Fractional flow reserve computed tomography for predicting the effect of coronary artery bypass grafting_Chinese Journal of Clinical Thoracic and Cardiovascular Surgery

Authors：

HUANG Qiuyue ,  LIANG Lin , CHI Liqun , ZHANG Yuxiao , ZHAO Guangxin , LIU Jiaji , MA Xiaolong

Minimally Invasive Cardiac Surgery Center, Beijing Anzhen Hospital, Capital Medical University, Beijing, 100020, P. R. China;

Corresponding?author：

LIANG Lin, Email: LL7616@126.com

Keywords：

Coronary artery bypass grafting; fractional flow reserve computed tomography; intraoperative transit-time flow; coronary angiography

DOI：

10.7507/1007-4848.202601099

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

Objective To compare the surgical outcomes between conventional coronary artery bypass grafting (CABG) and minimally invasive direct coronary artery bypass grafting via left small thoracotomy stratified by different levels of non-invasive fractional flow reserve computed tomography (FFR-CT), and to explore the recommended FFR-CT cut-off values for selecting appropriate coronary vessels for grafting in the two surgical procedures. Methods A retrospective enrollment was conducted on patients who underwent isolated CABG at the Minimally Invasive Cardiac Surgery Center of Beijing Anzhen Hospital from 2022 to 2025, including conventional median sternotomy CABG and minimally invasive CABG. Clinical data comprising preoperative FFR-CT of target vessels, preoperative coronary angiography, intraoperative instantaneous flow of corresponding bypass grafts, peak postoperative troponin level, postoperative graft patency after discharge, and the incidence of major adverse cardiovascular and cerebrovascular event (MACCE) were collected. Patients were divided into two groups according to FFR-CT value: FFR-CT＞0.80 and FFR-CT≤0.80. Intraoperative graft flow was classified into three grades: Grade 1 (flow≤30 mL/min), Grade 2 (30 mL/min＜flow≤60 mL/min), and Grade 3 (flow＞60 mL/min). The differences in intraoperative flow corresponding to different FFR-CT levels were compared between patients undergoing conventional CABG and minimally invasive CABG respectively, and regression analyses were performed separately. Postoperative troponin was also graded into three levels: Grade 1 (troponin I＜2 000 ng/L), Grade 2 (2 000 ng/L≤troponin I＜5 000 ng/L), and Grade 3 (troponin I≥5 000 ng/L). Troponin I levels were compared between the two groups. Results A total of 390 patients with 928 target vessels were enrolled, including 207 patients undergoing conventional CABG (542 target vessels; 153 males and 54 females, aged 43-81 years) and 183 patients undergoing minimally invasive CABG (386 target vessels; 144 males and 39 females, aged 46-84 years). For conventional CABG, target vessels with FFR-CT≤0.80 presented better intraoperative graft flow. The regression equation was Q (flow grade)=–3.077FFR³+3.455. FFR-CT＜0.78 was recommended to achieve optimal intraoperative graft flow. For minimally invasive CABG, superior intraoperative graft flow was also observed in target vessels with FFR-CT≤0.80, with the regression equation Q (flow grade)=–24.560FFR²+30.207FFR–6.492, and the recommended cut-off value was FFR-CT＜0.80. For coronary arteries with angiographically moderate stenosis, intraoperative graft flow differed significantly among different FFR-CT subgroups (P＜0.001), with higher flow in the FFR-CT≤0.80 group. Moreover, lower FFR-CT value of target vessels was associated with lower peak postoperative troponin I level. Conclusion FFR-CT serves as a reliable reference indicator for target vessel selection in conventional CABG and left small thoracotomy minimally invasive CABG, especially for coronary lesions with angiographically moderate stenosis. In addition, FFR-CT has certain predictive value for postoperative surgical efficacy.

