Effect of carboxylesterase 1 c.428G > A single nucleotide variation on the pharmacokinetics of quinapril and enalapril.

AIM: The aim of the present study was to investigate the effects of the carboxylesterase 1 (CES1) c.428G > A (p.G143E, rs71647871) single nucleotide variation (SNV) on the pharmacokinetics of quinapril and enalapril in a prospective genotype panel study in healthy volunteers. METHODS: In a fixed-order crossover study, 10 healthy volunteers with the CES1 c.428G/A genotype and 12 with the c.428G/G genotype ingested a single 10 mg dose of quinapril and enalapril with a washout period of at least 1 week. Plasma concentrations of quinapril and quinaprilat were measured for up to 24 h and those of enalapril and enalaprilat for up to 48 h. Their excretion into the urine was measured from 0 h to 12 h. RESULTS: The area under the plasma concentration-time curve from 0 h to infinity (AUC0-∞) of active enalaprilat was 20% lower in subjects with the CES1 c.428G/A genotype than in those with the c.428G/G genotype (95% confidence interval of geometric mean ratio 0.64, 1.00; P = 0.049). The amount of enalaprilat excreted into the urine was 35% smaller in subjects with the CES1 c.428G/A genotype than in those with the c.428G/G genotype (P = 0.044). The CES1 genotype had no significant effect on the enalaprilat to enalapril AUC0-∞ ratio or on any other pharmacokinetic or pharmacodynamic parameters of enalapril or enalaprilat. The CES1 genotype had no significant effect on the pharmacokinetic or pharmacodynamic parameters of quinapril. CONCLUSIONS: The CES1 c.428G > A SNV decreased enalaprilat concentrations, probably by reducing the hydrolysis of enalapril, but had no observable effect on the pharmacokinetics of quinapril.

Evaluation of a rapid method for the therapeutic drug monitoring of aliskiren, enalapril and its active metabolite in plasma and urine by UHPLC-MS/MS.

Given the increasing popularity of aliskiren, particularly in combination with angiotensin converting enzyme inhibitor (e.g. enalapril), it is important to determine whether its use in combination with these agents is associated with potentially life threatening safety events. Analytical methods for the simultaneous determination of both drugs in plasma and urine utilized in clinical studies on efficacy and safety have not been fully described in the literature. In this work, a new, fast and reliable method using a digitally controlled microextraction by packed sorbent (eVol(®)-MEPS) followed by ultra-high performance liquid chromatography (UHPLC) coupled with tandem mass spectrometry (MS/MS) was developed and validated to quantify an aliskiren, enalapril and its active metabolite in both human plasma and urine. Chromatographic separation was accomplished on a Poroshell 120 EC-C18 column with a gradient elution system consisting of 0.1% formic acid in water and acetonitrile (1.5min of total analysis). Detection was performed by multiple reaction monitoring (MRM) mode using electrospray ionization in the positive ion mode. This assay method has been fully validated in terms of selectivity, linearity, accuracy, precision, stability, recovery and matrix effect. The developed method can be applied to the routine determination of selected compounds in human plasma and urine and can be useful to elucidate the mechanisms of the potential risks triggered by the combination of aliskiren and enalapril as well as its active metabolite enalaprilat.

[Simultaneous determination of four drugs for kidney diseases in urine by high performance liquid chromatography].

A high performance liquid chromatographic (HPLC) method was proposed for the simultaneous determination of four drugs for kidney disease, enalapril, triamterene, furosemide and valsartan. After proteins being removed by acetone precipitation method, freeze drying and redissolving in mobile phase, the urine samples were analyzed by HPLC. Chromatographic separation was performed on a WondaSil C18-WR (150 mm x 4.6 mm, 5 µm) in gradient elution mode using 10.0 mmol/L ammonium acetate aqueous solution (pH 3.90) and acetonitrile as mobile phases at a flow rate of 1.0 mL/min. The detection wavelength was set at 254 nm. Under the optimized conditions, good linearities were obtained in the range of 0.15-300 mg/L, 0.05-100 mg/L, 0.75-750 mg/L, 0.05-100 mg/L, and the detection limits were 1.38 x 10(-2), 7. 67x103, 3.69x 10-2, 1. 16x 10-2 mg/L for enalapril, triamterene, furosemide and valsartan, respectively. The recoveries were in the range of 89.49%-99.20% with the relative standard deviations (RSDs) among 4.12%-9.44%. The method is simple, accurate and effective, and the results showed the method is applicable for the analysis of the four drugs for kidney diseases in real urine samples.

