Exposure to beta-carbolines norharman and harman

The aromatic beta-carbolines norharman and harman have been implicated in a number of human diseases including Parkinson's disease, tremor, addiction and cancer. It has been shown that these compounds are normal body constituents formed endogenously but external sources have been identified. Here, we summarise literature data on levels of norharman and harman in fried meat and fish, meat extracts, alcoholic drinks, and coffee brews. Other sources include edible and medicinal plants but tobacco smoke has been identified as a major source. Exposure levels from these different dietary sources are estimated to a maximum of 4 microg norharman per kg body weight (bw) per day and 1 microg harman per kg bw per day. Exposure via tobacco smoke depends on smoking habits and type of cigarettes but can be estimated to 1.1 microg/kg bw for norharman and 0.6 microg/kg bw for harman per package of cigarettes smoked. Studies on toxicokinetics indicate that inhalative exposure leads to a rapid increase in plasma levels and high bioavailability of norharman and harman. Oral bioavailability is lower but there are indications that sublingual absorption may increase dietary uptake of beta-carbolines. Endogenous formation can be estimated to be 50-100 ng/kg bw per day for norharman and about 20 ng/kg bw per day for harman but these rates may increase with high intake of precursors. Biomarker studies on plasma levels of beta-carbolines reported on elevated levels of norharman, harman or both in diseased patients, alcoholics and following tobacco smoking or consumption of beta-carboline-containing food. Cigarette smoking has been identified as major influence but dietary exposure may contribute to exposure.     

Pharmacokinetics of Sublingual Versus Oral Estradiol in Transgender Women

ObjectiveTo investigate the pharmacokinetics of 17β-estradiol (E2) administered orally versus those of 17β-E2 administered sublingually in transgender women.MethodsSingle doses of 17β-E2 were administered orally (1 mg) to 10 transgender women and then sublingually (1 mg) after a 1-week washout period. Blood samples were collected at baseline (0 hour) and at 1, 2, 3, 4, 6, and 8 hours after dosing. The samples were frozen and analyzed using liquid chromatography mass spectrometry (LC-MS/MS) and immunoassay.ResultsThe results demonstrated that sublingual E2 had a significantly higher peak serum E2 concentration of 144 pg/mL, measured using LC-MS/MS, compared with an oral E2 concentration of 35 pg/mL, measured using LC-MS/MS (P = .003). Sublingual E2 peaked at 1 hour and oral E2 peaked at 8 hours, as measured using LC-MS/MS. The area under the curve (AUC) (0-8 hours) for sublingual E2, measured using LC-MS/MS, was 1.8-fold higher than the AUC (0-8 hours) for oral E2, measured using LC-MS/MS. Additionally, sublingual E2 was found to have an increased E2-to-estrone ratio at all time points (1.1 ± 1.0 vs 0.7 ± 0.4, P ≤ .0001), the clinical significance of which is unclear.ConclusionOral E2 administered sublingually has a different pharmacokinetic profile, with higher serum E2 levels and AUC (0-8 hours) than traditionally administered oral E2. Multidaily dosing may be necessary to suppress testosterone levels with sublingual E2. The appropriate dosing, efficacy, and safety of sublingual E2, compared with those of other E2 preparations, are unknown.     

Stereoselective pharmacokinetics of tetrahydropalmatine after oral administration of (-)-enantiomer and the racemate

Tetrahydropalmatine (THP) is a biologically active ingredient isolated from a traditional Chinese herb Rhizoma corydalis (yanhusuo). THP is a racemic mixture which contains 50% of the (+) and 50% of (-) enantiomer. The (-) enantiomer accounts for most of the analgesic effects. Plasma concentrations of THP enantiomers were analyzed by chiral high-performance liquid chromatography (HPLC) on a Chiralcel OJ column with quantification by UV at 230 nm. The method was used to determine the pharmacokinetics of THP enantiomers in rats and dogs after oral administration of rac-THP or (-)-THP. The pharmacokinetic profiles of the two enantiomers after dosing with rac-THP were significantly different both in rats and dogs. The mean C(max) and AUC(0-infinity) values in rats were 1.93 +/- 0.36 microg/ml and 6.65 +/- 2.34 microg x h/ml for the (-) enantiomer, and 1.11 +/- 0.25 microg/ml and 2.03 +/- 0.45 microg x h/ml for the (+) enantiomer. The mean C(max) and AUC(0-infinity) in dogs were 1.60 +/- 0.81 microg/ml and 9.88 +/- 2.58 microg x h/ml for the (-) enantiomer, while 0.36 +/- 0.21 microg/ml and 1.22 +/- 0.40 microg x h/ml for the (+) enantiomer. rac-THP at 40 mg/kg and (-)-THP at 20 mg/kg had very similar plasma concentration-time profiles, and C(max), AUC(0-infinity), and t(1/2) of the (-) enantiomer in both rats and dogs, indicating that the two treatments were equivalent with respect to the pharmacokinetic properties of the (-) enantiomer.     

