Changes of blood endocannabinoids during anaesthesia: a special case for fatty acid amide hydrolase inhibition by propofol?

WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT: • Available data from animal studies suggest that the narcotic drug propofol interacts with the endocannabinoid system. Inhibition of enzymatic degradation of anandamide could explain some of the characteristics of propofol. Direct measurements have not been reported yet in humans. WHAT THIS STUDY ADDS: • Propofol does not change the time course of anandamide plasma concentrations during anaesthesia. Furthermore, propofol does not inhibit fatty acid amide hydrolase activity ex vivo or in vitro. Thus, specific characteristics of the narcotic drug propofol cannot be explained by peripheral inhibition of anandamide degradation in humans. AIMS: The aim of our study was to describe the time course of endocannabinoids during different anaesthesia protocols in more detail, and to challenge the hypothesis that propofol acts as a FAAH inhibitor. METHODS: Endocannabinoids were measured during the first hour of anaesthesia in 14 women and 14 men undergoing general anaesthesia with propofol and in 14 women and 14 men receiving thiopental/sevoflurane. We also incubated whole human blood samples ex vivo with propofol and the known FAAH inhibitor oloxa and determined FAAH enzyme kinetics. RESULTS: Plasma anandamide decreased similarly with propofol and thiopental/sevoflurane anaesthesia, and reached a nadir after 10 min. Areas under the curve for anandamide (mean and 95% CI) were 53.3 (47.4, 59.2) nmol l(-1) 60 min with propofol and 48.5 (43.1, 53.8) nmol l(-1) 60 min with thiopental/sevoflurane (P= NS). Anandamide and propofol plasma concentrations were not correlated at any time point. Ex vivo FAAH activity was not inhibited by propofol. Enzyme kinetics (mean ± SD) of recombinant human FAAH were K(m) = 16.9 ± 8.8 µmol l(-1) and V(max) = 44.6 ± 15.8 nmol mg(-1) min(-1) FAAH without, and K(m) = 16.6 ± 4.0 µmol l(-1) and V(max) = 44.0 ± 7.6 nmol mg( 1 ) min(-1) FAAH with 50 µmol l(-1) propofol (P= NS for both). CONCLUSIONS: Our findings challenge the idea that propofol anaesthesia and also propofol addiction are directly mediated by FAAH inhibition, but we cannot exclude other indirect actions on cannabinoid receptors.

Biochemical changes in endocannabinoid system are expressed in platelets of female but not male migraineurs.

The endogenous cannabinoid anandamide (AEA) plays important roles in modulating pain. Head pain is an almost universal human experience, yet primary headache disorders, such as migraine without aura (MoA) or episodic tension-type headache (ETTH), can represent a serious threat to well-being when frequent and disabling. We assessed the discriminating role of endocannabinoids among patients with ETTH or MoA, and control subjects. We measured the activity of AEA hydrolase and AEA transporter, and the level of cannabinoid receptors in peripheral platelets from MoA, ETTH and healthy controls. Sixty-nine headache patients and 36 controls were selected. Diagnosis of headache type was made according to the International Headache Society criteria. We observed significant sex differences concerning AEA membrane transporter and fatty acid amide hydrolase activity in all groups. An increase in the activity of AEA hydrolase and AEA transporter was found in female but not male migraineurs. Cannabinoid receptors were the same in all groups. Here we show that the endocannabinoid system in human platelets is altered in female but not male migraneurs. Our results suggest that in migraineur women an increased AEA degradation by platelets, and hence a reduced concentration of AEA in blood, might reduce the pain threshold and possibly explain the prevalence of migraine in women. The involvement of the endocannabinoid system in migraine is new and broadens our knowledge of this widespread and multifactorial disease.