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.     

Pharmacokinetics of piperacillin and tazobactam in plasma and subcutaneous interstitial fluid in critically ill patients receiving continuous venovenous haemodiafiltration

This prospective pharmacokinetic study aimed to describe plasma and interstitial fluid (ISF) pharmacokinetics of piperacillin and tazobactam in critically ill patients on continuous venovenous haemodiafiltration (CVVHDF). Piperacillin/tazobactam (4 g/0.5 g) was administered every 8 h and CVVHDF was performed as a 3–3.5 L/h exchange using a polyacrylonitrile filter with a surface area of 1.05 m². Serial blood (pre- and post-filter), filtrate/dialysate, urine and ISF concentrations were measured. Subcutaneous tissue ISF concentrations were determined using microdialysis. A total of 407 samples were collected. Median peak plasma concentrations were 210.5 (interquartile range = 161.5–229.0) and 29.4 (27.9–32.0) mg/L and median trough plasma concentrations were 64.3 (49.0–68.9) and 12.3 (7.7–13.7) mg/L for piperacillin and tazobactam, respectively. The plasma elimination half-life was 6.4 (4.6–8.7) and 7.3 (4.6–11.8) h, volume of distribution 0.42 (0.29–0.49) and 0.32 (0.24–0.36) L/kg, total clearance 5.1 (4.2–6.2) and 3.8 (3.3–4.2) L/h and CVVHDF clearance 2.5 (2.3–3.1) and 2.5 (2.3–3.2) L/h for piperacillin and tazobactam, respectively. The tissue penetration ratio or ratio of area under the concentration–time curve of the unbound drug in ISF to plasma (unbound AUC_ISF/AUC_plasma) was ca. 1 for both piperacillin and tazobactam. This is the first report of concurrent plasma and ISF concentrations of piperacillin and tazobactam during CVVHDF. For the CVVHDF settings used in this study, a dose of 4.5 g piperacillin/tazobactam administered evry 8 h resulted in piperacillin concentrations in plasma and ISF >32 mg/L throughout most of the dosing interval.     

The interaction between i.v. theophylline and chronic oral dosing with slow release nifedipine in volunteers.

Eight healthy volunteers received a 5 min i.v. infusion of lysine theophylline, equivalent to 197 mg anhydrous theophylline, both before (day 1) and during (day 5) steady state chronic oral dosing with slow release nifedipine 20 mg 12 hourly. A theophylline pharmacokinetic profile was performed on day 1 and day 5 and a nifedipine pharmacokinetic profile was performed on day 4 and day 5. The greatest difference in serum theophylline concentrations was seen at the first sampling time (5 min after completion of the infusion) with a mean concentration of 9.9 mg l-1 during nifedipine administration and 14.6 mg l-1 with theophylline alone. Thereafter, the difference fell to approximately 1 mg l-1 until 6 h when they became almost identical. Repeated measures analysis of variance using the theophylline serum concentrations at each of ten time points over 8 h as the repeated measures showed a small but significant effect of nifedipine (F(1,151) = 7.0, P less than 0.01) on serum theophylline concentrations. Mean volume of distribution (V) rose from 0.33 +/- 0.07 to 0.39 +/- 0.06 1 kg-1 corrected body weight (CBW) in the presence of nifedipine (t = 2.23, P = 0.052). Theophylline clearance, area under the curve to 8 h AUC (0-8), area under the curve to infinity AUC (0-infinity) and elimination half-life (t1/2) did not change appreciably. No statistically significant changes in nifedipine pharmacokinetics occurred in the presence of theophylline.     

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.     

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.     

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.     

