Pharmacokinetics and safety of a unilamellar liposomal formulation of amphotericin B (AmBisome) in rabbits.

A unilamellar liposomal formulation of amphotericin B (LAmB) known as AmBisome was safely administered intravenously to 20 rabbits at 0.5, 1.0, 2.5, 5, or 10 mg/kg of body weight, whereas of 12 rabbits given desoxycholate amphotericin B (DAmB) intravenously at 0.5, 1.0, or 1.5 mg/kg, 2 died of acute cardiac toxicity when DAmB was administered at the highest dose. Single-dose LAmB (1 mg/kg) achieved a maximum concentration in serum (Cmax) of 26 +/- 2.4 micrograms/ml and an area under the curve to infinity (AUC0-infinity) of 60 +/- 16 micrograms.h/ml, while single-dose DAmB (1.0 mg/kg), by comparison, achieved a lower Cmax (4.7 +/- 0.2 micrograms/ml; P = 0.001) and a lower AUC0-infinity (30.6 +/- 2.2 micrograms.h/ml; P = 0.07). Following administration of a single dose of LAmB (10 mg/kg), a disproportionately higher Cmax (287 +/- 14 micrograms/ml) and AUC0-infinity (2,223 +/- 246 micrograms.h/ml) occurred, indicating saturable elimination. After chronic dosing (n = 4) with LAmB at 5.0 mg/kg/day for 28 days or DAmB at 1.0 mg/kg/day for 28 days, LAmB achieved daily peak levels of 122.8 +/- 5.8 micrograms/ml and trough levels of 34.9 +/- 1.8 micrograms/ml, while DAmB reached a peak of only 1.76 +/- 0.11 microgram/ml and a trough of 0.46 +/- 0.04 microgram/ml (P < or = 0.001). Significant accumulations of amphotericin B into reticuloendothelial organs were observed, with 239 +/- 39 micrograms/g found in the liver after chronic LAmB dosing (5 mg/kg/day), which was seven times higher than the 33 +/- 6 micrograms/g after DAmB dosing (1 mg/kg/day) (P = 0.002). Accumulation in kidneys, however, remained 14-fold lower (P =0.04) following LAmB dosing (0.87 +/- 0.61 microgram/g) than after DAmB dosing (12.7 +/- 4.6 microgram/g). Nephrotoxicity occurred in only one of four LAmB treated animals, while it occurred in all four chronically DAmB-treated animals: mild hepatozicity with transaminase elevations was seen in one LAmB-treated rabbit. We conclude that LAmB safely achieved higher Cmax(s) and AUC0-infinity(s) and demonstrated saturable, nonlinear elimination from plasma via reticuloendothelial organ uptake. Take reduced nephrotoxicity of LAmB correlated with diminished levels of amphotericin B in the kidneys.     

Fever and associated changes in glomerular filtration rate erase anticipated diurnal variations in aminoglycoside pharmacokinetics.

Netilmicin (4.5 mg/kg of lean body weight) was administered intravenously once every 24 h at 10 a.m. to 23 patients (group I) and at 10 p.m. to 20 patients (group II) with severe infection. No significant differences (P > 0.05) in peak and trough concentrations in serum were found between groups I and II (peak, 12.9 +/- 3.7 versus 12.8 +/- 4.4 mg/liter, respectively; trough, 0.7 +/- 0.6 versus 0.8 +/- 0.6 mg/liter, respectively [mean +/- standard deviation]). Pharmacokinetic parameters (half-life [5.0 +/- 2.2 versus 4.9 +/- 1.8 h], volume of distribution [0.32 +/- 0.04 versus 0.35 +/- 0.06 liter/kg], and total clearance [0.920 +/- 0.417 versus 1.015 +/- 0.546 ml/min/kg]) were similar in the two groups and not influenced by the time of administration. These data suggest that, in the once-daily schedule, 10 a.m. or 10 p.m. administration had no influence on netilmicin levels in serum and pharmacokinetic parameters in these ill febrile patients.     

Pharmacokinetics of amphotericin B in children.