Simultaneous quantitative and qualitative analysis of aliskiren, enalapril and its active metabolite enalaprilat in undiluted human urine utilizing LC-ESI-MS/MS.

The benefit-risk ratio of combined blocking by the direct renin inhibitor aliskiren and an angiotensin-converting enzyme inhibitor (e.g. enalapril) on the renin-angiotensin-aldosterone system is discussed. No method was available for simultaneous determination of both drugs in urine. A novel sensitive method for simultaneous quantification in undiluted human urine was developed which enables systematic pharmacokinetic investigations, especially in poorly investigated populations like children. Matrix effects were clearly reduced by applying solid-phase extraction followed by a chromatographic separation on Xselect(TM) C18 CSH columns. Mobile phase consisted of methanol and water, both acidified with formic acid. Under gradient conditions and a flow rate of 0.4 mL/min the column effluent was monitored by tandem mass spectrometry with electrospray ionization. Calibration curves were constructed in the range of 9.4-9600 ng/mL regarding aliskiren, 11.6-12000 ng/mL for enalapril and 8.8-9000 ng/mL for enalaprilat. All curves were analyzed utilizing 1/x(2) -weighted quadratic squared regression. Intra-run and inter-run precision were 3.2-5.8% and 6.1-10.3% for aliskiren, 2.4-6.1% and 3.9-7.9% for enalapril as well as 3.1-9.4% and 4.7-12.7% regarding enalaprilat. Selectivity, accuracy and stability results comply with current international bioanalysis guidelines. The fully validated method was successfully applied to a pharmacokinetic investigation in healthy volunteers.

Determination of enalapril maleate and atenolol in their pharmaceutical products and in biological fluids by flow-injection chemiluminescence.

A chemiluminescent method using flow injection (FI) was investigated for rapid and sensitive determination of enalapril maleate and atenolol, which are used in the treatment of hypertension. The method is based on the sensitizing effect of these drugs on the Ce(IV)-sulfite reaction. The different experimental parameters affecting the chemiluminescence (CL) intensity were carefully studied and incorporated into the procedure. The method permitted the determination of 0.01-3.0 microg mL(-1) of enalapril maleate in bulk form with correlation coefficient r = 0.99993, lower limit of detection (LOD) 0.0025 microg mL(-1) (S/N = 2) and lower limit of quantitation (LOQ) 0.01 microg mL(-1). The linearity range of atenolol in bulk form was 0.01-2.0 microg mL(-1) (r = 0.99989) with LOD of 0.0003 microg mL(-1) (S/N = 2) and LOQ of 0.01 microg mL(-1). In biological fluids the linearity range of enalapril maleate was 0.1-2.0 microg mL(-1) in both urine and serum, and for atenolol the linearity range was 0.1-1.0 microg mL(-1) in both urine and serum. The method was also applied to the determination of the drugs in their pharmaceutical preparations.

Flow-injection chemiluminescence determination of enalapril maleate in pharmaceuticals and biological fluids using tris(2,2'-bipyridyl)ruthenium(II).

A chemiluminescence (CL) method using flow injection (FI) has been investigated for the rapid and sensitive determination of enalapril maleate. The method is based on the CL reaction of the drug with tris(2,2'-bipyridyl)ruthenium(II), Ru(bipy)3(2+) and acidic potassium permanganate. After selecting the best operating parameters, calibration graphs were obtained over concentration ranges of 0.005-0.2 microg/ml and 0.7-100 microg/ml with a detection limit (S/N=2) of 1.0 ng/ml. The average % found was 99.9 +/- 0.7 and 100.2 +/- 0.3 for the two concentration ranges respectively. %RSD (n=10) for 5.0 microg/ml was 0.44. The method was successfully applied to the determination of enalapril maleate in dosage forms and biological fluids without interferences.

Angiotensin II suppression in humans by the orally active renin inhibitor Aliskiren (SPP100): comparison with enalapril.

