Pharmacokinetic changes of unbound theophylline are due to plasma protein binding displacement and CYP1A2 activity inhibition by baicalin in rats

Abstract

Ethnopharmacological relevanceBaicalin is one of the major bioactive constituents of Scutellariae Radix, the root of Scutellariae baicalensis Georgi and possesses a wide variety of pharmacological properties. Aim of the studyTo elucidate the effect of baicalin on the pharmacokinetics of theophylline in rats, focusing on plasma protein binding displacement and inhibition effect on CYP1A2 in vivo and in vitro. Materials and methodsThe study was a randomized, three-period crossover design. Nine rats were given saline (control) or 450mg/kg baicalin (dosage regimen A or B). Dosage regimen A was administered once at 0h. Dosage regimen B was divided into three dosages (225,112.5, 112.5mg/kg) and was given at 0, 2 and 4h, respectively. Then theophylline (5mg/kg, i.v.) was administered immediately. The effect of baicalin on CYP1A2 activity was determined by metabolism of phenacetin in vitro and plasma protein binding of theophylline was determined by ultrafiltration. ResultsCmax decreased from (12.4±1.6) to (8.7±0.9) and (8.6±2.0)mg/L, T1/2 increased by 116 and 96%, Vd increased by 51 and 49% for total theophylline in rats treated with dosage regimen A and B of baicalin, respectively. Cmax was significantly increased, Vd decreased by 43 and 29% for unbound theophylline in rats treated with dosage regimen A and B of baicalin, respectively (P<0.01). T1/2 of unbound theophylline increased by 104% only in rats treated with dosage regimen B. No significant effects on the CL and AUC of both total and unbound theophylline were observed in the rats treated with dosage regimen A, but the CL decreased and AUC increased for total theophylline and CL decreased for unbound theophylline in the group treated with dosage regimen B (P<0.05). Correlation analysis showed that the mean unbound theophylline (%) and mean baicalin concentration was in good correlation (P<0.01). Baicalin decreased metabolism of phenacetin and exhibited a mixed-type inhibition in rat liver microsomes, with a Ki value of 88.1μM in vitro. Moreover baicalin was a competitive displacer of theophylline from plasma protein in vitro. ConclusionsThe changes in Cmax, T1/2, CL and AUC of theophylline due to baicalin may be attributed to two mechanisms, plasma protein binding displacement and CYP1A2 activity inhibition.