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Radial Wall Strain Assessment From AI-Assisted Angiography: Feasibility and Agreement With OCT as Reference Standard

Jiayue Huang, Shengxian Tu, Chunming Li, Huihong Hong, Zhiqing Wang, Lianglong Chen, Juan Luis Gutiérrez‐Chico, William Wijns

2022Journal of the Society for Cardiovascular Angiography & Interventions13 citationsDOIOpen Access PDF

Abstract

Background High-strain spots in coronary arteries are associated with plaque vulnerability and predict future events. Artificial intelligence currently enables the calculation of radial wall strain (RWS) from coronary angiography (RWS Angio ). This study aimed to determine the agreement between novel RWS Angio and RWS derived from optical coherence tomography (OCT) followed by finite element analysis, as the established reference standard (RWS OCT ). Methods All lesions from a previous OCT study were enrolled. OCT was automatically coregistered with angiography. RWS Angio was computed as the relative luminal deformation throughout the cardiac cycle, whereas RWS OCT was analyzed using finite element analysis on OCT cross-sections at 1-mm intervals. The luminal deformation in the direction of minimal lumen diameter was used to derive RWS OCT , using the same definition as RWS Angio . The maximal RWS OCT and RWS Angio at healthy segments adjacent to the interrogated lesion were also analyzed. Results Finite element analysis was performed in 578 OCT cross-sections from 45 lesions stemming from 36 patients. RWS Angio showed good correlation and agreement with RWS OCT ( r = 0.91; P < .001; Lin coefficient=0.85). RWS Angio in atherosclerotic segments was significantly higher than that in healthy segments (12.6% [11.0, 16.0] vs 4.5% [2.9, 5.5], P < .001). The intraclass correlation coefficients for intra- and interobserver variability in repeated RWS Angio analysis were 0.92 (95% CI, 0.87-0.95) and 0.88 (95% CI, 0.81-0.92), respectively. The mean analysis time of RWS OCT and RWS Angio for each lesion was 95.0 ± 41.1 and 0.9 ± 0.1 minutes, respectively. Conclusions Radial wall strain from coronary angiography can be rapidly and easily computed solely from angiography, showing excellent agreement with strain derived from coregistered OCT. This novel and simple method might provide a cost-effective biomechanical assessment in large populations.

Topics & Concepts

Coronary angiographyStrain (injury)AngiographyVulnerability (computing)Radial stressMedicineRadiologyCardiologyInternal medicineMaterials scienceComputer scienceComputer securityComposite materialDeformation (meteorology)Myocardial infarctionCoronary Interventions and DiagnosticsCardiac Imaging and DiagnosticsAcute Myocardial Infarction Research