Heart failure

Health Topics A-Z

Health Topics A-Z

Heart failure

Highlights

General Overview

Heart failure is a condition in which the heart does not pump enough blood to meet the needs of the bodys tissues. Heart failure can develop slowly over time as the result of other conditions (such as high blood pressure and coronary artery disease) that weaken the heart. It can also occur suddenly as the result of damage to the heart muscle.

Symptoms

Common signs and symptoms of heart failure include:

Fatigue
Shortness of breath
Wheezing or cough
Fluid retention and weight gain
Loss of appetite
Abnormally fast or slow heart rate

Treatment

Treatment for heart failure depends on its severity. Patients with very weakened hearts may need surgery or implanted devices, such as pacemakers or implantable cardioverter defibrillators. All patients need to make lifestyle changes, including restricting salt in their diets.

Doctors usually treat heart failure, and the underlying conditions that cause it, with a combination of medications. These medications include:

Angiotensin-converting enzyme (ACE) inhibitors or angiotensin-receptor blockers (ARBs)
Beta blockers
Diuretics
Aldosterone blockers
Digitalis
Hydralazine and nitrates

Other medications that may be helpful include:

Statins
Aspirin and warfarin

Introduction

To understand what occurs in heart failure, it helps to be familiar with the anatomy of the heart and how it works. The heart is composed of two independent pumping systems, one on the right side, and the other on the left. Each has two chambers, an atrium and a ventricle. The ventricles are the major pumps in the heart.

The external structures of the heart include the ventricles, atria, arteries, and veins. Arteries carry blood away from the heart while veins carry blood into the heart. The vessels colored blue indicate the transport of blood with relatively low content of oxygen and high content of carbon dioxide. The vessels colored red indicate the transport of blood with relatively high content of oxygen and low content of carbon dioxide.

The Right Side of the Heart. The right system receives blood from the veins of the whole body. This is "used" blood, which is poor in oxygen and rich in carbon dioxide.

The right atrium is the first chamber that receives blood.
The chamber expands as its muscles relax to fill with blood that has returned from the body.
The blood enters a second muscular chamber called the right ventricle.
The right ventricle is one of the heart's two major pumps. Its function is to pump the blood into the lungs.
The lungs restore oxygen to the blood and exchange it with carbon dioxide, which is exhaled.

The Left Side of the Heart. The left system receives blood from the lungs. This blood is now rihc in oxygen.

The oxygen-rich blood returns through veins coming from the lungs (pulmonary veins) to the heart.
It is received from the lungs in the left atrium, the first chamber on the left side.
Here, it moves to the left ventricle, a powerful muscular chamber that pumps the blood back out to the body.
The left ventricle is the strongest of the heart's pumps. Its thicker muscles need to perform contractions powerful enough to force the blood to all parts of the body.
This strong contraction produces systolic blood pressure (the first and higher number in blood pressure measurement). The lower number (diastolic blood pressure) is measured when the left ventricle relaxes to refill with blood between beats.
Blood leaves the heart through the aorta, the major artery that feeds blood to the entire body.

The Valves. Valves are muscular flaps that open and close so blood will flow in the right direction. There are four valves in the heart:

The tricuspid regulates blood flow between the right atrium and the right ventricle.
The pulmonary valve opens to allow blood to flow from the right ventricle to the lungs.
The mitral valve regulates blood flow between the left atrium and the left ventricle.
The aortic valve allows blood to flow from the left ventricle to the ascending aorta.

Click the icon to see an image of the internal structures of the heart.

The Heart's Electrical System. The heartbeats are triggered and regulated by the conducting system, a network of specialized muscle cells that form an independent electrical system in the heart muscles. These cells are connected by channels that pass chemically caused electrical impulses.

Click the icon to see an image of the conduction system of the heart.

