Austenitic stainless steel (AISI 316L) is the dominant material in food processing equipment due to high corrosion resistance and mechanical durability. The shift from animal-to plant-based food processing introduces new challenges for material performance, as plant-derived biomolecules may interact differently with food-contact surfaces than animal proteins. These interactions can modify interfacial properties, with consequences for fouling, corrosion, and metal migration. Despite its importance, such effects remain scarcely studied, with only a few reports on e.g. whey and casein proteins. Knowledge on rice-derived biomolecules is particularly limited, even though rice proteins and starches are increasingly relevant in gluten-free and plant-based systems. This study examines the adsorption kinetics and interfacial properties of rice protein concentrates (RPC) and rice starch (RS) dissolved in artificial tap water (ATW) onto 316L stainless steel. In situ quartz crystal microbalance with dissipation monitoring (QCM-D) was employed to quantify adsorption dynamics, complemented by atomic force microscopy (AFM) and carbohydrate-specific opto-tracing (Carbotrace 680) to detect, and visualize adsorption patterns. Atomic absorption spectroscopy (AAS) was used to determine metal migration and evaluated with respect to European Union specific release limits (SRLs) for food-contact materials. Electrochemical measurements including open circuit potential (OCP), potentiodynamic polarization (PDP), and cyclic potentiodynamic polarization (CPDP) were employed to assess the effects of adsorption on the corrosion behavior. By demonstrating how rice-derived biomolecules interact with stainless steel and influence corrosion and metal migration, this study addresses a critical knowledge gap in the literature. The insights advance fundamental understanding of food biomolecule–metal interactions and support the design of more durable, compliant, and safe food-contact materials.

The toxicity of micro- and nanoparticles in cell culture studies is influenced by factors like particle size, agglomeration, dissolution of the particles, and methodological factors like sonication protocols. The main aim of this study was to investigate the influence of sonication on the particle size, dissolution, cytotoxicity, and dosing accuracy of nickel (Ni) metal and Ni oxide (NiO) particle dispersions. Such investigations are important to enable studies on the cellular uptake of different Ni substances in lung cells. The effect of sonication was evaluated in ultrapure water, two types of cell media, and A549 human lung cells using the tip and water bath methods. Extended sonication significantly decreased particle size and increased particle dissolution, emphasizing the need for optimized sonication conditions tailored to the specific particle type and study design. Observed findings demonstrate that the sonication step potentially can have a large impact on the results due to changes in particle characteristics, size, and dissolution, properties which are highly dependent on the particle type, solution composition, and sonication parameters. Although only small differences were observed in the limited assessment of cytotoxicity (A549 cells) in this study, further investigation is required to determine the impact of sonication on toxicity. This study also emphasizes the need to evaluate transferred dose samples due to the evident effects of agglomeration, sedimentation, and losses during sample transfer of particle dispersions. The study clearly illustrates that the choice of sonication protocol is particularly critical for toxicity studies, which are the basis of government regulatory decisions and human exposure limits.

Molybdenum carbide (Mo2C) is a material with a combination of excellent functional characteristics, making it interesting for a practical application in variety of fields. In this study, the synthesis of Mo C was successfully conducted using a combined solution combustion synthesis (SCS) and controlled thermal annealing. Optimal synthesis conditions were identified through thermodynamic analysis, revealed that exothermic reactions occur with ammonium nitrate-to-ammonium molybdate ratios of 10-50 and fuel-to-oxidizer ratios (phi) of 1.5-5.0. The materials exhibited a highly porous structure, with single-phase Mo C achieved after annealing with glycine as a reducer. Mo C enhances thermocatalytic decomposition of synthetic aviation oil. Notably, Mo C reduces the activation energy by 25 % compared to homogeneous decomposition, achieving process efficiency improvements up to 639 %, at 250 degrees C. These findings highlight potential of application of combined SCS-thermal annealing method for the obtaining Mo C, while the synthesized materials have high potential for advanced catalytic applications in energy and aerospace.

