Fate Of NPs Research Articles

Environmental Fate and Toxicity of Zinc Oxide Nanoparticles in Aquatic Ecosystems: A Comprehensive Review

Zinc oxide nanoparticles (ZnO NPs) are increasingly utilized in agriculture, electronics, and medicine, raising concerns about their environmental fate and toxicity in aquatic ecosystems. This study aims to review the fate, bioaccumulation, and toxicity of ZnO NPs in aquatic ecosystem. This review was conducted through a comprehensive analysis of peer-reviewed literature from databases such as Scopus, Web of Science, and PubMed. Finding indicates that ZnO NP fate in aquatic ecosystems is governed by key environmental factors, including pH, ionic strength, and DOM. ZnO NPs tend to aggregate in high-salinity environments, whereas acidic conditions enhance dissolution, leading to increased Zn²⁺ ion release and potential toxicity. Smaller ZnO NPs exhibit higher reactivity and bioavailability, increasing their potential for bioaccumulation. Bioaccumulation of ZnO NPs is influenced by concentration, exposure time, and particle size, with smaller nanoparticles being more readily absorbed by aquatic organisms. Toxicity varies depending on exposure duration and environmental conditions, with DOM playing a mitigating role by reducing Zn²⁺ ion availability. Additionally, ZnO NP exposure has been linked to oxidative stress, developmental abnormalities, and behavioral changes in aquatic organisms, highlighting the need for regulations and tailored risk assessments that account for water chemistry variations to mitigate ecological risks. Future research should focus on long-term impacts, including multi-species interactions and trophic transfer, to improve mitigation strategies.

Colloidal stability of UV-aged and protein-coated nanoplastics in natural waters under warming.

Colloidal stability of UV-aged and protein-coated nanoplastics in natural waters under warming.

Nanoplastic in aqueous environments: The role of chemo-electric properties for nanoplastic-mineral interaction.

Due to increasing plastic production, the continuous release of primary and secondary nanoplastic particles (NPs, <1μm) has become an emerging contaminant in terrestrial environments. The fate and transport of NPs in subsurface environments remain poorly understood, largely due to the complex interplay of mineralogical, chemical, biological, and morphological heterogeneity. This study examines interactions between abundant subsurface minerals and NPs under controlled water chemistry (1mM KCl, pH5.5). These conditions minimize potential chemical effects from ions in solution, isolating the impact of mineral complexity. Surface-modified polystyrene nanoparticles (-COOH and -NH2 functional groups) are proxies for degradation products and organic associations found in environmental plastics. Experimental results are compared with theoretical predictions using DLVO (Derjaguin-Landau-Verwey-Overbeek) double-layer force models. Despite all studied minerals maintaining negative surface charges across varying pH, electrostatic double-layer (EDL) interactions played a minor role in NP attachment. Instead, mechanisms such as specific ion-binding interactions (mediated by trace metal ions), bridging via divalent ions, and hydrogen bonding were more significant. Evidence suggests that kinetic effects for most mineral-NP combinations persist beyond 24h. This study highlights the critical role of biogeochemical and mineralogical composition in controlling NP attachment and release in subsurface environments, with implications for their transport and fate in aquifers.

Assessing the size transformation of nanoplastics in natural water matrices

Assessing the size transformation of nanoplastics in natural water matrices

The In Vivo Biological Fate of Protein Corona: A Comparative PET Study of the Fate of Soft and Hard Protein Corona in Healthy Animal Models.

Radiolabeling and nuclear imaging techniques are used to investigate the biodistribution patterns of the soft and hard protein corona around poly (lactic-co-glycolic acid) nanoparticles (PLGA NPs) after administration to healthy mice. Soft and hard protein coronas of 131I-labeled BSA or 131I-labeled serum are formed on PLGA NPs functionalized with either polyehtylenimine (PEI) or bovine serum albumin (BSA). The exchangeability of hard and soft corona is assessed in vitro by gamma counting exposing PLGA NPs with corona to non-labeled BSA, serum, or simulated body fluid. PEI PLGA NPs form larger and more stable coronas than BSA PLGA NPs. Soft coronas are more exchangeable than hard ones.The in vivo fate of PEI PLGA NPs coated with preformed 18F-labeled BSA hard and soft coronas is assessed by positron emission tomography (PET)following intravenous administration. While the soft corona shows a biodistribution similar to free 18F BSA with high activity in blood and kidney, the hard corona follows patterns characteristic of nanoparticles, accumulating in the lungs, liver, and spleen. These results show that in vivo fates of soft and hard corona are different, and that soft corona is more easily exchanged with proteins from the body, while hard corona is largely retained on the nanoparticle surface.