The effect of tazobactam on the pharmacokinetics and the antibacterial activity of piperacillin in dogs

Tazobactam (Tazosyn®) is a novel β-lactamase inhibitor belonging to a class of penicillanic acid sulfones. Tazobactam was developed to be used in combination with piperacillin against β-lactamase producing microorganisms. The current study was conducted to determine the effect of tazobactam on the pharmacokinetics and the antibacterial activity of piperacillin in dogs. Three groups of animals consisting of three beagle dogs per group were used for the study. The animals were administered a single I.V. dose of tazobactam (40 mg/kg), piperacillin (320 mg/kg) or the combination in a ratio of 1:8 (tazobactam: piperacillin). Blood samples were drawn at different time intervals. The serum bactericidal titers (SBT) were determined against a plasmid-mediated β-lactamase producing strain of Eschericia coli (LSU-80-8). Serum concentrations of both compounds were determined by high performance liquid chromatography.The mean serum bactericidal titers of the combination was 1:16 against this piperacillin resistant strain of E. coli, 2 h after dosing as compared to less than 1:2 when piperacillin was given alone at the same dose. This indicates that serum concentrations greater than 187 μg/ml of piperacillin (SBT<1:2) were required to kill 99.9% of the piperacillin resistant E. coli inoculum (10⁶ CFU/ml) when piperacillin was given alone. However, when piperacillin was administered in combination with tazobactam, concentrations as low as 7 μg/ml of piperacillin and 2 μg/ml of tazobactam were sufficient to exhibit the same bactericidal activity. These results indicate an in-vivo synergistic effect of tazobactam on the piperacillin activity at this dosing ratio which lasted for approximately 5 h after dosing. The coadministration of tazobactam did not appear to affect the pharmacokinetic parameters of piperacillin. However, the elimination of tazobactam was significantly inhibited when coadministered with piperacillin, resulting in a reduction of the clearance (3.5 vs. 7.5 ml/min per kg) and prolongation of the half-life (43 vs. 31 min).     

Effect of probenecid and quinidine on the transport of alovudine (3'-fluorothymidine) to the rat brain studied by microdialysis

Microdialysis was used to sample extracellular unbound concentrations of alovudine in order to study the influence of well-known transport inhibitors (probenecid and quinidine) on the transport of alovudine between the blood and the brain extracellular fluid or whole brain tissue. The AUC (area under the time versus concentration curve) ratio brain extracellular fluid/serum was 0.17+/-0.036 after a subcutaneous injection of alovudine 25 mg/kg in rats treated with probenecid 25 mg/kg subcutaneous (n=5), which was not significantly different from the control group (AUC ratio 0.24+/-0.039). Perfusion through the microdialysis probe with probenecid 100 microM (n=4) also had no effect on the brain extracellular fluid/serum AUC ratio after alovudine 25 mg/kg subcutaneous. The AUC ratio brain extracellular fluid/serum was 0.085+/-0.009 after subcutaneous injection of alovudine 25 mg/kg in rats treated with quinidine 25 mg/kg intraperitoneally (n=8), which was significantly lower than the control group. However, the whole brain tissue concentration was not significantly different between control rats (n=5) and rats treated with quinidine (n=4) 1 hr after subcutaneous injection of alovudine 25 mg/kg (brain to serum ratios being 0.11+/-0.006 and 0.10+/-0.005 respectively). Finally, the microdialysis recovery of alovudine increased with increasing concentrations (10, 50, 250, 1250 microM) of alovudine in the perfusion fluid. The recovery of alovudine was increased in quinidine-treated rats but not in those given probenecid. Thus, probenecid does not significantly influence the concentration gradient of alovudine over the blood-brain barrier in the rat after systemic or after local administration, while quinidine lowered brain extracellular fluid concentration of alovudine, but not total brain tissue concentration. The mechanism behind this phenomenon is not yet known.     

Pharmacokinetics of SDZ RAD and cyclosporin including their metabolites in seven kidney graft patients after the first dose of SDZ RAD

