Vollenweider F X, Leenders K L, Oye I, Hell D, Angst J
Psychiatric University Hospital Zürich, Research Department, Switzerland.
Eur Neuropsychopharmacol. 1997 Feb;7(1):25-38. doi: 10.1016/s0924-977x(96)00042-9.
Until recently, racemic ketamine (S-ketamine/R-ketamine = 50:50) has been used to study NMDA receptor hypofunction in relation to pathophysiological models of schizophrenia. Ketamine given to normal humans in subanesthetic doses produces a model psychosis including both positive and negative symptoms of schizophrenia. More recently it has been shown that at subanesthetic doses the pure (S)- and (R)-ketamine enantiomeres interact differently with the NMDA and sigma receptor sites in human brain. It was found that (S)-ketamine binds with a 3-4 time higher affinity to the PCP binding site of the NMDA receptor than (R)-ketamine, and that at these concentrations (R)-ketamine interacts also weakly with the sigma receptor sites, where (S)-ketamine binds only negligibly. To further investigate the role of NMDA-receptor mediated neurotransmission in schizophrenic psychosis, the effects of pure (S)- and (R)-ketamine enantiomeres on brain energy metabolism in normal humans using positron emission tomography and [18F]fluorodeoxyglucose (FDG) are reported here. Psychotomimetic doses of (S)-ketamine increased cerebral metabolic rates of glucose (CMRglu) markedly in the frontal cortex including the anterior cingulate, parietal and left sensorimotor cortex, and in the thalamus. The metabolic changes in the frontal and left temporal cortex correlated with ego-disintegration and hallucinatory phenomena. Equimolar doses of (R)-ketamine tended to decrease CMRglu across brain regions and significantly suppressed CMRglu in the temporomedial cortex and left insula. (R)-ketamine did not produce psychotic symptoms, but a state of relaxation. The (S)-ketamine-induced metabolic hyperfrontality appears to parallel similar metabolic findings in acute psychotic schizophrenic patients and encourages further investigations of glutamatergic disturbances in schizophrenia.
直到最近,消旋氯胺酮(S-氯胺酮/R-氯胺酮 = 50:50)一直被用于研究与精神分裂症病理生理模型相关的NMDA受体功能低下。给正常人使用亚麻醉剂量的氯胺酮会产生一种模拟精神病,包括精神分裂症的阳性和阴性症状。最近有研究表明,在亚麻醉剂量下,纯(S)-和(R)-氯胺酮对映体与人类大脑中的NMDA和西格玛受体位点的相互作用不同。研究发现,(S)-氯胺酮与NMDA受体的苯环己哌啶结合位点的亲和力比(R)-氯胺酮高3至4倍,并且在这些浓度下,(R)-氯胺酮与西格玛受体位点的相互作用也较弱,而(S)-氯胺酮与该位点的结合可以忽略不计。为了进一步研究NMDA受体介导的神经传递在精神分裂症性精神病中的作用,本文报道了使用正电子发射断层扫描和[18F]氟脱氧葡萄糖(FDG)研究纯(S)-和(R)-氯胺酮对映体对正常人大脑能量代谢的影响。致幻剂量的(S)-氯胺酮显著提高了额叶皮质(包括前扣带回、顶叶和左侧感觉运动皮质)以及丘脑的脑葡萄糖代谢率(CMRglu)。额叶和左侧颞叶皮质的代谢变化与自我解体和幻觉现象相关。等摩尔剂量的(R)-氯胺酮倾向于降低全脑区域的CMRglu,并显著抑制颞内侧皮质和左侧岛叶的CMRglu。(R)-氯胺酮不会产生精神病症状,而是会产生一种放松状态。(S)-氯胺酮诱导的代谢性额叶功能亢进似乎与急性精神病性精神分裂症患者的类似代谢结果相似,并鼓励进一步研究精神分裂症中的谷氨酸能紊乱。
