TY - JOUR
T1 - Non-invasive physiological assessment of intermediate coronary stenoses from plain angiography through artificial intelligence: the STARFLOW system
AU - De Filippo, Ovidio
AU - Mineo, Raffaele
AU - Millesimo, Michele
AU - Wańha, Wojciech
AU - Proietto Salanitri, Federica
AU - Greco, Antonio
AU - Leone, Antonio Maria
AU - Franchin, Luca
AU - Palazzo, Simone
AU - Quadri, Giorgio
AU - Tuttolomondo, Domenico
AU - Fabris, Enrico
AU - Campo, Gianluca
AU - Giachet, Alessandra Truffa
AU - Bruno, Francesco
AU - Iannaccone, Mario
AU - Boccuzzi, Giacomo
AU - Gaibazzi, Nicola
AU - Varbella, Ferdinando
AU - Wojakowski, Wojciech
AU - Maremmani, Michele
AU - Gallone, Guglielmo
AU - Sinagra, Gianfranco
AU - Capodanno, Davide
AU - Musumeci, Giuseppe
AU - Boretto, Paolo
AU - Pawlus, Pawel
AU - Saglietto, Andrea
AU - Burzotta, Francesco
AU - Aldinucci, Marco
AU - Giordano, Daniela
AU - De Ferrari, Gaetano Maria
AU - Spampinato, Concetto
AU - D'Ascenzo, Fabrizio
PY - 2024
Y1 - 2024
N2 - Background Despite evidence supporting use of fractional flow reserve (FFR) and instantaneous waves-free ratio (iFR) to improve outcome of patients undergoing coronary angiography (CA) and percutaneous coronary intervention, such techniques are still underused in clinical practice due to economic and logistic issues.Objectives We aimed to develop an artificial intelligence (AI)-based application to compute FFR and iFR from plain CA.Methods and results Consecutive patients performing FFR or iFR or both were enrolled. A specific multi-task deep network exploiting 2 projections of the coronary of interest from standard CA was appraised. Accuracy of prediction of FFR/iFR of the AI model was the primary endpoint, along with sensitivity and specificity. Prediction was tested both for continuous values and for dichotomous classification (positive/negative) for FFR or iFR. Subgroup analyses were performed for FFR and iFR. A total of 389 patients from 5 centers were enrolled. Mean age was 67.9 +/- 9.6 and 39.2% of patients were admitted for acute coronary syndrome. Overall, the accuracy was 87.3% (81.2-93.4%), with a sensitivity of 82.4% (71.9-96.4%) and a specificity of 92.2% (90.4-93.9%). For FFR, accuracy was 84.8% (77.8-91.8%), with a sensitivity of 81.9% (69.4-94.4%) and a specificity of 87.7% (85.5-89.9%), while for iFR accuracy was 90.2% (86.0-94.6%), with a sensitivity of 87.2% (76.6-97.8%) and a specificity of 93.2% (91.7-94.7%, all confidence intervals 95%).Methods and results Consecutive patients performing FFR or iFR or both were enrolled. A specific multi-task deep network exploiting 2 projections of the coronary of interest from standard CA was appraised. Accuracy of prediction of FFR/iFR of the AI model was the primary endpoint, along with sensitivity and specificity. Prediction was tested both for continuous values and for dichotomous classification (positive/negative) for FFR or iFR. Subgroup analyses were performed for FFR and iFR. A total of 389 patients from 5 centers were enrolled. Mean age was 67.9 +/- 9.6 and 39.2% of patients were admitted for acute coronary syndrome. Overall, the accuracy was 87.3% (81.2-93.4%), with a sensitivity of 82.4% (71.9-96.4%) and a specificity of 92.2% (90.4-93.9%). For FFR, accuracy was 84.8% (77.8-91.8%), with a sensitivity of 81.9% (69.4-94.4%) and a specificity of 87.7% (85.5-89.9%), while for iFR accuracy was 90.2% (86.0-94.6%), with a sensitivity of 87.2% (76.6-97.8%) and a specificity of 93.2% (91.7-94.7%, all confidence intervals 95%).Conclusion The presented machine-learning based tool showed high accuracy in prediction of wire-based FFR and iFR.Graphical Abstract
