Lubricin
(LUB, aka PRG4), a mucin-like glycoprotein, is best known
for the significant role it plays in the boundary lubrication, wear
protection, and adhesion control systems in human joints. However,
LUB exhibits a number of diverse and useful properties, including
a remarkable ability to self-assemble into a telechelic brush structure
onto virtually any substrate. This self-assembly behavior has spawned
the emergence of numerous nontraditional applications of LUB coatings
in numerous areas such as microfluidics, electrochemical sensors,
contact lenses, antifouling surfaces, and bionic neural interfaces.
Although LUB will readily self-assemble on most substrates, it has
become apparent that the substrate has a significant influence on
the LUB layer’s demonstrated lubrication, antiadhesion, electrokinetic,
and size-selective transport properties; however, investigations into
LUB–substrate interactions and how they influence the self-assembled
LUB layer structure remain a neglected aspect of LUB research. This
study utilizes AFM force spectroscopy to directly assess the adhesion
energy of LUB molecules adsorbed to a wide variety of different substrates
which include inorganic, polymeric, and metallic materials. An analysis
of the steric repulsive forces measured on approach provides a qualitative
assessment of the LUB layer’s mechanical modulus, related to
the chain packing density, across substrates. These modulus measurements,
combined with characteristic features and the dwell time dependence
of the LUB adhesion forces provide insight into the organization and
uniformity of the LUB brush structure. The results of these measurements
indicate that LUB interactions with different substrates are highly
variable and substrate-specific, resulting in a surprisingly broad
spectrum of adhesion energies and layer properties (i.e., chain density,
uniformity, etc.) which are not, themselves, correlated or easily
predicted by substrate properties. In addition, this study finds exceptionally
poor LUB adhesion to both mica and poly(methyl methacrylate) surfaces
that remain widely used substrates for constructing model surfaces
in fundamental tribology studies which may have significant implications
for the findings of a number of foundational studies into LUB tribology
and molecular synergies.