Amphotericin B is the most effective agent for the majority of systemic fungal infections but often causes toxicity, and specific dosage guidelines for amphotericin B in pediatric patients are lacking. The purpose of this study was to characterize the pharmacokinetics of amphotericin B in children. Twelve patients (mean age, 6.6 years; range, 4 months to 14 years) receiving amphotericin B, 0.68 +/- 0.34 mg/kg per day (mean plus or minus standard deviation), were studied. Four to eight blood samples were collected during a 24-h period and analyzed by high-pressure liquid chromatography. The peak concentration of amphotericin B in serum was 2.9 +/- 2.8 micrograms/ml. The mean total clearance, apparent volume of distribution, and elimination half-life were 0.46 +/- 0.20 ml/min per kg, 0.76 +/- 0.52 liters/kg, and 18.1 +/- 6.6 h, respectively. Total clearance decreased with age (p less than 0.01). In children aged 8 months to 9 years, the mean total clearance was 0.57 +/- 0.15 ml/min per kg, and in children older than 9 years, it was 0.24 +/- 0.02 ml/min per kg. Interpatient variation in the clearance and volume of distribution of amphotericin B was greater than threefold and greater than eightfold, respectively. However, pharmacokinetic parameters did not change in two stable patients who were studied again. Because clearance decreased substantially with age, older children may require lower doses of amphotericin B per kilogram to decrease the potential for toxicity.     

Compartmentalized intrapulmonary pharmacokinetics of amphotericin B and its lipid formulations

We investigated the compartmentalized intrapulmonary pharmacokinetics of amphotericin B and its lipid formulations in healthy rabbits. Cohorts of three to seven noninfected, catheterized rabbits received 1 mg of amphotericin B deoxycholate (DAMB) per kg of body weight or 5 mg of either amphotericin B colloidal dispersion (ABCD), amphotericin B lipid complex (ABLC), or liposomal amphotericin B (LAMB) per kg once daily for a total of 8 days. Following sparse serial plasma sampling, rabbits were sacrificed 24 h after the last dose, and epithelial lining fluid (ELF), pulmonary alveolar macrophages (PAM), and lung tissue were obtained. Pharmacokinetic parameters in plasma were derived by model-independent techniques, and concentrations in ELF and PAM were calculated based on the urea dilution method and macrophage cell volume, respectively. Mean amphotericin B concentrations +/- standard deviations (SD) in lung tissue and PAM were highest in ABLC-treated animals, exceeding concurrent plasma levels by 70- and 375-fold, respectively (in lung tissue, 16.24 +/- 1.62 versus 2.71 +/- 1.22, 6.29 +/- 1.17, and 6.32 +/- 0.57 microg/g for DAMB-, ABCD-, and LAMB-treated animals, respectively [P = 0.0029]; in PAM, 89.1 +/- 37.0 versus 8.92 +/- 2.89, 5.43 +/- 1.75, and 7.52 +/- 2.50 mug/ml for DAMB-, ABCD-, and LAMB-treated animals, respectively [P = 0.0246]). By comparison, drug concentrations in ELF were much lower than those achieved in lung tissue and PAM. Among the different cohorts, the highest ELF concentrations were found in LAMB-treated animals (2.28 +/- 1.43 versus 0.44 +/- 0.13, 0.68 +/- 0.27, and 0.90 +/- 0.28 microg/ml in DAMB-, ABCD-, and ABLC-treated animals, respectively [P = 0.0070]). In conclusion, amphotericin B and its lipid formulations displayed strikingly different patterns of disposition in lungs 24 h after dosing. Whereas the disposition of ABCD was overall not fundamentally different from that of DAMB, ABLC showed prominent accumulation in lung tissue and PAM, while LAMB achieved the highest concentrations in ELF.     

Pharmacokinetics, excretion, and mass balance of liposomal amphotericin B (AmBisome) and amphotericin B deoxycholate in humans

The pharmacokinetics, excretion, and mass balance of liposomal amphotericin B (AmBisome) (liposomal AMB) and the conventional formulation, AMB deoxycholate (AMB-DOC), were compared in a phase IV, open-label, parallel study in healthy volunteers. After a single 2-h infusion of 2 mg of liposomal AMB/kg of body weight or 0.6 mg of AMB-DOC/kg, plasma, urine, and feces were collected for 168 h. The concentrations of AMB were determined by liquid chromatography tandem mass spectrometry (plasma, urine, feces) or high-performance liquid chromatography (HPLC) (plasma). Infusion-related side effects similar to those reported in patients, including nausea and back pain, were observed in both groups. Both formulations had triphasic plasma profiles with long terminal half-lives (liposomal AMB, 152 +/- 116 h; AMB-DOC, 127 +/- 30 h), but plasma concentrations were higher (P < 0.01) after administration of liposomal AMB (maximum concentration of drug in serum [C(max)], 22.9 +/- 10 microg/ml) than those of AMB-DOC (Cmax, 1.4 +/- 0.2 microg/ml). Liposomal AMB had a central compartment volume close to that of plasma (50 +/- 19 ml/kg) and a volume of distribution at steady state (Vss) (774 +/- 550 ml/kg) smaller than the Vss of AMB-DOC (1,807 +/- 239 ml/kg) (P < 0.01). Total clearances were similar (approximately 10 ml hr(-1) kg(-1)), but renal and fecal clearances of liposomal AMB were 10-fold lower than those of AMB-DOC (P < 0.01). Two-thirds of the AMB-DOC was excreted unchanged in the urine (20.6%) and feces (42.5%) with >90% accounted for in mass balance calculations at 1 week, suggesting that metabolism plays at most a minor role in AMB elimination. In contrast, <10% of the liposomal AMB was excreted unchanged. No metabolites were observed by HPLC or mass spectrometry. In comparison to AMB-DOC, liposomal AMB produced higher plasma exposures and lower volumes of distribution and markedly decreased the excretion of unchanged drug in urine and feces. Thus, liposomal AMB significantly alters the excretion and mass balance of AMB. The ability of liposomes to sequester drugs in circulating liposomes and within deep tissue compartments may account for these differences.     

