Finding the ideal biomaterial for aortic valve repair with ex vivo porcine left heart simulator and finite element modeling

Toeg, Hadi Daood;Abessi, Ovais;Al-Atassi, Talal;de Kerchove, Laurent;Boodhwani, Munir;et.al.
(2014) The Journal of Thoracic and Cardiovascular Surgery — Vol. 148, n° 4, p. 1739-1745 (2014)

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Authors
  • Toeg, Hadi Daood
    Author
  • Abessi, Ovais
    Author
  • Al-Atassi, Talal
    Author
  • de Kerchove, LaurentUCLouvain
    Author
  • El Khoury, GebrineUCLouvain
    Author
  • Boodhwani, Munir
    Author
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Abstract
OBJECTIVES: Aortic valve (AV) repair (AVr) has become an attractive alternative to AV replacement for the correction of aortic insufficiency; however, little clinical evidence exists in determining which biomaterial at AVr would be optimal. Cusp replacement in AVr has been associated with increased long-term AVr failure. We measured the hemodynamic and biomaterial properties using an ex vivo porcine AVr model with clinically relevant biomaterials and generated a finite element model to ascertain which materials would be best suited for valve repair. METHODS: Porcine aortic roots with intact AVs were placed in a left heart simulator mounted with a high-speed camera for baseline valve assessment. The noncoronary cusp was excised and replaced with autologous porcine pericardium, glutaraldehyde-fixed bovine pericardial patch (Synovis), extracelluar matrix scaffold (CorMatrix), or collagen-impregnated Dacron (Hemashield). The hemodynamic parameters were measured for a range of cardiac outputs (2.5-6.5 L/min) after repair. The biomaterial properties and St Jude Medical pericardial patch were determined using pressurization experiments. Finite element models of the AV and root complex were constructed to determine the hemodynamic characteristics and leaflet stresses. RESULTS: The geometric orifice areas after repair were significantly reduced in the Hemashield (P<.05) and CorMatrix (P=.0001) groups. Left ventricular work increased with increasing cardiac output (P=.001) in unrepaired valves, as expected, and was similar among all biomaterial groups. Finite element modeling of the biomaterials displayed differences in the percentage of changes in total Von Mises stress for both replaced (noncoronary cusp) and nonreplaced left and right cusps with the St Jude Medical pericardial patch (+4%, +24%) and autologous porcine pericardium (+5, +26%), with a lower percentage of changes than for the bovine pericardial patch (+12%, +27%), Hemashield (+30%, +9%), and CorMatrix (+13%, +32%). Conclusions: The present study has shown that postrepair left ventricular work did not increase despite a decrease in geometric orifice areas in the Hemashield and CorMatrix groups. The autologous porcine pericardium and St Jude Medical pericardial patch had the closest profile to normal AVs; therefore, either biomaterial might be best suited. Finally, the increased stresses found in the bovine pericardial patch, Hemashield, and CorMatrix groups might, after prolonged tensile exposure, be associated with late repair failure.
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Toeg, H. D., Abessi, O., Al-Atassi, T., de Kerchove, L., El Khoury, G., Labrosse, M., & Boodhwani, M. (2014). Finding the ideal biomaterial for aortic valve repair with ex vivo porcine left heart simulator and finite element modeling. The Journal of Thoracic and Cardiovascular Surgery, 148(4), 1739-1745. https://doi.org/10.1016/j.jtcvs.2014.05.004 (Original work published 2014)