Search Results (4,019)

Sulfide-alkaline wastewater (SAW) from petrochemical plants, particularly from pyrolysis and hydrotreating units, presents a significant environmental challenge due to its high toxicity, extreme alkalinity (pH > 12), and high concentrations of sulfides and organic pollutants. Traditional treatment methods like acid neutralization or air oxidation are often inefficient, generate secondary waste, or fail to recover valuable components. This study investigates the effectiveness of a novel electrochemical system for the simultaneous treatment of SAW and recovery of valuable products. A lab-scale four-chamber electrodialyzer, equipped with cation-exchange membranes and nickel bipolar electrodes, was designed and tested using real industrial wastewater. The wastewater was characterized by a pH of 13.06, chemical oxygen demand of 12,600 mg/L, and a sulfide content of approximately 5000 mg/L. The process leverages anodic oxidation to convert sulfide ions into elemental sulfur, while sodium cations migrate through cation-exchange membranes to the cathodic compartments. There, water reduction generates high-purity hydrogen (≥99.9%) and a concentrated, purified sodium hydroxide solution. The results demonstrate the ineffectiveness of electrodialysis with anion-exchange membranes due to rapid membrane degradation. In contrast, the proposed electrodialyzer with bipolar electrodes achieved excellent performance: a caustic soda solution with a concentration of 2.3–2.5% was recovered with a current efficiency of 83–85%, containing only trace amounts of sulfides (0.0052%) and organic impurities (0.053%). The process completely removed the original sulfide alkalinity. The study confirms the chemical and mechanical stability of the cation-exchange membranes under harsh SAW conditions. The proposed technology offers a path towards a closed-loop system in refineries by enabling the reuse of recovered caustic, utilization of hydrogen, and potential recovery of sulfur, aligning with the principles of green chemistry and circular economy. Full article

Nepetalactone (NL) is a volatile iridoid monoterpene widely used in biopesticidal and repellent applications, yet its toxicokinetic behavior and metabolic fate as a pure compound remain poorly characterized. This study aimed to provide an integrated toxicokinetic evaluation of NL by combining in silico absorption, distribution, metabolism, excretion and toxicity (ADMET) modeling with in vitro metabolism assays using rat and human liver microsomes, supported by UHPLC–MS/MS analysis for metabolite identification. The in silico biotransformation predicted extensive phase I oxidation followed by phase II conjugation, while ADMET predictions indicated low systemic persistence and limited toxicological concern for most metabolites. The performed in vitro microsomal assays confirmed the in silico prediction by a rapid and time-dependent NL metabolism via both oxidative (86% reduction in NL concentration after 120 min) and conjugative (89% reduction in NL concentration after 120 min) pathways in rat and human systems, with comparable depletion kinetics between species. UHPLC–MS/MS enabled the identification of multiple phase I and phase II metabolites, pointing to pronounced interspecies differences in conjugative metabolism. In this sense, while oxidoreduction and hydrolysis reactions were consistent with previously reported iridoid metabolism. This study suggests the possible formation of previously unreported amino acid-related derivatives, although these require further confirmation. Overall, these findings advance the understanding of NL biotransformation, propose a new, previously unknown, metabolic pathway for iridoids, and provide relevant data to support human health and environmental risk assessment frameworks. Full article

Cinnamomum zeylanicum (C. zeylanicum) is rich in bioactives, such as cinnamaldehyde and phenols, which are susceptible to thermal degradation, volatilisation, and oxidative deterioration during processing and storage, thereby reducing chemical stability and limiting bioavailability. Encapsulation using lecithin and chitosan-based systems mitigates these instabilities by forming a protective barrier against oxygen, light, and heat while enhancing structural stability. In this study, freeze-dried extracts of C. zeylanicum were encapsulated into lecithin-based primary liposomes (PL) and chitosan-coated secondary liposomes (CH/L). The coating of liposomes with chitosan improves the liposome stability, mucoadhesion, and provides protection in the gastric pH while facilitating electrostatic bonding with the biological membrane. The high compatibility and low toxicity of chitosan also make it a suitable carrier in food and nutraceutical applications. The formed liposomes were characterised for particle size, polydispersity index, zeta potential, encapsulation efficiency (EE), and storage stability over 8 weeks. CH/L showed superior EE (89.027%) compared to the PL (84.154%; p < 0.05). The particle size, polydispersity index, and zeta potential of the cinnamon-loaded lecithin-based primary liposome (CZ-PL) upon formation were 161.93 nm, 0.13, and −37.597 mV. In comparison, those of the cinnamon-loaded chitosan-coated liposomes (CZ-CH/L) were 591.7 nm, 0.27, and +28.17 mV. The particle size of CZ-PL and CZ-CH/L was 175.90 and 588.60 nm after 8 weeks of storage. The TEM confirmed the spherical morphology of the liposomes. The differential scanning calorimetry analysis demonstrated the disappearance of the characteristic cinnamon melting peak and shifts in liposomal transition temperatures, confirming successful encapsulation. FTIR analysis showed reduction or disappearance of characteristic cinnamon fingerprint peaks and slight band shifts, indicating successful encapsulation and non-covalent interactions, including hydrogen bonding and electrostatic effects, within the liposomal systems. These findings imply that lecithin-based and chitosan-coated liposomes could be employed to successfully carry C. zeylanicum bioactives. Full article