Double-blind randomized study of the effect of infusion rates on toxicity of amphotericin B.

Results of a double-blind randomized non-crossover study of rapid (45 min) versus slow (4 h) infusion of amphotericin B administered to 20 patients with proven or suspected fungal infection are reported. Toxicity was higher in the rapid infusion group than it was in the slow infusion group (mean total 7-day chill score, 173 +/- 276 versus 20 +/- 30 [P less than 0.01]; mean total 7-day dosage of meperidine required to abate rigors, 180 +/- 133 versus 58 +/- 78 mg [P less than 0.05]; and mean maximum total 7-day pulse rise, 225 +/- 64 versus 135 +/- 56 beats per min [P less than 0.02], respectively). When analyzed on a daily basis, the mean chill score, meperidine dosage, and pulse rise were also higher; and in addition, nausea and vomiting (5 of 11 patients who received a rapid infusion versus 0 of 9 patients who received a slow infusion [P less than 0.01]) appeared to be more common in those who received amphotericin B rapidly. The daily analysis approach proved that tolerance to these side effects developed with each subsequent infusion day, and by day 7 the incidence and severity were the same. This development of tolerance was significant for the mean chill score in the rapid infusion group (P less than 0.05) and for the proportion of patients with chills (P less than 0.005 for the slow infusion group; P less than 0.05 for the rapid infusion group). A decrease in creatinine clearance to greater than 51% of the baseline value was seen in two patients in each group. There were five deaths (four in the rapid infusion group, 1 in the slow infusion group) within 1 month, but none was clearly related to the amphotericin B infusion. The mean time to defervescence was similar for each group (10.8 +/- 4.1 days in the slow infusion group versus 9.9 +/- 5 days in the rapid infusion group). A rapid infusion regimen for amphotericin B cannot be recommended, at least during the first 5 to 7 days of treatment.     

Antifungal activity of HWA-138 and amphotericin B in experimental systemic candidiasis.

HWA-138, a pentoxifylline analog, has been shown to increase yeast urinary clearance and to reduce yeast counts in the kidneys of rats infected with Candida albicans. Furthermore, HWA-138 has also been shown to prevent amphotericin B-induced acute renal failure in rats. We report here on the effects of HWA-138 alone and in combination with amphotericin B in the treatment of systemic candidiasis in mice. When single doses of HWA-138 were administered intravenously (10, 25, or 50 mg/kg of body weight) into infected mice, no significant improvement in survival was observed. In infected mice treated intravenously with multiple doses of HWA-138 (10, 25, or 50 mg/kg once daily for 5 consecutive days), a significant increase in survival time was seen only in animals also receiving 25 mg of HWA-138 per kg (14 +/- 3 days test versus 9 +/- 1 days control; P less than 0.05). The coadministration of subtherapeutic doses of amphotericin B and HWA-138 resulted in increased survival time. Combination therapy with amphotericin B (0.1-mg/kg single dose) and HWA-138 (10-, 25-, or 50-mg/kg multiple doses) resulted in a significant increase in survival time over controls (19 +/- 4, 19 +/- 5, and 21 +/- 9 days, respectively, versus 9 +/- 3 days; P less than 0.05). Combination therapy with amphotericin B (0.2-mg/kg single dose) and HWA-138 (10-, 25-, or 50-mg/kg multiple doses) also resulted in a significant increase in survival time over controls (24 +/- 6, 24 +/- 6, and 24 +/- 6, respectively, versus 9 +/- 3 days; P less than 0.05). Combination therapy with amphotericin B (0.2-mg/kg single dose) and HWA-138 (10-, 25-, or 50-mg/kg multiple doses) also resulted in a significant increase in survival time over controls (24 +/- 6, 24 +/- 6, and 24 +/- 6, respectively, versus 9 +/- 3 days; P < 0.05). Variance analysis of these findings indicate synergistic activity between amphotericin B and HWA-138 in the treatment of experimental candidiasis in mice.     

