Search Results (24,126)

Bioactive glasses remain promising candidates for enhancing osseointegration on metallic implants. However, achieving a composition that combines controlled dissolution, cytocompatibility, and antimicrobial functionality remains an ongoing challenge. Building upon the prior structural and thermal characterization of boron-substituted 6P55 phosphosilicate glasses, this study investigates the biological consequences of incorporating 0, 5, 10, and 15 mol% B₂O₃ to determine their suitability as coatings for Ti6Al4V. Glass extracts were evaluated using L-929 fibroblast cultures (MTT assay and ImageJ-based cell counting), antimicrobial assays against Escherichia coli and Staphylococcus aureus using a semi-quantitative dilution-plating method, and SBF immersion studies to assess pH evolution, surface mineralization, and Ca/P ratio development. FTIR and SEM analyses revealed composition-dependent formation of phosphate-, carbonate-, and silicate-rich surface layers, with 5B exhibiting the most consistent early-stage hydroxyapatite-like signatures, supported by Ca/P ratios approaching the stoichiometric value. The pH measurements showed rapid alkalization for 5B and moderate buffering behavior at higher boron contents, consistent with boron-dependent modifications to network connectivity. Cytocompatibility studies demonstrated a dose- and time-dependent reduction in cell number at elevated B₂O₃ levels, whereas the 0B and 5B extracts maintained higher viability and preserved cell morphology. Antibacterial assays revealed strain-dependent and sub-lethal inhibitory effects, with E. coli exhibiting stronger sensitivity than S. aureus, likely due to differences in cell wall architecture and susceptibility to ionic osmotic microenvironment changes. When considered alongside previously published computational and physicochemical results, the biological data indicate that moderate boron incorporation (5 mol%) provides the most favorable balance between dissolution kinetics, apatite formation, cytocompatibility, and antimicrobial modulation. These findings identify the 5B composition as a strong candidate for further optimization toward bioactive glass coatings on Ti6Al4V implants. Full article

Background/Objectives: Traditionally consumed fermented foods and lactic acid bacteria (LAB)-based products have primarily been investigated for their nutritional and health-promoting benefits as dietary supplements. More recently, research has advanced toward exploring their therapeutic potential in pharmaceutical development. However, reliance on conventional LAB strains despite their established safety and efficacy has led to saturation at the strain level, underscoring the need for next-generation probiotics (NGPs) with novel therapeutic potential. In this context, we identified Flavonifractor plautii from human feces as a candidate NGP and investigated its effects on the human gut microbiota. Methods: Whole-genome sequencing revealed distinct genetic features that supported its uniqueness, and the strain was designated PMC93. A human gut microbial ecosystem simulator was used to administer F. plautii daily for one week, after which microbial community changes were evaluated using 16S rRNA gene-based metagenomic sequencing. Results: The administration did not induce significant changes in alpha or beta diversity, suggesting that F. plautii does not disrupt overall bacterial community structure, thereby supporting its microbial community safety. Taxonomic analysis demonstrated a significant increase in the Firmicutes-to-Proteobacteria ratio (NGP F/P index). The improvement surpassed that of conventional LAB treatments and was consistently maintained under supplementation with commonly encountered pharmaceutical compounds and nutrients. The shift was associated with an increase in short-chain fatty acid (SCFA)-producing beneficial taxa and a decrease in pro-inflammatory and potentially pathogenic groups. Functional outcomes, including elevated SCFA levels and downregulation of inflammation-related gene expression, further corroborated these compositional changes. The strain also demonstrated safety in in vivo models. Conclusions: Collectively, these findings suggest that strain PMC93 is a promising NGP candidate with substantial therapeutic potential for microbiota-associated health and disease modulation, particularly due to its ability to enhance the NGP F/P index. Full article

Essential oils (EOs) are volatile, aromatic, and hydrophobic extracts of plant origin, known for their complex chemical composition, which often includes over 300 natural molecules with low molecular weights. They are extracted from various plant organs through physical–mechanical processes or dry distillation, and their qualitative composition and quantity change depending on the species, cultivar, and environmental growth conditions. They play a key role in plants’ response to abiotic stresses, such as drought and salinity, whose effects are intensified by climate change. Several studies showed that drought and salinity can increase or decrease EO production, depending not only on the plant species but also on the severity of the stress; in fact, in many crops an enhancement of EO synthesis was often observed under mild stress, whereas moderate or severe stress reduced production. For a few years, EOs have been considered important biostimulants and bioprotectors, capable of replacing chemical pesticides in sustainable agriculture. Consequently, seed pre-treatments (e.g., seed priming or seed coating) with EOs may represent promising tools to improve germination, stress tolerance, and crop productivity under stress conditions. Nevertheless, the high costs of extraction of EOs and the little evidence collected from field experiments still limit their use in agronomic applications. The aim of this review was to gather the most important information, published over the last ten years, concerning the effects of drought and salinity on the production of EOs and their use as biostimulants. This review critically examines the available literature, highlighting a positive perspective towards the adoption of natural approaches to reduce the environmental impact of agricultural production. Current results indicate encouraging progress in the application of EOs as biostimulants; however, further studies are needed to verify their effectiveness in real agronomic environments. Full article

