Deformation of the Femoropopliteal Segment

Abstract

Purpose: To quantify the deformation behavior of the diseased femoropopliteal segment and assess the change to deformation behavior due to various stent placements. Methods: The length and curvature changes of 6 femoropopliteal segments (the right and left superficial femoral and popliteal arteries) from 3 cadavers were measured in 3-dimensional space based on rotational angiography image data in straight leg and flexed hip/knee (50°/90°) positions before and after placement of nitinol stents of varying type (EverFlex, Misago, and BioMimics 3D) and length (60, 100, and 200 mm) in different locations along the arteries. Three-dimensional centerline data were extracted for the measurements. Results: All 6 femoropopliteal cadaver segments displayed signs of peripheral artery disease. Hip/knee flexion resulted in vessel shortening and increases in the mean and maximum vessel curvatures in all cases. Location-specific results of the unstented arteries showed that magnitudes of vessel length and curvature change vary as a function of vessel length. The average shortening of the entire femoropopliteal segment due to flexion was observed at 10.7%±0.7%, which was reduced to 8.1%±0.9% after stent deployment. Average and maximum curvatures of the unstented segment increased due to flexion (average: 0.008±0.002 mm⁻¹ to 0.019±0.006 mm⁻¹, maximum: 0.030±0.009 mm⁻¹ to 0.091±0.045 mm⁻¹). After stent deployment, average and maximum curvatures of the flexed stented segments increased compared with the flexed unstented segments (average: 0.019±0.006 mm⁻¹ to 0.022±0.004 mm⁻¹, maximum: 0.091±0.045 mm⁻¹ to 0.103±0.025 mm⁻¹). The most flexurally stiff stent demonstrated the least ability to axially shorten during flexion of the leg at the knee joint. Conclusion: The deformation characteristics of the femoropopliteal segment change in the presence of a stent, with the change to the deformation behavior dependent on stent type, stent length, location, flexibility, and intrinsic centerline curvature.

Keywords

biomechanics cadaver curvature femoropopliteal segment nitinol stent peripheral artery disease popliteal artery rotational angiography superficial femoral artery vascular deformation

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References

Jonker

Schlosser

Moll

Muhs

. Dynamic forces in the SFA and popliteal artery during knee flexion. Endovascular Today. 2008;May:53–58.

Ansari

Pack

Brooks

. Design considerations for studies of the biomechanical environment of the femoropopliteal arteries. J Vasc Surg. 2013;58:804–813.

Werner

. Factors affecting reduction in SFA stent fracture rates. Endovascular Today. 2014;October:93–95.

Scheinert

Sax

. Prevalence and clinical impact of stent fractures after femoropopliteal stenting. J Am Coll Cardiol. 2005;45:312–315.

Smouse

Nikanorov

LaFlash

. Biomechanical forces in the femoropopliteal arterial segment. Endovascular Today. 2005;June:60–66.

Arena

. Arterial kink and damage in normal segments of the superficial femoral and popliteal arteries abutting nitinol stents—a common cause of late occlusion and restenosis? A single-center experience. J Invasive Cardiol. 2005;17:482–486.

Ní Ghriallais

Bruzzi

. A computational analysis of the deformation of the femoropopliteal artery with stenting. J Biomech Eng. 2014;136:071003.

Scheinert

Grummt

Piorkowski

. A novel self-expanding interwoven nitinol stent for complex femoropopliteal lesions: 24-month results of the SUPERA SFA registry. J Endovasc Ther. 2011;18:745–752.

O’Flynn

O’Sullivan

Pandit

. Methods for three-dimensional geometric characterization of the arterial vasculature. Ann Biomed Eng. 2007;35:1368–1381.

10.

Choi

Cheng

Wilson

. Methods for quantifying three-dimensional deformation of arteries due to pulsatile and nonpulsatile forces: implications for the design of stents and stent grafts. Ann Biomed Eng. 2009;37:14–33.

11.

Cheng

Choi

Herfkens

. The effect of aging on deformations of the superficial femoral artery resulting from hip and knee flexion: potential clinical implications. J Vasc Interv Radiol. 2010;21:195–202.

12.

Nikanorov

Schillinger

Zhao

. Assessment of self-expanding nitinol stent deformation after chronic implantation into the femoropopliteal arteries. EuroIntervention. 2013;9:730–737.

13.

MacTaggart

Phillips

Lomneth

. Three-dimensional bending, torsion and axial compression of the femoropopliteal artery during limb flexion. J Biomech. 2014;47:2249–2256.

14.

Klein

James

Chen S

Messenger

. Quantitative assessment of the conformational change in the femoropopliteal artery with leg movement. Catheter Cardiovasc Interv. 2009;74:787–798.

15.

Ganguly

Simons

Schneider

. In-vivo imaging of femoral artery nitinol stents for deformation analysis. J Vasc Interv Radiol. 2011;22:244–249.

16.

Kamenskiy

Pipinos

Dzenis

. Passive biaxial mechanical properties and in vivo axial pre-stretch of the diseased human femoropopliteal and tibial arteries. Acta Biomater. 2014;10:1301–1313.

17.

Nikanorov

Smouse

Osman

. Fracture of self-expanding nitinol stents stressed in vitro under simulated intravascular conditions. J Vasc Surg. 2008;48:435–440.

18.

Cheng

Wilson

Hallett

. In vivo MR angiographic quantification of axial and twisting deformations of the superficial femoral artery resulting from maximum hip and knee flexion. J Vasc Interv Radiol. 2006;17:979–987.

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