Pharmacokinetics of reboxetine in healthy volunteers. Single oral doses,linearity and plasma protein binding

The pharmacokinetics of reboxetine, a new antidepressant agent, were found to be close to linear in a crossover study comparing administration of single 2, 3, 4 and 5 mg capsule doses in 15 healthy male volunteers, and in the same study the capsules were bioequivalent to the proposed therapeutic tablet formulation (4mg). Kinetic analysis was based on HPLC assay of reboxetine in plasma and urine collected up to 72 h after each administration. Plasma levels indicated a rapid absorption (t_max?2h) and an elimination half-life of about 13 h. Clearance and volume of distribution were modest (ratios to bioavailability: CL/F?29 mL min^?1; V_z/F?32L); urinary excretion was ～9% of dose, corresponding to a renal clearance of only 3 mL min^?1 (a value consistent with the rate of glomerular filtration of unbound drug). In vitro, binding to plasma proteins, estimated from radioactivity levels following dialysis of ¹⁴C-labelled reboxetine, appeared to be dominated by α₁-acid glycoprotein without marked saturation up to plasma concentrations of over 500 ng mL^?1 (2.8–3.1% unbound with human plasma from three additional volunteers; 1.8–2.0% for 2gL^?1 orosomucoid α₁-acid glycoprotein, and 46.4–47.4% for 40 gL^?1 albumin), whilst the mean C_max in the current study was much lower (164 ng mL^?1 after a 5 mg dose).     

Assessment of in vitro metabolic stability,plasma protein binding,and pharmacokinetics of E‐ and Z‐guggulsterone in rat

Guggulsterone is a racemic mixture of two stereoisomers (E‐ and Z‐), obtained from the gum resin of Commiphora mukul and it is marketed as an antihyperlipidemic drug. The aim of our study was to assess the in vitro and in vivo absorption, distribution, metabolism, and excretion (ADME) properties namely solubility, in vitro metabolism, plasma protein binding and oral pharmacokinetic studies of E‐ and Z‐guggulsterone. In vitro metabolism experiments were performed by using rat liver and intestinal microsomes. In vitro intrinsic clearance (CL_int) was found to be 33.34 ± 0.51 and 39.23 ± 8.12 μL/min/mg protein in rat liver microsomes for E‐ and Z‐isomers, respectively. Plasma protein binding was determined by equilibrium dialysis method and in vivo pharmacokinetic studies were performed in male Sprague Dawley (SD) rats. Both isomers were highly bound to rat plasma proteins (>95% bound). Plasma concentration of E‐ and Z‐isomers decreased rapidly following oral administration and were eliminated from systemic circulation with a terminal half‐life of 0.63 ± 0.25 and 0.74 ± 0.35 h, respectively. The clearance (CL) for E‐isomer was 2.79 ± 0.73 compared to 3.01 ± 0.61 L/h/kg for Z‐isomer, indicating no significant difference (student t test; p <0.05) in their elimination.The pharmacokinetics of both isomers was characterized by extensive hepatic metabolism as seen with rat liver microsomes with high clearance and low systemic availability in rats. In brief, first‐pass metabolism seems to be responsible factor for low bioavailability of guggulsterone. Copyright © 2015 John Wiley & Sons, Ltd.     

Pharmacokinetics of quinidine related to plasma protein binding in man

Summary The disposition and plasma protein binding of quinidine after intravenous administration were studied in 13 healthy subjects. Plasma protein binding, expressed as the fraction of quinidine unbound ranged from 0.134–0.303 (mean 0.221). Elimination rate constant () varied from 0.071 to 0.146 h^–1 (mean 0.113), and apparent volume of distribution (V) varied from 1.39–3.20 l · kg^–1 (mean 2.27). Total body clearance was 2.32–6.49 ml min^–1 · kg^–1. There was a positive linear correlation between the plasma fraction of unbound quinidine and both V (r=0.885, p<0.01) and total body clearance (r=0.668, p<0.05). No significant correlation existed between the fraction of unbound quinidine in plasma and the elimination rate constant. The results show that both the apparent volume of distribution and total body clearance of quinidine are proportional to the unbound fraction in plasma. This implies that the total plasma concentration of quinidine at steady state will change with alterations in plasma binding, whilst the concentration of unbound compund and its elimination rate will remain unaffected.     