AIMS: The aim of the study was to investigate the pharmacokinetics and metabolism of the new immunosuppressant SDZ RAD during concomitant therapy with cyclosporin in stable renal transplant patients. Furthermore, we studied the influence of SDZ RAD on the pharmacokinetics of cyclosporin at steady state levels. METHODS: SDZ RAD was administered orally in different doses (0.25-15 mg day-1) to seven patients, who were on standard cyclosporin-based immunosuppression. The blood concentrations of both drugs including their main groups of metabolites were measured simultaneously by LC/electrospray-mass spectrometry. RESULTS: The mean area under the blood concentration-time curve to 12 h (AUC(0,12 h)) was 4244 +/- 1311 microg l-1 h for cyclosporin before SDZ RAD treatment and 4683 +/- 1174 microg l-1 h (P = 0.106) on the day of SDZ RAD treatment (95% CI for difference -126, 1003). On both study days Cmax, and tmax of cyclosporin were not significantly different. The metabolite pattern of cyclosporin did not change. The pharmacokinetic data of SDZ RAD dose-normalized to 1 mg SDZ RAD were as follows: AUC(0,24 h): 35.4 +/- 13.1 microg l-1 h, Cmax: 7.9 +/- 2.7 microg l-1 and tmax: 1.5 +/- 0.9 h. The metabolites of SDZ RAD found in blood were hydroxy-SDZ RAD, dihydroxy-SDZ RAD, demethyl-SDZ RAD, and a ring-opened form of SDZ RAD. CONCLUSIONS: A single dose of SDZ RAD did not influence significantly the pharmacokinetics of cyclosporin. The most important metabolite of SDZ RAD was the hydroxy-SDZ RAD, its AUC(0,24 h) being nearly half that of the parent compound SDZ RAD.     

Pharmacokinetics of zidovudine and dideoxyinosine alone and in combination in children with HIV infection.

The pharmacokinetics of zidovudine (ZDV) and dideoxyinosine (ddI) were investigated following administration alone and in combination to children with symptomatic HIV disease. The children were studied on three separate occasions and received ZDV 200 mg m-2, ddI 100 mg m2 or a combination of ZDV 200 mg m-2 plus ddI 100 mg m-2. The administration of ddI did not significantly alter ZDV pharmacokinetics. The area under the curve (AUC) was 14.2 +/- 4.9 and 15.8 +/- 7.2 mumol l-1 h and elimination half-life (t1/2, z) was 1.4 +/- 0.4 and 1.2 +/- 0.2 h in the absence and presence of ddI respectively. The peak concentration (Cmax), time to peak (tmax) and apparent oral clearance (CL/F) were also unchanged. The administration of ZDV had no significant effect on ddI Cmax, tmax, t1/2,z, or CL/F, however the AUC was reduced by 19% (5.9 +/- 2.9 to 4.8 +/- 2.7 mumol l-1 h; P < 0.05). This study suggests that ZDV and ddI may be co-administered to children with symptomatic HIV disease without concern of a clinically relevant pharmacokinetic drug interaction.     

Liver blood flow, antipyrine clearance, and antipyrine metabolite formation clearance in patients with chronic active hepatitis and alcoholic cirrhosis.

Duplex scanning was used to measure liver blood flow (hepatic artery and main branches of the portal and hepatic veins) in six healthy subjects, five cirrhotic patients, and six hepatitis patients. Antipyrine clearance and formation clearances to its metabolites were also measured. Compared with healthy control subjects, cirrhotic patients had a lower hepatic vein blood flow (-76%, P < 0.05). This was due primarily to a lower portal vein blood flow (-36%, NS). A statistically significant difference in liver blood flow between patients with hepatitis and normal subjects was not detected. Antipyrine half-life, clearance, and the area under the serum drug concentration vs time curve were significantly different in cirrhotic patients compared with the healthy subjects (mean +/- s.d.-healthy controls: t1/2 = 13.7 +/- 3.0 h, CL = 30.0 +/- 8.6 ml h-1 kg-1, AUC = 549 +/- 139 mg l-1 h; cirrhotic patients: t1/2 = 32.4 +/- 1.7 h, CL = 12.3 +/- 2.1 ml h-1 kg-1, AUC = 1061 +/- 218 mg l-1 h; P < 0.008). Antipyrine half-life, clearance, and the area under the serum drug concentration vs time curve were not significantly different in hepatitis patients compared with the healthy subjects (hepatitis patients: t1/2 = 14.3 +/- 3.7 h, CL = 29.3 +/- 8.5 ml h-1 kg-1, AUC = 498 +/- 142 mg l-1 h). The volume of distribution of antipyrine was similar in all three groups of subjects.(ABSTRACT TRUNCATED AT 250 WORDS)     

The pharmacokinetics and pharmacodynamics of nifedipine at steady state during concomitant administration of cimetidine or high dose ranitidine.

