|
cell adhesion |
8 |
|
3d culturing |
5 |
|
atomic force microscopy |
5 |
|
axon beading |
5 |
|
cell mechanics |
5 |
|
fibroblasts |
5 |
|
membrane shape stability |
5 |
|
myofibroblasts |
5 |
|
neuron injury |
5 |
|
stromal fibrosis |
5 |
|
transforming growth factor-beta 1 |
5 |
|
3d nanoscale topography |
4 |
|
atomic force microscope |
4 |
|
axon retraction |
4 |
|
cell-cell contact |
4 |
|
contact inhibition |
4 |
|
deep trench |
4 |
|
drug-resistance |
4 |
|
elasticity |
4 |
|
electrohydrodynamic printing |
4 |
|
electroporation |
4 |
|
high-aspect-ratio probe |
4 |
|
mechanotransduction |
4 |
|
modeling |
4 |
|
nano-indentation |
4 |
|
neuron adhesion |
4 |
|
neuron mechanics |
4 |
|
partial confinement |
4 |
|
rigidity-dependent cell growth |
4 |
|
traumatic injury |
4 |
|
viscoelasticity |
4 |
|
adhesion |
3 |
|
anodic aluminium oxide |
3 |
|
anodic aluminum oxide |
3 |
|
bio-polymer network |
3 |
|
biological organs |
3 |
|
cell culture |
3 |
|
cells |
3 |
|
cracks |
3 |
|
diseases |
3 |
|
dynamics |
3 |
|
electroosmosis |
3 |
|
finite element method |
3 |
|
fluidic devices |
3 |
|
focused-ion-beam |
3 |
|
friction |
3 |
|
indentation |
3 |
|
ion engines |
3 |
|
learning algorithms |
3 |
|
loads (forces) |
3 |
|
micro-pillars |
3 |
|
microtubule |
3 |
|
nanoindentation |
3 |
|
nucleus |
3 |
|
plastic deformation |
3 |
|
relaxation time |
3 |
|
active contraction |
2 |
|
affects |
2 |
|
binding kinetics |
2 |
|
biointerfaces |
2 |
|
biopolymer network |
2 |
|
cell blebbing |
2 |
|
cell plasticity |
2 |
|
cellular force |
2 |
|
columns |
2 |
|
compression |
2 |
|
constantly |
2 |
|
cross-linker |
2 |
|
cross-linking molecule |
2 |
|
deformation |
2 |
|
diamond |
2 |
|
diffusible ligands |
2 |
|
ecm dynamics |
2 |
|
endocytosis |
2 |
|
engineering biomaterials |
2 |
|
experiment |
2 |
|
focal adhesions |
2 |
|
fracture resistance |
2 |
|
honeycombs |
2 |
|
hydrogel |
2 |
|
kirigami electronics |
2 |
|
langevin dynamics |
2 |
|
ligand recruitment |
2 |
|
matrix mechanics |
2 |
|
mechanical response |
2 |
|
membrane deformation |
2 |
|
modulus |
2 |
|
morphogenesis |
2 |
|
motility |
2 |
|
myeloid |
2 |
|
nanofiber frameworks |
2 |
|
osmotic |
2 |
|
silicon vacancy center |
2 |
|
stiffness matrix |
2 |
|
stimuli |
2 |
|
stretch |
2 |
|
stretchable electronics |
2 |
|
thermal conductivity |
2 |
|
thermal fluctuations |
2 |
|
thermometry |
2 |
|
time-dependent |
2 |
|
tissue wave |
2 |
|
viscosity |
2 |
|
walls |
2 |
|
wearable systems |
2 |
|
actin-based motility |
1 |
|
actins - metabolism |
1 |
|
active motor |
1 |
|
adhesion and adhesives |
1 |
|
adhesion energy |
1 |
|
adhesive contact |
1 |
|
amorphous solids |
1 |
|
amyloid |
1 |
|
analytical expressions |
1 |
|
animals |
1 |
|
anisotropic |
1 |
|
anisotropic nanomaterials |
1 |
|
anisotropy orientation |
1 |
|
anomalous diffusion |
1 |
|
axonal cytoskeleton |
1 |
|
bending deformations |
1 |
|
bio-filament |
1 |
|
biomaterials |
1 |
|
biomechanics |
1 |
|
biophysics - methods |
1 |
|
body |
1 |
|
bonding |
1 |
|
boundary integral |
1 |
|
brownian mechanics |
1 |
|
cell biophysics |
1 |
|
cell contractility |
1 |
|
cell membrane |
1 |
|
cell membrane tension |
1 |
|
cell motility |
1 |
|
cell spreading |
1 |
|
cell-material interaction |
1 |
|
cellular traction |
1 |
|
cell–material interactions |
1 |
|
chemical potential |
1 |
|
chemo-mechanical processes |
1 |
|
circulating tumor cells |
1 |
|
closed form |
1 |
|
closed mitosis |
1 |
|
cohesive law |
1 |
|
computer simulation |
1 |
|
confinement energy |
1 |
|
contact mechanics |
1 |
|
contact problem |
1 |
|
contour lengths |
1 |
|
cooperative behaviors |
1 |
|
core interactions |
1 |
|
cytoskeletal network |
1 |
|
cytoskeleton |
1 |
|
cytoskeleton - metabolism |
1 |
|
cytoskeleton damage |
1 |
|
defect size |
1 |
|
deformation mechanism |
1 |
|
detachment |
1 |
|
diffusion |
1 |
|
electrotransfection |
1 |
|
energy dissipation |
1 |
|
filopodia |
1 |
|
focal adhesion |
1 |
|
focal adhesion (fa) |
1 |
|
fracture response |
1 |
|
frictional heating |
1 |
|
grafty molecule |
1 |
|
hysteresis |
1 |
|
instead |
1 |
|
interface |
1 |
|
lights |
1 |
|
lipid diffusion |
1 |
|
listeria - physiology |
1 |
|
live cell staining |
1 |
|
macroscopic deformations |
1 |
|
macroscopic response |
1 |
|
macroscopic stress |
1 |
|
matrix physical remodeling |
1 |
|
mechanical behavior |
1 |
|
mechanical stability |
1 |
|
mechano-sensing |
1 |
|
mechanosensing |
1 |
|
mechanosensitivity |
1 |
|
membrane resealing |
1 |
|
metastatic potential |
1 |
|
microscopy - methods |
1 |
|
microtubule dynamics |
1 |
|
models, biological |
1 |
|
molecular adhesion |
1 |
|
molecular bond |
1 |
|
molecular dynamics model |
1 |
|
molecular dynamics simulation |
1 |
|
monitored |
1 |
|
nanoparticle |
1 |
|
nanoscale ligand presentation |
1 |
|
non-small cell lung cancer |
1 |
|
nuclear envelope |
1 |
|
peel test |
1 |
|
peeling |
1 |
|
plasticity |
1 |
|
polymerization |
1 |
|
quantitatively |
1 |
|
rate dependence |
1 |
|
receptor‐ligand bonds |
1 |
|
rho pathway |
1 |
|
soft materials |
1 |
|
statistical mechanics |
1 |
|
steric repulsion |
1 |
|
stochastic detachment |
1 |
|
sudden |
1 |
|
surface roughness |
1 |
|
systematically |
1 |
|
t cell activation |
1 |
|
theory modeling |
1 |
|
thermal fluctuation |
1 |
|
thermal undulations |
1 |
|
thermoelasticity |
1 |
|
timescales |
1 |
|
topography |
1 |
|
transient state |
1 |
|
transverse isotropy |
1 |
|
vesicle mechanics |
1 |
