The effect of candesartan on the pharmacokinetics of enalaprilat in nephrotic rats

BACKGROUND AND OBJECTIVES

The adverse reactions in combination of angiotensin-converting enzyme inhibitors (ACEIs) and Ang II receptor blockers (ARBs) were severer than that in monotherapy for patients with nephropathy. The effect of candesartan on pharmacokinetics of enalaprilat in nephrotic rats was investigated to make references for the clinical therapy in patients with nephropathy to avoid related adverse effects.

MATERIALS AND METHODS

Nephrotic rats were prepared by adriamycin injection. Control group and one nephrotic group received enalapril alone, another nephrotic group received enalapril and candesartan simultaneously. Blood samples were drawn at time points after a single oral administration. The concentration of enalaprilat was determined using LC-MS/MS.

RESULTS

Compared with control group and nephrotic group received enalapril alone respectively, Tmax of enalaprilat in nephrotic group received both enalapril and candesartan cilexetil prolonged about 21.43% and 6.224%, respectively; AUC(0-t) increased by 185.3% and 60.63%, respectively; Cmax increased by 219.4% and 56.64%, respectively; t1/2 increased by 163.7% and 30.05%, respectively; CL/F reduced by 65.12% and 40.78%, respectively. There were no significant differences of the V1/F of enalaprilat between three groups. The CL/F and t1/2 of enalaprilat showed significant correlations with serum creatinine (Scr) respectively (r = -0.7502; r = 0.5626).

DISCUSSION

The combination with candesartan in nephrotic rats significantly changed the pharmacokinetics of enalaprilat, showing increased accumulation and decreased elimination. In view of these findings, we should lower dosage and prolong dosing interval for nephrotic patients in the combination of enalapril and candesartan.

Pharmacokinetics and pharmacodynamics profiles of enalapril maleate in healthy volunteers following determination of enalapril and enalaprilat by two specific enzyme immunoassays

BACKGROUND AND OBJECTIVES

Most of the pharmacokinetic (PK) parameters for enalapril and enalaprilat were established following determination of the drug and its metabolite, using angiotensin converting enzyme (ACE) inhibition assays. In these methods, enalapril has to be hydrolysed to enalaprilat first and then assayed. The purpose of this study was to re-estimate the PK parameters of enalapril and enalaprilat in healthy volunteers using two specific enzyme immunoassays for enalapril and enalaprilat.

METHODS

The rate and extent of absorption of enalapril and enalaprilat from a 10-mg dose of two enalapril maleate commercial brands (Renetic and Enalapril) were estimated using a two-way-cross over design with 1-week washout period. Blood pressure was also measured at specified time intervals and correlated to enalaprilat plasma concentrations.

RESULTS

For enalapril, the AUC(o-->infinity) values (Mean+/-SD) were 450.0+/-199.5 and 479.6+/-215.6 ng h/mL, Cmax values were 313.5+/-139.6 and 310.1+/-186.6 ng/mL, Tmax values were 1.06+/-0.30 h and 1.13+/-0.22 h, and t1/2 ranged between 0.3 to 6.1 h (1.6+/-1.5) and 0.40 to 5.05 h (1.3+/-1.0), for the two brands. For enalaprilat, the AUC(o-->infinity) values were 266.9+/-122.7 and 255.9+/-121.8 ng h/ml, Cmax values were 54.8+/-29.5 and 57.2+/-29.0 ng/mL, Tmax values were 4.6+/-1.6 h and 4.3+/-1.45 h, and t1/2 ranged between 1.1 to 10.5 h (4.5+/-2.9) and 0.6 to 9.4 h (3.5+/-2.5) for the two brands.

CONCLUSIONS

Cmax values for enalapril are about 10 times those published in the literature and the rate and extent of absorption of the two brands of enalapril and their deesterification to enalaprilat following the administration of either brand were bioequivalent. Secondly, enalaprilat concentrations at 12-24 h following a single oral dose of enalapril in healthy volunteers were lower than those reported in the literature. The values reported here correlated with the return of blood pressure to predose level. Thirdly, enzyme immunoassays for enalapril and enalaprilat are better than ACE inhibition assays and can be used in bioequivalence assessment of enalapril and enalaprilat and for therapeutic drug monitoring in a clinical laboratory setting.

Gender differences in angiotensin-converting enzyme (ACE) activity and inhibition by enalaprilat in healthy volunteers

This bioequivalence study was supported by Laboratorios Vita S.A (Barcelona). To study the existence of differences between sexes in the pharmacokinetic and pharmacodynamic of enalapril. A bioequivalence phase 1 clinical trial to compare two formulations of enalapril was carried out in twenty-four healthy volunteers (12 men and 12 women). Enalaprilat concentrations, plasma activity of ACE, and systolic and diastolic arterial pressure were determined. Basal activity of ACE and the maximum ACE inhibition were significantly smaller in women. No significant differences in the drug concentration required to produce 50% of Emax were observed. Women had lower systolic arterial pressures and ACE activities than men at any time, even when the maximum inhibition of the ACE activity was attained. Women at the follicular phase had a minimum activity of ACE significantly inferior than men. Healthy women had lower systolic arterial pressures and ACE activities than men.

