Hypertension
2081CHAPTER 277
APPROACH TO THE PATIENT
Hypertension
HISTORY AND PHYSICAL
The initial assessment of a hypertensive patient should include a
complete history and physical examination to confirm a diagnosis
of hypertension, screen for other cardiovascular disease risk factors,
screen for secondary causes of hypertension, identify cardiovascular consequences of hypertension and other comorbidities, assess
blood pressure–related lifestyles, and determine the potential for
intervention. Most patients with hypertension have no specific
symptoms referable to their blood pressure elevation. Table 277-5
lists salient features of the history and physical examination of the
hypertensive patient.
Reliable measurements of blood pressure depend on attention
to the details of the technique and conditions of the measurement.
Proper training of observers, positioning of the patient, and selection of cuff size are essential. At the first visit, blood pressure should
be measured in both arms, and the arm with higher readings should
be used for subsequent measurements. An average of two to three
measurements obtained on two to three separate occasions will
provide a more accurate estimation of blood pressure than a single
casual measurement. Rarely, in older patients, pseudohypertension
may be related to the inability to measure blood pressure accurately
in severely sclerotic arteries. This condition is suggested if the radial
pulse remains palpable despite occlusion of the brachial artery
by the cuff (Osler maneuver). The actual blood pressure can be
determined by direct intra-arterial measurement. Owing to recent
regulations preventing the use of mercury because of concerns
about its potential toxicity, most office measurements are made
with aneroid sphygmomanometers or with oscillometric devices.
These instruments should be calibrated periodically, and their
accuracy confirmed.
LABORATORY TESTING
Table 277-6 lists recommended laboratory tests in the initial evaluation of hypertensive patients. Repeat measurements of renal
Mineralocorticoid Glucocorticoid Androgen
Cholesterol
Pregnenolone 17 OH Pregnenolone
Deoxycortisol
(17α hydroxylase)
DHEA
Progesterone
Corticosterone
Aldosterone
Deoxycorticosterone
17 OH Progesterone
Cortisone
Cortisol
Androstenedione Testosterone
(21 hydroxylase)
(11β hydroxylase)
(11β hydroxysteroid dehydrogenase)
FIGURE 277-3 Adrenal enzymatic defects. DHEA, dehydroepiandrosterone.
TABLE 277-5 Relevant History and Physical
History
Duration of hypertension
Previous therapies: responses and side effects
Family history of hypertension and cardiovascular disease
Dietary and psychosocial history
Alcohol consumption
Other risk factors: weight change, dyslipidemia, smoking, diabetes, physical
inactivity
Evidence of secondary hypertension: history of renal disease; change in
appearance; muscle weakness; spells of sweating, palpitations, tremor; erratic
sleep, snoring, daytime somnolence; symptoms of hypo- or hyperthyroidism; use
of agents that may increase blood pressure
Evidence of target organ damage: history of TIA, stroke, transient blindness;
angina, myocardial infarction, congestive heart failure; sexual function
Other comorbidities
Physical
Body habitus
Blood pressure in both arms
Supine and standing blood pressures
Funduscopic examination of retina
Quality of femoral and pedal pulses
Vascular and abdominal bruits
Cardiac rate and rhythm
Signs of congestive heart failure
Characteristics of secondary hypertension
Abbreviation: TIA, transient ischemic attack.
function, serum electrolytes, fasting glucose, and lipids may be
obtained after the introduction of a new antihypertensive agent
and then annually or more frequently if clinically indicated. More
extensive laboratory testing is appropriate for patients with apparent drug-resistant hypertension or when the clinical evaluation
suggests a secondary form of hypertension.
2082 PART 6 Disorders of the Cardiovascular System
TREATMENT
Hypertension
Lowering systolic blood pressure by 10–12 mmHg and diastolic
blood pressure by 5–6 mmHg confers relative risk reductions of
35–40% for stroke and 12–16% for CHD within 5 years of the initiation of treatment. The risk of heart failure is reduced by >50%;
although the benefit of blood pressure lowering on progression
of renal failure is less apparent, hypertension control is the single
most effective intervention for slowing the rate of progression of
hypertension-related kidney disease. There are more potentially
preventable cardiovascular disease events attributed to elevated
blood pressure in individuals at higher than at lower risk of cardiovascular disease and in older rather than younger adults.
LIFESTYLE INTERVENTIONS
Implementation of lifestyles that favorably affect blood pressure has
implications for both the prevention and the treatment of hypertension. Health-promoting lifestyle modifications are recommended
for individuals with “elevated” blood pressure and as an adjunct
to drug therapy in hypertensive individuals (Table 277-7). These
interventions should address overall cardiovascular disease risk.
