Supercritical fluid chromatography with tandem mass spectrometry combined with postcolumn compensation and one-step acetone protein precipitation to evaluate the bioavailability of probucol solid dispersion tablet.

Solid dispersion technology was used to improve the bioavailability of probucol due to its low hydrophilicity and high lipophilicity. In this study, a highly rapid and sensitive supercritical fluid chromatography with tandem mass spectrometry method was optimized and validated for the determination of probucol in beagle dog plasma with diazepam as an internal standard. The analyte and internal standard were extracted by acetone and then separated on a polar 2-ethylpyridine phase column (100 mm × 3 mm, 1.7 µm) at a flow rate of 1.0 mL/min using CO2 (≥99.99%) and methanol (95:5, v/v) as the mobile phase. The mass transition ion-pair was m/z 515.6→236.2 and 285.2→193.1 for probucol and internal standard, respectively. Excellent linearity was observed over the concentration range of 5-5000 ng/mL (r2 ≥ 0.9999) with a lower limit of quantification of 5 ng/mL. The intra- and inter-day accuracy and precision for all quality control samples were within ±15%. The proposed method was accurate, rapid and reproducible, which was successfully applied to a bioavailabilty evaluation of probucol solid dispersion tablets.

[Determination of probucol in human plasma by HPLC-MS/MS].

OBJECTIVE: To develop a specific and sensitive method for the determination of probucol in human plasma using HPLC-MS/MS technique. METHODS: Probucol were extracted from plasma by ethyl ether: dichloromethane (1:1, V/V), with physcion as an internal standard. The analytes went through the column of ultimate CN (50 mm x 4.6 mm, 5 microm) with mobile phase acetonitrile: water: ammonia water = 97:3:0.05 (adjusted pH = 7.2 with formic acid). Probucol was analyzed with a negative mode. The ion pairs being detected were 515.5-->236.1 (probucol) and 283.0-->239.9 physcion, respectively. RESULTS: The established method was able to determine probucol in human plasma over the range of 2.5-6000 ng/mL, with a method recovery ranging from 93.02% to 104.12%. The intra and inter day variances were below 4.67% and 5.72%. CONCLUSION: The HPLC-MS/MS method for analyzing probucol was validated. It is sensitive and suitable for pharmacokinetic studies of probucol.

Enhanced bioavailability of probucol following the administration of solid dispersion systems of probucol-polyvinylpyrrolidone in rabbits.

Disks of probucol and solid dispersion systems of probucol-polyvinylpyrrolidone (PVP) in various weight ratios were prepared. Dissolution of probucol was markedly increased in the solid dispersion systems in J.P. XV disintegration media No. 1 (pH 1.2) and No. 2 (pH 6.8). The concentrations of probucol after the dissolution of the disks of solid dispersion systems showed supersaturation. Following the administration of disks of solid dispersion systems in rabbits, a marked increase in the area under the plasma concentration time curve (AUC) was observed. When the weight ratio of PVP to probucol was larger, a larger AUC was observed. When disks of the 1 : 9 solid dispersion system (weight ratio of probucol : PVP=1 : 9) containing 50 and 100 mg probucol were respectively administered, AUC values were approximately proportional to the dose. AUC values following the administration of disks of the 1 : 9 solid dispersion systems containing 15 mg probucol (total weight: 150 mg) and 500 mg probucol were approximately equal. The mean half life (t(1/2)) was 12 h when disks of the 1 : 9 solid dispersion system were administered, whereas the t(1/2) was 35 h when probucol disks were administered. The markedly increased dissolution of probucol in solid dispersion systems resulted in a marked increase in its bioavailability.

A comparison of the antiatherogenic effects of probucol and of a structural analogue of probucol in low density lipoprotein receptor-deficient rabbits.

