Search Results (790)

At many recreational beaches, the health of visitors is protected through water quality monitoring programmes. However, visitors may also be exposed to microbiological pathogens in sand via ingestion, inhalation and skin contact. Microbiological pathogens that can cause human illness may be naturally found in beach sands, or introduced with people, animals or water entering the beach. The World Health Organization has recommended that recreational water safety plans consider microbial pathogens in beach sand. This review shows that a range of faecal and non-faecal pathogens can be detected in beach sand, but difficulty in determining whether exposure occurred via the sand or water means that there is insufficient evidence to link their presence with adverse human health effects. Proactively integrating beach sand testing into recreational water safety programmes will generate data to assess the impact of risk management activities. The use of faecal indicator bacteria to indicate elevated risk from faeces should be a priority where there are potential sources of contamination. This should be complemented with sanitary surveys and analyses that elucidate faecal contamination sources. The inclusion of non-faecal pathogens into monitoring programmes needs further, locally relevant justification through evidence from epidemiological studies and human health risk assessment. Full article

This pilot study uses Raman spectroscopy and SERS to monitor monthly water composition changes in two adjacent hypersaline lakes (L1 and L2) at a balneary resort, during the peak tourist season (May–October 2023). In situ pH and electrical conductivity (EC) measurements, along with evaporite analyses, complemented the spectroscopic data. Although traditionally considered similar, the lakes frequently raise public questions about their relative bathing benefits. While not directly addressing the therapeutic effects, the study reveals distinct physicochemical profiles between the lakes. Raman data showed consistently higher sulfate levels in L2, a trend also observed in winter monitoring. pH levels were higher in L1 (8–9.8) than in L2 (7.2–8), except for one October depth reading. This trend held during winter, except in April. Surface waters showed more variability and slightly higher values than those at 1 m depth. SERS spectra featured β-carotene peaks, linked to cyanobacteria, and Ag–Cl bands, indicating nanoparticle aggregation from inorganic ions. SERS intensity strongly correlated with pH and EC, especially in L2 (r = 0.96), suggesting stable surface–depth chemistry. L1 exhibited more monthly variability, likely due to differing biological activity. Although salinity and EC were not linearly correlated at high salt levels, both reflected seasonal trends. The integration of Raman, SERS, and physicochemical data proves effective for monitoring hypersaline lake dynamics, offering a valuable tool for environmental surveillance and therapeutic water quality assessment, in support of evidence-based water management and therapeutic use of salt lakes, aligning with goals for sustainable medical tourism and environmental stewardship. Full article

Water treatment systems in swimming ponds support the natural self-cleaning capabilities of water based on the functions of repository macrophytes in their regeneration zone and the regulation of the internal metabolism of the reservoirs. As part of the project, a functional modular filtration chamber with system multiplication capabilities was designed and created. This element is dedicated to water treatment systems in natural swimming ponds. The prototype system consisted of modular filtration chambers and pump sections, as well as equipment adapted to the conditions prevailing in the eco-pool. An innovative solution for selective shutdown of the filtration chamber without closing the circulation circuit was also used, which forms the basis of a patent application. A verified high-performance adsorbent, Rockfos^® modified limestone, was used in the filtration chamber. In order to determine the effective filtration rate for three small test ponds with different flow rates (5 m/h, 10 m/h and 15 m/h), the selected physicochemical parameters of water (temperature, pH, electrolytical conductivity, oxygen saturation, total hardness, nitrites, nitrates, and total phosphorus, including adsorption efficiency and bed absorption capacity) were researched before and after filtration. Tests were also carried out on the composition of fecal bacteria and phyto- and zooplankton. Based on high effective phosphorus filtration efficiency of 32.65% during the operation of the bed, the following were determined: no exceedances of the standards for the tested parameters in relation to the German standards for eco-pools (FLL—Forschungsgesellschaft Landschaftsentwicklung Landschaftsbau e. V., 2011); lower number of fecal pathogens (on average 393—coliform bacteria; 74—Escherichia coli; 34—fecal enterococci, most probably number/100 mL); the lowest share of problematic cyanobacteria in phytoplankton (<250,000 individuals/dm³ in number and <0.05 µg/dm³—biomass); low chlorophyll a content (2.2 µg/dm³—oligotrophy) and the presence of more favorable smaller forms of zooplankton, an effective filtration speed of 5 m/h. This velocity was recommended in the FLL standards for swimming ponds, which were adopted in this study as a reference for rapid filters. In testing the functional efficiency of a dedicated filtration system for a Type II test pond (50 m²—area and 33 m³—capacity), at a filtration rate of 5 m/h, an average effective phosphorus adsorption efficiency of 18.28–53.98% was observed under the bed work-in-progress conditions. Analyses of other physicochemical water parameters, with appropriate calculations and statistical tests, indicated progressive functional efficiency of the system under bathing conditions. Full article