Characterization of the pharmacokinetic and pharmacodynamic properties of the angiotensin-converting enzyme inhibitor, enalapril, in horses

The pharmacokinetics of enalapril (0.5 mg/kg i.v.) and the pharmacodynamics of enalapril (0.5 mg/kg PO) in 5 mares were investigated. After single i.v. dosing, concentrations of enalapril and enalaprilat, its active metabolite, were measured. Two weeks later, enalapril was administered by nasogastric tube. Potassium, creatinine, blood urea nitrogen (BUN), enalapril, and enalaprilat concentrations and angiotensin converting enzyme (ACE) activity were measured in serum. In addition, heart rate, blood pressure, digital venous blood gases, and lactate were measured. Two weeks later, enalapril was again administered by nasogastric tube. To mimic activation of the renin-angiotensin-aldosterone system, angiotensin I (0.5 microg/kg) was administered at fixed intervals, followed by blood-pressure and heart-rate measurement. The elimination half lives of enalapril and enalaprilat were 0.59 and 1.25 hours, respectively, after i.v. administration. After PO administration, enalapril and enalaprilat were not detectable in serum. There was a tendency (P = .0625) toward a decrease in ACE activity 45-120 minutes after enalapril administration, but ACE activity suppression was never > 16%. There was a tendency (P = .0625) toward a decrease in mean arterial pressure (MAP) 6-8 hours after enalapril administration. Serum concentrations of potassium, creatinine, and BUN and digital venous blood gases and lactate concentrations did not change. In response to angiotensin I, there was a tendency (P = .0625) toward a decrease in the MAP response 4-24 hours after enalapril administration. Single-dose enalapril at 0.5 mg/kg PO did not demonstrate significant availability, pharmacodynamic effect, or substantial suppression of ACE activity.

Relative bioavailability study of 20-mg enalapril tablets in healthy male volunteers

The pharmacokinetic and relative bioavailability studies of 20-mg enalapril tablets, the test product manufactured by Biolab, Thailand compared to the reference product (Merck Sharp & Dohme, USA) was conducted in 14 healthy Thai male volunteers following a single dose, two-period, crossover design. Each subject received 20-mg enalapril tablets of both formulations with a 1-week washout period. Plasma samples collected over a 24-h period after administration were analyzed by LC/MS/MS. Pharmacokinetic parameters were determined by using non-compartmental analysis. Regarding bioequivalence testing, the 90 per cent confidence intervals of Cmax and AUC(0-infinity) ratios (test/reference) of enalapril were 101.8-134.9 per cent and 105.9-121.4 per cent and those of enalaprilat were 104.2-122.3 per cent and 104.5-118.1 per cent. Based on the European bioequivalence guideline, the 90 per cent confidence intervals of Cmax and AUC(0-infinity) ratios of both parent and metabolite forms were within the acceptable ranges of 70-143 per cent and 80-125 per cent, respectively. It was concluded that the test formulation was bioequivalent to the reference formulation and both formulations can be used interchangeably in clinical practice.

Myocardial uptake and biochemical and hemodynamic effects of ACE inhibitors in humans

There is little information on the processes affecting selective tissue ACE inhibition and the implications in human subjects. We compared intravenously administered ACE inhibitors, perindoprilat and enalaprilat, for myocardial drug uptake and effects on angiotensin and bradykinin peptides versus hemodynamic effects in 25 patients with stable angina and well-preserved left ventricular systolic function. Myocardial uptake was rapid and more efficient for perindoprilat than for enalaprilat (peak content at 26+/-3 and 30+/-4 seconds, 0.58+/-0.12% and 0.27+/-0.07% of the administered dose for perindoprilat and enalaprilat, respectively, P=0.04 for difference). Both drugs caused a decrease in angiotensin (Ang) II level, an increase in Ang I level, and reduction in Ang II/Ang I ratio in arterial and coronary sinus blood. Bradykinin (BK)-(1-9) and BK-(1-8) levels increased in arterial blood and BK-(1-8) levels increased in coronary sinus blood after drug administration. Perindoprilat and enalaprilat caused a small decrease in mean arterial pressure (-3+/-1%, P<0.05; and -4+/-1%, P<0.01, respectively) and LV+dP/dt (-5.8+/-1.7%, P<0.01 and -4.2+/-2.8%, P<0.05, respectively), whereas systemic vascular resistance index was unchanged. Despite relatively cardioselective uptake of perindoprilat, both drugs had similar effects on the cardiac metabolism of angiotensin and bradykinin and on cardiac function. Under resting conditions, both drugs exerted small negative inotropic effects.

Determination of enalapril and enalaprilat by enzyme linked immunosorbent assays: application to pharmacokinetic and pharmacodynamic analysis