The efficacies of probucol and a close structural analogue as antioxidants in the prevention of atherogenesis in LDL receptor-deficient rabbits were compared. The antioxidant potency of the analogue in vitro was equal to that of probucol. Its biological availability was much greater: almost comparable concentrations in total plasma were achieved by feeding 1% probucol (wt/wt) and 0.05% analogue (wt/wt). Total plasma concentrations were comparable, but the concentration of probucol within the LDL fraction was about twice that of the analogue. Probucol slowed lesion progression by almost 50%, confirming earlier reports; the analogue, however, showed no detectable inhibitory effect on atherogenesis. Resistance of LDL to oxidation was measured at the end of the study by incubating it with Cu2+ and measuring the rate of diene conjugation. Probucol prolonged diene conjugation lag time from the control value of 130 min to values > 1,000 min. The analogue approximately tripled the lag time (mean, 410 min) and yet failed to slow the atherogenic process. The results suggest that LDL resistance to oxidation must reach some threshold level before there is significant protection against atherogenesis. However, probucol has additional biological effects, possibly not shared by the analogue, that could contribute to its antiatherogenic potential.

Putative mechanisms of action of probucol on high-density lipoprotein apolipoprotein A-I and its isoproteins kinetics in rabbits.

Probucol is a widely prescribed lipid-lowering agent, the major effects of which are to lower cholesterol in both low- and high-density lipoproteins (LDL and HDL, respectively). The mechanism of action of probucol on HDL apolipoprotein (apo) A-I kinetics was investigated in rabbits, with or without cholesterol feeding. 125I-labeled HDL was injected intravenously, and blood samples were taken periodically for 6 days. Kinetic parameters were calculated from the apo A-I-specific radioactivity decay curves. Fractional catabolic rate (FCR) and synthetic rate (SR) of apo A-I in rabbits fed a normal chow and normal chow with 1% probucol were similar. Apo A-I FCR of the rabbits fed 0.5% cholesterol was significantly increased but there were no changes in SR, compared to findings in the normal chow-fed group. Apo A-I FCR of the rabbits fed 1% probucol with 0.5% cholesterol (both 1 month and 2 months) was significantly increased compared to findings in rabbits fed the normal chow as well as 0.5% cholesterol diet group, while SR of apo A-I was significantly reduced in the former groups. Kinetics at 1 month after discontinuation of 1% probucol (under cholesterol feeding) showed a similar FCR of HDL-apo A-I to that of the rabbits fed 0.5% cholesterol, but the SR of apo A-I remained lower. Apo A-I isoproteins kinetics assessed by autoradiography of isoelectric focusing slab gels showed that the synthesis of proapo A-I was significantly reduced in the 1% probucol with 0.5% cholesterol administered, compared to the 0.5% cholesterol group. Thus, the action of probucol on HDL apo A-I kinetics was only prominent in case of higher serum cholesterol levels. The decreased HDL or apo A-I seen with probucol was apparently the result of an increase in FCR and a decrease in SR of HDL-apo A-I. A decreased synthesis of apo A-I remained evident even 1 month after discontinuing probucol. The action of probucol on the intracellular synthetic processes of apo A-I was revealed by the reduced synthesis of proapo A-I.

Sterol synthesis in vitro in freshly isolated blood mononuclear leukocytes from familial hypercholesterolemic patients treated with probucol.

Sterol synthesis rates were measured in freshly isolated blood mononuclear leukocytes obtained from familial hypercholesterolemic patients undergoing treatment with either probucol alone or probucol plus cholestyramine. Subjects with heterozygous familial hypercholesterolemia on probucol had a significant 31% reduction in mononuclear cell sterol synthesis rates as compared to control patients; sterol synthesis in cells from homozygous familial hypercholesterolemic patients on probucol did not differ from that in control subjects. Addition of cholestyramine to probucol therapy in heterozygous familial hypercholesterolemic patients caused an increase in sterol synthesis rates equal to but not greater than control values, thus negating the decreased mononuclear leukocyte sterol synthesis associated with probucol administration alone. Probucol treatment effectively decreased plasma cholesterol levels in both homozygous and heterozygous familial hypercholesterolemic subjects; however, the data suggest that the drug may exert different effects on sterol synthesis in peripheral tissues depending upon the presence or absence of cellular receptors for low-density lipoproteins.

