To understand the role of surface
chemistry on cell behavior and the associated molecular mechanisms,
we developed and utilized a surface chemical gradient of amine functional
groups by carefully adjusting the gas composition of 1,7-octadiene
(OD) and allylamine (AA) of the plasma phase above a moving substrate.
The chemical gradient surface used in the present work shows an increasing
N/C ratio and wettability from the OD side toward the AA side with
no change in surface topography. Under standard culture conditions
(with serum), human adipose-derived stem cells (hASCs) adhesion and
spreading area increased toward the AA side of the gradient. However,
there were no differences in cell behavior in the absence of serum.
These results, supported by the trends in proteins adsorption on the
gradient surface, demonstrated that surface chemistry affects the
response of hASCs through cell-adhesive serum proteins, rather than
interacting directly with the cells. The expression of p-ERK and the
osteogenic differentiation increased toward the AA side of the gradient,
while adipogenic differentiation decreased in the same direction;
however, when the activation of ERK1/2 was blocked by PD98059, the
levels of osteogenic or adipogenic differentiation on different regions
of the chemical gradient were the same. This indicates that ERK1/2
may be an important downstream signaling pathway of surface chemistry
directed stem cell fate.