On the role of N-vinylpyrrolidone in the aqueous radical-initiated copolymerization with PEGDA mediated by eosin Y in the presence of O2

Abstract

The photochemistry of eosin Y has attracted attention for its role in visible-light induced polymerization reactions that proceed in the presence of ambient oxygen to form various macromolecular architectures that are useful for a wide range of applications, including biosensing and drug delivery. N-Vinylpyrrolidone (NVP) has been employed as a comonomer in the eosin-mediated synthesis of hydrogels with polyethylene glycol (PEG) based multifunctional monomers to aid in reducing oxygen inhibition and enhancing the rate of radical polymerization and the final conversion. However, the mechanism by which NVP reduces the oxygen inhibition time (t_inh) remains unclear. Additionally, no investigations were found on the integration of NVP into the radical-generating photocatalytic mechanism of eosin Y. Towards a better understanding of eosin-mediated synthesis of PEG-based hydrogels, we analyzed the effect of NVP on the steady-state kinetics of the aqueous NVP/PEG-diacrylate copolymerization reaction. In this case, the reduction in t_inh is lower than that reported for copolymerization with neat (meth)acrylate monomers. We propose the formation of a ground-state complex between eosin and NVP as the main reason for the reduction in oxygen inhibition and contrast it with previous theories. In addition, we discuss the role of this eosin/NVP complex and cross-propagation kinetics to explain the ∼70% increase in the initial rate of polymerization upon addition of NVP. The effect of cross-propagation kinetics is enhanced at the later stages, leading to a 10% increase in final vinyl conversion in this relatively mobile network. By analyzing the change in the scaling of the eosin decay coefficient as a function of light intensity during and after oxygen inhibition, we then link eosin inactivation to radical termination kinetics. Finally, we discuss the role of radical recombination between semireduced eosin and the propagating radicals as an additional eosin inactivation route by which leuco-eosin ends tethered to the network. These insights contribute to a thorough understanding of visible-light activated polymerization in the presence of oxygen and of the role of NVP in eosin-mediated radical production.