G5-PEG PAMAM dendrimer incorporating nanostructured lipid carriers enhance oral bioavailability and plasma lipid-lowering effect of probucol.

This work aimed to improve the oral bioavailability and plasma lipid-lowering effect of probucol (PB) by constructing a combined drug delivery system (CDDS) composed of nanostructured lipid carrier (NLC) and PEGylated poly(amidoamine) dendrimer (PEG-PAMAM). PEG-PAMAM with dendrimer generations of 5 (G5-PEG) or 7 (G7-PEG) were incorporated in PB-NLCs to form PB-CDDSs, PB-NLCs/G5-PEG and PB-NLCs/G7-PEG. The resultant two kinds of PB-CDDSs were characterized by particle size, zeta potential, drug encapsulation efficacy, PB release rates, and physical stability. Formulation effects of NLC and CDDS on the cellular uptake of hydrophobic drug were explored in Caco-2 cells by fluorescent Cy5 dye as a hydrophobic drug model. Furthermore, in vivo pharmacokinetics of the PB-CDDS composed of G5-PEG and PB-NLCs were investigated in a low density lipoprotein receptor knockout (LDLr-/-) mouse model, including plateau plasma PB concentrations after oral administration of multiple doses, and bioavailability after oral administration of a single dose of different PB formulations. In addition, lipid-lowering effect of PB-NLCs/G5-PEG was studied. The results indicate that both G5-PEG and G7-PEG significantly improved aqueous solubility of PB. The two PB-CDDSs exhibited similar particle size (around 150nm) as PB-NLCs, but slower PB burst release rate, higher total PB release amount, and better particle morphology and storage stability than PB-NLCs. In comparison with traditional NLC, CDDS dramatically enhanced cellular uptake of Cy5 into Caco-2 cells. In vivo results demonstrate that PB-NLCs/G5-PEG had the highest plateau plasma PB concentration and oral bioavailability, and the greatest cholesterol-lowering effect in comparison with PB suspensions and PB-NLCs. Therefore, G5-PEG incorporating NLC can be exploited as a promising drug delivery system to improve oral bioavailability and lipid-lowering effect of PB.

The hypolipidemic action of probucol. Drug transport and lipoprotein composition in type IIa hyperlipoproteinemia.

In this study Probucol transport and the effect of the drug on lipoprotein composition in 9 cases of type IIa hypercholesterolemia were investigated. Probucol lowered plasma cholesterol by 20%, without affecting triglycerides. HDL cholesterol was decreased and a slight reduction in LDL cholesterol was noted. This was due to a reduction in the number of circulating lipoprotein particles, without modification in the lipid/protein ratio, mainly cholesterol/protein ratio. Probucol was almost entirely removed by lipoproteins; 75% of the drug was found in LDL, the remainder being equally distributed in VLDL and HDL. There was no correlation between the serum Probucol level, or the amount of Probucol bound to lipoproteins, and the decrease in serum or lipoprotein cholesterol. However, there was a significant increase of the EC/TC (esterified cholesterol/total cholesterol) ratio in VLDL and LDL, but not in HDL.

Effect of probucol treatment on lipoprotein cholesterol and drug levels in blood and lipoproteins in familial hypercholesterolemia.