Clopidogrel variability: role of plasma protein binding alterations

Aim

The large inter-individual variability in clopidogrel response is attributed to pharmacokinetics. Although, it has been used since the late 1990s the pharmacokinetic fate of clopidogrel and its metabolites are poorly explained. The variable response to clopidogrel is believed to be multi-factorial, caused both by genetic and non-genetic factors. In this study, we examined whether the inactive metabolite can alter the plasma protein binding of the active metabolite, thus explaining the large inter-individual variability associated with clopidogrel response.

Methods

Female subjects (n = 28) with stable coronary disease who were not taking clopidogrel were recruited. Serial blood samples were collected following 300 mg oral dose of clopidogrel, plasma was isolated and quantified for total and free concentrations of active and inactive metabolites. Inhibition of platelet aggregation was measured using the phosphorylated vasodilator stimulated phosphoprotein (VASP) assay.

Results

A significant correlation was observed between VASP and both free (r = 0.49, P < 0.05) and total (r = 0.49, P < 0.05) concentrations of the active metabolite. Surprisingly, we observed a significant correlation with both free (r = 0.42, P < 0.05) and total (r = 0.67, P < 0.001) concentrations of the inactive metabolite as well. Free fractions of the active metabolite rose with increasing protein binding of the inactive metabolite (P < 0.05).

Conclusions

The above in vivo data suggest that the inactive metabolite displaces the active metabolite from binding sites. Thus, the inactive metabolite might increase the free concentration of the active metabolite leading to enhanced inhibition of platelet aggregation. The plasma protein binding mechanism would offer an additional therapeutic strategy to optimize clopidogrel pharmacotherapy.     

Melphalan concentration dependent plasma protein binding in healthy humans and rats

Summary The binding of melphalan to plasma proteins from four healthy humans and from rats was measured by centrifugal ultrafiltration. Melphalan concentrations were determined by HPLC and by measuring ¹⁴C-melphalan activity. In whole blood, melphalan was distributed preferentially in plasma. However, a constant fraction, 37%, which was independent of the total melphalan concentration in whole blood, was present within the red blood cells. The binding of melphalan to plasma proteins from humans was less than that from rats. In both, however, the fraction bound was constant throughout the concentration range (0.1 to 9.0 µM) that is achieved during standard-dose melphalan therapy. Albumin was the primary binding protein. At concentrations equal to or in excess of 33 µM, which have been achieved during high-dose melphalan therapy, free plasma melphalan concentrations were no longer linearly related to total drug concentrations, and the plasma protein binding of melphalan in the human became concentration dependent. This occurred at concentrations of 70 µM in the rat. Scatchard analysis of the data indicated the presence of 2 groups of binding sites. Class I sites had 0.03 and 0.4 binding sites per albumin molecule in humans and rats, with respective association constants of 4.43 × 10⁴M^–1 and 1.92 × 10⁴M^–1. Class II sites had 5.18 and 2.60 binding sites per molecule, with repective association constants of 3.82 × 10²M^–1 and 2.01 × 10²M^–1.     

Generalized pharmacokinetic modeling for drugs with nonlinear binding: I. Theoretical framework

The following integrodifferential equation is proposed as the basis for a generalized treatment of pharmacokinetic systems in which nonlinear binding occurs $$\phi '(c_u )c'_u = - q(c_u ) + g*c_u + f$$ where c_u≡unbound plasma drug concentration, f≡drug input rate,'indicates the derivative of a function, and * indicates the convolution operation: (g* c_u)(t)=∫ ₀ ^t g(t?u)c_udu.Possible physical interpretations of the functions q, g and f are: q (c_u)≡ rate at which drug leaves the sampling compartment, g * c_u ≡ rate at which drug returns to the sampling compartment from the peripheral system (tissues that are kinetically distinct from the sampling compartment), and φ(c_u) ≡ amount of drug in the sampling compartment. The approach assumes that drug binding is sufficiently rapid that it may be treated as an equilibrium process. It may be applied to systems in which nonlinear binding occurs within the sampling compartment, i.e., in the systemic circulation or in tissues to which drug is rapidly distributed. The proposed relationship is a generalization of most existing models for drugs with nonlinear binding. It can serve as a general theoretical framework for such models or as the basis for “model-independent” methods for analyzing the pharmacokinetics of drugs with nonlinear binding. Computer programs for the numerical solution of the integrodifferential equation are presented. Methods for pharmacokinetic system characterization, prediction and bioavailability are presented and demonstrated.     

