Direct characterization of radial modulus of DNA nanotube by AFM nanoindentation

Author

Zhipeng Ma ; Young-Joo Kim ; Seongsu Park ; Hirai, Yoshikazu ; Tsuchiya, Toshiyuki ; Do-Nyum Kim ; Tabata, Osamu

Author_Institution

Dept. of Micro Eng., Kyoto Univ., Kyoto, Japan

fYear

2015

fDate

7-11 April 2015

Firstpage

581

Lastpage

584

Abstract

DNA origami in a nanotube configuration is increasingly attractive for the creation of new structural systems that can confine or encapsulate a variety of nanoscale materials, but utilization as a functional mechanical component depends on understanding crucial properties such as the radial mechanical property that has rarely been studied. Here, we report the direct characterization of the radial modulus of a DNA nanotube by AFM nanoindentation. A corrected Hertz model was employed to interpret the measured force versus distance data. The biphasic material properties of the DNA nanotube were characterized for the first time and indicate a radial electrostatic modulus of about 10 ± 3 MPa in the small region where force was applied, and a radial elastic modulus of about 63 ± 20 MPa in a larger region.

Keywords

DNA; atomic force microscopy; biological techniques; biomechanics; elastic moduli; molecular biophysics; nanoindentation; nanotubes; AFM nanoindentation; DNA nanotube; DNA origami; Hertz model; biphasic material properties; direct characterization; functional mechanical component; nanoscale materials; nanotube configuration; radial elastic modulus; radial electrostatic modulus; radial mechanical property; structural systems; DNA; Force; Mathematical model; Nanobioscience; Nanoscale devices; Nanostructures; AFM nanoindentation; DNA origami; Hertz model; radial modulus;

fLanguage

English

Publisher

ieee

Conference_Titel

Nano/Micro Engineered and Molecular Systems (NEMS), 2015 IEEE 10th International Conference on

Conference_Location

Xi´an

Type

conf

DOI

10.1109/NEMS.2015.7147496

Filename

7147496