Pharmacokinetics of liposomal amphotericin B (Ambisome) in critically ill patients.

The liposomal formulation of amphotericin B (AmBisome) greatly reduces the acute and chronic side effects of the parent drug. The present study describes the pharmacokinetic characteristics of AmBisome applied to 10 patients at a dose of 2.8 to 3.0 mg/kg of body weight and compares them to the pharmacokinetics observed in 6 patients treated with amphotericin B deoxycholate at the standard dose of 1.0 mg/kg. Interpatient variabilities of amphotericin B peak concentrations (Cmax) and areas under concentration-time curves (AUC) were 8- to 10-fold greater for patients treated with AmBisome than for patients treated with amphotericin B deoxycholate. At the threefold greater dose of AmBisome, median Cmaxs were 8.4-fold higher (14.4 versus 1.7 microg/ml) and median AUCs exceeded those observed with amphotericin B deoxycholate by 9-fold. This was in part explained by a 5.7-fold lower volume of distribution (0.42 liters/kg) in AmBisome-treated patients. The elimination of amphotericin B from serum was biphasic for both formulations. However, the apparent half-life of elimination was twofold shorter for AmBisome (P = 0.03). Neither hemodialysis nor hemofiltration had a significant impact on AmBisome pharmacokinetics as analyzed in one patient. In conclusion, the liposomal formulation of amphotericin B significantly (P = 0.001) reduces the volume of drug distribution, thereby allowing for greater drug concentrations in serum. The low toxicity of AmBisome therefore cannot readily be explained by its serum pharmacokinetics.     

Risk factors of ventricular fibrillation during rapid amphotericin B infusion.

Amphotericin B causes reversible concentration-dependent loss of intracellular potassium in vitro and hyperkalemic ventricular arrhythmias in dogs. Hyperkalemic ventricular arrhythmias associated with amphotericin B infusion have not been well documented in humans. Ventricular fibrillation with progressive hyperkalemia (up to 8 to 8.4 meq/liter) occurred twice in an anuric patient during rapid infusion of high-dose amphotericin B (1.4 mg/kg over 45 min). The peak amphotericin B concentration in serum at the end of infusion was 6.7 micrograms/ml. Prolonged infusion (3 h) and concurrent hemodialysis each prevented the development of hyperkalemia and ventricular arrhythmia. In two anuric patients receiving 4-h infusions of amphotericin B during dialysis (0.7 and 1.0 mg/kg), peak amphotericin B concentrations in serum were lower, 1.6 +/- 0.1 and 2.7 +/- 0.7 micrograms/ml, respectively; serum potassium levels were maintained in the normal range; and venous access for outpatient therapy was convenient. Peak concentrations of amphotericin B in serum were also lower (1.7 +/- 0.7 micrograms/ml) in eight patients with normal renal function who received lower doses (0.7 +/- 0.2 mg/kg) over 45 min; there were only slight increases in the serum potassium level (from 3.9 +/- 0.9 to 4.4 +/- 0.6 meq/liter, P less than 0.05). We recommend that rapid infusion of amphotericin B not be used in patients with impaired potassium excretion unless accompanied by hemodialysis and careful potassium monitoring.     

Pharmacokinetics of ceftazidime in normal and uremic subjects.

The pharmacokinetics of ceftazidime, administered as a single intravenous dose of 15 mg/kg given in a bolus injection over 3 min, were investigated in 5 normal subjects and in 19 uremic patients. The subjects studied were divided into five groups according to values for endogenous creatinine clearance (CLCR): group I, five subjects with CLCR greater than 80 ml/min; group II, five patients with CLCR = 30 to 80 ml/min; group III, six patients with CLCR = 10 to 30 ml/min; group IV, four patients with CLCR = 2 to 10 ml/min; and group V, four anuric patients on hemodialysis. A two-compartment open model was used to calculate the pharmacokinetic parameters. In normal subjects, the mean apparent elimination half-life was 1.57 +/- 0.13 h. The central distribution volume and the apparent volume of distribution were 0.127 +/- 0.023 and 0.230 +/- 0.015 liter/kg, respectively. Of the injected dose, 83.6 +/- 3.6% was eliminated in the urine as parent drug within 24 h. The terminal half-life increased with impairment of renal function to about 25 h in severely uremic patients. Impairment of function did not significantly modify the half-life at alpha phase, central distribution volume, or apparent distribution volume. A 6- to 8-h hemodialysis procedure reduced concentrations of ceftazidime in plasma by approximately 88%, and the elimination half-life was 2.8 +/- 0.2 h. There was no evidence of accumulation of ceftazidime in four patients with severe and chronic impairment of function who received doses of 0.5 to 1.0 g every 24 h for 10 days.     