Human breast cancer (HBC) is the most common and often lethal malignancy in women. Canine mammary tumors (CMTs) share significant molecular and clinical characteristics with HBC, which makes dogs a valuable spontaneous model for the study of HBC. HBC chemotherapy treatment relies mainly on carboplatin, which is effective but, in turn, highly toxic. Here we tested enrofloxacin, a Minichromosomal Maintenance Complex Component (MCM2) inhibitor, for its ability to increase tumor cell sensitivity to platinum-based drugs, thus suggesting a potential synergistic therapeutic strategy. CMT samples were used to establish primary cell cultures. Cells were treated with carboplatin, enrofloxacin, and their combination at different concentrations. Cytotoxic and antiproliferative effects were assessed using xCELLigence and MTT assays. Single-drug treatments exert limited effects on cell proliferation, while enrofloxacin significantly enhances carboplatin efficacy, leading to a complete growth arrest within 48 h. The MTT assay confirms a strong synergistic effect of the two drugs, whereas the Dose Reduction Index analysis indicates that carboplatin could be decreased without losing effectiveness. These findings suggest that combined therapy could represent a more effective and less toxic option for HBC and CMTs. This work also strengthens the possible use of the canine model for cancer studies within a One Health framework. Full article

Candida parapsilosis is a major cause of healthcare-associated infections due to its persistence on abiotic surfaces and efficient transmission via healthcare workers’ hands. This study evaluated the antifungal efficacy and safety of clinically relevant antiseptics against 60 C. parapsilosis clinical isolates using a surface carrier test designed to simulate contamination and disinfection events on hospital surfaces. Antifungal activity was assessed by logarithmic reduction (log₁₀) assays on surface carriers and by minimum inhibitory concentration (MIC) testing. Potential synergistic interactions between antiseptics and selected phytochemicals were investigated using checkerboard assays, and toxicity was evaluated in vivo using Caenorhabditis elegans. Surface carrier assays showed that 70% ethanol and 0.5% alcoholic chlorhexidine (CHG) achieved the highest fungicidal activity, with reductions of up to 5 log₁₀ after 1 min exposure at 25 °C. Polyhexamethylene guanidine hydrochloride (PHMGH) displayed consistently low MIC values (0.4–0.9 ppm) and intermediate surface activity. CHG combined with eugenol or menthol produced strong synergistic interactions, reducing CHG MICs from up to 6250 ppm to as low as 20 ppm (>300-fold). Toxicity assays revealed a narrow safety margin for CHG, whereas PHMGH showed a more gradual concentration-dependent toxicity profile. These findings highlight clinically relevant differences in antiseptic performance and identify combination strategies that may reduce CHG exposure while maintaining antifungal efficacy. Full article

Plating on Plastics (PoP) requires specific surface pre-treatment steps to enable metallization. The conventional PoP industry utilizes hexavalent chromium (toxic, carcinogenic) and palladium (critical raw material) for surface etching and activation, respectively, raising significant health, environmental, and economic concerns. This work is based on a new Cr⁶⁺-free and Pd-free PoP technology that uses piranha (H₂O₂-H₂SO₄) solutions for surface etching, nickel salts for activation, and NaBH₄ for reduction, ultimately forming metallic nucleation sites for downstream electroless plating and electroplating. A comprehensive modeling approach was developed to simulate and predict unit operation performance (reaction kinetics and yields) and material properties (contact angle and adhesion) across processing stages of the new technology. State-of-the-art and data-driven modeling revealed the combinatorial relationships among process performance, the achieved properties and the different settings of process operating conditions. The results also highlighted capabilities for tuning all processes over a range of conditions, reaching desired product specifications (adhesion and thickness). The models were constructed as a Decision Support Tool (DST) serving economic, environmental, safety and Safe and Sustainable by Design (SSbD) objectives. The DST can be used through a user-friendly interface that enables the insertion of user-defined inputs and monitoring of optimization results. Full article

