Hypertension
2077CHAPTER 277
established, the rate of rise of blood pressure in the early morning
(blood pressure “surge”) may also predict a higher risk of cardiovascular events.
Home blood pressure and average 24-h ambulatory blood pressure
measurements are generally lower than clinic blood pressures. Recent
guidelines provide values of home and ambulatory blood pressure
monitoring that correspond to office-measured blood pressures.
Approximately 15–20% of patients with elevated office blood pressures
have normal ambulatory readings, a phenomenon termed “white coat
hypertension.” Long-term outcomes of individuals with white coat
hypertension are more similar to normotensive individuals than to
individuals with sustained hypertension (elevation of both office and
out-of-office blood pressures). In contrast, “masked hypertension”
(normal office blood pressure and elevated out-of-office blood pressure) is associated with a risk of cardiovascular disease and all-cause
mortality twice that of normotensive individuals, with a risk range
similar to that of patients with sustained hypertension. In populationbased surveys, the prevalence of masked hypertension varies from
10 to 30%.
CLINICAL DISORDERS OF HYPERTENSION
Depending on methods of patient ascertainment, ~80–95% of hypertensive patients are diagnosed as having primary, or “essential,”
hypertension (inclusive of patients with obesity and the metabolic
syndrome). In the remaining 5–20% of hypertensive patients, an
underlying disorder causing the elevation of blood pressure can be
identified (Tables 277-2 and 277-3). In individuals with “secondary”
TABLE 277-2 Systolic Hypertension with Wide Pulse Pressure
1. Decreased vascular compliance (arteriosclerosis)
2. Increased cardiac output
a. Aortic regurgitation
b. Thyrotoxicosis
c. Hyperkinetic heart syndrome
d. Fever
e. Arteriovenous fistula
f. Patent ductus arteriosus
TABLE 277-3 Secondary Causes of Systolic and Diastolic Hypertension
Renal Parenchymal diseases, renal cysts (including
polycystic kidney disease), renal tumors
(including renin-secreting tumors), obstructive
uropathy
Renovascular Arteriosclerotic, fibromuscular dysplasia
Adrenal Primary aldosteronism, Cushing’s syndrome,
17α-hydroxylase deficiency, 11β-hydroxylase
deficiency, 11-hydroxysteroid dehydrogenase
deficiency (licorice), pheochromocytoma
Aortic coarctation
Obstructive sleep apnea
Preeclampsia/eclampsia
Neurogenic Psychogenic, diencephalic syndrome, familial
dysautonomia, polyneuritis (acute porphyria, lead
poisoning), acute increased intracranial pressure,
acute spinal cord section
Miscellaneous endocrine Hypothyroidism, hyperthyroidism, hypercalcemia,
acromegaly
Medications High-dose estrogens, adrenal steroids,
decongestants, appetite suppressants,
amphetamines, cyclosporine, tricyclic
antidepressants, atypical antipsychotics,
monoamine oxidase inhibitors, erythropoietin,
nonsteroidal anti-inflammatory agents, alcohol,
herbal supplements, cocaine, others
Mendelian forms of
hypertension
See Table 277-4
hypertension, a specific mechanism for the blood pressure elevation
is often more apparent. Clues to secondary hypertension include
characteristic clinical features, severe or drug-resistant hypertension,
recent onset of hypertension, disproportionate target organ damage,
and younger age.
■ PRIMARY HYPERTENSION
Primary hypertension tends to be familial and is likely to be the consequence of an interaction between environmental and genetic factors. The prevalence of primary hypertension increases with age, and
individuals with relatively high blood pressures at younger ages are at
increased risk for the subsequent development of hypertension. It is
likely that primary hypertension represents a spectrum of disorders
with different underlying pathophysiologies. In the majority of patients
with established hypertension, peripheral resistance is increased and
cardiac output is normal or decreased; however, in younger patients
with mild or labile hypertension, cardiac output may be increased
and peripheral resistance may be normal. When plasma renin activity
(PRA) is plotted against 24-h sodium excretion, ~10–15% of hypertensive patients have high PRA, and 25% have low PRA. High-renin
patients may have a vasoconstrictor form of hypertension, whereas
low-renin patients may have volume-dependent hypertension. Compared to other U.S. populations, African Americans have a high prevalence of hypertension and hypertension-related cardiovascular disease
and renal morbidity and mortality. Hypertensive African Americans
tend to have low plasma renin and volume-dependent hypertension.