We have developed two enzyme linked immunosorbent assay (ELISA) methods for determining enalapril and enalaprilat in plasma. In this study, 48 healthy subjects received an oral dose of either 10 or 20 mg of enalapril and plasma concentrations of enalapril and enalaprilat were determined by their specific ELISA methods. These plasma concentrations and blood pressure measurements were applied to evaluate the pharmacokinetic (PK) and pharmacodynamic (PD) parameters of both enalapril and enalaprilat. The enalapril values for the area under the curve (AUC(0)--> infinity ) were 480 +/- 216 and 832 +/- 325 ngh/mL, maximum plasma concentrations (C(max)) were 310 +/- 187 and 481 +/- 185 ng/mL, and times required to reach the maximum concentration t(max) were 1.13 +/- 0.22 and 1.09 +/- 0.33 h for 10 and 20 mg doses, respectively. The enalaprilat values for AUC(0)--> infinity were 256 +/- 122 and 383 +/- 158 ngh/mL, C(max) values were 57 +/- 29 and 72.9 +/- 33.6 ng/mL and t(max) values were 4.28 +/- 1.45 and 4.05 +/- 01.22 h for 10 and 20 mg doses, respectively. The C(max) values of enalapril were approximately 10 times higher than those in the literature, which were determined by angiotensin converting enzyme (ACE) inhibition assays following alkaline hydrolysis, but similar to those of enalaprilat. The PD profiles revealed a significant correlation between enalaprilat concentrations in plasma and the decrease in systolic and diastolic blood pressures (r = -0.95 with P < 0.001 and r = -0.95 with P < 0.001), respectively, following a single oral dose of enalapril. These ELISA methods have the advantage of being simple, accurate, sensitive, and do not depend on enalaprilat binding to ACE. Such methods can be used for analysis and kinetic testing of enalapril and enalaprilat in biological fluids.

High serum enalaprilat in chronic renal failure

BACKGROUND

Most angiotensin-converting enzyme (ACE) inhibitors and their metabolites are excreted renally and doses should hence be reduced in renal insufficiency. We studied whether the dosage of enalapril in daily clinical practice is associated with drug accumulation of enalaprilat in chronic renal failure.

METHODS

Fifty nine out-patients with plasma creatinine >150 micromol/L and chronic antihypertensive treatment with enalapril were investigated, in a cross-sectional design.

RESULTS

Median glomerular filtration rate (GFR) was 23(range 6-60) ml/minute/1.73 m2. The daily dose of enalapril was 10 (2.5-20) mg and the trough serum concentration of enalaprilat was 31.8 (<2.5-584.7)ng/ml. Ninety percent of the patients had higher serum concentrations of enalaprilat than has been reported in subjects with normal kidney function, and a marked elevation of serum enalaprilat was observed in patients with GFR <30 ml/minute. All but three patients had serum ACE activity below the reference range. The ACE genotype did not influence the results. Additional pharmacokinetic studies were done in nine patients in whom GFR was 23 (10-42)ml/minute/1.73 m2. The median clearance of enalaprilat was 28 (16-68) ml/minute and correlated linearly with GFR (r=0.86, p=0.003). Intra-subject day-to-day variation in trough concentrations was 19.7%.

CONCLUSION

Patients with chronic renal failure given small or moderately high doses of enalapril may thus have markedly elevated levels of serum enalaprilat. Whether this affords extra renoprotection, or on the contrary may inappropriately impair renal function, is not known, and should be investigated in prospective, controlled studies.

Comparative study of effects of angiotensin II receptor antagonist, KD3-671, and angiotensin converting enzyme inhibitor, enalaprilat, on cough reflex in guinea pig

Angiotensin converting enzyme (ACE) inhibitor prevents the inactivation of bradykinin by inhibiting ACE activity, leading to side effects such as dry cough and angioedema. KD3-671 is a novel nonpeptide angiotensin II antagonist which is expected to exhibit persistent hypotensive action without these side effects. In this study, we investigated the relationship between the pharmacokinetics and cough-inducing effect of this drug in guinea-pig, compared with that of an ACE inhibitor, enalaprilat. KD3-671 was not significantly different from the vehicle treatment in the ability to induce coughing, whereas enalaprilat significantly enhanced coughing compared with the vehicle treatment. Thus, as expected from its mechanism of pharmacological action, KD3-671 did not induce coughing. We suggest that the citric acid-induced guinea pig coughing model will be useful in preclinical studies to examine the effect of drug on pulmonary function.

Evaluation of hypotonic preswelling method for encapsulation of enalaprilat in intact human erythrocytes

The hypotonic preswelling method for encapsulation of drugs in intact human erythrocytes was evaluated using enalaprilat as a model peptide-like drug. Several process variables, including volume, concentration, pH, and method of addition of drug solution, type of erythrocyte-suspending medium, temperature, initial packed density of erythrocytes, and individual process steps, were exploited with respect to their effects on the loading parameters (i.e., loaded amount, efficiency of entrapment, and cell recovery). In addition, the probable mechanism by which the erythrocytes were loaded by enalaprilat at the point of lysis was shown to be a simple concentration gradient-based diffusion through membrane openings occurring on hemolysis. Finally, the adopted method was validated, and the results showed a considerable degree of reproducibility and recovery for the entire loading procedure.

Dissociation between ACE activity and autonomic response to ACE inhibition in patients with heart failure

BACKGROUND

Administration of angiotensin-converting enzyme (ACE) inhibitors to patients with congestive heart failure has been shown to increase parasympathetic tone as indicated by increases in high-frequency heart rate variability. The mechanism for this effect, including its relation to changes in baroreflex activity, blood pressure variability, and suppression of ACE activity, remains undefined. This study was designed to test the relation of these variables, which may govern changes in autonomic activity, to the previously described increase in parasympathetic tone.

METHODS

Seven patients with heart failure received a 3-hour infusion of the ACE inhibitor enalaprilat. Hemodynamic variables and parameters of heart rate and blood pressure variability, baroreflex gain derived from the interaction of heart rate and blood pressure variability, and serum ACE activity were measured during and after the infusion. Measures of heart rate and blood pressure variability were also compared against a historic control group.