1.	Knuuti J, Wijns W, Saraste A, et al. 2019 ESC guidelines for the diagnosis and management of chronic coronary syndromes. Eur Heart J, 2020, 41(3): 407-477.
2.	Erne P, Schoenenberger AW, Burckhardt D, et al. Effects of percutaneous coronary interventions in silent ischemia after myocardial infarction: the SWISSIⅡ randomized controlled trial. JAMA, 2007, 297(18): 1985-1991.
3.	Radaideh Q, Osman M, Kheiri B, et al. Meta-analysis of the effect of percutaneous coronary intervention on death and myocardial infarction in patients with stable coronary artery disease and inducible myocardial ischemia. Am J Cardiol, 2020, 133: 171-174.
4.	Pijls NH, van Schaardenburgh P, Manoharan G, et al. Percutaneous coronary intervention of functionally nonsignificant stenosis: 5-year follow-up of the DEFER study. J Am Coll Cardiol, 2007, 49(21): 2105-2111.
5.	Williams C, Brown DL. Effect of random deferral of percutaneous coronary intervention in patients with diabetes and stable ischaemic heart disease. Heart, 2020, 106(21): 1651-1657.
6.	Pellicano M, De Bruyne B, Toth GG, et al. Fractional flow reserve to guide and to assess coronary artery bypass grafting. Eur Heart J, 2017, 38(25): 1959-1968.
7.	Rioufol G, Dérimay F, Roubille F, et al. Fractional flow reserve to guide treatment of patients with multivessel coronary artery disease. J Am Coll Cardiol, 2021, 78(19): 1875-1885.
8.	Jolly SS, Amlani S, Hamon M, et al. Radial versus femoral access for coronary angiography or intervention and the impact on major bleeding and ischemic events: a systematic review and meta-analysis of randomized trials. Am Heart J, 2009, 157(1): 132-140.
9.	Niu D, Gao Q, Ren B, et al. The safety and efficacy of non-emergent percutaneous coronary intervention via distal radial artery access in patients with acute coronary syndrome. Front Cardiovasc Med, 2025, 12: 1696742.
10.	Zhuang B, Wang S, Zhao S, Lu M. Computed tomography angiography-derived fractional flow reserve (CT-FFR) for the detection of myocardial ischemia with invasive fractional flow reserve as reference: systematic review and meta-analysis. Eur Radiol, 2020, 30(2): 712-725.
11.	Taylor CA, Fonte TA, Min JK. Computational fluid dynamics applied to cardiac computed tomography for noninvasive quantification of fractional flow reserve: scientific basis. J Am Coll Cardiol, 2013, 61(22): 2233-2241.
12.	Khav N, Ihdayhid AR, Ko B. CT-derived fractional flow reserve (CT-FFR) in the evaluation of coronary artery disease. Heart Lung Circ, 2020, 29(11): 1621-1632.
13.	Kim MY, Yang DH, Choo KS, Lee W. Beyond coronary ct angiography: CT fractional flow reserve and perfusion. Taehan Yongsang Uihakhoe Chi, 2022, 83(1): 3-27.
14.	De Bruyne B, Pijls NH, Bartunek J, et al. Fractional flow reserve in patients with prior myocardial infarction. Circulation, 2001, 104(2): 157-162.
15.	Ghaemian A, Yazdani J, Farsavian AA, et al. Fractional flow reserve as a standard of reference for ischemia early after ST elevation myocardial infarction. Cardiovasc Revasc Med, 2020, 21(11): 1411-1416.
16.	Qi X, Fan G, Zhu D, et al. Comprehensive assessment of coronary fractional flow reserve. Arch Med Sci, 2015, 11(3): 483-493.
17.	Pijls NH. Optimum guidance of complex PCI by coronary pressure measurement. Heart, 2004, 90(9): 1085-1093.
18.	Modolo R, Collet C, Onuma Y, et al. SYNTAX Ⅱ and SYNTAX Ⅲ trials: what is the take home message for surgeons? Ann Cardiothorac Surg, 2018, 7(4): 470-482.
19.	Collet C, Miyazaki Y, Ryan N, et al.Fractional flow reserve derived from computed tomographic angiography in patients with multivessel CAD. J Am Coll Cardiol, 2018, 71(24): 2756-2769.
20.	Bartorelli AL, Andreini D, Mushtaq S, et al. The revolution project: replacing coronary artery angiography with coronary computed tomography with functional evaluation. Eur Heart J Suppl, 2020, 22(Suppl L): L15-L18.
21.	Cavalcante R, Onuma Y, Sotomi Y, et al. Non-invasive heart team assessment of multivessel coronary disease with coronary computed tomography angiography based on SYNTAX score Ⅱ treatment recommendations: design and rationale of the randomised SYNTAX Ⅲ revolution trial. EuroIntervention, 2017, 12(16): 2001-2008.
22.	Andreini D, Takahashi K, Mushtaq S, et al. Impact of coronary calcification assessed by coronary CT angiography on treatment decision in patients with three-vessel CAD: insights from SYNTAX Ⅲ trial. Interact Cardiovasc Thorac Surg, 2022, 34(2): 176-184.
23.	Foy AJ, Dhruva SS, Peterson B, et al. Coronary computed tomography angiography vs functional stress testing for patients with suspected coronary artery disease: a systematic review and meta-analysis. JAMA Intern Med, 2017, 177(11): 1623-1631.
24.	Une D, Sakaguchi T. Initiation and modification of minimally invasive coronary artery bypass grafting. Gen Thorac Cardiovasc Surg, 2019, 67(4): 349-354.
25.	Zhang L, Fu Y, Gong Y, et al. Graft patency and completeness of revascularization in minimally invasive multivessel coronary artery bypass surgery. J Card Surg, 2021, 36(3): 992-997.
26.	Ruel M, Shariff MA, Lapierre H, et al. Results of the minimally invasive coronary artery bypass grafting angiographic patency study. J Thorac Cardiovasc Surg, 2014, 147(1): 203-208.
27.	Davierwala PM, Verevkin A, Sgouropoulou S, et al. Minimally invasive coronary bypass surgery with bilateral internal thoracic arteries: early outcomes and angiographic patency. J Thorac Cardiovasc Surg, 2021, 162(4): 1109-1119. e4.
28.	Rufa MI, Ursulescu A, Dippon J, et al. Is minimally invasive multi-vessel off-pump coronary surgery as safe and effective as MIDCAB? Front Cardiovasc Med, 2024, 11: 1385108.
29.	Demir OM, Ryan M, Rahman H, et al. Fractional flow reserve: current evidence base in stable coronary artery disease. 2019: 1-28.
30.	Parikh RV, Fearon WF. Physiology over angiography to determine lesion severity: the FAME trials. Interv Cardiol Clin, 2020, 9(4): 409-418.
31.	Li B, Mao B, Feng Y, et al. The hemodynamic mechanism of FFR-guided coronary artery bypass grafting. Front Physiol, 2021, 12: 503687.

