Search Results (623)

Background/Objectives: Antimicrobial resistance (AMR) is a major global public health threat, particularly in hospitals. Antimicrobial Stewardship Programs (ASPs) aim to optimize prescribing, reduce unnecessary exposure to broad-spectrum agents, and mitigate resistance. This study evaluated the clinical, ecological, and economic impact of an ASP implemented in January 2021 in a high-complexity hospital in Brazil, focusing on antimicrobial consumption, temporal trends in bacterial susceptibility, and direct antimicrobial-related costs. Methods: A quasi-experimental pre–post study using an interrupted time-series design was conducted in the adult intensive care unit from January 2019 to December 2023. Antimicrobial consumption was measured as Defined Daily Doses per 1000 patient-days (DDD/1000-PD) for ceftriaxone, meropenem, piperacillin–tazobactam, vancomycin, and polymyxin B. Temporal trends were assessed using Joinpoint regression, and pre- and post-intervention periods were compared using Student’s or Mann–Whitney tests. Susceptibility data were interpreted according to BrCAST standards. Results: Significant and sustained reductions were observed for all agents except polymyxin B. Susceptibility improved or stabilized among key Gram-negative pathogens, with a significant increase in aggregated Gram-negative susceptibility after 2021, while intrinsically resistant organisms showed limited change. Annual antimicrobial costs decreased by approximately USD 174,000. Conclusions: The ASP was associated with reduced broad-spectrum antimicrobial use, favorable ecological trends, and substantial cost savings. Full article

Premature deterioration of reinforced concrete is driven largely by moisture and chloride ingress, which accelerate steel corrosion and shorten service life. This study investigates a dual strategy to enhance durability while supporting circular-economy goals: (i) incorporating coal-fired biomass ash (CBA) as a fine-aggregate replacement (0%, 20%, and 50%) and (ii) applying bio-inspired surface treatments to reduce transport pathways. To capture variability in CBA performance across different environmental and material contexts, two concrete systems—produced in India and the UK—were evaluated, each subjected to a distinct coating approach: a bacterial self-healing treatment or a cinnamaldehyde (CNM) organic barrier. Mechanical, transport, and multi-scale characterization was performed, including compressive strength, capillary absorption, chloride migration (NT Build 492), SEM/EDS, XRF, and XRD. The 20% CBA mixes maintained or slightly improved strength, while higher CBA contents increased porosity but reduced chloride transport in the UK mix. The bacterial coating reduced long-term water absorption by over 80% through CaCO₃ mineralization, offering strong moisture resistance. The CNM coating decreased chloride migration by up to 68% via hydrophobic and ionic-blocking effects. Overall, moderate CBA with self-healing treatment enhances moisture control, whereas higher CBA with CNM provides effective chloride protection, extending the service life of CBA-based concrete. Full article

Yersinia enterocolitica is a foodborne pathogen that forms biofilms on surfaces, enhancing its survivability and increasing bacterial resistance, which poses a significant challenge to public health. Therefore, developing effective strategies to inhibit biofilm formation is crucial. Lipoic acid (LA) is a compound with antibiofilm properties. This study investigates the effects of LA on biofilm formation by Y. enterocolitica BNCC 108930 (a standard strain from the BeNa Culture Collection). Biofilm formation, maturation, removal, and cell viability were evaluated by crystal violet staining, extracellular polysaccharide assay, Methylthiazolyldiphenyl-tetrazolium bromide assays, motility, and quorum sensing (QS) assays. The results indicate that LA interferes with the early stages of biofilm formation by compromising cell membrane integrity and reducing cellular adhesion. Furthermore, 2.5 mg/mL of LA reduced biofilm biomass (with a 48 h treatment inhibition rate of 51.46 ± 1.29%) and extracellular polysaccharide production (with a relative inhibition rate of 30.09 ± 1.8%), while significantly reducing the metabolic activity of bacteria within the biofilm (inhibition rate over 85%) compared to the untreated group. Confocal laser scanning microscopy and field emission gun scanning electron microscopy confirm that LA induces a sparse biofilm structure, reduced aggregation, and decreased biofilm thickness to 21.33 ± 2.27 μm. Motility and QS assays demonstrate that LA affects flagellar motility and the secretion of N-acyl homoserine lactones. Transcriptome analysis revealed downregulation of genes involved in the QS system and biofilm formation (e.g., lsrA, lsrC, lsrD, lsrR, and oppA), as well as upregulation of genes related to bacterial chemotaxis and flagellar assembly (e.g., RS19655, RS15590, fliE, fliJ, fliP, fliA, and fliK). These alterations suggest that LA inhibits Y. enterocolitica biofilm formation by affecting intercellular communication and flagellar motility. This study highlights the antibiofilm properties of LA, providing a theoretical basis for potential applications in microbial and biofilm control. Full article