RESULTS

Serum ACE activity was significantly suppressed throughout and after enalaprilat infusion. Hemodynamic measures did not change other than a small decline in right atrial and pulmonary capillary wedge pressures. Parasympathetic tone showed an initial significant increase with a peak at 2 hours but then declined below baseline 8 hours after initiation of enalaprilat infusion. Sympathetically influenced low-frequency heart rate variability was significantly increased above baseline in the enalaprilat treatment group 8 hours after initiation of the infusion. Baroreflex gain showed a significant trend to an increase with the maximum value coinciding with the peak in parasympathetic tone. There was no change in blood pressure variability in the enalaprilat group and no change in baroreflex gain, heart rate variability, or blood pressure variability in the control group.

CONCLUSIONS

Parasympathetic tone and baroreflex gain increased with parenteral administration of an ACE inhibitor but subsequently decreased below baseline values despite continued suppression of serum ACE activity. The dissociation between ACE suppression and autonomic response to ACE inhibition indicates that enzyme systems not reflected by plasma ACE activity or independent from the classic pathways of angiotensin formation contribute to the regulation of the autonomic response to ACE inhibition in patients with heart failure. The absence of significant change in hemodynamic variables or in blood pressure variability indicates that these autonomic changes are not an indirect reflex response to ACE inhibitor-induced vasodilation or hemodynamic baroreceptor stimulation.

Comparison of the pharmacokinetics of fosinoprilat with enalaprilat and lisinopril in patients with congestive heart failure and chronic renal insufficiency

AIMS

To compare the serum pharmacokinetics of fosinoprilat with enalaprilat and lisinopril after 1 and 10 days of dosing with fosinopril, enalapril and lisinopril.

METHODS

Patients with congestive heart failure (CHF, NYHA Class II-IV) and chronic renal insufficiency (creatinine clearance </=30 ml min-1 ) were randomized to receive fosinopril, enalapril or lisinopril in two parallel-group studies. In the first study 24 patients were treated with 10 mg fosinopril (n=12 patients) or 2.5 mg enalapril (n=12) every morning for 10 consecutive days. In the second study 31 patients were treated with 10 mg fosinopril (n=16 patients) or 5 mg lisinopril (n=15) every morning for 10 consecutive days. Samples of blood were collected for determination of pharmacokinetic parameters. The area under the curve (AUC) between the first and last days of treatment and the accumulation index (AI) were the primary outcome measures.

RESULTS

All three angiotensin converting enzyme (ACE) inhibitors exhibited a significant increase in AUC between the first and last days of treatment in both studies. The difference between the AI for fosinoprilat (1.41) and enalaprilat (1.96) was statistically significant (95% CI: 1.05, 1.84). Similarly, the difference between the AI for fosinoprilat (1.21) and lisinopril (2.76) was statistically significant (95% CI: 1.85, 2.69). All three ACE inhibitors completely inhibited serum ACE for 24 h. All treatments were well tolerated.

CONCLUSIONS

Fosinoprilat exhibits significantly less accumulation than enalaprilat or lisinopril in patients with CHF and renal insufficiency, most probably because fosinoprilat is eliminated by both the kidney and liver, and increased hepatic elimination can compensate for reduced renal clearance in patients with kidney dysfunction.

Pharmacokinetic studies of enalaprilat in the in vitro perfused human placental lobule system

The objectives of this study were to evaluate the transplacental kinetics and effects on placental function of the angiotensin converting enzyme (ACE) inhibitor, enalaprilat, in the dually perfused human placental lobule system. When placed in the maternal perfusate at a high therapeutic serum concentration (150 ng/ml), enalaprilat was rapidly transferred from the maternal perfusate into placental tissue followed by a gradual release from the placenta into the fetal perfusate. Cmax and AUC values for enalaprilat in the maternal perfusate were approximately 3 times higher than in the fetal perfusate, and drug levels did not equilibrate between maternal and fetal perfusates during the 4-6 hours of perfusion. The more highly perfused regions of the placental lobule had higher drug levels than non-perfused areas. At the end of the perfusion period, the mean percent of total drug added in the maternal perfusate was 59%, with 23% in the fetal perfusate and the remainder (18%) in placental tissue. Despite the relatively high levels of drug found in placental tissue, there were no alterations in placental function as measured by fetal volume loss, fetal pressure, glucose utilization, lactate production, hCG release, net fetal oxygen transfer, and oxygen consumption. Results from this study clearly document placental transfer of enalaprilat in the perfused human placental lobule system. The lack of effect on placental function suggests that enalaprilat has no direct effect on fetoplacental vascular beds, and that fetal hypotension occurring from ACE inhibitor exposure may be due to direct effects on the fetal kidney and not to decreased perfusion of fetoplacental vascular beds; these findings require further validation in an in vivo model.

Treatment of congestive heart failure: experience with fosinopril

The prevalence of congestive heart failure (CHF), a debilitating condition associated with impaired quality of life and markedly shortened life expectancy, is increasing. The goals of therapy for CHF are reducing symptoms, improving functional capacity, and slowing the progression of the condition. In most cases, this is best achieved with a combination of diuretic and vasodilator therapy. Angiotensin-converting enzyme (ACE) inhibitors have several advantages over other vasodilatory agents and are becoming widely used for treating CHF. The most recently introduced ACE inhibitor, fosinopril, is at least as effective as enalapril, and its dual and compensatory route of excretion is particularly advantageous in patients with renal insufficiency. Fosinopril may also have particular benefits in the prevention of CHF, as it has beneficial effects on cardiac function that may help delay the onset of overt cardiac failure.