Concentration‐dependent plasma protein binding of the novel dipeptidyl peptidase 4 inhibitor BI 1356 due to saturable binding to its target in plasma of mice,rats and humans

Objectives The purpose of this study was to characterise the plasma protein binding of BI 1356. Methods BI 1356 (proposed trade name ONDERO) is a novel dipeptidyl peptidase 4 (DPP‐4) inhibitor, which is under clinical development for the treatment of type 2 diabetes. DPP‐4 is expressed in various tissues but soluble DPP‐4 is also present in plasma. Therefore, binding to soluble DPP‐4 may influence the pharmacokinetics of BI 1356. Plasma protein binding of BI 1356 was determined in vitro for wild type mice and rats and the results compared with those for DPP‐4 knockout mice and DPP‐4 deficient Fischer rats. In addition, protein binding of BI 1356 was examined in plasma from healthy human volunteers and renal excretion of the compound in the DPP‐4 knockout mice was compared with that occurring in wild type mice. Key findings The results showed that BI 1356 exhibited a prominent concentration‐dependent plasma protein binding due to a saturable high affinity binding to the DPP‐4 target in plasma. Differences in renal excretion of BI 1356 between DPP‐4 knockout mice and wild type mice suggested that saturable binding of BI 1356 to DPP‐4 in the body also influenced elimination. Conclusions High affinity, but readily saturable binding of BI 1356 to its target DPP‐4 accounted primarily for the concentration‐dependent plasma protein binding at therapeutic plasma concentrations of BI 1356.     

Differential protein binding of indinavir and saquinavir in matched maternal and umbilical cord plasma

AIMS: To determine whether lower umbilical cord than maternal binding of indinavir and saquinavir contributed to the low cord : maternal (C : M) total concentration ratios reported previously. METHODS: Indinavir and saquinavir unbound fraction (fu) was determined using equilibrium dialysis. Buffer solutions of human serum albumin (HSA) (20.0, 30.0, 40.0 g l(-1)) and alpha(1)-acid glycoprotein (AAG) (0.20, 0.60, 2.00 g l(-1)) were spiked with indinavir (1.00 and 8.00 mg l(-1)) or saquinavir (0.15 and 1.50 mg l(-1)). Matched maternal and umbilical cord plasma was spiked with 1.00 mg l(-1) indinavir (n = 12) or 0.15 mg l(-1) saquinavir (n = 20). Spiked protein/plasma solutions were dialyzed against isotonic phosphate buffer, at 37 degrees C. At equilibrium, indinavir and saquinavir concentrations were quantified, and the f(u) determined. RESULTS: Indinavir and saquinavir demonstrated protein concentration-dependent binding in buffer solutions of HSA and AAG. Indinavir f(u) was significantly higher in umbilical cord (0.53 +/- 0.12) compared with maternal (0.36 +/- 0.11) plasma (95% CI of the difference -0.26, -0.097). Similarly, saquinavir fu was different between umbilical cord (0.0090 +/- 0.0046) and maternal plasma (0.0066 +/- 0.0039) (95% CI of the difference -0.0032, -0.0016). The transplacental AAG concentration gradient contributed significantly to the binding differential of both drugs. CONCLUSIONS: The differential plasma binding of both drugs, which was largely the result of the transplacental AAG concentration gradient, would contribute to the low C : M total plasma concentration ratios observed previously. Unbound concentrations of indinavir and saquinavir are likely to be substantially lower in umbilical cord than maternal plasma.     