Impact of seed priming with Selenium nanoparticles on germination and seedlings growth of tomato

Poor germination and seedlings growth can lead to significant economic losses for farmers, therefore, sustainable agricultural strategies to improve germination and early growth of crops are urgently needed. The objective of this work was to evaluate selenium nanoparticles (Se NPs) as nanopriming agents for tomato (Solanum lycopersicum) seeds germinated without stress conditions in both trays and Petri dishes. Germination quality, seedlings growth, synergism-antagonism of Se with other elements, and fate of Se NPs, were determined as function of different Se NPs concentrations (1, 10 and 50 ppm). Results indicated that the germination rate in Petri dishes improved with 10 ppm, while germination trays presented the best results at 1 ppm, increasing by 10 and 32.5%, respectively. Therefore, seedlings growth was measured only in germination trays. Proline content decreased up to 22.19% with 10 ppm, while for same treatment, the total antioxidant capacity (TAC) and total chlorophyll content increased up to 38.97% and 21.28%, respectively. Antagonisms between Se with Mg, K, Mn, Zn, Fe, Cu and Mo in the seed were confirmed. In the case of seedlings, the N content decreased as the Se content increased. Transmission Electron Microscopy (TEM) imaging confirmed that Se NPs surrounded the plastids of the seed cells. By this finding, it can be inferred that Se NPs can reach the embryo, which is supported by the antagonism of Se with important nutrients involved in embryogenesis, such as K, Mg and Fe, and resulted in a better germination quality. Moreover, the positive effect of Se NPs on total chlorophyll and TAC, and the negative correlation with proline content with Se content in the seed, can be explained by Se NPs interactions with proplastids and other organelles within the cells, resulting with the highest length and fresh weight when seeds were exposed to 1 ppm.

Protein Coronas Derived from Mucus Act as Both Spear and Shield to Regulate Transferrin Functionalized Nanoparticle Transcellular Transport in Enterocytes.

The epithelial mucosa is a key biological barrier faced by gastrointestinal, intraoral, intranasal, ocular, and vaginal drug delivery. Ligand-modified nanoparticles demonstrate excellent ability on this process, but their efficacy is diminished by the formation of protein coronas (PCs) when they interact with biological matrices. PCs are broadly implicated in affecting the fate of NPs in vivo and in vitro, yet few studies have investigated PCs formed during interactions of NPs with the epithelial mucosa, especially mucus. In this study, we constructed transferrin modified NPs (Tf-NPs) as a model and explored the mechanisms and effects that epithelial mucosa had on PCs formation and the subsequent impact on the transcellular transport of Tf-NPs. In mucus-secreting cells, Tf-NPs adsorbed more proteins from the mucus layers, which masked, displaced, and dampened the active targeting effects of Tf-NPs, thereby weakening endocytosis and transcellular transport efficiencies. In mucus-free cells, Tf-NPs adsorbed more proteins during intracellular trafficking, which enhanced transcytosis related functions. Inspired by soft coronas and artificial biomimetic membranes, we used mucin as an "active PC" to precoat Tf-NPs (M@Tf-NPs), which limited the negative impacts of "passive PCs" formed during interface with the epithelial mucosa and improved favorable routes of endocytosis. M@Tf-NPs adsorbed more proteins associated with endoplasmic reticulum-Golgi functions, prompting enhanced intracellular transport and exocytosis. In summary, mucus shielded against the absorption of Tf-NPs, but also could be employed as a spear to break through the epithelial mucosa barrier. These findings offer a theoretical foundation and design platform to enhance the efficiency of oral-administered nanomedicines.