Although the impact of lifestyle interventions on blood pressure
is more pronounced in persons with hypertension, in short-term
trials, weight loss and reduction of dietary NaCl have been shown to
prevent the development of hypertension. In hypertensive individuals, even if these interventions do not produce a sufficient reduction
in blood pressure to avoid drug therapy, the number of medications
or doses required for blood pressure control may be reduced.
Prevention and treatment of obesity are important for reducing
blood pressure and cardiovascular disease risk. In short-term trials,
even modest weight loss can lead to a reduction of blood pressure
and an increase in insulin sensitivity. In longitudinal studies, a
direct correlation exists between change in weight and change
in blood pressure over time. Average blood pressure reductions
of 6.3/3.1 mmHg have been observed with a reduction in mean
body weight of 9.2 kg. Regular physical activity facilitates weight
loss, decreases blood pressure, and reduces the overall risk of
TABLE 277-6 Basic Laboratory Tests for Initial Evaluation
SYSTEM TEST
Renal Microscopic urinalysis, albumin
excretion, serum BUN and creatinine
(compute eGFR)
Endocrine Serum sodium, potassium, calcium,
TSH
Metabolic Fasting blood glucose, total
cholesterol, HDL and LDL (often
computed) cholesterol, triglycerides
Other CBC, electrocardiogram
Abbreviations: BUN, blood urea nitrogen; CBC, complete blood count; eGFR,
estimated glomerular filtration rate; HDL, high-density lipoprotein; LDL, low-density
lipoprotein; TSH, thyroid-stimulating hormone.
TABLE 277-7 Lifestyle Modifications to Manage Hypertension
Weight reduction Attain and maintain BMI <25 kg/m2
Dietary salt reduction <6 g NaCl/d
Adapt DASH-type
dietary plan
Diet rich in fruits, vegetables, and low-fat dairy
products with reduced content of saturated and
total fat. Diet is also rich in potassium, calcium, and
magnesium.
Moderation of alcohol
consumption
For those who drink alcohol, consume ≤2 drinks/d in
men and ≤1 drink/d in women
Physical activity Regular aerobic activity, e.g., brisk walking for 30 min/d
Abbreviations: BMI, body mass index; DASH, Dietary Approaches to Stop
Hypertension (trial).
cardiovascular disease. Blood pressure may be lowered by 30 min of
moderately intense physical activity, such as brisk walking, 6–7 days
a week, or by more intense, less frequent workouts.
There is individual variability in the sensitivity of blood pressure to NaCl, and this variability may have a genetic basis. Several
genetic loci have been associated with NaCl sensitivity. Based on
results of meta-analyses, lowering of blood pressure by limiting
daily NaCl intake to 4.4–7.4 g (75–125 meq) results in blood
pressure reductions of 3.7–4.9/0.9–2.9 mmHg in hypertensive individuals and lesser reductions in normotensive individuals. Salt
sensitivity is especially common in blacks, older adults, and those
with higher levels of blood pressure. Independent of its effect on
blood pressure, excessive consumption of NaCl is associated with
an increased risk of stroke and cardiovascular disease. Potassium
and calcium supplementation have inconsistent, modest antihypertensive effects, and, independent of blood pressure, potassium
supplementation may be associated with reduced stroke mortality.
Additionally, consuming three or more alcoholic drinks per day (a
standard drink contains ~14 g ethanol) is associated with higher
blood pressures, and a reduction of alcohol consumption is associated with a reduction of blood pressure. The Dietary Approaches
to Stop Hypertension (DASH) trial convincingly demonstrated that
over an 8-week period a diet high in fruits, vegetables, and low-fat
dairy products lowers blood pressure in individuals with highnormal blood pressures or mild hypertension. Reduction of daily
NaCl intake to <6 g (100 meq) augmented the effect of this diet on
blood pressure. Fruits and vegetables are enriched sources of potassium, magnesium, and fiber, and dairy products are an important
source of calcium.
PHARMACOLOGIC THERAPY
According to 2017 guidelines developed by the American College
of Cardiology (ACC)/American Heart Association (AHA), atherosclerotic cardiovascular disease (ASCVD) risk estimation guides
the threshold for initiation of blood pressure–lowering medications
(Table 277-8). A risk calculator may be used to estimate risk of
ASCVD, e.g., ACC/AHA Pooled Cohort Equations (http://tools.acc.
org/ASCVD-Risk-Estimator).
There is considerable variation in individual responses to different classes of antihypertensive agents, and the magnitude of
response to any single agent may be limited by activation of
counter-regulatory mechanisms. To achieve goal blood pressure,
most patients will require at least two antihypertensive agents.
