Interfacial engineering for silica nanocapsules

Silica nanocapsules have attracted significant interest due to their core-shell hierarchical structure. The core domain allows the encapsulation of various functional components such as drugs, fluorescent and magnetic nanoparticles for applications in drug delivery, imaging and sensing, and the silica shell with its unique properties including biocompatibility, chemical and physical stability, and surface-chemistry tailorability provides a protection layer for the encapsulated cargo. Therefore, significant effort has been directed to synthesize silica nanocapsules with engineered properties, including size, composition and surface functionality, for various applications. This review provides a comprehensive overview of emerging methods for the manufacture of silica nanocapsules, with a special emphasis on different interfacial engineering strategies. The review starts with an introduction of various manufacturing approaches of silica nanocapsules highlighting surface engineering of the core template nanomaterials (solid nanoparticles, liquid droplets, and gas bubbles) using chemicals or biomolecules which are able to direct nucleation and growth of silica at the boundary of two-phase interfaces (solid-liquid, liquid-liquid, and gas-liquid). Next, surface functionalization of silica nanocapsules is presented. Furthermore, strategies and challenges of encapsulating active molecules (pre-loading and post-loading approaches) in these capsular systems are critically discussed. Finally, applications of silica nanocapsules in controlled release, imaging, and theranostics are reviewed.

A Vesicle Supra-Assembly Approach to Synthesize Amine-Functionalized Hollow Dendritic Mesoporous Silica Nanospheres for Protein Delivery

Intracellular delivery of proteins is a promising strategy of intervention in disease, which relies heavily on the development of efficient delivery platforms due to the cell membrane impermeability of native proteins, particularly for negatively charged large proteins. This work reports a vesicle supra-assembly approach to synthesize novel amine-functionalized hollow dendritic mesoporous silica nanospheres (A-HDMSN). An amine silica source is introduced into a water-oil reaction solution prior to the addition of conventional silica source tetraethylorthosilicate. This strategy favors the formation of composite vesicles as the building blocks which further assemble into the final product. The obtained A-HDMSN have a cavity core of ≈170 nm, large dendritic mesopores of 20.7 nm in the shell and high pore volume of 2.67 cm³ g^-1 . Compared to the calcined counterpart without amine groups (C-HDMSN), A-HDMSN possess enhanced loading capacity to large negative proteins (IgG and β-galactosidase) and improved cellular uptake performance, contributed by the cationic groups. A-HDMSN enhance the intracellular uptake of β-galactosidase by up to 5-fold and 40-fold compared to C-HDMSN and free β-galactosidase, respectively. The active form of β-galactosidase delivered by A-HDMSN retains its intracellular catalytic functions.

Formation of mesoporous silica nanoparticles with tunable pore structure as promising nanoreactor and drug delivery vehicle

Mesoporous silica nanoparticles with tunable pore structures have been successfully fabricated by simply tuning the ethanol amounts in the precursor.

Fabrication of superhydrophobic aromatic cotton fabrics

Superhydrophobic fabrics with lasting fragrance were fabricated in light of the development trend of high value-added and multi-functional materials.