Donkey milk is increasingly recognized as a functional food due to its unique nutritional profile and richness in bioactive compounds. This longitudinal observational study investigated changes in both chemical composition (total solids, protein, fat, lactose, and ash) and immune-active proteins (lactoferrin, α-lactalbumin, β-lactoglobulin, and lysozyme) across lactation. A total of 153 donkey milk samples were collected from five farms from very early (1–3 days in milk) to late lactation (30–210 days in milk). Chemical composition was determined using mid-infrared spectroscopy, while the concentrations of the immune-active proteins were determined by ELISA Quantitative Sandwich. Chemical analysis showed high values in colostrum, including total solids (10.13%), protein (3.1%), and ash (0.73%), which declined progressively during lactation to 8.45%, 1.14%, and 0.64%, respectively. Fat varied modestly, between 0.55 and 0.25%, while lactose remained stable at 5.75–6.41%. In parallel, bioactive proteins measured between 31 and 210 days exhibited distinct trajectories. Lactoferrin increased from 0.07 to 0.14 mg/mL, α-lactalbumin peaked mid-lactation at 2.58 mg/mL (compared with 1.91 mg/mL early and 2.25 mg/mL late), β-lactoglobulin declined from 0.84 to 0.55 mg/mL, and lysozyme decreased from 0.95 mg/mL early to 0.64 mg/mL late. Across lactation, we observed dilution of total solids and protein, relatively stable lactose and fat, and distinct trajectories of lactoferrin, α-lactalbumin, β-lactoglobulin, and lysozyme, indicating that donkey milk modulates rather than loses its protective protein profile. These results refine reference values for donkey milk and support its nutraceutical relevance for human nutrition and health. Full article

Cardiovascular disease remains the world’s leading cause of death globally, and there is continuing interest in adjunct, diet-based strategies that may support vascular health alongside guideline-directed pharmacotherapy. Anthocyanin-rich berries are one such option: they are widely consumed, generally safe, and can provide substantial amounts of polyphenols in habitual diets. This narrative review focuses on two anthocyanin-rich species, blueberries (Vaccinium spp.) and haskap/blue honeysuckle (Lonicera caerulea L.), and examines the extent to which their intake may influence vascular endothelial function and cardiometabolic risk markers. For blueberries, which are typically dominated by malvidin- and delphinidin-based anthocyanins together with flavonols, phenolic acids and stilbenes such as pterostilbene, randomized controlled trials and meta-analyses have reported improvements in flow-mediated dilation, with modest effects on blood pressure and arterial stiffness in at-risk populations. Haskap berries, characterized by high levels of cyanidin-3-O-glucoside (C3G) and enriched in iridoids and vitamin C, have been studied mainly in cell and animal models, with early human data suggesting potential effects on vascular function, blood pressure and physical performance. Across both berries, emerging evidence indicates that vascular actions are mediated largely by gut- and host-derived phenolic metabolites rather than by transient circulating parent anthocyanins. We synthesize current knowledge on the phytochemical composition of blueberries and haskap, on molecular pathways implicated in endothelial protection (including NO/eNOS signaling, NRF2-mediated antioxidant defense, NF-κB-driven inflammation, lipoprotein metabolism and platelet activation), and on clinical outcomes related to vascular and cardiometabolic health. On this basis, we outline a mechanistic hypothesis that combined blueberry–haskap interventions could provide additive or synergistic effects on vascular function. This hypothesis is currently supported primarily by preclinical and indirect clinical evidence and should be regarded as hypothesis-generating, highlighting priorities for future mechanism-aware trials rather than constituting a practice-changing recommendation. Full article

