Search Results (108)

Grains and their derivatives play a crucial role as staple foods for the global population. Identifying grains in the food chain that are free from mycotoxin contamination is essential. Researchers have explored various traditional detection methods to address this concern. However, as grain consumption becomes increasingly time-sensitive and dynamic, traditional approaches face growing limitations. In recent years, emerging techniques—particularly molecular-based vibrational spectroscopy methods such as visible–near-infrared (Vis–NIR), near-infrared (NIR), Raman, mid-infrared (MIR) spectroscopy, and hyperspectral imaging (HSI)—have been applied to assess fungal contamination in grains and their products. This review summarizes research advances and applications of vibrational spectroscopy in detecting mycotoxins in grains from 2019 to 2025. The fundamentals of their work, information acquisition characteristics and their applicability in food matrices were outlined. The findings indicate that vibrational spectroscopy techniques can serve as valuable tools for identifying fungal contamination risks during the production, transportation, and storage of grains and related products, with each technique suited to specific applications. Given the close link between grain-based foods and humans, future efforts should further enhance the practicality of vibrational spectroscopy by simultaneously optimizing spectral analysis strategies across multiple aspects, including chemometrics, model transfer, and data-driven artificial intelligence. Full article

Maize is a key crop in Ecuador for both human and animal consumption. Its vulnerability to fungal contamination and mycotoxins poses risks to food safety. The aim of this study was to analyze the occurrence of fungi and mycotoxins in maize grown in different regions of Ecuador (29 localities) and postharvest factors influencing contamination. Fungal identification was performed through culturing and morphological analysis. Analysis of multi-toxins was carried out using liquid chromatography coupled with mass spectrometry (LC-MS/MS). Statistical analyses included PCA and linear regression models. Fungal contamination was found in 93.3% of samples; mycotoxins were present in 90%. Fusarium and Aspergillus were dominant. Fumonisins (66.6%), zearalenone (30%), aflatoxins (16.7%), and trichothecenes B (13.3%) were the most prevalent. Co-occurrence of up to three mycotoxins per sample was observed, more frequent on the coast. Grain moisture and temperature were strongly correlated with contamination levels. The study reveals widespread contamination of Ecuadorian maize, with environmental and postharvest factors playing key roles. This poses a food safety concern, highlighting the need for improved storage and monitoring systems. Full article

Background: Invasive fungal infections (IFIs) after liver transplantation (LT) remain a concern. No universal protocol for antifungal prophylaxis in LT exists. Antifungal prophylaxis varies across European centers. Studies suggest risk stratification for prophylaxis. This study assessed IFI frequency and outcomes in adult LT recipients without antifungal prophylaxis and evaluated risk stratification for predicting IFIs. Method: A retrospective analysis of clinical and microbiological data from 244 liver transplant patients focused on IFI within 100 days post-transplantation. Of these, 225 (92%) had right liver transplants from living donors. We assessed two risk stratification models for predicting IFI: one categorizes patients into low- and high-risk groups, and the other divides patients into three categories, with two eligible for prophylaxis and one not. Results: Of 244 patients, 3% (seven individuals) developed invasive fungal infections (IFI), including two aspergillosis and five candidiasis. IFI occurred in 8% of high-risk and 2% of low-risk patients in the first stratification, with no significant difference between groups (p = 0.144). In the second stratification, IFI was found in 4% of the target and 2% of non-target groups, without a significant difference (p = 0.455). Patients with IFI showed higher mean MELD scores of 21.71 ± 2.35 versus 17.04 ± 6.48 in those without IFI (p < 0.05). Conclusions: This study evaluated IFI outcomes without systemic antifungal prophylaxis in LT recipients. Limited antifungal use in a major living liver donor transplantation (LDLT) group, with low MELD scores and immunosuppression protocols, could be feasible. Future multicenter studies can improve understanding and develop prophylaxis algorithms for LT settings. Full article