Toxicity spectrum and detrimental effects of titanium dioxide nanoparticles as an emerging pollutant: A review

Titanium dioxide nanoparticles have wide industrial –applications, due to their enhanced mechanical, physical, optical and electrical properties. TiO2-based nanomaterials are extensively used in different industries for example paper, semiconductors, paint, food, cosmetics, water purification and textile. Besides its multiple applications in different domains of life, TiO2 has been reported for its hazardous effect on ecosystems, specifically on humans and mammals. The human body may be exposed to TiO2 NPs by three pathways i.e., oral, dermal and intra-gastric pathways and get accumulated in different parts of the body like the spleen, alimentary tract, central nervous system, liver, kidney, reproductive system, cardiac muscles and may form agglomerates with other mammalian cells. Additionally, these NPs may cross blood brain barrier and induce apoptosis in human hippocampal neurons. These NPs also show genotoxic effects that might leads towards the apoptosis and chromosomal instability. It has been observed experimentally that the cytotoxic effects of TiO2 depend on their size, shape, type and rate of consumption. This paper provides comprehensive information regarding hazardous effects reported for TiO2 NPs on living organisms (animals and humans). This information will be supportive for understanding the spectrum of toxicity associated with the NPs that will be helpful in deciding the fate of TiO2 NPs.

Core-Shell Au@Nanoplastics as a Quantitative Tracer to Investigate the Bioaccumulation of Nanoplastics in Freshwater Ecosystems.

Studies on the adverse effects of nanoplastics (NPs, particle diameter <1000 nm) including physical damage, oxidative stress, impaired cell signaling, altered metabolism, developmental defects, and possible genetic damage have intensified in recent years. However, the analytical detection of NPs is still a bottleneck. To overcome this bottleneck and obtain a reliable and quantitative distribution analysis in complex freshwater ecosystems, an easily applicable NP tracer to simulate their fate and behavior is needed. Here, size- and surface charge-tunable core-shell Au@Nanoplastics (Au@NPs) were synthesized to study the environmental fate of NPs in an artificial freshwater system. The Au core enables the quantitative detection of NPs, while the polystyrene shell exhibits NP properties. The Au@NPs showed excellent resistance to environmental factors (e.g., 1% hydrogen peroxide solution, simulating gastric fluid, acids, and alkalis) and high recovery rates (>80%) from seawater, lake water, sewage, waste sludge, soil, and sediment. Both positively and negatively charged NPs significantly inhibited the growth of duckweed (Lemna minor L.) but had little effect on the growth of cyanobacteria (Microcystis aeruginosa). In addition, the accumulation of positively and negatively charged NPs in cyanobacteria occurred in a concentration-dependent manner, with positively charged NPs more easily taken up by cyanobacteria. In contrast, negatively charged NPs were more readily internalized in duckweed. This study developed a model using a core-shell Au@NP tracer to study the environmental fate and behavior of NPs in various complex environmental systems.

Protein corona formed on the TiO2 nanoparticles promotes the hydrolysis of collagen in simulated gastrointestinal fluids

Protein corona formed on the TiO2 nanoparticles promotes the hydrolysis of collagen in simulated gastrointestinal fluids

Co-transport of biochar nanoparticles (BC NPs) and rare earth elements (REEs) in water-saturated porous media: New insights into REE fractionation

Co-transport of biochar nanoparticles (BC NPs) and rare earth elements (REEs) in water-saturated porous media: New insights into REE fractionation

Thermodynamic investigation of nanoplastic aggregation in aquatic environments

Thermodynamic investigation of nanoplastic aggregation in aquatic environments

Role of metal-nanoparticles in farming practices: an insight.

Nanotechnology introduces revolutionary approaches for agriculture in the form of nano-based pesticides, fertilizers, sensors, weed-controlling agents, enhanced seed germination materials,etc. Even though metal-nanoparticles (NPs) have shown their potential to improve crop yield, the mode of action at the cellular level and fate in the human body and the environment are not well understood yet. Several metal-nanoparticles have been studied extensively by researchers for their active role in enhancing the rate of seed germination and crop quality augmentation which may happen due to several mechanisms such as increased porosity in nano-primed seeds inducing up-regulation of the expression of aquaporin and Reactive Oxygen Species (ROS) genes involved in water uptake, improving the root dehydrogenase activity to enhance the water absorption capability, etc. However, researchers have also demonstrated and reported the possible toxicity of NPs in the environment due to their agricultural practices. But the fate of NPs and their environmental impact are still unclear and largely vary based on several factors such as the size of NPs, coating material, mode of discharge and locations, etc.This review thoroughly focuses on the mode of action of various NPs in seed germination and accumulation, translocation through cells, and potential environmental and health risks.