Twelve patients with mild and 3 with severe hypercholesterolemia were stabilized with an isocaloric diet containing less than 300 mg cholesterol daily with a P/S ratio of 1.8, and placebo period of 4 weeks. They were administered 1000 mg probucol daily for 12 weeks, followed by placebo for 6 weeks. In patients with mild disease, a significant cholesterol reduction was achieved in serum, LDL, and HDL (maximum decrease, 17%, 13%, and 31%, respectively). While HDL3 cholesterol was reduced significantly throughout the period (P less than 0.001), HDL2 cholesterol showed a significant decrease only at the 4th week of treatment (P less than 0.001), and returned to basal levels at the 8th and 12th treatment weeks. Serum apo B levels decreased only slightly, but the HDL-apo A-I fall was significant with a reduction in the HDL-CH/HDL-apo A-I ratio throughout the treatment period. In 3 patients with severe disease, cholesterol decrease in serum and in VLDL, LDL and HDL fractions varied, but on the whole was lower than in patients with mild disease. A decrease in VLDL-CH and HDL-CH was present in all 3, but LDL-CH levels were only slightly lowered in 2 patients, and unchanged in the third. Serum probucol levels fell 66% from the 4th to the 12th treatment week, and in parallel, the percentage of lipoprotein-bound drug increased about 2-fold. It is suggested that these changes in pharmacokinetics as well as the cholesterol-lowering effect of the drug may be due to a change in lipoprotein composition or structure.

Probucol treatment attenuates the aortic atherosclerosis in Watanabe heritable hyperlipidemic rabbits.

We examined the effect of probucol on the aortic atherosclerosis already developed in Watanabe heritable hyperlipidemic (WHHL) rabbits at the initiation of treatment. In WHHL rabbits treated with probucol for 5 months from 8 months old, the lesion area in the aorta was significantly (P < 0.05) reduced when compared with that in untreated animals as well as animals at age 8 months. In contrast, plasma cholesterol levels in the probucol-treated group and untreated group during the experiment were not significantly different. LDL prepared from rabbits receiving probucol for 5 months showed resistance to oxidation by copper ions. Plasma CETP activity was significantly (P < 0.05) increased by probucol treatment. An immunohistochemical study showed that macrophages were abundant in the atherosclerotic lesions of untreated rabbits whereas smooth muscle cells were predominant in lesions of probucol-treated rabbits. These results suggest that the atherosclerotic lesion in WHHL rabbits can regress when treated by probucol and that the attenuation of atherosclerosis in this animal involves effects of probucol other than a decrease in plasma cholesterol, for example anti-oxidant activity.

The effects of probucol on the progression of atherosclerosis in mature Watanabe heritable hyperlipidaemic rabbits.

1. Probucol was administered to mature Watanabe heritable hyperlipidaemic (WHHL) rabbits (approximately 9 months old). Groups of WHHL rabbits were randomly selected and treated as follows: Group 1 killed at 9 months (n = 9); Group II placed on sham-treated diet at 9 months and followed for 6 months (n = 8); Group III placed on probucol at 9 months and followed for 6 months (n = 8). Probucol was administered by mixing 1% wt/wt drug with standard laboratory diet. 2. Plasma concentrations of probucol increased to 93 +/- 11 micrograms ml-1 in Group III during the initial 2 weeks and increased further to 149 +/- 24 micrograms ml-1 at the end of the treatment period. 3. Plasma concentrations of total cholesterol, unesterified cholesterol and phospholipids were significantly reduced overall by probucol, while triglycerides were not affected. 4. No statistically significant differences were observed in the presence of oxidized products in low density lipoproteins (LDL) isolated from plasma of controls compared to probucol-treated rabbits. However, LDL from probucol-treated animals was resistant to oxidation in the presence of Cu2+ (3 microM). 5. Group I had aortic atherosclerosis covering 70 +/- 5% of intimal area of thoracic aortae, that increased to 91 +/- 3% in Group II. This was associated with cholesterol contents of aortae increasing from 1.4 +/- 0.2 microgram mg-1 in Group I to 2.7 +/- 0.3 microgram mg-1 in Group II. Probucol administration did not produce a statistically significant reduction of atherosclerotic lesion area (78 +/- 7%). However, probucol treatment reduced cholesterol content to 1.9 + 0.3,ugmg-' (P < 0.01). Collagen content of aortae was not affected by probucol treatment. 6. Thus, while probucol did not promote regression, the drug did retard the continued deposition of cholesterol esters into atherosclerotic lesions of mature WHHL rabbits.