Stereoselective plasma protein binding of ibuprofen enantiomers

Summary We have developed a novel and reproducible method for determining the plasma protein binding of the two ibuprofen enantiomers in the presence of each other. The method involves the use of radiolabelled racemic ibuprofen, equilibrium dialysis, derivatization of the enantiomers to diastereomeric amides, high-performance liquid chromatography, and radiochemical analysis.We have determined the plasma protein binding of R(–)- and S(+)-ibuprofen in 6 healthy male volunteers after the oral administration of 800 mg racemic ibuprofen.The mean time-averaged percentage unbound of the R(–)-enantiomer, 0.419 was significantly less than that of the S(+)-enantiomer, 0.643, consistent with stereoselective plasma protein binding.The percentage unbound of each ibuprofen enantiomer was concentration-dependent over the therapeutic concentration range and was influenced by the presence of its optical antipode.     

Pharmacokinetics,metabolism, excretion and plasma protein binding of 14C-levofloxacin after a single oral administration in the Rhesus monkey

Levofloxacin's metabolism, excretion, and in vitro plasma protein binding, together with its pharmacokinetics, were studied in the Rhesus monkey in support of an anthrax efficacy study in this species. Three males and three female Rhesus monkeys were dosed with a single oral dose of ¹⁴C-levofloxacin at 15?mg?kg^?1 (2?MBq?kg^?1). Following dose administration, blood samples were collected up to 48?h post-dose, and urine and faeces were quantitatively collected up to 168?h post-dose. Blood, plasma, urine, and faeces were analysed for total radioactivity. Metabolite profiling and identification was performed using radio-high-performance liquid chromatography (HPLC) and liquid chromatography coupled with tandem mass spectrometry detection (LC-MS/MS). Additionally, the plasma protein binding of levofloxacin was determined in vitro by means of equilibrium dialysis. Peak plasma levels of total radioactivity and levofloxacin were rapidly reached after oral administration with a total radioactivity blood: plasma ratio close to unity. The elimination half-life of levofloxacin was estimated at about 2?h. Total radioactivity was mainly excreted in urine (about 57–86% of the dose) with faecal excretion accounting for only a minor fraction of the total amount of excreted radioactivity (about 7.4–14.7%). In the plasma, the majority of total radioactivity was accounted for by levofloxacin. In addition, two minor metabolites, i.e. levofloxacin n-oxide and presumably a glucuronide conjugate of levofloxacin, were detected. In the urine, five components were found, with levofloxacin being the major component. Minor metabolites included desmethyl levofloxacin, levofloxacin n-oxide, and a glucuronide conjugate of levofloxacin. In the faeces, the major analyte was a polar metabolite, tentatively identified as a levofloxacin glucuronide. The in vitro plasma protein binding was low (on average 11.2%) and independent of concentration (1.0–10.0?µg?ml^?1). No sex differences were noted in any of the investigations. The present data indicated that the metabolism and excretion pattern, and also the in vitro plasma protein binding of levofloxacin in the Rhesus monkey, were comparable with those previously reported in man, hereby supporting the use of this animal species in the efficacy evaluation of levofloxacin against inhalation anthrax. The shorter half-life of levofloxacin in the Rhesus monkey relative to man (2 versus 7?h) prompted the development of an alternative dosing strategy for use in the efficacy study.     

Evaluation of oral and intravenous route pharmacokinetics, plasma protein binding, and uterine tissue dose metrics of bisphenol A: a physiologically based pharmacokinetic approach.