Bone is a structurally complex and dynamic tissue that plays a crucial role in mobility and skeletal stability. However, conditions such as osteoporosis, osteoarthritis, trauma-induced fractures, infections, and malignancies often necessitate the use of orthopedic and dental implants. Despite significant progress in implant biomaterials, challenges such as bacterial infection, inflammation, and loosening continue to compromise implant longevity, frequently leading to revision surgeries and extended recovery times. Smart coatings have emerged as a next-generation solution to these problems by providing on-demand, localized therapeutic responses to microenvironmental changes around implants and promoting bone regeneration. Such coatings can minimize antibiotic resistance by enabling controlled, stimulus-triggered drug release. Although the idea of using pH-sensitivity as a tool to make smart coatings is not a new thought, there are no options currently good enough to enter clinical studies. This review provides a comprehensive overview of recent advances in pH-sensitive polymers, hybrid composites, porous architectures, and bioactive linkers designed to dynamically respond to pathological pH variations at implant sites. By investigating the mechanisms of action, antibacterial and anti-inflammatory effects, and roles in bone regeneration, it is shown that the ability to provide time-dependent drug release for both short-term and long-term infections, as well as keeping the environment welcoming to the bone cell growth and replacement, is not an easy goal to reach, even with a fully biocompatable, non-toxic, and semi-biodegradable (one that releases the drug, but does not fade away) coating material compound. Reviewing all available options, including their functions and failures, finally, emerging trends, translational barriers, and future opportunities for clinical implementation are highlighted, underscoring the transformative potential of bioresponsive coatings in orthopedic and dental implant technologies. Full article

This study investigates the long-term service effects on Chinese fir (Cunninghamia lanceolata) components from ancient timber buildings in southern China. Anisotropic mechanical tests were performed to examine the evolution of mechanical properties from the perspectives of moisture absorption behavior, chemical composition, and microstructural characteristics. The results show that, after approximately 217 ± 12 years (Lvb specimens) and 481 ± 23 years (Xuc specimens) of service, the longitudinal compressive strength and corresponding elastic modulus of Chinese fir increased by about 11% and 15% and 33% and 71%, respectively, compared with fresh timber. The bending strength of the Lvb sample exhibited a slight reduction (approximately 6%), whereas the Xuc specimens showed the highest increase (33%). This difference is mainly attributed to long-term bending loads that caused structural damage in the Lvb beam specimens. In contrast, changes in lateral mechanical properties were negligible. Chemical composition analysis revealed an increase in extractive content and a reduction in cellulose and hemicellulose, leading to a notable rise in crystallinity. Scanning electron microscopy (SEM) observations further showed interlayer separation, wrinkling, and local collapse of the cell walls, suggesting significant cell wall densification. Overall, the evolution of mechanical properties is governed by the combined effects of increased crystallinity and microstructural densification, which together enhance the longitudinal and bending performance of aged timber with increasing service time. The findings provide a scientific basis for evaluating the performance and structural safety of aged timber components in the conservation of ancient timber buildings. Full article

The xerophyte medicinal species Crithmum maritimum was investigated for its physiological and antioxidant responses under increasing salinity stress and foliar biostimulant application. At moderate salinity (10 dS/m sodium chloride NaCl), plant growth and photosynthetic activity were enhanced, whereas high salinity (20 dS/m) led to significant reductions in biomass, photosynthetic efficiency, and water use efficiency. Salinity-induced oxidative stress was confirmed by elevated levels of malondialdehyde (MDA) and hydrogen peroxide (H₂O₂), in upper plant tissues. Foliar application of two bioactive compounds—Aquamin and Cultisano—partially mitigated the detrimental effects of high salinity. Treated plants maintained higher photosynthetic parameters and exhibited improved antioxidant profile compared to untreated controls. Furthermore, GC–MS analysis of essential oils revealed that salinity altered the composition of key volatile components, notably increasing γ-terpinene and reducing p-cymene content. Biostimulant treatments counteracted these changes, enhancing terpene components such as p-cymene, and thymol-methyl-ether. Overall, the findings highlight the potential of biostimulants to enhance both salt tolerance as well as the phytochemical value of C. maritimum, suggesting promising applications in sustainable agriculture and high-value plant product development under saline conditions. It was concluded that the type of biostimulant significantly influenced the physiological and quality characteristics of sea fennel plants. Further study on this topic is proposed, aiming at the improvement of antioxidant activity, which is beneficial to human health. Full article