■ OBESITY AND THE METABOLIC SYNDROME
(See also Chap. 408) Sixty percent of hypertensive adults are >20%
overweight, and there is a well-documented association between obesity (body mass index >30 kg/m2
) and hypertension. Cross-sectional
studies document a direct linear correlation between body weight
(or body mass index) and blood pressure. Centrally located body fat
is a more important determinant of blood pressure elevation than is
peripheral body fat.
Hypertension and dyslipidemia frequently occur together and in
association with resistance to insulin-stimulated glucose uptake. This
clustering of risk factors is often, but not invariably, associated with
obesity, particularly abdominal obesity. Insulin resistance also is associated with an unfavorable imbalance in the endothelial production of
mediators that regulate platelet aggregation, coagulation, fibrinolysis,
and vessel tone. When these risk factors cluster, the risks for CHD,
stroke, diabetes, and cardiovascular disease mortality are increased
further.
Depending on the populations studied and the methodologies
for defining insulin resistance, ~25–50% of nonobese, nondiabetic
hypertensive persons are insulin resistant. The constellation of insulin
resistance, abdominal obesity, hypertension, and dyslipidemia has been
designated as the metabolic syndrome. First-degree relatives of patients
with primary hypertension are also insulin resistant, and hyperinsulinemia (a surrogate marker of insulin resistance) may predict the
eventual development of hypertension and cardiovascular disease. An
antinatriuretic effect of insulin may contribute to the development
of hypertension. Although the metabolic syndrome may in part be
heritable as a polygenic condition, the expression of the syndrome is
modified by environmental factors, such as degree of physical activity
and diet. Insulin sensitivity increases and blood pressure decreases in
response to weight loss. The recognition that cardiovascular disease
risk factors tend to cluster within individuals has important implications for the evaluation and treatment of hypertension. Evaluation
of both hypertensive patients and individuals at risk for developing
hypertension should include assessment of overall cardiovascular disease risk. Similarly, introduction of lifestyle modification strategies and
drug therapies should address overall risk and not focus exclusively on
hypertension.
■ RENAL PARENCHYMAL DISEASES
Virtually all disorders of the kidney may cause hypertension, and
renal disease is the most common cause of secondary hypertension.
2078 PART 6 Disorders of the Cardiovascular System
Hypertension is present in >80% of patients with chronic renal failure.
In general, hypertension is more severe in glomerular diseases than in
interstitial diseases such as chronic pyelonephritis. Conversely, hypertension may cause nephrosclerosis, and in some instances, it may be
difficult to determine whether hypertension or renal disease was the
initial disorder. Proteinuria >1000 mg/d and an active urine sediment
are indicative of primary renal disease. In either instance, the goals are
to control blood pressure and retard the rate of progression of renal
dysfunction.
■ RENOVASCULAR HYPERTENSION
Hypertension due to an occlusive lesion of a renal artery, renovascular hypertension, is a potentially curable form of hypertension. Two
groups of patients are at risk for this disorder: older arteriosclerotic
patients who have a plaque obstructing the renal artery, frequently
at its origin, and patients with fibromuscular dysplasia. Atherosclerosis accounts for the large majority of patients with renovascular
hypertension. Although fibromuscular dysplasia may occur at any
age, it has a strong predilection for young white women. The lesions
of fibromuscular dysplasia are frequently bilateral and, in contrast to
atherosclerotic renovascular disease, tend to affect more distal portions
of the renal artery.
Renovascular hypertension should be considered in patients with
other evidence of atherosclerotic vascular disease. Severe or refractory
hypertension, recent loss of hypertension control or recent onset of
moderately severe hypertension, carotid or femoral artery bruits, flash
pulmonary edema, and unexplained deterioration of renal function or
deterioration of renal function associated with an angiotensin-converting
enzyme inhibitor (ACEI) should raise the possibility of renovascular
hypertension. Approximately 50% of patients with renovascular hypertension have an abdominal or flank bruit, and the bruit is more likely to
be hemodynamically significant if it lateralizes or extends throughout
systole into diastole.
