Human subcutaneous tissue distribution of fluconazole: comparison of microdialysis and suction blister techniques

AIMS: To investigate uptake of fluconazole into the interstitial fluid of human subcutaneous tissue using the microdialysis and suction blister techniques. METHODS: A sterile microdialysis probe (CMA/60) was inserted subcutaneously into the upper arm of five healthy volunteers following an overnight fast. Blisters were induced on the lower arm using gentle suction prior to ingestion of a single oral dose of fluconazole (200 mg). Microdialysate, blister fluid and blood were sampled over 8 h. Fluconazole concentrations were determined in each sample using a validated HPLC assay. In vivo recovery of fluconazole from the microdialysis probe was determined in each subject by perfusing the probe with fluconazole solution at the end of the 8 h sampling period. Individual in vivo recovery was used to calculate fluconazole concentrations in subcutaneous interstitial fluid. A physiologically based pharmacokinetic (PBPK) model was used to predict fluconazole concentrations in human subcutaneous interstitial fluid. RESULTS: There was a lag-time (approximately 0.5 h) between detection of fluconazole in microdialysate compared with plasma in each subject. The in vivo recovery of fluconazole from the microdialysis probe ranged from 57.0 to 67.2%. The subcutaneous interstitial fluid concentrations obtained by microdialysis were very similar to the unbound concentrations of fluconazole in plasma with maximum concentration of 4.29 +/- 1.19 microg ml(-1) in subcutaneous interstitial fluid and 3.58 +/- 0.14 microg ml(-1) in plasma. Subcutaneous interstitial fluid-to-plasma partition coefficient (Kp) of fluconazole was 1.16 +/- 0.22 (95% CI 0.96, 1.35). By contrast, fluconazole concentrations in blister fluid were significantly lower (P < 0.05, paired t-test) than unbound plasma concentrations over the first 3 h and maximum concentrations in blister fluid had not been achieved at the end of the sampling period. There was good agreement between fluconazole concentrations derived from microdialysis sampling and those estimated using a blood flow-limited PBPK model. CONCLUSIONS: Microdialysis and suction blister techniques did not yield comparable results. It appears that microdialysis is a more appropriate technique for studying the rate of uptake of fluconazole into subcutaneous tissue. PBPK model simulation suggested that the distribution of fluconazole into subcutaneous interstitial fluid is dependent on tissue blood flow.     

Muscle distribution of antimicrobial agents after a single intravenous administration to rats

The purpose of this study was to evaluate the distribution of three fluoroquinolones (pazufloxacin, ciprofloxacin and ofloxacin) and a beta-lactam, ceftazidime in the tissue interstitial and intracellular spaces after a single intravenous administration to rats based on muscle microdialysis. The unbound concentration in the tissue interstitial fluid (C(isf,u)) after administration was estimated from the concentration in the dialysate by muscle microdialysis, the in vitro permeability rate constant, and the previously reported effective dialysis coefficient. The C(isf,u)s of pazufloxacin, ciprofloxacin, ofloxacin and ceftazidime in the muscle were close to their unbound concentrations in the venous plasma. These results were consistent with ones previously obtained at steady state. Based on these results, the total concentration in the tissue interstitial fluid (C(isf)) was calculated from the ratio of plasma protein binding, the plasma concentration, and previously reported interstitial-to-plasma albumin ratio in muscle of rats. The calculated C(isf) was compared with the muscle concentration (C(m)) obtained using the homogenized tissue. The C(isf) of ceftazidime was higher than the C(m). The C(isf) of pazufloxacin was found to be almost equal to its C(m). The C(isf)s of ciprofloxacin and ofloxacin were lower than their C(m)s with the exception of the values at 5 min after administration. These results indicate that ceftazidime is mainly distributed in the interstitial space of the muscle, that pazufloxacin is distributed equally in both the interstitial space and the tissue cells, and that ciprofloxacin and ofloxacin are mainly distributed in the tissue cells rather than the interstitial space.     