Effects of long-term treatment with probucol on serum lipoproteins in cases of familial hypercholesterolemia in the elderly.

The effect of probucol in lowering serum lipoprotein in young and middle-aged (YM) and elderly (E) patients with familial hypercholesterolemia were compared. Probucol at 1000 mg/day was administered orally to 37 YM patients and 14 E patients for an average of 10 months. Probucol treatment for this period caused significant reductions in the serum levels of total cholesterol, low density lipoprotein cholesterol (LDL-C), high density lipoprotein cholesterol, and apoprotein AI, AII, B, and CIII in both groups. The decreases in the levels of total cholesterol, LDL-C, and apoprotein B were greater in the E group than in the YM group (total cholesterol: YM, -19.3%, E, -31.3% [P less than .001]; LDL-C: YM, -17.0%, E, -35.4% [P less than .001]; apoprotein B: YM, -12.3%, E, -28.1% [P less than .01]). The decreases in other parameters in the two groups were not significantly different. The serum probucol concentrations in the YM and E groups were not significantly different. No significant side effects were observed in any patient. Thus probucol reduced the serum level of LDL more in the E group than in the YM group, and did so without any increase in the serum concentration of the drug or in side effects, suggesting that probucol is safe and beneficial for use in elderly patients.

Probucol protects lipoprotein (a) against oxidative modification.

Probucol, which decreases cholesterol levels and has antioxidant properties, was administered orally to patients with familial combined hyperlipidemia and high plasma lipoprotein(a) [Lp(a)] levels. The drug had no effect on Lp(a) concentrations after 4 weeks, but was found to be distributed in both Lp(a) and low-density lipoprotein (LDL). Before treatment, in each case LDL and Lp(a) isolated from the same individual were readily oxidized by copper, resulting in increased electrophoretic mobility and enhanced uptake and degradation by macrophages of both lipoproteins. After probucol treatment, both lipoproteins acquired resistance to in vitro oxidation by copper. Furthermore, probucol prevented their enhanced uptake and degradation by the macrophages. It is surmised that oxidized Lp(a) may carry an atherogenic potential that could be opposed by probucol administration.

Mechanisms of high-density lipoprotein reduction after probucol treatment: changes in plasma cholesterol esterification/transfer and lipase activities.

Probucol treatment results in a significant reduction of plasma high-density lipoprotein (HDL) levels. Since the remodeling of HDL within the plasma compartment is a crucial determinant of HDL levels, the activities of several factors participating in the process, ie, lecithin:cholesterol acyltransferase (LCAT), cholesteryl ester transfer protein (CETP), and lipoprotein and hepatic lipases (LPL, HL), were evaluated in 15 hypercholesterolemic patients treated with probucol (1 g/d) for 8 weeks. Drug treatment was associated with significant reductions of HDL cholesterol ([HDL-C] -32%), HDL2-C (-65%), HDL3-C (-22%), apolipoprotein (apo)A-I (-27%), and apo A-II (-11%) levels and with the accumulation of small HDL in plasma. CETP activity increased by 48%, with minor changes in LCAT (-7%), LPL (+4%), and HL (-7%) activities. By linear regression analysis, CETP activity correlated inversely with HDL-C, HDL2-C, and apo A-I levels (r = -.63, -.52, and -.73, respectively) and with HDL particle size. In multivariate analysis, CETP activity was the strongest predictor of HDL-C levels, apo A-I levels, and HDL particle size. The hypothetical mechanism of probucol is a stimulation of CETP activity, resulting in the formation of triglyceride (TG)-enriched HDL. These are acted on by HL, leading to the accumulation of small HDL in plasma.

