posted on 2022-11-24, 08:30authored byChao Lin, Pengju Pan, Guorong Shan, Miao Du
Water-in-oil-in-water (W/O/W) Pickering double emulsions
are promising
materials for the construction of carriers for water-soluble and oil-soluble
molecules or drug delivery systems if the contradictive trade-off
between their extreme stability and controlled release properties
can be resolved. In this study, biodegradable and biocompatible poly(ethylene
glycol)-b-poly(ε-caprolactone-co-δ-valerolactone) (PEG-b-PCVL) diblock copolymers
with predesigned hydrophilic to hydrophobic block length ratios and
nearly identical ε-caprolactone/δ-valerolactone molar
ratio (8/2), were synthesized by ring-opening copolymerization. Then,
they self-assembled to create semicrystalline micelles. The melting
points of PEG-b-PCVL copolymers and their lyophilized
micelles were within a physiological range of temperatures, as determined
by differential scanning calorimetry. Water contact angle measurements
provided evidence that the surface wettability of PEG-b-PCVL micelles could be tuned by the PCVL block mass fractions or
temperature stimulus. Such PEG-b-PCVL micelles were
employed as a single particulate stabilizer to develop Pickering double
emulsions through a one-step emulsification technique. W/O/W Pickering
double emulsions could be generated using relatively hydrophobic PEG-b-PCVL micelles with high mass fractions (exceeding about
89%) of PCVL blocks, and they displayed excellent long-term physical
stabilities at room temperature. However, the Pickering double emulsions
underwent a rapid microstructural transition into simple oil-in-water
Pickering emulsions instead of complete demulsification at elevated
temperature (37 °C), which was attributed to the hydrophilicity
of micelles enhanced when the core-forming PCVL melted realized by
temperature stimulus. Consequently, such W/O/W Pickering double emulsions
stabilized solely with semicrystalline PEG-b-PCVL
micelles exhibit thermal responsiveness, enabling them to release
vitamin B12 encapsulated within the internal aqueous phase rapidly.