Salivary cortisol in low dose (1 microg) ACTH test in healthy women: comparison with serum cortisol

To date, a single report has appeared on the use of salivary cortisol for adrenal function testing with a low dose ACTH, although 1 microg has become preferred as a more physiological stimulus than the commonly used 250 microg ACTH test. Our present study was aimed to obtain physiological data on changes of free salivary cortisol after 1 microg ACTH stimulation. This approach was compared with the common method based on the changes of total serum cortisol. Intravenous, low-dose ACTH test was performed in 15 healthy women (aged 22-40 years) with normal body weight, not using hormonal contraceptives, in the follicular phase of the menstrual cycle. Blood and saliva for determination of cortisol were collected before ACTH administration and 30 and 60 min after ACTH administration. Basal concentration of salivary cortisol (mean +/- S.E.M., 15.9+/-1.96 nmol/l) increased after 1 microg ACTH to 29.1+/-2.01 nmol/l after 30 min, and to 27.4+/-2.15 nmol/l after 60 min. The differences between basal and stimulated values were highly significant (p<0.0001). The values of salivary cortisol displayed very little interindividual variability (p<0.04) in contrast to total serum cortisol values (p<0.0001) A comparison of areas under the curve (AUC) related to initial values indicated significantly higher AUC values for salivary cortisol than for total serum cortisol (1.89+/-0.88 vs. 1.22+/-0.19, p<0.01). Correlation analysis of serum and salivary cortisol levels showed a borderline relationship between basal levels (r=0.5183, p=0.0525); correlations after stimulation were not significant. Low-dose ACTH administration appeared as a sufficient stimulus for increasing salivary cortisol to a range considered as a normal adrenal functional reserve.     

Pharmacokinetics of ipriflavone, an isoflavone derivative, after intravenous and oral administration to rats hepatic and intestinal first-pass effects

Pharmacokinetic parameters of ipriflavone were evaluated after intravenous administration of spray-dried ipriflavone with polyvinylpyrrolidone, SIP (5, 10, 20, and 40 mg/kg as ipriflavone) and oral administration of SIP (50, 100, and 200 mg/kg as ipriflavone) to rats. The hepatic, gastric, and intestinal first-pass effects of ipriflavone were also measured after intravenous, intraportal, intraduodenal, and oral administration of SIP (20 or 50 mg/kg as ipriflavone) to rats. After intravenous and oral administration, the pharmacokinetic parameters of ipriflavone were dose-independent. The extent of absolute oral bioavailability (F) was also independent of oral doses; the mean F value was approximately 24%. Considering the amount of unchanged ipriflavone recovered from 24-hr gastrointestinal tract (the mean value was approximately 12%), the low F values could be due to the hepatic, gastric, and/or intestinal first-pass effects. Based on total body clearance (CL) data of ipriflavone after intravenous administration, the first-pass effect in the heart and lung could be almost negligible, if any, in rats. Approximately 30% of ipriflavone absorbed into the portal vein was eliminated by liver (hepatic first-pass effect) based on intravenous and intraportal administration of SIP. The area under the plasma concentration-time curve from time zero to time infinity (AUC) values after oral administration and intraduodenal instillation of SIP, 50 mg/kg as ipriflavone, were not significantly different, but the values were significantly smaller (129 and 116 microg ml/min) than that after intraportal administration of SIP, 20 mg/kg as ipriflavone (513 microg ml/min based on 50 mg/kg), indicating that gastric first-pass effect of ipriflavone was negligible, but intestinal first-pass effect was considerable in rats. Therefore, the low F value of ipriflavone after oral administration to rats was mainly due to intestinal first-pass effect. The hepatic first-pass effect and incomplete absorption of ipriflavone from rat gastrointestinal tract could also contributed to the low F in rats.     

