Slope-Dependent Cell Motility Enhancements at the
Walls of PEG-Hydrogel Microgroove Structures
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Abstract
In recent years, research utilizing
micro- and nanoscale geometries
and structures on biomaterials to manipulate cellular behaviors, such
as differentiation, proliferation, survival, and motility, have gained
much popularity; however, how the surface microtopography of 3D objects,
such as implantable devices, can affect these various cell behaviors
still remains largely unknown. In this study, we discuss how the walls
of microgroove topography can influence the morphology and the motility
of unrestrained cells, in a different fashion from 2D line micropatterns.
Here adhesive substrates made of tetra(polyethylene glycol) (tetra-PEG)
hydrogels with microgroove structures or 2D line micropatterns were
fabricated, and cell motility on these substrates was evaluated. Interestingly,
despite being unconstrained, the cells exhibited drastically different
migration behaviors at the edges of the 2D micropatterns and the walls
of microgroove structures. In addition to acquiring a unilamellar
morphology, the cells increased their motility by roughly 3-fold on
the microgroove structures, compared with the 2D counterpart or the
nonpatterned surface. Immunostaining revealed that this behavior was
dependent on the alignment and the aggregation of the actin filaments,
and by varying the slope of the microgroove walls, it was found that
relatively upright walls are necessary for this cell morphology alterations.
Further progress in this research will not only deepen our understanding
of topography-assisted biological phenomena like cancer metastasis
but also enable precise, topography-guided manipulation of cell motility
for applications such as cancer diagnosis and cell sorting