1 German Aortic Center, Department of Vascular Medicine, University Heart Center Hamburg-Eppendorf, Hamburg, Germany.
2 Department of Cardiovascular Surgery, Inselspital, Bern University Hospital, University of Bern, Switzerland.
J Endovasc Ther. 2019 Aug;26(4):448-455. doi: 10.1177/1526602819849931. Epub 2019 May 15.
To analyze the distribution of air bubbles in the supra-aortic vessels during thoracic stent-graft deployment in zones 2 and 3 in an aortic flow model. Ten identical, investigational, tubular, thoracic stent-grafts were deployed in a glass aortic flow model with a type I arch: 5 in zone 2 and 5 in zone 3. A pulsatile pump generated a flow of 5 L/min with systolic and diastolic pressures (±5%) of 105 and 70 mm Hg, respectively. The flow rates (±5%) were 300 mL/min in the subclavian arteries, 220 mL/min in the vertebral arteries, and 400 mL/min in the common carotid arteries (CCAs). The total amounts of air released in each supra-aortic branch and in the aorta were recorded. The mean amounts of air measured were 0.82±0.23 mL in the zone-2 group and 0.94±0.28 mL in the zone-3 group (p=0.49). In the zone-2 group compared with zone 3, the amounts of released air were greater in the right subclavian artery (0.07±0.02 vs 0.02±0.02 mL, p<0.01) and right CCA (0.30±0.8 vs 0.18±07 mL, p=0.04). There were no differences between the groups concerning the mean amounts of air measured in the right vertebral and all left-side supra-aortic branches. The amount of air released in the descending aorta was significantly higher in the zone-3 group vs the zone-2 group (0.48±0.12 vs 0.13±0.08 mL, p<0.01). Small bubbles were observed continuously during deployment, whereas large bubbles appeared more commonly during deployment of the proximal stent-graft end and after proximal release of the stent-graft. Air is released into all supra-aortic branches and the descending aorta during deployment of tubular thoracic stent-grafts in zones 2 and 3 in an aortic flow model. Higher amounts of air were observed in right-side supra-aortic branches during deployment in zone 2, whereas significantly greater amounts of air were observed in the descending aorta during deployment in zone 3.
分析在主动脉血流模型中,Zone 2 和 Zone 3 区域胸主动脉支架置入期间,升主动脉血管内气泡的分布情况。在一个具有 I 型弓的玻璃主动脉血流模型中,10 个相同的管状胸主动脉支架被置入:5 个在 Zone 2,5 个在 Zone 3。脉动泵产生 5L/min 的流量,收缩压和舒张压(±5%)分别为 105 和 70mmHg。锁骨下动脉的流量(±5%)为 300mL/min,椎动脉为 220mL/min,颈总动脉(CCA)为 400mL/min。记录每个升主动脉分支和主动脉中释放的总气量。测量的平均气量分别为 Zone-2 组 0.82±0.23mL,Zone-3 组 0.94±0.28mL(p=0.49)。与 Zone 3 相比,Zone-2 组右锁骨下动脉(0.07±0.02 vs 0.02±0.02mL,p<0.01)和右 CCA(0.30±0.8 vs 0.18±07mL,p=0.04)释放的气量更大。在右侧椎动脉和所有左侧升主动脉分支的平均气量方面,两组之间没有差异。Zone-3 组降主动脉释放的气量明显高于 Zone-2 组(0.48±0.12 vs 0.13±0.08mL,p<0.01)。在支架置入过程中持续观察到小气泡,而在近端支架置入末端和近端支架释放后更常见到大气泡。在主动脉血流模型中,Zone 2 和 Zone 3 区域的管状胸主动脉支架置入过程中,空气会释放到所有升主动脉分支和降主动脉中。在 Zone 2 置入过程中,右侧升主动脉分支的空气量较大,而在 Zone 3 置入过程中,降主动脉的空气量明显较大。