Penetration of piperacillin and tazobactam into pneumonic human lung tissue measured by in vivo microdialysis

OBJECTIVES: The pharmacokinetic profile of antibiotics at the site of anti-infective action is one of the most important determinants of drug response, since it correlates with antimicrobial effect. Up to now, only limited information on the lung tissue pharmacokinetics of antibiotic agents has been available. The aim of this study was to measure, using a new microdialysis-based approach, antibiotic penetration into the extracellular space fluid of pneumonic human lung parenchyma. PATIENTS AND METHODS: The lung penetration of a combination of piperacillin and tazobactam, substances with low protein binding, was determined in five patients suffering from pneumonia and metapneumonic pleural empyema. The condition was treated by decortication after lateral thoracotomy. Intra-, or post-operatively, respectively, two microdialysis probes were inserted into pneumonic lung tissue, and into healthy skeletal muscle to obtain reference values. Serum and microdialysis samples were collected at 20-min intervals for at last 8 h following i.v. administration of a single dose of 4 g piperacillin and 500 mg tazobactam. RESULTS: The mean free interstitial concentration profiles of piperacillin in infected lung tissue and serum showed a maximal tissue concentration (Cmax) of 176.0 +/- 105.0 mg l-1 and 326.0 +/- 60.6 mg l-1, respectively. The mean AUC (area under the curve) for infected lung tissue was 288.0 +/- 167.0 mg.h l-1 and for serum 470.0 +/- 142.0 mg.h l-1. There was a statistically significant difference between AUC (lung) and AUC (serum) (P = 0.018) as well as between AUC (lung) and AUC (muscle) (P = 0.043). The intrapulmonary concentrations of piperacillin and tazobactam exceeded the minimum inhibitory concentrations (MIC) for most relevant bacteria for 4-6 h. The procedure was well tolerated by all patients and no adverse events or microdialysis-associated side-effects were observed. CONCLUSION: This microdialysis technique enabled continuous tissue pharmacokinetic measurement of free, unbound anti-infective agents in the lung tissue of patients with pneumonia. The present data corroborate the use of piperacillin and tazobactam in the treatment of lung infections caused by extracellular bacteria and demonstrate the distribution of piperacillin and tazobactam in the interstitial space of pneumonic lung tissue.     

Validation of microdialysis sampling for oral availability studies by means of a new ganciclovir prodrug

Microdialysis sampling was validated for oral availability studies using ganciclovir (9-(1, 3-dihydroxy-2-propoxymethyl) guanine) and a ganciclovir prodrug (9-(1-L-valyloxy-3-octadecanoyloxy-prop-2-oxymethyl) guanine). Three different techniques were used in the study; microdialysis, blood and urinesampling. The oral uptake (11+/-2%) and the urinary recovery (106+/-5%) were determined. Animals given ganciclovir subcutaneously were subject either to microdialysis and blood sampling or to microdialysis alone. There was no significant difference between microdialysis and blood sampling in terms of blood concentration data, CL, Vd, half-life or AUC by means of Student's t-test. The oral bioavailability of the prodrug was 40+/-7% estimated from microdialysis sampling data and 48+/-4% estimated from urine sampling data. It is concluded that microdialysis is a valid method to use in pharmacokinetic studies of oral availability as well as for basic pharmacokinetic parameter estimation.     

Pharmacokinetics and Determination of Tumor Interstitial Distribution of a Therapeutic Monoclonal Antibody Using Large-Pore Microdialysis

R7072 is a fully human monoclonal antibody (mAb) exerting anti-tumor activity via blockade of insulin like growth factor 1 receptor. The tumoral interstitial concentrations are anticipated to be better surrogates of active site concentrations than commonly used serum concentrations for pharmacokinetic-pharmacodynamic correlation of anti-tumor mAbs. Previously, a large-pore microdialysis technique for measuring tissue interstitial concentrations of R7072 in non-tumor bearing mice was established. In the current studies, the serum pharmacokinetics of R7072 were assessed and tissue interstitial concentrations were measured by large-pore microdialysis following intravenous and intraperitoneal administration of R7072 in tumor bearing mice. R7072 exhibited nonlinear pharmacokinetics in the studied dose range. Tumor and subcutaneous interstitial concentration data suggested some delay in tissue distribution after dosing. A dose-dependent increase in the ratio of tumor interstitial to serum concentration was observed indicating target-mediated drug disposition in tumor tissue. However, subcutaneous interstitial to serum concentration ratios were similar across the doses as observed previously in non-tumor bearing mice. A two-compartment population pharmacokinetic model with subcutaneous and tumor as open-loop compartments comprising of parallel linear and non-linear elimination from serum, linear disposition from subcutaneous interstitium and non-linear disposition from tumor interstitium was developed to simultaneously describe the pharmacokinetic data from all matrices.     

