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In the work by Quan et al. about the Use of Intraoperative Transit Time Flow Measurement Can Reduce Preoperative Myocardial Injury, the authors did a retrospective, observational study of the effects of exposure to the TTFM procedure. They collected patient data from the Second People's Hospital of Changzhou, affiliated with Nanjing Medical University, from June 2016 to June 2021; patients undergoing off‐pump coronary artery bypass grafting surgical procedures with general anesthesia were eligible. If they met one of the following criteria, patients were excluded: postoperative troponin did not reach normal value; combined with other valve surgery and significant liver dysfunction; died within 1 week after surgery. And after excluding 30 patients who did not meet the criteria, 146 patients were eventually included in the trial. In these studies, the postoperative myocardial injury was defined as an independent rise in cardiac troponin (from baseline) 70 times the upper reference limit (URL) according to ARC‐2 criteria 10, regardless of the symptoms of ischemia and electrocardiogram changes, within this study, specifically 2380 ng/L. All data entered into EpiData Version 2.1 (EpiData Association) was reviewed manually to ensure accuracy. After the coronary vessel bypass is completed, the heart is restored to its anatomic position, attachments are removed, and blood flow is measured immediately using theTTFM. In general, a 3‐mm size probe is used for the internal mammary artery and a 4‐ or 5‐mm probe for the radial artery or cavernous vein, as appropriate. The decision to review the graft is based on theTTFM flow, along with the specific clinical situation and an assessment of the target vessel. Blood samples were collected immediately postoperatively, 4 h postoperatively, 12 h postoperatively, 24 h postoperatively, and 48 h postoperatively and tested for cTNI within 1 h using a VITROS immunoassay analyzer (Ortho Clinical Diagnostics, Raritan). According to the manufacturer's instructions, the lower limit of cTNI using the Immunodiagnostic Troponin I ES Test Kit was 12 ng/L. The 99th percentile upper reference limit was 34 ng/L, Therefore, they set the standard for significant myocardial injury at 2380 ng/L. This association between the use of TTFM and myocardial injury was robust in the multivariate regression models (in all models, p = .05). Multiple logistic regression models were fit to estimate the relationship between the use of TTFM and myocardial events while adjusting for other independent variables. They performed three model fittings on the use of TTFM to confirm its stability, and the results indicated that the association between the use of TTFM and myocardial injury was still independently predicted. Fifty‐nine people received TTFM, while 47 did not. In total, seven (6.6%) had at least one grafting vessel obstruction. Only one patient where the TTFM was used had an occlusion graft versus six patients where the TTFM was not used and had a postoperative injury. In 2001, the use of TTFM techniques for assessing the quality of grafts intraoperatively, on the basis of the presence and volume of flow was clearly described. In our initial experience with OPCAB in the setting of acute AMI, the role that spread of thrombus played in the recovery of cardiac function became apparent. Technology, such as flowmetry, was not available to quantify flow measurements in coronary grafts, and the degree of myocardial damage immediately after surgery. Using TTFM, we can reconsider the most common use of OPCAB in situations of acute AMI where we can give the patient a better long‐ term survival, such as a Lima to Lad or arterial conduits in a young patient, or situations where we can do a MIDCAB and the variables, MINI OPCAB (lower middle incisions), or ROBOTIC operations. A systematic review of the evidence and expert opinion statements, concluded that although TTFM use may increase the cost and duration of the procedure and requires a learning curve, its cost/benefit ratio seems largely favorable, in view of the potential clinical consequences of graft dysfunction. These consensus statements will help to standardize the use of TTFM in clinical practice and provide guidance in clinical decision‐making. Although the use of TTFM is around 30% of coronary operations, it is clear that there are different situations where the use is fundamental. For example, when you do not have total control of the graft because of the incision; or situations like