Mechanism of angiotensin converting enzyme inhibitor-related anemia in renal transplant recipients

To delineate the pathogenesis of the reduction in hemoglobin occurring in renal transplant patients treated with angiotensin converting enzyme inhibitors (ACEI) and azathioprine (AZA) a controlled, prospective trial of ACEI withdrawal was conducted. The ACEI was replaced by nifedipine or clonidine in 15 kidney transplant patients immunosuppressed with AZA and prednisone (enalapril in 14 and captopril in 1). Before and during 10 to 12 weeks after withdrawal of the ACEI, AZA metabolites, renal function parameters and hematological parameters including erythropoietin and reticulocytes were evaluated. Enalaprilat levels were measured and compared with 15 similar patients matched for transplant function and enalapril dosage immunosuppressed with cyclosporine and prednisone. AZA metabolites did not differ significantly in the presence or absence of the ACEI. Enalaprilat levels also showed no significant difference between the two patient groups treated with AZA or cyclosporine. Hematocrit and hemoglobin increased significantly from 37.5 +/- 6.4 to 39.7 +/- 3.6% (mean +/- SD, P = 0.02) and 12.8 +/- 2.2 to 13.5 +/- 1.2 g/dl, P = 0.04, respectively, 10 to 12 weeks after ACEI treatment had been discontinued. Simultaneously numbers of reticulocytes and erythropoietin concentrations rose significantly after 2, 4 and 10 weeks, with a peak at two weeks (from 14.1 +/- 3.8 to 20.6 +/- 8.0/1000, P < 0.05 and from 14.3 +/- 12.4 to 29.3 +/- 54.5 mU/ml, P < 0.05, respectively). In conclusion, ACEI-related anemia in renal transplant recipients seems to be due to the erythropoietin-lowering effect of this group of drugs. A pharmacokinetic interaction between AZA and enalapril is not likely since plasma enalaprilat levels were independent of the immunosuppressive regimen and AZA metabolite levels were unchanged in the presence and absence of the ACEI. Several mechanisms by which angiotensin converting enzyme blockade may cause a decrease in circulating erythropoietin are discussed.

Pharmacokinetic and fetal cardiovascular effects of enalaprilat administration to maternal rhesus macaques

OBJECTIVE

The purpose of this study was to determine the extent of placental transfer of the angiotensin-converting enzyme inhibitor enalaprilat and the effects on maternal and fetal cardiovascular parameters.

STUDY DESIGN

Between gestational days 122 and 126 (term 167 days) five rhesus macaques underwent surgery for implantation of maternal and fetal vascular catheters. At least 4 days after surgery maternal and fetal blood pressures and heart rates were recorded for 1 hour. This was followed by a 5-minute maternal venous infusion of saline solution vehicle and recording for an additional hour. Enalaprilat was then infused over 5 minutes through the maternal femoral artery at doses of 0.05, 0.1, or 0.2 mg/kg. Maternal and fetal arterial blood samples were collected for determination of blood gas status and plasma enalaprilat concentrations.

RESULTS

Enalaprilat rapidly crossed the placenta, and fetal values for areas under the concentration time curve were 50% to 65% of maternal values across dose groups. Drug was retained in the fetal plasma approximately threefold to fourfold longer than in maternal plasma. Maternal heart rate, blood pressure, arterial Po2 and pH were unchanged after enalaprilat infusion, as were fetal heart rate and blood gases. In contrast, fetal arterial pressure decreased significantly (19% to 23%, p < 0.01) after maternal treatment with 0.1 and 0.2 mg/kg and remained depressed throughout the 6-hour study interval. At 0.05 mg/kg fetal arterial pressure was decreased by 13% from baseline; differences were not significantly different (p > 0.05).

CONCLUSIONS

Results from this study indicate that enalaprilat rapidly crosses the primate placenta with a single intravenous administration to the mother, resulting in significant and prolonged reduction of fetal arterial pressure. Because maternal cardiovascular parameters were unaffected, enalaprilat appears to have a direct effect on fetal arterial pressure.

The kinetic profiles of enalapril and enalaprilat and their possible developmental changes in pediatric patients with congestive heart failure