Characterization and Biomedical Application Opportunities of the Nanoparticle's Protein Corona

AbstractNanoparticles (NPs) are widely used in a variety of biomedical fields, such as drug delivery systems, novel theragnostic strategies, bioimaging, and biosensing. The protein corona formed by the contact between NPs and biological liquids changes the physicochemical nanoparticle characteristics, including size, shape, and surface statement. Moreover, it affects the biological fate of NPs in organisms, for instance, pharmacokinetic processes and therapeutical efficacy. Therefore, it is necessary to comprehensively identify and quantify the properties of the nanoparticle protein corona. This review focuses on screening the milestones and latest advances of the protein corona, the interaction between NPs and the protein corona, the detection and characterization of the protein corona, and the application of the protein corona in biomedicine. The application section mainly includes three aspects: 1) novel NPs targeting design based on protein corona; 2) personalized protein corona powered precision medicine by integrating multiple strategies, i.e., proteomics and computer science; and 3) opportunities for protein coronas in nanomedicine applications. Collectively, these summaries reveal the significance of the protein corona in nanomedicine and highlight the challenges of studying protein coronas based on nanoparticle properties.

Potential application of Au core labeling for tracking Ag nanoparticles in the aquatic and biological system

Potential application of Au core labeling for tracking Ag nanoparticles in the aquatic and biological system

Role of nanotechnology in management of plant viral diseases

Role of nanotechnology in management of plant viral diseases

Solubility of ZnO Nanoparticles in Food Media: An Analysis Using a Novel Semiclosed Dynamic System.

Food media can affect the solubility of zinc oxide nanoparticles (ZnO NPs). Moreover, when a single digestive fluid and a three-step digestion system were applied to investigate the fate of ZnO NPs, several contradictory results were obtained. Here, we manipulated a novel semiclosed in vitro dynamic digestion system to investigate the difference in the released ionic zinc (Zn2+) content in three types of artificial fluids in the presence of different food media. The results show that there was a significant difference in the released Zn2+ content between the three different types of digestion systems in the presence of the same food media. In addition, the released Zn2+ content was significantly different when different types of food media were applied to the same digestion system. These results demonstrate that the different levels of released Zn2+ content can be ascribed to the difference in digestion systems and food media.

Fate and impact of maghemite (γ-Fe2O3) and magnetite (Fe3O4) nanoparticles in barley (Hordeum vulgare L.).

The increasing demand for food in the world has made sustainable agriculture practices even more important. Nanotechnology applications in many areas have also been used in sustainable agriculture in recent years for the purposes to improve plant yield, pest control, etc. However, ecotoxicology and environmental safety of nanoparticles must be evaluated before large-scale applications. This study comparatively explores the efficacy and fate of different iron oxide NPs (γ-Fe2O3-maghemite and Fe3O4-magnetite) on barley (Hordeum vulgare L.). Various NP doses (50, 100, and 200 mg/L) were applied to the seeds in hydroponic medium for 3 weeks. Results revealed that γ-Fe2O3 and Fe3O4 NPs significantly improved the germination rate (~37% for γ-Fe2O3; ~63% for Fe3O4), plant biomass, and pigmentation (P < 0.005). Compared to the control, the iron content of tissues gradually raised by the increasing NPs doses revealing their translocation, which is confirmed by VSM analysis as well. The findings suggest that γ-Fe2O3 and Fe3O4 NPs have great potential to improve barley growth. They can be recommended for breeding programs as nanofertilizers. However, special care should be paid before the application due to their unknown effects on other living beings.

Effects of clay minerals on the transport of nanoplastics through water-saturated porous media

Effects of clay minerals on the transport of nanoplastics through water-saturated porous media

Heteroaggregation of different surface-modified polystyrene nanoparticles with model natural colloids

Heteroaggregation of different surface-modified polystyrene nanoparticles with model natural colloids