Search Results (19,757)

Although blood–brain barrier (BBB) models are of great value in investigating neurological diseases, the structural complexity and intricate function based on cell–cell interactions of the BBB bring various limitations to the applications of existing models. In this study, a novel BBB micro-organoid model was established by culturing neurovascular unit (NVU) cells on a decellularized squid mantle scaffold (DSMS) film to reconstitute a more authentic and reliable NVU microenvironment for in vitro research. The DSMS applied was obtained from squid mantle scaffolds via decellularization, followed by defatting, and showed good biocompatibility with no cytotoxicity. The DSMS film was finally prepared by lyophilization. The lyophilized film exhibited a void ratio and pore size suitable for the adhesion and growth of endothelial cells (hCMEC/D3) and astrocytes (hACs), which led to the formation of a BBB-like spatial structure. The BBB micro-organoid model exhibited functional barrier properties, including an effective transendothelial electrical resistance (TEER) of approximately 230 Ω/cm², restricted permeability to macromolecules—with apparent permeability coefficients (Papp) of 6.3 × 10⁻⁷ cm/s for 10 kDa and 2.7 × 10⁻⁷ cm/s for 70 kDa FITC–dextran—and expression of tight junctional complex (TJC) proteins such as vascular endothelial cadherin (VE-cad) and Zonula Occludens-1 (ZO-1). Furthermore, low-density lipoprotein receptor-related protein 1 (LRP1), a key receptor stably expressed in these two NVU cell types, was utilized as a critical indicator to assess the integrity of the BBB micro-organ model and its responsiveness to pathophysiological stimuli, particularly under thrombotic conditions. This study not only validates the feasibility of constructing a functionally competent BBB micro-organ model using DSMS films integrated with NVU cells but also provides a promising in vitro platform for subsequent studies on the BBB-related pathological mechanisms and the evaluation of drug permeability across the BBB. Full article

Sub-Saharan Africa, a region marked by enormous social and health inequalities, has the largest population infected with HIV and Mycobacterium tuberculosis, which are considered the main risk factors for fungal infections. At the same time, sub-Saharan Africa is the region of the world with the highest rates of helminth infections, whose immunomodulatory effects impair the host’s immune responses to other microorganisms, including HIV and M. tuberculosis. Through this indirect way, helminth immune modulation could be another syndemic factor influencing the development of fungal infections. However, some epidemiological peculiarities of five fungal diseases in sub-Saharan Africa, which we analyze in this paper, suggest that the influence of helminth immune modulation on the development of fungal infections there could also be direct. In light of the knowledge of all those interactions, any healthcare and epidemiological approach to Invasive Fungal Infections in sub-Saharan Africa should be carried out from a syndemic perspective that takes into account the ways in which social environments contribute to the clustering of infections, the pathways through which infecting microorganisms could interact biologically in each individual, influencing the development and evolution of the disease in course, and the ways in which those interactions complicate diagnosis, treatment, and control. Full article

This study examined how different photoperiods affect net energy partitioning and explored the mechanisms via blood biochemistry, gut microbiota, and fecal metabolites. Twelve healthy crossbred pigs (47.7 ± 7.5 kg) were randomly allocated to two groups and subjected to a self-controlled crossover design. Following an 8-day baseline under a normal photoperiod (12L:12D, 12 h light:12 h dark), pigs were assigned to two photoperiod treatment groups: prolonged photoperiod (18L:6D, 18 h light:6 h dark; P group) and shortened photoperiod (6L:18D, 6 h light:18 h dark; S group). Measurements during the baseline (12L:12D) and treatment phases are designated as N1/P (for the P group) and N2/S (for the S group), respectively. The treatment periods were interspersed with the baseline 12L:12D photoperiod and repeated six times. It was observed that, compared to N2, shortened photoperiod (S) had significantly higher net energy deposition, net energy for protein deposition, and net energy for fat deposition (p < 0.05). Compared with N2, plasma low-density lipoprotein in short photoperiod decreased (p < 0.05), and gastric inhibitory peptides increased (p < 0.05). Compared to the prolonged photoperiod, the levels of ghrelin and apolipoprotein A-IV were higher in the shortened photoperiod (p < 0.05). A shortened photoperiod decreased fecal acetic acid compared to N2 (p < 0.05) and decreased propionic acids compared to P (p < 0.05). The significance test of differences between microbial groups showed that there were different microorganisms among the different groups. The results indicated that shortening the photoperiod significantly altered the energy allocation in growing pigs. Full article