Evaluation of gatifloxacin penetration into skeletal muscle and lung by microdialysis in rats

This study aimed to investigate gatifloxacin distribution into skeletal muscle and lung interstitial fluid by microdialysis and to correlate free tissue and free plasma levels of the drug. Microdialysis recoveries were determined in vitro by extraction efficiency and retrodialysis at 80, 160 and 400 ng/ml resulting in 33.5+/-1.3%, 33.1+/-1.2%, 31.8+/-2.7% and 31.4+/-2.6%, 33.1+/-2.2%, 30.6+/-3.3%, respectively. In vivo recovery by retrodialysis in Wistar rats' skeletal muscle and lung were 29.1+/-1.0% and 30.7+/-1.4%, respectively. The recovery was constant and independent on the method or media used. Gatifloxacin tissue penetration was investigated after intravenous dosing of 6 mg/kg to Wistar rats. Free skeletal muscle, lung and plasma profiles were virtually superimposable resulting in similar area under the curve (AUC(0-9)) of 3888+/-734 ng h/ml, 4138+/-1071 ng h/ml and 3805+/-577 ng h/ml, respectively (alpha=0.05). The tissue distribution factors were 1.02 and 1.08 for muscle and lung relative to plasma. In conclusion, free plasma levels are a good surrogate for gatifloxacin active levels at the infection site.     

Assessment of in vitro and in vivo recovery of gallamine using microdialysis

The application of microdialysis technique for the investigation of pharmacokinetics and pharmacodynamics of drugs requires careful assessment of probe performance to ensure validity of the data obtained using this technique. The aim of this study was to establish and validate the microdialysis technique for investigation of the pharmacokinetics and pharmacodynamics of the neuromuscular blocker, gallamine. In vitro recovery of gallamine from the microdialysis probe when different perfusion flow rates were employed was evaluated leading to selection of a flow rate of 2 microl/min with 15-min sampling intervals for the subsequent studies. In vitro recovery of gallamine from the microdialysis probe was independent of concentration, stable over an 8-h period and reproducible. Comparable in vitro recoveries were obtained by different established approaches including recovery estimation by gain, loss and the zero-net flux (ZNF) method. Recovery by loss was used to study the in vivo recovery of gallamine from rat muscle tissue. The in vivo recovery was stable over a 5.5-h sampling period. In vitro performance of the probe subsequent to the in vivo study remained stable supporting reusage of the probe. These data highlight the importance of a systematic examination of microdialysis probe validation.     

Skin and soft tissue concentrations of tedizolid (formerly torezolid), a novel oxazolidinone, following a single oral dose in healthy volunteers

Plasma concentrations of antimicrobial drugs have long been used to correlate exposure with effect, yet one cannot always assume that unbound plasma and tissue concentrations are similar. Knowledge about unbound tissue concentrations is important in the development of antimicrobial drugs, since most infections are localised in tissues. Therefore, a clinical microdialysis study was conducted to evaluate the distribution of tedizolid (TR-700), the active moiety of the antimicrobial prodrug tedizolid phosphate (TR-701), into interstitial fluid (ISF) of subcutaneous adipose and skeletal muscle tissues following a single oral 600 mg dose of tedizolid phosphate in fasting conditions. Twelve healthy adult subjects were enrolled. Two microdialysis probes were implanted into the thigh of each subject, one into the vastus medialis muscle and one into subcutaneous adipose tissue. Probes were calibrated using retrodialysis. Dialysate samples were collected every 20 min for 12h following a single oral dose of 600 mg tedizolid phosphate, and blood samples were drawn over 24h. Unbound tedizolid levels in plasma were similar to those in muscle and adipose tissue. The ratios of unbound (free) AUC in tissues over unbound AUC in plasma (fAUC(tissue)/fAUC(plasma)) were 1.1 ± 0.2 and 1.2 ± 0.2 for adipose and muscle tissue, respectively. The median half-life was 8.1, 9.2 and 9.6h for plasma, adipose tissue and muscle tissue, respectively. Mean protein binding was 87.2 ± 1.8%. The study drug was very well tolerated. The results of this study show that tedizolid distributes well into ISF of adipose and muscle tissues. Unbound levels of tedizolid in plasma, adipose tissue and muscle tissue were well correlated. Free plasma levels are indicative of unbound levels in the ISF of muscle and adipose tissues.     

