Search Results (261)

The catalytic removal of refractory VOCs in gas–solid reactions usually suffers from the formation of toxic byproducts and catalyst deactivation. The advanced oxidation process (AOP) wet scrubber has recently attracted interest in VOCs purification due to its high efficiency and inhibited gaseous byproducts emission. MOFs/metal sulfides (termed M50C50) were designed to activate peroxymonosulfate (PMS) for toluene removal in a wet scrubber. The heterojunction interface synergistically couples MIL-100(Fe) and CoS for dual functions, the M50C50 enabled the rapid transfer the toluene from the gas phase to the aqueous phase, where they were subsequently mineralized by SO₄^•− and •OH radicals. The primary active sites responsible for PMS activation were identified as reducing sulfur species, along with low-valence cobalt and iron species. Over 90% of toluene were removed with a wide pH range, while •OH and SO₄^•− were involved in the mineralization of intermediates. The process showed high mineralization efficiency (75% CO₂ evolution) and effectively reduced the formation of toxic byproducts, underscoring its potential for minimizing secondary pollution risks. This work provides a novel route to designing composite catalysts for deep VOC oxidation via AOP wet scrubbers, greatly facilitating their use in environmental remediation. Full article

Achieving the EU’s climate goals by 2050 requires a rapid transition to a resource-efficient and circular economy. The electrification of transport increases the demand for rechargeable lithium-ion batteries (LiBs), where lithium–nickel–cobalt–manganese (Li-NMC) is the predominant cathode technology in the European automotive sector. Large-scale facilities for LiB production and recycling are emerging worldwide, bringing not only technical challenges but also challenges regarding healthy and safe working environments. Current knowledge on occupational exposure and health risks in the LiB industry is limited and largely based on evidence from other occupational settings. However, the LiB industry involves legacy and new combinations of metals and chemicals in novel contexts. Some of these substances have well-known adverse health effects, and combined exposure may increase their absorption and toxicity. Although processes are often highly specialised and automated, manual handling tasks remain, which put workers at risk of exposure. Important knowledge gaps remain regarding exposure levels, exposure pathways, dermal and systemic uptake, combined exposures, and potential health effects among workers. This perspective paper discusses current exposure scenarios and health risks in LiB production and recycling, identifies key knowledge gaps, and highlights future research needs to support evidence-based occupational risk management. To address several of these challenges, the GreenWorkLiB initiative applies a multidisciplinary approach combining exposure assessment, biomonitoring, and occupational medicine. The initiative investigates exposure pathways via air and skin, internal dose through biomonitoring, and potential health effects among workers in LiB production and recycling. The results can support the assessment of human health and safety within the EU’s Safe and Sustainable by Design (SSbD) framework and contribute to safe and sustainable working environments in the LiB industry. Full article

Lithium-ion batteries (LIBs) release significant amounts of toxic, corrosive, and flammable gases when they enter thermal runaway (TR). These emissions can be hazardous to human health, damage nearby equipment, pose fire and explosion risks, and degrade air quality. This study measured concentrations for a range of hazardous gases released from TR-driven combustion of cylindrical lithium iron phosphate (LFP) and pouch-style lithium cobalt oxide (LCO) LIB cells. Gas emissions were measured by dedicated analyzers and Fourier transform infrared spectroscopic (FTIR) analysis, and emission factors were calculated. Dangerous concentrations of hydrogen fluoride (HF) were observed, reaching up to 50 ppm from the combustion of single LIB cells. Large amounts of combustible electrolyte solvents and light hydrocarbons were released in some cases, depending on cell combustion behavior. Electrolyte solvents, hydrogen chloride (HCl), and particles were released earlier than other species and should be targeted for early TR detection. Gas emissions were correlated with cell state of charge (SOC) and combustion behavior. Cells at high SOCs had higher peak concentrations of HF, HCl, CO, and flammable hydrocarbons, and these peaks happened sooner after cell failure than for low-SOC tests. Full article

