Heart failure pharmacokinetics

Finally, a pharmacokinetic interaction between betablocker therapy and ACEID genotype has been observed in patients with congestive heart failure. Almost 90% of patients were treated with an ACE inhibitor. In the entire cohort of 328 patients transplant-free survival was significantly poorer in patients with a D allele. This adverse outcome was prevented by concomitant treatment with betablocker and enhanced in patients without betablockers [38]. 

While essentially all ACE inhibitors have a similar mechanism of action and therefore exhibit similar efficacy in the treatment of hypertension and congestive heart failure, these drugs differ slightly in their pharmacokinetic profiles. Enalapril, lisinopril, and quinapril are excreted primarily by the kidney, with minimal liver metabolism, while the other prodrug compounds are metabolized by the liver and renally excreted. Thus, in patients with renal insufficiency, the half-life of renally excreted ACE inhibitors is prolonged. In addition, patients with impaired liver func-... 

Pharmacokinetics Almost completely absorbed following PO administration. Absorption is reduced to 43% in congestive heart failure (CHF) patients. Not firmly bound to serum protein. Excreted in urine. Half-life 25 hr. 

The pharmacokinetic properties of these drugs are set forth in Table 12-5. The choice of a particular calcium channel-blocking agent should be made with knowledge of its specific potential adverse effects as well as its pharmacologic properties. Nifedipine does not decrease atrioventricular conduction and therefore can be used more safely than verapamil or diltiazem in the presence of atrioventricular conduction abnormalities. A combination of verapamil or diltiazem with 3 blockers may produce atrioventricular block and depression of ventricular function. In the presence of overt heart failure, all calcium channel blockers can cause further worsening of heart failure as a result of their negative inotropic effect. Amlodipine, however, does not increase the mortality of patients with heart failure due to nonischemic left ventricular systolic dysfunction and can be used safely in these patients. 

Sotalol is well absorbed orally with bioavailability of approximately 100%. It is not metabolized in the liver and is not bound to plasma proteins. Excretion is predominantly by the kidneys in the unchanged form with a half-life of approximately 12 hours. Because of its relatively simple pharmacokinetics, solatol exhibits few direct drug interactions. Its most significant cardiac adverse effect is an extension of its pharmacologic action a dose-related incidence of torsade de pointes that approaches 6% at the highest recommended daily dose. Patients with overt heart failure may experience further depression of left ventricular function during treatment with sotalol. 

An important class of orally active ACE inhibitors, directed against the active site of ACE, is now extensively used. Captopril and enalapril are examples of the many potent ACE inhibitors that are available. These drugs differ in their structure and pharmacokinetics, but in clinical use, they are interchangeable. ACE inhibitors decrease systemic vascular resistance without increasing heart rate, and they promote natriuresis. As described in Chapters 11 and 13, they are effective in the treatment of hypertension, decrease morbidity and mortality in heart failure and left ventricular dysfunction after myocardial infarction, and delay the progression of diabetic nephropathy. 

---