Increased aminoglycoside dosage requirements in hematologic malignancy.

Aminoglycoside pharmacokinetic parameters were studied prospectively in 27 patients with an underlying hematologic malignancy and fever associated with neutropenia and in 18 control patients. Pharmacokinetic parameters and dosages were determined by linear regression analysis of a one-compartment model by the method of Sawchuk et al. (R. J. Sawchuk, D. E. Zaske, R. J. Cippolle, W. A. Wargin, and R. G. Strate, Clin. Pharmacol. Ther. 21:362-369, 1976). Significant differences between the study and control groups were found for aminoglycoside volume of distribution (0.40 +/- 0.1 versus 0.27 +/- 0.05 liter/kg [mean +/- standard deviation], respectively; P less than 0.0001), clearance (116.6 +/- 48.9 versus 68.6 +/- 26.7 ml/min, respectively; P less than 0.0001), half-life (2.27 +/- 0.66 versus 3.5 +/- 1.8 h, respectively; P less than 0.0001), and elimination rate constant (0.33 +/- 0.11 versus 0.24 +/- 0.09 h-1, respectively; P less than 0.001). The percentage of bone marrow blast cells (at the time of diagnosis) in patients with acute leukemia significantly correlated with increased aminoglycoside clearance (R2 = 36.98%; P = 0.0001). Patients with stage IV lymphomas (Hodgkins disease and non-Hodgkins lymphoma) had a significantly increased clearance compared with patients with lower stages of lymphomas (105.1 +/- 18.5 versus 84.1 +/- 14.9 ml/min; P = 0.014). Fever, leukocyte count, or chemotherapy, among other clinical and laboratory parameters that were studied, had no significant correlation or effect on aminoglycoside disposition. The average dose of amikacin required to maintain peak concentrations in serum above 20 micrograms/ml in patients with a hematologic malignancy was 27.5 +/- 8.43 mg/kg per day. Pharmacokinetic parameters and dosages for the control patients were comparable to general literature standards. we conclude that the dosages recommended by the manufacturers or those derived from nomograms underestimate the aminoglycoside volume of distribution and clearance in patients with a hematologic malignancy and result in suboptimal peak aminoglycoside concentrations in serum. We recommend that in febrile neutropenic patients with an underlying hematologic malignancy, amikacin be initiated at 7.5 to 10 mg/kg per dose every 8 h (2 to 2.5 mg/kg per dose every 8 h for gentamicin) and adjusted within 24 h based on individual pharmacokinetic analysis.     

PHARMACOKINETICS AND PHARMACODYNAMICS OF 2,4-DIAMINOPYRIDINE IN THE CAT

The pharmacokinetics, antagonistic effects, and cardiovascular effects of 2,4-diaminopyridine (2,4-DAP) were studied in 7 anaesthetized cats. Cats received a pancuronium infusion at a constant rate to cause a 90% block of contraction of the anterior tibialis muscle, stimulated through the sciatic nerve. After steady state was reached, 2,4-DAP (750 micrograms/kg IV) was administered. Plasma, urine, and bile were collected over 8 h and analyzed by means of an HPLC assay. Plasma concentrations decreased biexponentially with half-lives of 9.0 +/- 5.7 min and 140 +/- 36 min, respectively. The volume of the central compartment was 0.85 +/- 0.27 L/kg, and the volume of distribution in the steady state was 3.1 +/- 1.1 L/kg. Total plasma clearance was 18 +/- 5 ml/kg/min. Ninety percent of the administered dose was recovered in the urine and 0.1 percent in the bile in 8 h. The antagonism of the pancuronium-induced steady-state block was 98% +/- 5%, with onset and duration of 3.5 +/- 2 min and 165 +/- 40 min, respectively.     

Effect of concomitant administration of piperacillin on the dispositions of isepamicin and gentamicin in patients with end-stage renal disease.

