The transport of
macromolecules and nanoscopic particles to a target
cellular site is a crucial aspect in many physiological processes.
This directional motion is generally controlled via active mechanical and chemical processes. Here we show, by means
of molecular dynamics simulations and an analytical theory, that completely
passive nanoparticles can exhibit directional motion when embedded
in nonuniform mechanical environments. Specifically, we study the
motion of a passive nanoparticle adhering to a mechanically nonuniform
elastic membrane. We observe a nonmonotonic affinity of the particle
to the membrane as a function of the membrane’s rigidity, which
results in the particle transport. This transport can be both up or
down the rigidity gradient, depending on the absolute values of the
rigidities that the gradient spans across. We conclude that rigidity
gradients can be used to direct average motion of passive macromolecules
and nanoparticles on deformable membranes, resulting in the preferential
accumulation of the macromolecules in regions of certain mechanical
properties.
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