Background: Invasive fungal infections (IFIs) are a major complication in patients with acute myeloid leukemia (AML), particularly during chemotherapy-induced neutropenia. Posaconazole is the standard drug for primary antifungal prophylaxis (PAP), but its use is limited by oral bioavailability and CYP3A4 interactions. Study Objective: This study aims to evaluate the clinical efficacy and safety of intravenous caspofungin versus oral posaconazole as PAP in AML patients during their first cycle of chemotherapy and assess their subsequent impact on clinical outcomes. Methods: A retrospective, monocentric study was conducted on 75 consecutive AML patients treated at the Federico II University Medical School of Naples, Italy (2021–2025). Patients received either caspofungin or posaconazole as PAP based on the drug–drug interaction risk or clinical conditions. IFIs were diagnosed using EORTC/MSG criteria. Logistic and Cox regression models were used to assess risk factors and overall survival (OS). Results: IFI incidence was 13.3% overall (9.4% proven/probable). No significant difference was found between the caspofungin and posaconazole groups (six vs. four IFIs; p = 0.878). Post-chemotherapy refractory AML (OR = 11.9; p = 0.003) and liver disease (OR = 30.4; p = 0.004) independently predicted IFI development. Median OS did not significantly differ in patients receiving caspofungin versus posaconazole (29.3 vs. 32.1 months, p = 0.6). Conclusions: Caspofungin appears clinically comparable to posaconazole for PAP in AML during the induction phase, especially when azole use is contraindicated. Prospective studies are warranted to refine prophylactic strategies in the era of new AML therapies. Full article

Within museum depots, the largest part of all heritage collections is stored. Often, the preservation of highly sensitive objects is an ongoing challenge, as the materials are constantly subjected to and influenced by ever-present environmental factors—above all the surrounding climate and other physicochemical processes. Biological degradation is also a major risk for collections. Fungal infestation poses a particular threat, in many regions increasingly the result of climate change. Models for damage prediction and risk assessment are still underdeveloped and require a more substantial database. Approaching this need, nine museum depots and archives were selected in this study. Two years of monitoring the indoor microclimate with thermohygrometric sensors, investigating fungal abundance and diversity through culture-dependent and -independent (metagenomics) approaches, and the collection of relevant additional information resulted in a vast amount of diverse data. The main fungal genera identified through cultivation were Cladosporium, Penicillium, Aspergillus, Alternaria and Epicoccum. The cultivation-independent approach identified Aspergillus, Pyronema, Penicillium, Xenodidymella and Blumeria as the main taxa. Data analyses indicated that key drivers involved in similarities, patterns and differences between the locations were their geographic location, immediate outdoor surroundings and indoor (micro)climatic fluctuations. The study also sheds light on a possible shift in focus when developing strategies for preventing mold growth in collection depots beyond the prevailing path of tightest possible climate control. Full article

Background/objectives: Candida albicans is a major fungal pathogen that poses a serious threat to immunocompromised individuals. The increasing prevalence of fluconazole-resistant strains presents a critical clinical challenge, emphasizing the urgent need for novel therapeutic strategies. This study aimed to evaluate the prophylactic potential of a new liposomal vaccine formulation, Tuft-lip-WCAgs, comprising Tuftsin and C. albicans whole cell antigens, in providing immune protection against systemic candidiasis. Methods: The vaccine formulation was tested in a murine model of systemic C. albicans infection. The efficacy of the Tuft-lip-WCAg vaccine was evaluated through a survival analysis, fungal burden assessments, and immunological profiling. Immune responses were assessed by measuring serum antibody titers and isotypes, T cell proliferation, and cytokine secretion (IFN-γ and IL-4) from splenocytes. Results: FLZ treatment showed weak antifungal activity, high MIC values, and limited biofilm disruption and failed to ensure long-term survival, resulting in 100% mortality by day 40. In contrast, Tuft-lip-WCAg vaccination was well tolerated and conferred complete protection, with no detectable fungal burden by day 40. Vaccinated mice exhibited significantly elevated total antibody titers (166,667 ± 14,434), increased IgG2a levels, and enhanced T cell proliferation (stimulation index: 3.9 ± 0.84). Splenocytes from immunized mice secreted markedly higher levels of IFN-γ (634 ± 128 pg/mL) and IL-4 (582 ± 82 pg/mL), indicating a balanced Th1/Th2 immune response. Tuft-lip-WCAg vaccination also achieved 100% survival and the lowest kidney fungal burden (556 ± 197 CFUs/g). Conclusions: Tuft-lip-WCAg formulation is a safe, immunogenic, and highly effective vaccine candidate that offers complete protection against drug-resistant C. albicans in a murine model. These findings support its promise as a novel immunoprophylactic strategy, particularly for immunocompromised populations at high risk of invasive candidiasis. Full article