Description of Heart Failure

Heart failure is not a disease. It is a condition or process in which the heart is unable to pump enough blood to meet the needs of the body's tissues. The heart doesn't "fail" in the sense of ceasing to beat (as occurs during a heart attack). Rather, it weakens, usually over the course of months or years, so that it is unable to pump out all the blood that enters its chambers. As a result, fluids tend to build up in the lungs and tissues, causing congestion. This condition used to be called "congestive heart failure," but the name was officially changed to heart failure in 2005.

Ways the Heart Can Fail. Heart failure can occur in several ways:

The muscles of the heart pumps (ventricles) become thin and weakened. They stretch (dilate) and cannot pump the blood with enough force to reach all the body's tissues.
The heart muscles stiffen or thicken. Here, they lose elasticity and cannot relax. Insufficient blood enters the chamber, so not enough blood is pumped out into the body to serve its needs.
Sometimes the valves of the heart are abnormal. (Valves open or close to control the flow of blood entering or leaving the heart). They may narrow, such as in aortic stenosis, causing a back up of blood, or they may close improperly so that blood leaks back into the heart. The mitral valve (which regulates blood flow between the two chambers on the left side of the heart) often becomes leaky in severe heart failure -- a condition called mitral regurgitation.

Click the icon to see an image of the valves of the heart.

The very mechanisms that the body uses to compensate for inefficient heart pumping can, over time, change the architecture of the heart (called remodeling) and finally lead to irreversible problems.

The specific effects of heart failure on the body depend on whether it occurs on the left or right sides of the heart. Over time, however, in either form of heart failure, the organs in the body do not receive enough oxygen and nutrients, and the body's wastes are removed slowly. Eventually, vital systems break down.

Failure on the Left Side (Left-Ventricular Heart Failure). Failure on the left side of the heart is more common than failure on the right side. The failure can be a result of abnormal systolic (contraction) or diastolic (relaxation) action:

Systolic. Systolic heart failure is a pumping problem. In systolic failure, the heart muscles weaken and cannot pump enough blood throughout the body. The left ventricle is usually stretched (dilated). Fluid backs up and accumulates in the lungs (pulmonary edema). Systolic heart failure typically occurs in men between the ages of 50 - 70 years who have had a heart attack.
Diastolic. Diastolic heart failure is a filling problem. When the left ventricle muscle becomes stiff and cannot relax properly between heartbeats, the heart cannot fill fully with blood. When this happens, fluid entering the heart backs up. This causes the veins in the body and tissues surrounding the heart to swell and become congested. Patients with diastolic failure are typically women, overweight, and elderly, and have high blood pressure and diabetes.

Failure on the Right Side (Right-Ventricular Heart Failure). Failure on the right side of the heart is most often a result of failure on the left. Because the right ventricle receives blood from the veins, failure here causes the blood to back up. As a result, the veins in the body and tissues surrounding the heart to swell. This causes swelling in the feet, ankles, legs, and abdomen. Pulmonary hypertension (increase in pressure in the lung's pulmonary artery) and lung disease may also cause right-sided heart failure.

Ejection Fraction. To help determine the severity of left-sided heart failure, doctors use an ejection fraction (EF) calculation, also called a left-ventricular ejection fraction (LVEF). This is the percentage of the blood pumped out from the left ventricle during each heartbeat. An ejection fraction of 50 - 75% is considered normal. Patients with left-ventricular heart failure are classified as either having a preserved ejection fraction (greater than 50%) or a reduced ejection fraction (less than 50%).

Patients with preserved LVEF heart failure are more likely to be female and older, and have a history of high blood pressure and atrial fibrillation (a disturbance in heart rhythm). Experts are now urging that more studies focus on patients with preserved LVEF so that better treatment options can be established.

Causes

Heart failure has many causes and can evolve in different ways.

It can be a direct, last-stage result of heart damage from one or more of several heart or circulation diseases.
It can occur over time as the heart tries to compensate for abnormalities caused by these conditions, a condition called remodeling.

In all cases, the weaker pumping action of the heart means that less blood is sent to the kidneys. The kidneys respond by retaining water and salt. This in turn increases edema (fluid buildup) in the body, which causes widespread damage.

