Transport-Limited Adsorption of Plasma Proteins on
Bimodal Amphiphilic Polymer Co-Networks: Real-Time Studies by Spectroscopic
Ellipsometry
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Abstract
Traditional hydrogels
are commonly limited by poor mechanical properties
and low oxygen permeability. Bimodal amphiphilic co-networks (β-APCNs)
are a new class of materials that can overcome these limitations by
combining hydrophilic and hydrophobic polymer chains within a network
of co-continuous morphology. Applications that can benefit from these
improved properties include therapeutic contact lenses, enzymatic
catalysis supports, and immunoisolation membranes. The continuous
hydrophobic phase could potentially increase the adsorption of plasma
proteins in blood-contacting medical applications and compromise in
vivo material performance, so it is critical to understand the surface
characteristics of β-APCNs and adsorption of plasma proteins
on β-APCNs. From real-time spectroscopic visible (Vis) ellipsometry
measurements, plasma protein adsorption on β-APCNs is shown
to be transport-limited. The adsorption of proteins on the β-APCNs
is a multistep process with adsorption to the hydrophilic surface
initially, followed by diffusion into the material to the internal
hydrophilic/hydrophobic interfaces. Increasing the cross-linking of
the PDMS phase reduced the protein intake by limiting the transport
of large proteins. Moreover, the internalization of the proteins is
confirmed by the difference between the surface-adsorbed protein layer
determined from XPS and bulk thickness change from Vis ellipsometry,
which can differ up to 20-fold. Desorption kinetics depend on the
adsorption history with rapid desorption for slow adsorption rates
(i.e., slow-diffusing proteins within the network), whereas proteins
with fast adsorption kinetics do not readily desorb. This behavior
can be directly related to the ability of the protein to spread or
reorient, which affects the binding energy required to bind to the
internal hydrophobic interfaces