If renal artery stenosis is suspected and if the clinical condition
warrants an intervention such as percutaneous transluminal renal
angioplasty (PTRA), placement of a vascular endoprosthesis (stent),
or surgical renal revascularization, imaging studies should be the next
step in the evaluation. Doppler ultrasound of the renal arteries produces reliable estimates of renal blood flow and offers the opportunity
to track a lesion over time. Positive studies usually are confirmed at
angiography, whereas false-negative results occur frequently, particularly in obese patients. Gadolinium-contrast magnetic resonance
angiography offers clear images of the proximal renal artery but may
miss distal lesions. An advantage is the opportunity to image the renal
arteries with an agent that is not nephrotoxic. Contrast arteriography
remains the “gold standard” for evaluation and identification of renal
artery lesions.
Some degree of renal artery obstruction may be observed in almost
50% of patients with atherosclerotic disease, and there are several
approaches for evaluating the functional significance of such a lesion
to predict the effect of vascular repair on blood pressure control and
renal function. Functionally significant lesions generally occlude >70%
of the lumen of the affected renal artery. On angiography, the presence
of collateral vessels to the ischemic kidney suggests a functionally
significant lesion. A lateralizing renal vein renin ratio (ratio >1.5 of
affected side/contralateral side) has a 90% predictive value for a lesion
that would respond to vascular repair; however, the false-negative rate
for blood pressure control is 50–60%.
A decision concerning vascular repair versus medical therapy and
the type of repair procedure should be individualized. Several randomized clinical trials have found that PTRA with stent placement in
patients with arteriosclerotic renal artery stenosis offers no advantages
to medical therapy in controlling blood pressure, reducing cardiovascular events and mortality, or preserving kidney function. If blood
pressure is adequately controlled with medical therapy and renal function remains stable, there may be little impetus to pursue an extensive
evaluation for renal artery stenosis. Patients with long-standing hypertension, advanced renal insufficiency, or diabetes mellitus are less likely to
benefit from renal vascular repair. Patients with fibromuscular disease
have more favorable outcomes with vascular repair than do patients
with atherosclerotic lesions, presumably owing to their younger age,
shorter duration of hypertension, and less systemic disease. The most
effective medical therapies for renovascular hypertension include an
ACE inhibitor or an angiotensin II receptor blocker; however, these
agents decrease glomerular filtration rate in a stenotic kidney owing to
efferent renal arteriolar dilation. In the presence of bilateral renal artery
stenosis or renal artery stenosis to a solitary kidney, progressive renal
insufficiency may result from the use of these agents. Importantly, the
renal insufficiency is generally reversible after discontinuation of the
offending drug.
■ PRIMARY ALDOSTERONISM
Excess aldosterone production due to primary aldosteronism is a
potentially curable form of hypertension. In patients with primary
aldosteronism, increased aldosterone production is independent of the
renin-angiotensin system, and the consequences are sodium retention,
hypertension, hypokalemia, low PRA, cardiovascular disease, and kidney damage. The reported prevalence of this disorder varies from <2
to ~15% of hypertensive individuals. In part, this variation is related to
the intensity of screening and the criteria for establishing the diagnosis.
History and physical examination provide little information about
the diagnosis. The age at the time of diagnosis is generally the third
through fifth decade. Hypertension is usually mild to moderate but
occasionally may be severe; primary aldosteronism should be considered in all patients with refractory hypertension. Most patients are
asymptomatic; however, infrequently, polyuria, polydipsia, paresthesias, or muscle weakness may be present as a consequence of hypokalemic alkalosis. Although serum K+ is an insensitive screening test, in
hypertensive patients with unprovoked hypokalemia (i.e., unrelated to
diuretics, vomiting, or diarrhea), the prevalence of primary aldosteronism approaches 40–50%. In patients on diuretics, serum potassium
<3.1 mmol/L (<3.1 meq/L) also raises the possibility of primary
aldosteronism.
The ratio of plasma aldosterone (PA) to PRA (PA/PRA) is a useful
screening test. These measurements preferably are obtained in ambulatory patients in the morning. A ratio >30:1 in conjunction with a PA
concentration >555 pmol/L (>20 ng/dL) reportedly has a sensitivity of
90% and a specificity of 91% for an aldosterone-producing adenoma.
