Pharmacokinetics of cyclosporine in heart and lung transplant candidates and recipients with cystic fibrosis and Eisenmenger's syndrome.

OBJECTIVE: To compare the pharmacokinetics of cyclosporine in patients with either cystic fibrosis or Eisenmenger's syndrome. METHODS: Patients in the study were heart and lung transplant candidates with either cystic fibrosis (n = 6) or Eisenmenger's syndrome (n = 5), as well as patients who received heart and lung transplantation for either cystic fibrosis (n = 13) or Eisenmenger's syndrome (n = 7). This was no experimental pharmacokinetic study in transplant candidates and an exploratory population pharmacokinetic study in transplant recipients. RESULTS: Patients with cystic fibrosis showed higher blood cyclosporine clearance, higher apparent oral clearance, shorter mean residence time, and more erratic absorption. The coefficient of variation of pharmacokinetic parameters was higher in patients with cystic fibrosis. There were no significant differences in metabolite indexes between the two groups of patients after either oral or intravenous administration. A significant negative correlation was found between cyclosporine clearance and hematocrit (r = 0.81 [95% confidence interval, -0.95 to -0.4.1]). Dose-normalized predose blood concentration measurements were lower in patients with cystic fibrosis after transplantation. There was a significant correlation between hematocrit and log dose-normalized cyclosporine concentration (r = 0.40 [95% confidence interval, 0.30 to 0.49]). The total daily dose per 100 ng/ml trough blood concentration required was estimated to be 2.36 times (95% confidence interval, 1.96 to 2.84) higher in patients with cystic fibrosis. CONCLUSIONS: Cyclosporine pharmacokinetics is more variable in patients with cystic fibrosis. The difference in cyclosporine clearance between the two groups is accounted for by differences in binding in blood rather than metabolism. The findings suggest that patients with cystic fibrosis could be conservatively given initial oral doses that are 1.5 times higher than those for patients who receive transplants because of Eisenmenger's syndrome.

Blood cyclosporin concentrations and the short-term risk of lung rejection following heart-lung transplantation.

1. The relationship between blood cyclosporin concentration (CyACb) and a patient's risk of organ rejection following heart-lung (HL) transplantation was investigated. 2. Longitudinal data were collected for 90 days post-operation for 31 HL transplant recipients. Following exploratory analysis, a multiple logistic regression model with a binary outcome variable representing presence or absence of lung rejection (as defined on biopsy findings and/or intention to treat) in the next 5 days was fitted to the data. 3. A significant interaction between time post-transplant and CyACb was found. During weeks 1-3, the relative risk (RR) of rejection per unit increase in log(e) (5-day mean CyACb) was reduced: RR = 0.29, 95% confidence interval (CI) = (0.12, 0.72). After 3 post-operative weeks, this trend was reversed: RR = 1.61, 95% CI = (0.96, 2.70). Increases in cyclosporin dose (CyAD) and in coefficient of variation (CV) for both CyAD and CyACb over the previous 10 days significantly increased the risk of rejection: RR per unit increase in log(e) (5-day mean CyAD) = 2.72, 95% CI = (1.18, 6.25); RR per increase of 10% (i.e. from, say, 20% to 30%) in the CV for CyAD = 1.20, 95% CI = (1.07, 1.36); RR if the CV for CyACb > 40% = 1.51, 95% CI = (1.01, 2.27). Administration of high dose steroids in the previous 5 days was found to protect against further rejection: RR if steroid treatment was given = 0.23, 95% CI = (0.13, 0.38).(ABSTRACT TRUNCATED AT 250 WORDS)

Blood cyclosporin concentrations but not doses correlate with acute changes in renal function following heart and heart-lung transplantation.

