Search Results (3,632)

Background/Objectives: Nosocomial outbreaks of viral respiratory infections strain healthcare systems and endanger patients and healthcare workers (HCWs). We describe two large nosocomial outbreaks with the SARS-CoV-2 Alpha variant, during its initial emergence in Germany, to assess transmission dynamics, effectiveness of control measures, and challenges in managing highly transmissible respiratory viruses. Methods: Confirmed cases were inpatients, HCWs, or their contacts testing SARS-CoV-2-positive since 1 January 2021 (Hospital A [HA])) or 21 January 2021 (Hospital B [HB])) with N501Y and delH69/V70 spike gene mutations. We conducted case interviews, reviewed medical records and shift schedules, and performed sequencing, genome reconstruction, and phylogenetic analysis. We describe cases, transmission chains, and control measures. Results: HA reported 18 patient cases, 20 HCW cases, and 33 community cases (N = 71). HB reported 48 patient cases, 43 HCW cases (13 in a COVID-19 ward), and 27 community cases (N = 118). In-hospital transmission occurred patient-to-patient, HCW-to-patient, patient-to-HCW, and HCW-to-HCW. HA halted admissions immediately after the initial cases; HB implemented measures gradually. Regular testing detected pre-symptomatic (HA = 6; HB = 18) and asymptomatic cases (HA = 3; HB = 13). Testing of agency staff was incomplete. The suspected primary case was an HCW in HA and a patient in HB who required resuscitation shortly after admission. Conclusions: Early COVID-19 outbreaks offer valuable lessons for managing emerging nosocomial outbreaks of highly transmissible respiratory viruses. Our findings provide empirical evidence for effective interventions, including rapid response, testing, HCW protection, and rigorous contact tracing in high-risk emergency situations. Managing agency staff remains a major challenge. Full article

Traditional concert-hall evaluations primarily rely on ISO 3382-1 scalar parameters (e.g., C₅₀ and C₈₀), which summarize temporal energy behavior but provide limited insight into the directional composition of early reflections, particularly in geometrically shadowed seating zones. This paper presents a first-order Ambisonics (FOA)-based 3D acoustic sensing framework to diagnose under-balcony directional imbalance, with emphasis on early vertical-reflection deficiency. Scene-based FOA impulse responses (WXYZ) were measured at 11 audience positions (P1–P11) in the National Concert Hall (Taipei) and analyzed using intensity-based direction-of-arrival (DoA) proxies, axis-resolved directional energy build-up, and a distributional descriptor based on directional spatial entropy. Results are presented at three representative frequencies (125 Hz, 1 kHz, and 4 kHz) and analyzed within full (0–200 ms), early (0–80 ms), and late (80–200 ms) windows. While the magnitude proxy $\mid p^{meas}\left(f\right)\mid$ exhibits strong seat-to-seat variability and does not support a uniform attenuation assumption under the balcony, direction-resolved metrics reveal a consistent under-balcony signature. Specifically, the early–late vertical energy discrepancy $\Delta R_z={\displaystyle R_z^{early}}-{\displaystyle R_z^{late}}$ is persistently negative at under-balcony positions (P7–P11) across all three frequencies, indicating a selective reduction in early vertical contribution relative to the late field. Directional entropy analysis further shows predominantly negative $\Delta H_n={\displaystyle H_n^{early}}-{\displaystyle H_n^{late}}$, with more negative values in the under-balcony group, consistent with stronger early directional constraint in shadowed seats. Spatial trend maps are provided via Gaussian RBF interpolation within the audience domain for visualization only. The proposed FOA-based diagnostic framework provides a practical and physically interpretable approach to identify direction-specific early-reflection deficits that remain masked in conventional scalar evaluations, supporting mechanism-oriented assessment and targeted intervention in geometrically constrained listening areas. Full article