Application of Microdialysis in Pharmacokinetic Studies

The objective of this review is to survey the recent literature regarding the various applications of microdialysis in pharmacokinetics. Microdialysis is a relatively new technique for sampling tissue extracellular fluid that is gaining popularity in pharmacokinetic and pharmacodynamic studies, both in experimental animals and humans. The first part of this review discusses various aspects of the technique with regard to its use in pharmacokinetic studies, such as: quantitation of the microdialysis probe relative recovery, interfacing the sampling technique with analytical instrumentation, and consideration of repeated procedures using the microdialysis probe. The remainder of the review is devoted to a survey of the recent literature concerning pharmacokinetic studies that apply the microdialysis sampling technique. While the majority of the pharmacokinetic studies that have utilized microdialysis have been done in the central nervous system, a growing number of applications are being found in a variety of peripheral tissue types, e.g. skin, muscle, adipose, eye, lung, liver, and blood, and these are considered as well. Given the rising interest in this technique, and the ongoing attempts to adapt it to pharmacokinetic studies, it is clear that microdialysis sampling will have an important place in studying drug disposition and metabolism.     

Microdialysis for in vivo pharmacokinetic/pharmacodynamic characterization of anti-infective drugs

Inadequate tissue penetration of antibiotics can lead to therapeutic failure and bacterial resistance. Pharmacokinetic evaluation of antibiotics should therefore be based on tissue rather than serum concentrations. Over several years, tissue concentration data obtained by methods such as tissue biopsies have flawed the correct interpretation of antibiotic tissue distribution. Microdialysis--a semi-invasive catheter-based sampling technique--has been employed for the in vivo measurement of antibiotic tissue pharmacokinetics. Owing to selective access to the target site for most anti-infective drugs, microdialysis satisfies regulatory requirements for pharmacokinetic distribution studies and might become a reference technique for tissue distribution studies in the near future. Furthermore, microdialysis might contribute to the definition of meaningful surrogate markers for antibiotic efficiency during drug development.     

Norepinephrine measurement in the isolated, blood-perfused papillary muscle of the dog by using ex vivo microdialysis

Subendocardial interstitial norepinephrine (NE) was measured in the isolated, blood-perfused papillary muscle (PM) preparation of the dog by using ex vivo microdialysis. A microdialysis fiber was inserted into the base of the PM and perfused with Ringer's solution at a rate of 1 microl/min. Dialyzed NE concentrations were measured by high-performance liquid chromatography with an electrical detector. The basal dialyzed NE concentration from the subendocardial interstitium was 1.74+/-0.24 nM (n = 12, mean +/- SE). When the anterior septal artery was occluded for 5 min, the dialyzed NE concentration from the subendocardial interstitium 0-5 min after occlusion increased to 2.90 +/-0.61 nM (n = 12, p<0.05 versus before occlusion). When desmethylimipramine, a neuronal uptake 1 inhibitor, was administered into the anterior septal artery at a rate of 100 nmol/ml for 30 min, dialyzed NE concentration substantially increased from 1.55+/-0.33 to 2.63+/-0.34 nM (n = 3, p<0.05). Likewise, the occlusion-induced increase in dialyzed NE was augmented to 3.75+/-0.90 nM by desmethylimipramine infusion into the anterior septal artery. These observations suggested that the ex vivo microdialysis of the isolated, blood-perfused PM preparation of the dog is a sensitive method for measuring the subendocardial interstitial NE and that coronary artery occlusion increases the subendocardial interstitial NE as early as within 5 min.     