BackgroundThe eco-corona, consisting of environmental biomolecules formed around engineered nanomaterials (ENMs) when released to the environment, has gained increasing focus in the scientific literature and its role for ENM fate and toxicity is now widely acknowledged. The European chemicals legislation, REACH, entails reporting requirements when it comes to the transformation of nanoforms. Guidance provided by the European Chemicals Agency (ECHA) highlights eco-corona and biotransformation as relevant transformation processes. Still, no specific advice is given on how to test these processes. Based on the findings from the MISTRA Environmental Nanosafety project, we here map out methods to characterise ENM eco-corona and biotransformation and assess their effects. Furthermore, the regulatory relevance of the methods is evaluated.ResultsWe identified methods to assess both eco-coronas formed ex vivo (by interaction with natural organic matter-based solutions or solutions with animal secretes) and bio-coronas formed in vivo (via biotransformation, i.e., filtration of ENMs through living organisms). We recommend implementing these methods and methodological considerations in a future update of ECHA's guidance on ENM ecotoxicity and fate testing, both in the sections on transformation and aquatic pelagic toxicity. When exploring the characteristics and kinetics of eco-corona formation, various data are needed, including data on time-dependent interaction/adsorption/desorption between ENM and constituents in the medium (both with and without the addition of natural organic matter/biomolecules). It is, furthermore, proposed that environmental relevance is enhanced for hazard assessment of nanoforms in REACH. This can be done by incorporating eco-corona considerations in the persistency, bioaccumulative, and toxicity (PBT) assessment.ConclusionsWe here propose to update ECHA 's guidance on ENM ecotoxicity testing and the PBT assessment required under REACH to include eco-corona considerations. If updated, this will aid in implementing information requirements on ENM transformation, increase the environmental relevance of ENM ecotoxicity tests, and reduce uncertainties in the extrapolation of ENM ecotoxicity data.

Nanomaterials are vital in catalysis, sensing, energy storage, and biomedicine and now incorporate multiprincipal element materials to meet evolving technological demands. However, achieving a uniform distribution of multiple elements in these nanomaterials poses significant challenges. In this study, various Cu-Ni compositions were used as a model system to investigate the formation of bimetallic nanoparticles by employing computer simulation molecular dynamics methods and comparing the results with observations from solution-combustion-synthesized materials of the same compositions. The findings reveal the successful synthesis of 12-18 nm bimetallic Cu-Ni nanoparticles with high phase homogeneity, alongside phase-segregated nanoparticles predicted by molecular dynamics simulations. Based on the comparison of the experimental and computational data, a possible scenario for phase segregation during the synthesis was proposed. It includes clustering of the atoms of the same type in an initial solution or the stage of gel formation and further developing segregation during the combustion/cooling stage. The research concludes that early synthesis stages, including particle preformation, significantly influence the phase homogeneity of multiprincipal element alloys. This study contributes to understanding nanomaterial formation, offering insights for improved alloy synthesis and enhanced functionalities in advanced applications.

The use of metal and metal oxide nanomaterials (NMs) is experiencing a significant surge in popularity due to their distinctive structures and properties, making them highly attractive for a wide range of applications. This increases the risks of their potential negative impact on organisms if dispersed into the environment. Information about their behavior and transformation upon environmental interactions in aquatic settings is limited. In this study, the influence of naturally excreted biomolecules from the zooplankton Daphnia magna on nanosized Y2O3 of different concentrations was systematically examined in synthetic freshwater in terms of adsorption and eco-corona formation, colloidal stability, transformation, dissolution, and ecotoxicity towards D. magna. The formation of an eco-corona on the surface of the Y2O3 NMs leads to improved colloidal stability and a reduced extent of dissolution. Exposure to the Y2O3 NMs lowered the survival probability of D. magna considerably. The ecotoxic potency was slightly reduced by the formation of the eco-corona, though shown to be particle concentration-specific. Overall, the results highlight the importance of systematic mechanistic and fundamental studies of factors that can affect the environmental fate and ecotoxic potency of NMs.

