Unveiling the Spatiotemporal
and Dose Responses within
a Single Live Cancer Cell to Photoswitchable Upconversion Nanoparticle
Therapeutics Using Hybrid Hyperspectral Stimulated Raman Scattering
and Transient Absorption Microscopy
Photodynamic therapy (PDT) provides an alternative approach
to
targeted cancer treatment, but the therapeutic mechanism of advanced
nanodrugs applied to live cells and tissue is still not well understood.
Herein, we employ the hybrid hyperspectral stimulated Raman scattering
(SRS) and transient absorption (TA) microscopy developed for real-time
in vivo visualization of the dynamic interplay between the unique
photoswichable lanthanide-doped upconversion nanoparticle-conjugated
rose bengal and triphenylphosphonium (LD-UCNP@CS-Rb-TPP) probe synthesized
and live cancer cells. The Langmuir pharmacokinetic model associated
with SRS/TA imaging is built to quantitatively track the uptakes and
pharmacokinetics of LD-UCNP@CS-Rb-TPP within cancer cells. Rapid SRS/TA
imaging quantifies the endocytic internalization rates of the LD-UCNP@CS-Rb-TPP
probe in individual HeLa cells, and the translocation of LD-UCNP@CS-Rb-TPP
from mitochondria to cell nuclei monitored during PDT can be associated
with mitochondria fragmentations and the increased nuclear membrane
permeability, cascading the dual organelle ablations in cancer cells.
The real-time SRS spectral changes of cellular components (e.g., proteins,
lipids, and DNA) observed reflect the PDT-induced oxidative damage
and the dose-dependent death pattern within a single live cancer cell,
thereby facilitating the real-time screening of optimal light dose
and illumination duration controls in PDT. This study provides new
insights into the further understanding of drug delivery and therapeutic
mechanisms of photoswitchable LD-UCNP nanomedicine in live cancer
cells, which are critical in the optimization of nanodrug formulations
and development of precision cancer treatment in PDT.