Phosphonate-based fungicides are believed to control fungal diseases while also supplying nutrients to plants. However, opinions differ on whether they truly serve as nutrients for plants, and the residues of their transformation products have not yet been thoroughly evaluated or mathematically characterized. To address this gap, this study analyzed data from a two-factorial experiment investigating the effects of Agrifos 400 (potassium phosphonate) application. The experiment involved two soil types: red basalt soil and an organically enriched soil. Three-month-old pepper plants (Piper nigrum L.) were treated with Agrifos at application intervals of 10 and 20 days. The soils were inoculated with pathogenic Pythium spp., known to cause root rot diseases in plants. The soil chemical concentrations were analyzed every ten days, while plant growth parameters (height and leaf numbers) were recorded weekly. A mathematical model describing the fate of Agrifos transformation products was developed and parameterized using this experimental data. The results from the two-month experiment indicated that Agrifos did not enhance plant growth during this period. However, it led to a dramatic increase in soil phosphate (PO₄³⁻) levels, which could pose environmental risks. Despite this, the developed mathematical model demonstrated strong explanatory power, accurately capturing the observed data trends. Consequently, future research should consider integrating this model into broader biogeochemical cycle simulations, particularly those that incorporate chemical transport through soil water. Such integration would support more accurate predictions of the long-term environmental impacts of phosphonate-based products like Agrifos. Full article

Objectives: Microbial keratitis is a precursor to corneal scarring, the fifth-leading cause of blindness and visual impairment worldwide. Despite its significance, there is a paucity of data quantifying the recurrence rates of keratitis and the subsequent corneal damage. This study aims to address this gap by providing a comprehensive analysis of the frequency and origin of keratitis recurrences and its impact on visual deterioration. Methods: We retrospectively analyzed a cohort of 1303 patients diagnosed with microbial keratitis at the Independent Public University Eye Hospital in Warsaw, Poland, between January 2018 and December 2023. All adult patients with at least one documented episode of infectious keratitis were included in the study. Patients were divided into two cohorts: Group 1: patients with recurrent keratitis (n = 233) and Group 2: patients with the first episode of keratitis (n = 1070). Results: The recurrence rate of keratitis was 17.88% (233 of 1303 patients), regardless of etiology. Visual acuity on admission did not differ significantly between the recurrent and naïve groups. However, among patients with at least three episodes, visual acuity was worse (median logMAR for 1 vs. 2 vs. 3 recurrences were the following: 0.30 (0.08–0.67) vs. 0.60 (0.12–1.30) vs. 0.44 (0.20–0.92), accordingly, p = 0.049). Univariate logistic regression identified contact lens usage as a significant risk factor for recurrence (OR 2.37, 95% CI: 1.84–3.08, p < 0.001), also including its inappropriate use (OR 2.25, 95% CI: 1.42–3.66, p = 0.001). In terms of etiology, bacteria were the most common identified cause of keratitis in both the recurrent and naïve groups, accounting for 38.36% (90 cases) in Group 1 and 47% (503 cases) in Group 2. Viruses were the second most prevalent etiology, representing 31.33% (73 cases) in Group 1 and 19.91% (213 cases) in Group 2. Furthermore, a multivariate logistic regression model indicated that advanced age, delayed treatment, fungal etiology, and post-corneal transplant status were strongly associated with worse visual outcomes. Conclusions: Although each recurrence contributes to cumulative vision loss, the majority of patients with recurrent keratitis present with a useful visual acuity (0.3 to 0.60 logMAR). Our study identified older age, fungal etiology, delayed treatment, and post-keratoplasty keratitis as the most significant risk factors for visual deterioration. These findings underscore the need for targeted interventions in populations at higher risk of adverse visual outcomes. Full article