High Blood Pressure

Uncontrolled high blood pressure (hypertension) is a major cause of heart failure even in the absence of a heart attack. In fact, about 75% of cases of heart failure start with hypertension. It generally develops as follows:

The heart muscles thicken to make up for increased blood pressure.
The force of the heart muscle contractions weaken over time, and the muscles have difficulty relaxing. This prevents the normal filling of the heart with blood.

[For more information, see In-Depth Report #14:High blood pressure.]

Hypertension is a disorder characterized by consistently high blood pressure. Generally, high blood pressure consists of systolic blood pressure (the "top" number, which represents the pressure generated when the heart beats) higher than 140, or diastolic blood pressure (the "bottom" number, which represents the pressure in the vessels when the heart is at rest) over 90.

Coronary Artery Disease

Coronary artery disease is the end result of a complex process called atherosclerosis (commonly called "hardening of the arteries"). It is the most common cause of heart attack and involves the build-up of unhealthy cholesterol in the arteries, with inflammation and injury in the cells of the blood vessels. The arteries narrow and become brittle. Heart failure in such cases most often results from a pumping defect in the left side of the heart. [For more information, see In-Depth Report #3: Coronary artery disease and angina; and In-Depth Report #23: Cholesterol.]

Click the icon to see an image of atherosclerosis.

People now often survive heart attacks, but eventually many develop heart failure from the physical damage the attack does to the heart muscles. Ironically, heart attack recovery is probably one of the major factors in the dramatic increase in heart failure cases over the past decade. On an encouraging note, however, new therapies that are reducing the severity of heart attacks may help stabilize heart failure rates. [For more information, see In-Depth Report #12: Heart attack. ]

Valvular Heart Disease

The valves of the heart control the flow of blood leaving and entering the heart. Abnormalities can cause blood to back up or leak back into the heart.

Click the icon to see an image of the heart valves.

In the past, rheumatic fever, which scars the heart valves and prevents them from closing, was a major cause of death from heart failure. Fortunately, antibiotics have relegated this disease to a minor cause of heart failure. Birth defects may also cause abnormal valvular development. Although more children born with heart defects are now living to adulthood, they still face a higher than average risk for heart failure as they age.

Cardiomyopathy

Cardiomyopathy is disease that damages the heart muscles and leads to heart failure. There are several different types. Injury to the heart muscles may cause the heart muscles to thin out (dilate) or become too thick (become hypertrophic). In either case, the heart doesn't pump correctly. Viral myocarditis is a rare viral infection that involves the heart muscle and can produce either temporary or permanent heart muscle damage.

Dilated Cardiomyopathy. Dilated cardiomyopathy involves an enlarged heart ventricle. The muscles thin out, reducing the pumping action, usually on the left side. Although this condition is associated with genetic factors, the direct cause often is not known. (This is called idiopathic dilated cardiomyopathy.) Research strongly indicates that viruses, such as Coxsackie virus, or other infections may be at the base of this condition. Experts think that an autoimmune response occurs in which infection-fighting antibodies attack a person's own proteins in the heart, mistaking them for foreign substances.

Chronic alcohol abuse can damage the heart muscles, can cause hypertension, and may be one cause of idiopathic dilated cardiomyopathy. Moderate alcohol consumption, on the other hand (generally defined as 2 drinks a day for men and 1 drink for women), may protect against heart failure. Non-drinkers, though, are not advised to begin drinking.

Click the icon to see an image of dilated cardiomyopathy.

Hypertrophic Cardiomyopathy. In hypertrophic cardiomyopathy, the heart muscles become thick and contract with difficulty. Some research indicates that this occurs because of a genetic defect that causes a loss of power in heart muscle cells and, subsequently, lower pumping strength. To compensate for this power loss, the heart muscle cells grow. This condition, rare in the general population, is often the cause of sudden death in young athletes.

Click the icon to see an image of hypertrophic cardiomyopathy.

Lung Disease

Chronic obstructive pulmonary disease (severe emphysema) and other major lung diseases are risk factors for right-side heart failure.