More often than not, combinations of agents, with complementary
antihypertensive mechanisms, are required to achieve goal blood
pressure reductions. Selection of antihypertensive agents and combinations of agents should be individualized, taking into account
TABLE 277-8 ACC/AHA Guidelines for Hypertension Management
Indications for Use of Blood Pressure–Lowering Medications
Secondary prevention of recurrent CVD events in patients with clinical CVD
(defined as CHD, CHF, stroke) and SBP ≥130 mmHg or DBP ≥80 mmHg
Primary prevention in patients with an estimated 10-year ASCVD risk ≥10% and
SBP ≥130 mmHg or DBP ≥80 mmHg
Primary prevention of CVD and low CVD risk in patients with SBP ≥140 mmHg or
DBP ≥90 mmHg
Blood Pressure Goal for Patients with Hypertension
For adults with confirmed hypertension and known CVD or 10-year ASCVD event
risk ≥10% , a BP target <130/80 mmHg
Possible Exceptions to Therapeutic Target of <130/80 mmHg
Patients >80 years of age
Patients previously untreated for hypertension who experience an ischemic
stroke or TIA and have blood pressure <140/90 mmHg
Acute therapy of most hypertensive urgencies and emergencies
Abbreviations: ACC, American College of Cardiology; AHA, American Heart
Association; ASCVD, atherosclerotic cardiovascular disease; BP, blood pressure;
CHD, coronary heart disease; CHF, congestive heart failure; CVD, cardiovascular
disease; DBP, diastolic blood pressure; SBP, systolic blood pressure.
Hypertension
2083CHAPTER 277
age, severity of hypertension, other cardiovascular disease risk
factors, comorbid conditions, and practical considerations related
to cost, side effects, and frequency of dosing. The primary classes of
drugs used to treat hypertension are listed in Table 277-9.
Diuretics Low-dose thiazide diuretics may be used alone or in
combination with other antihypertensive drugs. Thiazides inhibit
the Na+/Cl–
pump in the distal convoluted tubule and hence
increase sodium excretion. In the long term, they also may act as
TABLE 277-9 Examples of Oral Drugs Used in Treatment of Hypertension
DRUG CLASS EXAMPLES
USUAL TOTAL DAILY DOSEa
(DOSING FREQUENCY/DAY) OTHER INDICATIONS CONTRAINDICATIONS/CAUTIONS
Diuretics
Thiazides Hydrochlorothiazide 6.25–50 mg (1–2) Diabetes, dyslipidemia, hyperuricemia,
gout, hypokalemia
Chlorthalidone 25–50 mg (1)
Loop diuretics Furosemide 40–80 mg (2–3) CHF due to systolic dysfunction,
CHF with preserved ejection
fraction, renal failure
Diabetes, dyslipidemia, hyperuricemia,
gout, hypokalemia
Ethacrynic acid 50–100 mg (2–3)
Aldosterone antagonists Spironolactone 25–100 mg (1–2) CHF, primary aldosteronism,
resistant hypertension
Renal failure, hyperkalemia
Eplerenone 50–100 mg (1–2)
K+
retaining Amiloride 5–10 mg (1–2) Liddle’s syndrome Renal failure, hyperkalemia
Triamterene 50–100 mg (1–2)
Beta blockers Asthma, COPD, second- or third-degree
heart block, sick-sinus syndrome
Cardioselective Atenolol 25–100 mg (1) Angina, CHF, post-MI, sinus
tachycardia, ventricular
tachyarrhythmias, thoracic
aortic disease
Metoprolol 25–100 mg (1–2)
Nonselective Propranolol 40–160 mg (2)
Propranolol LA 60–180 (1)
Combined alpha/beta Labetalol 200–800 mg (2)
Carvedilol 12.5–50 mg (2)
Alpha antagonists
Selective Prazosin 2–20 mg (2–3) Prostatism
Doxazosin 1–16 mg (1)
Terazosin 1–10 mg (1–2)
Nonselective Phenoxybenzamine 20–120 mg (2–3) Pheochromocytoma
Sympatholytics
Central Clonidine 0.1–0.6 mg (2)
Clonidine patch 0.1–0.3 mg (1/week)
Methyldopa 250–1000 mg (2)
Reserpine 0.05–0.25 mg (1)
Guanfacine 0.5–2 mg (1)
ACE inhibitors Captopril 25–200 mg (2) Post-MI, coronary syndromes,
CHF, nephropathy
Acute renal failure, bilateral renal artery
stenosis, pregnancy, hyperkalemia
Lisinopril 10–40 mg (1)
Ramipril 2.5–20 mg (1–2)
Angiotensin II antagonists Losartan 25–100 mg (1–2) CHF, nephropathy, ACE inhibitor
cough
Renal failure, bilateral renal artery
stenosis, pregnancy, hyperkalemia
Valsartan 80–320 mg (1)
Candesartan 2–32 mg (1–2)
Renin inhibitors Aliskiren 150–300 mg (1) Diabetic nephropathy Pregnancy
Calcium antagonists
Dihydropyridines Nifedipine
(long-acting)
30–60 mg (1)
Nondihydropyridines Verapamil
(long-acting)
120–360 mg (1–2) Post-MI, supraventricular
tachycardias, angina
Second- or third-degree heart block
Diltiazem
(long-acting)
180–420 mg (1)
Direct vasodilators Hydralazine 25–100 mg (2) Severe coronary artery disease
Minoxidil 2.5–80 mg (1–2)
a
At the initiation of therapy, lower doses may be preferable for elderly patients and for select combinations of antihypertensive agents.