Background: Veno-venous extracorporeal membrane oxygenation (V-V ECMO) represents a progressively adopted life-sustaining intervention worldwide, particularly in the management of acute respiratory distress syndrome. Nevertheless, data concerning the prognostic significance of fungal isolation in this setting remain unclear. This study aims (i) to assess the incidence of fungal infection and colonization in a homogeneous cohort of V-V ECMO patients, and (ii) to evaluate the association between fungal infection or colonization and 1-year mortality, with a focus on the impact of specific fungal species. Methods: All consecutive adults admitted to the Intensive Care Units of five Italian university-affiliated hospitals and requiring V-V ECMO were screened. Exclusion criteria were age < 18 years, pregnancy, veno-arterial or mixed ECMO-configuration, incomplete records and survival < 24 h after V-V ECMO placement. A standard protocol of microbiological surveillance was applied and the distinction between different fungal species were made through in vivo and vitro tests. Cox-proportional hazards models, Kaplan–Meier curves and linear logistic regressions were applied for investigating mortality. Results: Two-hundred and seventy-nine V-V ECMO patients (72% male) were enrolled. The overall fungal isolation was 41% (n. 114): 23% infections and 18% colonizations. The overall 1-year mortality, among fungal isolations, was 40%, with no different risk in case of fungal infection (26 out of 63, 41%) (aHR 0.85, 95% CI [0.53–1.37], p-value 0.505) and colonization (20 out of 51, 39%) (aHR 0.86, 95%CI [0.51–1.43], p-value 0.556), as compared to patients never detecting fungi (68 out of 165, 41%, reference). According to the isolated mycotic species, as compared to Candida sp. group (reference), the risk of death was greater when different fungal species (e.g., Aspergillus sp. and Candida sp.) were concomitantly isolated in the same patient (OR 1.17, 95%CI [1.12–11.07], p-value 0.031. Conclusions: In the overall population, 23% V-V ECMO patients recorded ‘late’ fungal infections and 18% fungal colonizations, with a similar risk of death as compared to patients never experiencing fungi during the V-V ECMO course. The detection of concomitant different fungal species was an independent risk factor for 1-year mortality. Full article

Currently, workers in the ribbed smoked sheet (RSS) rubber production industry face increasing health risks, primarily due to their direct involvement in converting fresh latex into raw rubber sheets. This process involves the manual addition of appropriately diluted commercial formic acid and acetic acid to induce coagulation, resulting in a tofu-like consistency, which is subsequently processed into rubber sheets. Previous studies have indicated that the use of commercial formic and acetic acids poses significant health hazards to workers and contributes to environmental pollution. Therefore, this study explores the feasibility of replacing commercial formic and acetic acids with wood vinegar derived from para-rubber wood, bamboo, and eucalyptus in the RSS production process. Wood vinegar samples from the three biomass sources were analyzed for their organic compound compositions using gas chromatography and subsequently used as coagulants in the preparation of raw rubber sheets. The drying kinetics and antifungal properties of the resulting sheets were then evaluated. The results revealed that wood vinegar derived from para-rubber wood contained the highest concentration of acetic acid (41.34%), followed by bamboo (38.19%) and eucalyptus (31.25%). Rubber sheets coagulated with wood vinegar from para-rubber wood and bamboo exhibited drying kinetics comparable to those obtained using acetic acid, with the two-term exponential model providing the best fit. Conversely, rubber sheets coagulated with eucalyptus-derived wood vinegar, which had a relatively high concentration of phenolic derivatives (22.08%), followed drying behavior consistent with the Midilli et al. model, similar to sheets treated with formic acid. In terms of antifungal properties, five fungal genera—Aspergillus, Penicillium, Fusarium, Trichoderma, and Paecilomyces—were identified on the rubber sheets. Fungal growth was most pronounced in the control samples (untreated with wood vinegar), whereas samples treated with wood vinegar exhibited significantly reduced fungal colonization. These findings indicate that wood vinegar is effective in inhibiting fungal growth on the surface of rubber sheets and may serve as a safer and more environmentally friendly alternative to commercial acid coagulants. Full article