Bioavailability and pharmacokinetics of a praziquantel bolus in kingfish Seriola lalandi

Oral praziquantel (PZQ) preparations have recently been investigated for the treatment of monogeneans that infect the skin and gills of kingfish Seriola lalandi cultured in sea-cages. To evaluate an oral PZQ dosing strategy, the pharmacokinetics of a dissolved and in feed oral PZQ preparation (40 mg kg(-1) body weight) were compared with an intravenous bolus in kingfish plasma and skin using HPLC. Compared with intravenous administration, PZQ bioavailability (area under curve, AUC0-24h) was slightly improved when the drug was administered with food in both kingfish plasma (56.8% in feed vs. 50.8% in solution) and skin (55.5% in feed vs. 50.3% in solution). After oral dosing, maximum drug concentrations in skin were approximately one-third of those achieved in plasma and higher when the drug was administered in solution (5.26 microg ml(-1)) than in feed (3.96 microg ml(-1)); additionally, the time to achieve maximum PZQ concentration was similar in plasma and skin, although markedly reduced when the drug was administered in solution (1 h) than in feed (6 h). However, clearance of the drug was delayed in skin; administered as an oral formulation, PZQ concentrations in the systemic circulation fell below the limit of quantification after 24 h, but remained quantifiable (0.3 microg g(-1)) in skin at this time. These initial studies indicate that a daily treatment interval will lead to the exposure of parasites to highly variable anthelmintic concentrations, which may be sub-optimal for the treatment of monogeneans in this finfish species.     

The antinociceptive effect and pharmacokinetics of olvanil following oral and subcutaneous dosing in the mouse

Mice were tested for response latency on a 55 degrees C hot plate after subcutaneous (S.C.) or oral administration of olvanil (dose level 200 and 300 mg/kg, respectively). Only the S.C. injection of olvanil produced antinociception. A pharmacokinetics experiment with radiolabeled olvanil (200 mg/kg) was conducted to determine whether this antinociception difference was related to a difference in plasma concentration of olvanil following the two routes of administration. The results indicate that concentrations of radioactivity (olvanil plus metabolites) in plasma reach a peak higher and faster after oral dosing than after S.C. injection. However, the area under the concentration-time curve (AUC) for recovery of radioactivity was slightly higher after the S.C. injection than after the oral dose of olvanil. In contrast, intact olvanil is barely measurable (10 to 30 ng/g) in plasma following an oral dose but is present in high concentration (100 to 2000 ng/g) following S.C. injection. The AUC for olvanil was also higher following a S.C. dose. These data indicate that olvanil fails to produce antinociception after oral dosing in mice not due to lack of absorption, but because it undergoes first pass metabolism.     

N-terminally modified glucagon-like peptide-1(7-36) amide exhibits resistance to enzymatic degradation while maintaining its antihyperglycaemic activity in vivo

Glucagon-like peptide-1(7-36)amide (tGLP-1) is inactivated by dipeptidyl peptidase (DPP) IV by removal of the NH(2)-terminal dipeptide His(7)-Ala(8). We examined the degradation of NH(2)-terminally modified His(7)99% of His(7)-glucitol tGLP-1 remained intact at 12 h. His(7)-glucitol tGLP-1 was similarly resistant to plasma degradation in vitro. His(7)-glucitol tGLP-1 showed greater resistance to degradation in vivo (92% intact) compared to tGLP-1 (27% intact) 10 min after i.p. administration to Wistar rats. Glucose homeostasis was examined following i.p. injection of both peptides (12 nmol/kg) together with glucose (18 mmol/kg). Plasma glucose concentrations were significantly reduced and insulin concentrations elevated following peptides administration compared with glucose alone. The area under the curve (AUC) for glucose for controls (AUC 691+/-35 mM/min) was significantly lower after administration of tGLP-1 and His(7)-glucitol tGLP-1 (36 and 49% less; AUC 440+/-40 and 353+/-31 mM/min, respectively; P<0.01). This was associated with a significantly higher AUC for insulin (98-99% greater; AUC 834+/-46 and 838+/-39 ng/ml/min, respectively; P<0.01) after tGLP-1 and His(7)-glucitol tGLP-1 administration compared to controls (421+/-30 ng/ml/min). In conclusion, His(7)-glucitol tGLP-1 resists plasma DPP IV degradation while retaining potent antihyperglycaemic and insulin-releasing activities in vivo.     