Abbreviations: ACE, angiotensin-converting enzyme; CHF, congestive heart failure; COPD, chronic obstructive pulmonary disease; MI, myocardial infarction.
2084 PART 6 Disorders of the Cardiovascular System
vasodilators. Thiazides are safe, efficacious, inexpensive, and reduce
clinical events. They provide additive blood pressure–lowering
effects when combined with beta blockers, ACEIs, or ARBs. In
contrast, addition of a diuretic to a calcium channel blocker is less
effective. Usual doses of hydrochlorothiazide range from 6.25 to
50 mg/d. Owing to an increased incidence of metabolic side effects
(hypokalemia, insulin resistance, increased cholesterol), higher
doses generally are not recommended. Chlorthalidone is a diuretic
structurally similar to hydrochlorothiazide, and like hydrochlorothiazide, it blocks sodium-chloride cotransport in the early distal
tubule. However, chlorthalidone has a longer half-life (40–60 h vs
9–15 h) and an antihypertensive potency ~1.5–2.0 times that of
hydrochlorothiazide. Potassium loss is also greater with chlorthalidone. Two potassium-sparing diuretics, amiloride and triamterene,
act by inhibiting ENaC in the distal nephron. These agents are weak
antihypertensive agents but may be used in combination with a
thiazide to protect against hypokalemia. The main pharmacologic
target for loop diuretics is the Na+-K+-2Cl–
cotransporter in the
thick ascending limb of the loop of Henle. Loop diuretics generally
are reserved for hypertensive patients with reduced glomerular filtration rates (reflected in serum creatinine >220 μmol/L [>2.5 mg/
dL]), CHF, or sodium retention and edema for some other reason,
such as treatment with a potent vasodilator, e.g., minoxidil.
Blockers of the Renin-Angiotensin System ACEIs decrease the
production of angiotensin II, increase bradykinin levels, and reduce
sympathetic nervous system activity. ARBs provide selective blockade of AT1
Rs, and the effect of angiotensin II on unblocked AT2
Rs
may augment their hypotensive effect. Both classes of agents are
effective antihypertensive agents that may be used as monotherapy or in combination with diuretics, calcium antagonists, and
alpha-blocking agents. ACEIs and ARBs improve insulin action and
ameliorate the adverse effects of diuretics on glucose metabolism.
Although the overall impact on the incidence of diabetes is modest,
compared with amlodipine (a calcium antagonist), valsartan (an
ARB) has been shown to reduce the risk of developing diabetes in
high-risk hypertensive patients. ACEI/ARB combinations are less
effective in lowering blood pressure than is the case when either
class of these agents is used in combination with other classes of
agents. In patients with vascular disease or a high risk of diabetes,
combination ACEI/ARB therapy has been associated with more
adverse events (e.g., cardiovascular death, myocardial infarction,
stroke, and hospitalization for heart failure) without increases in
benefit.
Side effects of ACEIs and ARBs include functional renal insufficiency due to efferent renal arteriolar dilation in a kidney with a
stenotic lesion of the renal artery. Additional predisposing conditions to renal insufficiency induced by these agents include dehydration, CHF, and use of nonsteroidal anti-inflammatory drugs.
Dry cough occurs in ~15% of patients, and angioedema occurs in
<1% of patients taking ACEIs. Angioedema occurs most commonly
in individuals of Asian origin and more commonly in African
Americans than in whites. Hyperkalemia due to hypoaldosteronism
is an occasional side effect of both ACEIs and ARBs.
An alternative approach to blocking the renin-angiotensin system has recently been introduced into clinical practice for the
treatment of hypertension: direct renin inhibitors. Blockade of the
renin-angiotensin system is more complete with renin inhibitors
than with ACEIs or ARBs. Aliskiren is the first of a class of oral,
nonpeptide competitive inhibitors of the enzymatic activity of
renin. Monotherapy with aliskiren seems to be as effective as an
ACEI or ARB for lowering blood pressure, but not more effective.
Further blood reductions may be achieved when aliskiren is used in
combination with a thiazide diuretic or a calcium antagonist. Currently, aliskiren is not considered a first-line antihypertensive agent.