The galvanic industry requires considerable amounts of water and produces significant quantities of wastewater. Two types of wastewater are created in the processes of the galvanic application of metal coatings: used galvanic baths and wastewater generated while rinsing coated elements. The composition and amount of wastewater depend on the type of process, the plant’s operational system, and the quantity of water utilised to rinse the coated elements. In this article, the possibilities of using different techniques, such as chemical precipitation, coagulation and flocculation, ion exchange, adsorption, and membrane filtration, to remove heavy metals from galvanic wastewater were analysed and assessed. It was determined that the use of physicochemical methods (i.e., chemical precipitation, coagulation, and flocculation) to remove heavy metals has significant disadvantages, including operational costs connected with the purchase of chemical reagents and the emergence of metal complexes requiring management/utilisation. On the other hand, the processes of ion exchange and adsorption can be used only for wastewater characterised by a low heavy metal concentration, with organic matter preliminarily removed. In addition, waste polluted with heavy metals in the form of used regenerative baths and used sorbents is generated during these processes. In turn, the advanced techniques of membrane filtration allow for the removal of different types of organic pollutants and heavy metals. The processes of membrane wastewater treatment exhibit a range of advantages compared to traditional technologies, including the complete, environmentally friendly removal of permanent organic pollution, easy integration into conventional technologies, a limited amount of residue, a high level of separation, and a shorter process time. The efficiency of membrane wastewater treatment depends on many parameters, including, most of all, the composition, pH, and type of membrane, as well as process conditions. The possibility of using new types of membranes to remove heavy metals from spent galvanic baths was analysed, and the possibility of using the processes in wastewater treatment systems according to the circular economy model was assessed. The assessment of the efficiency of heavy metal removal in hybrid systems combining specific individual processes and the development of state-of-the-art material solutions to realise these processes may be an interesting direction of research in this field. Full article

Background/Objectives: Heat processing techniques can alter the energy and nutritional value of meat. This study examined the effect of various types of heat processing (water bath cooking WBC, oven convection roasting OCR, grilling G, and pan frying PF) on the content and retention of vitamins A, D, E, K, and cholesterol in White Kołuda^® goose breast meat without or with skin (n = 36). Methods: The contents of fat-soluble vitamins and cholesterol were determined by High-Performance Liquid Chromatography (HPLC). Cooking loss (CL), retention, and the percentage coverage of the Nutrient Reference Values (NRV) for vitamins in adults by 100 g of meat were calculated. Results: The CL was higher (p ≤ 0.01) in goose breast meat with skin (43.2%) compared to skinless meat (37.1%). The contents of vitamins A, D, E, K, and cholesterol were also significantly greater (p ≤ 0.01) in meat with skin than in meat without skin. The G and PF resulted in the greatest reductions in A, D, E, and K compared with raw meat. The highest retention (>52%) was observed after WBC, whereas the lowest (<43.7%) occurred after PF, although the difference was statistically significant (p ≤ 0.01) only for vitamin D. While 100 g of raw goose breast meat provided the highest percentage of NRV for the analyzed components, WBC appeared to be the most favorable cooking method for consumers. Conclusions: Our research can help consumers choose goose meat as an alternative to red meat to diversify and balance their diet. WBC ensures the least loss of fat-soluble vitamins while ensuring the health safety of meat, which may be important information for consumers, the catering industry, and the poultry industry. Full article

