posted on 2018-04-17, 00:00authored byYun Li, Wenhao Qian, Jin Huang, Xianjing Zhou, Biao Zuo, Xinping Wang, Wei Zhang
To
investigate protein-resistant surfaces with heterogeneous nanopatterns,
V-shaped polymer brushes composed of a hydrophilic methoxypoly(ethylene
glycol) (mPEG) arm and a hydrophobic polystyrene (PS) or fluorinated
poly(methyl methacrylate) (PMMA-b-PFMA) arm were
prepared, in which the surface structure and phase-separation behavior
were controlled by altering the relative lengths of the two arms.
The protein resistance of these amphiphilic brushes was better than
that of pure poly(ethylene glycol) (PEG) brushes, and when the domain
size of the phase-separated structures was about twice the size of
the protein molecules, the surfaces exhibited optimal protein repellence.
At the same time, the amount of protein adsorption was well related
to both the adhesion and the relative friction coefficient of the
protein on the brush surface. A heterogeneous surface with phase-separated
domains twice the size of protein molecules may be beneficial for
minimizing protein adsorption through the synergistic effect of hydrophobic
and water-soluble domains. These results provide an important way
for designing and preparing protein-resistant materials with heterogeneous
surfaces.