Ranitidine may be used at doses of up to 300 mg twice daily in the healing of duodenal ulcers, and this study investigated the potential for a pharmacokinetic or pharmacodynamic interaction between nifedipine 10 mg three times daily and ranitidine 300 mg twice daily compared with cimetidine 800 mg daily and placebo in a randomised crossover study in 18 healthy male subjects. Twelve blood samples were taken on the fifth day in each treatment period and assayed for nifedipine by h.p.l.c. Pulse, blood pressure and ECG recordings were also taken. Cimetidine, but not ranitidine, produced significant changes in the pharmacokinetics of nifedipine at steady state. Mean +/- s.d. values of AUC were 105 +/- 40 micrograms l-1 for placebo treatment, 111 +/- 45 micrograms l-1 h for ranitidine and 211 +/- 64 micrograms l-1 h for cimetidine (P less than 0.001), and Cmax values were 33 +/- 14, 39 +/- 27 and 76 +/- 40 micrograms l-1 (P less than 0.001), respectively. Neither ranitidine nor cimetidine produced statistically significant changes in the pharmacological response to nifedipine.     

Naproxen pharmacokinetics in patients with rheumatoid arthritis during active polyarticular inflammation.

Patients with rheumatoid arthritis often have hypoalbuminaemia as a sign of disease activity. In view of the extensive binding of naproxen to albumin, the pharmacokinetics of total and unbound drug were studied in eight patients and eight healthy male volunteers during chronic intake of 500 mg twice daily. The area under the serum concentration-time curve of total naproxen during a dose interval, AUC (0,12), smaller in patients (641 +/- 101 mg l-1 h) than in volunteers (896 +/- 85 mg l-1 h; P less than 0.0001). The unbound naproxen AUCu (0,12) was larger in patients (1.9 +/- 0.9 mg l-1 h) than in volunteers (0.7 +/- 0.2 mg l-1 h; P less than 0.01). The higher unbound naproxen concentrations in patients were accompanied by an approximately 40% increase in apparent clearance/bioavailability (CL/F) and a 60% increase in volume of distribution (V/F). Both CL/F and V/F were inversely correlated with the individual serum albumin concentration (r = 0.76, P less than 0.001; r = -0.85, P less than 0.001, respectively). The high unbound naproxen concentration in the serum of patients with active rheumatoid arthritis and concomitant hypoalbuminaemia is not known to be accompanied by an increase in side effects and may be beneficial if anti-inflammatory effects correlate with unbound drug concentration.     

Pain-mediated altered absorption and metabolism of ibuprofen: an explanation for decreased serum enantiomer concentration after dental surgery

AIMS: Rapid onset of analgesia is essential in the treatment of acute pain. There is evidence that conditions of stress cause delayed and decreased pain relief from oral analgesic products through impaired absorption. The aim was to determine the effect of surgery for removal of wisdom teeth on the plasma concentration-time profile of ibuprofen enantiomers. METHODS: Racemic ibuprofen, 200 mg in one group (n=7) and 600 mg in another group (n=7) was administered 1 week before (control) and again after (test) surgical removal of wisdom teeth. Serum concentrations of ibuprofen enantiomers were measured for 6 h. RESULTS: During the control phase, S- and R-ibuprofen concentrations were within the suggested therapeutic range. Surgery resulted in a 2 h delay in the mean time to peak concentration, significant decreases in serum ibuprofen concentration following both doses, and a fall to sub-optimal serum concentrations following the 200 mg dose. During the first 2 h after the 200 mg dose, dental extraction resulted in a significant reduction of the area under serum drug concentration (AUC (0, 2 h) mg l-1 h) from 5.6+/-2.9 to 1.6+/-1.8 (P<0.01) and from 5.5+/-3.0 to 2.1+/-2.0 (P<0.05) for S and R-ibuprofen, respectively. Similar observations were made following the 600 mg dose for AUC (0, 2 h) of S-ibuprofen (from 14.2+/-6.1 to 7.2+/-5.5 mg l-1 h, P<0.05) with no significant difference for R-ibuprofen (from 14.4+/-9.5 to 5.8+/-7. 1). AUC (0, 6 h) was also significantly reduced by surgery. The pattern of stereoselectivity in serum ibuprofen concentration was reversed by surgery such that the S enantiomer was predominant in the control phase but not in the post-surgery phase, which is suggestive of reduced metabolic chiral inversion. CONCLUSIONS: Surgery for wisdom tooth removal resulted in substantial decreases in the serum concentration of ibuprofen enantiomers and a prolongation in the time to peak concentration. Reduced absorption and altered metabolism are the likely cause of these changes. Thus, dental patients may experience a delayed response and possible treatment failure when taking ibuprofen for pain relief after surgery. Our observation may have implications for the treatment of other diseases.     