Cellulose nanocrystals (CNCs) are highly desirable nanomaterials for reinforcing biopolymer films. Coconut husks are generated in massive quantities after harvesting and processing, leading to waste management issues. This study isolated and characterized CNCs from young (y-CNCs) and mature (m-CNCs) coconut husks via acid hydrolysis (32% H₂SO₄, 50 °C, 5 h), comparing them with commercial CNCs (c-CNCs) to evaluate their performance in gelatin-based films. TEM confirmed rod-shaped morphology for all CNCs. Notably, m-CNCs exhibited a smaller particle size (199 nm), a higher surface charge (−46.8 mV), and superior crystallinity (63.98%), demonstrating properties comparable to c-CNCs. FTIR and XRD confirmed characteristic cellulose functional groups and crystalline structure, while TGA demonstrated excellent thermal stability above 300 °C for all samples. Incorporation of CNCs into gelatin films significantly improved tensile strength (from 15.63 to 24.93 MPa) and reduced water vapor permeability (from 2.65 to 2.43 × 10⁻¹⁰ g m m⁻² s⁻¹ Pa⁻¹; p < 0.05). These findings demonstrate how coconut husk residues can be upcycled into high-value nanomaterials fostering economic growth with innovation in sustainable manufacturing. This research also promotes responsible waste utilization, highlighting the benefits of biodegradability and a reduced carbon footprint for sustainable food packaging applications. Full article

Mesoporous bioactive glass nanoparticles (MBGNs) are promising for bone tissue engineering; however, surgical site infection and oxidative stress often compromise regeneration. To address this, MBGNs co-doped with cerium (Ce), zinc (Zn), and strontium (Sr) were synthesized using a microemulsion-assisted sol-gel route (xCe-yZn-Sr-MBGNs; x = 0, 1, 2; y = 0, 0.5, 1). The resulting spherical nanoparticles (150–200 nm) exhibited a mesoporous structure with a specific surface area of (~340–425 m²/g), sustained ion release, and apatite formation in simulated body fluid. In vitro evaluations with MC3T3-E1 pre-osteoblasts demonstrated dose-dependent cytocompatibility, specifically in the co-doped formulations; however, higher Ce concentrations (2Ce-yZn-Sr-MBGNs) reduced viability following prolonged exposure. Crucially, the 1Ce-1Zn-Sr-MBGNs significantly enhanced osteogenic differentiation, as evidenced by a two-fold increase in osteogenic marker gene expression and a ~45% increase in calcium mineral deposition compared to undoped MBGNs within 14 days. Moreover, these particles accelerated cell migration, achieving ~70% scratch-wound closure within 24 h. Furthermore, 1Ce-1Zn-Sr-MBGNs displayed strong radical scavenging capacity and potent antibacterial activity against S. aureus and P. aeruginosa. These findings indicated that 1Ce-1Zn-Sr-MBGNs exhibited multiple therapeutic effects, including antibacterial, radical-scavenging, and osteogenic effects. By optimizing dopant ratios, these multifunctional nanomaterials emerge as promising candidates for next-generation bone grafts or implant coatings. Within the scope of this study, they demonstrated the capacity to simultaneously address three critical challenges in bone healing: controlling infection, mitigating oxidative stress, and promoting mineralized tissue formation. While these in vitro results provide a robust foundation, further in vivo validation is warranted to confirm their efficacy within complex physiological environments. Full article

Raphidiopsis raciborskii (formerly Cylindrospermopsis raciborskii) is a bloom-forming cyanobacterium that employs the production of toxins and other secondary metabolites as a competitive and allelopathic strategy. This study evaluated the effects of exudates from R. raciborskii cultivated under three nitrogen-to-phosphorus (N:P) ratios on the photosynthetic performance of Limnothrix sp. (cyanobacterium), Chlorella sp. (green algae), and Raphidocelis subcapitata (green algae), using pulse-amplitude-modulated (PAM) fluorometry. Rapid light curves (rETR) obtained under different N:P ratios and across the three target species exhibited similar response patterns. Likewise, effective quantum yield (ΦPSII), regulated (Y(NPQ)) and non-regulated (Y(NO)) energy dissipation showed comparable profiles among treatments after 24 h of exposure. Overall, the results of the present study indicate that, within the 24 h exposure period and based on the fluorescence parameters measured, exudates produced by R. raciborskii under the tested nutrient conditions did not cause measurable alterations in the photosynthetic performance of the three evaluated species. Full article