Piperacillin inactivation of the aminoglycosides isepamicin and gentamicin in 12 chronic hemodialysis patients was assessed. Six subjects each received isepamicin (7.5 mg/kg of body weight) or gentamicin (2 mg/kg) alone and in combination with piperacillin (4 g every 12 h for four doses). Isepamicin and gentamicin concentrations in plasma and urine were monitored over 48 h after each dose and analyzed by high-performance liquid chromatography and fluorescence polarization immunoassay, respectively. The pharmacokinetics of isepamicin were not significantly altered during combination treatment with piperacillin. The total body clearance (3.79 +/- 0.71 versus 3.94 +/- 1.05 ml/min), the steady-state volume of distribution (0.19 +/- 0.04 versus 0.18 +/- 0.03 liter/kg), and the terminal elimination half-life (47.91 +/- 7.20 versus 45.08 +/- 10.34 h) were not significantly altered in the presence of piperacillin. In contrast, the terminal elimination half-life (47.68 +/- 20.58 versus 35.67 +/- 11.18 h) of gentamicin was significantly reduced when gentamicin was given with piperacillin. The total body clearance (4.26 +/- 3.07 versus 4.89 +/- 1.94 ml/min) and the steady-state volume of distribution (0.19 +/- 0.04 versus 0.20 +/- 0.04 liter/kg) of gentamicin were not significantly altered during combination therapy; however, the nonrenal clearance of gentamicin administered in combination with piperacillin (3.56 +/- 0.38 ml/min) increased significantly compared with that of gentamicin (2.03 +/- 0.50 ml/min) given alone. The results of this study suggest that no additional dosage adjustment of isepamicin during concomitant therapy with piperacillin in hemodialysis patients is necessary. However, this does not preclude the need for appropriately ex vivo-handled specimens for monitoring isepamicin concentrations in plasma to ensure therapeutic efficacy and prevent toxicity. Furthermore, additional dosage adjustments may be necessary when gentamicin is used concomitantly with piperacillin, on the basis of the significant in vivo inactivation that takes place in end-stage renal disease patients.     

Titrated hypertonic/hyperoncotic solution for hypotensive fluid resuscitation during uncontrolled hemorrhagic shock in rats

BACKGROUND: In volume- or pressure-controlled hemorrhagic shock (HS) a bolus intravenous infusion of hypertonic/hyperoncotic solution (HHS) proved beneficial compared to isotonic crystalloid solutions. During uncontrolled HS in animals, however, HHS by bolus increased blood pressure unpredictably, and increased blood loss and mortality. We hypothesized that a titrated i.v. infusion of HHS, compared to titrated lactated Ringer's solution (LR), for hypotensive fluid resuscitation during uncontrolled HS reduces fluid requirement, does not increase blood loss, and improves survival. METHODS: We used our three-phased uncontrolled HS outcome model in rats. HS phase I began with blood withdrawal of 3 ml/100g over 15 min, followed by tail amputation. Then, hydroxyethyl starch 10% in NaCl 7.2% was given i.v. to the HHS group (n=10) and LR to the control group (n=10), both titrated to prevent mean arterial pressure (MAP) from falling below 40 mmHg during HS time 20-90 min. At HS 90 min, resuscitation phase II of 180 min began with hemostasis, return of all the blood initially shed, plus fluids i.v. as needed to maintain normotension (MAP>or=70 mmHg). Liver dysoxia was monitored as increase in liver surface pCO2 during phases I and II. Observation phase III was to 72 h. RESULTS: During HS, preventing a decrease in MAP below 40 mmHg required HHS 4.9+/-0.6 ml/kg (all data mean+/-S.E.M.), compared to LR 62.2+/-16.6 ml/kg (P<0.001), with no group difference in MAP. Uncontrolled blood loss during HS from the tail stump was 13.3+/-1.9 ml/kg with HHS infusion, versus 12.6+/-2.5 ml/kg with LR infusion (P=0.73). Serum sodium concentrations were moderately elevated at the end of HS in the HHS group (149+/-3 mmol/l) versus the LR group (139+/-1 mmol/l) (P=0.001), and remained elevated throughout. Liver pCO2 increased during HS in both groups equally (P<0.001 versus baseline), and tended to return to baseline levels at the end of HS. Blood gas and lactate values throughout did not differ between groups. During HS, 2 of 10 rats in the HHS group versus 0 of 10 in the LR group died (P=0.47). There was no difference between HHS and LR groups in survival rates to 72 h (3 of 10 in the HHS group versus 2 of 10 in the LR group) (P=1.0). Survival times, by life table analysis, were not different (P=0.75). CONCLUSION: In prolonged uncontrolled HS, a titrated i.v. infusion of HHS can maintain controlled hypotension with only one-tenth of the volume of LR required, without increasing blood loss. This titrated HHS strategy may not increase the chance of long-term survival.     

