Secondary hyperaldosteronism pathophysiology: Difference between revisions
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== Pathophysiology == | == Pathophysiology == | ||
Renin-angiotensin system components | === Renin-angiotensin system components === | ||
Renin | Renin | ||
* | * In each kidney there is a specialized system called juxtaglomerular system, which is located in afferent arteriole of each glomerulus. | ||
* These apparatus synthesizes prorenin, and then later it converts into renin with mediation of a proteolytic enzyme. | |||
* Renin stores in and then may be released from secretory granules, in response to various factors. | |||
* Renin releasing starts a cascade of steps, and the first step is the cleavage of the angiotensin I, from angiotensinogen, an alpha-2-globulin produced in the liver (and other organs including the kidney) [11,12]. This first step is also the rate-limiting step of the RAS cascade. Renal hypoperfusion, caused by hypotension or volume depletion, and increased sympathetic activity are the major physiologic stimuli to renin secretion (figure 3). | |||
{| class="wikitable" | {| class="wikitable" |
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Overview
Secondary hyperaldosteronism is a disease of increasing aldosterone or other mineralocorticoid levels. The resulting Na+ retention produces hypertension, and elevated K+ excretion may cause hypokalemia.
Pathophysiology
Renin-angiotensin system components
Renin
- In each kidney there is a specialized system called juxtaglomerular system, which is located in afferent arteriole of each glomerulus.
- These apparatus synthesizes prorenin, and then later it converts into renin with mediation of a proteolytic enzyme.
- Renin stores in and then may be released from secretory granules, in response to various factors.
- Renin releasing starts a cascade of steps, and the first step is the cleavage of the angiotensin I, from angiotensinogen, an alpha-2-globulin produced in the liver (and other organs including the kidney) [11,12]. This first step is also the rate-limiting step of the RAS cascade. Renal hypoperfusion, caused by hypotension or volume depletion, and increased sympathetic activity are the major physiologic stimuli to renin secretion (figure 3).
Renin-angiotensin system components | Secretion control | Measurement | Inhibition |
---|---|---|---|
Renin |
|
|
|
Angiotensinogen | |||
Angiotensin-converting enzyme | |||
Angiotensin II | |||
Aldosterone |
Basic physiology of aldosterone
Circulating aldosterone is principally made in the zona glomerulosa of the adrenal cortex (outer layer of the cortex) by a cascade of enzyme steps leading to the conversion of cholesterol to aldosterone.
- Aldosterone's production is regulated at two critical enzyme steps:
- (1) early in its biosynthetic pathway (the conversion of cholesterol to pregnenolone by cholesterol side chain cleavage enzyme) and
- (2) late (the conversion of corticosterone to aldosterone by aldosterone synthase).
- A variety of factors modify aldosterone secretion--the most important are angiotensin II (AngII), the end-product of the renin-angiotensin system (RAS), and potassium. However ACTH, neural mediators and natriuretic factors also play part in the feedback mechanism.
- Aldosterone's classical epithelial effect is to increase the transport of sodium across the cell in exchange for potassium and hydrogen ions. [1]
Pathogenesis
Secondary hyperaldosteronism syndrome is a disease of increasing aldosterone or other mineralocorticoid levels. The resulting Na+ retention produces hypertension, and elevated K+ excretion may cause hypokalemia. Patients with Secondary hyperaldosertonism may have:
- Renin-producing tumors
- Renal artery stenosis
- Cushing syndrome
- Liddle's syndrome
- Ectopic ACTH production
- Licorice ingestion
- Other mineralocorticoids excess:
Genetics
References
- ↑ Williams GH (2005). "Aldosterone biosynthesis, regulation, and classical mechanism of action". Heart Fail Rev. 10 (1): 7–13. doi:10.1007/s10741-005-2343-3. PMID 15947886.
- ↑ "File:Adrenal Steroids Pathways.svg - Wikimedia Commons".