Antegrade cerebral perfusion (ACP) and retrograde cerebral perfusion (RCP) are the two major types of brain protection during aortic arch surgery. Which one is better has still been debated. By summarizing and analyzing the research progress of the comparative research of antegrade cerebral perfusion and retrograde cerebral perfusion in aortic arch surgery, we have found that there was no significant difference between ACP and RCP in terms of temporary nerve dysfunction (TND), permanent nerve dysfunction (PND), stroke, early mortality, morbidity, long-time survival, and a composite outcome of hospital death, bleeding, prolonged ventilation, need for dialysis, infection and stroke. But RCP resulted in a high incidence of prolonged mean ICU-stay and hospital-stay, longer mean extubation time as well as higher cost. And the surgeon is given more time to reconstruct the vessels of the arch since mean operative time is longer in the ACP. So we think that antegrade cerebral perfusion might be preferred as the brain protection method for complicated aortic arch procedures. If a surgeon confirms that the surgery is not very sophisticated and can be completed in a short time, it is better to choose RCP because of no catheter or cannula in the surgical field to impede the surgeon. The article aims at providing a reference to cardiac surgeries when choosing cerebral protection strategy in aortic arch surgery.
Increasing evidences show that a gradual trend away from deep hypothermia toward moderate hypothermic circulatory arrest, which has been proved to be safe and effective in clinic. By summarizing and analyzing the research progress and applying status of the moderate hypothermia circulatory arrest with selective antegrade cerebral perfusion, the article aims at promoting the application of this tenique as a cerebral protection strategy in aortic arch surgery for adults in China.
Abstract: Objective To investigate the cerebral protective effects of hyperoxia management during deep hypothermia circulatory arrest(DHCA) rabbit by the blood gas indexes, superoxide dismutase( SOD) activity and malondialdehyde (MDA) levels of brain, and ratio of water to brain. Methods A DHCA and antegrade selective cerebral perfusion (ASCP) rabbit model was established. Twenty-four 11-13 week-old male New Zealand rabbits( weighing 2.7 to 3.4 kg) were assigned to three groups with a random number table: a sham operation group (Sham group), an ASCP group (S group), and an ASCP + hyperoxia management group (SH group). There were eight rabbits in each group. We recorded the intraoperative values for arterial oxygen pressure (PaO2), arterial oxygen saturation (SaO2), jugular venous oxygen pressure(PjvO2), jugular venous oxygen saturation( SjvO2) and blood lactate level. The brain SOD activity, MDA levels, and ratio of water to brain were measured after the operation. Results Before initiating circulatory arrest, before initiating reperfusion and five minutes of reperfusion, levels of PaO2 , PjvO2 , and SjvO2 in the SH group were significantly higher than those of the S group and Sham group. SOD activity in the SH group was not significantly different from that of the S group[(213.53±33.52) U/mg. prot vs. (193.02±27.67) U/mg. prot] and Sham group[(213.53±33.52) U/mg. prot vs.(244.38±35.02)U/mg. prot], but the SOD activity in the S group was lower than that in the Sham group( P < 0.05). MDA levels in the SH group were lower than that in the S group[(1.42±0.30) nmol/mg. prot vs. (2.37±0.55) nmol/mg. prot, P < 0.05]. Conclusion Our data show that hyperoxia management during DHCA+ASCP improves rabbits’PjvO2 and SjvO2, maintains brain SOD activity, and decreases brain MDA levels, demonstrating the neuroprotective effects of hyperoxia mangagement.
To valuate cerebral protection by retrograde cerebral perfusion (RCP) via superior vena cava,the study results for the last ten years have been reviewed.RCP is regarded as an assistant method in deep hypothermic circulatory arrest(DHCA) in that it provides partial brain blood flow,maintains a low brain temperature,optimizes cerebral metabolic function during DHCA by supplying oxygen and some nutrient and removal of catabolic products;it also reduces the incidence of cerebral embolization by flushing out air...