Composting chicken manure is a source of significant ammonia (NH₃) emissions, which, because of propagation, contributes to the eutrophication of the environment and decreases in air quality. Therefore, it is reasonable to use methods to limit its emission into the atmosphere. Biofiltration, using the metabolic activity of nitrifying and heterotrophic microorganisms capable of oxidizing ammonia, is an effective method to reduce ammonia emissions. In addition, the performance of the biofiltration process depends on operational parameters such as the humidity of the medium, the temperature, the contact time of the gas with the biofiltering medium, and the chemical composition and structure of the filter material. The aim of the study was to evaluate the effectiveness of biofilter fillings in reducing ammonia emissions from composting chicken manure along with the identification of factors allowing us to determine the proposed design solution as the most advantageous in terms of efficiency. Experiments on reducing odour emissions with biofiltration were carried out in two compact composting reactors, in which a compost mixture with a C:N ratio of 10:1 was used. The mixture was prepared in a ratio of 5:1 of chicken manure to the structuring material, with wheat straw used as the structuring material. Based on the results of the research on the course of the composting process, high values of ammonia concentration were recorded. Ammonia concentrations of 886 ppm (composter 1) and 811 ppm (composter 2) were recorded, which confirms the intensive nature of this gas emissions during the process of stabilizing the chicken manure. As part of the conducted research, the effectiveness of biofiltration in reducing ammonia emissions was evaluated by analysing the influence of the aeration intensity of the biofilter (20 dm³/h and 50 dm³/h), directly determining the time of contact of the gas with the bed (EBCT—Empty Bed Contact Time). Coconut-activated carbon was used as a filter bed, which was an effective carrier for the development of microorganisms responsible for the biological removal of ammonia from waste gases generated during composting. In addition, this material showed the ability to physically adsorb ammonia, thus supporting the process of its elimination. Each of the test stations has been equipped with a biofiltration installation. To determine the effectiveness of biological removal of ammonia and to assess the legitimacy of the use of selected strains of microorganisms in the process of biological removal of ammonia, the bed of one of the biofilters (biofilter 2) was inoculated with a strain of nitrifying bacteria. During the study, the high efficiency of ammonia removal because of biofiltration was noted in each of the configurations. In the case of an aeration intensity of 20 dm³/h, a reduction in emissions of 99% was achieved; with a higher aeration value, i.e., 50 dm³/h, the efficiency was 89%. These results indicate that the intensity of aeration has a significant impact on the efficiency of the biofiltration process. The analysis of a biofilter enriched with a strain of nitrifying bacteria requires long-term testing. This is important to reliably determine the effect of inoculation on the efficiency of the biological removal of ammonia in biofilters. It has been shown that optimizing these factors allows us to achieve a reduction in ammonia emissions of up to 90%, while minimizing the formation of unpleasant odours. The use of biofiltration in composting systems for organic waste of animal origin is an effective, sustainable solution that fits into the idea of sustainable development, combining the efficiency of air purification technology with environmental protection and the responsible management of resources. This study demonstrates that biofiltration using coconut-shell-activated carbon is an effective and economical method for reducing ammonia and odour emissions from composting chicken manure. The results provide valuable theoretical and practical information on emissions management in organic waste composting processes. Data from this study could be useful in developing strategies to minimize odour emissions, including from the agricultural sector. Full article