Heat stress, intensified by global warming, poses a great threat to plant growth and crop production. However, the molecular mechanisms underlying heat stress response (HSR) remain largely unclear. In this study, we identified and characterized SlFBX38, an F-box gene in tomato. SlFBX38 was predominantly expressed in leaves and fruits, and its expression levels were induced by heat stress and various phytohormones, including ABA, JA and SA. Subcellular location analysis revealed that SlFBX38 resides in both the nucleus and cytoplasm in N. benthamiana leaf cells, but it displays no transcriptional activity. Overexpression of SlFBX38 (OE) lines conferred enhanced heat stress tolerance, as evidenced by improved photosynthetic efficiency, elevated accumulation of ascorbic acid (AsA), stronger protective enzyme activities, and upregulation of HSR-related genes in SlFBX38-OE lines under heat stress condition. To identify potential interacting proteins, yeast two-hybrid (Y2H) library screening and further Y2H verification indicate that SlFBX38 may interact with SlbHLH058. Collectively, these findings establish SlFBX38 as a positive regulator of thermotolerance in tomato and provide a basis for further mechanistic studies of its role in HSR. Full article

Drought stress severely restricts the growth of pear trees. As a widely used drought-tolerant rootstock, Pyrus betulifolia exhibits stable growth performance; however, the molecular mechanisms underlying its drought tolerance remain to be elucidated. In this study, we investigated the molecular responses of P. betulifolia leaves to osmotic stress induced by 20% PEG-4000 using time-series RNA-seq technology. A total of 3745 differentially expressed genes were identified, with transcriptional changes peaking at 6 h, indicating a critical phase of transcriptional reprogramming during drought response. Genes associated with osmotic adjustment (e.g., P5CS) and oxidative stress responses (e.g., SOD and POD) were significantly upregulated between 6 and 12 h. Weighted gene co-expression network analysis (WGCNA) identified three distinct temporal modules and screened out NF-Y, RVE1, COL9, COL6, C2C2 zinc finger proteins, and Pseudo ARR-B as putative key regulators, whose expression patterns were validated using qRT-PCR. Collectively, these results provide a comprehensive view of the temporal transcriptional dynamics of drought response in P. betulifolia and offer valuable candidate gene resources for further functional studies and drought tolerance breeding. Full article

Amid growing environmental pressure and increasing demand for resource sustainability, the efficient recovery of valuable metals from spent lithium-ion batteries (LIBs) has become a critical challenge in the field of resource recycling. Therefore, a novel approach is presented for selective lithium (Li) and manganese (Mn) separation from LiNi_xCo_yMn_1−x−yO₂ by combining carbothermic reduction roasting and selective leaching. Low-cost glucose (C₆H₁₂O₆) was selected as the reduction roasting reductant, which converts the cathode materials into water-soluble lithium carbonate (Li₂CO₃), water-insoluble cobalt (Co), nickel (Ni), and manganese oxide (MnO). Wet magnetic separation was employed to preferentially extract Li while simultaneously removing excess carbon from Ni, Co, and MnO. Under optimal roasting conditions at 600 °C for 90 min followed by wet magnetic separation with a liquid–solid ratio of 30 mL/g for 30 min, 95.42% of Li was preferentially extracted. Subsequently, at a formic acid (HCOOH) concentration of 1.6 mol/L, liquid–solid ratio of 6 mL/g, and leaching time of 30 min, 94.29% of Mn was selectively extracted from the wet magnetic separation products, whereas Ni and Co were leached at 6.13% and 7.22%, respectively. The acid-leaching residue can be recycled as a Ni-Co alloy. Full article