Silver nanoparticles were biosynthesized using the culture supernatant of Staphylococcus sp. YRA, a strain isolated from Colombian mining sediments. Synthesis was optimized at 1 mM AgNO₃, pH 7, 40 °C and 7 μg/mL extract, producing spherical, protein-capped AgNPs with primary sizes in the tens-of-nanometers range (~35–90 nm by SEM), while DLS indicated larger hydrodynamic diameters (~250–320 nm) consistent with aggregation in suspension (ζ-potential −16.6 mV). These nanoparticles remained stable over 6 months. Characterization by UV–Vis, SEM, AFM, EDS and FTIR confirmed extracellular protein-mediated reduction and capping. The AgNPs showed antibacterial activity against multidrug-resistant clinical isolates (Staphylococcus aureus, Escherichia coli, Klebsiella pneumoniae, Salmonella bongori, Enterococcus spp.), with inhibition zones of 8–16 mm at 400–1000 μg/mL. Biofilm formation was reduced by >50% at 700 μg/mL in both Gram-positive and Gram-negative strains. In Phaseolus vulgaris (P. vulgaris), low concentrations (5–100 μg/mL) increased growth and chlorophyll content, while 500 μg/mL caused moderate inhibition. FTIR analysis identified amide and thiol groups from bacterial enzymes as capping agents. These results suggest Staphylococcus sp. YRA as a bacterial platform for AgNPs production with antibiofilm activity against MDR pathogens and acceptable phytotoxicity profile for potential applications. Full article

This work provides an in vitro assessment of the antibacterial efficacy of ethanolic extracts derived from four medicinal plants historically utilized in the Aseer region (Foeniculum vulgare, Solanum incanum, Forsskaolea tenacissima, and Abutilon pannosum) against cultured oral bacterial isolates obtained from healthy volunteers. Oral samples from a subset of 50 healthy female participants were included in this analysis, yielding independent cultured bacterial isolates. Isolates were identified using morphological and biochemical characterization combined with partial 16S rRNA gene sequencing and included representatives of common oral-associated genera. Antibacterial activity was assessed using agar disk diffusion and broth microdilution assays. Abutilon pannosum and Solanum incanum had lower values of MIC (range of 16–128 µg/mL), whereas Forsskaolea tenacissima had higher values of MIC (maximum to >512 µg/mL) with the tested isolates. Qualitative microscopic observations and crystal violet biofilm staining showed extract-associated varying cellular morphology, aggregation patterns and surface coverage under sub-inhibitory conditions. Representative isolate scanning electron microscopy (SEM) qualitatively validated descriptive cell surface morphology and organization changes. The research presents preliminary in vitro results of inconsistent antibacterial and antibiofilm effects of crude ethanolic extracts of four plants in the Aseer region on a small (n = 13) group of cultured oral bacteria isolates in healthy volunteers, which requires fractionation and further testing. Full article

Weizmannia coagulans has emerged as a prominent probiotic candidate due to its resilience in extreme environments and therapeutic potential for non-gastrointestinal diseases, including obesity, bacterial vaginosis, and irritable bowel syndrome-related depression. This study comprehensively evaluated the probiotic properties, safety profile, and functional characteristics of W. coagulans strains (MA42, P13, and S5) compared with the reference strain W. coagulans ATCC 7050. All tested strains exhibited excellent gastrointestinal survival (>90% viability), superior auto-aggregation (up to 36.60%), hydrophobicity (up to 36.58%), and susceptibility to commonly used antimicrobials. Cell-free culture supernatants showed potent antimicrobial activity against pathogenic bacteria, including Escherichia coli ATCC 25922, Salmonella enterica serovar Typhimurium TISTR 292, and Bacillus cereus TISTR 747, primarily through organic acid production. Notably, strain MA42 uniquely inhibited the growth of Staphylococcus aureus TISTR 746. All strains showed negative hemolytic activity, confirming their safety profile. W. coagulans MA42 distinguished itself through exceptional metabolic versatility, demonstrating vigorous growth on diverse complex dietary fibers and prebiotics, with significant production of beneficial organic acids, particularly lactic and acetic acids. This superior fermentation capacity correlated directly with elevated extracellular-enzyme activities. Furthermore, all strains maintained excellent viability (>90% recovery) after freeze-drying with maltodextrin as a cryoprotectant, indicating industrial scalability. Full article

