, promoting the accumulation of osmotic adjustment substances, and synergistically regulating carbon metabolism-related pathways. The concentration of 200 μM was identified as optimal, based on its most pronounced alleviating effects across the physiological parameters measured. This study provides an important theoretical basis for utilizing MT to enhance plant salt resistance. Full article

Background/Objectives: Alopecia areata (AA) and psoriasis are immune-mediated diseases that can coexist, suggesting shared pathogenic mechanisms. While Janus kinase inhibitors (JAKi) are approved for AA treatment, their role in managing concomitant psoriasis and psoriatic arthritis (PsA) remains unclear. This study evaluates the efficacy and safety of baricitinib in patients with severe AA and coexisting psoriasis and/or PsA. Materials and Methods: A retrospective case series of five patients (mean age 53.2 years) with severe AA (SALT > 80) or alopecia universalis (AU) and concomitant psoriasis (n = 2) and/or PsA (n = 3) was conducted in the Dermatology Unit of Policlinico of Tor Vergata, Catholic University of the Sacred Heart and La Sapienza University of Rome, Italy. Patients received baricitinib 4 mg/day and were assessed at weeks 4, 24, and 52 using SALT, PASI, and pVAS scores. Results: At week 52, one patient achieved complete AA remission, while two improved to SALT < 20 (mean SALT 83 to 8.75). Psoriasis remained stable (mean PASI 1.4 to 0.5). However, one PsA patient worsened (pVAS 9) and discontinued the treatment. Conclusions: Baricitinib was effective for AA, with potential benefits for psoriasis, but it may not be optimal for PsA. Further studies are needed to define its role in multiple immune diseases. Full article

Targeted synthesis of Ni/C-containing composite materials was carried out using the matrix isolation method. The Ni content was varied (5–20 wt.% from chitosan). The morphology and physicochemical properties of the obtained materials were characterized using a number of methods: elemental analysis, SEM, TEM, XRD, FTIR, Raman spectroscopy, TPR–H₂, and SSA. FTIR showed that nickel ions are immobilized on the chitosan molecule, and heat treatment of the polymer molecule results in the formation of polyconjugation centers. It was also revealed that heat treatment of the salt–polymer films results in the formation of a graphite-like structure (Raman spectroscopy) with the inclusion of nickel in metallic form (XRD, TPR–H₂), with a particle size from 2 to 10 nm (TEM). The composites were shown to have a SSA of up to 269 m²/g. The resulting composite materials were used as catalysts for the decomposition of methane to produce hydrogen. High activity was observed in the catalytic methane decomposition at 700 °C (methane conversion up to 25.8%; hydrogen yield up to 1.98 g_H2/g_Ni/h). Full article

Identifying plant-growth-promoting rhizobacteria tolerant to saline–alkali conditions is critical for developing effective microbial agents and multi-strategy approaches to remediate saline–alkali soil. Two salt–alkali-tolerant bacterial strains—phosphorus-solubilizing Bacillus pumilus JL-C and cellulose-decomposing B. halotolerans XW-3—were isolated from saline–alkali soil, with both exhibiting multiple plant-growth-promoting properties, including nitrogen fixation and the generation of indole-3-acetic acid, siderophores, and 1-aminocyclopropane-1-carboxylate deaminase. Alfalfa pot experiments were conducted under four treatments: a control, the strain JL-C treatment, the strain XW-3 treatment, and a co-inoculation treatment (JL-C/XW-3), all mixed with corn straw and applied to the saline–alkali soil. The results demonstrated that the co-inoculation treatment yielded the most significant growth-promoting effects on alfalfa, showing enhanced antioxidant enzyme activities; increased contents of proline, soluble sugar, and protein; reduced malondialdehyde content; lowered pH and electrical conductivity; elevated activities of key enzymes; and increased levels of available nitrogen, phosphorus, potassium, and organic matter content in the soil. The pot experiments were confirmed by field experiments. The results of 16S rRNA high-throughput sequencing revealed changes in the bacterial community composition in the alfalfa rhizosphere, showing shifts in the relative abundance of several bacterial taxa often reported as plant-associated or potentially beneficial. This study establishes a combined remediation strategy for saline–alkali soil utilizing complex microbial agents and corn straw. Full article

