Endocytosis,
as one of the main ways for nanostructures enter cells,
is affected by several aspects, and shape is an especially critical
aspect during the endocytosis of nanostructures. However, it has remained
challenging to capture the dynamic internalization behaviors of rod-shaped
nanostructures while also probing the mechanical aspects of the internalization.
Here, using the atomic force microscopy-based force tracing technique,
transmission electron microscopy, and molecular dynamic simulation,
we mapped the detailed internalization behaviors of rod-shaped nanostructures
with different aspect ratios at the single-particle level. We found
that the gold nanorod is endocytosed in a noncontinuous and force-rebound
rotation manner, herein named “intermittent rotation”.
The force tracing test indicated that the internalization force (∼81
pN, ∼108 pN, and ∼157 pN) and time (∼0.56 s,
∼0.66 s, and ∼1.14 s for a 12.10 nm × 11.96 nm
gold nanosphere and 26.15 nm × 13.05 nm and 48.71 nm × 12.45
nm gold nanorods, respectively) are positively correlated with the
aspect ratios. However, internalization speed is negatively correlated
with internalization time, irrespective of the aspect ratio. Further,
the energy analysis suggested that intermittent rotation from the
horizontal to vertical direction can reduce energy dissipation during
the internalization process. Thus, to overcome the energy barrier
of internalization, the number and angle of rotation increases with
aspect ratios. Our findings provide critical missing evidence of rod-shaped
nanostructure’s internalization, which is essential for fundamentally
understanding the internalization mechanism in living cells.