The stability, elasticity, and thermoelectric property of ABX₃ (A = K, Ag, Cu; B = Si_xGe_ySn_zPb_{(1−x−y−z)}; X = Br, I) metal halide perovskites (MHPs) with B-type medium entropy sub-lattices (MESLs) are investigated by first principles calculations. The results show that the order of dissociation formation enthalpy ${\Delta H}_{\mathrm{f}}$ for conventional unit cell APbX₃ with changing atomic type in the A site is K < Ag < Cu, and for each case Br < I. The ${\Delta H}_{\mathrm{f}}$ values of (KBBr₃, KBI₃, AgBBr₃) and (CuBBr₃, CuBI₃, AgBI₃) with MESL in the B site slightly increase and decrease, respectively, with the exception of certain situations. By using Slack’s model, the lattice thermal conductivity (LTC) ${\kappa }_l$ at finite temperatures is obtained. It is found that the LTC ${\kappa }_l$ for all MHPs shows an extremely low value at room temperature, not exceeding 1.5 Wm⁻¹K⁻¹. Interestingly, it is also found that the B-type MESLs significantly increase the ZT_max values of KPbX₃, whereas they decrease the ZT_max values of CuPbX₃ and AgPbX₃, except for in some cases. All calculated parameters show obvious variation laws with the increase in atomic number of the high-content B-type atom in the ABX₃, and CuBX₃ and AgBX₃ materials exhibit an extremely low ZT value (ZT ≈ 0) due to their high σ accompanied by high ${\kappa }_e$ and low S. We believe that KSi_0.375Ge_0.25Sn_0.25Pb_0.125Br₃ with a ZT value of 3.012 can serve as an excellent thermoelectric material at room temperature. These findings make contributions to the design of high-quality thermoelectric MHP materials. Full article

The development of shelf-stable functional foods remains a key challenge in probiotic product formulation, particularly for non-dairy alternatives adapted to traditional diets. Amlou, a Moroccan spread made from argan oil, almonds, and honey or sugar, may serve as a promising plant-based probiotic carrier. This study evaluated the viability of three LAB strains, Lactobacillus gasseri (commercial), Latilactobacillus sakei AE126, and Enterococcus durans Y17, in seven Amlou formulations containing varying argan oil (5–10%) and sugar (0–10%) concentrations. Samples were stored at ambient temperature (25 °C) for 45 days. Viability, pH, and water activity were monitored periodically. Probiotic survival significantly depended on formulation (ANOVA, p < 0.05). Viability losses remained below 1 log CFU/g across all samples. The best results were observed in formulations containing 10% argan oil and either 0% or 5% sugar, depending on the probiotic strain, suggesting a synergistic protective effect of lipids and moderate carbohydrate levels. These findings indicate that Amlou could serve as a shelf-stable, culturally relevant carrier for probiotic delivery. Full article

Neurodegenerative disorders (NDs), such as Alzheimer’s disease and Parkinson’s disease (PD), represent a significant challenge for ageing populations, with their prevalence increasing worldwide. Elevated human Monoamine Oxidase B (hMAO-B) activity has been related to neurodegenerative progression, where it contributes, among others, to oxidative stress and neuroinflammation. The identification and optimization of selective hMAO-B inhibitors is therefore pivotal in addressing the progression of NDs. In this work we introduced 2-aroylbenzothiophene analogues as promising agents to mitigate neurodegeneration. The synthesized compounds were screened against hMAO-A and hMAO-B, identifying compounds 4, 11, and 12 as the most promising. In vitro studies in hGF and SH-SY5Y cells revealed distinct toxicity profiles, with compound 4 being the least tolerated at 100 µM. ROS generation was investigated as a possible mechanism underlying this toxicity. Compounds 4 (12.5 µM), 11, and 12 (100 µM) were further evaluated for neuroprotective effects against 6-hydroxydopamine (6-OHDA)-induced toxicity in SH-SY5Y cells, showing a modest neuroprotective effect after 72 h at a sub-toxic 6-OHDA concentration (250 µM), comparable to the clinically used hMAO-B inhibitor (R)-(−)-Deprenyl at 100 µM. Finally, molecular modelling studies revealed that compound 4 establishes key stabilizing interactions within hMAO-B, accounting for its high inhibitory potency and selectivity over hMAO-A. Full article

