posted on 2020-04-22, 10:29authored byJingjing Yao, Wenwen Fang, Jiaqi Guo, Dejin Jiao, Shiyan Chen, Shinsuke Ifuku, Huaping Wang, Andreas Walther
Many
biological high-performance composites, such as bone, antler,
and crustacean cuticles, are composed of densely mineralized and ordered
nanofiber materials. The mimicry of even simplistic bioinspired structures,
i.e., of densely and homogeneously mineralized nanofibrillar materials
with controllable mechanical performance, continues to be a grand
challenge. Here, using alkaline phosphatase as an enzymatic catalyst,
we demonstrate the dense, homogeneous, and spatially controlled mineralization
of calcium phosphate nanostructures within networks of anionically
charged cellulose nanofibrils (CNFs) and cationically charged chitin
nanofibrils (ChNFs)both emerging biobased nanoscale building
blocks for sustainable high-performance materials design. Our study
reveals that anionic CNFs lead to a more homogeneous nanoscale mineralization
with very high mineral contents up to ca. 70 wt % with a transition
from amorphous to crystalline deposits, while cationic ChNFs yield
rod-like crystalline morphologies. The bone-inspired CNF bulk films
exhibit a significantly increased stiffness, maintain good flexibility
and translucency, and have a significant gain in wet state mechanical
properties. The mechanical properties can be tuned both by the enzyme
concentration and the mineralization time. Moreover, we also show
a spatial control of the mineralization using kinetically controlled
substrate uptake in a dialysis reactor, and by spatially selectively
incorporating the enzyme into 2D printed filament patterns. The strategy
highlights possibilities for spatial encoding of enzymes in tailored
structures and patterns and programmed mineralization processes, promoting
the potential application of mineralized CNF biomaterials with complex
gradients for bone substitutes and tissue regeneration in general.