Pharmacokinetics of iloprost and cicaprost in mice.

Iloprost and cicaprost are two PGI2-mimetics, which are chemically stable and highly pharmacologically potent. Both compounds differ by their susceptibility to metabolic degradation. While iloprost contains a pentanoic acid upper side chain, which is subject to beta-oxidative degradation, cicaprost is metabolically stabilized by the introduction of an oxygen atom at position 3 of the pentanoic acid chain, preventing beta-oxidation. Both compounds have been characterized concerning their pharmacological and pharmacokinetic profile in a number of animal species and in man. In the present set of experiments both drugs were characterized in terms of pharmacokinetics in mice, an animal species quite routinely used in long-term toxicity studies on cancerogenicity, by iv and ig administration of 0.2 mg/kg (iloprost) and 0.01 mg/kg (cicaprost) using tritiated substances. Iloprost was rapidly inactivated after iv dosing with plasma levels declining from 247 to 0.27 ng/ml within 60 min. Disposition half-lives were 3 and 14 min. Total clerance accounted for 152 ml/min/kg. Total radiolabel exhibited a clearance of 35 ml/min/kg, its AUC in plasma was 146 ng-equiv.h/ml. After ig administration Iloprost peak plasma levels of 9.2 ng/ml occurred after 5 min. Bioavailability was 10%. AUC of total radiolabel was 152 ng-equiv.h/ml, showing complete absorption. Excretion of 3H-label was 41%/57% of dose (iv) and 36%/47% o.d. (ig) with the urine and 32%/18% o.d. (iv) and 36%/25% o.d. (ig) in male/female animals and proceeded for > 90% of dose fraction recovered with half-lives of 0.2-0.3 d. Metabolic patterns revealed the known profile consisting of unchanged drug, dinor- and tetranor-metabolites in plasma and mainly, tetranor-products in urine and feces. After iv dosing of cicaprost total radiolabel plasma levels declined biphasically with half-lives of approx. 0.05 h and 0.31 h. Extrapolated AUC was 1.6 ng-equiv. h/ml and total clearance accounted for 108 ml/min/kg. After ig treatment peak radioactivity plasma levels of 0.7 and 1 ng-equiv./ml were observed at 0.16 and 1 h postdose, probably due to differences between animal groups. Extrapolated AUC was 1 ng-equiv.h/ml. Excretion of 3H-label was mainly biliary: With the feces 83%/89% o.d. (iv) and 93%/92% o.d. (ig) were excreted by male/female animals, while 8.3%/5.7% o.d. (iv) and 2.6%/5.5% were recovered in the urine. More than 90% of the excreted radiolabel was found in samples collected up to 24 h postdose. Metabolic patterns in plasma revealed that after both routes of administration 3H-cicaprost was the dominant radiolabel fraction accounting for up to 90% of total radiolabel chromatographed.(ABSTRACT TRUNCATED AT 400 WORDS)     