Renin is the main determinant of angiotensin (Ang) II levels. It, therefore, always appeared desirable to reduce Ang II levels by direct inhibition of renin. So far, specific renin inhibitors lacked potency and/or oral availability. We tested the new orally active nonpeptidic renin inhibitor SPP100 (Aliskiren, an octanamide with a 50% inhibitory concentration [IC50] in the low nanomolar range) in 18 healthy volunteers on a constant 100 mmol/d sodium diet using a double-blind, 3-way crossover protocol. In 3 periods of 8 days, separated by wash-outs of 6 days, each volunteer received 2 dosage levels of Aliskiren (low before high; 40 and 80 or 160 and 640 mg/d) and randomized placebo or 20 mg enalapril. Aliskiren was well tolerated. Not surprisingly, blood pressure and heart rate remained unchanged in these normotensive subjects. There was a dose-dependent decrease in plasma renin activity, Ang I, and Ang II following single doses of Aliskiren starting with 40 mg. Inhibition was still marked and significant after repeated dosing with maximal decreases in Ang II levels by 89% and 75% on Days 1 and 8, respectively, when the highest dose of Aliskiren was compared with placebo. At the same time, mean plasma active renin was increased 16- and 34-fold at the highest dose of Aliskiren. Plasma drug levels of Aliskiren were dose-dependent with maximal concentrations reached between 3 to 6 hours after administration; steady state was reached between 5 and 8 days after multiple dosing. Less than 1% of dose was excreted in the urine. Plasma and urinary aldosterone levels were decreased after doses of Aliskiren > or =80 mg and after enalapril. Aliskiren at 160 and 640 mg enhanced natriuresis on Day 1 by +45% and +62%, respectively, compared with placebo (100%, ie, 87+/-11 mmol/24h) and enalapril (+54%); kaliuresis remained unchanged. In conclusion, the renin inhibitor Aliskiren dose-dependently decreases Ang II levels in humans following oral administration. The effect is long-lasting and, at a dose of 160 mg, is equivalent to that of 20 mg enalapril. Aliskiren has the potential to become the first orally active renin inhibitor that provides a true alternative to ACE-inhibitors and Ang II receptor antagonists in therapy for hypertension and other cardiovascular and renal diseases.

The pharmacokinetics of enalapril in children and infants with hypertension.

Forty children with hypertension between the age of 2 months and 15 years received 0.07 to 0.14 mg/kg of enalapril as a single daily dose. Enalapril was administered orally as a novel extemporaneous suspension in children younger than 6 years of age and as tablets in older children. First-dose and steady-state pharmacokinetics were estimated in children ages 1 to 24 months, 25 months to < 6 years, 6 to < 12 years, and 12 to < 16 years. Maximum serum concentrations for enalapril occurred approximately 1 hour after administration. Serum concentrations of enalaprilat, the active metabolite of enalapril, peaked between 4 and 6 hours after the first dose and 3 and 4 hours after multiple doses. The area under the concentration versus time curve (AUC), adjusted for body surface area, did not differ between age groups. Based on comparison of first-dose and steady-state AUCs, the accumulation of enalaprilat in children ranged from 1.13- to 1.45-fold. For children ages 2 to 15 years, mean urinary recovery of total enalaprilat ranged from 58.3% in children ages 6 to < 12 years to 71.4% in children ages 12 to < 16 years. Urinary recovery for children ages 2 to < 6 years was 66.8%. The mean percentage conversion of enalapril to enalaprilat ranged from 64.7% for children ages 1 to 24 months to 74.6% for children ages 6 to < 12 years. The median effective half-life for accumulation ranged from 14.6 hours in children ages 12 to < 16 years to 16.3 hours in children ages 6 to < 12 years. There were two serious adverse events, neither of which was attributed to enalapril or resulted in discontinuation of the study drug. The extemporaneous suspension used in this study was tolerated well. The pharmacokinetics of enalapril and enalaprilat in hypertensive children ages 2 months to 15 years with normal renal function appears to be similar to that previously observed in healthy adults.

Inhibition of esterolysis of enalapril by paraoxon increases the urinary clearance in isolated perfused rat kidney.

The effect of competing elimination pathways on the metabolic and excretory clearance estimates was examined with tracer concentrations of [(3)H]enalapril, which was both metabolized and excreted by the rat kidney. Perturbation was achieved with use of the carboxylesterase inhibitor paraoxon, which inhibited [(3)H]enalapril metabolism to [(3)H]enalaprilat in rat renal S9 fraction. At 0.1, 0.5, 1, and 10 microM paraoxon, esterolysis of enalapril was inhibited by 76 +/- 7, 93 +/- 5, 96 +/- 5, and 93 +/- 6%, respectively. The lowest concentration (0.1 microM) of paraoxon was chosen for single-pass isolated perfused kidney (IPK) studies because viability was least compromised, and the sodium and glucose reabsorptive functions of the IPK remained constant. After an equilibration period (15-20 min at constant pressure, 90-100 mm Hg), perfusion of the rat kidney with [(3)H]enalapril was carried out under constant flow (8 ml/min) for 30 min in the absence and presence of paraoxon (0.1 microM). The metabolic (from 1.83 +/- 0.52 to 1.48 +/- 0.47 ml/min/g) and total renal (from 1.87 +/- 0.46 to 1. 57 +/- 0.41 ml/min/g) clearances of [(3)H]enalapril in the IPKs were decreased significantly (p <.05) in the presence of paraoxon when compared with controls. Concomitantly, the urinary clearance (from 0. 04 +/- 0.07 to 0.09 +/- 0.09 ml/min/g) and the fractional excretion (from 0.23 +/- 0.18 to 0.52 +/- 0.25) of [(3)H]enalapril doubled (p <.05). The study illustrates that a reduction in cellular metabolism of the kidney brings forth a rise in the estimate of clearance of its complimentary pathway, estimate of the excretory (urinary) clearance.