Enalapril and enalaprilat concentrations were measured after enalapril maleate (0.05 to 0.3 mg/kg) was administered orally to 12 pediatric patients (age range, 10 days to 6 1/2 years) with congestive heart failure caused by congenital heart disease and compared with those obtained from seven normal adults (age range, 21 to 39 years). When normalized to the oral 1 mg/m2 dose of enalapril maleate, the mean +/- SD area under the serum concentration-time curve (AUC) of enalaprilat, a pharmacologically active angiotensin-converting enzyme inhibitor, did not differ significantly between the pediatric group aged > 20 days and adult group (83.1 +/- 47.0 versus 64.6 +/- 17.8 ng.hr/ml per 1 mg/m2). When normalized to the oral 0.1 mg/kg dose, the mean AUC was significantly (p < 0.05) smaller in this pediatric group than in the adult group (138.4 +/- 69.2 versus 245.7 +/- 61.8 ng.hr/ml per 0.1 mg/kg). The AUC observed in three younger (age < 20 days) subjects tended to be much greater compared with infants aged > 20 days. The mean AUC ratio of enalaprilat to enalapril was significantly (p < 0.05) lower in the older pediatric subgroup (2.0 +/- 1.0) than in the adult group (3.4 +/- 1.6), whereas the mean ratios were comparable between the two subdivided pediatric groups. The results suggest that the oral enalapril dose would be better determined on a body surface area rather than on a body weight basis in pediatric patients with congestive heart failure aged > 20 days. The oral dosage should be much reduced in infants with congestive heart failure aged < 20 days compared with those aged > 20 days.(ABSTRACT TRUNCATED AT 250 WORDS)

Intestinal drug absorption during induced net water absorption in man; a mechanistic study using antipyrine, atenolol and enalaprilat

1. The effect of induced water absorption on the intestinal permeability of antipyrine, atenolol and enalaprilat in the proximal jejunum was studied in eight healthy subjects with a regional intestinal perfusion technique. 2. The mean (+/- s.d.) net water flux changed from a secretory status of 1.2 +/- 1.2 ml h-1 cm-1 to an absorptive status of -3.7 +/- 3.5 ml h-1 cm-1 (P < 0.0025) on the introduction of a hypo-osmolar glucose-containing electrolyte solution. 3. The mean permeability values for the three drugs in the eight subjects were unchanged despite the increase in net water absorption (5.7 +/- 3.0 to 7.0 +/- 3.6 x 10(-4) cm s-1 for antipyrine, 0.1 +/- 0.2 to 0.2 +/- 0.2 x 10(-4) cm s-1 for atenolol and 0.3 +/- 0.3 to 0.1 +/- 0.2 x 10(-4) cm s-1 for enalaprilat). One subject showed a large change in the permeability for antipyrine and atenolol in parallel with a large increase in water absorption, but enalaprilat was unaffected. 4. The luminal recovery of PEG 4000 was similar before (100 +/- 4%) and during (101 +/- 7%) induction of water absorption, which indicates that the barrier function of the intestine appears to be maintained during glucose-stimulated fluid absorption in man. 5. We conclude that induced net water absorption in man does not influence the paracellular permeability of hydrophilic drugs or drugs with high molecular weight to any significant extent.(ABSTRACT TRUNCATED AT 250 WORDS)

Enalapril clinical pharmacokinetics and pharmacokinetic-pharmacodynamic relationships. An overview

The conventional pharmacokinetic profile of the angiotensin converting enzyme (ACE) inhibitor, enalapril, is a lipid-soluble and relatively inactive prodrug with good oral absorption (60 to 70%), a rapid peak plasma concentration (1 hour) and rapid clearance (undetectable by 4 hours) by de-esterification in the liver to a primary active diacid metabolite, enalaprilat. Peak plasma enalaprilat concentrations occur 2 to 4 hours after oral enalapril administration. Elimination thereafter is biphasic, with an initial phase which reflects renal filtration (elimination half-life 2 to 6 hours) and a subsequent prolonged phase (elimination half-life 36 hours), the latter representing equilibration of drug from tissue distribution sites. The prolonged phase does not contribute to drug accumulation on repeated administration but is thought to be of pharmacological significance in mediating drug effects. Renal impairment [particularly creatinine clearance < 20 ml/min (< 1.2 L/h)] results in significant accumulation of enalaprilat and necessitates dosage reduction. Accumulation is probably the cause of reduced elimination in healthy elderly individuals and in patients with concomitant diabetes, hypertension and heart failure. Conventional pharmacokinetic approaches have recently been extended by more detailed descriptions of the nonlinear binding of enalaprilat to ACE in plasma and tissue sites. As a result of these new approaches, there have been significant improvements in the characterisation of concentration-time profiles for single-dose administration and the translation to steady-state. Such improvements have further importance for the accurate integration of the pharmacokinetic and pharmacodynamic responses to enalapril(at) in a concentration-effect model.(ABSTRACT TRUNCATED AT 250 WORDS)

Combined recirculation of the rat liver and kidney: studies with enalapril and enalaprilat

Combined recirculation of the rat liver (L) and kidney (IPK) at 10 ml min-1 per organ (LK) was developed to examine the hepatorenal handling of the precursor-metabolite pair: [14C]-enalapril and [3H]enalaprilat. Loading doses followed by constant infusion of [14C]enalapril and preformed [3H]enalaprilat to the reservoirs of the IPK or the LK preparation was used to achieve steady state conditions. In both organs, enalapril was mostly metabolized to its dicarboxylic acid metabolite, enalaprilat, which was excreted unchanged. At steady state, the fractional excretion for [14C]enalapril (FE = 0.45 to 0.48) and preformed [3H]enalaprilat (FE[pmi] = 1.1) were constant and similar for both the IPK and LK. The additivity of clearance was demonstrated in the LK preparation, namely, the total clearance of enalapril was the sum of its hepatic and renal clearances. However, the apparent fractional excretion for formed [14C]enalaprilat, FE(mi) and the apparent urinary clearance were time-dependent and higher than the corresponding values for preformed [3H]enalaprilat in both the IPK and LK. The FE(mi) and urinary clearance values further differed between the IPK and LK. Biliary clearance of formed vs. preformed enalaprilat displayed the same discrepant trends as observed for FE(mi) vs. FE(pmi) for the LK. These observations on the time-dependent and variable excretory clearance (urinary or biliary) of the formed metabolite vs. the constant, and much reduced, excretory clearance of the preformed metabolite are due to dual contributions to formed metabolite excretion: the nascently formed, intracellular metabolite which immediately underwent excretion and the formed metabolite which reentered the circulation, behaved as a preformed species. When data for the IPK and LK preparations were modeled with a physiological model with parameters previously reported for the L and IPK, all data, including metabolite excretory clearances, were well predicted. Model simulations revealed that the apparent FE(mi) differed between the LK and IPK preparations when the liver was present as an additional metabolite formation organ; the apparent excretory (urinary or biliary) clearance of the formed metabolite was further modulated by the volume of distribution of the metabolite, which altered levels of the formed, circulating metabolite.