Inhibition of cancer growth by resveratrol is related to its low bioavailability

The relationship between resveratrol (RES) bioavalability and its effect on tumor growth was investigated. Tissue levels of RES were studied after i.v. and oral administration of trans-resveratrol (t-RES) to rabbits, rats, and mice. Half-life of RES in plasma, after i.v. administration of 20 mg t-RES/kg b.wt., was very short (e.g., 14.4 min in rabbits). The highest concentration of RES in plasma, either after i.v. or oral administration (e.g., 2.6 +/- 1.0 microM in mice 2.5 min after receiving 20 mg t-RES/kg orally), was reached within the first 5 min in all animals studied. Extravascular levels (brain, lung, liver, and kidney) of RES, which paralleled those in plasma, were always < 1 nmol/g fresh tissue. RES measured in plasma or tissues was in the trans form (at least 99%). Hepatocytes metabolized t-RES in a dose-dependent fashion (e.g., 43 nmol of t-RES/g x min in the presence of 20 microM tRES), which means that the liver can remove circulating RES very rapidly. In vitro B16 melanoma (B16M) cell proliferation and generation of reactive oxygen species (ROS) was inhibited by t-RES in a concentration-dependent fashion (100% inhibition of tumor growth was found in the presence of 5 microM t-RES). Addition of 10 microM H(2)O(2) to B16M cells, cultured in the presence of 5 microM t-RES, reactivated cell growth. Oral administration of t-RES (20 mg/kg twice per day; or included in the drinking water at 23 mg/l) did not inhibit growth of B16M inoculated into the footpad of mice (solid growth). However, oral administration of t-RES (as above) decreased hepatic metastatic invasion of B16M cells inoculated intrasplenically. The antimetastatic mechanism involves a t-RES (1 microM)-induced inhibition of vascular adhesion molecule 1 (VCAM-1) expression in the hepatic sinusoidal endothelium (HSE), which consequently decreased in vitro B16M cell adhesion to the endothelium via very late activation antigen 4 (VLA-4).     

Gliclazide mainly affects insulin secretion in second phase of type 2 diabetes mellitus.

We studied the effect of the acute administration of gliclazide at 160 mg on insulin release during hyperglycaemic clamps in 12 type 2 diabetes patients, age 50 +/- 9.0 years, diabetes duration 5.5 +/- 4.8 years, fasting blood glucose 9.6 +/- 2.1 mmol/L (means +/- SD). After a 210 min of hyperinsulinaemic euglycaemic clamp (blood glucose 4.6 +/- 0.14mmol/L), gliclazide or placebo (randomised, double-blind, cross-over) was administered; 60 minutes later, a hyperglycaemic clamp (4hr) at 8mmol/L was started. Plasma C-peptide levels increased significantly after the administration of gliclazide (increment 0.17 +/- 0.15 vs. 0.04 +/- 0.07 nmol/L, p = 0.024) before the clamp. After the start of the hyperglycaemic clamp, the areas under the curve (AUC) for insulin and C-peptide did not differ from 0-10 min (first phase) with gliclazide. However, second-phase insulin release (30-240 min) was markedly enhanced by gliclazide. AUC plasma insulin (30 to 240 min) was statistically significantly higher after gliclazide (12.3 +/- 13.9 vs. -0.56 +/- 9.4 nmol/L x 210 min, p = 0.022); similarly, AUC plasma C-peptide (30 to 240 min) was also higher: 128 +/- 62 vs. 63 +/- 50 nmol/L x 210 min, p = 0.002). In conclusion, in long-standing type 2 diabetes the acute administration of gliclazide significantly enhances second phase insulin release at a moderately elevated blood glucose level. In contrast to previous findings in mildly diabetic subjects, these 12 type 2 diabetes patients who had an inconsiderable first phase insulin release on the placebo day, only showed an insignificant increase in first phase with gliclazide.     

Influence of footshock stress on pharmacokinetics of nicorandil in rats

The influence of footshock stress on the pharmacokinetics of nicorandil was examined in rats. In the group exposed to a 30-min period of footshock immediately after the oral administration of nicorandil (10 mg/kg), plasma nicorandil levels were markedly lower than those in the control group 30-120 min after administration. Plasma levels after the subcutaneous injection of nicorandil (5 mg/kg) were also slightly but significantly lower in stressed rats than in control rats. When footshock was applied from 60 min after oral administration or 30 min after subcutaneous injection (the time when the plasma nicorandil level was maximum), it also significantly decreased the plasma levels thereafter. Furthermore, footshock applied immediately after intravenous injection of nicorandil (3 mg/kg) significantly decreased the plasma levels 30-60 min after injection. Plasma levels of N-(2-hydroxyethyl) nicotinamide, one of the main metabolites of nicorandil, were slightly increased 30 min after the intravenous injection of nicorandil (10 mg/kg) by footshock. Nicorandil levels in the heart, kidney, and skin were significantly lower in the stressed rats similar to the change in the plasma level, but levels in the muscle, liver, and thymus showed no significant difference. The urinary excretion of nicorandil tended to be higher in the stressed rats. These results suggest that footshock stress affects not only the absorption of nicorandil but also its distribution, metabolism, and excretion.     

