posted on 2017-04-07, 00:00authored byConghui Yuan, Bihong Hong, Ying Chang, Jie Mao, Yang Li, Yiting Xu, Birong Zeng, Weiang Luo, Jean-François Gérard, Lizong Dai
Covalently
stabilized polymer assemblies are normally fabricated from the self-assembly
of polymer chains followed by a cross-linking reaction. In this report,
we show that a cross-linking-induced self-assembly approach, in which
boronate cross-linking sites are formed by the condensation reaction
between boronic and catechol groups, can organize polymer networks
into uniform assemblies. Self-assembly of these boronate cross-linked
polymer networks adopts two different driving forces in water and
methanol solutions. Hydrophobic aggregation of polymer networks in
water solution affords spherical assemblies, while B–N dative
bond formed between boronate and imine functionalities in methanol
solution organizes the polymer networks into bundle-like assemblies.
We not only demonstrate the intrinsic stimuli-responsive degradability
of these cross-linked assemblies but also show that their degradation
can cause a controllable release of guest molecules. Moreover, bundle-like
assemblies with rough surface and exposed boronate functionalities
exhibit dramatically higher cell penetration capability than the spherical
assemblies with smooth surface and embedded boronate functionalities.