Background/Objectives: There is no consensus regarding the impacts of supplementation with milk proteins (MPs) on body composition (BC). This systematic review and dose–response meta-analysis of randomized controlled trials (RCTs) assessed the effects of MP, casein protein (CP), and whey protein (WP) supplementation on BC and anthropometric parameters. Methods: A comprehensive search was performed in several databases to identify eligible RCTs published until October 2025. Random-effects models were applied to estimate the pooled effects of MP supplementation on anthropometric parameters. Results: A total of 150 RCTs were included. MP supplementation substantially increased lean body mass (LBM) (weighted mean difference (WMD): 0.41 kg; 95% CI: 0.19, 0.62; p < 0.001) and fat-free mass (FFM) (WMD: 0.67 kg; 95% CI: 0.40, 0.94; p < 0.001). It also significantly reduced body fat percentage (BFP) (WMD: −0.66%; 95% CI: −1.03, −0.28; p = 0.001), fat mass (FM) (WMD: −0.66 kg; 95% CI: −0.91, −0.41; p < 0.001), and waist circumference (WC) (WMD: −0.69 cm; 95% CI: −1.16, −0.22; p = 0.004). No considerable effects were observed for muscle mass (MM), body mass index (BMI), and body weight (BW). Dose–response analysis revealed that MP dosage was associated with significant changes in BFP, LBM, and MM. Conclusions: MP supplementation was associated with favorable modifications in body composition, including increases in LBM and FFM, as well as reductions in FM, BFP, and WC. These findings provide coherent and consistent evidence supporting the potential role of MP supplementation in targeted body composition management. Full article

Artemisia ludoviciana Nutt. is an important aromatic plant widely used in traditional Mexican medicine for its therapeutic potential. Its medicinal activity is attributed to a wide range of bioactive compounds, including flavonoids. However, overexploitation, habitat loss, climate change and plant diseases threaten its natural populations and diversity. Although the species reproduces both sexually and asexually, conventional propagation methods are often slow, limited by environmental factors, and susceptible to pests and pathogens. Therefore, this research aimed to establish a micropropagation protocol for A. ludoviciana and to evaluate the changes in its phenolic composition and antioxidant activity while adapting to ex vitro conditions. Full-strength Murashige and Skoog (MS) media supplemented with 0.1 mg L⁻¹ 6-benzylaminopurine resulted in the highest number of shoots (3.30 ± 0.34) and shoot length (3.00 ± 0.12 cm). Moreover, 1/2 MS media supplemented with 0.5 mg L⁻¹ indole-3-acetic acid improved the number (14.45 ± 0.56) and quality of roots. Hardening and acclimatization of plantlets showed 100% survival after 10 weeks. Also, the phenolic composition and antioxidant activity of A. ludoviciana changed in response to stress derived from growth conditions. The results support the sustainable use and rapid propagation of the species, as well as provide the basis for the study of secondary metabolism in the plant. Full article

Background/Objectives: Long COVID (LC) is characterized by persistent symptoms such as fatigue, pain, and reduced quality of life, often lasting months after acute infection. Exercise-based interventions have shown promise, but evidence for non-aerobic programs remains limited. This study aimed to evaluate the effects of a 12-week motor control exercise program on body composition and fatigue in women with LC and to explore associations with physical activity and psychosocial factors. Methods: An exploratory pre–post non-controlled intervention study was conducted in 17 women with LC symptoms persisting for over one year. Participants completed 24 individualized sessions of a non-aerobic therapeutic exercise program focused on trunk stabilization. Outcomes included body composition (bioimpedance analysis), fatigue (Modified Fatigue Impact Scale), health-related quality of life (EQ-5D-5L), physical activity (IPAQ), and kinesiophobia (TSK-11). Paired t-tests, effect sizes, correlations, and regression models were applied. Results: The intervention significantly reduced total body fat (37.09% to 35.41%, p < 0.001) and trunk fat (35.82% to 33.82%, p < 0.001), with large effect sizes. Physical and psychosocial fatigue improved markedly (MFIS physical: 29.71 to 21.06, p < 0.001; psychosocial: 6.00 to 4.29, p = 0.001), while cognitive fatigue showed non-significant change. Pain/discomfort scores decreased substantially (2.86 to 1.79, p < 0.001). Vigorous activity and walking time increased, and sedentary time decreased. No significant changes were observed in muscle mass or kinesiophobia. Conclusions: A structured, non-aerobic exercise program can effectively reduce body fat, alleviate fatigue, and improve pain perception in women with LC, supporting its role in rehabilitation. Multimodal strategies may be required to address cognitive symptoms and fear of movement. Full article