Background/Objectives: Advances in molecular biology, genetics, and microbiome research have significantly expanded our understanding of probiotic microorganisms and their interactions with human health, stimulating the development of both traditional and next-generation probiotic products. Although probiotics are widely used and generally considered safe for healthy individuals, accumulating evidence indicates that their safety profile varies significantly depending on the strain, dose, host, and context, with rare but clinically significant adverse events reported in vulnerable populations. Methods: This review summarizes current knowledge on the efficacy and safety of probiotics, analyzes limitations in clinical safety reporting, and compares regulatory frameworks governing the use of probiotics as dietary supplements, medicinal products, and live biotherapeutics. Particular attention is given to new genomic and computational approaches to safety assessment. Conclusions: Overall, the review emphasizes the need for coordinated regulation, rigorous clinical evidence, and integrated, modern safety assessment strategies to support the responsible expansion of probiotic use. Full article

“Unusual sporotrichosis”, a concept proposed in this review, refers to severe, extracutaneous, or anatomically atypical manifestations of sporotrichosis occurring in immunocompetent hosts and represents an underrecognized clinical subset associated with important diagnostic and therapeutic challenges. This systematic review aimed to characterize unusual sporotrichosis worldwide and to clarify its epidemiological, clinical, diagnostic, and therapeutic patterns. Following a registered protocol and PRISMA guidelines, PubMed, Scopus, and BVS/LILACS were searched up to November 2025 using a PICO-based strategy. Eligible studies included peer-reviewed case reports and case series with laboratory-confirmed sporotrichosis in patients without immunosuppression, diabetes mellitus, alcoholism, or other confounding comorbidities; classical lymphocutaneous and fixed cutaneous forms were excluded. From 922 records, 39 studies were included (13 case series and 26 case reports), yielding 55 cases reported between 1957 and 2024 across five world regions, mainly from the United States of America and Brazil. Adults aged 40–59 years (41.8%) and males (74.5%) predominated. Sapronotic transmission was most frequent (69.0%), although zoonotic transmission increased over time. Sporothrix schenckii/Sporothrix schenckii sensu stricto was the predominant species (87.3%). Osteoarticular (30.9%) and systemic (27.2%) forms were the most common presentations. Although cure was achieved in most cases (58.1%), sequelae were frequent (21.8%), and the worst prognosis—including most deaths—was observed in osteoarticular sporotrichosis. Unusual sporotrichosis is globally distributed and clinically distinct; therefore, early recognition and multimodal diagnostic and therapeutic strategies are essential to improve outcome. Full article

Umami is a key determinant of pork flavor, but the association between the intestinal microbial community and umami differences remains unclear. Here, we used the taste-sensing electronic tongue system to divide the Duroc × Landrace × Yorkshire pigs into high, medium and low groups. We combined 16S rRNA gene and shotgun metagenomic sequencing to study the differences in the microbial community composition and functional genes. The results showed that the microorganisms in the cecum of different groups had a similar core microbial community. The Shannon diversity analysis showed that there were no significant differences among the different groups. The Bray–Curtis distance indicated that there were differences in the bacterial communities between the high umami group and the other two groups. The LEfSe analysis and Spearman correlation analysis revealed that the uncultured species CAG-632 sp900539185 maintained a high abundance in the high umami group and was significantly correlated with umami. Metagenomic functional analysis revealed distinct functional signatures among umami groups, with enrichment of genes related to carbohydrate transport and metabolism, butanoate and other short-chain fatty acid pathways, nitrogen utilisation, cell-surface structures, adhesion and RNA metabolism in high umami groups. These research findings indicate that the differences in the delicious flavor of pork are more likely to be associated with specific microbial species and the functional characteristics of the cecal microbial community, rather than the overall situation of the entire microbial community. Full article

