Résumé
@#Objective To analyze the safety and efficacy of vacuum-assisted venous drainage (VAVD) in cardiac surgery under cardiopulmonary bypass (CPB). Methods A total of 180 patients from 3 centers between November 17, 2017 and October 1, 2018 were enrolled and randomly assigned to a VAVD group and a gravity drainage (GD) group by 1∶1 ratio. During the open-heart surgery under CPB, the VAVD group completely relied on VAVD, and the GD group used conventional GD. The primary endpoint was arterial flow before CPB, 15 min after aortic cross-clamping and rewarming to 36 °C of nasopharyngeal temperature. The secondary endpoints included hematocrit, hemoglobin concentration, blood product transfusion, etc. The safety endpoint was free hemoglobin concentration, etc. Results The full analysis set contained 175 patients, 87 in the VAVD group and 88 in the GD group. Patients in the VAVD group were aged 52.8±12.0 years, and males accounted for 55.2%; patients in the GD group were aged 51.4±12.1 years, and males accounted for 59.1%. The demographic characteristics between the two groups were not statistically different. Compared to the GD group, the VAVD group could provide comparable arterial flow in CPB [average of 3 time points, 2.37±0.22 L/(min·m2) vs. 2.41±0.25 L/(min·m2), P=0.271], while not elevating free hemoglobin concentration. Conclusion VAVD can provide enough venous drainage, while not elevating free hemoglobin concentration or damaging blood.
Résumé
A 29-year-old man with high fever and chest pain was admitted to our hospital. He had undergone aortic valve replacement 1 month before admission to our hospital. Since computed tomography revealed a pseudoaneurysm in the ascending aorta, he underwent an emergency operation. An occlusion catheter was inserted into the ascending aorta via the left femoral artery, in preparation for pseudoaneurysm rupture. Cardiopulmonary bypass was established with inflow via the right femoral artery and the right axillary artery, and with vacuum-assisted venous drainage via the right femoral vein. After core cooling, we performed resternotomy. The pseudoaneurysm ruptured while we were exfoliating the adhesion around the aorta. We inflated the occlusion catheter in the ascending aorta and controlled the bleeding. We continued core cooling and ventricular fibrillation occurred at 30°C. Subsequently, we induced circulatory arrest, and selective cerebral perfusion was initiated. We inflated the occlusion catheter in the descending aorta and initiated systemic circulation with inflow via the right femoral artery. The origin of the pseudoaneurysm was the region of cannulation in the previous operation. Therefore, we replaced the ascending aorta and performed omentopexy. In this case we reported the use of a strategy involving cardiopulmonary bypass for a pseudoaneurysm in the ascending aorta.