1. Knuuti J, Wijns W, Saraste A, et al. 2019 ESC guidelines for the diagnosis and management of chronic coronary syndromes. Eur Heart J, 2020, 41(3): 407-477.
2. Erne P, Schoenenberger AW, Burckhardt D, et al. Effects of percutaneous coronary interventions in silent ischemia after myocardial infarction: the SWISSIⅡ randomized controlled trial. JAMA, 2007, 297(18): 1985-1991.
3. Radaideh Q, Osman M, Kheiri B, et al. Meta-analysis of the effect of percutaneous coronary intervention on death and myocardial infarction in patients with stable coronary artery disease and inducible myocardial ischemia. Am J Cardiol, 2020, 133: 171-174.
4. Pijls NH, van Schaardenburgh P, Manoharan G, et al. Percutaneous coronary intervention of functionally nonsignificant stenosis: 5-year follow-up of the DEFER study. J Am Coll Cardiol, 2007, 49(21): 2105-2111.
5. Williams C, Brown DL. Effect of random deferral of percutaneous coronary intervention in patients with diabetes and stable ischaemic heart disease. Heart, 2020, 106(21): 1651-1657.
6. Pellicano M, De Bruyne B, Toth GG, et al. Fractional flow reserve to guide and to assess coronary artery bypass grafting. Eur Heart J, 2017, 38(25): 1959-1968.
7. Rioufol G, Dérimay F, Roubille F, et al. Fractional flow reserve to guide treatment of patients with multivessel coronary artery disease. J Am Coll Cardiol, 2021, 78(19): 1875-1885.
8. Jolly SS, Amlani S, Hamon M, et al. Radial versus femoral access for coronary angiography or intervention and the impact on major bleeding and ischemic events: a systematic review and meta-analysis of randomized trials. Am Heart J, 2009, 157(1): 132-140.
9. Niu D, Gao Q, Ren B, et al. The safety and efficacy of non-emergent percutaneous coronary intervention via distal radial artery access in patients with acute coronary syndrome. Front Cardiovasc Med, 2025, 12: 1696742.
10. Zhuang B, Wang S, Zhao S, Lu M. Computed tomography angiography-derived fractional flow reserve (CT-FFR) for the detection of myocardial ischemia with invasive fractional flow reserve as reference: systematic review and meta-analysis. Eur Radiol, 2020, 30(2): 712-725.
11. Taylor CA, Fonte TA, Min JK. Computational fluid dynamics applied to cardiac computed tomography for noninvasive quantification of fractional flow reserve: scientific basis. J Am Coll Cardiol, 2013, 61(22): 2233-2241.
12. Khav N, Ihdayhid AR, Ko B. CT-derived fractional flow reserve (CT-FFR) in the evaluation of coronary artery disease. Heart Lung Circ, 2020, 29(11): 1621-1632.
13. Kim MY, Yang DH, Choo KS, Lee W. Beyond coronary ct angiography: CT fractional flow reserve and perfusion. Taehan Yongsang Uihakhoe Chi, 2022, 83(1): 3-27.
14. De Bruyne B, Pijls NH, Bartunek J, et al. Fractional flow reserve in patients with prior myocardial infarction. Circulation, 2001, 104(2): 157-162.
15. Ghaemian A, Yazdani J, Farsavian AA, et al. Fractional flow reserve as a standard of reference for ischemia early after ST elevation myocardial infarction. Cardiovasc Revasc Med, 2020, 21(11): 1411-1416.
16. Qi X, Fan G, Zhu D, et al. Comprehensive assessment of coronary fractional flow reserve. Arch Med Sci, 2015, 11(3): 483-493.