Bisphenol A (BPA) is a weakly estrogenic monomer used in the production of polycarbonate plastic and epoxy resins, both of which are used in food contact and other applications. A physiologically based pharmacokinetic (PBPK) model of BPA pharmacokinetics in rats and humans was developed to provide a physiological context in which the processes controlling BPA pharmacokinetics (e.g., plasma protein binding, enterohepatic recirculation of the glucuronide [BPAG]) could be incorporated. A uterine tissue compartment was included to allow the correlation of simulated estrogen receptor (ER) binding of BPA with increases in uterine wet weight (UWW) in rats. Intravenous- and oral-route blood kinetics of BPA in rats and oral-route plasma and urinary elimination kinetics in humans were well described by the model. Simulations of rat oral-route BPAG pharmacokinetics were less exact, most likely the result of oversimplification of the GI tract compartment. Comparison of metabolic clearance rates derived from fitting rat i.v. and oral-route data implied that intestinal glucuronidation of BPA is significant. In rats, but not humans, terminal elimination rates were strongly influenced by enterohepatic recirculation. In the absence of BPA binding to plasma proteins, simulations showed high ER occupancy at doses without uterine effects. Restricting free BPA to the measured unbound amount demonstrated the importance of including plasma binding in BPA kinetic models: the modeled relationship between ER occupancy and UWW increases was consistent with expectations for a receptor-mediated response with low ER occupancy at doses with no response and increasing occupancy with larger increases in UWW.     

Effect of caffeine on ceftriaxone disposition and plasma protein binding in the rat

Previous studies have shown that caffeine can affect drug kinetics by altering drug binding to plasma protein, drug absorption, or drug distribution. In this study, the effect of caffeine on the in vivoprotein binding and the disposition of ceftriaxone (a highly protein-bound cephalosporin) were investigated in the rat. Ceftriaxone 100mg/kg and caffeine 20mg/kg were i.v. injected via the tail vein and ceftriaxone in plasma, plasma filtrate, urine, feces, and tissues (brain, heart, kidney, liver, gut, lung, and muscle) was assayed by HPLC with UV detection. The fraction of free ceftriaxone in plasma ranged from 5.6 to 32.8% of total ceftriaxone (3–347 g/ml) without caffeine and showed no alteration by caffeine. The total amount of ceftriaxone excreted in urine and feces was increased significantly (p<0.05)from 13.1±1.8mg (mean±SD, 54.6% of total) to 15.3 ±1.1 mg (63.8% of total) by caffeine coadministration. The terminal half-life of ceftriaxone in plasma was shortened from 59 to 47 min, and the area under the plasma drug concentration-time curve (AUC)was reduced from 612 to 516 g hr/ml Although the peak drug concentrations and the times of peak concentration of ceftriaxone in tissues were not altered by caffeine administration, the elimination of ceftriaxone was increased, as indicated by generally shorter half-lives (decreases ranged from 17.5% in liver to 34.2% in brain) and lower AUCvalues (from 9.0% in heart to 54.5% in brain). These results suggest that caffeine does not alter the protein binding of ceftriaxone, but enhances the elimination of ceftriaxone in the rat.This study was supported in part by a grant from Chong Kun Dang Co., Korea.     

Accumulation kinetics of drugs with nonlinear plasma protein and tissue binding characteristics

The purpose of this investigation was to study, by digital computer simulation, the accumulation kinetics of drugs which exhibit concentration-dependent binding to tissues and either linear (constant free fraction) or concentration-dependent (increasing free fraction with increasing drug concentration) binding to plasma proteins. It was assumed that elimination rate is proportional to free drug concentration in plasma and that there occurs instantaneous equilibration of drug between vascular and nonvascular spaces. Nonlinear binding can yield, under certain conditions, apparently biexponential plasma concentrationtime curves which may be misinterpreted as being representative of a linear and biexponential-system. Such misinterpretation would cause the following errors in the prediction of drug accumulation and elimination kinetics during and after constantrate infusion: (a) the time required to reach steady state may be overestimated, and (b) the prominence of the apparent distribution phase after cessation of infusion may be underestimated. Drugs with linear and nonlinear plasma protein binding characteristics differ with respect to the relationship between infusion rate and steadystate concentration. This relationship is linear when plasma protein binding is linear. Steadystate concentration increases less than proportionally with increasing infusion rate if plasma protein binding is drug concentration dependent.     