AB - Background Despite evidence supporting use of fractional flow reserve (FFR) and instantaneous waves-free ratio (iFR) to improve outcome of patients undergoing coronary angiography (CA) and percutaneous coronary intervention, such techniques are still underused in clinical practice due to economic and logistic issues.Objectives We aimed to develop an artificial intelligence (AI)-based application to compute FFR and iFR from plain CA.Methods and results Consecutive patients performing FFR or iFR or both were enrolled. A specific multi-task deep network exploiting 2 projections of the coronary of interest from standard CA was appraised. Accuracy of prediction of FFR/iFR of the AI model was the primary endpoint, along with sensitivity and specificity. Prediction was tested both for continuous values and for dichotomous classification (positive/negative) for FFR or iFR. Subgroup analyses were performed for FFR and iFR. A total of 389 patients from 5 centers were enrolled. Mean age was 67.9 +/- 9.6 and 39.2% of patients were admitted for acute coronary syndrome. Overall, the accuracy was 87.3% (81.2-93.4%), with a sensitivity of 82.4% (71.9-96.4%) and a specificity of 92.2% (90.4-93.9%). For FFR, accuracy was 84.8% (77.8-91.8%), with a sensitivity of 81.9% (69.4-94.4%) and a specificity of 87.7% (85.5-89.9%), while for iFR accuracy was 90.2% (86.0-94.6%), with a sensitivity of 87.2% (76.6-97.8%) and a specificity of 93.2% (91.7-94.7%, all confidence intervals 95%).Methods and results Consecutive patients performing FFR or iFR or both were enrolled. A specific multi-task deep network exploiting 2 projections of the coronary of interest from standard CA was appraised. Accuracy of prediction of FFR/iFR of the AI model was the primary endpoint, along with sensitivity and specificity. Prediction was tested both for continuous values and for dichotomous classification (positive/negative) for FFR or iFR. Subgroup analyses were performed for FFR and iFR. A total of 389 patients from 5 centers were enrolled. Mean age was 67.9 +/- 9.6 and 39.2% of patients were admitted for acute coronary syndrome. Overall, the accuracy was 87.3% (81.2-93.4%), with a sensitivity of 82.4% (71.9-96.4%) and a specificity of 92.2% (90.4-93.9%). For FFR, accuracy was 84.8% (77.8-91.8%), with a sensitivity of 81.9% (69.4-94.4%) and a specificity of 87.7% (85.5-89.9%), while for iFR accuracy was 90.2% (86.0-94.6%), with a sensitivity of 87.2% (76.6-97.8%) and a specificity of 93.2% (91.7-94.7%, all confidence intervals 95%).Conclusion The presented machine-learning based tool showed high accuracy in prediction of wire-based FFR and iFR.Graphical Abstract
KW - Artificial intelligence
KW - Coronary physiology
KW - Percutaneous coronary intervention
KW - Instantaneous waves-free ratio
KW - Fractional flow reserve
KW - Artificial intelligence
KW - Coronary physiology
KW - Percutaneous coronary intervention
KW - Instantaneous waves-free ratio
KW - Fractional flow reserve
UR - http://hdl.handle.net/10807/296076
U2 - 10.1093/ehjqcco/qcae024
DO - 10.1093/ehjqcco/qcae024
M3 - Article
SN - 2058-1742
SP - N/A-N/A
JO - EUROPEAN HEART JOURNAL. QUALITY OF CARE & CLINICAL OUTCOMES (ONLINE)
JF - EUROPEAN HEART JOURNAL. QUALITY OF CARE & CLINICAL OUTCOMES (ONLINE)
ER -