Antimony (Sb) contamination in agricultural soils threatens the safety of rapeseed production, yet the mechanisms driving cultivar differences in seed Sb accumulation remain unclear. A pot experiment was conducted with two Sb-tolerant cultivars showing contrasting accumulation patterns, Nanyouza 1 (high-accumulating) and Fengyou 958 (low-accumulating), grown under increasing Sb levels. (1) Sb stress inhibited growth and reduced photosynthetic performance in both cultivars; antioxidant enzymes showed a “low stimulation–high inhibition” response and MDA increased under high Sb, indicating aggravated oxidative damage beyond the tolerance threshold. (2) Nanyouza 1 accumulated more Sb in vegetative tissues and exhibited stronger root-to-shoot translocation than Fengyou 958, whereas seed Sb remained relatively low in both cultivars and bioconcentration/translocation efficiencies declined with increasing Sb. (3) At maturity, rhizosphere bacterial communities shifted along the Sb gradient, and taxa associated with Sb differed, with Ramlibacter and Bacillus positively correlated. These findings provide mechanistic insights supporting the integration of cultivar selection and rhizosphere regulation to achieve both safe production and phytoremediation in Sb-contaminated farmland. Full article

The Brown Planthopper, Nilaparvata lugens (Stål.) (Hemiptera: Delphinidae), is one of the most destructive pests of rice. Its reproductive and developmental traits are influenced by various environmental and biological factors including endosymbiotic microorganisms. Arsenophonus, a widespread endosymbiotic bacterium of insects, can affect host fitness and metabolic processes. This study investigates the role of Arsenophonus in modulating the developmental and reproductive traits of N. lugens fed on transgenic cry30Fa1 rice (KF30-14) and its parent variety Minghui 86 (MH86). Life table analysis revealed that Arsenophonus infection (Ars⁺) increased the development time and reduced the reproductive capacity of N. lugens, especially those feeding on KF30-14. The first-instar nymphs in MH86 Ars⁺ (infected) exhibited slower development compared to MH86 Ars⁻ (uninfected). Similarly, the third and fourth-instar nymphs in KF30-14 Ars⁺ exhibited prolonged development time compared to KF30-14 Ars⁻. In addition, KF30-14 Ars⁺ females had significantly reduced reproductive capacity, smaller ovarian tubules and lower relative expression levels of reproduction-related genes including Trehalose transporter (Tret), Vitellogenin (Vg) and Cytochrome P450 hydroxylase (cyp314a1), while Juvenile hormone acid methyltransferase (JHAMT) expression was upregulated. RNA sequencing and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analysis revealed significant enrichment of genes involved in lipid, amino acid, and vitamin metabolisms, with Long-chain acyl-CoA synthetase implicated as a key regulator of lipid metabolism and reproductive fitness. These results highlight the complex interactions between endosymbionts, host plants and pest biology, offering a solid foundation for sustainable approaches to control N. lugens in rice production systems. Full article

Stormwater and greywater are increasingly recognized as freshwater resources, and the effective separation and reutilization of nitrogen (N) and phosphorus (P) from these streams is vital for water quality improvement and urbanization sustainability. In this study, we constructed a pilot-scale hydroponic green roof wetland system planted with two economically important Chinese herbal plant species (Mentha spicata L. (ML) and Basella alba L. (BL)) to separate and reutilize N and P from synthetic stormwater/greywater. The results reveal that the highest plant biomass was obtained at an ML:BL ratio of 1:3, indicating their superior adaptation to rooftop hydroponics with synthetic stormwater/greywater. This configuration also achieved the strongest water purification, with substantial separation and reutilization efficiency of N (82.09%) and P (81.90%). Furthermore, the lowest microbial richness in the ML roots at this specific plant ratio suggested that increasing BL may enhance ML’s allelopathic effects. An increase in the BL proportion was further associated with a gradual shift in the dominant ML root-associated microorganisms toward microeukaryotic taxa. The green vegetation of the two plant species also effectively suppressed algal blooms (especially diatoms) in the hydroponic rooftop system. This study demonstrates that a Chinese herb-based green roof wetland system can effectively separate and reuse N and P from stormwater/greywater while concurrently purifying water and producing economic crops. Full article