Role of concentration-dependent plasma protein binding in disopyramide disposition

Plasma disopyramide concentration-time data and plasma protein binding measurements were obtained in 12 patients requiring disopyramide for suppression of their cardiac arrhythmias. The fraction of disopyramide unbound to plasma proteins varies from approximately 0.19 to 0.46 over the therapeutic range of total plasma concentrations (2–8 mg/liter). Data from single and multiple intravenous doses were analyzed using two models based on the hypothesis either that clearance is independent of the total disopyramide plasma concentration (total clearance model) or that clearance is independent of the concentration of disopyramide unbound to plasma proteins (free clearance model). This analysis indicates that only the free clearance model satisfactorily describes the data as a linear system. Using the free clearance model and data obtained from single doses, multiple intravenous infusions were designed for each patient which would rapidly attain and maintain predetermined plasma disopyramide concentrations. The calculated and observed disopyramide concentrations were in close agreement. In the 12 patients studied, at any given total disopyramide plasma concentration, there was an approximately twofold range in the fraction of disopyramide unbound to plasma proteins. Mean plasma protein binding data are therefore of little value in a given patient for predicting free disopyramide concentrations from measurements of total disopyramide concentration. Difficulties in the clinical management of patients receiving disopyramide, resulting from the nonlinear disposition of the usually measured total disopyramide concentrations, are discussed.This work was supported in part by NIH Grants Nos. 1-RO1-HL-21221 and RR-70, and by Searle Laboratories, Skokie, Illinois. Dr. Winkle is the recipient of a Mellon Foundation Fellowship.     

Minimal impact of hepatic and renal impairment on plasma protein binding of lenvatinib,and identification of its major plasma binding protein

Plasma protein binding (PPB) can be different depending on the status of hepatic or renal functions. In this study, the PPB of lenvatinib was determined using equilibrium dialysis in plasma from healthy volunteers and from subjects with mild, moderate, or severe hepatic impairment or renal impairment. Plasma from these subjects, fortified with lenvatinib at four concentrations (20, 200, 500, or 1200 ng/ml), was dialysed against phosphate buffered saline (PBS), and then determinations of the total concentrations of lenvatinib in plasma and unbound concentrations in PBS were made. In addition, the binding of lenvatinib was determined in human serum albumin (HSA), α₁‐acid glycoprotein (AAG), and human γ‐globulin (HG) in order to identify major binding proteins in human plasma. The PPB of lenvatinib in subjects with HI or RI ranged from 97.5% to 98.2% in hepatic impairment and 98.0% to 98.4% in renal impairment, which was similar to that of healthy volunteers. The binding of lenvatinib to HSA, AAG, and HG was 96.6%–97.1%, 46.4%–69.9%, and 19.1%–23.9%, respectively. These findings suggest that lenvatinib mainly binds to HSA and neither renal nor hepatic impairment impacts the PPB of lenvatinib.     

Effect of plasma protein and tissue binding on the time course of drug concentration in plasma

We have studied by digital computer simulation the effect of concentration-dependent plasma protein and tissue binding on the time course of drug concentrations (both unbound and total) in plasma following rapid injection of a drug whose elimination rate is proportional to either free or total drug concentration in plasma, assuming instantaneous equilibration of the drug between vascular and nonvascular spaces. The following observations were made when elimination rate was assumed to be a function of free drug concentration: (a) when plasma protein binding is nonlinear and there is either no tissue binding or linear tissue binding, log concentration-time plots of free drug are always concave whereas such plots for total (sum of free and bound) drug can be convex, almost linear, or concave (apparently biexponential) depending on the plasma protein binding parameters relative to the initial concentration; (b) linear tissue binding in association with nonlinear plasma protein binding can reduce the concavity or enhance the convexity of log total concentration-time plots. When drug elimination rate was assumed to be a function of total concentration in plasma, nonlinear plasma protein binding in association with linear or no tissue binding yielded convex log total concentration-time plots which could sometimes be described by Michaelis-Menten kinetics. In general, drug concentration-dependent changes in the apparent volume of distribution resulting from nonlinear plasma protein and (where applicable) tissue binding have a pronounced effect on the slope of log total plasma concentration- time plots. It appears that under clinically realistic conditions an otherwise marked curvature of such plots, due to nonlinear plasma protein binding, may in fact be dampened or overcome by linear tissue binding.This work was supported in part by Grant GM-20852 from the National Institute of General Medical Sciences, National Institutes of Health.     