Soil salinization is a major threat to agricultural sustainability. Poly-gamma-glutamic acid (γ-PGA), a biopolymer produced by microbial fermentation, has received attention as a biostimulant due to its positive effects on crop performance. However, the function of γ-PGA in crop salt stress tolerance and its effect on the rhizosphere are unclear. This study explores the effects of γ-PGA application on rhizosphere soil nutrients and the soil–physical environment and examines the salt tolerance response of maize seedlings grown in saline–alkali soil under such an application regime. The results show a significant promotion of maize seedling growth and of nutrient accumulation with γ-PGA application under salt stress; plant dry weight, stem diameter, and plant height increased 121%, 39.5%, 18.4%, respectively, and shoot accumulation of nitrogen, phosphorus, potassium, and carbon increased by 1.38, 2.11, 1.50, and 1.36 times, respectively, under an optimal-concentration γ-PGA treatment (5.34 mg kg⁻¹ (12 kg ha⁻¹)) compared with the control. γ-PGA treatment significantly decreased rhizospheric pH and soil electrical conductivity and significantly increased nutrient availability in the rhizosphere, especially available nitrogen (AN) and available potassium (AK). Compared with the control, AN, available phosphorus (AP), and AK increased by 13.9%, 7.70%, and 17.7%, respectively, under an optimal concentration treatment with γ-PGA. γ-PGA application also significantly increased the activities of urease, acid phosphatase, alkaline phosphatase, dehydrogenase, and cellulose in rhizosphere soil by 35.5–39.3%, 35.4–39.3%, 5.59–8.85%, 18.9–19.8%, and 19.2–47.0%, respectively. γ-PGA application significantly decreased Na⁺ concentration and increased K⁺ concentration in shoots, resulting in a lowering of the Na⁺/K⁺ ratio by 30.5% and an increase in soluble sugar and soluble protein contents. Therefore, rhizosphere application of water-soluble and biodegradable γ-PGA facilitates the creation of an optimized rhizospheric environment for maize seedling and overcomes osmotic and ionic stresses, offering possibilities for future use in drip-irrigation systems in the cultivation of crops on saline-alkali land. Full article

Background/Objectives: Calcinosis cutis universalis is a rare and severe manifestation of dystrophic calcification, most associated with connective tissue diseases such as dermatomyositis, systemic sclerosis, and systemic lupus erythematosus. It is characterized by widespread deposition of calcium salts throughout the soft tissues, leading to pain, recurrent infections, restricted mobility, and significant impairment in daily functioning and quality of life. Management remains challenging due to the absence of standardized treatment guidelines with risks including delayed wound healing and recurrence. Adjunctive therapies may support symptom control in refractory cases. Conclusions: Management of calcinosis cutis universalis requires an individualized, multimodal strategy. Based on available evidence and expert opinion, a stepwise therapeutic decision-making algorithm integrating medical, minimally invasive, and surgical approaches is proposed to guide clinical practice and the variable efficacy of available therapies. This review aims to summarize current therapeutic strategies and to propose a pragmatic approach to clinical decision-making. Methods: A narrative review of the literature was conducted using PubMed and Google Scholar. The review focused primarily on calcinosis cutis universalis and severe or extensive forms of calcinosis cutis, with particular emphasis on surgical management and its integration with medical and minimally invasive treatments. Results: Pharmacological treatments—including bisphosphonates, calcium-channel blockers, tetracyclines, phosphate binders, probenecid, immunomodulatory agents, biologics, colchicine, sodium thiosulfate and JAK inhibitors—show heterogeneous and often partial efficacy, with more favorable responses in early or localized disease. Surgical interventions such as excision, curettage, CO₂ laser ablation, and reconstructive procedures provide meaningful symptomatic relief in selected patients but are associated. Full article

Pre-sowing seed treatment (priming) is a strategic tool for programming future crop yield, aimed at improving early plant development and enhancing stress resilience. This study investigated the effects of priming wheat seeds with 100 µM ibuprofen on early ontogeny under optimal conditions and salt stress (100 mM NaCl). An evaluation of germination energy, growth parameters, phytohormone levels (abscisic acid, indolylacetic acid, and cytokinins) and the status of the antioxidant system in 7-day-old seedlings demonstrated that ibuprofen treatment stimulates wheat growth and tolerance, despite its absence of accumulation in plant tissues. Modulation of hormonal balance plays a key role in these protective effects: under optimal conditions, ibuprofen elevates abscisic acid and indolylacetic acid levels, while under salt stress, it prevents excessive abscisic acid accumulation and mitigates the stress-induced decline in indolylacetic acid and cytokinins. Furthermore, ibuprofen promotes a coordinated increase in glutathione, ascorbate, and H₂O₂ levels, concomitant with the activation of key enzymes (glutathione reductase and ascorbate peroxidase), thereby enhancing the plants’ antioxidant potential. Under saline conditions, ibuprofen pretreatment also reduces stress-induced dysregulation of this system. Therefore, ibuprofen acts as a hormetic preconditioning agent that improves seedling vigor and stress tolerance by fine-tuning hormonal signaling and redox metabolism. Full article