Pulmonary Hypertension

The development of right-sided heart failure in patients with pulmonary hypertension is a strong predictor of death within 6 - 12 months.

Medications Associated with Heart Failure

Long-term use of anabolic steroids (male hormones used to build muscle mass) increases the risk for heart failure. The drug itraconazole (Sporanox), used to treat skin, nail, or other fungal infections, has been linked to heart failure. In 2006, the Food and Drug Administration (FDA) warned that the cancer drug imatinib (Gleevec) has been associated with heart failure cases. Most patients who took imatinib and developed heart failure had a history of diabetes, high blood pressure, or heart disease. Other chemotherapy drugs, such as doxorubicin, can increase the risk for later developing heart failure years after cancer treatment. (Cancer radiation therapy to the chest can also damage the heart muscle.)

Corrective Mechanisms, Remodeling, and the Failing Heart

High blood pressure, heart attacks, or other initial processes that impair the pumping actions of the heart trigger a number of hormonal and neurochemical mechanisms to correct imbalances in pressure and blood flow. Unfortunately, while these corrective responses help in the short term, they increase the work of the heart. The mechanisms are now viewed as major contributors to the end stages of heart failure. Some are described briefly in the following sections.

Remodeling. The heart responds to high blood pressure and overload by enlarging in order to increase blood input. This leads to structural damage called remodeling:

The thinner heart muscles and the impaired heart contractions further weaken the heart's pump.
Mitral valve regurgitation is a possible outcome of remodeling.
These changes are generally irreversible, although heart pacemakers and certain drugs, including beta-blockers and ACE inhibitors, may reverse some of the remodeling in some patients.

Activation of the Sympathetic Nervous System. The sympathetic nervous system consists of the nerve cells that automatically govern and regulate the beating heart.

This nervous system responds to the failing heart pump by signaling the release of stress hormones, in particular a powerful one called norepinephrine.
These hormones flood the heart, causing it to beat even faster, which further accelerates the damage.

The Renin-Angiotensin-Aldosterone System (RAAS). The renin-angiotensin-aldosterone system (RAAS) is a group of hormones that are responsible for the opening and narrowing of blood vessels and retention of fluids. They also affect cell development in the heart.

These hormones respond to the lower blood volume of the weakened heart by constricting the blood vessels and retaining fluids and sodium.
The heart then works harder to pump blood through these narrowed vessels. Blood pressure, then, is forced to increase, which creates a vicious cycle.

Immune System Response. The immune system may also compound the damage. In response to injury in the heart muscle cells or in other parts of the body that occurs as the heart fails, the immune system releases immune factors intended to protect these areas. In excess, however, these proteins can cause inflammation and damage.

Other Players. Other molecules or compounds have been identified that might play a positive or negative role in the process of the failing heart.

Natriuretic peptides are a family of compounds released to counterbalance the effects of RAAS. Atrial natriuretic peptide (ANP) is a specific member of this family that opens blood vessels and counteracts the sodium-retaining properties of aldosterone (one of the RAAS hormones). It is of particular interest to researchers looking for new treatments.
Endothelin is a powerful protein involved in blood vessel constriction, cell proliferation and build-up, and other negative effects on the heart.
Nitric oxide is important for blood vessel dilation and elasticity.

Symptoms

Many symptoms of heart failure result from the congestion that develops as fluid backs up into the lungs and leaks into the tissues. Other symptoms result from inadequate delivery of oxygen-rich blood to the body's tissues. Since heart failure can progress rapidly, it is essential to consult a doctor immediately if any of the following symptoms are detected:

Fatigue.

Shortness of Breath (Dyspnea).

Patients typically report that they feel out of breath after exertion. While this may begin only when climbing stairs or taking longer walks, it can eventually be present even when walking around the home. (Those who experience chest pain or feel like a heavy weight is pressing on the chest should also be evaluated for possible angina.)
Orthopnea refers to the shortness of breath patients may experience when they lie flat at night. Patients may report that they need to use one or two pillows underneath their head and shoulders in order to be able to sleep. Sitting up with legs hanging over the side of the bed often relieves symptoms.
Paroxysmal nocturnal dyspnea (PND) refers to sudden episodes that awaken a patient at night. Symptoms include severe shortness of breath and coughing or wheezing, which generally occur 1 - 3 hours after going to sleep. Unlike orthopnea, symptoms are not relieved by sitting up.