Comparative protein binding, stability and degradation of satraplatin, JM118 and cisplatin in human plasma in vitro

1. Satraplatin is an investigational orally administered platinum-based antitumour drug. The present study compared the plasma protein binding, stability and degradation of satraplatin with that of its active metabolite JM118 and cisplatin. 2. The platinum complexes were incubated in human plasma for up to 2 h at 37 degrees C and quantified in plasma fractions by inductively coupled plasma-mass spectrometry on- or off-line to high-performance liquid chromatography. 3. All three platinum drugs became irreversibly bound to plasma proteins and showed negligible reversible protein binding. They were also unstable in plasma and generated one or more platinum-containing degradation products during their incubation. However, the three platinum complexes differed in the kinetics of their instability and protein binding, as well as in the number of degradation products formed during their incubation. 4. In conclusion, the plasma protein binding, instability and degradation of satraplatin and its active metabolite JM118 are qualitatively similar to that of cisplatin and other clinically approved platinum-based drugs. Quantitative differences in their irreversible protein binding and degradation were related to their respective physiochemical properties and bioactivation mechanisms.     

In‐situ absorption,protein binding and pharmacokinetic studies of S002‐853, a novel antidiabetic and antidyslipidaemic flavone derivative in rats

Objectives The aim of the study was to investigate the in‐situ absorption kinetics, plasma protein binding and pharmacokinetic characteristics of a novel synthetic flavone derivative, S002‐853, which shows pronounced antidiabetic and antidyslipidaemic activity. Methods Quantification of S002‐853 in plasma was performed by the LC‐MS/MS method and in‐situ sample analysis was carried out by the HPLC‐UV method. Key findings The absorption rate constant was 0.274/h in a mild alkaline environment, which S002‐853 experiences in the intestine following oral dose administration. Plasma protein binding was found to be 26.37 ± 2.58% at a concentration of 1 μg/ml. The pharmacokinetic parameters were determined in male rats after administration of a single 40 mg/kg oral dose and 10 mg/kg intravenous dose. The peak plasma concentration (C_max) was found to be 60.93 ng/ml at 8 h after oral administration. Irregular concentration–time profiles with secondary peaks were observed after oral dose administration. The elimination half‐life of the compound was 19.56 h and 16.30 h after oral and intravenous doses, respectively. Comparison of the AUC after oral and intravenous dosing of S002‐853 indicates that only about 29.48% (bioavailability) of the oral dose reaches the systemic circulation. Conclusions In‐situ study of S002‐853 shows slow absorption from the gastrointestinal tract. S002‐853 also shows low plasma protein binding. The pharmacokinetic parameters after oral and intravenous dose reveal low oral bioavailability and high mean residence time.     

盐酸去氢骆驼蓬碱血浆蛋白结合率的测定

目的:测定盐酸去氢骆驼蓬碱的血浆蛋白结合率.方法:采用超滤法和高效液相色谱法对盐酸去氢骆驼蓬碱的血浆蛋白结合率进行测定.结果:盐酸去氢骆驼蓬碱与小牛血清白蛋白、人血清白蛋白和正常人血浆的蛋白结合率分别为( 74.6 ± 9.8 )%、( 69.1 ± 8.7 )%、( 87.1 ± 5.3 )%.结论:盐酸去氢骆驼蓬碱与血浆蛋白具有中等强度的结合.     

西瑞香素与大鼠血浆蛋白结合率的测定

目的采用HPLC法对西瑞香素与大鼠血浆蛋白结合率进行研究。方法采用平衡透析法,结合HPLC法测定西瑞香素的大鼠血浆蛋白结合率。结果西瑞香素在低(0.50 mg.L-1)、中(1.0 mg.L-1)、高(2.0 mg.L-1)3个质量浓度下,其血浆蛋白结合率分别为(91.7±1.8)%、(91.6±1.4)%和(90.7±0.81)%。结论西瑞香素具有较强的血浆蛋白结合率。