Pharmacokinetic study of 11-Keto beta-Boswellic acid.

INTRODUCTION: Boswellia serrata has been used in traditional medicine for treatment of inflammatory diseases since antiquity. However human kinetic studies are lacking for this. Hence to better elucidate its effects in humans and determine its optimal dosing, this study was planned. MATERIAL AND METHODS: Twelve healthy adult men volunteers were given capsule Wok Vel containing 333 mg of Boswellia Serrata Extract, orally, after a seven days washout period. Venous blood samples were drawn through indwelling canula from each volunteer prior to drug administration and at 30, 60, 120, 150, 180, 210, 240, 300, 360, 480, 600, 720, 840 minutes after drug administration. Plasma obtained after centrifuge was analyzed to measure concentration of 11-Keto beta-Boswellic Acid (KBA) by HPLC. Various kinetic parameters were then calculated from the plasma concentrations. RESULTS: The results are expressed as mean +/- Standard Error of Mean. The peak plasma levels (2.72 x 10(-3) +/- 0.18 micromoles/ml) of BSE were reached at 4.5 +/- 0.55 h. The concentration declined with a mean elimination half life of 5.97 +/- 0.95 h. The apparent volume of distribution averaged 142.87 +/- 22.78 L and the plasma clearance was 296.10 +/- 24.09 ml/min. The AUC(0-infinity) was 27.33 x 10(-3) +/- 1.99 micromoles/ml h. CONCLUSION: Elimination half life of nearly six hours suggests that the drug needs to be given orally at the interval of six hours. The plasma concentration will attain the steady state after approximately 30 hours. BSE is a safe drug and well tolerated on oral administration. No adverse effects were seen with this drug when administered as single dose in 333 mg.     

Pharmacokinetics of meloxicam in rabbits after single and repeat oral dosing

We evaluated the pharmacokinetic profile of meloxicam (0.3 and 1.5 mg/kg) given as single and repeated (once daily for 5 d) oral doses to female rabbits (n = 5/group) to define the optimal dose and dosing interval for clinical use. Clinical signs, body weight, and serum chemistry parameters (sodium, potassium, chloride, total protein, urea, creatinine, glucose, alkaline phosphatase, gamma glutamyl transferase, and alanine aminotransferase) were evaluated before and 5 d after dosing to monitor safety at the 2 dose levels in both studies. Plasma samples were collected serially, and concentrations were determined by high performance liquid chromatography. After single oral dosing at 0.3 or 1.5 mg/kg, maximal plasma concentrations of meloxicam were achieved at 6 to 8 h and were 0.14 and 0.3 microg/ml, respectively. Plasma drug levels decreased rapidly to near-undetectable levels by 24 h. There was moderate interindividual variability in plasma meloxicam concentrations with less than proportional increases in peak plasma concentration and area under the concentration curve values at the higher dose after the single and repeat dosing. The elimination half-life was approximately 8 h at both dose levels, suggesting that metabolism was not saturated. Oral clearance of meloxicam is high in rabbits, indicating rapid metabolism and elimination. There was no accumulation of meloxicam when given at 0.3 or 1.5 mg/kg for 5 d, and meloxicam was rapidly eliminated after discontinuation of dosing. Rabbits may require a dose exceeding 0.3 mg/kg given once daily to achieve optimal plasma levels of meloxicam over a 24-h interval.     