Fosfomycin kinetics after intravenous and oral administration to human volunteers.

The pharmacokinetics of fosfomycin, administered intravenously and orally at two different doses (20 and 40 mg/kg of body weight), was studied in seven volunteers. The elimination profile of this antibiotic, when administered intravenously, followed a two-compartment kinetic model, independent of dosage, giving an elimination half-life of 2.23 +/- 0.62 h and an average total volume of distribution at steady state of 0.34 liter/kg. Peak serum levels after rapid intravenous administration of 20 and 40 mg/kg were 132.1 +/- 31.8 and 259.3 +/- 32.5 micrograms/ml, respectively. Peak serum levels after oral administration were 7.1 +/- 1.6 and 9.4 +/- 3.6 micrograms/ml for the 20 and 40 mg/kg doses, respectively. During the first 24 h after administration, an average of 80% of the intravenous doses and less than 25% of the oral doses were recovered in the urine.     

Effects of timing of food and fluid volume on cefetamet pivoxil absorption in healthy normal volunteers.

Cefetamet pivoxil (1,000 mg orally) absorption was evaluated in 16 male subjects (age, 23.4 +/- 1.7 years; weight, 73.9 +/- 7.0 kg) 1 h before (BE), with (WI), and 1 h after (AF) a standard breakfast. The time to peak concentration of cefetamet in plasma (Tmax) was increased from 3.25 +/- 1.44 h in the BE group to 4.31 +/- 1.54 and 4.13 +/- 1.54 h in the WI and AF groups, respectively (P less than 0.05). The maximum cefetamet concentration in plasma (Cmax) and the area under the plasma cefetamet concentration-time profiles (AUC) in the BE, WI, and AF groups were 5.50 +/- 1.06, 5.47 +/- 1.4, and 6.57 +/- 0.93 micrograms/ml and 38.2 +/- 10.1, 35.7 +/- 11.9, and 42.8 +/- 6.8 micrograms.h/ml, respectively. The Cmax and AUC values were not different between the BE and WI groups (P greater than 0.05). However, differences in these values were found between the WI and AF groups (P less than 0.05). The effect of fluid volume intake on cefetamet pivoxil (1,000 mg orally) absorption was evaluated in 12 male subjects (age, 23.8 +/- 2.3 years; weight, 74.9 +/- 9.0 kg) under fasted and WI conditions. Increasing fluid volume intake from 250 to 450 ml under the fasted condition had no effect on the absorption of the prodrug (Tmax, 2.50 +/- 0.52 versus 2.83 +/- 0.94 h; Cmax, 4.89 +/- 1.04 versus 4.84 +/- 0.89 micrograms/ml; AUC, 29.6 +/- 5.1 versus 30.7 +/- 7.1 micrograms.h/ml; P greater than 0.05. Thus, independent of fluid volume intake, cefetamet pivoxil absorption is enhanced when it is given within 1 h of a meal, and it is recommended that the prodrug should be taken during this period of increased bioavailability.     

Pharmacokinetics of cefodizime in patients with liver cirrhosis and ascites.

The pharmacokinetics of cefodizime were studied in 6 healthy male volunteers (group A) and 6 patients with liver cirrhosis and ascites (group B) receiving 1 g of the drug as an i.v. bolus. Cefodizime was assayed in serum and ascitic fluid (AF) samples by a microbiological assay. The serum concentration-time curve fitted a two-compartment open model in group A and a three-compartment open model in group B. Initially, the serum level of cefodizime in group A exceeded that in group B for about 10 h; thereafter the reverse occurred until 24 h post-dosing. Cefodizime penetrated rapidly into the AF, reaching a peak at 6 h, and its AF level was still above the MIC90 for Enterobacteriaceae in most patients at 24 h post-dosing. The half-life of distribution did not differ significantly between the two groups, while the elimination half-life was prolonged significantly (p < 0.001) from 2.7 +/- 0.2 h in group A to 5.4 +/- 0.8 h in group B. The central volume of distribution (Vc) did not differ significantly in the two groups, while the terminal volume of distribution (Vp) was significantly smaller (p < 0.01) in group A (0.172 +/- 0.30 l/kg) than in group B (0.55 +/- 0.20 l/kg). The area under the serum concentration-time curve (AUC0-infinity serum) was significantly larger (p < 0.001) in group A [322 +/- 34 (micrograms/ml).h than in group B (180 +/- 34 (micrograms/ml).h]. The area under the AF concentration-time curve (AUC0-infinity ascites) in group B was 141 +/- 37 (micrograms/ml).h.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of amiloride on amphotericin B-induced hypokalaemia.