The transformation pathways of organic carbon (OC) fractions and their interrelationship with microbial activity during natural composting (NC) and vermicomposting (VC) remain poorly understood across pig manure (PM)/straw pellets (SP) ratios. Therefore, the objective of this study was to elucidate the regulatory mechanisms of substrate mixing ratios on carbon fraction transformation and microbial functional networks during these processes. To achieve this, five PM/SP ratios [100:0 (T1), 75:25 (T2), 50:50 (T3), 25:75 (T4), and 0:100 (T5)] were composted with or without earthworms, revealing the T2 (75:25) ratio had most efficient composting performance within 60 days due to the suitable initial C/N ratio (31.65 ± 0.99). Consequently, the T2 treatment reached the highest organic degradation, including TOC reduction (58.6%), TN accumulation (63.9%), and C/N decline (74.8%) in the VC. Vermicomposting markedly stimulated functional microbial groups—nitrogen-fixing, phosphate-solubilizing, and potassium-solubilizing bacteria—thereby enhancing nutrient (N, P, K) bioavailability. The prominence of the optimal C/N ratio across multiple hydrolytic and oxidative enzymes in the VC-T2 further proved that this ratio provided an optimal nutrient and structural balance for both earthworms and microbial consortia. Strong correlations between bacterial abundance and enzyme activities (r ≥ 0.98), lignin and dissolved OC (r ≈ −0.81), and particulate organic carbon and mineral-associated carbon (r > 0.9) highlighted microbially mediated carbon stabilization through enzymatic mineralization, aggregation, and redistribution of carbon from active pools toward mineral-associated OC. This work identifies the critical PM-SP ratio for waste valorization and mechanistically links earthworm–bacteria interactions to carbon sequestration pathways. Full article

This study investigates the elaboration, structural characteristics, and antibacterial performance of silver-based nanoparticles obtained via a hydrolytic chemical route, with and without assistance from ultrasound and microwave irradiation. Two silver nitrate precursor concentrations (1 M and 2 M) were employed to evaluate the influence of synthesis conditions on phase composition, morphology, and antimicrobial efficiency. The obtained powders were characterized by ATR-FTIR, X-ray diffraction (XRD), and scanning electron microscopy (SEM). XRD analysis revealed that drying at 120 °C led to oxide-rich systems dominated by Ag₂O, with minor contributions from metallic Ag and carbonate species, while calcination at 550 °C resulted in complete phase transformation into highly crystalline metallic silver. SEM observations demonstrated that precursor concentration and synthesis assistance strongly affect particle size, aggregation degree, and surface morphology. Ultrasound- and microwave-assisted synthesis promoted finer crystallite sizes and more homogeneous particle distributions compared to non-assisted routes. The antibacterial activity was evaluated against Escherichia coli (Gram-negative) and Clostridium perfringens (Gram-positive, anaerobic, spore-forming). Oxide-rich samples, particularly Ox.Ag/2 M, exhibited rapid and complete bacterial inactivation within 30 min, while metallic silver samples showed time-dependent antibacterial behavior, achieving full inhibition after 4 h. The results demonstrate that antibacterial efficiency is governed by a synergistic interplay between silver oxidation state, nanoscale morphology, and surface reactivity. These findings highlight the potential of tailored silver-based nanomaterials as effective antibacterial materials for biomedical, food safety, and environmental applications. Full article

Pseudomonas fluorescens is a primary spoilage bacterium in aquatic products. Due to its strong ability to adhere to surfaces and form persistent biofilm, it poses a persistent challenge to food safety. Therefore, developing strategies to effectively inhibit biofilm formation holds significant research value. Dubosiella newyorkensis, a recently identified probiotic, has gained growing attention for its distinctive physiological features and potential functional benefits. Although various probiotic-derived cell-free supernatants (CFSs) have been explored for food preservation, the application of D. newyorkensis CFS against aquatic spoilage bacteria, and particularly its specific mechanism against P. fluorescens biofilm, has not been previously reported. Increasing evidence indicates that CFS from probiotic can influence microbial behavior, including biofilm development. In this study, we investigated the ability of D. newyorkensis CFS to inhibit P. fluorescens biofilm formation. The CFS treatment impaired bacterial growth and motility, lowered surface hydrophobicity, reduced self aggregation, and consequently hindered biofilm formation. Furthermore, CFS markedly decreased bacterial adhesion to food and contact surfaces. RT-qPCR analysis revealed that key genes associated with biofilm regulation were also significantly suppressed. Taken together, these results demonstrate that D. newyorkensis CFS exerts both antibacterial and antibiofilm effects against P. fluorescens. These findings provide a sound basis for exploring its application as a natural biopreservative to enhance the microbial safety and extend the shelf life of aquatic food products. Full article

