Study on patterns and characteristics of in vivo tissue distribution of anti-inflammatory extract of Tetrastigma hemsleyanum aerial part in healthy and inflammatory pathological model rats / 中国中药杂志

The concentrations of seven anti-inflammatory components in blood and tissues were determined by UPLC-MS/MS after oral administration of Tetrastigma hemsleyanum aerial part(THAA) in healthy and inflammatory pathological model rats. The determination was carried out by using positive and negative ion switching technique, and multiple reaction monitoring(MRM) mode. The tissue distributions of the seven components in different physiological states were compared, and the patterns and characteristics of the effective components of THAA were studied. The results revealed that the seven effective components have large drug-time-curve areas(AUC) in heart, brain, small intestine, and stomach in both normal rats and inflammatory pathological model rats. This suggests that the anti-inflammatory effective component groups in THAA extract can all penetrate the blood-brain barrier, and have a large distribution area in gastrointestinal tract. It is inferred that gastrointestinal reabsorption may be one of the causes of the bimodal distribution of the drug-time curve of the drug blood distribution graph. As compared to normal rats, the effective component groups in THAA extract have higher drug-time curve area(AUC) in heart, brain, small intestine, stomach, liver, spleen, lung, kidney, and muscle of inflammatory pathological model rats. Among them, the effective component groups have the largest distribution area in heart, brain, small intestine, and stomach. This suggests that the binding force of organ tissues and drugs in the body may change under pathological conditions. It is speculated that the heart, brain, small intestine, and stomach may be the target tissues of THAA to produce anti-inflammatory effect. The retention times of THAA effective component groups in various organ tissues of rats in different physiological states are all relatively short, and do not have much difference. This suggests that no effective component accumulates in body, and that the pathological state of inflammation does not affect the onset times of the effective component groups. This experiment elucidates the patterns and characteristics of the in vivo target-effecting tissue distribution of THAA anti-inflammatory extract, and provides an experimental basis for clinical treatment.

Tissue distribution of Aconitum alkaloids extracted from Radix aconiti preparata after oral administration to rats / 药学学报

Aim To develop an HPLC method for the determination of Aconitum alkaloids extracted from Radix aconiti preparata in rats. Methods Waters 2690@996 PAD system was used. The analytical column was a Halsil 100 C18 column (250 mm×4.6 mm ID, 5 μm). The mobile phase was water, methanol and diethyl amine at the ratio of 75∶ 25∶ 0.1. The flow rate was 0.9 mL·min -1. The wavelength of the detector was 240 nm. Results The linear ranges of aconitine in the heart, spleen, lung and kidney were 0.4-100 μg·mL -1, the correlation coefficients were 0.997 2, 0.998 6, 0.999 3 and 0.999 4, respectively. The linear range of aconitine in liver was 2-200 μg·mL -1 and the correlation coefficient was 0.999 0. The linear ranges of hypaconitine in heart, liver, spleen, lung, kidney, brain and spinal cord were 5-100 μg·mL -1, the correlation coefficients were 0.999 4, 0.999 7, 0.999 8, 0.998 4, 0.999 8, 0.999 8 and 0.999 7, respectively. Detection limits (S/N=3) of aconitine and hypaconitine were 0.4 μg·mL -1. The recoveries of aconitine and hypaconitine ranged from 88.7% to 102.2% and 86.5% to 101.3%, respectively, and the RSD of precision of aconitine and hypaconitine was 10%. Conclusion It appears to be an accurate and effective method that can offer reference basis for in toxication of Radix aconiti preparata clinically.