Enalaprilat handling by the kidney: barrier-limited cell entry

The angiotensin-converting enzyme inhibitor enalaprilat is formed in vivo in liver and kidney by esterolysis of the antihypertensive drug enalapril. To gain insight into the renal elimination of enalaprilat, we carried out multiple-indicator dilution experiments in the isolated perfused rat kidney. Kidneys were perfused single pass with an amino acid-supplemented Krebs-Henseleit buffer containing 20% bovine red blood cells and 4% bovine serum albumin, at a flow rate of 0.11 +/- 0.02 (SD) ml.s-1 x g-1. A bolus of 51Cr-labeled red blood cells (vascular red blood cell indicator), 125I-labeled albumin (vascular plasma indicator), L-[14C]glucose (interstitial space indicator), and [3H]-enalaprilat was injected into the renal artery, and timed samples of venous blood (up to 1 min) and urine (up to 10 min) were collected. The data were analyzed using a variable-transit-time, space-distributed model with modifications accounting for glomerular filtration and the observed 14% protein binding of enalaprilat; the glomerular filtration rate (GFR) estimated from L-glucose clearance was 9.0 +/- 2.9% of total plasma flow. The ratio of renal clearance of unbound enalaprilat to GFR was 1.56 +/- 0.29, indicating both glomerular filtration and net tubular secretion of enalaprilat. Unidirectional influx from plasma to tubular cells exceeded tubular secretion by a factor of 2.2 +/- 0.5. Thus only about one-half of the enalaprilat taken up by the tubular cells was excreted into urine, with the remainder refluxing into the capillary blood stream, indicating bidirectional permeation of enalaprilat across the basolateral tubular membrane.

Renal handling of enalaprilat

Most converting enzyme inhibitors share a predominantly renal dual elimination pathway consisting of glomerular filtration and tubular secretion. Since enalaprilat has two functional acidic groups, it is likely that it may be secreted via the proximal tubule organic acid system and, thus, its clearances would exceed that of glomerular filtration rate markers. We therefore examined the renal clearance of enalaprilat in normal volunteers and compared it with simultaneously measured inulin and creatinine clearances to explore the contribution of tubular secretion to the renal elimination of the drug. Twelve healthy male subjects with an age range of 24 to 58 years (mean +/- SE, 33.1 +/- 2.8) were studied. They had representative height (178.6 +/- 1.99 cm) and weight (73.3 +/- 2.1 kg) and had normal renal function as judged by blood urea nitrogen (BUN) (6 +/- 0.3 mmol/L [17 +/- 0.8 mg/dL]), plasma creatinine (88 +/- 3 mumol/L [1.0 +/- 0.03 mg/dL]), and creatinine clearance determined by a prestudy 24-hour urine collection (123.2 +/- 6.2 mL/min). Results are as follows: mean creatinine clearance, 2.12 mL/s (127 mL/min); mean inulin clearance, 119.1 ml/min mean creatinine clearance/inulin clearance, 1.07 mean enalaprilat protein binding, 37.9% unbound enalaprilat clearance, 222.4 ml/min; and the mean fractional enalaprilat clearances were: enalaprilat clearance/creatinine clearance, 1.72 (P less than 0.05, difference from 1.0); enalaprilat clearance/inulin clearance, 1.85, (P less than 0.05, difference from 1.0). Our results demonstrate that the clearance of free enalaprilat exceeds that of inulin and creatinine, suggesting that elimination of the drug proceeds through two complementary pathways, namely glomerular filtration and tubular secretion.

The effect of saturation of ACE binding sites on the pharmacokinetics of enalaprilat in man

1. Eight healthy male volunteers received oral enalapril, 10 mg, in the presence and absence of pretreatment with captopril, 50 mg, twice daily for 5 days. 2. Enalaprilat pharmacokinetics were characterised after both doses of enalapril to investigate the effect of saturating ACE binding sites by pretreatment with captopril. 3. The pharmacokinetics of enalaprilat were best described by a one compartment model with zero order input incorporating saturable binding to plasma and tissue ACE. 4. Values of AUC (0.72 h) for enalaprilat were 419 +/- 97 and 450 +/- 87 ng ml-1 h in the presence and absence of captopril, respectively. The difference was not statistically significant nor were there any other differences in model parameters. 5. Induction of ACE by captopril resulting in an increase in the number of ACE binding sites, may have obscured any effect of captopril on the occupancy of ACE binding sites by enalapril.

