Understanding coronary artery bypass transit time flow curves: role of bypass graft compliance

OBJECTIVES Low mean bypass graft flow (Q) and high pulsatility index (PI) measured by the transit time flow measurement method are not specific for anastomotic stenosis, but occur with competitive flow and poor coronary run-off. We hypothesized that graft compliance is responsible for these changes...

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Published in:Interactive cardiovascular and thoracic surgery 2014-02, Vol.18 (2), p.164-168
Main Authors: Jelenc, Matija, Jelenc, Bla, Kloko ovnik, Tomislav, Laki, Nikola, Geršak, Borut, Kne evi, Ivan
Format: Article
Language:English
Subjects:
Blood Flow Velocity
Compliance
Coronary Artery Bypass - adverse effects
Coronary Artery Bypass - methods
Coronary Circulation
Coronary Vessels - physiopathology
Coronary Vessels - surgery
Female
Graft Occlusion, Vascular - etiology
Graft Occlusion, Vascular - physiopathology
Humans
Internal Mammary-Coronary Artery Anastomosis - adverse effects
Male
Models, Cardiovascular
Original
Pulsatile Flow
Risk Factors
Saphenous Vein - physiopathology
Saphenous Vein - transplantation
Time Factors
Treatment Outcome
Vascular Capacitance
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Summary:OBJECTIVES Low mean bypass graft flow (Q) and high pulsatility index (PI) measured by the transit time flow measurement method are not specific for anastomotic stenosis, but occur with competitive flow and poor coronary run-off. We hypothesized that graft compliance is responsible for these changes and that flow measured at the proximal end of the coronary bypass can be viewed as a sum of the graft capacitive flow and flow that passes through the distal anastomosis. METHODS Transit time flow measurements (TTFMs) of 15 left internal thoracic artery (LITA) to LAD bypass grafts and 10 saphenous vein grafts (SVGs) to either the right coronary artery (RCA) or posterior descending artery (PDA) were analysed. The TTFM was performed on the proximal and distal end of the graft, and proximally with distal occlusion of the graft. Low mean bypass graft flow PI and diastolic filling (DF) measured distally and proximally were compared, and graft compliance was estimated. RESULTS Diastolic filling was higher distally in every single case (LITA-LAD: distal DF 76 ± 12% vs proximal 66 ± 13%, P = 0.005; SVG-RCA/PDA: distal 72 ± 15% vs proximal 63 ± 12%, P = 0.018). There were no significant differences in Q and PI. Subtracting the distal from the proximal flow gave a result identical to the proximal TTFM in distally occluded grafts, confirming the presence of graft capacitive flow. Graft compliance estimated from the flow of distally occluded grafts was 0.99 ± 0.47 l/mmHg for LITA grafts and 0.78 ± 0.42 l/mmHg for SVG grafts. CONCLUSIONS The study confirmed that the TTFM measured at the proximal end of the coronary bypass could be viewed as a sum of graft capacitive flow and the flow that passes through the distal anastomosis. Graft capacitive flow increases the systolic and decreases the diastolic TTFM when measured at the proximal end of the graft. It explains the higher DF when the TTFM is measured at the distal end of the graft and the increase in the PI at the proximal end when Q decreases. As the influence of graft capacitive flow on the PI in low Q can be eliminated by performing the TTFM at the distal end of the graft, we believe that the value of PI is clinically irrelevant.
ISSN:1569-9293
1569-9285
DOI:10.1093/icvts/ivt457