Abstract
Atherosclerotic plaque progression and rupture play an important role in cardiovascular disease development and the final drastic events such as heart attack and stroke. Medical imaging and image-based computational modeling methods advanced considerably in recent years to quantify plaque morphology and biomechanical conditions and gain a better understanding of plaque evolution and rupture process. This article first briefly reviewed clinical imaging techniques for coronary thin-cap fibroatheroma (TCFA) plaques used in image-based computational modeling. This was followed by a summary of different types of biomechanical models for coronary plaques. Plaque progression and vulnerability prediction studies based on image-based computational modeling were reviewed and compared. Much progress has been made and a reasonable high prediction accuracy has been achieved. However, there are still some inconsistencies in existing literature on the impact of biomechanical and morphological factors on future plaque behavior, and it is very difficult to perform direct comparison analysis as differences like image modality, biomechanical factors selection, predictive models, and progression/vulnerability measures exist among these studies. Encouraging data and model sharing across the research community would partially resolve these differences, and possibly lead to clearer assertive conclusions. In vivo image-based computational modeling could be used as a powerful tool for quantitative assessment of coronary plaque vulnerability for potential clinical applications.
Highlights
Background and clinical current statusCoronary artery disease (CAD, or ischemic heart disease) is a leading cause of death and disability, killing 9.14 million people in 2019 glob ally [1]
The goal of this paper is to review the recent advances in medical imaging, computational modeling and their applications in plaque progression and vulnerability predictions to guide further effort in this critical area
We focus more on high-risk plaque with thin cap infiltrated by macrophages covering a large lipid necrotic core, termed as thin-cap fibroatheroma (TCFA)
Summary
Coronary artery disease (CAD, or ischemic heart disease) is a leading cause of death and disability, killing 9.14 million people in 2019 glob ally [1]. Using optical coherence tomography (OCT) scanning, Araki et al showed that lipid-rich plaques, TCFA, and layered plaques were predictors of subsequent rapid plaque progression [11] These large cohort clinical studies have demonstrated that in vivo imaging technologies could provide accurate detection of plaque morphology for investigations of plaque development and clinical events. International Journal of Cardiology 352 (2022) 1–8 biomechanical conditions in the coronary plaque, which could provide valuable complementary information to morphological characteristics on plaque development It remains to be a grand challenge to accurately predict future plaque behaviors (quantitatively in native coronary ar teries).
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