Exposure to patulin (PAT) poses a significant health risk to animals, emphasizing the need for natural, safe substances to mitigate toxicity. Acremonium terricola culture (ATC), a fungal fermentation-derived feed additive, is known for its antioxidant properties, yet its potential to alleviate mycotoxin-induced toxicity remains largely uninvestigated. In this study, the ethanol extracts from the ATC (EEAT) were prepared with a total phenolic content of 67.9 mg GAE/g and a total flavonoid content of 32.7 mg RE/g. Ultra-high performance liquid chromatography coupled with tandem mass spectrometry (UPLC-ESI-MS/MS) analysis was employed to investigate the bioactive components in EEAT. In PAT-exposed Caenorhabditis elegans models, EEAT treatment significantly enhanced locomotory capacity and elevated antioxidant enzyme activities by 63.1% (SOD) and 90.1% (GSH-ST), respectively. Molecular docking analysis revealed that key active compounds in EEAT, such as coumarin, succinic acid, and trigonelline, exhibited effective binding affinities to potential targets SIR-2.1 and DAF-2. Notably, coumarin and trigonelline were most effective in alleviating PAT toxicity, as evidenced by rescued locomotor rates and oxidative impairment in C. elegans. Our findings not only elucidate the molecular basis of EEAT-mediated PAT mitigation but also establish A. terricola culture as a sustainable antioxidant. Full article

The production of organic strawberries (Fragaria × ananassa) in Texas is becoming more popular because consumers prefer locally grown berries and are willing to pay premium prices. However, local climatic conditions pose a high risk for insect problems and fungal diseases; hence, effective pest and disease management strategies are needed. Developing effective and safe methods of producing organic strawberries is necessary for meeting local consumer demand. Therefore, the objective of this study was to evaluate the impacts of selected commercially available soil-applied biopesticides on yield and the quality of Camino Real strawberries established using bare roots on plastic mulch-covered beds with drip irrigation. The ten biopesticide treatments were replicated three times in a completely randomized design. The berries used for this study were subsampled from harvests made in mid-April, late April, and mid-May 2019. Yield, biometrical characteristics, and physicochemical analyses such as pH, acidity, total soluble solids, sugars and organic acid contents, firmness, and instrumental color were determined for fresh strawberries after each harvest period. Experimental data were analyzed using the PROC Mixed model procedure. The effects of the soil-applied biopesticide treatments on strawberry yield varied. The results of strawberry yield suggest that biopesticides applied at the right time and frequency have the potential to perform at similar levels to their conventional counterparts. Camino Real strawberries treated with biopesticides, harvested during mid-April, late April, or mid-May, exhibited acceptable flavor based on the recommended values of TA and TSS for strawberries. The biopesticides showed no negative effects on yield and fruit quality and thus they could serve as alternatives to conventional products used. Full article