The pancreas is an organ with two functions: endocrine and exocrine. The proper functioning of the pancreas depends on many factors. One of these is trace elements—precise control of trace element homeostasis is important for both the endocrine and exocrine parts. This review provides a comprehensive summary of current knowledge regarding the role of trace elements: iron (Fe), copper (Cu), cobalt (Co), iodine (I), manganese (Mn), zinc (Zn), silver (Ag), cadmium (Cd), mercury (Hg), lead (Pb), and selenium (Se) in pancreatic physiology and their influence on the pathogenesis of key diseases of this organ, such as diabetes (DM), acute (AP) and chronic pancreatitis (CP), autoimmune pancreatitis (AIP), and pancreatic cancer (PC). Trace elements, including Fe, Cu, Zn, Se, and Mn, play a fundamental role in maintaining endocrine and exocrine homeostasis, participating in insulin synthesis, stabilizing digestive enzymes, and the functioning of antioxidant systems. It has been demonstrated that disturbances in their concentrations lead to the activation of pathological molecular pathways, including oxidative stress, chronic inflammation, and beta-cell apoptosis. In the context of diabetes, excess Fe promotes ferroptosis, whilst exposure to heavy metals such as Cd, Pb, and Hg induces insulin resistance and pancreatic islet dysfunction. In the course of pancreatitis, elements such as Zn and Se exhibit protective potential by stabilizing tissue barriers, whereas toxic metals impair ion transport, exacerbating fibrotic processes. Furthermore, analysis of available data indicates a significant association between heavy metal accumulation and pancreatic carcinogenesis, driven by DNA damage and oncogene modulation. Understanding pancreatic metallomics opens new prospects for early diagnosis, environmental prevention, and the development of targeted therapeutic strategies that restore the body’s micronutrient balance. Full article

Cobalt oxide (Co₃O₄), a transition metal oxide with a cubic spinel structure, shows high potential in peroxymonosulfate (PMS) activation, while its catalytic efficiency is often limited by sluggish interfacial charge transfer. In this study, a chlorine-doped Co₃O₄ (Cl-Co₃O₄) was synthesized via a hydrothermal method for the degradation of bisphenol A (BPA) through PMS activation. Systematic characterizations and electrochemical tests demonstrated that chlorine doping could effectively modulate the surface electronic structure of the catalyst, significantly reducing the interfacial charge transfer resistance. Degradation performance evaluations revealed that, compared to pristine Co₃O₄, Cl-Co₃O₄ exhibited a significantly enhanced BPA degradation, achieving near-complete removal of BPA within 15 min under neutral to weakly alkaline conditions. The optimal operational parameters were determined as catalyst dosage of 0.20 g/L, PMS concentration of 0.10 mM and initial pH of 7.0–9.0, with the pseudo-first-order rate constant reaching 0.37 min⁻¹. High-concentration NO₃⁻ showed weak inhibition, while Cl⁻ showed moderate inhibition; 50 mM HCO₃⁻ drastically reduced the rate constant to 0.05 min⁻¹ and almost completely suppressed the reaction. Sulfate (SO₄•⁻) and superoxide (O₂•⁻) radicals were the primary reactive species in this system, explicitly excluding the role of the non-radical electron transfer pathway. Furthermore, three plausible BPA degradation pathways involving C-C bond cleavage, hydroxylation and C-O bond breakage were proposed with 19 intermediates identified. Ecotoxicological assessments based on ECOSAR verified that both acute and chronic toxicity of the intermediates to fish, daphnid and green algae decreased gradually, and the final small-molecule products exhibited significantly lower toxicity than the parent BPA. This study provides a novel strategy for enhancing the PMS activation performance of cobalt-based catalysts by modulating their electronic structures via halogen doping. Full article

Volatile organic compounds can aggravate the atmospheric pollution and health risks due to their high toxicity and photochemical reactivity. Herein, a series of cobalt aluminate spinel catalysts with high efficiency was fabricated via a cost-efficient solvothermal method. Plentiful oxygen vacancies with negative charge were introduced adjacent to the octahedrally coordinated Co³⁺ species in CoAl₂O₄ catalysts, thereby generating the synergetic Co³⁺-oxygen vacancy (Ov) sites, which facilitated the rapid activation and migration of oxygen species. Accordingly, the superior catalytic activity was observed for 1Al-1Co even with lower cobalt due to the presence of abundant Co³⁺-Ov sites, revealing the predominant roles of synergetic sites in the toluene oxidation. Moreover, the 1Al-1Co catalyst exhibited the optimal intrinsic catalytic performance with the lowest activation energy of 161.2 kJ·mol⁻¹ and the highest specific toluene reaction rate of 3.18 × 10⁻⁵ mmol·h⁻¹·m⁻². In situ DRIFTS results further verified that oxygen vacancies and active Co³⁺ species could synergistically boost highly reactive oxygen species, which rapidly oxidize benzoate into maleic anhydride, achieving the efficient complete oxidation of toluene. Full article