Determination of acteoside in Cistanche deserticola and Boschniakia rossica and its pharmacokinetics in freely-moving rats using LC-MS/MS

A sensitive LC-MS/MS method with a simple solid-phase extraction for the determination of acteoside in rat plasma and tissue homogenates was established for the investigation of bioavailability and brain distribution in freely-moving rats. Acteoside in Cistanche deserticola and Boschniakia rossica was also determined. Acteoside and internal standard were separated on a RP-select B column (125mmx4.6mm i.d., particle size 5microm). The mobile phase consisted of 35% methanol and 65% acetic acid-water (1:100, v/v) at a flow-rate of 1mL/min. Acteoside and the internal standard were monitored using the multiple-reaction monitoring (MRM) mode at m/z transitions of 623-->161 and 609-->301, respectively. The acteoside content was 38.4+/-2.4mg/kg (n=3) for B. rossica, which is obviously lower than 21134.2+/-805.5mg/kg (n=3) of C. deserticola. The protein binding in rat plasma was 75.5+/-1.8%. The brain distribution result indicated that acteoside was evenly distributed in brain tissues (brain stem, cerebellum, the rest of the brain, cortex, hippocampus and striatum) which was about 0.45-0.68% of that in plasma (4.5+/-0.5microg/mL) after 15min of acteoside administration (10mg/kg, i.v.). After acteoside was given (3mg/kg, i.v.; 100mg/kg, p.o.), the oral bioavailability (AUC(p.o.)/dose(p.o.))/(AUC(i.v.)/dose(i.v.)) was only 0.12%.     

Pharmacokinetic profile of (+/-)-gossypol in male Sprague-Dawley rats following single intravenous and oral and subchronic oral administration

The pharmacokinetic profile of (+/-)-gossypol was determined in male Sprague-Dawley rats following a single intravenous or oral 10 mg/kg dose and after receiving a daily oral 10 mg/kg dose for 14 days. The intravenous plasma (+/-)-gossypol level data were fitted with a three-compartment, open-model system. The apparent half-life of elimination of (+/-)-gossypol following intravenous administration was 11.44 hr, corresponding to an elimination rate constant of 0.05 hr-1. The total plasma clearance (Cl), volume of distribution (Vd), and AUCplasma following a single intravenous administration were 0.16 liter/hr/kg, 0.05 liter/kg, and 63.09 mg.hr/liter, respectively. The bioavailability of a single oral dose of (+/-)-gossypol in rats was 60%. The change in plasma (+/-)-gossypol concentration after a single or after multiple doses showed a biphasic pattern. A single oral dose of (+/-)-gossypol, however, was eliminated five times faster than the daily administered chemical. Thus, a single oral dose of (+/-)-gossypol was eliminated at a rate constant of 0.01 hr-1, corresponding to half-life of 64.76 hr. Subchronic oral administration of (+/-)-gossypol showed an apparent half-life of 101.91 hr-1, corresponding to a rate constant of 0.007 hr-1. The results indicate that multiple oral dosing of (+/-)-gossypol resulted in its longer retention in body tissue than a single oral dose. This study suggests that pharmacokinetics of (+/-)-gossypol may play, at least in part, a role in the reproductive toxicity of subchronic but not single oral dosing.     

Effects of cysteine on the pharmacokinetics and pharmacodynamics of intravenous and oral azosemide in rats with protein-calorie malnutrition

The effects of cysteine on the pharmacokinetics and pharmacodynamics of azosemide were investigated after intravenous (10 mg/kg) and oral (20 mg/kg) administration to male Sprague-Dawley rats fed on 23% protein diet (control rats), and 5% protein diet with (rats with PCMC) or without (rats with PCM) oral cysteine (250 mg/kg, twice daily for the fourth week) for 4 weeks. After intravenous administration to rats with PCMC, some pharmacokinetic parameters restored fully or more than the level of control rats; the time-averaged nonrenal clearance (2.70 versus 2.32 ml/min/kg) and apparent volume of distribution at steady state (160 versus 189 ml/kg) were comparable to those in control rats, however, the terminal half-life (34.7 versus 57.2 min) and mean residence time (73.3 versus 99.3 min) were significantly shorter, area under the plasma concentration-time curve from time zero to time infinity (AUC, 1930 versus 2680 microg min/ml) was significantly smaller, and time-averaged renal (2.24 versus 1.21 ml/min/kg) and total body (CL, 4.98 versus 3.65 ml/min/kg) clearances were significantly faster than those in control rats. This could be mainly due to significantly faster renal clearance and at least partly due to increased cytochrome P450 1A2 activity by cysteine supplementation. After intravenous administration to rats with PCMC, the total amount of 8-hr urinary excretion of unchanged azosemide was significantly greater (457 versus 305 microg/g body weight), however, the 8-hr urine output (15.3 versus 31.1 ml/g kidney) was not significantly different between control rats and rats with PCMC. This could be due to the fact that urine output seemed to reach an upper plateau from 10 mg/kg dose of azosemide in rats.     