The pharmacokinetics of enalapril in patients with compensated liver cirrhosis

The possibility of an impaired hepatic de-esterification of enalapril to enalaprilat due to hepatic dysfunction was assessed in seven patients with compensated liver cirrhosis and 10 normal control subjects. The peak serum concentration and time to the peak serum concentration of enalaprilat, as well as the suppression of serum angiotensin converting enzyme activity, following a single oral dose of enalapril maleate (10 mg) were not different in the two groups. The elimination half-life of enalaprilat was related to renal function. The results suggest that hepatic biotransformation of the drug may not be disturbed in a clinically significant manner in patients with moderate hepatic dysfunction due to compensated liver cirrhosis.

Pharmacokinetic and pharmacodynamic actions of enalapril in humans: effect of probenecid pretreatment

The pharmacokinetic and pharmacodynamic profiles of oral enalapril (20 mg), in absence and in presence of probenecid pretreatment (1 g twice daily for 5 days), were investigated in 12 healthy volunteers on normal salt intake (150 mmol/24 hr). Mean peak serum concentration of enalapril rose from 158 +/- 7 to 216 +/- 1 ng/ml (P less than .01), whereas that of its metabolite, enalaprilat, rose from 62 +/- 6 to 84 +/- 8 ng/ml (P less than .01) in the presence of probenecid pretreatment. Area under the curve of both enalapril and enalaprilat increased by 50% (P less than .001), which was accompanied by a reduction in renal excretion of both compounds. The renal clearance of enalapril decreased from 229 +/- 19 to 61 +/- 4 ml/min (P less than .001) and that of enalaprilat from 108 +/- 4 to 66 +/- 2 ml/min (P less than .001). The total drug recovery fell from 48 +/- 3 to 38 +/- 2% (P less than .01) of the administered dose with no accompanying changes in plasma elimination half-lives of the parent drug or metabolite. The pharmacodynamic response of enalapril such as fractional excretions of sodium, calcium, magnesium and urate were enhanced by probenecid pretreatment. Absolute urinary excretion of sodium increased from 51 +/- 5 to 91 +/- 8 mmol/6 hr (P less than .001) after enalapril and from 55 +/- 4 to 113 +/- 13 mmol/6 hr (P less than .01) after enalapril in presence of probenecid pretreatment, despite a significant decrease in the renal excretion of enalapril and enalaprilat over the same interval.(ABSTRACT TRUNCATED AT 250 WORDS)

Systemic and coronary haemodynamics and pharmacodynamics of enalapril and enalaprilat in congestive heart failure

Enalapril is an effective angiotensin-converting enzyme (ACE) inhibitor which produces salutary, beneficial haemodynamic effects in patients with congestive heart failure. Enalapril also produces beneficial neurohumoral changes, as well as improving abnormal coronary haemodynamics and myocardial energetics that are frequently encountered in these patients. Administration of enalapril once or twice daily appears to be quite effective during maintenance therapy in patients with chronic congestive heart failure.

Renal handling of enalapril and enalaprilat: studies in the isolated red blood cell-perfused rat kidney

An isolated recirculating or single pass red cell-perfused rat kidney preparation (IPK) was used to examine the differential handling of renal metabolites. In single pass experiments, enalapril was primarily metabolized to its polar, dicarboxylic acid metabolite, enalaprilat, and its fractional excretion (FE) was less than unity, suggesting net reabsorption. Its steady-state extraction ratio decreased from 0.3 to 0.2 at concentrations of 1.06 to 12.7 microM, due to a saturation of enzymes for esterolysis. Enalaprilat administered to the IPK was excreted into urine in a concentration-independent (0.41-35.3 microM) fashion, with FE values approximating unity, suggesting net filtration. Differences in handling were observed for enalaprilat, as a metabolite formed from enalapril and as an administered (preformed) species in the single pass IPK, when tracer concentrations of [14C]enalapril and [3H]enalaprilat were given simultaneously. A comparison made between steady-state extraction ratio Ess[mi] [generated metabolite]/glomerular filtration rate (GFR) and Ess[pmi] [preformed metabolite]/GFR, respectively, revealed a 2-fold difference. The finding suggests the presence of a barrier for entry of enalaprilat into the kidney. Or else, in absence of the barrier, the opposite would be observed, that is, Ess [pmi]/GFR greater than Ess [mi]/GFR because preformed enalaprilat, in contrast to generated enalaprilat, undergoes filtration and utilizes facilitative transport carriers at the basolateral membrane. In recirculating IPKs which received simultaneously a tracer bolus dose of [14C]enalapril and [3H]enalaprilat, the FE values for generated [14C]enalaprilat were high and variable, decreasing with perfusion time and exceeding those for preformed [3H]enalaprilat, which approached unity with perfusion time. The variable FE values for [14C]enalaprilat are due to time-dependent contributions of circulating enalaprilat (which behaves identically to preformed enalaprilat) and the intrarenally generated enalaprilat. Hence, with renal drug metabolism, the conventional method of estimating urinary clearance (or Fe[mi]) for the metabolite [(total) excretion rate/midpoint plasma FE[mi] metabolite concentration] results in a greater metabolite clearance than that predicted from the administration of preformed metabolite.