posted on 2022-01-18, 19:09authored byYounggeun Park, Hyeun Joong Yoon, Somin Eunice Lee, Luke P. Lee
Multifunctional nanoprobes have attracted
significant attention
in a wide range of disciplines such as nanomedicine, precision medicine,
and cancer diagnosis and treatment. However, integrating multifunctional
ability in a nanoscale structure to precisely target, image, and deliver
with cellular spatial/temporal resolution is still challenging in cellulo applications. This is because the development
of such high-precision resolution needs to be carried out without
labeling, photobleaching, and structurally segregating live cells.
In this study, we present an integrated nanostructure of a mesoporous-silica
nanosphere with an optical nanocrescent antenna (MONA) for multifunctional
cellular targeting, drug delivery, and molecular imaging with spatiotemporal
resolution. MONA comprises a systematically constructed Au nanocrescent
(AuNC) antenna as a nanosensor and optical switch on a mesoporous-silica
nanosphere as a cargo to molecular delivery. MONA made of antiepithelial
cell adhesion molecules (anti-EpCAM)-conjugated AuNC facilitates the
specific targeting of breast cancer cells, resulting in a highly focused
photothermal gradient that functions as a molecular emitter. This
light-driven molecular, doxorubicin (DOX) delivery function allows
rapid apoptosis of breast cancer cells. Since MONA permits the tracking
of quantum biological electron-transfer processes, in addition to
its role as an on-demand optical switch, it enables the monitoring
of the dynamic behavior of cellular cytochrome c pivoting
cell apoptosis in response to the DOX delivery. Owing to the integrated
functions of molecular actuation and direct sensing at the precisely
targeted spot afforded by MONA, we anticipate that this multifunctional
optical nanoantenna structure will have an impact in the fields of
nanomedicine, cancer theranostics, and basic life sciences.