Issue 26, 2017

Carbon nanoscroll–silk crystallite hybrid structures with controllable hydration and mechanical properties

Abstract

Hybrid structures of nanomaterials (e.g. tubes, scrolls, threads, cages) and biomaterials (e.g. proteins) hold tremendous potential for applications as drug carriers, biosensors, tissue scaffolds, cancer therapeutic agents, etc. However, in many cases, the interacting forces at the nano–bio interfaces and their roles in controlling the structures and dynamics of nano–bio-hybrid systems are very complicated but poorly understood. In this study, we investigate the structure and mechanical behavior of a protein-based hybrid structure, i.e., a carbon nanoscroll (CNS)–silk crystallite with a hydration level controllable by an interlayer interaction in CNS. Our findings demonstrate that CNS with a reduced core size not only shields the crystallite from a weakening effect of water, but also markedly strengthens the crystallite. Besides water shielding, the enhanced strength arises from an enhanced interaction between the crystallite and CNS due to the enhanced interlayer interaction in CNS. In addition, the interfacial strength for pulling the crystallite out of the CNS–silk structure is found to be dependent on both the interlayer interaction energy in CNS as well as the sequence of protein at the CNS–silk interface. The present study is of significant value in designing drugs or protein delivery vehicles for biomedical applications, and serves as a general guide in designing novel devices based on rolled-up configurations of two-dimensional (2D) materials.

Graphical abstract: Carbon nanoscroll–silk crystallite hybrid structures with controllable hydration and mechanical properties

Supplementary files

Article information

Article type
Paper
Submitted
27 Feb 2017
Accepted
02 Jun 2017
First published
05 Jun 2017

Nanoscale, 2017,9, 9181-9189

Carbon nanoscroll–silk crystallite hybrid structures with controllable hydration and mechanical properties

Y. Cheng, L. Koh, F. Wang, D. Li, B. Ji, J. Yeo, G. Guan, M. Han and Y. Zhang, Nanoscale, 2017, 9, 9181 DOI: 10.1039/C7NR01428G

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