Anionic synthesis of a clickable middle-chain azidefunctionalized polystyrene and its application in shape amphiphiles

Click chemistry is, by definition, a general functionalization methodology (GFM) and its marriage with living anionic polymerization is particularly powerful in precise macromolecular synthesis. This paper reports the synthesis of a clickable middle-chain azide-functionalized polystyrene (mPS-N-3) by anionic polymerization and its application in the preparation of novel shape amphiphiles based on polyhedral oligomeric silsesquioxane (POSS). The mPS-N-3 was synthesized by coupling living poly(styryl)lithium chains (PSLi) with 3-chloropropylmethyldichlorosilane and subsequent nucleophilic substitution of the chloro group in the presence of sodium azide. Excess PSLi was end-capped with ethylene oxide to facilitate its removal by flash chromatography. The mPS-N-3 was then derived into a giant lipid-like shape amphiphile in two steps following a sequential click strategy. The copper(I)-catalyzed azide-alkyne cycloaddition between mPS-N-3 and alkyne-functionalized vinyl-substituted POSS derivative (VPOSS-alkyne) ensured quantitative ligation to give polystyrene with VPOSS tethered at the middle of the chain (mPS-VPOSS). The thiol-ene reaction with 1-thioglycerol transforms the vinyl groups on the POSS periphery to hydroxyls, resulting in an amphiphilic shape amphiphile, mPS-DPOSS. This synthetic approach is highly efficient and modular. It demonstrates the click philosophy of facile complex molecule construction from a library of simple building blocks and also suggests that mPS-N-3 can be used as a versatile clickable motif in polymer science for the precise synthesis of complex macromolecules.