The relationship between changes in cyclosporin (CyA) dose or CyA blood concentration and the reciprocal creatinine concentration was investigated by cross-correlation analysis over the first 3 postoperative months in 32 consecutive heart and heart-lung recipients. Exploratory analysis suggested that early changes in renal function, probably attributable to recovery from preoperative cardiac failure, obscured later underlying correlations. Therefore, all data up to the first nadir in plasma creatinine following transplantation were excluded from the analysis. Five-day mean CyA doses or blood concentrations were cross-correlated with 5-day mean reciprocal creatinine concentrations measured either in the same 5-day period or with the creatinine measured up to two 5-day periods later. Although a significant correlation was found between CyA dose and blood concentration (the 95% confidence interval of the population correlation coefficient did not overlap zero), there was no relationship between dose and changes in renal function. The blood CyA concentration, however, correlated significantly with the reciprocal creatinine concentration measured in the same 5-day period and was also predictive of changes in creatinine measured in the subsequent 5-day period. Thus, a major criterion for therapeutic drug monitoring had been fulfilled: CyA dosage adjustment based on blood CyA concentrations, as the intermediate therapeutic end point, is helpful in the management of acute nephrotoxicity in heart and heart-lung transplant recipients because of the lack of a dose-effect relationship. Regular CyA monitoring and appropriate dosage adjustment is essential for the management of acute nephrotoxicity in the first 3 months following heart or heart-lung transplantation.

Altered pharmacokinetics of cyclosporin in heart-lung transplant recipients with cystic fibrosis.

The cyclosporin dose versus blood concentration relationship for 11 heart-lung transplant recipients with cystic fibrosis was studied retrospectively. Eleven patients, closely matched for age and gender, who received heart-lung transplantation for other diseases were selected as controls. Cystic fibrosis patients received 16.7 (SD 7.2) mg/kg/day of oral cyclosporin compared with 8.2 (SD 1.9) mg/kg/day given to the control patients (p less than 0.01). Nine of the cystic fibrosis patients received higher mean daily doses of cyclosporin. Mean blood cyclosporin concentrations were, however, not significantly different (p = 0.58), and there were no apparent differences in clinical outcome in terms of rejection, infection, and nephrotoxicity in the two groups. The apparent oral clearance of cyclosporin was significantly higher (p less than 0.01) in cystic fibrosis patients. Cyclosporin dosage individualization with the aid of cyclosporin blood concentration measurements is critically important in this subpopulation of heart-lung transplant recipients.

Studies on the mechanism of coumarin-induced toxicity in rat hepatocytes: comparison with dihydrocoumarin and other coumarin metabolites.

Single doses of coumarin (125 mg/kg, ip) produced a depletion of hepatic nonprotein sulfhydryl groups (mainly reduced glutathione; GSH) in young male Sprague-Dawley rats after 2 hr and increased liver weight and produced hepatic centrilobular necrosis after 24 hr. Coumarin also produced time- and dose-dependent toxic effects in primary rat hepatocyte cultures. A marked reduction of GSH levels was also observed in vitro and this was not due either to the formation of oxidized glutathione (GSSG) or to the leakage of GSH and/or GSSG from the hepatocytes. Coumarin-induced toxicity in rat hepatocytes could be inhibited by the cytochrome P450 inhibitors ellipticine and metyrapone and potentiated by depleting hepatocyte GSH levels with diethyl maleate. In contrast to coumarin, dihydrocoumarin--which lacks the 3,4-double bond--produced little toxicity in rat hepatocytes either in vivo (127 and 254 mg/kg, ip) or in vitro. Similarly, coumarin was more toxic to rat hepatocytes than a number of known coumarin metabolites including 3- and 7-hydroxycoumarin and o-hydroxyphenylacetic acid. The results of these studies demonstrate a good in vivo/in vitro correlation for the effects of coumarin and dihydrocoumarin in rat hepatocytes. Furthermore, the data suggest that coumarin hepatoxicity in the rat is due to coumarin bioactivation by cytochrome P450-dependent enzymes to a toxic metabolite(s), which may be a coumarin 3,4-epoxide intermediate. GSH appears to protect against coumarin-induced toxicity possibly by the formation of conjugates with the toxic coumarin metabolite(s).