TY - JOUR
T1 - A patient-specific study investigating the relation between coronary hemodynamics and neo-intimal thickening after bifurcation stenting with a polymeric bioresorbable scaffold
AU - Migliori, Susanna
AU - Rampat, Rajiv
AU - Bologna, Marco
AU - Montin, Eros
AU - Burzotta, Francesco
AU - Hildick-Smith, David
AU - Dubini, Gabriele
AU - Mainardi, Luca
AU - Migliavacca, Francesco
AU - Cockburn, James
AU - Chiastra, Claudio
PY - 2018
Y1 - 2018
N2 - We present an application of a validated reconstruction methodology for the comparison between patient-specific hemodynamics and neo-intimal thickening at nine months from the intervention. (1) Background: Coronary bifurcation stenting alters the vessel geometry, influencing the local hemodynamics. The evaluation of wall shear stress (WSS) relies on the application of computational fluid dynamics to model its distribution along the coronary tree. The endothelium actively responds to WSS, which triggers eventual cell proliferation to cover the stent struts. (2) Methods: Baseline optical coherence tomography and angiographic data were combined to reconstruct a patient-specific coronary bifurcation with an implanted bioresorbable scaffold and to simulate the hemodynamics. Results were linked with the neo-intimal thickening after nine months from the intervention. (3) Results: Blood velocity patterns were disrupted at the bifurcation due to the presence of the stent. It was observed that 55.6% of the scaffolded lumen surface was exposed to values of time-averaged WSS lower than 0.4 Pa. Follow-up images showed a luminal narrowing of 19% in the main branch. There was also a complete coverage in 99% of struts. (4) Conclusions: This approach provided valuable complementary information that might improve the clinical outcomes in this subset of coronary diseases.
AB - We present an application of a validated reconstruction methodology for the comparison between patient-specific hemodynamics and neo-intimal thickening at nine months from the intervention. (1) Background: Coronary bifurcation stenting alters the vessel geometry, influencing the local hemodynamics. The evaluation of wall shear stress (WSS) relies on the application of computational fluid dynamics to model its distribution along the coronary tree. The endothelium actively responds to WSS, which triggers eventual cell proliferation to cover the stent struts. (2) Methods: Baseline optical coherence tomography and angiographic data were combined to reconstruct a patient-specific coronary bifurcation with an implanted bioresorbable scaffold and to simulate the hemodynamics. Results were linked with the neo-intimal thickening after nine months from the intervention. (3) Results: Blood velocity patterns were disrupted at the bifurcation due to the presence of the stent. It was observed that 55.6% of the scaffolded lumen surface was exposed to values of time-averaged WSS lower than 0.4 Pa. Follow-up images showed a luminal narrowing of 19% in the main branch. There was also a complete coverage in 99% of struts. (4) Conclusions: This approach provided valuable complementary information that might improve the clinical outcomes in this subset of coronary diseases.
KW - Bioresorbable scaffold
KW - Computational fluid dynamics
KW - Coronary artery bifurcation
KW - Image segmentation
KW - Neo-intimal coverage
KW - Optical coherence tomography
KW - Patient-specific computer modeling
KW - Stent
KW - Three-dimensional reconstruction
KW - Wall shear stress
KW - Bioresorbable scaffold
KW - Computational fluid dynamics
KW - Coronary artery bifurcation
KW - Image segmentation
KW - Neo-intimal coverage
KW - Optical coherence tomography
KW - Patient-specific computer modeling
KW - Stent
KW - Three-dimensional reconstruction
KW - Wall shear stress
UR - http://hdl.handle.net/10807/170952
U2 - 10.3390/app8091510
DO - 10.3390/app8091510
M3 - Article
SN - 2076-3417
VL - 8
SP - 1510-N/A
JO - APPLIED SCIENCES
JF - APPLIED SCIENCES
ER -