Aluminum matrix composites (AMCs), incorporating Zirconium Nitride (ZrN) as reinforcing additives, demonstrate immense promise for applications in aerospace, automotive, and power generation due to their unique combination of low density, superior mechanical properties, and excellent thermal/electrical conductivity. This study explores the influence of ZrN reinforcement on the microstructure and mechanical properties of AlSi10Mg metal-matrix composites. Utilizing high-energy ball milling (HEBM) and spark-plasma sintering (SPS), ZrN/AlSi10Mg composites were synthesized, achieving nearly full density with uniform ZrN distribution, while phase and chemical transformations were not observed in the bulk composites. The addition of ZrN resulted in a notable increase in hardness of 237% (182 +/- 8 HV2), elastic modulus of 56% (114 +/- 3 GPa), compressive and tensile strength of 183% (565 +/- 15 GPa), and 125% (387 +/- 9 GPa), respectively, for composites containing 30% ZrN, compared to the non-reinforced alloy. Experimentally determined coefficients of thermal expansion (CTEs) for composites with 10%, 20%, and 30% ZrN content were 19.8x10(-6) degrees C-1, 19.1x10(-6) degrees C-1, and 18x10(-6) degrees C-1, respectively, which well relates to Schapery's model. These findings contribute to understanding the synthesis, mechanical behavior, and thermal properties of ZrN/AlSi10Mg composites, demonstrating their potential for diverse engineering applications.

Safe and Sustainable by Design (SSbD) is a new regulatory concept guiding chemical and material innovation. The European Commission has recommended a two-stage SSbD framework and plan to revise it based on stakeholder feedback. The framework involves establishing key (re)design SSbD principles and assessment of the final innovation, however the applicability of the framework to advanced materials remains to be addressed. Here, we applied the SSbD framework on Ti3C2Tx MXenes, an emerging advanced material, by (1) reviewing health, environmental and safety information; (2) characterizing MXenes transformation/dissolution in different media; (3) conducting (eco)toxicological experiments, and (4) completing a prospective life-cycle assessment. Our analysis suggests that Ti3C2Tx is safe and sustainable when applying the SSbD framework. Further research is needed regarding long-term hazardous effects of Ti3C2Tx and the sustainable production of the titanium precursor. Guidance is also needed on how much weight one should assign to the different lines of evidence in the overall SSbD assessment.

In the research, a one-step method for the rapid preparation of spherical nanostructured particles of Ca3Co4O9, involving the combustion of reactive aerosol drops containing calcium and cobalt nitrates as the metal precursors and hexamethylenetetramine as the fuel, is reported. The results of thermodynamic analysis and study of crystalline structure of obtained materials suggest that the reaction in the investigated system proceeds with heat release, which indicates its self-sustaining nature. Applying hexamethylenetetramine fuel at φ range of 0.4 – 0.6 and ambient temperature of 900 ℃ resulted in formation of Ca3Co4O9 powders with narrow particle size distribution of 0.2 – 1 µm. Microstructural studies revealed that the Ca3Co4O9 particles are hollow with nanometer-scale wall thicknesses and their surface consists of lamellar grains with sizes ranging from 14 to 100 nm.

Advanced materials are materials that have been engineered to exhibit novel or enhanced properties that confer superior performance when compared to conventional materials. Here, we evaluated the impact of Ti₃C₂ MXenes, a two-dimensional (2D) material, on the adverse effects caused by polycyclic aromatic hydrocarbons. To this end, we studied benzo[a]pyrene denoted here as B[a]P as a model compound. B[a]P was found to adsorb to MXenes as evidenced by UV–Vis spectroscopy. MXenes in the presence or absence of natural organic matter (NOM) were well tolerated by zebrafish embryos. The uptake (ingestion) of MXenes by zebrafish was determined by quantifying the Ti content using inductively coupled plasma mass spectrometry (ICP-MS) while Raman confocal mapping was applied for the label-free identification of MXenes in situ in exposed zebrafish. The body burden of B[a]P was determined by gas chromatography-mass spectrometry (GC-MS). The potential impact of MXenes on B[a]P triggered aryl hydrocarbon receptor (AhR) induction was assessed by evaluating the induction of downstream genes including cyp1a, and results were validated by using the transgenic zebrafish reporter tg(cyp1a-eGFP). The potential impact of MXenes on the genotoxicity caused by B[a]P was also assessed. MXenes were shown to ameliorate AhR induction and DNA damage caused by B[a]P. This was corroborated by using the human colon-derived cell line HT-29. Taken together, MXenes were found to be non-hazardous and alleviated the adverse effects caused by B[a]P in vitro and in vivo.