posted on 2012-12-03, 00:00authored bySean Bickerton, Siriporn Jiwpanich, S. Thayumanavan
Polymer-based nanoassemblies have
emerged as viable platforms for
the encapsulation and delivery of lipophilic molecules. Among the
criteria that such carriers must meet, if they are to be effective,
are the abilities to efficiently solubilize lipophilic guests within
an assembled scaffold and to stably encapsulate the molecular cargo
until desired release is achieved through the actions of appropriately
chosen stimuli. The former feature, dictated by the inherent loading
capacity of a nanocarrier, is well studied, and it has been established
that slight variations in assembly structure, such as introducing
hydrophobic content, can improve miscibility with the lipophilic guests
and increase the driving force for encapsulation. However, such clear
correlations between assembly properties and the latter feature, nanocarrier
encapsulation stability, are not yet established. For this purpose,
we have investigated the effects of varying hydrophobic content on
the loading parameters and encapsulation stabilities of self-cross-linked
polymer nanogels. Through investigating this nanogel series, we have
observed a fundamental relationship between nanoassembly structure,
loading capacity, and encapsulation stability. Furthermore, a combined
analysis of data from different loading amounts suggests a model of
loading-dependent encapsulation stability that underscores an important
correlation between the principal features of noncovalent encapsulation
in supramolecular hosts.