posted on 2012-03-06, 00:00authored byKan Wang, Lei Cai, Stephen Jesse, Shanfeng Wang
We report that protein adsorption, cell attachment, and
cell proliferation
were enhanced on spherulites-roughened polymer surfaces. Banded spherulites
with concentric alternating succession of ridges and valleys were
observed on spin-coated thin films of poly(ε-caprolactone) (PCL)
and two series of PCL binary homoblends composed of high- and low-molecular-weight
components when they were isothermally crystallized at 25–52
°C. Their thermal properties, crystallization kinetics, and surface
morphology were examined. The melting temperature (Tm), crystallinity (χc), crystallization
rate, and spherulitic patterns showed strong dependence on the crystallization
temperature (Tc) and the blend composition.
The surface roughness of the spherulites was higher when Tc was higher; thus, the larger surface area formed in
banded spherulites could adsorb more serum proteins from cell culture
media. In vitro mouse preosteoblastic MC3T3-E1 cell attachment, proliferation,
and nuclear localization were assessed on the hot-compressed flat
disks and spherulites-roughened films of the high-molecular-weight
PCL and one of its homoblends. The number of attached MC3T3-E1 cells
and the proliferation rate were greater on the rougher surfaces than
those on the flat ones. It is interesting to note that cell nuclei
were preferentially, though not absolutely, located in or close to
the valleys of the banded spherulites. The percentage of cell nuclei
in the valleys was higher than 78% when the ridge height and adjacent
ridge distance were ∼350 and ∼35 nm, respectively. This
preference was weaker when the ridge height was lower or at a higher
cell density. These results suggest that isothermal crystallization
of semicrystalline polymers can be an effective thermal treatment
method to achieve controllable surface roughness and pattern for regulating
cell behaviors in tissue-engineering applications.