Effect of hydrochlorothiazide on the pharmacokinetics of enalapril in hypertensive patients with varying renal function.

An open, randomised, cross-over study was performed to investigate the pharmacokinetics of enalaprilat, administered as 20 mg enalapril both as monotherapy and in combination with hydrochlorothiazide (HCTZ 12.5 mg). Three groups of 6 hypertensive patients were enrolled [untreated diastolic blood pressure (DBP) 90-115 mm Hg]; normal renal function [glomerular filtration rate (GFR) > 81 ml min-1 1.73 m-2], mild renal impairment (GFR 51-80 ml min-1 1.73 m-2), and moderate renal impairment (GFR 31-50 ml min-1 1.73 m-2). The pharmacokinetics of enalaprilat and enalaprilat plus HCTZ correlated predictably with renal impairment with increased plasma concentrations and decreased urinary elimination at lower values of GFR. The coadministration of HCTZ had no significant effect on the pharmacokinetics of enalaprilat in any group. We conclude that although the pharmacokinetics of both enalaprilat and HCTZ are related to renal function, HCTZ has no significant effect on the pharmacokinetics of enalaprilat and that dosage adjustment for both regimens should be based on renal function.

HPLC analysis of azathioprine metabolites in red blood cells, plasma and urine in renal transplant recipients.

Anemia has been frequently reported in renal transplant recipients receiving azathioprine for immunosuppression and enalapril for treatment of hypertension. During the course of a prospective trial in such patients we determined azathioprine metabolites in erythrocytes, plasma, and urine as well as erythropoietin and hemoglobin levels in order to evaluate a potential interaction between these 2 drugs, possibly leading to anemia. Two specific high performance liquid chromatography (HPLC) methods for determination of azathioprine metabolites, both employing a mercurial cellulose resin for extraction, are presented. One method using a strong anion exchange column allows detection of 6-thioguanosine di- and triphosphate (thioguanine nucleotides) in red blood cells (RBC) with a sensitivity of 30 pmol/100 microliters RBC. 6-mercaptopurine (MP) and 6-thiouric acid (TUA) in plasma and urine were analyzed simultaneously by reversed-phase HPLC with a sensitivity of 5 ng/ml. The average (median values are given) steady state concentrations of thioguanine nucleotides in erythrocytes came to 267 pmol/100 microliters RBC (range 53-613) with and to 246 pmol/100 microliters RBC (range 39-629) without concomitant enalapril medication. Mean plasma concentrations of MP and TUA 3 hours after drug intake came to 14.8 +/- 9.9 ng/ml and 398 +/- 262 ng/ml, respectively, during enalapril comedication. Withdrawal of enalapril did not influence these metabolite levels coming to 15.3 +/- 9.1 and 451 +/- 253 after stopping enalapril treatment. Thioguanine nucleotides in RBCs were neither related to the dose of azathioprine given (r = -0.113, p > 0.05) nor to hemoglobin levels (r = 0.278, p > 0.05). However, azathioprine dose/kg body weight seemed to be related to hemoglobin concentration, with and without enalapril comedication. We conclude that enalapril therapy does not influence the measured azathioprine metabolites, the reported cases of anemia may rather be due to a pharmacodynamic interaction as shown by the significant increase in erythropoietin after withdrawal of enalapril. The assays described here are suitable to study the metabolism of azathioprine in patients with various diseases.

Determination of enalapril and its active metabolite enalaprilat in plasma and urine by gas chromatography/mass spectrometry.

