Formation of silver nanoparticles in aquatic environments facilitated by algal extracellular polymeric substances: Importance of chloride ions and light

Population-specific responses of Lemna minor to silver nanoparticle exposure: Implications for standardizing toxicity assessments

The globally distributed and excellent growth properties of Lemna minor make it an ideal model species in ecotoxicology. However, the variability among different L. minor populations is often overlooked in laboratory toxicity assessments, which could lead to inaccurate toxicity evaluations, especially for newly emerging pollutants. In this study, we investigated the responses of L. minor populations from various regions (Wuhan (WH), South Korea (KR), Yunnan (YN), and Tibet (TB)) to silver nanoparticles (AgNPs), a newly emerging pollutant, at concentrations ranging from 0 to 10 mg L-1 over a 72-hour exposure period. The results showed a significant increase in silver accumulation in L. minor tissues with increasing AgNPs concentration. Concurrently, photosynthetic pigments content (chlorophyll a, b, and carotenoids) and chlorophyll fluorescence parameters exhibited a dose-dependent decline, while malondialdehyde levels increased, indicating that AgNPs induced oxidative stress in different L. minor populations. Notably, the populations displayed significant differences in tolerance to AgNPs: the KR population showed the highest tolerance, followed by TB, while the YN and WH populations were more sensitive. Further analysis revealed that the differences in toxicity response among L. minor populations were mainly attributed to variations in Ag accumulation capacity. Therefore, it is recommended that, when using L. minor from different regions to assess AgNPs toxicity, parameters could be standardized based on the silver accumulated by the plants rather than the externally applied silver. This approach will improve the comparability of results across laboratories and provide a more accurate understanding of AgNPs toxicity in global aquatic ecosystems.

Ecotoxicity of fungal-synthesized silver nanoparticles: mechanisms, impacts, and sustainable mitigation strategies

The review investigates the ecotoxicological implications of fungal-synthesized silver nanoparticles (AgNPs), focusing on their behavior, transformations, and impacts across aquatic and terrestrial ecosystems. Advanced techniques, such as Single-Particle ICP-MS and Nanoparticle Tracking Analysis, reveal the persistence and biotransformation of AgNPs, including silver ion (Ag⁺) release and reactive oxygen species (ROS) generation. The review highlights species-specific bio-accumulation pathways in algae, soil microbes, invertebrates, and vertebrates, along with the limited biomagnification potential within trophic levels. Long-term exposure to AgNPs leads to reduced soil fertility, altered microbial communities, and inhibited plant growth, raising significant ecological concerns. Sustainable mitigation strategies, including bioremediation and advanced filtration systems, are proposed to reduce the environmental risks of AgNPs. This comprehensive analysis provides a framework for future ecological studies and regulatory measures, balancing the technological benefits of fungal-synthesized AgNPs with their environmental safety.

Spatiotemporal Mapping of the Evolution of Silver Nanoparticles in Living Cells

Bioaccumulated silver nanoparticles (AgNPs) can undergo transformation and release toxic Ag+, which can be further reduced and form secondary AgNPs (Ag0NPs). However, the intricate interconversions among AgNPs, Ag+, and Ag0NPs remain speculative. Herein, we developed a bioimaging method by coupling the aggregation-induced emission method with the label-free confocal scattering and hyperspectral imaging techniques to quantitatively visualize the biodistribution and biotransformation of AgNPs, Ag0NPs, and Ag+ in living cells. We demonstrated that AgNPs were first dissolved in the medium, and the released Ag+ was converted into Ag0NPs with the presence of algal extracellular polymeric substances and light. Under these conditions, AgNPs alone accounted for 12.4% of the total AgNP toxicity, a percentage comparable to that of Ag0NPs (15.6%). However, Ag+ remained the primary contributor to overall AgNP toxicity. Additionally, we found that about 9.00% of the accumulated AgNPs within the algal cells were transformed after 24 h exposure. Of these transformed AgNPs, 4.70% remained as Ag+ forms (located in the apical region, nucleus, and pyrenoid), while 4.30% persisted as Ag0NP forms (located in the cytosol) that were only detectable after a 4 h exposure. We further showed that AgNP exposure upregulated algal glutathione production with a 38.3-fold increase in glutathione reductase activity, which potentially resulted in Ag0NP formation at the active site. Overall, this study differentiated the toxicity of AgNPs, Ag+, and Ag0NPs and directly visualized the ongoing transformation and translocation of AgNPs, Ag+, and Ag0NPs within living cells, which are critical in unveiling the toxicity mechanisms of AgNPs.

Role of extracellular polymeric substances in the aggregation and biological response of micro(nano)plastics with different functional groups and sizes

In this work, the effects of extracellular polymeric substances (EPS) on the aggregation and biological responses of different micro(nano)plastics (MNPs, <1000 µm) were investigated. EPS increased the colloidal stability of PS MPs in NaCl or CaCl₂. For the three PS NPs (PS-NH₂, PS-COOH, and PS-naked), EPS also enhanced their colloidal stabilities in the presence of NaCl. However, the effect of CaCl₂ on the colloidal stabilities of PS NPs in the presence of EPS depended on their surface functional groups. In CaCl₂, both Derjaguin-Landau-Verwey-Overbeek theory and molecular bridging explained the interaction between MNPs (both NPs and MPs) and EPS. Laser Direct Infrared and scanning electron microscope imaging showed that opalescent EPS corona formed on PS MPs via intermolecular-bridging by Ca²⁺, and the critical coagulation concentrations (70 mM in NaCl, 1.5 mM in CaCl₂) in EPS were much lower than that for PS NPs (1000 mM for NaCl; 65 mM for CaCl₂). PS-NH₂ NPs showed the highest increase in the growth of bacteria (Bacillus subtilis), followed by PS MPs and PS-naked NPs, while PS-COOH NPs had no significant effect. Biological response of PS NPs was unaffected by EPS, while EPS further enhanced the positive effects of PS MPs on bacterial growth.

Highly effective and sustainable antibacterial membranes synthesized using biodegradable polymers

In order to reduce foodborne diseases caused by bacterial infections, antibacterial membranes have received increasing research interests in recent years. In this study, highly effective antibacterial membranes were prepared using biodegradable polymers, including polylactic acid (PLA), polybutylene adipate terephthalate (PBAT), and carboxymethyl cellulose (CMC). The cation exchange property of CMC was utilized to introduce silver to prepare antibacterial materials. The presence of silver in the membranes was confirmed by EDS mapping, and the reduction of silver ions to metallic silver was confirmed by the Ag3d XPS spectrum which displayed peaks at 374.46 eV and 368.45 eV, revealing that the oxidation state of silver changed to zero. Two common pathogenic bacteria, Staphylococcus aureus (S. aureus) and Escherichia coli (E. coli), were used to investigate the antibacterial performance of the prepared membranes. Zone of inhibition and bacteria-killing tests revealed that the antibacterial membranes were efficient in inhibiting the growth of bacteria (diameters of inhibition zone ranged from 16 mm to 19 mm for fresh membranes) and capable of killing 100% of bacteria under suitable conditions. Furthermore, after 6 cycles of continuous zone of inhibition tests, the membranes still showed noticeable antibacterial activities, which disclosed the sustainable antibacterial properties of the membranes.