Fluid Retention and Weight Gain. Patients may complain of leg or abdominal swelling. The swelling in the ankles and legs is referred to as edema. Fluid retention can cause sudden weight gain.

Wheezing or Cough. Patients may have asthma-like wheezing, or a dry hacking cough that occurs a few hours after lying down but then stops after sitting up.

Loss of Muscle Mass. Over time, patients may lose muscle weight due to low cardiac output and a significant reduction in physical activity.

Gastrointestinal Symptoms. Patients experience loss of appetite or a sense of feeling full after eating small amounts. They may also have abdominal pain.

Pulmonary Edema. When fluid in the lungs builds up, it is called pulmonary edema. When this happens, symptoms become more severe. These episodes may happen suddenly, or gradually build up over a matter of days:

In addition to shortness of breath, patients sometimes have a cough that produces a pinkish froth.
Patients may experience a bubbling sensation in the lungs and feel as if they are drowning.
Typically, the skin is clammy and pale, sometimes nearly blue. This is a life-threatening situation, and the patient must go immediately to an emergency room.

Depression. Many patients with more advanced heart failure experience symptoms of depression, which can affect their quality of life as well as their ability to continue to monitor their condition and care for themselves.

Abnormal Heart Rhythms. Patients may experience episodes of abnormally fast or slow heart rate.

Central Sleep Apnea. This disorder results when the brain fails to signal the muscles to breathe during sleep. It occurs in up to half of people with heart failure. Sleep apnea causes disordered breathing at night. If heart failure progresses, the apnea may be so acute that a person, unable to breathe, may awaken from sleep in panic.

Risk Factors

Nearly 5 million Americans suffer from heart failure. About 550,000 new cases of heart failure are diagnosed each year. In 1970, there were only 250,000 new cases, so the annual numbers have risen dramatically. Such numbers represent an increasingly older population. Although there has been a dramatic increase over the last several decades in the number of people who suffer from heart failure, survival rates have greatly improved.

Coronary artery disease and high blood pressure are the main causes of heart failure. Other diseases that damage or weaken the heart muscle or heart valves can also cause heart failure. Heart failure is most common in people over age 65, African-Americans, and women.

Advancing Age

Heart failure is the most common reason for hospitalization in the elderly, and as the population ages, the incidence of heart failure is rising dramatically. According to one report, it occurs at a rate of about 10 in 1,000 people after age 65. The positive implication is, however, that people are living longer with heart failure.

Gender

Men are at higher risk for heart failure than women, although the difference narrows with age. Women also have a better survival rate than men do when heart failure is caused by valvular heart disease, high blood pressure, or alcohol abuse. (Some studies indicate that this is because men may be more susceptible to the process of heart muscle-cell remodeling, a damaging effect of hypertension.)

The survival rates of women and men are more similar, however, when heart failure evolves from coronary artery disease or heart attack. Women are much more likely to develop heart failure after a heart attack than men. In such cases, some evidence suggests that the reasons for this may include less aggressive approaches to treatment for the initial heart conditions.

Ethnicity

African-Americans may be at higher risk for heart failure than Caucasians, and studies have reported that they tend to do much worse. Some evidence suggests that African-Americans are more often likely than Caucasians to develop diastolic heart failure (a failure of the heart muscle to relax normally), which is often a precursor to systolic heart failure (impaired ability to pump blood). Caucasians tend to develop systolic heart failure first.

Family History and Genetics

According to a 2006 New England Journal of Medicine study, people whose parents had heart failure have a greatly increased risk of developing heart failure, particularly left-ventricular systolic heart failure. Earlier studies have suggested that a family history of early heart failure caused by cardiomyopathies (diseases that damage the heart muscle) may also predispose people to the disease. Researchers are looking for changes in specific genes that might regulate systems involved in heart failure and so increase susceptibility in certain populations.