This review of the literature examines diseases and pathogen characteristics on military vessels, in order to improve the success of missions on a boat. Our aim is to understand the spread of disease, aiming to maximize biological resilience and hopefully eliminate outbreaks. Keyword research was conducted from various sources of information, including scientific publications, theses, public health organization websites, and clinical trials. A synthesis of bacterial, viral, fungal, and parasitosis characteristics was established, and a risk prioritization index was defined, based on contagiousness (basic reproduction number (R0)) and clinical severity. For instance, COVID-19 was assessed as moderately contagious, with critical severity, and Influenza A H1N1 as having a minor level of contagiousness with critical severity, resulting in a level two out of three risk prioritization index. This approach demonstrates that while diseases have numerous characteristics, a method for classifying them by isolating specific criteria and prioritizing them could be proposed. In conclusion, further work is needed to analyze onboard operator activities and develop simulation models related to pathogen characteristics. Full article

The presence of fungal spores in water poses a significant risk to public health, requiring effective inactivation strategies. Ultraviolet (UV) radiation is a widely used approach, traditionally employing mercury vapor lamps. However, these lamps have efficiency limitations and contain hazardous materials. As an alternative, ultraviolet light-emitting diodes (UV-LEDs) have emerged as a safer and more sustainable option. Despite their advantages, research on their efficacy against fungal spores remains limited. This study investigates the inactivation and post-exposure response of Aspergillus niger and Penicillium sp. spores using a collimated UV-LED system. The impact of two different wavelengths (265 nm and 280 nm) and post-treatment conditions (light and darkness for 24 h) on fungal viability was analyzed. Kinetic modeling was applied to assess the resistance of the spores and their capacity for photoreactivation. The results demonstrate that both the UV wavelength and the environmental conditions after exposure significantly influence disinfection outcomes. Penicillium sp. exhibited greater susceptibility to UV radiation but also higher photoreactivation potential, while A. niger showed stronger resistance and lower recovery capacity. The UV dose required for 99% inactivation, considering photoreactivation effects, was 323.7 ± 90.0 mJ cm⁻² and 321.9 ± 43.8 mJ cm⁻² for A. niger, whereas for Penicillium sp., it was 167.7 ± 13.0 mJ cm⁻² and 146.5 ± 29.2 mJ cm⁻² at 265 nm and 280 nm, respectively. These findings emphasize the necessity of tailoring UV-LED disinfection strategies based on the specific characteristics of the target organisms and post-treatment environmental factors. Full article

Background: Globally, neonatal fungal sepsis (NFS) is a leading cause of neonatal mortality, particularly among vulnerable populations in neonatal intensive care units (NICU). The use of spatial frailty models with a Bayesian approach to identify hotspots and risk factors for neonatal deaths due to fungal sepsis has not been explored before. Methods: A cohort of 80 neonates admitted to the NICU at a Government Hospital in Tamil Nadu, India and diagnosed with fungal sepsis through blood cultures between 2018–2020 was considered for this study. Bayesian spatial frailty models using parametric distributions, such as Log-logistic, Log-normal, and Weibull proportional hazard (PH) models, were employed to identify associated risk factors for NFS deaths and hotspot areas using the R version 4.1.3 software and QGIS version 3.26 (Quantum Geographic Information System). Results: The spatial parametric frailty models were found to be good models for analyzing NFS data. Abnormal levels of activated thromboplastin carried a significantly higher risk of death in neonates across all PH models (Log-logistic, Hazard Ratio (HR), 95% Credible Interval (CI): 22.12, (5.40, 208.08); Log-normal: 20.87, (5.29, 123.23); Weibull: 18.49, (5.60, 93.41). The presence of hemorrhage also carried a risk of death for the Log-normal (1.65, (1.05, 2.75)) and Weibull models (1.75, (1.07, 3.12)). Villivakkam, Tiruvallur, and Poonamallee blocks were identified as high-risk areas. Conclusions: The spatial parametric frailty models proved their effectiveness in identifying these risk factors and quantifying their association with mortality. The findings from this study underline the importance of the early detection and management of risk factors to improve survival outcomes in neonates with fungal sepsis. Full article