Aldosterone Antagonists Spironolactone is a nonselective
aldosterone antagonist that may be used alone or in combination
with a thiazide diuretic. It may be a particularly effective agent in
patients with low-renin primary hypertension, resistant hypertension, and primary aldosteronism. In patients with CHF, low-dose
spironolactone reduces mortality and hospitalizations for heart
failure when given in addition to conventional therapy with ACEIs,
digoxin, and loop diuretics. Because spironolactone binds to progesterone and androgen receptors, side effects may include gynecomastia, impotence, and menstrual abnormalities. These side effects
are circumvented by a newer agent, eplerenone, which is a selective
aldosterone antagonist.
Calcium Channel Blockers Calcium antagonists reduce vascular
resistance through L-channel blockade, which reduces intracellular calcium and blunts vasoconstriction. This is a heterogeneous
group of agents that includes drugs in the following three classes:
phenylalkylamines (verapamil), benzothiazepines (diltiazem), and
1,4-dihydropyridines (nifedipine-like). Used alone and in combination with other agents (ACEIs, beta blockers, α1
-adrenergic blockers), calcium antagonists effectively lower blood pressure; however,
it is unclear if adding a diuretic to a calcium blocker results in a further lowering of blood pressure. Side effects of flushing, headache,
and edema with dihydropyridine use are related to their potencies
as arteriolar dilators; edema is due to an increase in transcapillary
pressure gradients, not to net salt and water retention.
Beta Blockers β-Adrenergic receptor blockers lower blood pressure by decreasing cardiac output owing to a reduction of heart rate
and contractility. Other proposed mechanisms by which beta blockers lower blood pressure include a central nervous system effect and
inhibition of renin release. Beta blockers are particularly effective
in hypertensive patients with tachycardia, and their hypotensive
potency is enhanced by co-administration with a diuretic. In lower
doses, some beta blockers selectively inhibit cardiac β1
receptors
and have less influence on β2
receptors on bronchial and vascular
smooth muscle cells; however, there seems to be no difference in
the antihypertensive potencies of cardioselective and nonselective
beta blockers. Some beta blockers have intrinsic sympathomimetic
activity, although it is uncertain whether this constitutes an overall
advantage or disadvantage in cardiac therapy. Beta blockers without
intrinsic sympathomimetic activity decrease the rate of sudden
death, overall mortality, and recurrent myocardial infarction. In
patients with CHF, beta blockers reduce the risks of hospitalization
and mortality. Carvedilol and labetalol block both β receptors and
peripheral α-adrenergic receptors. The potential advantages of
combined β- and α-adrenergic blockade in treating hypertension
remain to be determined. Nebivolol represents another class of
cardioselective beta blockers that has additional vasodilator actions
related to enhancement of nitric oxide activity. Whether this confers greater clinical effectiveness remains to be determined.
α-Adrenergic Blockers Postsynaptic, selective α-adrenoreceptor
antagonists lower blood pressure by decreasing peripheral vascular
resistance. They are effective antihypertensive agents used either
as monotherapy or in combination with other agents. However,
in clinical trials of hypertensive patients, alpha blockade has not
been shown to reduce cardiovascular morbidity and mortality or to
provide as much protection against CHF as other classes of antihypertensive agents. These agents are also effective in treating lower
urinary tract symptoms in men with prostatic hypertrophy. Nonselective α-adrenoreceptor antagonists bind to postsynaptic and
presynaptic receptors and are used primarily for the management
of patients with pheochromocytoma.
Sympatholytic Agents Centrally acting α2
sympathetic agonists
decrease peripheral resistance by inhibiting sympathetic outflow.
They may be particularly useful in patients with autonomic neuropathy who have wide variations in blood pressure due to baroreceptor denervation. Drawbacks include somnolence, dry mouth, and
rebound hypertension on withdrawal. Peripheral sympatholytics
decrease peripheral resistance and venous constriction by depleting nerve terminal norepinephrine. Although they are potentially
Hypertension
2085CHAPTER 277
effective antihypertensive agents, their usefulness is limited by
orthostatic hypotension, sexual dysfunction, and numerous drugdrug interactions. Rebound hypertension is another concern with
abrupt cessation of drugs with a short half-life.
Direct Vasodilators Direct vasodilators decrease peripheral
resistance and concomitantly activate mechanisms that defend
arterial pressure, notably the sympathetic nervous system, the reninangiotensin-aldosterone system, and sodium retention. Usually,
they are not considered first-line agents but are most effective when
added to a combination that includes a diuretic and a beta blocker.