Increased plasma apoA-IV level is a marker of abnormal postprandial lipemia: a study in normoponderal and obese subjects.

Plasma apolipoprotein A-IV (apoA-IV) levels are found elevated in hypertriglyceridemic patients. However, the relationship between plasma apoA-IV level and postprandial lipemia is not well known and remains to be elucidated. Thus, our objective was to study the relationship between plasma apoA-IV and postprandial TG after an oral fat load test (OFLT). Plasma apoA-IV was measured at fast and during an OFLT in 16 normotriglyceridemic, normoglucose-tolerant android obese subjects (BMI = 34.6 +/- 2.9 kg/m(2)) and 30 normal weight controls (BMI = 22.2 +/- 2.3 kg/m(2)). In spite of not statistically different fasting plasma TG levels in controls and obese patients, the former group showed an altered TG response after OFLT, featuring increased nonchylomicron TG area under the curve (AUC) compared with controls (516 +/- 138 vs. 426 +/- 119 mmol/l x min, P < 0.05). As compared to controls, obese patients showed increased apoA-IV levels both at fast (138.5 +/- 22.4 vs. 124.0 +/- 22.8 mg/l, P < 0.05) and during the OFLT (apoA-IV AUC: 79,833 +/- 14,281 vs. 68,176 +/- 17,463 mg/l x min, P < 0.05). Among the whole population studied, as among the control and obese subgroups, fasting plasma apoA-IV correlated significantly with AUC of plasma TG (r = 0.60, P < 0.001), AUC of chymomicron TG (r = 0.45, P < 0.01), and AUC of nonchylomicron TG (r = 0.62, P < 0.001). In the multivariate analysis, fasting apoA-IV level constituted an independent and highly significant determinant of AUC of plasma TG, AUC of chymomicron TG, AUC of nonchylomicron TG, and incremental AUC of plasma TG. In conclusion, we show a strong link between fasting apoA-IV and postprandial TG metabolism. Plasma fasting apoA-IV is shown to be a good marker of TG response after an OFLT, providing additional information on post-load TG response in conjunction with other known factors such as fasting TGs.     

Synthesis, antiviral activity, and pharmacokinetic evaluation of P3 pyridylmethyl analogs of oximinoarylsulfonyl HIV-1 protease inhibitors

As a continuation of the recently communicated discovery of oximinoarylsulfonamides as potent inhibitors of HIV-1 aspartyl protease, compounds bearing pyridylmethyl substituents at P3 were designed and synthesized. Potent analogs in this series provided low single-digit nanomolar EC50 values against both wild-type HIV and resistant mutant virus (A17), attenuated some 3- to 12-fold in the presence of 50% human serum. Pharmacokinetic results for compounds in this series showed good to excellent exposure when co-administered orally with an equal amount of ritonavir (5mg/kg each) in the rat, with average AUC >8 microg h/mL. Similar dosing in dog resulted in significantly lower plasma levels (average AUC <2 microg h/mL). The 3-pyridylmethyl analog 30 gave the best overall exposure (rat AUC=7.1 microg h/mL and dog AUC=4.9 microg h/mL), however, this compound was found to be a potent inhibitor of cytochrome P450 3A (Ki=2.4 nM).     

Absorption of intragastrically administered DDAVP in conscious dogs

Plasma concentrations of DDAVP were measured after intragastric administration and intravenous infusion in dogs. Oral ingestion of DDAVP led to a dose dependent increase in peak plasma concentrations as well as area under the curve (AUC). Intravenous infusion of DDAVP (0.13 pmol/l min) resulted in a mean steady-state level of 20.3 pmol/l. Elimination half-lives for oral DDAVP were 77.6 and 76.1 min for low and high doses respectively. T1/2 estimated from the ascending part of the i.v. infusion curve was 50 min. A metabolic clearance rate (MCR) of 3.9 ml/kg . min was assessed from the i.v. steady-state level.