STUDY OBJECTIVE: The aim of the study was to investigate collateral coronary flow and regional myocardial function following different coronary occlusion protocols. DESIGN: Effects of brief left anterior descending artery (LAD) occlusions in dogs (using a pneumatic occluder around the proximal artery) on collateral circulation were evaluated using three different protocols, each producing the same period of pressure gradient across the collateral network: (1) 10 s occlusion X 30 at 1 min intervals; (2) 1 min occlusion X 5 at 1 min intervals; (3) 5 min occlusion X 1. Each protocol was followed by a 10 s occlusion after a further 1 min period. SUBJECTS: 14 mongrel dogs of either sex were used, weight 10-21 kg. MEASUREMENTS AND MAIN RESULTS: Left ventricular pressure, left circumflex coronary artery (LCCA) flow, and subendocardial segment shortening (% delta L) in the area perfused by the LAD were monitored. Collateral blood flow from LCCA to LAD territory was measured as a stepwise decrease in LCCA flow on release of LAD occlusion. During the first 10 s of occlusion, % delta L decreased from 23.6(SEM 2.2)% to 14.2(2.9)%. After protocol (1), % delta L decreased from 23.1(2.2)% to 14.8(3.0)%. By contrast, after protocol (2) and (3) % delta L decreased only slightly, from 22.7(2.6)% to 20.5(2.8)%, and from 22.4(2.4)% to 19.8(2.4)%, respectively. Although collateral blood flow remained unchanged after protocol (1), it increased from 1.6(0.4) ml.min-1 during the first LAD occlusion to 3.0(0.7) ml.min-1 (p less than 0.05) after protocol (2), and to 3.5(0.6) ml.min-1 (p less than 0.05) after protocol 3. Haemodynamic measurements prior to each 10 s LAD test occlusion remained unchanged throughout the experiment. CONCLUSIONS: The pressure gradient across the collateral network cannot dilate pre-existing collateral vessels by itself, but ischaemia related metabolites may play an important role in the recruitment of collateral circulation.
STUDY OBJECTIVE: The aim of the study was to investigate collateral coronary flow and regional myocardial function following different coronary occlusion protocols. DESIGN: Effects of brief left anterior descending artery (LAD) occlusions in dogs (using a pneumatic occluder around the proximal artery) on collateral circulation were evaluated using three different protocols, each producing the same period of pressure gradient across the collateral network: (1) 10 s occlusion X 30 at 1 min intervals; (2) 1 min occlusion X 5 at 1 min intervals; (3) 5 min occlusion X 1. Each protocol was followed by a 10 s occlusion after a further 1 min period. SUBJECTS: 14 mongrel dogs of either sex were used, weight 10-21 kg. MEASUREMENTS AND MAIN RESULTS: Left ventricular pressure, left circumflex coronary artery (LCCA) flow, and subendocardial segment shortening (% delta L) in the area perfused by the LAD were monitored. Collateral blood flow from LCCA to LAD territory was measured as a stepwise decrease in LCCA flow on release of LAD occlusion. During the first 10 s of occlusion, % delta L decreased from 23.6(SEM 2.2)% to 14.2(2.9)%. After protocol (1), % delta L decreased from 23.1(2.2)% to 14.8(3.0)%. By contrast, after protocol (2) and (3) % delta L decreased only slightly, from 22.7(2.6)% to 20.5(2.8)%, and from 22.4(2.4)% to 19.8(2.4)%, respectively. Although collateral blood flow remained unchanged after protocol (1), it increased from 1.6(0.4) ml.min-1 during the first LAD occlusion to 3.0(0.7) ml.min-1 (p less than 0.05) after protocol (2), and to 3.5(0.6) ml.min-1 (p less than 0.05) after protocol 3. Haemodynamic measurements prior to each 10 s LAD test occlusion remained unchanged throughout the experiment. CONCLUSIONS: The pressure gradient across the collateral network cannot dilate pre-existing collateral vessels by itself, but ischaemia related metabolites may play an important role in the recruitment of collateral circulation.