Energy optimization is crucial for unmanned aerial vehicle (UAV) path planning, particularly in complex wind-field environments. Most existing path-planning algorithms rely on simplified energy consumption models, which often fail to adequately capture the effects of wind fields. To address this limitation, a wind-adaptive lifelong planning A* algorithm (WA-LPA*) is proposed for energy-aware path planning in dynamic wind environments. WA-LPA* constructs a composite heuristic function incorporating wind-field alignment factors and integrates a hierarchical height-aware optimization strategy. Meanwhile, an adaptive replanning mechanism is designed based on the change characteristics of the wind field. Simulation experiments conducted across representative scenarios demonstrate that, compared to conventional algorithms that neglect wind-field effects, WA-LPA* achieves energy efficiency improvements of 5.9–29.4%. Full article

This study investigated the mechanical properties of a boltless hexagonal segment lining structure in TBM tunnels through a 1:10 scale similarity model test. The analysis considered the effects of burial depth and lateral pressure coefficient. A gypsum-diatomite composite simulated C50 concrete segments, and a custom loading system applied equivalent soil-water loads. The tests examined variations in bending moment, axial force and displacement. The results demonstrate that: (1) The tongue-and-groove joints behave like hinges, effectively reducing joint bending moments. (2) The unique staggered interlocking structure induces significantly higher axial forces at the joints than traditional rectangular segments, increasing susceptibility to stress concentration. (3) Increased burial depth has the most significant impact on the tunnel crown, where the bending moment, axial force, and displacement change most notably. (4) The lateral pressure coefficient (λ) alters the joint load transfer mechanism by modifying the structure’s triaxial stress state. An optimal λ of 0.6 maximizes axial force transfer efficiency, while excessively high values impair horizontal load-bearing capacity. (5) Structural failure was ductile, with a final ovality slightly exceeding 10‰. The findings of this study can provide a reference for the design and application of similar boltless hexagonal segment tunnels. Full article

Alpine treeline ecotones (ATEs) are critical ecological boundaries that are highly sensitive to climate change, yet their long-term spatial dynamics remain understudied in mountainous regions. This study investigates four decades (1984–2023) of ATE elevational shift along the Eastern Slopes of the Canadian Rocky Mountains (ESCR) using the Alpine Treeline Ecotone Index (ATEI), developed by integrating NDVI gradients, elevation data, and logistic regression. Multi-temporal Landsat composites and Shuttle Radar Topography Mission (SRTM) data were processed in Google Earth Engine (GEE) to map ATE boundaries over nine composite intervals. Results show a 13.32% increase in ATE area (from 1494.17 km² to 1693.19 km²), indicating a general upslope expansion consistent with a warming climate and extended growing seasons. Although the Mann–Kendall test did not reveal a significant monotonic trend in area change (neither upward nor downward) (p-value > 0.05), notable spatial variability was observed (approximately 8 km²/year). North-facing aspects exhibited the greatest mean elevation gain (+40.21 m), and significant ecotonal changes occurred within the Bow and Athabasca watersheds (p < 0.05), which are equal to around 416 and 452 km², respectively. These findings highlight the complex, aspect- and watershed-dependent nature of alpine vegetation responses to climate forcing and demonstrate the utility of ATEI for monitoring vegetation biodiversity shifts in high-elevation ecosystems. Full article

The development of the ceramic industry requires the creation of new innovative products with improved properties. Given the growing demand for high-quality finishing materials and the limited availability of traditional raw materials, the search for more efficient technologies for porcelain stoneware production is a relevant challenge. The aim of this study was to develop porcelain stoneware with enhanced performance characteristics. The research presents the results of a study aimed at improving the production technology of porcelain stoneware in Kazakhstan using local raw materials and microsilica. The raw materials from the Turkestan region were examined for their suitability for porcelain stoneware production. The influence of technological parameters (firing temperature, particle size) on the properties of porcelain stoneware was studied. New ceramic compositions with various microsilica contents, a by-product of silicon production, were investigated. Different compositions with varying raw material mixtures and microsilica content were prepared and fired at temperatures of 1100, 1150, and 1200 °C. The optimization of process parameters for producing porcelain stoneware in different compositions showed the degree of yield dependence on firing temperature and time as well as the effect of microsilica content. The temperature, time, and visually determined parameters at which different yield values were achieved were highlighted in different colors. The results showed that changes in the mixture composition and sintering temperature affect the quality of ceramic tiles. The final experimental conclusions demonstrated that the production of ceramic tiles containing up to 3% microsilica at a firing temperature of 1200 °C. The addition of microsilica increases the flexural strength of porcelain stoneware to 41 MPa (exceeding the standard), reduces water absorption to 0.023%, increases frost resistance to 107 cycles, and also enhances shrinkage. These findings open new prospects for the development of the domestic ceramic industry, the expansion of the product range, and the resolution of environmental issues. Full article