Metals are an essential part of the life of all organisms because they participate as an essential part of diverse components, especially as enzymatic cofactors. In humans, there are metals that are trace elements and therefore are required for the proper functioning of different biological processes, so they must be present in cells and tissues. However, when the organism is overexposed, those same essential metals—in high concentrations that become toxic—cause imbalances or overt pathologies. On the other hand, there are metals that are not essential in humans, so their presence and accumulation in the organism can cause adverse effects. In this review we focus on the essentiality and toxicity of the main trace metals such as iron, zinc, copper, manganese, chromium, cobalt, molybdenum, and nickel, as well as on the toxicity of metals such as vanadium, cadmium, and lead that are not essential for humans. In addition, the report describes the main mechanisms by which metals exert their toxic effects on the body, as well as the primary sources of pollution through which they are released into the environment. Full article

Magnetic nanocomposite sorbents are increasingly explored for the remediation of metal-contaminated waters; however, high abiotic removal efficiency may not always translate into biological safety. The present study evaluated the single and combined effects of dissolved cobalt (II) ions and magnetite–chitosan nanocomposites (MCN) in zebrafish (Danio rerio) embryos and larvae. MCN (30 wt.% Fe₃O₄) were synthesized via co-precipitation and crosslinking and physiochemically characterized. Adsorption experiments conducted in fish incubation medium demonstrated the efficacy of divalent Co removal and were well described by the Langmuir isotherm model, with a maximum experimental capacity of 20.08 mg g⁻¹. The biological endpoints encompassed survival, hatching, heart rate, locomotor behavior, and oxidative stress biomarkers in early-stage zebrafish. The presence of cobalt (II) was found to result in a reduced hatching success rate, the induction of persistent bradycardia, and the occurrence of oxidative stress, as evidenced by a decline in SOD activity and an increase in H₂O₂ and MDA levels. The study found that MCN alone did not lead to mortality or increase peroxide levels or lipid peroxidation, although a modest decrease in SOD activity was observed. In contrast, combined exposure to cobalt and MCN resulted in significant delayed mortality (>85% at 96 h) and early neuromotor impairment. These findings indicate that high abiotic sorption efficiency alone does not guarantee reduced biological toxicity when nanomaterial–metal interactions occur. Consequently, safety assessments of remediation nanomaterials should explicitly consider nanomaterial–metal interactions and developmental stage-specific biological responses. Full article

Biohydrometallurgical processing of spent lithium-ion batteries offers a low-impact route for critical metal recovery compared with conventional hydrometallurgy. In this work, the iron-oxidizing bacterium Acidithiobacillus ferrooxidans was evaluated for the bioleaching of cobalt (Co), nickel (Ni), lithium (Li) and copper (Cu) from pyrolyzed industrial black mass derived primarily from LiCoO₂-based batteries, containing both LiCoO₂ and LiNiO₂ layered oxide phases. Batch experiments were conducted in 9K medium at 30 °C, varying pulp density (1%–2%, w/v), inoculum volume (10–20 mL in 200 mL medium) and initial pH (with and without adjustment). At 1% pulp density and 10% v/v inoculum, metal recoveries after 6–7 days reached about 64%–70% Co, 57%–72% Ni, 52%–60% Li and 81%–100% Cu, with most dissolution occurring in the first 6 days. Higher inoculum loads without initial pH adjustment increased Li recovery up to 79%, but did not further improve Co and Cu, indicating a trade-off between microbial activity, metal toxicity and ferric iron availability. The temporal evolution of pH and metal dissolution is consistent with indirect redoxolysis by biogenic Fe³⁺ and sulfuric acid generated during ferrous iron and elemental sulfur oxidation. Overall, the results confirm the feasibility of A. ferrooxidans-assisted bioleaching as a green option for Co, Ni, Li and Cu recovery from spent LiCoO₂ batteries and provide operating windows for subsequent process optimization and scale-up. Full article