The method for the simultaneous determination of angiotensin-converting enzyme (ACE) inhibitor enalapril and its active metabolite enalaprilat in plasma and urine was developed by gas chromatography/mass spectrometry. Enalapril and enalaprilat in plasma and urine were extracted and cleaned up by using Sep-Pak C18 and silica cartridges. Derivatization was carried out using diazomethane and trifluoroacetic anhydride. Detection by selected ion monitoring was selected to m/z 288 (enalaprilat) and 302 (enalapril). The detection limit of enalapril and enalaprilat was 200 pg/mL in plasma and 2 ng/mL in urine. This method was applied to the pharmacokinetic analysis of enalapril and enalaprilat in body fluids.

Preferential biliary elimination of FPL 63547, a novel inhibitor of angiotensin-converting enzyme, in the rat.

1. The route of elimination of FPL 63547, a novel inhibitor of angiotensin-converting enzyme (ACE), has been investigated in the anaesthetized rat. Comparisons have been made with other ACE inhibitors. 2. Bile and urine samples were collected over a 5 hour period following a single i.v. dose of ACE inhibitor (2 mumol kg-1). Samples were bioassayed for ACE inhibitory activity using affinity-purified rabbit lung ACE and the amounts of the active form of inhibitor present in each sample were calculated by comparison with a standard curve. 3. FPL 63547 was rapidly and extensively excreted as the diacid in the bile but appeared in the urine in negligible amounts. The bile:urine ratio was 21.4:1 indicating a marked preference for the biliary route. A similar elimination profile was observed when the compound was dosed in its active form (FPL 63547 diacid), 87.9% of which was found in the bile over the 5 h collection period, with a bile: urine ratio of 14.6:1. 4. The marked preference of FPL 63547 for biliary elimination was not shared by the other ACE inhibitors tested in this study. Lisinopril demonstrated the opposite pattern, being excreted almost exclusively by the kidney (bile:urine ratio 0.06:1). Enalapril was eliminated in approximately equal amounts in bile and urine (ratio 0.7:1) while spirapril diacid showed a slight preference for the bile (ratio 2.6:1). 5. The physical chemical properties of FPL 63547 diacid may be responsible for its unusual preference for biliary elimination. In particular, the amphipathic character and strong acid functionality of the compound are thought to favour transport into the bile. 6. Elimination by the biliary route will be preferred in patients whose renal function is impaired as a result of disease or age. In such patients the elimination of renally-excreted ACE inhibitors is known to be compromised, resulting in compound accumulation and the need for closer monitoring. Therefore, the elimination profile of FPL 63547, if confirmed in man, may prove to be clinically advantageous.

Kinetics and dynamics of enalapril in patients with liver cirrhosis.

The pharmacokinetics and pharmacodynamics (blood pressure, heart rate, serum angiotensin-converting enzyme, and plasma renin activity) of enalapril and enalaprilat were studied after oral administration of enalapril maleate (10 mg) to seven biopsy-proven cirrhotic patients and to seven healthy subjects. The mean Cmax, AUC, and urinary excretion of enalapril and enalaprilat were greater and less (p less than 0.01), respectively, and mean oral clearance of enalapril was less (p less than 0.01) in the cirrhotic group than in the healthy group. However, there was no significant difference in the mean total drug (enalapril plus enalaprilat) excretion between the two groups. Blood pressure fell (p less than 0.05) only at 3 or 4 hours postdose, with no change in heart rate in the two groups. Serum angiotensin-convering enzyme (ACE) decreased (p less than 0.001) and plasma renin activity (PRA) increased (p less than 0.05) in the two groups. The magnitude of the percentage of inhibition of ACE activity was comparable between the two groups. Serum enalaprilat concentration correlated (p less than 0.001) with the percentage of inhibition of ACE activity. The results suggest that the bioactivation of enalapril to enalaprilat is considerably impaired in patients with cirrhosis but that the pharmacodynamic effects do not appear to be blunted in those patients. The mechanism and clinical implications remained unclear.

A study of the potential pharmacokinetic interaction of lisinopril and digoxin in normal volunteers.

1. The pharmacokinetics of single oral doses of 20 mg lisinopril and 0.25 mg digoxin, given alone and together, have been studied in 12 normal young male volunteers. 2. Peak serum conc of lisinopril occurred at 6 to 8 h and were slightly higher during combined treatment. Subsequent elimination proceeded moderately rapidly in both cases, concn declining to approx. 25% of peak values in 24 h. The AUC of lisinopril was similarly slightly higher during combined treatment. 3. After lisinopril alone, urinary elimination of unchanged lisinopril was 13% dose in 72 h, and after combined therapy was 17% dose. 4. Although there were no statistically significant differences in lisinopril pharmacokinetics during single or combined treatment, serum and urinary parameters suggest that bioavailability may be enhanced slightly during combined treatment. 5. Plasma concentrations of digoxin were slightly lower and urinary excretion slightly higher during combined treatment, the mean renal clearance being 20% higher.