In a Mayo Clinic series, an aldosterone-producing adenoma subsequently was confirmed surgically in >90% of hypertensive patients
with a PA/PRA ratio ≥20 and a PA concentration ≥415 pmol/L
(≥15 ng/dL). There are, however, several caveats to interpreting the
ratio. The cutoff for a “high” ratio is laboratory- and assay-dependent.
Some antihypertensive agents may affect the ratio (e.g., aldosterone
antagonists, angiotensin receptor blockers [ARBs], and ACEIs may
increase renin; aldosterone antagonists may increase aldosterone).
Current recommendations are to withdraw aldosterone antagonists
for at least 4–6 weeks before obtaining these measurements. Because
aldosterone biosynthesis is potassium-dependent, hypokalemia should
be corrected with oral potassium supplements prior to screening. A
high ratio in the absence of an elevated PA level is considerably less
specific for primary aldosteronism. In patients with renal insufficiency, the ratio may also be elevated because of decreased aldosterone
clearance. In patients with an elevated PA/PRA ratio, the diagnosis of
primary aldosteronism can be confirmed by demonstrating failure to
suppress PA to any one of four suppression tests: oral sodium loading,
saline infusion, fludrocortisone, or captopril.
Several sporadic and familial adrenal abnormalities may culminate
in the syndrome of primary aldosteronism, and appropriate therapy
depends on the specific etiology. The two most common causes of sporadic primary aldosteronism are an aldosterone-producing adenoma
and bilateral adrenal hyperplasia. Together, they account for >90%
of all patients with primary aldosteronism. The tumor is most often
unilateral and measures <3 cm in diameter. Most of the remainder
of these patients have bilateral adrenocortical hyperplasia (idiopathic
hyperaldosteronism). An increasing number of somatic mutations,
including mutations in aldosterone-regulating genes, has been identified in adenomas and in idiopathic hyperaldosteronism. Rarely,
Hypertension
2079CHAPTER 277
primary aldosteronism may be caused by an adrenal carcinoma or an
ectopic malignancy, e.g., ovarian arrhenoblastoma. Functional differences in hormone secretion may assist in the diagnosis of adenoma
versus hyperplasia. Aldosterone biosynthesis is more responsive to
ACTH in patients with adenoma and more responsive to angiotensin
in patients with hyperplasia. Consequently, patients with adenoma
tend to have higher PA in the early morning that decreases during
the day, reflecting the diurnal rhythm of ACTH, whereas PA tends to
increase with upright posture in patients with hyperplasia, reflecting
the normal postural response of the renin-angiotensin-aldosterone
axis. However, there is overlap in the ability of these measurements to
discriminate between adenoma and hyperplasia. Rare familial forms
of primary aldosteronism include glucocorticoid-remediable primary
aldosteronism and familial aldosteronism types II and III. Familial
primary aldosteronism reflects a variety of germline mutations, and
genetic testing may assist in the diagnosis of these disorders.
Adrenal computed tomography (CT) should be carried out in all
patients diagnosed with primary aldosteronism. High-resolution CT may
identify tumors as small as 0.3 cm and is positive for an adrenal tumor
90% of the time. If the CT is not diagnostic, an adenoma may be detected
by adrenal scintigraphy with 6-β-[I131] iodomethyl-19-norcholesterol after
dexamethasone suppression (0.5 mg every 6 h for 7 days); however, this
technique has decreased sensitivity for adenomas <1.5 cm.
When carried out by an experienced radiologist, bilateral adrenal
venous sampling for measurement of PA is the most accurate means
of differentiating unilateral from bilateral forms of primary aldosteronism. A major difference in the aldosterone/cortisol ratio is indicative
of unilateral disease. The sensitivity and specificity of adrenal venous
sampling (95 and 100%, respectively) for detecting unilateral aldosterone hypersecretion are superior to those of adrenal CT; success rates
are 90–96%, and complication rates are <2.5%. One frequently used
protocol involves sampling for aldosterone and cortisol levels in
response to ACTH stimulation. An ipsilateral/contralateral aldosterone
ratio >4, with symmetric ACTH-stimulated cortisol levels, is indicative
of unilateral aldosterone production.