Gamma-aminobutyric acid (GABA) has been implicated in gut–brain interactions and neuronal activation. We hypothesized that GABA could ameliorate memory decline. We investigated whether oral GABA administration ameliorated age-related cognitive decline in aged mice (C57BL/6J, male) and explored the role of circulating exosomes in mediating these effects. Aged mice that drank water containing 0.5% GABA exhibited significantly improved discrimination index scores compared with that of controls, indicating enhanced memory function. Their plasma-derived exosomes induced neurite outgrowth and mitochondrial activation and restored neuronal activity in SH-SY5Y cells. GABA enhanced the exosomal expression of several miRNAs linked to neuronal activation, longevity, and anti-senescence pathways. Plasma-derived exosomes also restored object recognition memory, reduced hippocampal neuroinflammation, and decreased senescent cell markers (p21 and γH2AX) in aged mice. Additionally, mitochondria- and neurite-related genes were upregulated, and pathways associated with oxidative phosphorylation and Alzheimer’s disease were enriched. Collectively, long-term GABA administration was found to improve cognitive function of aged mice through the secretion of functional exosomes. Full article

Background: Sexual dysfunction (SD) and sleep disturbances are frequent but underrecognized non-motor symptoms in Parkinson’s disease (PD) and significantly affect quality of life. However, the relationships among sexual dysfunction, sleep quality, and excessive daytime sleepiness (EDS) and the possible sex-related differences remain insufficiently investigated. Methods: In this cross-sectional case–control study, we evaluated these non-motor symptoms in 147 Turkish patients with PD and 160 age- and sex-matched healthy controls, and we assessed their associations and impact on quality of life, with particular attention to sex-specific patterns. Sexual function was assessed using the Arizona Sexual Experiences Scale (ASEX), sleep quality using the Pittsburgh Sleep Quality Index (PSQI), daytime sleepiness using the Epworth Sleepiness Scale (ESS), quality of life using the 39-item Parkinson’s Disease Questionnaire (PDQ-39), and disease severity using the Unified Parkinson’s Disease Rating Scale (UPDRS) and Hoehn and Yahr (H&Y) staging scale. Group comparisons, correlation analyses, and sex-stratified subgroup analyses were performed. Results: Patients with PD had significantly higher ASEX, PSQI, and ESS scores compared with controls (p < 0.01), and women with PD had significantly higher total ASEX scores than men, indicating greater sexual dysfunction. Sexual dysfunction was significantly associated with poor sleep quality and excessive daytime sleepiness but showed no significant association with the motor severity measures (UPDRS, H&Y stage). Sleep quality, as measured via PSQI scores, was worse in patients with PD, and poor sleep quality and excessive daytime sleepiness were both associated with significantly worse quality of life. Conclusions: According to our findings, sexual dysfunction and sleep disturbances are interrelated non-motor symptoms that significantly impair quality of life, largely independently of motor severity, and these associations were particularly pronounced among women. A combined evaluation of sleep and sexual function may therefore improve the recognition and management of the non-motor burden in PD. Full article

This study investigated the biochemical composition and antioxidant potential of flours from pigment-deficient Chlorella vulgaris variants (honey and white) and wild-type (green) and the impact of lactic acid bacteria–yeast co-culture fermentation. The three variants were characterized for composition, total polyphenol (TPC) and flavonoid (TFC) contents, antioxidant capacity (DPPH, FRAP, and ORAC assays), and reactive oxygen species production in HT-29 intestinal cells. All extracts were noncytotoxic up to 100 µg/mL. Among all variants, the green showed the highest native TPC, TFC, and overall antioxidant activity. TPC and TFC were similar between honey and white, while FRAP was higher in honey and ORAC was higher in white. Biomasses were subsequently fermented for 24 h using Lactiplantibacillus plantarum CR L1 or Levilactobacillus brevis L204 with either Saccharomyces cerevisiae TRE Y100 or Kluyveromyces marxianus MK Y55. Fermentation resulted in significant pH reduction and increases in titratable acidity and lactic acid production, particularly in co-cultures involving K. marxianus. However, the effects on antioxidant properties were strongly matrix-dependent, with significant increases in TPC and antioxidant activity observed only in the white variant. Overall, pigmentation and microbial pairing emerged as key determinants of metabolic outcomes. These findings highlight the potential of co-culture fermentation to enhance the bioactive profile of pigment-deficient C. vulgaris, supporting their application in functional foods. Full article