Hydralazine is a direct vasodilator that has antioxidant and nitric
oxide–enhancing actions. Minoxidil is a particularly potent vasodilator and is used most frequently in patients with renal insufficiency
who are refractory to all other drugs. Hydralazine may induce a
lupus-like syndrome, and side effects of minoxidil include hypertrichosis and pericardial effusion. Intravenous nitroprusside can
be used to treat malignant hypertension and life-threatening left
ventricular heart failure associated with elevated arterial pressure.
COMPARISONS OF ANTIHYPERTENSIVES
Meta-analyses of pooled clinical trials suggest essentially equivalent
blood pressure–lowering effects of the following six major classes
of antihypertensive agents when used as monotherapy: thiazide
diuretics, beta blockers, ACEIs, ARBs, calcium antagonists, and
α1
blockers. On average, standard doses of most antihypertensive
agents reduce blood pressure by 8–10/4–7 mmHg; however, there
may be subgroup differences in responsiveness. Younger patients
may be more responsive to beta blockers and ACEIs, whereas
patients aged >50 years may be more responsive to diuretics and
calcium antagonists. There is a limited relationship between plasma
renin and blood pressure response. Patients with high-renin hypertension may be more responsive to ACEIs and ARBs than to other
classes of agents, whereas patients with low-renin hypertension are
more responsive to diuretics and calcium antagonists. Hypertensive African Americans tend to have low renin and may require
higher doses of ACEIs and ARBs than whites for optimal blood
pressure control, although this difference is abolished when these
agents are combined with a diuretic. Beta blockers also appear to
be less effective than thiazide diuretics in African Americans than
in non–African Americans. Early pharmacogenetic studies, utilizing a candidate gene approach, genome-wide scans, or integrated
metabolomic and genetic profiles, have shown associations of gene
polymorphisms with blood pressure responsiveness to specific antihypertensive drugs. However, the reported effects have generally
been too small to affect clinical decisions, and associated polymorphisms remain to be confirmed.
A meta-analysis of >30 randomized trials of blood pressure–
lowering therapy indicates that for a given reduction in blood pressure,
with several notable exceptions, the major drug classes produce
similar overall net effects on total cardiovascular events. For example, the Antihypertensive and Lipid-Lowering Treatment to Prevent
Heart Attack Trial (ALLHAT) demonstrated that the occurrence
of fatal CHD and nonfatal myocardial infarction was virtually
identical in hypertensive patients treated with an ACEI (lisinopril),
a diuretic (chlorthalidone), or a calcium antagonist (amlodipine).
However, one arm of ALLHAT involving therapy with a peripherally acting α antagonist (doxazosin) was terminated prematurely
because the incidence of heart failure, stroke, and combined cardiovascular disease events was higher in doxazosin-treated than in
chlorthalidone-treated patients. Increasing evidence suggests that
beta blockers are inferior to other classes of agents for prevention of
cardiovascular events, stroke, renal failure, and all-cause mortality.
Some beta blockers have less effect on central aortic pressure than
other classes of antihypertensive agents. However, beta blockers
remain appropriate therapy for hypertensive patients with concomitant heart disease and related comorbidities. Calcium channel
blockers may be inferior and diuretics superior to other classes of
agents for the prevention of heart failure.
In specific patient groups, ACEIs may have particular advantages,
beyond that of blood pressure control, in reducing cardiovascular
and renal outcomes. ACEIs and ARBs decrease intraglomerular
pressure and proteinuria and may retard the rate of progression of
renal insufficiency, not totally accounted for by their hypotensive
effects, in both diabetic and nondiabetic renal diseases. In patients
with type 2 diabetes, treatment with an ACEI, an ARB, or aliskiren
decreases proteinuria and delays the progression of renal disease.
In experimental models of hypertension and diabetes, renal protection with aliskiren is comparable to that with ACEIs and ARBs.
However, in patients with type 2 diabetes, addition of aliskiren to
an ACEI provides no additional protection against cardiovascular
or renal disease and may be associated with more adverse outcomes.
Among African Americans with hypertension-related renal disease,
ACEIs appear to be more effective than beta blockers or dihydropyridine calcium channel blockers in slowing, although not preventing, the decline of glomerular filtration rate. The renoprotective
effect of these renin-angiotensin blockers, compared with other
antihypertensive drugs, is less obvious at lower blood pressures.
In most patients with hypertension and heart failure due to
systolic and/or diastolic dysfunction, diuretics, ACEIs or ARBs,
and beta blockers improve survival. Independent of blood pressure, in both hypertensive and normotensive individuals, ACEIs
attenuate the development of left ventricular hypertrophy, improve
symptomatology and risk of death from CHF, and reduce morbidity and mortality rates in post–myocardial infarction patients.
Similar benefits in cardiovascular morbidity and mortality rates
in patients with CHF have been observed with the use of ARBs.
