# Mono- versus multi-phosphonic acid based PEGylated polymers for   functionalization and stabilization of metal (Ce, Fe, Ti, Al)oxide   nanoparticles in biological media

**Authors:** V. Baldim, A. Graillot, N. Bia, C. Loubat, J.-F. Berret

arXiv: 1902.07172 · 2021-09-21

## TL;DR

This study develops mono- and multi-phosphonic acid PEG polymers to improve the stability and functionalization of metal oxide nanoparticles in biological media, addressing the need for scalable, tailored coatings.

## Contribution

It introduces multi-phosphonic acid PEG polymers as effective, long-lasting coatings for various metal oxide nanoparticles, enhancing stability in biological environments.

## Key findings

- Multi-functionalized polymers provide long-term stability (months).
- PEG density of 0.2 - 0.5 nm-2 yields optimal performance.
- Coatings control nanoparticle interfacial properties in biological media.

## Abstract

For applications in nanomedicine, particles need to be functionalized to prevent protein corona formation and or aggregation. Most advanced strategies take advantage of functional polymers and assembly techniques. Nowadays there is an urgent need for coatings that are tailored according to a broad range of surfaces and that can be produced on a large scale. Herein, we synthesize mono- and multi-phosphonic acid based poly(ethylene glycol) (PEG) polymers with the objective of producing efficient coats for metal oxide nanoparticles. Cerium, iron, titanium and aluminum oxide nanoparticles of different morphologies (spheres, platelets, nanoclusters) and sizes ranging from 7 to 40 nm are studied in physiological and in protein rich cell culture media. It is found that the particles coated with mono-functionalized polymers exhibit a mitigated stability over time, whereas the multi-functionalized copolymers provide resilient coatings and long-term stability (months). With the latter, PEG densities in the range 0.2 - 0.5 nm-2 and layer thickness about 10 nm provide excellent performances. The study suggests that the proposed coating allows controlling nanomaterial interfacial properties in biological environments.

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Source: https://tomesphere.com/paper/1902.07172