Objective To observe the changes of blood biochemistry during orthotopic liver transplantation in pigs. Methods Fourteen healthy pigs were anesthetized and intubated, the right carotic artery was cannulated for blood pressure monitoring and blood biochemical sampling. The right internal jugular vein was cannulated for central venous pressure monitoring. No exogenous glucose was administrated during operation, the donor liver was perfused with Collin’s solution. During the anhepatic stage, the veno-venous bypass was established, blood was pumped from the portal and femoral veins using an extracorporeal circuit, and returned to the axillary vein. The arterial blood was sampled for monitoring arterial blood gas tensions, Na+,K+,Ca2+, and blood glucose levels.Results During preanhepatic stage, blood glucose levels increased progressively, blood electrolytes and acidbase balance were stable. During anhepatic stage, pH was decreased, base deficit was increased significantly, blood glucose levels were significantly decreased, blood electrolytes were stable. During neohepatic stage, acidosis became more severe, blood potassium increased abruptly on reperfusin of the grafted liver, blood glucose was higher than that in prehepatic and anhepatic stage. Conclusion During operation of liver transplantation, metabolic acidosis developed progressively, blood glucose decreased in anhepatic stage, blood glucose and potassium increased significantly on reperfusion of the grafted liver.
Objective To explore the correlations between the time of tracheal extubation and the intraoperative basic factors of ex vivo liver resection followed by autotransplantation in patients with advanced hepatic alveolar echinococcosis (HAE), and analyze the change trend of blood gas analysis during operation. Methods The data of 24 patients with advanced HAE who underwent ex vivo liver resection followed by autotransplantation in West China Hospital of Sichuan University between February 2014 and August 2017 were retrospectively analyzed. Results There were significant correlations between the extubation time and the duration of anesthesia (r=0.472, P=0.031), the amount of bleeding (r=0.524, P=0.015), the amount of erythrocyte suspensions infusion (r=0.627, P=0.002), and the amount of plasma infusion (r=0.617, P=0.003). There was no statistical difference in extubation time between patients with and without pulmonary complications in 3 months postoperatively [(23.74±15.84), (15.52±19.40) h, P=0.327]. Compared with those arterial blood gas results before the interruption, the pH value, blood glucose, lactic acid and base excess were statistically significantly different (P<0.05) at each time point after the interruption. Blood potassium increased at the end of operation compared with that before interruption (P<0.05); and the free calcium after blocking and opening increased with a temporary decrease (P<0.05); the hemoglobin decreased significantly after interruption and clamping (P<0.05). Conclusions Anesthesia length and bleeding should be reduced in ex vivo liver resection followed by autotransplantation, thus the extubation time would be shortened and the prognosis of the patients might be improved. Because of the longer anhepatic phase, the blood gas analysis varies largely. During operation, blood gas analysis and monitoring should be strengthened, and the acid-base balance and electrolytes should be maintained in time.
The acid-base balance of the brain is critical to the functioning of the nervous system. The mechanisms that maintain acid-base homeostasis in the brain are complex and regulated by a variety of transporter proteins and enzymes. Slight changes in acid-base balance can affect neuronal excitability and even lead to epilepsy. Epilepsy is a common neurological disease with complex pathogenesis and numerous causes. Drug therapy is still the main method, but the treatment effect is limited. Therefore, it is urgent to clarify the pathological mechanism of epilepsy and explore new treatment directions This study provides an overview of the transporter proteins (acid-sensing ion channel, Na+/H+ exchanger, Na+/HCO3- cotransporters, anion exchangers, carbonic anhydrases) and the regulation of acid-base balance in the lungs. This study also introduces how these transporters participate in the stable maintenance of brain acid-base balance and their influence in epileptogenesis from both basic and clinical aspects in detail, providing new targets for epilepsy treatment and intervention.