Per- and polyfluoroalkyl substances (PFAS) are environmentally persistent chemicals associated with a wide range of adverse health effects, yet individual PFAS compounds may exert distinct toxicological mechanisms. In this study, we investigate the toxic effects of perfluorooctanoic acid (PFOA) and perfluorononanoic acid (PFNA) in Drosophila melanogaster using survival assays and measurements of acetylcholinesterase (AChE) activity as indicators of systematic toxicity and neurotoxicity, respectively. Male flies were exposed to PFOA and PFNA under different feeding conditions, concentrations, and temperatures. Both compounds reduced fly viability and impaired neuronal function, but with markedly different toxicological profiles. PFNA caused a pronounced, concentration-dependent reduction in lifespan under all tested conditions, indicating a strong systemic toxicity. In contrast, PFOA exerted a comparatively weaker effect on survival but induced a more pronounced reduction in AChE activity, consistent with enhanced neurotoxicity. PFOA-induced neurotoxicity in Drosophila may represent early molecular events that predispose neurons to degeneration, contributing to conditions such as dementia. Together, these findings demonstrate that structurally similar PFAS compounds can induce distinct toxicological outcomes and highlight the importance of evaluating individual PFAS using complementary assays. Moreover, this study underscores the utility of Drosophila melanogaster as a sensitive and mechanistically informative model for dissecting compound-specific PFAS toxicity. Full article

Synthetic dyes, such as methylene blue (MB), constitute a major category of environmental pollutants due to their toxicity, persistence, and resistance to standard treatment methods. In this study, Bacillus cereus BC WW Saida was isolated from the heavily polluted Saida dumpsite in Lebanon and evaluated for its MB degradation efficiency. The isolate was identified through whole-genome sequencing, which revealed the presence of key enzymatic systems involved in azo dye degradation. Under optimized conditions, the strain achieved 82% decolorization, as determined by optical density measurements using a microplate reader. The process was further examined using High-Performance Liquid Chromatography (HPLC), which revealed a significant reduction in the original dye peak and the emergence of new intermediate products. These findings suggest the strong biodegradation capability of B. cereus BC WW Saida isolated from contaminated environments and highlight its potential application in the eco-friendly treatment of azo dye-contaminated wastewater. Full article

Background: Mirvetuximab soravtansine (MIRV) improves outcomes in FRα-positive, platinum-resistant ovarian cancer; however ocular adverse events (OAEs), particularly corneal epithelial toxicity, are frequent and warrant structured ophthalmologic monitoring. Methods: In this retrospective observational study, 31 consecutive patients receiving MIRV for FRα-positive gynecologic malignancies underwent standardized ophthalmic assessments at baseline and prior to each treatment cycle (every 21 days). The protocol included best corrected visual acuity (BCVA), slit-lamp biomicroscopy, anterior-segment optical coherence tomography (AS-OCT), corneal topography, and tear film analysis. OAEs were graded according to the Common Terminology Criteria for Adverse Events (CTCAE) v5.0, based on symptom severity and functional impairment. Results: OAEs occurred in all patients (31/31, 100%), predominantly grade 1–2. Corneal epithelial toxicity was documented in 28/31 patients (90.3%), while no grade ≥ 3 events were observed. Symptoms typically developed 7–14 days after the second infusion. AS-OCT and corneal topography consistently revealed epithelial microcysts and surface irregularities, which were usually detected during scheduled pre-cycle ophthalmologic evaluations. Tear-film instability (break-up time ≤ 5 s) developed in 19/31 patients (61.3%), generally within 10 days after the second infusion, and improved in all but 2 patients (6.5%) following prophylactic lubrication. Transient refractive changes occurred in 28/31 patients (90.3%) and were associated with a temporary BCVA reduction (mean nadir ~20/32 Snellen), followed by recovery during follow-up. Conclusions: MIRV-related ocular alterations are frequent but reversible and clinically manageable. Multimodal imaging combined with functional and refractive assessment provides sensitive markers of corneal epithelial toxicity and supports integrated ophthalmologic monitoring to preserve visual function and maintain oncologic treatment continuity. Full article