Pharmacokinetics and protein binding of mycophenolic acid in stable lung transplant recipients

Mycophenolate mofetil (MMF) use is increasing in solid organ transplantation. Mycophenolic acid (MPA), the active metabolite of MMF, is highly protein bound and only free MPA is pharmacologically active. The average MPA free fraction in healthy adult individuals, stable renal transplant recipients, and heart transplant recipients is approximately 2 to 3%. However, no data are currently available on MPA protein binding in stable lung transplant recipients and little is known regarding MPA's pharmacokinetic characteristics after lung transplantation. The purpose of this study was to characterize the pharmacokinetic profile and protein binding of MPA in this patient population. Seven patients were entered into the study. On administration of a steady-state morning MMF dose, blood samples were collected at 0, 1, 2, 3, 4, 5, 6, 8, 9, 10, and 12 hours post-dose. Total MPA concentrations were measured by a validated HPLC method with UV detection and followed by ultrafiltration of pooled samples for free MPA concentrations. Area under the curve (AUC), peak concentration (Cmax), time to peak concentration (Tmax), trough concentration (Cmin), free fraction (f), and free MPA AUC were calculated by traditional pharmacokinetic methods. Patient characteristics included; 3 males and 4 females, an average of 4.4 years post-lung transplant (range, 0.3-11.5 yr), mean (+/- SD) age of 50 +/- 10 years and weight 69 +/- 20 kg. Mean albumin concentration was 37 +/- 3 g/L and serum creatinine was 142 +/- 49 micromol/L. All patients were on cyclosporine and prednisone. MMF dosage ranged from 1 to 3 g daily (35.5 +/- 14.1 mg/kg/d; range, 15.2-60.0 mg/kg/d). Mean (+/- SD) AUC was 45.78 +/- 18.35 microg.h/mL (range, 16.56-74.22 microg.h/mL), Cmax was 17.37 +/- 7.69 microg/mL (range, 4.92-26.63 microg/mL), Tmax was 1.2 +/- 0.4 hours (range, 1.0-2.0 h), Cmin was 3.12 +/- 1.41 microg/mL (range, 1.47-4.82 microg/mL), f was 2.90 +/- 0.56% (range, 2.00-3.40%), and free MPA AUC was 1.29 +/- 0.50 microg.h/mL (range, 0.54-1.88 microg.h/mL). This is the first study to determine these pharmacokinetic characteristics of MPA in the lung transplant population. Further studies should focus on identification of MMF dosing strategies that optimize immunosuppressive efficacy and minimize toxicity in lung allograft recipients.     

Serum level monitoring of a new slow release theophylline formulation in patients with chronic lung disease.

