1. Multifunctional biomolecular corona-inspired nanoremediation of antibiotic residues.
- Author
-
Hou J, Lu Y, Chen Q, Liao X, Wu X, Sang K, White JC, Gardea-Torresdey JL, Xu J, Zhang J, Yang K, Zhu L, and Lin D
- Subjects
- Animals, Protein Corona chemistry, Protein Corona metabolism, Water Pollutants, Chemical chemistry, Water Pollutants, Chemical metabolism, Oligochaeta metabolism, Biodegradation, Environmental, Environmental Restoration and Remediation methods, Nanocomposites chemistry, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Iron chemistry, Iron metabolism
- Abstract
Facing complex and variable emerging antibiotic pollutants, the traditional development of functional materials is a "trial-and-error" process based on physicochemical principles, where laborious steps and long timescales make it difficult to accelerate technical breakthroughs. Notably, natural biomolecular coronas derived from highly tolerant organisms under significant contamination scenarios can be used in conjunction with nanotechnology to tackling emerging contaminants of concern. Here, super worms ( Tubifex tubifex ) with high pollutant tolerance were integrated with nano-zero valent iron (nZVI) to effectively reduce the content of 17 antibiotics in wastewater within 7 d. Inspired by the synergistic remediation, nZVI-augmented worms were constructed as biological nanocomposites. Neither nZVI (0.3 to 3 g/L) nor worms (10
4 to 105 per liter) alone efficiently degraded florfenicol (FF, as a representative antibiotic), while their composite removed 87% of FF (3 μmol/L). Under antibiotic exposure, biomolecules secreted by worms formed a corona on and modified the nZVI particle surface, enabling the nano-bio interface greater functionality, including responsiveness, enrichment, and reduction. Mechanistically, FF exposure activated glucose-alanine cycle pathways that synthesize organic acids and amines as major metabolites, which were assembled into vesicles and secreted, thereby interacting with nZVI in a biologically response design strategy. Lactic acid and urea formed hydrogen bonds with FF, enriched analyte presence at the heterogeneous interface. Succinic and lactic acids corroded the nZVI passivation layer and promoted electron transfer through surface conjugation. This unique strategy highlights biomolecular coronas as a complex resource to augment nano-enabled technologies and will provide shortcuts for rational manipulation of nanomaterial surfaces with coordinated multifunctionalities., Competing Interests: Competing interests statement:The authors declare no competing interest.- Published
- 2024
- Full Text
- View/download PDF