Abstract
A major challenge in understanding nanoplastic toxicity (or nanoparticles in general) lies in establishing the causal relationships between its physical properties and biological impact. This difficulty can be attributed to surface alterations that follow the formation of a biological complex around the nanoplastic, as exemplified by protein coronae. The protein corona is known to be responsible for the biological response elicited, although its own structure and attributes remain unknown. We approach this knowledge gap by independently studying the structure of soft and hard coronae using neutron scattering techniques. We investigated the formation and the structure of corona proteins (human serum albumin and lysozyme) and the resulting protein corona complexes with polystyrene nanoplastics of different sizes (20 and 200 nm) and charges. Soft corona complexes (regardless of protein type) adopted a structure where the nanoplastics were surrounded by a loose protein layer (∼2-3 protein molecules thick). Hard corona complexes formed fractal-like aggregates, and the morphology of which is known to be harmful to cellular membranes. In most cases, hard-corona coated nanoplastics also formed fractal-like aggregates in solution. Nanoplastic size affected the structures of both the protein corona and the intrinsic protein: more significant conformational change was observed in the hard corona proteins around smaller nanoparticles compared to larger ones, as the self-association forces holding the nanoplastic/protein complex together were stronger. This also implies that protein-dependent biochemical processes are more likely to be disrupted by smaller polystyrene nanoplastics, rather than larger ones.
Highlights
The emergence of nanotoxicology has led to many studies investigating the physiological effects of engineered nanomaterials.[1,2] While exposure to engineered nanoparticles can be managed with rigorous safety regulations or safer designing, unintentional exposure may impose greater health risks than the engineered nanomaterials
We investigated the formation and the structure of corona proteins and the resulting protein corona complexes with polystyrene nanoplastics of different sizes (20 and 200 nm) and charges
The particle size distribution of the nanoplastics was first evaluated with dynamic light scattering (DLS) for each nanoplastic
Summary
The emergence of nanotoxicology has led to many studies investigating the physiological effects of engineered nanomaterials.[1,2] While exposure to engineered nanoparticles can be managed with rigorous safety regulations or safer designing, unintentional exposure may impose greater health risks than the engineered nanomaterials. Plastic nanoparticles (nanoplastics) are an exemplary case of unintentional exposure in humans through drinking water and seafood.[3,4] It is known that bulk and microplastics in the environment fragment to nanoplastics, which will lead to increased environmental avs.scitation.org/journal/bip concentrations in the future. The key to understand toxicity mechanisms is to determine the causal relationships between nanoparticle properties and the biological outcomes (e.g., cellular response and immunological response).[9]. It is well established that nanoparticle properties are significantly altered by the association of biological molecules on the nanoparticle’s surface (e.g., protein corona).[10]. The presence of a protein corona is understood to play a role in further interactions with other biological entities.[10]. The chemical and biological bases of these effects are unclear, and a critical knowledge gap has been recognized for this bio-interface.[9]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
