Department of Emergency Medicine, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA, 19104, USA.
The Children's Hospital of Philadelphia , The Resuscitation Science Center, Philadelphia, PA, 19104, USA.
J Med Toxicol. 2023 Apr;19(2):196-204. doi: 10.1007/s13181-022-00928-w. Epub 2023 Feb 9.
Cyanide exposure can occur in various settings such as industry and metallurgy. The primary mechanism of injury is cellular hypoxia from Complex IV (CIV) inhibition. This leads to decreased ATP production and increased reactive oxygen species production. The brain and the heart are the organs most affected due to their high metabolic demand. While the cardiac effects of cyanide are well known, the cerebral effects on cellular function are less well described. We investigated cerebral metabolism with a combination of brain respirometry, microdialysis, and western blotting using a rodent model of sub-lethal cyanide poisoning.
Twenty rodents were divided into two groups: control (n = 10) and sub-lethal cyanide (n = 10). Cerebral microdialysis was performed during a 2 mg/kg/h cyanide exposure to obtain real-time measurements of cerebral metabolic status. At the end of the exposure (90 min), brain-isolated mitochondria were measured for mitochondrial respiration. Brain tissue ATP concentrations, acyl-Coenzyme A thioesters, and mitochondrial content were also measured.
The cyanide group showed significantly increased lactate and decreased hypotension with decreased cerebral CIV-linked mitochondrial respiration. There was also a significant decrease in cerebral ATP concentration in the cyanide group and a significantly higher cerebral lactate-to-pyruvate ratio (LPR). In addition, we also found decreased expression of Complex III and IV protein expression in brain tissue from the cyanide group. Finally, there was no change in acyl-coenzyme A thioesters between the two groups.
The key finding demonstrates mitochondrial dysfunction in brain tissue that corresponds with a decrease in mitochondrial function, ATP concentrations, and an elevated LPR indicating brain dysfunction at a sub-lethal dose of cyanide.
氰化物暴露可发生在工业和冶金等各种环境中。其主要损伤机制是细胞色素氧化酶复合物 IV(CIV)抑制导致的细胞缺氧。这会导致 ATP 生成减少和活性氧生成增加。由于大脑和心脏的代谢需求高,它们是受影响最严重的器官。虽然氰化物对心脏的影响众所周知,但对细胞功能的大脑影响描述得较少。我们使用亚致死剂量氰化物中毒的啮齿动物模型,结合脑呼吸测量法、微透析和 Western 印迹法来研究大脑代谢。
将 20 只啮齿动物分为两组:对照组(n=10)和亚致死氰化物组(n=10)。在 2mg/kg/h 的氰化物暴露过程中进行脑微透析,以获得大脑代谢状态的实时测量值。在暴露结束时(90 分钟),测量分离的脑线粒体的线粒体呼吸。还测量了脑组织 ATP 浓度、酰基辅酶 A 硫酯和线粒体含量。
氰化物组显示出明显的乳酸增加和低血压降低,同时伴有大脑 CIV 相关的线粒体呼吸降低。氰化物组的大脑 ATP 浓度也明显降低,且大脑乳酸/丙酮酸比值(LPR)显著升高。此外,我们还发现氰化物组脑组织中复合物 III 和 IV 的蛋白表达明显降低。最后,两组之间的酰基辅酶 A 硫酯没有变化。
关键发现表明,脑组织中线粒体功能障碍与线粒体功能下降、ATP 浓度降低以及 LPR 升高相对应,这表明在亚致死剂量的氰化物下大脑功能障碍。