Microdialysis: current applications in clinical pharmacokinetic studies and its potential role in the future

Microdialysis is a probe-based sampling method, which, if linked to analytical devices, allows for the measurement of drug concentration profiles in selected tissues. During the last two decades, microdialysis has become increasingly popular for preclinical and clinical pharmacokinetic studies. The advantage of in vivo microdialysis over traditional methods relates to its ability to continuously sample the unbound drug fraction in the interstitial space fluid (ISF). This is of particular importance because the ISF may be regarded as the actual target compartment for many drugs, e.g. antimicrobial agents or other drugs mediating their action through surface receptors. In contrast, plasma concentrations are increasingly recognised as inadequately predicting tissue drug concentrations and therapeutic success in many patient populations. Thus, the minimally invasive microdialysis technique has evolved into an important tool for the direct assessment of drug concentrations at the site of drug delivery in virtually all tissues. In particular, concentrations of transdermally applied drugs, neurotransmitters, antibacterials, cytotoxic agents, hormones, large molecules such as cytokines and proteins, and many other compounds were described by means of microdialysis. The combined use of microdialysis with non-invasive imaging methods such as positron emission tomography and single photon emission tomography opened the window to exactly explore and describe the fate and pharmacokinetics of a drug in the body. Linking pharmacokinetic data from the ISF to pharmacodynamic information appears to be a straightforward approach to predicting drug action and therapeutic success, and may be used for decision making for adequate drug administration and dosing regimens. Hence, microdialysis is nowadays used in clinical studies to test new drug candidates that are in the pharmaceutical industry drug development pipeline.     

Blood-to-muscle distribution and urinary excretion of higenamine in rats

Higenamine is a β₂-agonist that has been prohibited in sports by the World Anti-Doping Agency. Higenamine could potentially promote anabolism and lipolysis; however, its crucial pharmacokinetics data, particularly muscle distribution, remain unavailable. The present study aims to investigate the blood-to-muscle distribution as well as the urinary excretion of higenamine in laboratory rats. In the first experiment, the microdialysis technique was employed to continuously measure free, protein-unbound concentrations in blood and muscle for 90 min (sampling at a 5-min interval) after rats received IV infusion of higenamine. The mean half-lives of higenamine in blood and muscle were 17.9 and 19.0 min, respectively. The blood-to-muscle distribution ratio (AUC_muscle/AUC_blood) of higenamine was estimated to be 22%. In the second experiment, rats were orally administered with a single-dose higenamine, and their urine samples were profiled at a 12-h interval for up to 48 h. Results showed only a small portion of total consumption (1.44%, ranging 0.71%–2.50%) was excreted in the urine. Among these time points, about 43% cumulative amount of higenamine was eliminated within the first 12 h. Our data suggested that one-quarter of the unbound higenamine rapidly penetrates from the vessels into muscle, distributes to the interstitial fluid, then eliminates from the rat in a short span of time. The muscle tissue is likely to have a low binding affinity for higenamine, and renal excretion plays a minor role in its elimination. Together, our findings provide valuable pharmacokinetics data that may gain deeper insights into higenamine's role in skeletal muscle functions.     

Microdialysis in peripheral tissues

The objective of this review is to survey the recent literature regarding the applications of microdialysis in pharmacokinetic studies and facilitating many other studies in peripheral tissues such as muscle, subcutaneous adipose tissue, heart, lung, etc. It has been reported extensively that microdialysis is a useful technique for monitoring free concentrations of compounds in extracellular fluid (ECF), and it is gaining popularity in pharmacokinetic and pharmacodynamic studies, both in experimental animals and humans. The first part of this review discusses the use of microdialysis technique for ECF sampling in peripheral tissues in animal studies. The second part of the review describes the use of microdialysis for ECF sampling in peripheral tissues in human studies. Microdialysis has been applied extensively to measure both endogenous and exogenous compounds in ECF. Of particular benefit is the fact that microdialysis measures the unbound concentrations in the peripheral tissue fluid which have been shown to be responsible for the pharmacological effects. With the increasing number of applications of microdialysis, it is obvious that this method will have an important place in studying drug pharmacokinetics and pharmacodynamics.     