Ginkgolic acids (GAs), the principal toxic constituents in Ginkgo biloba, pose health risks including cytotoxicity, allergenicity, and pro-inflammatory effects, limiting the application of Ginkgo resources in the food and health product industries. Developing efficient and environmentally friendly removal methods is essential. The endophytic fungus Fusarium sp. DLT-118, isolated from Ginkgo biloba, degraded 96.47% of GAs in Ginkgo biloba leaf extract (GE) at an initial concentration of 1 mg/mL within 7 days at 28 °C, while concurrently enhancing the antioxidant activity of GE, as indicated by a reduction in the 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical scavenging IC₅₀ from 755.7 μg/mL to 544.6 μg/mL. Morphological and oxidative stress analyses showed critical cellular adaptations and stress responses under degradation conditions. Integrated multi-omics analysis indicated that GE stress induced the remodeling of fungal amino acid, lipid, and energy metabolism, as well as the adjustment of membrane and transport functions, to facilitate GAs detoxification. Cytotoxicity assays indicated no significant cytotoxicity of the degradation products towards human normal lung epithelial cells (Beas-2B) and gastric mucosal epithelial cells (GES-1). These findings highlight Fusarium sp. DLT-118 as a promising agent for the efficient removal of GAs, offering a potential strategy for the production of GA-reduced Ginkgo-based food and health products. Full article

Surgical wards constitute a significant contributor to global medical waste (MW), accounting for over one-third of total healthcare sector trash. Medical interventions produce hazardous, infectious, and potentially toxic byproducts, making effective MW management crucial, especially where current mechanisms are insufficient. Substantial disparities persist between high-income and low- and middle-income countries regarding MW infrastructure, enforcement, and adoption of safe, sustainable treatment technologies. Proper segregation, recycling, treatment, and disposal are key to protecting public health, environmental integrity, and promoting healthcare sustainability. Waste treatment technologies divide into thermal and physico-chemical processes, requiring thorough evaluation of advantages, disadvantages, and suitability for each waste type. This narrative review updates MW knowledge by synthesizing data from scientific literature, institutional documents, and regulatory sources. Key quantitative data indicate operating rooms generate up to 30% of total hospital waste, with recyclable materials representing over 40% of that volume. Improper segregation rates remain high, and incineration remains dominant despite sustainability concerns. The Romanian case study highlights progressive EU alignment, enforcing standardized MW classification, color-coded segregation, and specialized disposal protocols in surgical wards. Despite legal compliance, Romania is advancing incrementally, with systematic audits, digital tracking, and national outcome-based evaluations yet to be fully established. The Plastic Surgery Unit at Oradea County Emergency Clinical Hospital demonstrates good protocol adherence; however, strengthening data feedback mechanisms would enhance hospital-wide performance optimization and strategic waste reduction. Training and monitoring represent important areas for continued development. Coordinated professional engagement, modernized infrastructure, and enforceable audits are identified as critical priorities for improving MW handling in surgical environments. Future research should emphasize management innovation, evidence-based policy formulation, and a systematic strategy to achieve sustainable MW. Full article

Fenvalerate residues on edible mushrooms pose significant risks to food safety and aquatic ecosystems. This study investigated the efficiency, degradation mechanisms, toxicity evolution, and quality effects of atmospheric cold plasma (ACP) for removing fenvalerate from shiitake mushrooms. Fenvalerate degradation increased with ACP treatment voltage and exposure time, reaching a maximum efficiency of 82.5% at 80 kV for 15 min. Quantum chemical calculations based on Fukui functions and frontier molecular orbitals identified phenoxy and chlorophenyl moieties as primary reactive sites. High-performance liquid chromatography–tandem mass spectrometry revealed degradation pathways dominated by hydroxylation, ester bond cleavage, and oxidative transformations. Toxicity assessment using ECOSAR predictions and yeast bioassays demonstrated substantial reductions in acute and chronic toxicity by ACP treatment, although some intermediates retained residual toxicity. In addition, ACP preserved mushroom quality during refrigerated storage. Overall, ACP represents a promising non-thermal strategy for pesticide detoxification while preserving edible mushroom quality. Full article