Amiloride was administered to 19 oncology patients exhibiting marked amphotericin B-induced electrolyte wasting. Mean serum potassium concentrations increased in the 5 days preceding and following administration (3.4 +/- 0.5 versus 3.9 +/- 0.8 mmol/L, P = 0.002). A trend towards decreased potassium supplementation was also observed (48.0 +/- 66.5 versus 29.4 +/- 43.2 mmol/day, P = 0.12). Amiloride is a therapeutic option to decrease potassium wasting in patients being treated with amphotericin B.     

Effects of telmisartan on renal excretory function in conscious dogs

The present study investigated the effects of telmisartan, a selective AT1 receptor antagonist, on renal function in dogs. Conscious female dogs were treated with (i) vehicle (controls) and three doses of telmisartan (0.03 mg/kg, 0.1 mg/kg and 0.3 mg/kg) administered intravenously; (ii) vehicle and three doses of telmisartan (0.3 mg/kg, 1.0 mg/kg and 3.0 mg/kg) administered orally; or (iii) 1.0 mg/kg per day telmisartan orally for 12 days. Eight dogs were used for each experiment. Each of the four treatments in (i) and (ii) was administered 7 days apart. During the 6 h after intravenous administration, urine volume was significantly higher in dogs treated with telmisartan 0.1 mg/kg (8.5 +/- 1.6 ml/kg) and 0.3 mg/kg (7.0 +/- 0.9 ml/kg) than controls (2.7 +/- 0.3 ml/kg; P < 0.05), and renal sodium excretion was increased significantly with telmisartan 0.03 mg/kg (803 +/- 124 micromol/kg), 0.1 mg/kg (1039 +/- 213 micromol/kg) and 0.3 mg/kg (966 +/- 161 micromol/kg) versus controls (159 +/- 21 micromol/kg; P < 0.05). Oral telmisartan at doses of 1.0 mg/kg and 3.0 mg/kg also produced significant increases in urine volume (7.2 +/- 1.1 ml/kg and 6.6 +/- 1.2 ml/kg, respectively) and renal sodium excretion (599 +/- 146 micromol/kg and 555 +/- 131 micromol/kg, respectively) compared with controls (2.8 +/- 0.5 ml/kg and 80 +/- 33 mciromol/kg; P < 0.05) over the 6-h post-dose period. Telmisartan at all intravenous doses and at 3.0 mg/kg orally increased the urinary excretion of chloride significantly over the 6-h post-dose period compared with vehicle alone. The excretion of potassium and creatinine were unchanged by any treatment. Telmisartan 1.0 mg/kg administered orally for 12 days produced similar results. In conclusion, acute intravenous or oral as well as subchronic oral administration of telmisartan to conscious dogs promotes diuresis and natriuresis without affecting potassium or creatinine excretion.     

Effect of concomitant administration of piperacillin on the dispositions of netilmicin and tobramycin in patients with end-stage renal disease.

The effect of piperacillin administration on the dispositions of netilmicin and tobramycin was assessed in 12 chronic hemodialysis patients. Six subjects each received netilmicin (2 mg/kg) or tobramycin (2 mg/kg) alone and in combination with piperacillin (4 g every 12 h for four doses). Subjects also received a single dose of piperacillin (4 g) on a separate occasion. The serum concentration-versus-time profiles of netilmicin and tobramycin were biexponential. The terminal elimination half-life (t1/2 beta) of tobramycin was markedly reduced (59.62 +/- 25.18 [mean +/- standard deviation] versus 24.71 +/- 5.41 h) and total body clearance (CLP) was significantly increased in the presence of piperacillin (3.45 +/- 1.61 versus 7.16 +/- 1.64 ml/min). In contrast, the t1/2 beta (41.80 +/- 13.24 versus 40.07 +/- 10.37 h) and CLP (5.11 +/- 2.15 versus 5.55 +/- 2.32 ml/min) of netilmicin were not significantly altered when netilmicin was administered in combination with piperacillin. No change in the central or steady-state volume of distribution of netilmicin or tobramycin was observed. The disposition of piperacillin in hemodialysis patients was not altered in the presence of either aminoglycoside antibiotic. Although no adjustment in netilmicin dosing is required, tobramycin should be administered more frequently when given concomitantly with piperacillin to hemodialysis patients to avoid prolonged periods of subtherapeutic concentrations.