Nanoindentation of histological specimens using an extension of the Oliver and Pharr method

Research output: Chapter in Book/Report/Conference proceedingConference contribution

  • External authors:
  • Riaz Akhtar
  • Nick Bierwisch
  • Norbert Schwarzer

Abstract

The micro-mechanical properties of 5 μm thick histological sections of ferret aorta and vena cava were mapped as a function of distance from the outer adventitial layer using nanoindentation. In order to decouple the effect of the glass substrate on the elastic modulus of these thin sections, the nanoindentation data were analyzed using the extended Oliver and Pharr method which is readily accessible for coatings and layered materials with the software package, FilmDoctor®. In the aorta, the elastic modulus was found to decrease progressively from 35 MPa at the adventitia (outermost layer) to 8 MPa at the intima (innermost layer). This decrease in modulus was inversely correlated with elastic fibre density. In contrast, in the vena cava, the stiffest regions were found to be the adventitial (outer) and intimai (innermost) sections of the vessel cross-section. Both these regions were enriched in ECM components. The central region, thought to be largely cellular, had a relatively constant modulus of around 20 MPa. This study demonstrates that with this methodology it is possible to distinguish micro-mechanically between large arteries and veins, and therefore the same approach should allow age or disease related changes in the mechanical properties within a tissue to be quantified. © 2008 Materials Research Society.

Bibliographical metadata

Original languageEnglish
Title of host publicationMaterials Research Society Symposium Proceedings|Mater Res Soc Symp Proc
PublisherMaterials Research Society
Pages33-38
Number of pages5
Volume1097
ISBN (Print)9781605608525
Publication statusPublished - 2008
Event2008 MRS Spring Meeting - San Francisco, CA, United States
Event duration: 24 Mar 200828 Mar 2008

Conference

Conference2008 MRS Spring Meeting
CountryUnited States
CitySan Francisco, CA
Period24/03/0828/03/08