Hypertension generally is responsive to surgery in patients with
adenoma but not in patients with bilateral adrenal hyperplasia. For
patients with a unilateral adenoma, surgical treatment is generally
more effective than medical therapy. Unilateral adrenalectomy, often
done via a laparoscopic approach, is curative in 40–70% of patients
with an adenoma. Transient hypoaldosteronism may occur up to
3 months postoperatively, resulting in hyperkalemia, which should be
treated with potassium-wasting diuretics and with fludrocortisone, if
needed. Patients with bilateral hyperplasia should be treated medically.
The drug regimen for these patients, as well as for patients with an adenoma who are poor surgical candidates, should include an aldosterone
antagonist and, if necessary, other potassium-sparing diuretics.
Glucocorticoid-remediable hyperaldosteronism is a rare, monogenic
autosomal dominant disorder characterized by moderate to severe
hypertension, often occurring at an early age. These patients may have
a family history of hemorrhagic stroke at a young age. Hypokalemia is
usually mild or absent. Normally, angiotensin II stimulates aldosterone
production by the adrenal zona glomerulosa, whereas ACTH stimulates cortisol production in the zona fasciculata. Owing to a chimeric
gene on chromosome 8, ACTH also regulates aldosterone secretion
by the zona fasciculata in patients with glucocorticoid-remediable
hyperaldosteronism. The consequence is overproduction in the zona
fasciculata of both aldosterone and hybrid steroids (18-hydroxycortisol
and 18-oxocortisol) due to oxidation of cortisol. The diagnosis may be
established by urine excretion rates of these hybrid steroids that are
20–30 times normal or by direct genetic testing. Therapeutically, suppression of ACTH with low-dose glucocorticoids corrects the hyperaldosteronism, hypertension, and hypokalemia. Aldosterone antagonists
are also therapeutic options. Patients with familial aldosteronism types
II and III are treated with aldosterone antagonists or adrenalectomy.
■ CUSHING’S SYNDROME
(See also Chap. 386) Cushing’s syndrome is related to excess cortisol
production due either to excess ACTH secretion (from a pituitary
tumor or an ectopic tumor) or to ACTH-independent adrenal production of cortisol. Hypertension occurs in 75–80% of patients with
Cushing’s syndrome. The mechanism of hypertension may be related
to stimulation of mineralocorticoid receptors by cortisol and increased
secretion of other adrenal steroids. If clinically suspected based on
phenotypic characteristics, in patients not taking exogenous glucocorticoids, laboratory screening may be carried out with measurement of
24-h excretion rates of urine-free cortisol or an overnight dexamethasonesuppression test. Late night salivary cortisol is also a sensitive and
convenient screening test. Further endocrine and radiologic evaluation
is required to confirm the diagnosis and identify the specific etiology
of Cushing’s syndrome. Appropriate therapy depends on the etiology.
■ PHEOCHROMOCYTOMA
(See also Chap. 387) Catecholamine-secreting tumors are located
in the adrenal medulla (pheochromocytoma) or in extra-adrenal
paraganglion tissue (paraganglioma) and account for hypertension in
~0.05% of patients. If unrecognized, pheochromocytoma may result in
lethal cardiovascular consequences. Clinical manifestations, including
hypertension, are primarily related to increased circulating catecholamines, although some of these tumors may secrete a number of other
vasoactive substances. In a small percentage of patients, epinephrine is
the predominant catecholamine secreted by the tumor, and these
patients may present with hypotension rather than hypertension. The
initial suspicion of the diagnosis is based on symptoms and/or the
association of pheochromocytoma with other disorders (Table 277-4).
Approximately 20% of pheochromocytomas are familial with autosomal dominant inheritance. Inherited pheochromocytomas may be
associated with multiple endocrine neoplasia (MEN) type 2A and
type 2B, von Hippel-Lindau disease, and neurofibromatosis. Each of
these syndromes is related to specific germline mutations. Mutations
of succinate dehydrogenase genes are associated with paraganglioma
syndromes, generally characterized by head and neck paragangliomas.