This study investigated the sustainable dyeing process of two natural dyes, Phellodendron Bark and camphor fruit, on oak veneer. The oak was pretreated with SC-CO₂ and dyed using three methods, namely conventional water bath, SC-CO₂, and vacuum pressurization, and the dyeing rate, color difference, washing fastness, and sunlight fastness were compared horizontally. BET test showed that the specific surface area of the oak was increased by 38%, the pore volume was increased by 46%, and the permeability of the oak was significantly improved after SC-CO₂ pretreatment. The results of the three dyeing methods in dyeing show that vacuum-pressurized dyeing has the best effect, with a dyeing rate up to 27.64%, and an increase of 4.63%; the wood-washing color difference with SC-CO₂-assisted Phellodendron Bark dyeing is only 3.15; the camphor berries’ actual air pressurized wood dyeing increased the sunlight fastness by 49%; SC-CO₂-assisted Phellodendron Bark dyeing resulted in the highest crystallinity of 62.34%. This study compared the dyeing effects of different natural dyes under SC-CO₂ pretreatment and different dyeing methods to solve the poor effect and low color fastness that natural dyes exhibit on wood, hoping to expand the application of wood in green, sustainable, functional materials. Full article

Over the past 15 years, Nodularia spumigena blooms in the Gulf of Gdańsk (southern Baltic Sea) have reached exceptional intensity, accounting for up to 90% of phytoplankton biomass during peak summer periods. Our long-term observations revealed oscillations in blooms intensity, with peak nodularin concentrations (up to 45,000 μg/L) recorded in 2012, 2015, and 2018—the highest levels of this toxin documented to date in both the Baltic Sea and worldwide. An extreme cyanobacterial bloom in 2018, caused by unusually high air and water temperatures, covered almost the whole surface of the Gulf of Gdańsk, causing multi-day closures of bathing areas. During this bloom, high levels of microcystins (up to 6640 μg/L MC-LR) were also detected, as well as the presence of 42 cyanopeptides, mainly anabaenopeptides and spumigins, which were present at concentrations 5–10 times higher than hepatotoxins. Full article

Background: Escherichia coli and Salmonella contamination in goose bath water releases endotoxins like lipopolysaccharide (LPS), compromising immunity and hindering goose farming. Objective: This study evaluated effects of dietary Bacillus subtilis and bacteriophage supplementation on water quality, carcass traits, and muscle growth in Magang geese. Method: A total of 288 geese were divided into four groups based on similarity in weight (n = 6 geese): A (basal diet); B (basal diet + bacteriophage: 5.0 × 10¹⁰ PFU/L at 1:1000 dilution); C (basal diet + Bacillus subtilis: 5.0 × 10⁹ CFU/kg); D (basal diet + bacteriophage + Bacillus subtilis). Results: Supplementation significantly increased wing length, tibia length, and live weight at 60 days. It reduced water and plasma endotoxin levels and suppressed viable counts of Escherichia coli, Salmonella, and total bacteria in water across rearing stages. Supplementation up-regulated mRNA and protein expression of myogenic regulators (MYOD, MYOG, MYH1) and IGF-1, while down-regulating pro-inflammatory cytokines (TNF-α, IL-6), suggesting enhanced myofiber growth. Conclusion: These findings demonstrate that Bacillus subtilis and bacteriophage supplementation improves goose growth performance and immune status by modulating key genes, reducing pathogens and endotoxins, offering an eco-friendly strategy to enhance productivity and potentially reduce antibiotic dependency. Full article

This study presents a highly sensitive non-enzymatic electrochemical sensor for detecting Sunset Yellow, a common food additive in beverages, based on palladium-cerium oxide composite decorated carbon black (CB). The sensing material was prepared by depositing palladium nanoparticles onto cerium oxide nanocubes, followed by the uniform dispersion of CB through sonication in a water bath. The strong metal–support interaction between palladium and cerium oxide significantly enhances catalytic activity, while the CB ensures excellent conductivity and structural support for the catalyst. Under optimized conditions, the sensor exhibits a linear response to Sunset Yellow concentrations in the range from 1 to 100 nM, with a limit of detection (LOD) of 0.056 nM. Additionally, the sensor demonstrates remarkable selectivity and stability. Practical application in real orange juice samples yielded recoveries from 99.11% and 101.34%, confirming its reliability for real-world beverage analysis. Full article