Formation of malonaldehyde in the presence of probucol, an anti-atherosclerosis drug.

Formation and inhibition of malonaldehyde (MA) from blood plasma lipids oxidized by Fenton's reagent in the absence or presence of probucol [4,4'-(isopropylidenedithio)bis(2,6-di-tert-butylphenol)] and L-ascorbic acid were investigated. The amount of MA formed was quantitatively analysed by gas chromatography. L-Ascorbic acid inhibited MA formation by about 30% at the level of 4.0/micromol, but the amount of MA formed was increased by the presence of probucol. When 3.0 micromol oxidized probucol was hydrolysed at pH 1. 3 and 5, 2616.5 nmol, 287.5 nmol and 103.9 nmol MA were recovered, respectively. This is the first report of quantitative analysis of MA formed from probucol on oxidation.

Effect of LDL-apheresis on the pharmacokinetics of the lipophilic antilipidemic agent probucol.

The effect of LDL-apheresis on the pharmacokinetics of antilipidemic agents has not been evaluated thoroughly. In this study, we investigated the effect of LDL-apheresis on the pharmacokinetics of probucol, a lipophilic antilipidemic agent, by studying its distribution and changes in the blood concentration of probucol after LDL-apheresis. The concentrations of lipoproteins were measured before and after LDL-apheresis in eight patients with familial hypercholesterolemia taking probucol. Concentrations of probucol in the various lipoprotein fractions and plasma were measured by HPLC. The serum concentrations of probucol before and after LDL-apheresis were 39.8 +/- 3.3 and 16.5 +/- 1.6 micrograms/ml, and the correlation coefficient between the changes in the serum probucol concentration and those in the serum cholesterol concentration before and after LDL-apheresis was significant (r = 0.73, P < 0.01). Changes in the probucol and cholesterol concentrations after LDL-apheresis were mainly found in the LDL fraction. The calculated reductions in the serum contents of probucol and cholesterol were similar to the contents of probucol and cholesterol in the irrigation fluid of the dextran sulfate column. These data suggest that changes of probucol concentration in plasma by LDL-apheresis are mainly due to reductions in the LDL fraction.

[A comparison of the hypolipidemic action of probucol at doses of 500 and 1000 mg/day in moderate hyperlipoproteinemia]. / Sopostavlenie gipolipidemicheskogo deistviia probukola v doze 500 i 1000 mg/sut pri umerennoi giperlipoproteidemii.

AIM: Evaluation of effectiveness of hypolipidemic action of probucol in doses 500 and 1000 mg/day and comparison of probucol blood concentrations on the treatment month 3 and 6. MATERIALS AND METHODS: Probucol (Akrikhin, Russia) was given to 41 patients with primary hypercholesterolemia in a dose 500 mg/day. 3 months later the patients were divided into two groups. Group 1 patients exhibited a > 10% decrease in cholesterol levels and continued to take probucol in the dose 500 mg/day. Group 2 patients were crossed over to higher cholesterol dose--up to 1000 mg/day. Lipids levels were measured by enzyme tests, apoproteins--by immunoturbidimetry and immunodiffusion, probucol concentrations--by high-performance liquid chromatography. RESULTS: After 3 months of treatment, cholesterol lowered by 14.3 and 9.2% in groups 1 and 2, respectively. After 6 months, by 19.7 and 12.9%, respectively. Probucol concentrations in blood were higher after 6 months of treatment than after 3 months in both groups. No significant differences existed between the groups by probucol concentrations in 3 and 6 months. CONCLUSION: Hypolipidemic effect of probucol depended on the individual features of lipoproteins metabolic disorders rather than the drug blood concentration. Larger probucol doses fail to reduce cholesterol further.

Application of phospholipid complex technique to improve the dissolution and pharmacokinetic of probucol by solvent-evaporation and co-grinding methods.