Laboratory testing consists of measuring catecholamines in either
urine or plasma, e.g., 24-h urine fractionated metanephrine excretion
or plasma-free metanephrines under standardized conditions. The
urine measurement is less sensitive but more specific. The next step
would involve imaging of the abdomen and pelvis (CT or magnetic resonance imaging). Genetic screening is available for evaluating patients
and relatives suspected of harboring a pheochromocytoma associated
with a familial syndrome. Peripheral α-adrenergic antagonists may be
used to control blood pressure. Surgical excision is the definitive treatment of pheochromocytoma and results in cure in ~90% of patients.
■ MISCELLANEOUS CAUSES OF HYPERTENSION
Hypertension occurs in >50% of individuals with obstructive sleep
apnea. Hypertension appears to be due to sympathetic activation
caused by intermittent hypoxia and fragmented sleep. The severity of
hypertension correlates with the severity of sleep apnea. Approximately
70% of patients with obstructive sleep apnea are obese. Hypertension
related to obstructive sleep apnea also should be considered in patients
with drug-resistant hypertension and patients with a history of snoring. The diagnosis can be confirmed by polysomnography. In obese
patients, weight loss may alleviate or cure sleep apnea and related
hypertension. Continuous positive airway pressure (CPAP) and bilevel
positive airway pressure (BiPAP) administered during sleep are effective therapies for obstructive sleep apnea. Although CPAP and BiPAP
generally have only a modest effect on blood pressure, their use may
improve blood pressure responsiveness to antihypertensive agents.
Increasing evidence links other sleep-related disorders to hypertension,
including restless legs syndrome and sleep-related bruxism
Coarctation of the aorta is the most common congenital cardiovascular cause of hypertension (Chap. 269). The incidence is 1–8 per
1000 live births. It is usually sporadic but occurs in 35% of children
with Turner’s syndrome. Even when the anatomic lesion is surgically
corrected in infancy, up to 30% of patients develop subsequent hypertension and are at risk of accelerated coronary artery disease and
cerebrovascular events. Patients with less severe lesions may not be
diagnosed until young adulthood. Physical findings include diminished
2080 PART 6 Disorders of the Cardiovascular System
and delayed femoral pulses and a systolic pressure gradient between the
right arm and the legs and, depending on the location of the coarctation, between the right and left arms. A blowing systolic murmur may
be heard in the posterior left interscapular areas. The diagnosis may be
confirmed by thoracic and abdominal CT, angiogram, and transesophageal echocardiography. Therapeutic options include surgical repair
and balloon angioplasty, with or without placement of an intravascular
stent. Subsequently, many patients do not have a normal life expectancy but may have persistent hypertension, with death due to ischemic
heart disease, cerebral hemorrhage, or aortic aneurysm.
Several additional endocrine disorders, including thyroid diseases
and acromegaly, cause hypertension. Mild diastolic hypertension
may be a consequence of hypothyroidism, whereas hyperthyroidism
may result in systolic hypertension. Hypercalcemia of any etiology,
the most common being primary hyperparathyroidism, may result in
hypertension. Preeclampsia, a hypertensive disorder of pregnancy that
commonly presents after 20 weeks of gestation, may be a risk factor for
subsequent cardiovascular disease and stroke. Hypertension also may
be related to a number of prescribed or over-the-counter medications
and other substances.
MONOGENIC HYPERTENSION
In addition to glucocorticoid-remediable primary aldosteronism, a
number of rare forms of monogenic hypertension have been identified (Table 277–4). These disorders may be recognized by their
characteristic phenotypes, and in many instances, the diagnosis may
be confirmed by genetic analysis. Several inherited defects in adrenal
steroid biosynthesis and metabolism result in mineralocorticoidinduced hypertension and hypokalemia. In patients with a 17αhydroxylase deficiency, synthesis of sex hormones and cortisol is
decreased (Fig. 277-3). Consequently, these individuals do not mature
sexually; males may present with pseudohermaphroditism and females
with primary amenorrhea and absent secondary sexual characteristics. Because cortisol-induced negative feedback on pituitary ACTH
production is diminished, ACTH-stimulated adrenal steroid synthesis
proximal to the enzymatic block is increased. Hypertension and hypokalemia are consequences of increased synthesis of mineralocorticoids
proximal to the enzymatic block, particularly desoxycorticosterone.
