|
molecular imaging |
5 |
|
fluorescence imaging |
4 |
|
image-guided surgery |
4 |
|
nir-iib imaging |
4 |
|
short-wave infrared |
4 |
|
anode-free lithium batteries |
3 |
|
battery |
3 |
|
caries detection |
3 |
|
chemistry |
3 |
|
clinical photography |
3 |
|
dental caries |
3 |
|
diagnosis |
3 |
|
diagnostic accuracy |
3 |
|
digital dentistry |
3 |
|
energy storage |
3 |
|
high-voltage |
3 |
|
ionic liquid electrolytes |
3 |
|
light-sheet microscope |
3 |
|
material sciences |
3 |
|
near-infrared ii imaging |
3 |
|
near-infrared reflection |
3 |
|
nonflammable materials |
3 |
|
noninvasive imaging |
3 |
|
structured-illumination microscopy |
3 |
|
teledentistry |
3 |
|
bio-syncretic robots |
2 |
|
biohybrid devices |
2 |
|
cell actuation |
2 |
|
cl2 trapping |
2 |
|
deep learning |
2 |
|
deep tissue |
2 |
|
excretion |
2 |
|
gold nanoclusters |
2 |
|
hexagonal-textured surfaces |
2 |
|
high-capacity |
2 |
|
imaging agents |
2 |
|
imaging-guided surgery |
2 |
|
in vivo |
2 |
|
living machines |
2 |
|
microsphere |
2 |
|
molecular imaging of apoptosis |
2 |
|
moving contact line |
2 |
|
nanomedicine |
2 |
|
nanoparticles |
2 |
|
near-infrared |
2 |
|
near-infrared imaging |
2 |
|
nir-ii fluorophore |
2 |
|
nir-ii imaging |
2 |
|
nir-ii window |
2 |
|
nir-iib window |
2 |
|
pd-l1 |
2 |
|
photothermal therapy |
2 |
|
privacy and federated learning |
2 |
|
quantum dots |
2 |
|
rechargeable lithium/chlorine battery |
2 |
|
renal excretion |
2 |
|
second near-infrared window |
2 |
|
soft robots |
2 |
|
super-resolution |
2 |
|
superhydrophilic |
2 |
|
superspreading |
2 |
|
thionyl chloride (socl2) |
2 |
|
ultralow temperature |
2 |
|
absorbance |
1 |
|
atomic force microscope |
1 |
|
atomic force microscopy |
1 |
|
atomic force microscopy (afm) |
1 |
|
bio-detection principles |
1 |
|
biosensor |
1 |
|
biostress sensing |
1 |
|
biosyncretic imaging system |
1 |
|
broadband emission |
1 |
|
cell-based photodetector |
1 |
|
cr3+ |
1 |
|
dielectric microsphere |
1 |
|
dielectric microsphere nanoscopy |
1 |
|
direct inverse asymmetric pi model |
1 |
|
distance accuracy |
1 |
|
dynamic cantilever model |
1 |
|
echo effect |
1 |
|
electrohydrodynamic instability |
1 |
|
enhancement mechanisms |
1 |
|
exciton emission |
1 |
|
feedforward control |
1 |
|
fluorescent protein |
1 |
|
glucose sensor |
1 |
|
graphene |
1 |
|
hysteresis |
1 |
|
immunotherapy |
1 |
|
laser processing |
1 |
|
laser-nanomachining |
1 |
|
magnification factor |
1 |
|
micro-pillars |
1 |
|
micro-robotics |
1 |
|
micro/nanofabrication |
1 |
|
microelectromechanical systems |
1 |
|
microfluidic devices |
1 |
|
microlens |
1 |
|
microlens array |
1 |
|
microparticles |
1 |
|
multi-site occupancy |
1 |
|
multiple modes |
1 |
|
nano-scale processing |
1 |
|
nanomanipulation |
1 |
|
nanoscale imaging |
1 |
|
nanoscale manipulation |
1 |
|
nir ml |
1 |
|
nir-ii fluorophore probe |
1 |
|
nirii |
1 |
|
optical microscopy |
1 |
|
optically induced electrokinetics |
1 |
|
optically induced electrokinetics forces |
1 |
|
optogenetically engineered cell |
1 |
|
particle concentration |
1 |
|
pdms |
1 |
|
photoacoustic |
1 |
|
photodynamic therapy |
1 |
|
photonic nanojet |
1 |
|
photostability |
1 |
|
photothermal/photodynamic/chemo combination therapy |
1 |
|
piezoelectric actuator |
1 |
|
real-time |
1 |
|
robotic fish |
1 |
|
scanning platform |
1 |
|
scanning probe-lens microscopy |
1 |
|
scanning superlens microscopy |
1 |
|
self-sensing cantilever |
1 |
|
sensing |
1 |
|
signal-to-noise ratio |
1 |
|
single laser triggering |
1 |
|
singlet oxygen quantum yield |
1 |
|
sub-diffraction limited |
1 |
|
sub-nanomachining |
1 |
|
super-resolution imaging |
1 |
|
thin-film patterning |
1 |
|
thiophene donor |
1 |
|
three-dimensional imaging |
1 |
|
ultrasonic-assisted machining |
1 |
|
visible light communication |
1 |
