Gupta, T.; Bui, Q. A.; Manirakiza, H.; El Hajji, L.; Humbert, N.; Mouhamad, A. W.; Reisch, A.; Gautier, A.; Klymchenko, A. S.

Stealth properties of nanoparticles are essential for their proper functionalization in biological systems. To address limitations of polyethylene glycol (PEG), commonly used for this purpose, we explore the potential of polysarcosine (PSar) as stealth shell in peptide-functionalized dye-loaded polymeric NPs. To this end, polymeric NPs loaded with rhodamine dye with bulky hydrophobic counterion and bearing azide groups at their surface were grafted with PSar of different lengths ranging from 5 to 19 sarcosine units using strain-promoted cycloaddition. The obtained peptide-functionalized NPs showed remarkable colloidal stability in physiological media. The length of PSar showed a profound effect on stealth properties of NPs. The increase in the length of grafted PSar lead to decrease in the negative surface charge to nearly neutral values and decreased protein adsorption according to fluorescence correlation spectroscopy. The NPs with 19mer PSar showed minimal interactions with live cells and glass surfaces in a complex biological medium, in contrast to its shorter PSar analogues. These stealth NPs bearing HaloTag ligand enabled specific targeting of proteins at the cell surface. The obtained results show that a relatively short PSar peptide can be used for achieving stealth properties in polymeric NPs, allowing specific protein targeting with minimized non-specific interactions. The obtained PSar-functionalized polymeric NPs appear as a powerful platform for the fabrication of the next generation of nanomaterials for bioimaging and biosensing applications.