ACE inhibitors reduce the activity of the
renin–angiotensin–aldosterone system (RAAS) as the primary etiologic (causal) event in the development of hypertension in people with diabetes mellitus, as part of the insulin-resistance syndrome or as a manifestation of renal disease.
Renin–angiotensin–aldosterone system The renin–angiotensin–aldosterone system is a major blood pressure regulating mechanism. Markers of electrolyte and water imbalance in the body such as
hypotension, low
distal tubule sodium concentration, decreased blood volume and high
sympathetic tone trigger the release of the enzyme
renin from the cells of
juxtaglomerular apparatus in the kidney. Renin activates a circulating liver derived
prohormone angiotensinogen by proteolytic cleavage of all but its first ten
amino acid residues known as
angiotensin I.
ACE (angiotensin converting enzyme) then removes a further two residues, converting angiotensin I into
angiotensin II. ACE is found in the
pulmonary circulation and in the
endothelium of many blood vessels. The system increases blood pressure by increasing the amount of salt and water the body retains. Angiotensin II is also a potent
vasoconstrictor.
Effects ACE inhibitors block the conversion of angiotensin I (ATI) to angiotensin II (ATII). They thereby lower arteriolar resistance and increase venous capacity; decrease cardiac output, cardiac index, stroke work, and volume; lower resistance in renal blood vessels; and lead to increased natriuresis (excretion of sodium in the urine). Renin increases in concentration in the blood as a result of negative feedback from reduced conversion of ATI to ATII, and ATI levels increase for the same reason, while ATII and aldosterone concentrations decrease. Bradykinin levels increase because angiotensin-converting enzyme also degrades bradykinin, and its inhibition reduces bradykinin inactivation. Under normal conditions, angiotensin II has these effects: • Vasoconstriction (narrowing of blood vessels) and vascular smooth muscle hypertrophy (enlargement) induced by ATII may lead to increased blood pressure and hypertension. Further, constriction of the
efferent arterioles of the kidney leads to increased perfusion pressure in the
glomeruli. • It contributes to
ventricular remodeling and
ventricular hypertrophy of the heart through stimulation of the
proto-oncogenes
c-fos,
c-jun,
c-myc,
transforming growth factor beta (TGF-B), through fibrogenesis and apoptosis (programmed cell death). • Stimulation by ATII of the
adrenal cortex to release
aldosterone, a hormone that acts on kidney tubules, causes sodium and chloride ions retention and potassium excretion. Sodium is a "water-holding" ion, so water is also retained, which leads to increased blood volume, hence an increase in blood pressure. • Stimulation of the posterior pituitary to release
vasopressin (antidiuretic hormone, ADH) also acts on the kidneys to increase water retention. If ADH production is excessive in heart failure, Na+ level in the plasma may fall (hyponatremia), and this is a sign of increased risk of death in heart failure patients. • A decrease renal protein kinase C During the course of ACE inhibitor use, the production of ATII is decreased, which prevents aldosterone release from the adrenal cortex. This action of ACE inhibitors is used in the prevention of diabetic
renal failure. ACE inhibitors have been shown to be effective for indications other than hypertension even in patients with normal blood pressure. The use of a maximum dose of ACE inhibitors in such patients (including for prevention of diabetic nephropathy, congestive heart failure, and prophylaxis of cardiovascular events) is justified, because it improves clinical outcomes independently of the blood pressure-lowering effect of ACE inhibitors. Such therapy, of course, requires careful and gradual titration of the dose to prevent the effects of rapidly decreasing blood pressure (dizziness, fainting, etc.). ACE inhibitors have also been shown to cause a central enhancement of
parasympathetic nervous system activity in healthy volunteers and patients with heart failure. This action may reduce the prevalence of malignant cardiac arrhythmias, and the reduction in sudden death reported in large clinical trials. ACE Inhibitors also reduce plasma
norepinephrine levels, and its resulting vasoconstriction effects, in heart failure patients, thus breaking the vicious circles of
sympathetic and renin angiotensin system activation, which sustains the downward spiral in cardiac function in congestive heart failure The ACE inhibitor
enalapril has also been shown to reduce cardiac
cachexia in patients with chronic heart failure. Cachexia is a poor prognostic sign in patients with chronic heart failure. ACE inhibitors are under early investigation for the treatment of frailty and muscle wasting (sarcopenia) in elderly patients without heart failure. ==Examples==