Surface topography is a biophysical factor affecting
cell behaviors,
yet the underlying cues are still not clear. Herein, we hypothesized
that stereo coverage and overall stiffness of biomaterial arrays on
the scale of single cells underly parts of topography effects on cell
adhesion. We fabricated a series of microarrays (micropillar, micropit,
and microtube) of poly(l-lactic acid) (PLLA) using mold casting
based on pre-designed templates. The characteristic sizes of array
units were less than that of a single cell, and thus, each cell could
sense the micropatterns with varied roughness. With human umbilical
vein endothelial cells (HUVECs) as the model cell type, we examined
spreading areas and cell viabilities on different surfaces. “Stereo
coverage” was defined to quantify the actual cell spreading
fraction on a topographic surface. Particularly in the case of high
micropillars, cells were confirmed not able to touch the bottom and
had to partially hang among the micropillars. Then, in our opinion,
a cell sensed the overall stiffness combining the bulk stiffness of
the raw material and the stiffness of the culture medium. Spreading
area and single cell viability were correlated to coverage and topographic
feature of the prepared microarrays in particular with the significantly
protruded geometry feather. Cell traction forces exerted on micropillars
were also discussed. These findings provide new insights into the
surface modifications toward biomedical implants.