1 Serum theophylline levels were performed in 26 patients with chronic lung disease receiving rapid release theophylline (125 mg 6 hourly) and 28 patients receiving slow release theophylline (250 mg 12 hourly) under steady state conditions. 2 For rapid release theophylline the mean +/- s.d. serum theophylline levels at 0 and 2 h were 41.0 +/- 21.7 and 52.3 +/- 20.9 mumol l-1 respectively and for slow release theophylline at 0, 4 and 6 h 43.7 +/- 25.5, 50.9 +/- 23.0 and 51.7 +/- 26.4 mumol l-1 respectively. 3 Serum theophylline monitoring with slow release theophylline was performed in 70 patients with chronic lung disease. The initial dose was 250 mg administered 12 hourly. 4 The mean +/- s.d. steady state serum theophylline level achieved was 76.0 +/- 18.8 mumol l-1 and the mean +/- s.d. dose to produce this level was 9.4 +/ 2.3 mg kg-1 day-1. There was no correlation between dosage and serum theophylline level. 5 Sixty percent of patients required a dosage change for stabilization (375 to 1000 mg/day). Seventeen patients reported unwanted effects (nausea or tremor), which either settled quickly or resolved with dosage reduction. 6 Serum theophylline levels were obtained at different dosages in 44 patients and 18 patients demonstrated dose-dependent kinetics. 7 An initial dose of 500 mg/day is recommended and dosage increments should not exceed 125 mg/day with monitoring by serum theophylline levels.     

Pharmacokinetics of ticlopidine during chronic oral administration to healthy volunteers and its effects on antipyrine pharmacokinetics.

1. The pharmacokinetics of ticlopidine, a novel antithrombotic agent, have been investigated in 10 healthy volunteers dosed orally with the drug (250 mg 12 hourly for 21 days), to determine the basic pharmacokinetic parameters in humans, to investigate its accumulation during repeated administration, and to assess its effects on hepatic drug-metabolizing enzymes. 2. After the first dose, peak plasma concentrations (median 0.31, range 0.08-0.80 mg/l) were generally found at 2 h. The levels decreased rapidly to a median concentration of 0.087 mg/l by 4 h then declined to 0.022 (range less than 0.005-0.128) mg/l at 12 h after administration, with apparent half-lives of approx. 4 h. The median AUC value for this first dosage interval (AUC tau) was 0.97 (range 0.41-3.49) mg h l-1. 3. Pre-dose plasma concentrations indicated that steady state was reached after 5-10 days, and then remained essentially unchanged through to the end of the study. From 30 h after the final dose, drug levels declined exponentially with a median half-life of 28.8 (range less than or equal to 20-50) h. 4. Following the final dose, the median peak concentration and AUC tau were 0.99 (range 0.22-2.12) mg/l and 4.06 (range 0.90-15.2) mg h l-1 respectively. Based on AUC values, the mean accumulation factor +/- SD was 3.73 +/- 1.14. 5. The metabolic status of subjects was assessed by administration of single doses of antipyrine (700 mg orally) 7 days before the first dose of ticlopidine and 2 days after the final dose. Treatment with ticlopidine decreased antipyrine clearance, demonstrating that it inhibited drug-metabolizing enzymes. Significant correlations (r2 = 0.84, p less than 0.01) were found between the AUC values for ticlopidine and antipyrine, indicating that the interindividual variation in the pharmacokinetics of ticlopidine are explained by differences in metabolic clearance.     

The pharmacokinetics and pharmacodynamics of quinidine and 3-hydroxyquinidine.

1. The pharmacokinetics and pharmacodynamics of quinidine and 3-hydroxyquinidine based upon measurements of total and unbound serum concentrations were determined after a single dose (400 mg) and at steady state (200 mg every 6 h). 2. The oral clearance (7.6 +/- 1.9 vs 4.8 +/- 2.0 ml min-1 kg-1; P less than 0.05) and renal clearance (1.2 +/- 0.3 vs 0.63 +/- 0.25 ml min-1 kg-1; P less than 0.005) or quinidine were lower during steady state than after the single dose. 3. The area under the serum concentration vs time curve (AUC) of 3-hydroxyquinidine was greater at steady state than after the single dose (2.0 +/- 0.7 vs 3.0 +/- 0.6 mg l-1 h; P less than 0.05) and its renal clearance was less (3.0 +/- 1.1 vs 1.54 +/- 0.38 ml min-1 kg-1; P less than 0.05). 4. The slope of the relationship between quinidine concentration and change in QTc interval was greater at steady state (40.1 +/- 21.7 vs 72.2 +/- 41.7 ms/(mg l-1); P less than 0.05).     

