Artificial joint replacement is the most effective way
to treat
osteoarthritis. However, these artificial joints are too stiff with
high interfacial contact stress and poor surface lubrication, resulting
in stress shielding and severe wear and tear lead to an extremely
high failure rate. At present, hydrogels are considered the most promising
substitute for artificial joint prostheses owing to their good biocompatibility,
adjustable mechanical properties, and excellent flexibility. Nevertheless,
a traditional single-layer hydrogel has poor bearing capacity and
lubrication, which are far from the properties of natural articular
cartilage. The high strength and low friction properties of natural
articular cartilage are based on its own multilayer fibrous structure.
Therefore, by simulating the multilayer structure of natural cartilage,
a bilayer bionic cartilage hydrogel was prepared; that is, the upper
hydrogel realized excellent lubrication and the lower hydrogel realized
high load-bearing capacity. However, the interface binding of bilayer
hydrogels is a challenge at present. Therefore, the interfacial adhesion
of the bilayer hydrogel is improved by adding tannic acid (TA) based
on the adhesion of the natural polyphenol structure. The average interfacial
toughness reaches 3650 J/m2, and the average interfacial
shear force reaches 800 kPa. In the preparation of the bilayer hydrogel,
taking advantage of the coordination reaction between TA and metal
cations, Fe3+ is further added to endow the bilayer hydrogel
with excellent mechanical properties and good sliding friction performance.
Therefore, this work opens up a new way to construct cartilage-like
materials with high toughness and a soft–soft interface.