Introduction: Infections attributed to multidrug-resistant organisms have resulted in a significant clinical burden, high mortality, and excessive costs. Identifying the most appropriate and efficacious treatments will aid in reducing these burdens. Imipenem/cilastatin + relebactam (I/R) is used against multidrug-resistant infections providing an alternative option which may support patients where traditional treatments are no longer effective. Objective: The objective was to evaluate the efficacy of I/R for complicated urinary tract infections, complicated intra-abdominal infections, hospital-acquired bacterial pneumonia, and ventilator-associated bacterial pneumonia, based on data aggregated from randomized controlled trials. Method: Two systematic literature reviews were conducted to include randomized controlled trials which aligned with the inclusion criteria reporting on the efficacy of I/R against placebo or other comparators such as piperacillin/tazobactam or colistin. The outcomes of interest were mortality, clinical response, and microbiological response. Results: The results found reduced mortality and comparable clinical and microbiological response with I/R versus its comparators. I/R displayed the largest favorable clinical and microbiological responses within high-risk populations, including those with severe renal impairment when compared with piperacillin/tazobactam. Conclusions: These findings support the efficacy of I/R for key Gram-negative infections, particularly within vulnerable patient populations. Despite the favorable outcomes reported, there is a need for further real-world evidence generation to support the efficacy of I/R to aid in standardizing treatment guidelines and reducing the clinical and economic burden associated with multidrug-resistant bacterial infections. Full article

Background/Objectives: Bacterial outer membrane vesicles (OMVs) play a role in bacterial communication, virulence, antimicrobial resistance, and host–pathogen interaction. OMV isolation is a key step for studying these particles’ functions; nevertheless, isolation procedures can greatly influence the yield, purity, and structural integrity of OMVs, thereby affecting downstream biological analyses and functional interpretation. Methods: In this study, we compared the efficacy of two OMV isolation techniques, differential ultracentrifugation (dUC) and size-exclusion chromatography (SEC), in separating and concentrating vesicles produced by two Escherichia coli strains belonging to uropathogenic (UPEC) and Shiga toxin-producing (STEC) pathotypes. The isolated OMVs were characterized using a multi-analytical approach including transmission and scanning electron microscopy (TEM, SEM), nanoparticle tracking analysis (NTA), dynamic light scattering (DLS), ζ-potential measurement, and protein quantification to assess the purity of the preparations. Results: Samples obtained by dUC exhibited higher total protein content, broader particle size distributions, and more pronounced contamination by non-vesicular material. In contrast, SEC yielded morphologically homogeneous and structurally well-preserved vesicles, higher particle-to-protein ratios, and lower total protein content, reflecting reduced co-isolation of protein aggregates. NTA and DLS analyses revealed polydisperse populations in samples obtained with both isolation methods, with DLS measurements highlighting the contribution of larger or transient aggregates. ζ-potential values were close to neutrality for all samples, consistent with limited electrostatic repulsion and with the aggregation tendencies observed in some preparations. Conclusions: This study describes features of OMV produced by two relevant E. coli strains considering two isolation strategies which exert method- and strain-dependent effects on vesicle properties, including size distribution and surface charge, and emphasizes the trade-offs between yield, purity, and vesicle integrity. Full article

Vegetation restoration is an effective strategy to improve the ecosystem function of the Loess Plateau. Soil microbiomes play a critical role in maintaining soil multifunctionality (SMF). However, the role of aggregate-scale microbial communities and interactions in regulating SMF during vegetation restoration remains poorly understood. Here, we selected six types of vegetation restoration measures in the Loess Plateau, including natural grassland (NL), Medicago sativa (MS), Hippophae rhamnoides (HR), Caragana korshinskii (CK), Armeniaca vulgaris (AV), and Populus alba (PA), and used abandoned land (AL) as a control to identify key microbial mechanisms driving SMF at the aggregate scale. The results show that vegetation restoration increased bacterial diversity, fungal network complexity, and SMF, especially in AV. In contrast, fungal diversity and bacterial network complexity exhibited asynchronous dynamics across different-sized aggregates. Soil microbial diversity peaked at micro-aggregates (0.053–0.25 mm), while fungal network complexity increased with decreasing aggregate size. The structural equation model confirmed that fungal community composition in large macro-aggregates (>2 mm) and fungal network complexity in <2 mm aggregates were the key drivers of SMF. Our results emphasize the divergent mechanisms by which microbial properties influence SMF across aggregate sizes, highlighting the importance of fungal communities in maintaining soil ecosystem functions. Full article

