1. Date of download: 3/3/2018
Copyright © ASME. All rights reserved.
From: Compliance and Longitudinal Strain of Cardiovascular Stents: Influence of Cell Geometry
J. Med. Devices. 2011;5(4): doi: /
Figure Legend:
A schematic of Hybrid geometry combining a regular hexagon (left) with an auxetic, re-entrant hexagon (middle) to give a hybrid geometry (right) of zero effective Poisson’s ratio

2. Date of download: 3/3/2018
Copyright © ASME. All rights reserved.
From: Compliance and Longitudinal Strain of Cardiovascular Stents: Influence of Cell Geometry
J. Med. Devices. 2011;5(4): doi: /
Figure Legend:
Stent cell geometries considered in this study

3. Date of download: 3/3/2018
Copyright © ASME. All rights reserved.
From: Compliance and Longitudinal Strain of Cardiovascular Stents: Influence of Cell Geometry
J. Med. Devices. 2011;5(4): doi: /
Figure Legend:
Summary of the mean radial compliance for various cell geometries

4. Date of download: 3/3/2018
Copyright © ASME. All rights reserved.
From: Compliance and Longitudinal Strain of Cardiovascular Stents: Influence of Cell Geometry
J. Med. Devices. 2011;5(4): doi: /
Figure Legend:
Summary of longitudinal strain for various cell geometries

5. Date of download: 3/3/2018
Copyright © ASME. All rights reserved.
From: Compliance and Longitudinal Strain of Cardiovascular Stents: Influence of Cell Geometry
J. Med. Devices. 2011;5(4): doi: /
Figure Legend:
Effect of cell geometry on foreshortening: (a) Diamond stent before expansion, (b) Hybrid C stent before expansion, (c) Diamond stent after expansion and (d) Hybrid C stent after expansion. Notice the negligible foreshortening for Hybrid C design.