Activated peroxymonosulfate (PMS) processes have emerged as a highly effective advanced oxidation technique for the removal of emerging organic contaminants in water. This study successfully converted δ-MnO₂ into α-MnO₂ through a crystal phase transformation method via the application of a mild water bath heating process, enhancing its catalytic properties. α-MnO₂ (k = 0.092 ± 0.0059 min⁻¹) exhibited significantly higher activity than δ-MnO₂ (k = 0.027 ± 0.0075 min⁻¹) in the PMS-activated degradation of sulfamethoxazole (SMX). Importantly, ¹O₂ was identified as the primary reactive oxygen species in the α-MnO₂ + PMS system for SMX degradation. XPS and O₂-TPD characterizations demonstrated that α-MnO₂ possesses a higher concentration of active lattice oxygen a and lower concentration of Mn(III) than δ-MnO₂. Further analysis reveals that both surface Mn(III) and active lattice oxygen in α-MnO₂ are crucial for PMS activation. Notably, ¹O₂ is predominantly generated through the interaction between PMS and reactive lattice oxygen. Moreover, a heterogeneous PMS activation mechanism toward α-MnO₂ was proposed. This research underscores the critical role of active lattice oxygen in MnO₂ for PMS activation, providing valuable insight relevant to the design of catalysts aimed at pollutant elimination in environmental applications. To the best of our knowledge, our study is the first to report a pathway for MnO₂ crystal phase transition under relatively mild conditions. Full article

Many industries release untreated synthetic dye effluents into water bodies, harming ecosystems and human health. Therefore, an economical and sustainable solution for treating dye-contaminated water must be developed. In this study, mulberry leaves (Morus nigra L.), as a cost-effective and sustainable adsorbent, were prepared to remove Basic Yellow 28 (BY28) and Basic Blue 3 (BB3) cationic dyes from industrial dye wastewater using adsorption. Batch experiments with key variables such as initial dye concentration, adsorbent dosage, contact time, temperature, stirring speed, and pH were conducted to find optimal conditions. The effectiveness of mulberry leaves as an adsorbent after multiple regeneration cycles was examined. The adsorbent was characterized through various instrumental methods, including FTIR, SEM, XRD, and BET analysis. Adsorption performance was analyzed using the Langmuir and Freundlich isotherm models. The results showed that the mulberry leaf adsorbent best fits the Langmuir model, with R² values of 0.999 for BY28 and 0.973 for BB3. The maximum adsorption capacities were 0.15 mg/g for BY28 and 7.19 mg/g for BB3, indicating their upper limits for dye uptake. The optimal conditions achieving removal efficiencies of over 99% were 1.5 g, 50 mL, 15 min, 180 rpm, and 10 mg/L at 30 °C for BY28 in neutral pH (7) and 1.5 g, 50 mL, 45 min, 100 rpm, and 30 mg/L at 40 °C for BB3 in basic pH (10). The regeneration of mulberry leaves as an adsorbent through acid treatment with 0.1 M HCl and 0.1 M CH₃COOH solutions maintained a high performance, achieving up to 98% dye removal efficiency after two regeneration cycles. It has been observed that successful results can be achieved in terms of reusability. Additionally, the removals of BB3 and BY28 performed in an ultrasonic-bath-assisted environment successfully achieved removal efficiencies of 84.87% and 75.41%, respectively. According to the results, mulberry leaves can effectively be used in wastewater treatment to remove dyes, can be reused multiple times, and thus serve as an environmentally friendly and sustainable adsorbent. Full article

Anion-exchange membranes (AEMs) not only enable the fabrication of catalyst-coated membranes without precious metals but are also projected to achieve a technology-readiness level (TRL) suitable for industrial deployment before the end of this decade. Accurate and reproducible water uptake data are essential for guiding AEM design, yet conventional gravimetric methods—relying on manual blotting and loosely defined drying steps—can introduce variabilities exceeding 20%. Here, we present a standardized protocol that transforms water uptake measurements from rough estimates into precise, comparable “hydration fingerprints.” By replacing manual wiping with a calibrated pressure-blotting rig (0.44 N cm⁻² for 10 s twice) and verifying both dry and wet states via ATR-FTIR spectroscopy, we dramatically reduce scatter and align our FAAM-PK-75 (Fumatech, Bietigheim, Germany) results with published benchmarks in DI water, aqueous KOH (0.1–9 M), various alcohols, and controlled humidity (39–96% RH). These uptake profiles reveal how OH⁻ screening, thermal densification at 60 °C, and PEEK reinforcement govern equilibrium hydration. A low-cost salt-bath method for vapor-phase sorption further distinguishes reinforced from unreinforced architectures. Extending the workflow to additional commercial and custom membranes confirms its broad applicability. Ultimately, this work establishes a new benchmark for AEM hydration testing and provides a predictive toolkit for correlating water content with conductivity, dimensional stability, and membrane–ink interactions during catalyst-coated membrane fabrication. Full article