Bowdichia virgilioides Kunth is a tree largely present in South America, notably in the Cerrado savannah. The species is known for the quality of its dense and resistant wood, used in construction and furnishing. B. virgilioides is also a medicinal plant used, from leaves to roots, for the treatment of various human pathologies (pharyngitis, bronchitis, healing wounds, diabetes, and arthritis). The present review provides an analysis of the scientific literature pertaining to B. virgilioides, with a focus on pharmacological activities. Aqueous and organic extracts have been used to treat inflammatory pathologies and to combat infectious diseases caused by microorganisms and parasites. All phytochemicals at the origin of the bioactivities of extracts have been identified, including 37 terpenoids, 8 alkaloids, 21 flavonoids and 13 other products. All natural products are discussed, with a focus on a dozen compounds with well-documented pharmacological properties and/or a known mechanism of action. Key products include ormosanine (alkaloid), vouacapane (diterpenoid), lupeol (terpenoid), isoquercetin (flavonoid), isocordoin (chalcone), and little-known specific products (bowdichine and bowdenol). The botanical and phytochemical analysis shed light on this valuable Fabaceae species with the objective to promote its preservation and cultivation, as well as further pharmacological investigations aimed at rationalizing its long-established ethnobotanical use. Full article

Safe drinking water and microbial inactivation from surfaces and devices are among the World Health Organization’s priorities. Plasma-activated water (PAW) inactivates microorganisms mainly by producing radicals (hydroxyl radicals, superoxide, nitrogen oxide, etc.), which form secondary reactive species like nitrates, nitrites, hydrogen peroxide, etc., from the air–liquid interface, where the plasma interacts with the water. A plasma arc device for water treatment with enhanced arc length was constructed at the Andronikashvili Institute of Physics (TSU) and used in the study. PAW’s antibacterial efficacy has been evaluated against Gram-negative E. coli and remarkably stress-resistant Gram-positive B. pumilus. This study identifies reactive oxygen (hydrogen peroxide and superoxide anions) and nitrogen species (total nitrate and nitrite ions) in plasma-activated water, analyzing their potential impact on antioxidant enzyme activity and their relationships with bacterial cell viability. B. pumilus exhibits greater resistance to plasma-activated water as a disinfectant compared to E. coli. Catalase is more effective than superoxide dismutase in protecting cells from external oxidative stress, based on the two antioxidant enzymes studied. Full article

This study evaluated whether body size could serve as a quality and traceability marker for cage-reared butter catfish (Ompok bimaculatus) from the Pak Phanang Basin, Nakhon Si Thammarat, Thailand, in support of Geographical Indication (GI) certification. Fish were classified into three commercial size grades—small (12–15 fish/kg), medium (6–10 fish/kg), and large (3–5 fish/kg)—corresponding to fish harvested after 6, 8, and 12 months of rearing, respectively, with mean body weight and total length of 75 ± 7 g and 19.8 ± 1.1 cm (small), 120 ± 9 g and 25.8 ± 2.1 cm (medium), and 260 ± 10 g and 32.2 ± 2.8 cm (large). Dorsal muscle samples were comparatively analyzed to assess size-related differences in physicochemical properties, nutritional composition, and microbiological quality. Proximate analysis showed that moisture, lipid, ash, and total energy contents increased significantly with fish size (p < 0.05), whereas protein and carbohydrate contents did not differ significantly among size groups (p > 0.05). Small fish exhibited slightly higher muscle pH (7.02 ± 0.18) than medium and large fish (6.65 ± 0.11 to 6.66 ± 0.25) (p < 0.05). Flesh color was characterized by a pale whitish to slightly yellow appearance with high lightness (L*; p < 0.05), while redness (a*) and yellowness (b*) did not differ significantly among size groups (p > 0.05). Mineral composition varied with size, with large fish containing significantly higher levels of calcium and magnesium (p < 0.05). Amino acid profiling identified 17 amino acids, including eight essential amino acids (EAA) and nine non-essential amino acids (NEAA), with EAA being more abundant in large fish—particularly leucine and lysine—indicating improved protein quality, while NEAA were dominated by glutamic and aspartic acids across all size groups. Fatty acid analysis revealed higher proportions of polyunsaturated fatty acids (PUFA) and greater unsaturated fatty acid/saturated fatty acid (UFA/SFA) ratios (1.7–1.8) in medium and large fish. Microbiological assessment showed a decrease in total viable counts with increasing fish size, while Escherichia coli, Staphylococcus aureus, and Salmonella spp. were not detected in any size group, as these microorganisms are commonly used as key hygiene and food-safety indicators in fish products (E. coli for fecal/handling hygiene, S. aureus for human-handling contamination, and Salmonella spp. as a major foodborne pathogen). Overall, body size was associated with consistent variations in physicochemical characteristics, nutritional composition, and microbial quality of Pak Phanang Basin butter catfish. These findings provide baseline compositional and safety markers that can support product specification development and GI documentation. Full article