血液微渗析技术研究酮洛芬在大鼠体内的药代动力学

目的考察酮洛芬微渗析体内外回收率及影响因素，研究酮洛芬静脉给药后非结合型药物在大鼠体内的药代动力学。方法大鼠颈静脉插入探针后，依次用不同浓度的灌注液对探针进行灌注，测定酮洛芬体内回收率及非结合型酮洛芬在大鼠体内的药代动力学。以高效液相色谱法测定微渗析液中药物浓度。体外回收率的测定采用浓差法。结果增量法及减量法测定的回收率一致。以浓差法测定的体外回收率为28.75%；反渗析法测定体内回收率为(40.3±2.7)%。酮洛芬静脉给药后非结合型药物的T_1/2，AUC和CL分别为(181±16) min，(112±27) μg·min·mL^-1和(0.22±0.05) min^-1。结论血液微渗析技术可用于研究非结合型酮洛芬在大鼠体内的药代动力学。     

Validation of a new intraarterial microdialysis shunt probe for the estimation of pharmacokinetic parameters

The aim of our study was to compare pharmacokinetic parameters of a highly bound protein drug, irbesartan, obtained from microdialysis data (MD) of arterial blood and conventional blood samples (BS). A new vascular shunt microdialysis probe was inserted into the carotid artery and one femoral vein was cannulated for i.v. administration of irbesartan. Microdialysis samples were collected every 15 min. Blood samples were taken every 15 min. Levels of drug were measured by HPLC. Pharmacokinetic parameters were estimated using TOPFIT program. Corrected MD were compared with BS taken at same time to determine protein binding. The irbesartan protein binding did not change during the experiment. The estimated Ke from MD and BS were similar (MD: 1.8+/-0.3 h(-1), n=5; BS: 1.7+/-0.2 h(-1), n=5). After protein binding correction for the MD, the estimated values of volume of distribution (Vd) (MD: 1.2+/-0.4 l, n=5; BS: 1.1+/-0.4 l, n=5), clearance (Cl) (MD: 32.3+/-7.3 ml min(-1), n=5; BS: 30.7+/-8.2 ml min(-1), n=5) and AUC (MD: 7.7+/-3.2 microg x ml(-1) h, n=5; BS: 8.8+/-3.4 microg x ml(-1) h, n=5) were similar between MD and BS. In conclusion, these results show that our new probe inserted in the carotid artery provides accurate MD to estimate pharmacokinetic parameters of a highly bound protein drug like irbesartan. On the other hand, MD were also useful to the in vivo study of drug protein binding and saturation in protein binding.     

Pharmacokinetics of scopolamine in serum and subcutaneous adipose tissue in healthy volunteers

OBJECTIVE: The objective was to develop a microdialysis set-up to measure the concentration-time course of scopolamine in the interstitium of subcutaneous adipose tissue. MATERIALS AND METHODS: Six healthy male volunteers were eligible for data analysis. Subjects received 0.5 mg scopolamine as a 15-minute intravenous infusion. Microdialysis samples from interstitial space fluid of subcutaneous adipose tissue and blood samples were taken at predefined intervals over a period of 360 minutes. Scopolamine concentrations were measured by liquid chromatography-tandem mass spectrometry (LC-MS-MS). RESULTS: High inter-individual variability was observed in all pharmacokinetic parameters. The mean peak serum concentration (C(max)) of 6.5 +/- 3.9 ng/ml (data in mean +/- SD) was attained after 15 +/- 3 minutes (t(max)), whereas in dialysate, a mean peak concentration of 2.7 +/- 1.7 ng/ml was measured after 27 +/- 8 minutes. The ratio of the area under the concentration versus time curve from 0-360 min for interstitium (AUC(interstitium 0-360 min0) to the AUC for serum (AUC(serum 0-360 min)) was 0.96 +/- 0.7. The elimination half-life of scopolamine was 121 +/- 85 minutes in serum and 166 +/- 117 minutes in dialysate. Values for total clearance and volume of distribution in serum were 99.1 +/- 35.0 1/h and 188 +/- 76 1, respectively. CONCLUSIONS: In the present study, we were able to define a microdialysis set-up, which allows for the measurement of scopolamine concentrations in target tissues. In addition, we demonstrated that the concentrations of scopolamine in subcutaneous adipose tissue resemble closely the concentration-time course in serum of healthy volunteers.     