To enhance the aqueous solubility and thus oral bioavailability of a poorly water-soluble drug, probucol (PB), probucol-phospholipid complex (PB-PC) was formulated by solvent-evaporation or co-grinding methods. The complexes were characterized by differential scanning calorimetry (DSC), infrared spectroscopy (IR), powder X-ray diffraction (PXRD), solubility, oil-water partition coefficient and in vitro dissolution. The DSC, IR and PXRD data confirmed the formation of phospholipid complex. Furthermore, the results indicated hydrogen bond formation between PB and PC molecules play an important role in the formation of PB-PC without the formation of a new compound. The water solubility of PB in the complexes was improved from 0.005 to 17.76 or 1.65 µg/mL (by solvent-evaporation or co-grinding methods respectively). As a result of it, the improved dissolution was shown in the prepared complexes. The PB-PC complexes by both solvent-evaporation and co-grinding methods exhibited higher peak plasma concentration (16,625.7 or 5343.3 vs. 2628.4 ng mL(-1)), increased AUC0-48 h (145,863.2 or 77,477.0 vs. 34,435.9 ng mL(-1)h) when compared with the commercial product, suggesting improved bioavailability of the drug. The study therefore suggests that the phospholipid complexes have possibilities in enhancing the therapeutic efficacy of PB which may be due to its improved aqueous solubility, dissolution behavior and thus bioavailability.

Effects of probucol, a typical hERG expression inhibitor, on in vivo QT interval prolongation in conscious dogs.

The cholesterol-lowering drug, probucol, is known to induce QT interval prolongation and torsades de pointes in patients. Recent in vitro studies have indicated that probucol reduces hERG expression in the plasma membrane and does not directly block human ether-a-go-go-related gene (hERG) channels. The present study was performed to investigate the effects of probucol on in vivo QT interval prolongation. Epicardial electrocardiograms were recorded in conscious dogs given oral single or repeated (7 days) doses of probucol (100mg/kg), and in combination with moxifloxacin (20mg/kg). QTc intervals were analyzed by a probabilistic method with individual rate collection formulae. Values of change in QTc (QTc) interval and its integration from 1 to 21 h (AUC1-21h) were calculated to evaluate drug-induced QT prolongation. A single dose of probucol slightly but significantly increased the AUC1-21h QTc interval on days 2 and 3. The QT prolongation was markedly augmented by repeated doses of probucol in a time-dependent manner, despite the lack of increase in plasma concentration. The combination of probucol and moxifloxacin produced additive effects on QT interval prolongation. These results suggest that long-term exposure to the hERG expression inhibitor, probucol, is required to evaluate its maximal effects on in vivo QT interval prolongation. A combination of direct and indirect hERG inhibitors may produce simple additive effects on QT interval prolongation.

A new function of Vitamin E-TPGS in the intestinal lymphatic transport of lipophilic drugs: enhancing the secretion of chylomicrons.

The purpose of this study was to examine whether Vitamin E-TPGS had a function in promoting the secretion of chylomicrons in enterocytes. Therefore, we simulated the human intestinal epithelial cells by Caco-2 cell model to study the effect of Vitamin E-TPGS on the chylomicron secretion in vitro. Meanwhile, chylomicron flow blocking rat model and mesenteric lymph cannulated rat model were used for the studies in vivo to evaluate the effect and probucol was chosen as the model drug. The results of cell experiments indicated that Vitamin E-TPGS at low concentration had a strong enhancement on the secretion of chylomicrons. The results of animal experiments indicated that Vitamin E-TPGS could significantly enhance the lymphatic transport of probucol by the same role consistently with the results obtained from cell experiments. However, the role would reach the plateau and saturate after a concentration dependent increase. These studies first demonstrate the function of Vitamin E-TPGS in the intestinal lymphatic transport of lipophilic drugs, which can significantly promote the secretion of chylomicrons by the intestinal epithelial cells.