Exploiting topology-directed nanoparticle disassembly for triggered drug delivery

Arno, M.C., Williams, R.J., Bexis, P., Pitto-Barry, Anaïs, Kirby, N., Dove, A.P., O'Reilly, R.K.

03 September 2019

Yes / The physical properties of cyclic and linear polymers are markedly different; however, there are few examples which exploit these differences in clinical applications. In this study, we demonstrate that self-assemblies comprised of cyclic-linear graft copolymers are significantly more stable than the equivalent linear-linear graft copolymer assemblies. This difference in stability can be exploited to allow for triggered disassembly by cleavage of just a single bond within the cyclic polymer backbone, via disulfide reduction, in the presence of intracellular levels of l-glutathione. This topological effect was exploited to demonstrate the first example of topology-controlled particle disassembly for the controlled release of an anti-cancer drug in vitro. This approach represents a markedly different strategy for controlled release from polymer nanoparticles and highlights for the first time that a change in polymer topology can be used as a trigger in the design of delivery vehicles. We propose such constructs, which demonstrate disassembly behavior upon a change in polymer topology, could find application in the targeted delivery of therapeutic agents. / ERC are acknowledged for support to M.C.A., A.P.D. (grant number: 681559) and R.O.R. (grant number: 615142).

Graft copolymers

Cyclic polymers

Disulfide linker

Acetal linker

Topology-controlled particle disassembly