Gingerols were metabolized by multiple hepatic and gastrointestinal UGT enzymes. Also, UGT1A9 and 2B7 were the main contributors to regioselective glucuronidation of gingerols in the liver.
Macelignan is a natural phenolic compound that possesses many types of health benefits such as antiinflammation. This study aimed to characterize the metabolism of macelignan via the glucuronidation pathway and to identify the main UGT enzymes involved in macelignan glucuronidation. The rates of glucuronidation were determined by incubating macelignan with UDPGA-supplemented microsomes. Kinetic parameters were derived by fitting an appropriate model to the data. Reaction phenotyping, the relative activity factor (RAF) approach and activity correlation analysis were employed to identify the main UGT enzymes contributing to the hepatic metabolism of macelignan. Glucuronidation of macelignan in pooled human liver microsomes (pHLM) was rather efficient with a high CLint (the intrinsic clearance) value of 13.90 ml/min/mg. All UGT enzymes, except UGT1A4, 1A6 and 2B10, showed metabolic activities toward macelignan. UGT1A1 and 2B7 were the enzymes with the highest activities; the CLint values were 4.92 and 2.13 ml/min/mg, respectively. Further, macelignan glucuronidation was significantly correlated with 3-O-glucuronidation of β-estradiol (r = 0.69; p < 0.01) and glucuronidation of zidovudine (r = 0.60; p < 0.05) in a bank of individual HLMs (n = 14). Based on the RAF approach, UGT1A1 and 2B7, respectively, contributed 55.40% and 32.20% of macelignan glucuronidation in pHLM. In conclusion, macelignan was efficiently metabolized via the glucuronidation pathway. It was also shown that UGT1A1 and 2B7 were probably the main contributors to the hepatic glucuronidation of macelignan.
The neuromuscular blocking agent cisatracurium is frequently used adjunctively in anesthesia to facilitate endotracheal intubation and to provide muscle relaxation during surgery. We aimed to determine the pharmacokinetics (PK)/pharmacodynamics (PD) of cisatracurium in patients with congenital heart defects (CHDs), such as ventricular septal defects and atrial septal defects, and to assess the effects of CHDs on the PK/PD profiles of cisatracurium. A modified two-compartment model with drug clearance from both compartments was best fitted to the PK data to determine the PK parameters. The model suggested that septal defects significantly lowered the rate of cisatracurium distribution from the central to peripheral compartment. The intercompartment rate constants k 12 and k 21 were significantly reduced (35%-60%, P < 0.05) in patients with ventricular septal defects and in patients with atrial septal defects compared with control patients. Consistently, septal defects caused a marked increase (160%-175%, P < 0.001) in the distribution half-life. Furthermore, significantly delayed pharmacodynamic responses to cisatracurium were observed in patients with septal defects. The onset time (i.e., the time to maximal neuromuscular block) was prolonged from 2.2 minutes to 5.0 minutes. PK/PD modeling suggested that reduced concentrations of cisatracurium in the effect compartment due to poorer distribution were the main cause of lagged pharmacodynamic responses. In conclusion, cisatracurium PK/PD were significantly altered in patients with septal defects. Our study should be of use in clinical practice for the administration of cisatracurium to patients with CHDs.
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