Investigation on mussel periostracum, a viscoelastic-to-poro-gel graded material, as an interface between soft tissue and rigid materials

Mussel periostracum, a nonliving multifunctional gel that covers the rigid inorganic shells of mussels, provides protection against mechanical impacts, biofouling, and corrosion in harsh ocean environments. The inner part of the periostracum, which emerges from biological tissues, functions as a nat...

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Bibliographic Details
Published in:NPG Asia materials 2024-04, Vol.16 (1), p.23-13, Article 23
Main Authors: Kim, Hyungbin, Lim, Heejin, Kim, Sangsik, Koo, Jun Mo, Lim, Chanoong, Kwak, Hojung, Oh, Dongyeop X., Hwang, Dong Soo
Format: Article
Language:English
Subjects:
631/45
639/301/54/1754
Biofouling
Biomaterials
Chemistry and Materials Science
Compressive properties
Connective tissues
Durability
Energy dissipation
Energy Systems
Human tissues
Inorganic materials
Marine environment
Materials Science
Moisture content
Mussels
Optical and Electronic Materials
Proteins
Soft tissues
Stiffness
Structural Materials
Surface and Interface Science
Thin Films
Tissues
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Summary:Mussel periostracum, a nonliving multifunctional gel that covers the rigid inorganic shells of mussels, provides protection against mechanical impacts, biofouling, and corrosion in harsh ocean environments. The inner part of the periostracum, which emerges from biological tissues, functions as a natural interface between tissue and inorganic materials. The periostracum shows significant potential for application in implantable devices that provide interfaces; however, this system remains unexplored. In this study, we revealed that the inner periostracum performs graded mechanical functions and efficiently dissipates energy to accommodate differences in stiffness and stress types on both sides. On the tissue end, the lightly pigmented periostracum exhibits extensibility and energy dissipation under repetitive tension. This process was facilitated by the slipping and reassembly of β-strands in the discovered major proteins, which we named periostracin proteins. On the shell end, the highly pigmented, mineralized, and porous segment of the periostracum provided stiffness and cushioned against compressive stresses exerted by the shell valves during closure. These findings offer a novel possibilities for the design of interfaces that bridge human tissue and devices. The interfaces linking biological tissues and man-made devices is challenging due to mechanical mismatch, biofouling, and water content. Soft materials such as hydrogels have emerged in diverse applications, however, their unresolved problem is the loss of functions in a short period. This report explores natural connective tissue, called periostracum, which is perfectly bridged between biological tissue and inorganic nonliving shell with high durability for long-lasting functions. Its hierarchically designed strategy provides a novel blueprint to design durable soft materials for the interfacing device into tissue.
ISSN:1884-4057
1884-4049
1884-4057
DOI:10.1038/s41427-024-00543-x