Background: Growing evidence indicates that oral microbiome dysbiosis contributes to systemic inflammation, immune activation, and neural dysfunction. These processes may influence the onset and progression of major neuropsychiatric and neurodegenerative disorders. This review integrates clinical, epidemiological, and mechanistic findings linking periodontal pathogens and oral microbial imbalance to Alzheimer’s disease (AD), Parkinson’s disease (PD), depression, and anxiety. Methods: A narrative review was conducted using PubMed/MEDLINE, Scopus, Web of Science, and Google Scholar to identify recent studies examining alterations in the oral microbiota, microbial translocation, systemic inflammatory responses, blood–brain barrier disruption, cytokine signaling, and neural pathways implicated in brain disorders. Results: Evidence from human and experimental models demonstrates that oral pathogens, particularly Porphyromonas gingivalis, Fusobacterium nucleatum, and Treponema denticola, can disseminate systemically, alter immune tone, and affect neural tissues. Their virulence factors promote microglial activation, cytokine release (IL-1β, IL-6, TNF-α), amyloid-β aggregation, and α-synuclein misfolding. Epidemiological studies show associations between oral dysbiosis and cognitive impairment, motor symptoms in PD, and alterations in mood-related taxa linked to stress hormone profiles. Immunometabolic pathways, HPA-axis activation, and the oral–gut–brain axis further integrate these findings into a shared neuroinflammatory framework. Conclusions: Oral dysbiosis emerges as a modifiable contributor to neuroinflammation and brain health. Periodontal therapy, probiotics, prebiotics, synbiotics, and targeted inhibitors of bacterial virulence factors represent promising strategies to reduce systemic and neural inflammation. Longitudinal human studies and standardized microbiome methodologies are still needed to clarify causality and evaluate whether restoring oral microbial balance can modify the course of neuropsychiatric and neurodegenerative disorders. Full article

Background/Objectives: The treatment of bacterial infections is complicated by emerging antibiotic resistance. This paper identifies a novel approach with a nanoparticle that targets bacterial surface charge and is responsive to the nutrient environment (i.e., glucose) and presence of metabolically active bystander species (i.e., amylase secretion) within microbial communities. Methods: Thus, metabolically responsive composite nanoparticles (440 ± 58 nm) were fabricated via electrohydrodynamic jetting of a cationic starch polymer incorporating 5–7 nm copper nanoparticles (0.3 wt%). Starch was selected as the base polymer, as it is a common carbon source for amylase-producing bacterial communities, in particular under glucose-limited growth conditions. Results: The resulting positively charged particles effectively associated with Gram-positive Staphylococcus aureus, forming co-aggregates with bacterial cells and exhibiting antibacterial activity tenfold greater than free copper nanoparticles. In co-cultures of S. aureus and the amylase-producing bystander species, Bacillus subtilis, enzymatic degradation of the copper–starch nanoparticles increased antibacterial activity against S. aureus by 44%. Conclusions: This work highlights the potential for metabolically regulated particles as a novel paradigm for selective, narrow-spectrum antibacterial therapies that exploit ecological interactions within microbial communities. Full article

Helicobacter pylori infection is a primary cause of gastritis and gastric ulcers. It is crucial to find alternative therapies for H. pylori infection due to the significant side effects of current antibiotics. Heyndrickxia coagulans is an ideal probiotic due to its functionality and stability in production and storage. This study explored the anti-bacterial effects of H. coagulans BHE26 in vitro and in vivo. H. coagulans BHE26 showed notable tolerance to simulated gastric juice (pH 3.0) and 1% bile salts, highlighting its potential suitability for gastrointestinal survival. H. coagulans BHE26 was resistant to ceftriaxone but sensitive to penicillin, ampicillin, erythromycin, gentamicin, ciprofloxacin, ceftriaxone, lincomycin, tetracycline and chloramphenicol. These characteristics showed that H. coagulans BHE26 is a potential probiotic bacterium. In vitro assays demonstrated that H. coagulans BHE26 inhibited H. pylori, reduced urease activity, and displayed notable auto-aggregation and co-aggregation abilities. In vivo, administration of H. coagulans BHE26 alleviated H. pylori-induced gastric mucosal damage, significantly lowered serum anti-bacterial IgG levels, and modulated gastric microbiota composition, including an increase in Turicibacter and a decrease in Lactobacillus abundance. These results indicate that H. coagulans BHE26 alleviated H. pylori-induced inflammation, offering a novel therapeutic strategy against H. pylori infection. Full article