Acute and chronic wounds are a major clinical burden, with persistent inflammation, impaired fibroblast function, defective angiogenesis, and disordered extracellular matrix deposition. The translational potential of existing in vitro models is limited by their poor durability and physiological relevance. The present paper aims to develop a robust in vitro organotypic model to simulate the early phases of both acute and chronic wounds and to validate it by testing the biocompatibility of clinically available wound dressings. Human fibroblasts and vascular endothelial cell lines were cultured at a ratio of 1:1 for 48 h, either on uncoated tissue culture plastic or on tissue culture plastic coated with a synthetic substrate (PhenoDrive-Y) that biomimics the extracellular matrix and promotes cell organization into tissue-like structures on a 2D plane (i.e., angiogenesis sprouting and fibroblast organization around it). Wound conditions were then created by damaging the formed structures using a conventional scratch procedure and introducing U937 human macrophage cells to the model to simulate either the onset of an acute wound or that of a chronic wound through the simultaneous spiking of the culture with relevant cytokines, i.e., IL-6 and TNF-α. The formation of new tissue-like structures in the scratch area was quantified by the extent of scratch closure after a further 24 h of incubation. Morphological analysis of wound healing was performed by light microscopy, while angiogenesis was assessed by CD31 immunostaining by confocal microscopy. The deposition of components of the extracellular matrix was determined both qualitatively and quantitatively by Picrosirius Red staining for collagen production and by Alcian Blue staining for glycosoaminoglycan synthesis on the adhering cells and their supernatants. Macrophage polarization into either M1 or M2 phenotype was studied by immunostaining with iNOS (M1) and CD206 (M2) antibodies by confocal microscopy. The model was validated by studying the gap closure areas in simulated acute and chronic wound-like conditions when incubated with clinically available wound dressings, N-A Ultra and Kaltostat. PhenoDrive-Y allowed the formation of tissue-like structures on the 2D tissue culture plane as opposed to the formation of cell monolayers on the uncoated tissue culture plastic. Upon mechanical damage, cell migration was significantly different; uncoated control co-cultures achieved complete closure as an indistinct monolayer by 24 h, while the organotypic wound models showed a slower percentage of damage closure. A further delay in the closure of the damaged area was observed when chronic wound-like conditions were simulated. Angiogenesis in chronic wound conditions was considerably impaired compared to the acute conditions. The analysis of the extracellular matrix component synthesis, specifically collagen and polysaccharides, revealed the deposition of dense, organized collagen fibers in the acute wound model, in contrast to the thin, fragmented collagen fibers and intracellular polysaccharides observed under chronic wound-like conditions. This corresponded to a statistically significant increase in the levels of both collagen and polysaccharides detected as soluble molecules in the supernatants. Macrophage polarization showed no statistically significant differences in the acute and chronic wound models, though iNOS did significantly decrease after N-A application in acute and chronic models. However, acute wound-like conditions showed a restoration of the vascularized tissue-like structures after treatment with these types of dressings, albeit through different organizational pathways, whereas only minimal improvement was noted under chronic wound conditions, particularly in the case of the N-A dressing. The organotypic dermis model for the onsets of acute and chronic wounds emerges as a highly versatile tool to understand healing mechanisms in the absence or presence of co-morbidities and to assess the biocompatibility of wound dressings as well as the safety, efficacy and dosage of drugs. Full article