In Vivo Microdialysis Sampling for Pharmacokinetic Investigations

In vivo microdialysis sampling coupled to liquid chromatography was used to study acetaminophen disposition in anesthetized rats. The pharmacokinetics of acetaminophen and its sulfate and glucuronide metabolites were determined using both microdialysis sampling and collection of whole blood. For microdialysis, samples were continuously collected for over 5 hr without fluid loss using a single experimental animal. Microdialysis sampling directly assesses the free drug concentration in blood. The pharmacokinetic results obtained with microdialysis sampling were the same as those obtained from blood collection. The administration of heparin, necessary when collecting blood samples, was found to double the elimination half-life of acetaminophen. Microdialysis sampling is a powerful tool for pharmacokinetic studies, providing accurate and precise pharmacokinetic data.     

Pharmacokinetics, tissue distribution and excretion of vinflunine.

The plasma pharmacokinetics, tissue distribution, excretion and binding to plasma proteins of vinflunine, were investigated after intravenous (iv) administration. We obtained plasma profiles after iv administration of vinflunine at the doses of 3.5, 7 and 14 mg/kg in rats. The t1/2 values for vinflunine were estimated to be 18.38+/-1.20, 17.05+/-0.77, 18.35+/-1.57 h, and the mean AUC0-t values were 3.48+/-0.38, 6.54+/-0.68, 12.79+/-2.93 microg x h/ml, respectively. Of the various tissues tested, vinflunine was widely distributed into tissues, with the highest concentrations of vinflunine being found in well perfused organs. Maximal concentration of vinflunine was reached at 0.5 h postdose in the majority of tissues. In tumor-bearing mice, the similar pattern of tissue distribution was observable, except that vinflunine can be distributed into tumor. The binding of vinflunine in human and rat plasma proteins were 39.6% and 58.4% respectively. Within 96 h after administration, 9.58%, 15.36% and 0.71% of the given dose was excreted in urine, feces and bile, respectively. In conclusion, Vinflunine had a longer terminal half-life, a wide tissue distribution and less than 25% of the given dose was excreted as unchanged drug, suggesting metabolism as a major style of elimination.     

PHARMACOKINETICS OF AZITHROMYCIN IN LUNG TISSUE, BRONCHIAL WASHING, AND PLASMA IN PATIENTS GIVEN MULTIPLE ORAL DOSES OF 500 AND 1000 MG DAILY

The present study compares the pharmacokinetics of azithromycin in plasma, lung tissue, and bronchial washing after oral administration of 500 mg (standard dose) versus 1000 mg daily for 3 days. Samples were taken during surgery for lung resection at various time points up to 204 h after the last drug dose, and azithromycin levels were analyzed by HPLC method. Azithromycin was widely distributed within the lower respiratory tract; sustained concentrations of the drug were detectable at the last sampling time (204 h) in lung tissue and bronchial washing, with long terminal half-lives of 132.86 and 74.32 h at 500 mg daily and 133.32 and 70.5 h at 1000 mg daily, respectively. Doubling the drug dose resulted in a remarkable increase in lung area under the curve (AUC, 1318 hx microg g(-1) vs 2502 hx microg g(-1)) and peak tissue concentration (9.13+/-0.53 microg g(-1) vs 17.85+/-2.4 microg g(-1)). In addition to this, enhanced azithromycin penetration from plasma into bronchial secretion and lung tissue was evidenced by the increase in the ratio of AUC(bronchial washing) versus AUC(plasma) (2.96 vs 5.27 at 500 and 1000 mg, respectively) and AUC(lung) versus AUC(plasma) (64.35 vs 97.73 at 500 and 1000 mg, respectively). In conclusion, the exposure of lung and bronchial washing to azithromycin is increased by doubling the dose, which results in favorable pharmacokinetic profile of the drug in the lower respiratory tract.