Cobalt, a toxic heavy metal frequently present in wastewater, poses serious environmental and health risks but also represents a valuable resource for recovery. This study investigates a novel, environmentally friendly continuous flow in-liquid plasma discharge (CFILPD) system for simultaneous removal of cobalt, zinc, copper, and lead ions from aqueous solutions. The reactor contains two conductive channels where a stable plasma discharge forms between dielectric plates separating opposing electrodes, generating energetic electrons and hydroxyl radicals that react with dissolved metal ions. The effects of varying concentrations (5, 10, 50, and 100 ppm) of zinc, copper, and lead ions on the removal efficiency of 100 ppm cobalt ions were examined under constant conditions: 0.2 L/min argon flow rate, 200 W input power, and 50 mL/min liquid flow rate for 30 min. Results showed that increasing concentrations of co-existing metals significantly inhibited cobalt removal, with the largest reduction (91%) observed in multi-metal systems. Among individual metals at equimolar levels with cobalt, copper showed the strongest inhibitory effect (85% reduction), followed by zinc (53%) and lead (52%). Characterization of the recovered solids revealed cobalt–metal oxide composites (2.5–3 µm), suggesting their potential reuse in technological applications. Full article

Dromedary camels possess unique anatomical, physiological, and metabolic adaptations that enable survival in arid environments; however, these same adaptations make them highly sensitive to nutritional imbalance under modern feeding conditions. This review synthesizes current knowledge on nutritional pathologies and metabolic disorders in camels, emphasizing the links between diet composition, foregut fermentation, mineral status, and systemic health. Imbalances in energy and carbohydrates predispose camels to subacute and acute acidosis, negative energy balance, and ketosis-like syndromes, particularly when rapidly fermentable feeds are introduced without adequate fiber or water. Protein and nitrogen disorders, including ammonia toxicity and impaired urea recycling, arise from mismatches between degradable protein, fermentable energy, hydration, and mineral availability. Widespread deficiencies of phosphorus, copper, cobalt, zinc, selenium, and vitamins A and E remain major constraints, leading to pica, poor microbial fermentation, oxidative stress, immunosuppression, reproductive failure, and skeletal disorders. Nutritional disturbances frequently extend beyond the gastrointestinal tract, forming a gut–liver–kidney metabolic axis characterized by hepatic dysfunction, renal compromise, and systemic oxidative stress. The review also addresses gastrointestinal impaction, foreign-body ingestion, toxic plant consumption, and feeding on human food waste as emerging nutritional challenges, particularly in peri-urban systems. Advances in diagnostic ultrasonography, feed evaluation techniques, probiotics, mineral–vitamin supplementation, and omics-based approaches are discussed as tools for improving early diagnosis and precision nutrition. Despite growing research interest, the lack of camel-specific feeding standards and reliance on cattle-based recommendations remain critical gaps. This review highlights the need for species-specific nutrient requirement models, sustainable rangeland management, and integrative research to support the health, resilience, and productivity of camels under changing environmental and production systems. Full article

This study aimed to determine the exposure levels of young individuals living in Istanbul, a region in Turkey with a high population density and significant environmental pollution, by measuring the levels of heavy metals and trace elements in blood, serum, and urine. A total of 95 young people aged 18–24 participated in the study. Toxic heavy metals (Pb, As, Hg, Cd, and Cr) and physiological trace elements (Cu, Zn, Se, Mo, Mn, and Co) were measured in participants’ whole blood, serum, and urine samples using the ICP-MS technique. Participants were stratified by gender, as differences in body surface area may affect the absorption and metabolism of trace elements, and by smoking status, since smoking is a recognized source of heavy metal exposure. Gender differences revealed that blood lead levels were higher in males (p < 0.05), while manganese levels were higher in females (p < 0.05). When serum samples were analyzed, males had significantly higher zinc (p < 0.05) and selenium (p < 0.05) levels compared to females, whereas females had significantly higher levels of copper (p < 0.05) and cobalt (p < 0.05). Similar differences for copper (p < 0.05) and cobalt (p < 0.05) were observed in urine samples, with higher levels found in females. Blood cadmium levels were found to be significantly higher in smokers (p < 0.05). This biomonitoring study is one of the rare studies conducted in this region to assess heavy metal exposure among young adults. Full article