Arsenic induces apoptosis in both cancerous and non-cancerous cells. The mechanism of arsenic-induced apoptosis is complex. We previously demonstrated that the antioxidant acetyl L-carnitine prevented sodium arsenite-induced apoptosis in zebrafish embryos. To gain more insight into the mechanism of arsenic-induced apoptosis, we explored the effect of another antioxidant, N-acetylcysteine (NAC). Co-treatment of sodium arsenite with 1 or 2 mM NAC had no effect on zebrafish development. There was a significant but partial reduction in apoptosis in the embryos co-treated with sodium arsenite and 1 mM NAC, while embryos treated with 1 mM NAC alone showed the loss of normal apoptosis that was observed in the control embryos. Complete abolition of apoptosis occurred in embryos co-treated with sodium arsenite and 2 mM NAC; however, 2 mM NAC alone resulted in 100% mortality, indicating antioxidant toxicity at high doses. NAC (1 mM) did not prevent sodium arsenite-induced increase in motor neurons, suggesting that arsenic-induced apoptosis and supernumerary motor neuron development are mediated via distinct pathways. To determine whether NAC prevented arsenic-induced apoptosis via reactive oxygen species (ROS) signaling, we assessed ROS levels and oxidative modification of proteins (carbonylation) using an OxyBlot assay. Neither sodium arsenite nor NAC altered protein oxidation, ROS levels, or p53, a pro-apoptotic protein, transcript levels. Additionally, dicoumarol, an inducer of p53 protein degradation, did not inhibit sodium arsenite-induced apoptosis. These results indicate that protein oxidation and p53 signaling are not involved in arsenic-induced apoptosis and that NAC prevents arsenic toxicity in zebrafish embryos through a hitherto unknown mechanism. Full article

Bisphenol S (BPS) is widely used as a replacement for bisphenol A, yet accumulating evidence suggests that it has comparable endocrine and cardiovascular toxicity. Here, we investigated whether prolonged low-dose BPS exposure induces subtle but classifiable phenotypic alterations in human coronary artery endothelial cells (HCAEC), using an end-to-end experimental and ML pipeline that spans cell culture, high-content imaging, feature extraction, and robust classification. Cells were exposed to 0.1 µM BPS for 96 h and profiled using a cell painting assay and high-content microscopy. Image segmentation yielded ~2500 quantitative features per cell across four compartments—Membrane, Cytoplasm, Ring region (i.e., perinuclear region), and Nucleus—for multiple fluorophores. We systematically compared different classifiers (Random Forest, XGBoost, LASSO logistic regressor) using feature selection (MRMR, ReliefF, LASSO) or transformation-based dimensionality reduction (PCA, autoencoders). Tree-based ensembles robustly handled high-dimensional inputs, with XGBoost combined with ReliefF-selected features achieving the best performance. The most informative descriptors predominantly mapped to mitochondrial and nuclear channels, indicating early alterations in mitochondrial organisation and chromatin-related features. These findings show that chronic low-dose BPS exposure elicits a distinct endothelial phenotype, consistent with early endothelial dysfunction, and demonstrate that integrating high-content imaging with machine learning provides a sensitive, scalable framework for vascular toxicity assessment of environmental contaminants. Full article

With the introduction of total neoadjuvant therapy (TNT) in locally advanced rectal cancer treatment, multidisciplinary treatment options have become more diverse than before, and many challenges remain unresolved. A randomized clinical study in intermediate-risk locally advanced rectal cancer showed that neoadjuvant full-dose systemic chemotherapy with response-adapted omission of radiation therapy is non-inferior to concurrent chemoradiotherapy. Given that preoperative systemic chemotherapy provides an additional layer of local disease control, the traditional role and extent of neoadjuvant radiation therapy could be strategically re-evaluated within the TNT framework. In this context, a risk-adapted approach featuring selective reduction in elective nodal irradiation volume, particularly of the lateral pelvic lymph nodes, may offer a promising middle ground for treatment personalization. Drawing parallels from surgical practice—where total mesorectal excision is standard but lateral pelvic lymph node dissection is reserved for selected cases—this perspective advocates for similar selectivity in radiation therapy targeting, focusing on mesorectal and presacral regions while judiciously omitting lateral nodes in appropriately selected patients. This approach could maintain oncologic safety by focusing radiation therapy on limited but essential volumes. With modern intensity-modulated radiation therapy, reducing the target volume translates directly to enhanced organs-at-risk sparing, thereby mitigating radiation-induced toxicity. When combined with induction chemotherapy response assessment to refine patient selection, this approach can offer a biologically informed, personalized treatment paradigm that balances disease control with quality of life. Full article