Marine-Inspired Water-Structured Biomaterials
Kapitel i bok, 2010
Biomimetics can provide new insights for the design of the next generation of biomaterials based on hierarchical structures. In an inspirational project for research on structured materials with tailored mass transport properties, we have used the jellyfi sh as a model system because of its remarkable water - holding capacity. The microstructure of the jellyfi sh, Aurelia aurita , has been characterized by confocal laser scanning microscopy (CLSM) and by transmission electron microscopy (TEM). The characterization was focused on the mesoglea in order to understand the water management of jellyfi sh and related rheological properties. The results revealed a structure spanning a wide range of length scales. The mesoglea consists of long fi bers and a network spanning the space between them. It is a relatively coarse and open network consisting of proteins, as well as polysaccharides, which suggests a complex supermolecular proteoglucan structure. Jellyfi sh are sensitive to variations in salt content, and change in volume, shrinking with increasing salt content. The hierarchical structural levels are necessary for jellyfi sh to maintain their overall structure in water with varying salt contents. The coarse fi bers stabilize the jellyfi sh structure, and the network structure between the fi bers is most likely responsible for water management. By understanding the hierarchy and structures at different length scales, we can gain important information for the development of a new generation of hierarchically structured biomaterials with tailor - made mass transport, water management, and molecular mobilities.
Superabsorbents (SAPs) - absorbing pure water
Superabsorbents - components in modern hygiene products
Biomimetics - new insights for biomaterials designing
Mass transport - length scale dependent
Biomimetics - inspiring creating new functions
Superabsorbent - cross-linked polyacrylic acid