ACEIs provide better coronary protection than do calcium channel
blockers, whereas calcium channel blockers provide more stroke
protection than do either ACEIs or beta blockers. Results of a large,
double-blind, prospective clinical trial (Avoiding Cardiovascular
Events through Combination Therapy in Patients Living with Systolic Hypertension [ACCOMPLISH] Trial) indicated that combination treatment with an ACEI (benazepril) plus a calcium antagonist
(amlodipine) was superior to treatment with the ACEI plus a
diuretic (hydrochlorothiazide) in reducing the risk of cardiovascular events and death among high-risk patients with hypertension.
However, the combination of an ACEI and a diuretic has recently
been shown to produce major reductions in morbidity and mortality in the very elderly. After a stroke, combination therapy with
an ACEI and a diuretic, but not with an ARB, has been reported to
reduce the rate of recurrent stroke.
There has been a recent resurgence of interest in two nonpharmacologic antihypertensive therapies that interrupt sympathetic outflow: (1) device-based carotid baroreflex activation by
electrical stimulation of the carotid sinus; and (2) endovascular
radiofrequency ablation of the renal sympathetic nerves. Both
have been suggested as potential options for treatment of resistant
hypertension. Whereas renal denervation is a minimally invasive
procedure, carotid baroreceptor stimulation is a surgical procedure,
usually performed under general anesthesia, that involves implanting electrodes on both the right and left carotid arteries. Clinical
experience with baroreflex activation is limited. Enthusiasm for
renal denervation has been questioned by the results of Simplicity
HTN-3, a randomized, prospective clinical trial comparing bilateral renal denervation with a sham procedure in 535 patients with
resistant hypertension. At the end of 6 months, there was no benefit
of renal artery denervation on both office and ambulatory systolic
blood pressures, the trial’s primary endpoints. Subsequent clinical
trials have demonstrated substantial blood pressure variability in
responses to both of these interventions. It remains to be seen
whether these interventions will be adopted into clinical practice.
BLOOD PRESSURE GOALS OF ANTIHYPERTENSIVE
THERAPY
Based on clinical trial data, the maximum protection against
combined cardiovascular endpoints is achieved with pressures
2086 PART 6 Disorders of the Cardiovascular System
<135–140 mmHg for systolic blood pressure and <80–85 mmHg
for diastolic blood pressure; however, treatment has not reduced
cardiovascular disease risk to the level in nonhypertensive individuals. According to a recent meta-analysis, the magnitude of the proportional reduction of cardiovascular events is broadly consistent
regardless of baseline comorbidity, although the absolute benefit
of blood pressure reduction is greater among individuals with the
highest risk for cardiovascular events.
The degree of benefit derived from antihypertensive agents
is related to the magnitude of the blood pressure reduction. An
intensive blood pressure–lowering strategy is superior to a less
intensive strategy for prevention of stroke and myocardial infarction. For example, the SPRINT trial studied 9361 subjects aged
>50 years at increased risk for cardiovascular events. Intensive blood
pressure control (systolic blood pressure <120 mmHg) reduced the
risk of cardiovascular events and mortality by 25% compared with
less intensive control (systolic blood pressure 135–139 mmHg).
In patients with chronic renal insufficiency, a small, nonprogressive increase in the serum creatinine concentration may occur
with intensive blood pressure lowering. This generally reflects a
hemodynamic response, not structural renal injury, indicating that
intraglomerular pressure has been reduced. Blood pressure control
should not be allowed to deteriorate in order to prevent the modest
creatinine rise.
In diabetic patients, effective blood pressure control reduces
the risk of cardiovascular events and death as well as the risk for
microvascular disease (nephropathy, retinopathy). Various guidelines have been recommended for hypertension control in patients
with type 2 diabetes (e.g., <140/90, <140/85, or <130/80 mmHg).
One widely cited study, the Action to Control Cardiovascular Risk
in Diabetes (ACCORD) clinical trial, failed to find superiority of
intensive blood pressure lowering (<120 mmHg) over standard
blood pressure control (<140 mmHg) in reducing the risk of the
study’s primary outcome (a composite endpoint of myocardial
infarction, stroke, and cardiovascular death) in diabetic patients.
However, that trial did demonstrate a significant reduction of stroke
and left ventricular hypertrophy with more intensive therapy.
