Bridge-rich and loop-less hydrogel networks through suppressed micellization of multiblock polyelectrolytes.
Jihoon HanSaeed NajafiYouyoung ByunLester GeonzonSeung-Hwan OhJiwon ParkJun Mo KooJehan KimTaehun ChungIm Kyung HanSuhun ChaeDong Woo ChoJinah JangUnyong JeongGlenn H FredricksonSoo-Hyung ChoiKoichi MayumiEunji LeeJoan-Emma SheaYoun Soo KimPublished in: Nature communications (2024)
Most triblock copolymer-based physical hydrogels form three-dimensional networks through micellar packing, and formation of polymer loops represents a topological defect that diminishes hydrogel elasticity. This effect can be mitigated by maximizing the fraction of elastically effective bridges in the hydrogel network. Herein, we report hydrogels constructed by complexing oppositely charged multiblock copolymers designed with a sequence pattern that maximizes the entropic and enthalpic penalty of micellization. These copolymers self-assemble into branched and bridge-rich network units (netmers), instead of forming sparsely interlinked micelles. We find that the storage modulus of the netmer-based hydrogel is 11.5 times higher than that of the micelle-based hydrogel. Complementary coarse grained molecular dynamics simulations reveal that in the netmer-based hydrogels, the numbers of charge-complexed nodes and mechanically reinforcing bridges increase substantially relative to micelle-based hydrogels.
Keyphrases
- drug delivery
- hyaluronic acid
- tissue engineering
- molecular dynamics simulations
- wound healing
- drug release
- cancer therapy
- molecular dynamics
- molecular docking
- physical activity
- extracellular matrix
- genome wide
- radiation therapy
- mental health
- transcription factor
- gene expression
- dna methylation
- wastewater treatment
- early stage
- rectal cancer