Bioelectromechanical imaging by scanning probe microscopy: Galvani's experiment at the nanoscale

Sergei V. Kalinin; B. J. Rodriguez; J. Shin; S. Jesse; V. Grichko; T. Thundat; A. P. Baddorf; A. Gruverman

doi:10.1016/j.ultramic.2005.10.005

Bioelectromechanical imaging by scanning probe microscopy: Galvani's experiment at the nanoscale

Sergei V. Kalinin
, B. J. Rodriguez
, J. Shin
, S. Jesse
, V. Grichko
, T. Thundat
, A. P. Baddorf
, A. Gruverman

Research output: Contribution to journal › Article › peer-review

68 Scopus citations

Abstract

Since the discovery in the late 18th century of electrically induced mechanical response in muscle tissue, coupling between electrical and mechanical phenomena has been shown to be a near-universal feature of biological systems. Here, we employ scanning probe microscopy (SPM) to measure the sub-Angstrom mechanical response of a biological system induced by an electric bias applied to a conductive SPM tip. Visualization of the spiral shape and orientation of protein fibrils with 5 nm spatial resolution in a human tooth and chitin molecular bundle orientation in a butterfly wing is demonstrated. In particular, the applicability of SPM-based techniques for the determination of molecular orientation is discussed.

Original language	English
Pages (from-to)	334-340
Number of pages	7
Journal	Ultramicroscopy
Volume	106
Issue number	4-5
DOIs	https://doi.org/10.1016/j.ultramic.2005.10.005
State	Published - Mar 2006

Keywords

Nanoscale
Piezoelectricity
Piezoresponse force microscopy
Proteins
Scanning probe microscopy

Access to Document

10.1016/j.ultramic.2005.10.005

Cite this

@article{69a96c4c65234a66aafbcf2a399f5d40,

title = "Bioelectromechanical imaging by scanning probe microscopy: Galvani's experiment at the nanoscale",

abstract = "Since the discovery in the late 18th century of electrically induced mechanical response in muscle tissue, coupling between electrical and mechanical phenomena has been shown to be a near-universal feature of biological systems. Here, we employ scanning probe microscopy (SPM) to measure the sub-Angstrom mechanical response of a biological system induced by an electric bias applied to a conductive SPM tip. Visualization of the spiral shape and orientation of protein fibrils with 5 nm spatial resolution in a human tooth and chitin molecular bundle orientation in a butterfly wing is demonstrated. In particular, the applicability of SPM-based techniques for the determination of molecular orientation is discussed.",

keywords = "Nanoscale, Piezoelectricity, Piezoresponse force microscopy, Proteins, Scanning probe microscopy",

author = "Kalinin, \{Sergei V.\} and Rodriguez, \{B. J.\} and J. Shin and S. Jesse and V. Grichko and T. Thundat and Baddorf, \{A. P.\} and A. Gruverman",

year = "2006",

month = mar,

doi = "10.1016/j.ultramic.2005.10.005",

language = "English",

volume = "106",

pages = "334--340",

journal = "Ultramicroscopy",

issn = "0304-3991",

publisher = "Elsevier",

number = "4-5",

}

TY - JOUR

T1 - Bioelectromechanical imaging by scanning probe microscopy

T2 - Galvani's experiment at the nanoscale

AU - Kalinin, Sergei V.

AU - Rodriguez, B. J.

AU - Shin, J.

AU - Jesse, S.

AU - Grichko, V.

AU - Thundat, T.

AU - Baddorf, A. P.

AU - Gruverman, A.

PY - 2006/3

Y1 - 2006/3

N2 - Since the discovery in the late 18th century of electrically induced mechanical response in muscle tissue, coupling between electrical and mechanical phenomena has been shown to be a near-universal feature of biological systems. Here, we employ scanning probe microscopy (SPM) to measure the sub-Angstrom mechanical response of a biological system induced by an electric bias applied to a conductive SPM tip. Visualization of the spiral shape and orientation of protein fibrils with 5 nm spatial resolution in a human tooth and chitin molecular bundle orientation in a butterfly wing is demonstrated. In particular, the applicability of SPM-based techniques for the determination of molecular orientation is discussed.

AB - Since the discovery in the late 18th century of electrically induced mechanical response in muscle tissue, coupling between electrical and mechanical phenomena has been shown to be a near-universal feature of biological systems. Here, we employ scanning probe microscopy (SPM) to measure the sub-Angstrom mechanical response of a biological system induced by an electric bias applied to a conductive SPM tip. Visualization of the spiral shape and orientation of protein fibrils with 5 nm spatial resolution in a human tooth and chitin molecular bundle orientation in a butterfly wing is demonstrated. In particular, the applicability of SPM-based techniques for the determination of molecular orientation is discussed.

KW - Nanoscale

KW - Piezoelectricity

KW - Piezoresponse force microscopy

KW - Proteins

KW - Scanning probe microscopy

UR - https://www.scopus.com/pages/publications/33344466735

U2 - 10.1016/j.ultramic.2005.10.005

DO - 10.1016/j.ultramic.2005.10.005

M3 - Article

C2 - 16387441

AN - SCOPUS:33344466735

SN - 0304-3991

VL - 106

SP - 334

EP - 340

JO - Ultramicroscopy

JF - Ultramicroscopy

IS - 4-5

ER -

Bioelectromechanical imaging by scanning probe microscopy: Galvani's experiment at the nanoscale

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this