Coronary Artery Disease Clinical Trial
Official title:
Effect of FFRCT-angio in Functional Diagnosis of Coronary Artery Stenosis: a Prospective, Multicenter Clinical Study
Coronary CT angiography (CTA) or invasive coronary angiography (CAG) is usually performed to
evaluate the severity of coronary stenosis depending on the probability of CAD. However, the
stenosis severity is not closely corresponding with the hemodynamic significance in coronary
arteries.
As a result, fractional flow reserve (FFR) with pressure wire measurement was introduced to
functionally assess the coronary stenosis. FFR is defined as the ratio of maximum blood flow
distal to a stenotic lesion under hyperemia state to normal maximum flow in the same vessel.
The cutoff value of FFR to detect significant ischemia is set to be 0.80, indicating that PCI
should be considered if FFR≤0.80. However, FFR does have some limitations, such as risks of
pressure wire injury, extra time and cost, and side effects of hyperemic agents.
To overcome the limitations of FFR, CTA- and CAG-based methods to functionally assess
coronary stenosis were proposed, i.e. FFR derived from CTA (FFRCT) and FFR derived from
angiography-based quantitative flow ratio (QFR), which can simultaneously evaluate anatomic
and hemodynamic significance of stenotic lesions. A number of studies have demonstrated that
FFRCT has high sensitivity and specificity in identifying myocardial ischemia. However, the
diagnostic accuracy of FFRCT depends on the image quality of coronary CTA, and it is
relatively low in lesions with severe calcification and/or tortuosity. Besides, the
methodology of FFRCT relies on computational fluid dynamics, which is complicated and time
consuming. As for QFR, it is a novel method for deriving FFR based on 3-dimensional
quantitative coronary angiography (3D-QCA) and contrast frame counting during CAG. Recent
studies have shown that QFR has good diagnostic performance in evaluating the functional
significance of coronary stenosis. The accuracy of QFR is also highly associated with
anatomic information, thereby its diagnostic accuracy may be decreased in diffuse, tandem,
thrombus-containing, calcified, or torturous lesions, and it is not suitable for prior
infarction-related or collateral donor arteries as well. Given the above issues concerning
FFRCT and QFR, we proposed a novel approach that integrates coronary CTA and CAG images to
calculate FFR (FFRCT-angio) using artificial intelligence. The present study was undertaken
to test the diagnostic accuracy of FFRCT-angio in patients with SCAD.
Cardiovascular disease remains the leading cause of death worldwide, and stable coronary
artery disease (SCAD) accounts for the greatest proportion of cardiovascular disease. In the
past decades, percutaneous coronary intervention (PCI) has become one of the most common
treatments for SCAD, and therefore assessing the hemodynamic significance of coronary
stenosis is important for physicians to make the optimal treating strategy. Coronary CT
angiography (CTA) or invasive coronary angiography (CAG) is usually performed to evaluate the
severity of coronary stenosis depending on the probability of CAD. However, the stenosis
severity is not closely corresponding with the hemodynamic significance in coronary arteries.
As a result, fractional flow reserve (FFR) with pressure wire measurement was introduced to
functionally assess the coronary stenosis. FFR is defined as the ratio of maximum blood flow
distal to a stenotic lesion under hyperemia state to normal maximum flow in the same vessel.
The cutoff value of FFR to detect significant ischemia is set to be 0.80, indicating that PCI
should be considered if FFR≤0.80. FAME (Fractional Flow Reserve versus Angiography for
Multivessel Evaluation) study confirmed that FFR guided PCI was superior to angiography
guided PCI in reducing major adverse cardiovascular events (MACE) in patients with
multivessel disease. In the subsequent FAME 2 study, FFR guided PCI plus the optimal medical
treatment (OMT), as compared with the OMT alone, decreased the composite event rates mainly
driven by urgent revascularization in SCAD patients. However, FFR does have some limitations,
such as risks of pressure wire injury, extra time and cost, and side effects of hyperemic
agents.
To overcome the limitations of FFR, CTA- and CAG-based methods to functionally assess
coronary stenosis were proposed, i.e. FFR derived from CTA (FFRCT) and FFR derived from
angiography-based quantitative flow ratio (QFR), which can simultaneously evaluate anatomic
and hemodynamic significance of stenotic lesions. A number of studies have demonstrated that
FFRCT has high sensitivity and specificity in identifying myocardial ischemia. However, the
diagnostic accuracy of FFRCT depends on the image quality of coronary CTA, and it is
relatively low in lesions with severe calcification and/or tortuosity. Besides, the
methodology of FFRCT relies on computational fluid dynamics, which is complicated and time
consuming. As for QFR, it is a novel method for deriving FFR based on 3-dimensional
quantitative coronary angiography (3D-QCA) and contrast frame counting during CAG. Recent
studies have shown that QFR has good diagnostic performance in evaluating the functional
significance of coronary stenosis. The accuracy of QFR is also highly associated with
anatomic information, thereby its diagnostic accuracy may be decreased in diffuse, tandem,
thrombus-containing, calcified, or torturous lesions, and it is not suitable for prior
infarction-related or collateral donor arteries as well. Given the above issues concerning
FFRCT and QFR, we proposed a novel approach that integrates coronary CTA and CAG images to
calculate FFR (FFRCT-angio) using artificial intelligence. The present study was undertaken
to test the diagnostic accuracy of FFRCT-angio in patients with SCAD.
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