Increased steroid production and, hence, hypertension may be treated
with low-dose glucocorticoids. An 11β-hydroxylase deficiency results
in a salt-retaining adrenogenital syndrome that occurs in 1 in 100,000
live births. This enzymatic defect results in decreased cortisol synthesis, increased synthesis of mineralocorticoids (e.g., desoxycorticosterone), and shunting of steroid biosynthesis into the androgen pathway.
In the severe form, the syndrome may present early in life, including
the newborn period, with virilization and ambiguous genitalia in
females and penile enlargement in males, or in older children as precocious puberty and short stature. Acne, hirsutism, and menstrual
irregularities may be the presenting features when the disorder is first
recognized in adolescence or early adulthood. Hypertension is less
common in the late-onset forms. Patients with an 11β-hydroxysteroid
dehydrogenase deficiency have an impaired capacity to metabolize cortisol to its inactive metabolite, cortisone, and hypertension is related to
activation of mineralocorticoid receptors by cortisol. This defect may
be inherited or acquired, due to licorice-containing glycyrrhizin acid.
The same substance is present in the paste of several brands of chewing
tobacco. The defect in Liddle’s syndrome (Chaps. 53 and 386) results
from constitutive activation of amiloride-sensitive ENaC on the distal
renal tubule, resulting in excess sodium reabsorption; the syndrome
is ameliorated by amiloride. Hypertension exacerbated in pregnancy
(Chap. 479) may be due to activation of the mineralocorticoid receptor
by progesterone.
TABLE 277-4 Rare Mendelian Forms of Hypertension
DISEASE PHENOTYPE GENETIC CAUSE
Glucocorticoid-remediable
hyperaldosteronism
Autosomal dominant
Absent or mild hypokalemia
Chimeric 11β-hydroxylase/aldosterone gene on
chromosome 8
17α-Hydroxylase deficiency Autosomal recessive
Males: pseudohermaphroditism
Females: primary amenorrhea, absent secondary sexual characteristics
Random mutations of the CYP17 gene on chromosome
10
11β-Hydroxylase deficiency Autosomal recessive
Masculinization
Mutations of the CYP11B1 gene on chromosome
8q21-q22
11β-Hydroxysteroid dehydrogenase
deficiency (apparent
mineralocorticoid excess syndrome)
Autosomal recessive
Hypokalemia, low renin, low aldosterone
Mutations in the 11β-hydroxysteroid dehydrogenase
gene
Liddle’s syndrome Autosomal dominant
Hypokalemia, low renin, low aldosterone
Mutation subunits of the epithelial sodium channel
SCNN1B and SCNN1C genes
Pseudohypoaldosteronism type II
(Gordon’s syndrome)
Autosomal dominant
Hyperkalemia, normal glomerular filtration rate
Linkage to chromosomes 1q31-q42 and 17p11-q21
Hypertension exacerbated in
pregnancy
Autosomal dominant
Severe hypertension in early pregnancy
Missense mutation with substitution of leucine for
serine at codon 810 (MRL810)
Polycystic kidney disease Autosomal dominant
Large cystic kidneys, renal failure, liver cysts, cerebral aneurysms,
valvular heart disease
Mutations in the PKD1 gene on chromosome 16 and
PKD2 gene on chromosome 4
Pheochromocytoma Autosomal dominant
(a) Multiple endocrine neoplasia, type 2A (a) Mutations in the RET protooncogene
Medullary thyroid carcinoma, hyperparathyroidism
(b) Multiple endocrine neoplasia, type 2B (b) Mutations in the RET protooncogene
Medullary thyroid carcinoma, mucosal neuromas, thickened corneal
nerves, alimentary ganglioneuromatoses, marfanoid habitus
(c) von Hippel-Lindau disease (c) Mutations in the VHL tumor-suppressor gene
Retinal angiomas, hemangioblastomas of the cerebellum and spinal
cord, renal cell carcinoma
(d) Neurofibromatosis type 1 (d) Mutations in the NF1 tumor-suppressor gene
Multiple neurofibromas, café-au-lait spots
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