Climate change has intensified the occurrence of biotic and abiotic stresses, representing a major threat to agricultural productivity. This climate variability, coupled with the excessive use of agrochemicals, not only compromises environmental sustainability but also exacerbates food insecurity, directly affecting food availability and quality. In this context, biotechnological strategies have proven essential for mitigating the effects of stress on plants, promoting practices focused on agricultural sustainability. Notable among these strategies is the use of plant growth-promoting microorganisms, which are emerging as promising alternatives capable of improving plant tolerance to stress conditions and simultaneously reducing dependence on agrochemicals. These microorganisms can act as nitrogen fixers and solubilizers of nutrients, such as phosphorus and potassium. Additionally, they can influence plant immune responses by inducing systemic resistance and promoting the synthesis of phytohormones, such as auxins, cytokinins, and abscisic acid, which support plant development during the stress response. The interaction between plants and microorganisms represents a sustainable agricultural management strategy capable of enhancing crop tolerance to environmental adversities. In this review, we discuss the microorganisms known to establish beneficial interactions with plants, leading to improved performance under biotic and abiotic stress. Overall, this work highlights the potential of plant–microbe partnerships as a cornerstone for advancing sustainable agriculture in the face of global challenges. Full article

The combination of additives in ruminant diets is a growing strategy focused on cow health and productivity; therefore, the additives need to have synergistic effects when combined. Because of this, the objective of this study was to evaluate the effects of combining functional additives (biocholine, live yeasts, Yucca schidigera extract, and exogenous enzymes) on the productive performance, milk quality, rumen environment, oxidative status, and metabolic parameters of lactating Jersey cows maintained in an intensive system as well as verifying whether the effects on metabolism and the rumen environment (volatile fatty acids and microbiota) directly or indirectly influence productive efficiency. Eighteen Jersey cows in their second lactation were used, distributed in a completely randomized design into two groups: control, receiving a basal diet, and treatment, receiving the same diet plus the additive mixture. The experiment lasted 56 days. Dry matter intake, milk production and composition, feed efficiency, apparent digestibility, volatile fatty acid profile, rumen microbiota, hematological and biochemical parameters, and oxidative stress markers were evaluated. The combination of additives was able to increase milk production and production corrected for fat, protein, and energy, without altering dry matter intake, resulting in greater feed efficiency. There was an increase in milk protein content from day 28 onwards. In the rumen, a reduction in the protozoan population and an increase in the proportion of propionic acid were observed, without altering the ruminal pH or the total production of volatile fatty acids. The apparent digestibility of crude protein was higher in the treated group. The consumption of additives also promoted specific changes in the ruminal microbiota, with a greater abundance of microorganisms associated with carbohydrate degradation and less activity of pathways related to denitrification. From a systemic point of view, the treatment reduced markers of oxidative stress (reactive oxygen species—ROS and thiobarbituric acid reactive substances—TBARS), decreased creatine kinase and cholinesterase activity, and increased serum fructosamine concentration, indicating antioxidant, anti-inflammatory effects and improved energy status, respectively. It is concluded that the combination of plant biocholine, yeasts, Yucca schidigera extract, and exogenous enzymes improves productive efficiency, promotes ruminal fermentation, and contributes to greater metabolic and oxidative stability in lactating Jersey cows. Full article