17. Pijls NH. Optimum guidance of complex PCI by coronary pressure measurement. Heart, 2004, 90(9): 1085-1093.
18. Modolo R, Collet C, Onuma Y, et al. SYNTAX Ⅱ and SYNTAX Ⅲ trials: what is the take home message for surgeons? Ann Cardiothorac Surg, 2018, 7(4): 470-482.
19. Collet C, Miyazaki Y, Ryan N, et al.Fractional flow reserve derived from computed tomographic angiography in patients with multivessel CAD. J Am Coll Cardiol, 2018, 71(24): 2756-2769.
20. Bartorelli AL, Andreini D, Mushtaq S, et al. The revolution project: replacing coronary artery angiography with coronary computed tomography with functional evaluation. Eur Heart J Suppl, 2020, 22(Suppl L): L15-L18.
21. Cavalcante R, Onuma Y, Sotomi Y, et al. Non-invasive heart team assessment of multivessel coronary disease with coronary computed tomography angiography based on SYNTAX score Ⅱ treatment recommendations: design and rationale of the randomised SYNTAX Ⅲ revolution trial. EuroIntervention, 2017, 12(16): 2001-2008.
22. Andreini D, Takahashi K, Mushtaq S, et al. Impact of coronary calcification assessed by coronary CT angiography on treatment decision in patients with three-vessel CAD: insights from SYNTAX Ⅲ trial. Interact Cardiovasc Thorac Surg, 2022, 34(2): 176-184.
23. Foy AJ, Dhruva SS, Peterson B, et al. Coronary computed tomography angiography vs functional stress testing for patients with suspected coronary artery disease: a systematic review and meta-analysis. JAMA Intern Med, 2017, 177(11): 1623-1631.
24. Une D, Sakaguchi T. Initiation and modification of minimally invasive coronary artery bypass grafting. Gen Thorac Cardiovasc Surg, 2019, 67(4): 349-354.
25. Zhang L, Fu Y, Gong Y, et al. Graft patency and completeness of revascularization in minimally invasive multivessel coronary artery bypass surgery. J Card Surg, 2021, 36(3): 992-997.
26. Ruel M, Shariff MA, Lapierre H, et al. Results of the minimally invasive coronary artery bypass grafting angiographic patency study. J Thorac Cardiovasc Surg, 2014, 147(1): 203-208.
27. Davierwala PM, Verevkin A, Sgouropoulou S, et al. Minimally invasive coronary bypass surgery with bilateral internal thoracic arteries: early outcomes and angiographic patency. J Thorac Cardiovasc Surg, 2021, 162(4): 1109-1119. e4.
28. Rufa MI, Ursulescu A, Dippon J, et al. Is minimally invasive multi-vessel off-pump coronary surgery as safe and effective as MIDCAB? Front Cardiovasc Med, 2024, 11: 1385108.
29. Demir OM, Ryan M, Rahman H, et al. Fractional flow reserve: current evidence base in stable coronary artery disease. 2019: 1-28.
30. Parikh RV, Fearon WF. Physiology over angiography to determine lesion severity: the FAME trials. Interv Cardiol Clin, 2020, 9(4): 409-418.
31. Li B, Mao B, Feng Y, et al. The hemodynamic mechanism of FFR-guided coronary artery bypass grafting. Front Physiol, 2021, 12: 503687.

Chinese Journal of Clinical Thoracic and Cardiovascular Surgery

Latest ArticlesFractional flow reserve computed tomography for predicting the effect of coronary artery bypass grafting

Abstract Full text Figures/Tables Video References Cited by

Format

Content