80th Annual Meeting of the APS Southeastern Section
Volume 58, Number 17
Wednesday–Saturday, November 20–23, 2013;
Bowling Green, Kentucky
Session GB: Cellular Mechanics and Biomechanics
1:30 PM–4:55 PM,
Friday, November 22, 2013
Room: 1
Chair: Martin Guthold, Wake Forest University
Abstract ID: BAPS.2013.SES.GB.1
Abstract: GB.00001 : Mechanical Property measurements of Single Nanofibers
1:30 PM–1:55 PM
Preview Abstract
Abstract
Author:
Christine Helms
(University of Richmond)
Mechanical properties of biological materials play an important role in
physiology. Specifically, mechanical properties of nanofibers are important
to the extracellular matrix as well as in blood coagulation. Previous
studies measured mechanical and structural properties such as creep, storage
modulus, G', and loss modulus, G'' of nanofiber mats or bundles however,
individual fiber properties were not measured due to measurement limitations
because of the size of the fibers. However, advances in technologies,
instrumentations and techniques now allow us to probe the properties of
individual nanofibers. The mechanical properties of individual fibers help
us to understand and model the properties of the bulk fiber network.
Our research focuses on the mechanical properties of fibrin fibers and
electrospun fibrinogen. Studies on electrospun fibers have determined their
bending modulus and extensibility and elastic limit. We have worked in
concert with these efforts to expand the knowledge of single fiber
mechanical properties using a combined atomic force microscope (AFM) and
inverted optical microscope. We found fibrin fiber have a modulus of 4 $+$/-
3 MPa when uncrosslinked and 15 $+$/- 7 MPa when crosslinked. When we
measured a variant fibrinogen molecule, which eliminates gamma-gamma
crosslinking, the modulus was 10 $+$/- 12 MPa. We also measured the
extensibility of the fibers, the extensibilities were 221 $+$/- 44 {\%}, 177
$+$/- 58 {\%} and 236 $+$/- 96 {\%} for uncrosslinked, crosslinked and
variant fibrin, respectively. In addition we measured the modulus (17.6
$+$/- 1.5 MPa) and extensibility (130 $+$/- 10 {\%}) for electrospun
fibrinogen fibers. These studies provide insight into the similarities and
differences between native and electrospun fibrin/fibrinogen fibers as well
as, provide insight in to the role of crosslinking on the mechanical
properties of fibrin fibers.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2013.SES.GB.1