We report a low-cost protocol and platform for whole-abdomen 3D dynamic contrast-enhanced ultrasound (DCE-US) imaging in mice using a clinical matrix-array transducer. Background/Objectives: This platform addresses common limitations of preclinical ultrasound systems. In particular, these systems often lack real-time volumetric and molecular imaging capabilities. Methods: Using a modified silicone cup and water bath configuration, mice with dual subcutaneous tumors were imaged in vivo on a clinical EPIQ 7 system equipped with an X6-1 transducer. Results: Intravenous administration of targeted microbubbles enabled high-resolution, contrast-mode 3D imaging at multiple time points. Volumetric reconstructions captured both tumors and surrounding anatomy in a single scan, while time–intensity curves and Differential Targeted Enhancement (DTE) analysis revealed greater microbubble uptake in irradiated tumors, consistent with elevated P-selectin expression. Conclusions: This standardized imaging platform enables whole-abdomen molecular DCE-US in preclinical studies, facilitating intra-animal comparisons of vascular and molecular features across lesions or organs. Full article

Background: Greek islands face mounting pressures on their marine water resources due to tourism growth, agricultural runoff, climate change, and emerging pollutants. Safeguarding seawater quality is critical for ecosystem integrity, public health, and the sustainability of tourism-based economies. Objectives: This scoping review synthesizes and evaluates the existing research on seawater quality in the Greek islands, with emphasis on pollution sources, monitoring methodologies, and socio-environmental impacts, while highlighting the gaps in addressing emerging contaminants and aligning with sustainable development goals. Methods: A systematic literature search was conducted in Scopus, Google Scholar, ResearchGate, Web of Science, and PubMed for English- and Greek-language studies published over the last two to three decades. The search terms covered physical, chemical, and biological aspects of seawater quality, as well as emerging pollutants. The PRISMA-ScR guidelines were followed, resulting in the inclusion of 178 studies. The data were categorized by pollutant type, location, water quality indicators, monitoring methods, and environmental, health, and tourism implications. Results: This review identifies agricultural runoff, untreated wastewater, maritime traffic emissions, and microplastics as key pollution sources. Emerging contaminants such as pharmaceuticals, PFASs, and nanomaterials have been insufficiently studied. While monitoring technologies such as remote sensing, fuzzy logic, and Artificial Neural Networks (ANNs) are increasingly applied, these efforts remain fragmented and geographically uneven. Notable gaps exist in the quantification of socio-economic impact, source apportionment, and epidemiological assessments. Conclusions: The current monitoring and management strategies in the Greek islands have produced high bathing water quality in many areas, as reflected in the Blue Flag program, yet they do not fully address the spatial, temporal, and technological challenges posed by climate change and emerging pollutants. Achieving long-term sustainability requires integrated, region-specific water governance linked to the UN SDGs, with stronger emphasis on preventive measures, advanced monitoring, and cross-sector collaboration. Full article

The funerary cenotaph dedicated to Antonio Canova in the Frari basilica was erected in 1827. Since the beginning, some alteration features were recorded. In the last decades, some areas showed a sharp increase in deterioration processes due to large pieces of marble details missing from the statue surfaces. Macroscopic observation of the marble surface showed different forms of alteration as well as the massive presence of salt efflorescence. The main aim of this paper is to assess if there is a relationship between the decay observed and the presence of salt efflorescence, to subsequently ascertain the source of salts, and consequently to propose how to intervene to stop any further cause of alteration. In order to assess the relationship between the different types of alteration macroscopically observed, some samples were taken from the specific areas showing significant alteration features. Optical (OM) and scanning electron microscopic (SEM) observations associated with energy dispersive analysis (EDS) allowed us to explain the stages, each one corresponding to different features, through which the exfoliation and lamination of surface scales have been taking place. Moisture content in the brick structure was in the range of 17–26% until 140 cm of height. Above this height, moisture content is decreasing, and the maximum height of the capillary rise front is between 200 and 250 cm. In these areas, ions coming from the foundations of the monument deposit salt crystals within marble at a sub-surface level, causing the detachment of marble surface layers. In order to stop the rapidly increasing rate of decay observed over the last decades, it has been recommended to remove the statues from the basement and to insert a damp-proof course to prevent any further capillary rising damp. For the removal of embedded salts in the statues, the immersion of the removed statues inside deionized water baths has been recommended. Full article