The present research aims to determine the impact of stenoses in downstream vessels on the FFR and iFR measurements of left main coronary artery (LMCA) stenoses of intermediate severity as determined by coronary angiography. Anatomic metrics derived from intravascular imaging modalities of IVUS and optical coherence tomography (OCT) will also be validated using as the comparator the FFRtrue and iFRtrue measurements pf LMCA lesions.
Accurate characterization of the functional significance of intermediate stenoses located in the left main coronary artery (LMCA) is of central relevance for decisions about the need of myocardial revascularization. However, the physiological assessment of such lesions by means of fractional flow reserve (FFR) measurements are affected by stenoses in the downstream vessels (left anterior descending artery and/or left circumflex artery), which frequently coexist in series with LMCA lesions. More recently introduced, the instantaneous wave-free ratio (iFR) is a resting index that is less influenced by crosstalk between serial lesions and, in theory, could be more accurate for assessment of LMCA stenoses in the presence of downstream disease. Nonetheless, iFR has not been validated for assessment of LMCA lesions. Due to the difficulty in interpreting FFR results, the possibility of characterizing the atheroma type, precisely estimate lesion severity and disease extension and distribution, intravascular imaging \[especially intravascular ultrasound (IVUS)\] became an attractive alternative to assess LMCA lesions and guide the percutaneous treatment, whenever this strategy is selected. However, most IVUS validations for LMCA stenosis assessment used FFR as the standard comparator, which by itself has limited diagnostic ability in this anatomic scenario. Thus, the main objective of the current research project is to determine the impact of stenoses in downstream vessels on FFR and iFR measurements of LMCA stenoses of intermediate severity as determined by coronary angiography. The primary endpoint is the change (delta) in FFR and iFR values prior and after percutaneous treatment of downstream stenoses. Assuming a change of 0.04 mmHg between the FFRpredicted and FFRtrue with a standard deviation of 0.04 mmHg, and a change of 0.01 mmHg between iFRpredicted and iFRtrue with a standard deviation of 0.03 mmHg, a total of 53 patients are needed to confirm the mean difference of 0.03 mmHg between iFR and FFR changes before and after treatment of downstream stenoses. Anatomic metrics derived from intravascular imaging modalities of IVUS and optical coherence tomography (OCT) will also be validated using as the comparator the FFRtrue and iFRtrue measurements.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
DIAGNOSTIC
Masking
NONE
Enrollment
53
intermediate lesion evaluation with intracoronary physiology and imaging
Instituto Dante Pazzanese de Cardiologia
São Paulo, Brazil
RECRUITINGChange of iFR and FFR values of the LMS stenosis before and after PCI of the significant downstream stenosis
determine the change of iFR and FFR values of the LMS stenosis before and after PCI of the significant downstream stenosis (iFRtrue - iFRpred and FFRtrue - FFRpred)
Time frame: diagnostic procedure
Accuracy of intravascular imaging in predicting functionally signifcant LMS stenosis
establish the diagnostic accuracy of the minimum lumen areas determined by IVUS and OCT in the LMS in comparison with the iFRtrue and FFRtrue)
Time frame: diagnostic procedure
Accuracy of pressure changes in the iFR and FFR pullback curves before PCI of the downstream lesion in predicting the functional significance of LMS stenosis
Establish the accuracy of pressure changes in the iFR and FFR pullback curves before PCI of the downstream lesion to predict the iFRtue and FFRtrue observed after PCI of the downstream lesion;
Time frame: diagnostic procedure
Accuracy of iFRpred-contra and FFRpred-contra before PCI of the downstream lesion in predicting the functional significance of LMS stenosis
Establish the ability of iFRpred-contra and FFRpred-contra before PCI of the downstream lesion in predict the iFRtrue and FFRtrue of the LMS stenosis;
Time frame: diagnostic procedure
Agreement of the iFRcontra and FFRcontra after PCI of the downstream stenosis with the iFRtrue and FFRtrue.
Verify the agreement of the iFRcontra and FFRcontra after PCI of the downstream stenosis with the iFRtrue and FFRtrue.
Time frame: diagnostic procedure
Accuracy of minimum lumen area determined by IVUS and OCT in the LMS to predict the functional significance of LMS stenosis
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Diagnostic accuracy of the minimum lumen area in the LMS by IVUS and OCT to predict iFRtrue and FFRtrue of the LMS stenosis
Time frame: diagnostic procedure
Accuracy of minimum lumen diameter determined by IVUS and OCT in the LMS to predict the functional significance of LMS stenosis
Diagnostic accuracy of the minimum lumen diameter in the LMS by IVUS and OCT to predict iFRtrue and FFRtrue of the LMS stenosis
Time frame: diagnostic procedure
Accuracy of percent diameter stenosis determined by IVUS and OCT in the LMS to predict the functional significance of LMS stenosis
Diagnostic accuracy of the percent diameter stenosis in the LMS by IVUS and OCT to predict iFRtrue and FFRtrue of the LMS stenosis
Time frame: diagnostic procedure
Accuracy of percent area stenosis determined by IVUS and OCT in the LMS to predict the functional significance of LMS stenosis
Diagnostic accuracy of the percent area stenosis in the LMS by IVUS and OCT to predict iFRtrue and FFRtrue of the LMS stenosis
Time frame: diagnostic procedure
Accuracy of lesion length determined by IVUS and OCT in the LMS to predict the functional significance of LMS stenosis
Diagnostic accuracy of lesion length in the LMS by IVUS and OCT to predict iFRtrue and FFRtrue of the LMS stenosis
Time frame: diagnostic procedure