Pharmacokinetics of lisinopril in hypertensive patients with normal and impaired renal function.

The pharmacokinetics of lisinopril was studied after administration of single and multiple doses of 5 mg to hypertensive patients with normal and impaired renal function. In patients with severe renal failure the peak concentrations were higher, the decline in serum concentration was slower and the time to peak concentration was extended. Accumulation of lisinopril was highly correlated with the creatinine clearance. The effective half-life was doubled and tripled in patients with mild and severe renal impairment, respectively, as compared to patients with a normal renal function. Lisinopril lowered blood pressure in all three groups over 24 h. It is suggested that smaller doses of lisinopril should be administered to patients with severe renal failure.

Effect of food on the bioavailability of lisinopril, a nonsulfhydryl angiotensin-converting enzyme inhibitor.

A randomized, two-way, crossover study was performed on 18 normal volunteers to assess the influence of food on the bioavailability of lisinopril, (1-[N2-[(S)-1-carboxy-3-phenylpropyl]-L-lysyl]-L-proline), a long-acting nonsulfhydryl angiotensin converting enzyme inhibitor. A single, 20-mg oral dose of lisinopril was administered to volunteers in the fasting state or following a standardized breakfast. Treatment periods were separated by 2-week intervals. No significant differences existed between fasting and fed regimens in the mean +/- SD area under the serum concentration-time curve (AUC0-120h; 1231 +/- 620 versus 1029 +/- 254 ng X h X ml-1), peak lisinopril serum concentration (86 +/- 48 versus 69 +/- 19 ng/mL), or time to peak lisinopril serum concentration (6.2 +/- 1.1 versus 6.8 +/- 1.0 h). Five-day urinary excretion of lisinopril was not altered by food (5.3 +/- 3.0 versus 5.1 +/- 2.0 mg). Based on the urinary data, the mean +/- SD bioavailability of lisinopril was not different following fasting or fed regimens (27 +/- 15 versus 26 +/- 10%). Unlike with captopril, food did not affect the bioavailability of lisinopril.

Enalapril and the kidney: renal vasodilation and natriuresis due to the inhibition of angiotensin II formation.

Essential hypertension is characterized by increased renal vascular resistance, which also has definite implications for renal sodium handling. We studied the possibility of correcting these abnormalities by inhibiting angiotensin-converting enzyme with enalapril. Enalaprilic acid produced renal vasodilation. This, particularly postglomerular, vasodilation was accompanied with an increase in sodium excretion. The natriuresis was positively correlated to initial plasma renin activity. During continuous treatment with enalapril up to 12 weeks, this vasodilation persisted in 22 patients with essential hypertension. We also showed that orally administered enalapril induces natriuresis, both during a 50-mmol and during a 200-mmol sodium intake a day. This natriuresis caused a net negative sodium balance of approximately 120-140 mmol Na after 1 week of enalapril therapy. This was accompanied with a fall in body weight. We conclude that enalapril in essential hypertension alleviates the angiotensin-II-mediated abnormalities in renal hemodynamics and sodium excretion.

The effect of renal function on enalapril kinetics.

Enalapril maleate (MK-421), a nonmercapto-containing angiotensin converting enzyme (ACE) inhibitor, is converted in vivo to enalaprilat (MK-422), the active diacid. We evaluated serum profiles and urinary excretion of oral enalapril maleate in patients with renal disease (group I, creatinine clearance less than 3 ml/min, patients undergoing dialysis, n = 10; group II, creatinine clearance 10 to 79 ml/min, n = 9) compared with healthy subjects (group III, creatinine clearance greater than 80 ml/min, n = 10). Group I received a 10 mg dose during a day while not receiving dialysis and a 10 mg dose 1 hour before dialysis 2 weeks later. Groups II and III received a single 10 mg dose. Blood samples and urine were collected for 48 hours. Impaired renal function resulted in elevated serum and plasma concentrations of enalapril maleate and decreased excretion rates and urinary recovery of enalapril maleate and enalaprilat. The data suggest an apparent increase in the extent of metabolism of enalapril maleate to enalaprilat or an increase in nonrenal elimination of unchanged enalapril maleate in renal disease compared with normal health. Enalaprilat was dialyzable.