Zeolites are microporous aluminosilicate minerals widely recognized for their adsorption and ion-exchange properties. Their capacity to capture toxic heavy metals has prompted growing interest in their use as anti-pollution agents in skin care formulations. This study investigates zeolite-based creams through an in vitro permeation test using Franz diffusion cells within a Quality by Design (QbD) framework. A 2 × 2 × 2 full factorial design was applied to evaluate the effects of three critical factors: membrane type (Strat-M^® vs. silicone), dosage (10 vs. 20 mg), and dosage regimen. The adsorption and retention of five heavy metals, cadmium (Cd), cobalt (Co), chromium (Cr), lead (Pb), and nickel (Ni), were assessed over 12 h using an in vitro membrane model. The cream containing Zeolite demonstrated significantly higher adsorption of Cr, Co, and Cd compared to placebo and membrane controls, while Ni and Pb exhibited less consistent patterns. No sampling of the receptor compartment was performed; therefore, the analysis focused on metal residues in the donor and membrane compartments. Statistical analyses confirmed the significance of these findings, and graphical trends further supported zeolite’s selective adsorption behavior. Overall, the results provide mechanistic and statistical evidence supporting zeolite as a promising active ingredient for the development of anti-pollution skin care formulations and offer a methodological framework for assessing metal adsorption in topical products. Full article

Contamination of drinking water by potentially toxic elements (PTEs) remains a critical public-health concern in Uganda. This systematic review compiled and harmonized quantitative concentrations (mg/L) for key PTEs, lead (Pb), cadmium (Cd), arsenic (As), chromium (Cr), mercury (Hg), copper (Cu), zinc (Zn), nickel (Ni), cobalt (Co), manganese (Mn), and iron (Fe), across various potable and informal water sources used for drinking, including municipal tap water, boreholes, protected and unprotected springs, wells, rainwater, packaged drinking water, rivers, lakes, and wetlands. A comprehensive search of different databases and key institutional repositories yielded 715 records; after screening and eligibility assessment, 161 studies met the inclusion criteria, and were retained for final synthesis. Reported PTE concentrations frequently exceeded WHO and UNBS drinking water guidelines, with Pb up to 8.2 mg/L, Cd up to 1.4 mg/L, As up to 25.2 mg/L, Cr up to 148 mg/L, Fe up to 67.3 mg/L, and Mn up to 3.75 mg/L, particularly in high-risk zones such as Rwakaiha Wetland, Kasese mining affected catchments, and Kampala’s urban springs and drainage corridors. These hotspots are largely influenced by mining activities, industrial discharges, agricultural runoff, and corrosion of aging water distribution infrastructure, while natural geological conditions contribute to elevated background Fe and Mn in several regions. The review highlights associated health implications, including neurological damage, renal impairment, and cancer risks from chronic exposure, and identifies gaps in regulatory enforcement and routine monitoring. It concludes with practical recommendations, including stricter effluent control, expansion of low-cost adsorption and filtration options at household and community level, and targeted upgrades to water-treatment and distribution systems to promote safe-water access and support Uganda’s progress toward Sustainable Development Goal 6. Full article

The proliferation of antibiotic resistance urgently demands the development of novel non-antibiotic-dependent antimicrobial strategies. Metal–organic framework material ZIF-8, with its tunable structure and excellent biocompatibility, shows great promise in the field of photocatalytic antibacterial applications. However, pure ZIF-8 suffers from limitations such as a narrow light absorption range and high carrier recombination rates. Doping ZIF-8 with transition metals such as cobalt or copper, herein denoted as M-ZIF-8 (M=Co, Cu), can significantly broaden its photoresponsive spectrum, promote reactive oxygen species (ROS) generation, and enable controlled metal ion release, thereby enhancing antimicrobial performance. Nevertheless, the release of metal ions also introduces potential biotoxicity concerns, limiting practical applications. This paper systematically reviews the trade-off between the photocatalytic antibacterial mechanism and biotoxicity of metal-doped M-ZIF-8 (M=Co, Cu), focusing on material design principles, antibacterial pathways, toxicity manifestations and mechanisms, as well as optimization strategies for “enhancing efficacy while reducing toxicity.” It further proposes future research challenges and directions in mechanism elucidation, smart material development, standardization, and industrialization to advance the safe and efficient application of these materials in medical and environmental fields. Full article