Guidelines establishing blood pressure targets for hypertension
control continue to evolve. According to 2017 guidelines developed
by the ACC/AHA, the recommended goal of blood pressure control
for the primary and secondary prevention of cardiovascular disease
is a blood pressure <130/80 mmHg, including patients with diabetes mellitus and chronic kidney diseases (Table 277-8). However,
in hypertensive patients without elevated ASCVD risk, the clinical
trial evidence is strongest for a target blood pressure of 140/90
mmHg. In contrast to other ACC/AHA recommendations that
are based on randomized clinical trials, this guideline is primarily
based on observational studies. Among older patients with isolated
systolic hypertension, further lowering of diastolic blood pressure
does not result in harm. Relatively little information is available
concerning the risk-versus-benefit ratio of intensive antihypertensive therapy in individuals >80 years of age, and in this population,
gradual blood pressure reduction to a less aggressive target level of
control may be appropriate (e.g., 130–150 mmHg). More intensive
control may be associated with a higher incidence of adverse events
(e.g., syncope, electrolyte abnormalities, deterioration of renal function). Additionally, the <130/80 mmHg target blood pressure may
not be acceptable or implementable in low- and middle-income
countries because of the lack of supporting resources. In the final
analysis, all patients need to be carefully monitored, and clinical
decision-making should be individualized.
To achieve recommended blood pressure goals, the majority of
individuals with hypertension will require treatment with more
than one drug. Three or more drugs frequently are needed in
patients with diabetes and renal insufficiency. For most agents,
reduction of blood pressure at half-standard doses is only ~20%
less than at standard doses. Appropriate combinations of agents at
these lower doses may have additive or almost additive effects on
blood pressure with a lower incidence of side effects. Hypertension
control rates are <20% worldwide and <50% in the United States.
These low control rates reflect patient nonadherence and lack of
implementation of recommended guidelines.
The term resistant hypertension refers to patients with blood
pressures persistently >140/90 mmHg despite taking three or more
antihypertensive agents, including a diuretic. Resistant or difficultto-control hypertension is more common in patients aged >60 years
than in younger patients. Resistant hypertension may be related
to nonadherence to therapy, identifiable causes of hypertension
(including obesity, primary aldosteronism, and excessive alcohol
intake), and the use of any of a number of nonprescription and prescription drugs (Table 277-3). Evaluation of patients with resistant
hypertension might include home blood pressure monitoring to
determine if office blood pressures are representative of the usual
blood pressure. A more extensive evaluation for a secondary form
of hypertension should be undertaken if no other explanation for
hypertension resistance becomes apparent. In the absence of a
specific identifiable cause, mineralocorticoid receptor antagonists,
especially spironolactone, have been demonstrated to be the most
effective add-on drugs for the treatment of resistant hypertension. Additionally, resistant hypertension is often associated with
increased sympathetic nervous activity, raising the possibility that
electrical stimulation of the carotid baroreceptor or renal denervation may have a role in the treatment of these patients. However,
that remains to be determined.
HYPERTENSIVE EMERGENCIES
Probably due to the widespread availability of antihypertensive
therapy, in the United States, there has been a decline in the numbers of patients presenting with hypertensive urgencies and emergencies. Severe asymptomatic hypertension (systolic blood pressure
≥180 mmHg or diastolic blood pressure ≥120 mmHg) is considered
a hypertensive “urgency,” but when accompanied by acute target
damage, it is considered a hypertensive “emergency.” Most patients
who present with severe hypertension are chronically hypertensive,
and there are inherent risks to overly aggressive initial antihypertensive therapy. In hypertensive individuals, the upper and lower
limits of autoregulation of cerebral blood flow are shifted to higher
levels of arterial pressure, and rapid lowering of blood pressure to
below the lower limit of autoregulation may precipitate cerebral
ischemia or infarction as a consequence of decreased cerebral blood
flow. Renal and coronary blood flows also may decrease with overly
aggressive acute therapy. Consequently, the rapidity with which
blood pressure should be lowered is dependent on the presence of
new or worsening target organ damage and the presence or absence
of cardiovascular disease complications. In patients with a hypertensive urgency, except for those with acute aortic dissections or
hemorrhagic strokes, blood pressure is generally gradually lowered
over 24 h to ~25% of the initial value. Tables 277-10 and 277-11 list
a number of hypertension-related emergencies and recommended
therapies.
The syndrome of malignant hypertension is an example of a
hypertensive emergency that is associated with an abrupt increase
of blood pressure in a patient with underlying hypertension or
related to the sudden onset of hypertension in a previously normotensive individual. The absolute level of blood pressure is not as
important as its rate of rise. Pathologically, the syndrome is associated with diffuse necrotizing vasculitis, arteriolar thrombi, and
fibrin deposition in arteriolar walls. Fibrinoid necrosis has been
observed in arterioles of kidney, brain, retina, and other organs.
Clinically, the syndrome is recognized by progressive retinopathy (arteriolar spasm, hemorrhages, exudates, and papilledema),
deteriorating renal function with proteinuria, microangiopathic
hemolytic anemia, and encephalopathy. Historic inquiry should
include questions about the use of monoamine oxidase inhibitors
and recreational drugs (e.g., cocaine, amphetamines). In patients
with encephalopathy, the initial goal of therapy is to reduce mean
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