RESUMEN
Polymer nanocapsules have demonstrated significant value in materials science and biomedical technology, but require complicated and time-consuming synthetic steps. We report here the facile synthesis of monodisperse polymer nanocapsules via a redox-mediated kinetic strategy from two simple molecules: dopamine and benzene-1,4-dithiol (BDT). Specifically, BDT forms core templates and modulates the oxidation kinetics of dopamine into polydopamine (PDA) shells. These uniform nanoparticles can be tuned between ≈70 and 200â nm because the core diameter directly depends on BDT while the shell thickness depends on dopamine. The supramolecular core can then rapidly disassemble in organic solvents to produce PDA nanocapsules. Such nanocapsules exhibit enhanced physicochemical performance (e.g., loading capacity, photothermal transduction, and anti-oxidation) versus their solid counterparts. Particularly, this method enables a straightforward encapsulation of functional nanoparticles providing opportunities for designing complex nanostructures such as yolk-shell nanoparticles.
Asunto(s)
Indoles/química , Nanocápsulas/química , Polímeros/química , Compuestos de Sulfhidrilo/química , Dopamina/química , Indoles/síntesis química , Estructura Molecular , Oxidación-Reducción , Tamaño de la Partícula , Polímeros/síntesis químicaRESUMEN
Long-range assembly of DNA currently comprises both top-down and bottom-up methods. The top-down techniques consist of physical alignment of DNA and lithographic patterning to organize DNA on surfaces. The bottom-up approaches include lipid-and polymer-DNA co-assembly, the self-assembly of DNA amphiphiles, and the remarkably specific and versatile methods of DNA nanotechnology. DNA-based materials possess unprecedented molecular control and may offer innovative solutions in the fields of nanotechnology, sensing, nanomedicine, as well as optical and electronic devices. To realize the potential of these materials, a number of hurdles must be addressed. Bridging the gap between top-down fabrication and bottom-up assembly is of critical importance to the successful development of functional DNA-based technology. A profound understanding of both regimes is necessary to achieve this goal.