Impact of gastric emptying on the pharmacokinetics of ethanol as influenced by cisapride

AIMS: To examine the influence of cisapride on the pharmacokinetics of ethanol and the impact of gastric emptying monitored by the paracetamol absorption test. METHODS: Ten healthy male volunteers took part in a cross-over design experiment. They drank a moderate dose of ethanol 0.30 g kg-1 body weight exactly 1 h after eating breakfast either without any prior drug treatment or after taking cisapride (10 mg three times daily) for 4 consecutive days. In a separate study, the same dose of ethanol was ingested on an empty stomach (overnight fast). Paracetamol (1.5 g) was administered before consumption of ethanol to monitor gastric emptying. Venous blood was obtained at 5-10 min intervals for determination of ethanol by headspace gas chromatography and paracetamol was analysed in serum by high performance liquid chromatography (h.p.l.c.). Results The maximum blood-ethanol concentration (Cmax ) increased from 3.8+/-1.7 to 5.6+/-2.3 mmol l-1 (+/-s.d.) after treatment with cisapride (95% confidence interval CI on mean difference 0.28-3.28 mmol l-1 ). The area under the blood-ethanol curve (AUC) increased from 6.3+/-3.5 to 7.9+/-2.6 mmol l-1 h after cisapride (95% CI -0. 74-3.9 mmol l-1 h). The mean blood ethanol curves in the cisapride and no-drug sessions converged at approximately 2 h after the start of drinking. Both Cmax and AUC were highest when the ethanol was ingested on an empty stomach (Cmax 9.5+/-1.7 mmol l-1 and AUC 14. 6+/-1.9 mmol l-1 h), compared with drinking 1 h after a meal and regardless of pretreatment with cisapride. CONCLUSIONS: A small but statistically significant increase in Cmax occurred after treatment with cisapride owing to faster gastric emptying rate as shown by the paracetamol absorption test. However, the rate of absorption of ethanol, as reflected in Cmax and AUC, was greatest after drinking the alcohol on an empty stomach. The cisapride-ethanol interaction probably lacks any clinical or forensic significance.     

Population pharmacokinetics of piperacillin/tazobactam in neonates and young infants

Objectives

To develop population pharmacokinetic (PK) models for piperacillin/tazobactam in neonates and infants of less than 2 months of age in order to determine the appropriate dosing regimen and provide a rational basis for the development of preliminary dosing guidelines suitable for this population.

Methods

A two-stage, open-label study was conducted in neonates and infants less than 2 months of age in the neonatal intensive care unit (NICU). A total of 207 piperacillin and 204 tazobactam concentration–time data sets from 71 patients were analyzed using a nonlinear mixed-effect modeling approach (NONMEM VII). PK models were developed for piperacillin and tazobactam. The final models were evaluated using both bootstrap and visual predictive checks. External model evaluations were made in 20 additional patients.

Results

For neonates and young infants less than 2 months of age, the median central clearance was 0.133 and 0.149 L/h/kg for piperacillin and tazobactam, respectively. Postmenstrual age (PMA) was identified as the most significant covariate on central clearance of piperacillin and tazobactam. However, the combination of current bodyweight (BW) and postnatal age proved to be superior to PMA alone. BW was the most important covariate for apparent central volume of distribution. Both internal and external evaluations supported the prediction of the final piperacillin and tazobactam PK models. The dosing strategy 44.44/5.56 mg/kg/dose piperacillin/tazobactam every 8 or 12 h evaluated in this study achieved the pharmacodynamic target (free piperacillin concentrations >4 mg/L for more than 50 % of the dosing interval) in about 67 % of infants.

Conclusions

Population PK models accurately described the PK profiles of piperacillin/tazobactam in infants less than 2 months of age. The results indicated that higher doses or more frequent dosing regimens may be required for controlling infection in this population in NICU.