Diabetes

People with diabetes are at high risk for heart failure, particularly if they also have coronary artery disease. Even blood sugar abnormalities that precede diabetes increase the risk.

Obesity

Obesity is associated with both hypertension and type 2 diabetes, conditions that place people at risk for heart failure. Evidence strongly suggests that obesity itself is a major risk factor for heart failure, particularly in women.

Thyroid Problems

An overactive thyroid (hyperthyroidism) or underactive thyroid (hypothyroidism) can have severe effects on the heart and increase the risk for heart failure.

Complications

At least 20% of hospitalizations in older adults are due to heart failure. For people over age 65, it is the number one cause of death, with nearly 290,000 people dying from this disease each year. Nevertheless, although heart failure produces very high mortality rates, treatment advances in hypertension, heart surgeries, and heart pacemakers are improving survival rates.

Cardiac Cachexia. If patients with heart failure are overweight to begin with, their condition tends to be more severe. Once heart failure develops, however, an important indicator of a worsening condition is the occurrence of cardiac cachexia, which is unintentional rapid weight loss (a loss of at least 7.5% of normal weight within 6 months).

Impaired Kidney Function. Heart failure weakens the hearts ability to pump blood. This can affect other parts of the body including the kidneys (which in turn can lead to fluid build-up). Decreased kidney function is common in patients with heart failure, both as a complication of heart failure and as a complication of other diseases associated with heart failure (such as diabetes). Studies suggest that in patients with heart failure, impaired kidney function increases the risks for heart complications including hospitalization and death.

Congestion (Fluid Buildup). In left-sided heart failure, fluid builds up first in the lungs. Later, as right-sided heart failure develops, fluid builds up in the legs, feet, and abdomen. Fluid buildup is treated with lifestyle measures, such as reducing salt in the diet, as well as drugs, such as diuretics.

Arrythmias (Irregular Beatings of the Heart)

Atrial fibrillation is a rapid quivering beat in the upper chambers of the heart. It is a major cause of stroke and very dangerous in people with heart failure.
Left bundle-branch block is an abnormality in electrical conduction in the heart. It develops in about 30% of patients with heart failure. It worsens heart failure because the heart does not pump as efficiently as it could.
Ventricular tachycardia and ventricular fibrillation are serious arrythmias that can occur in patients when heart function is significantly impaired.

Sleep Apnea. Patients with heart failure can have two kinds of sleep apnea:

Obstructive sleep apnea is a disorder where a person stops breathing for brief spells during the night due to blockage in the upper airways when trying to breathe. Up to a third of heart failure patients may have it, especially those who are obese. This type of sleep apnea can make heart failure worse, and patients with apnea have a higher mortality rate than those who do not. Treatment of obstructive sleep apnea may help improve heart function.
Central sleep apnea results from a defect in the brains control of respiration. There is no attempt at breathing during a central apnea episode. This problem may happen in patients with more severe heart failure and can occur at the same time as obstructive sleep apnea.

Depression. The presence of depression indicates a poorer outlook for the heart. Studies indicate that depression may have adverse biologic effects on the immune and nervous systems, blood clotting, blood pressure, blood vessels, and heart rhythms.

Angina and Heart Attacks. While coronary artery disease is a major cause of heart failure, patients with heart failure are at continued risk for angina and heart attacks. Special care should be taken with sudden and strenuous exertion, particularly snow-shoveling, during colder months.

Diagnosis

Doctors can often make a preliminary diagnosis of heart failure by medical history and careful physical examination.

A thorough medical history may identify risks for heart failure that include:

High blood pressure
Diabetes
Poor cholesterol levels
Heart or peripheral vascular disease
Sleep apnea
Thyroid problems
Obesity
Lifestyle factors (smoking, alcohol use)

The following physical signs, along with medical history, strongly suggest heart failure:

Enlarged heart
Abnormal heart sounds
Abnormal sounds in the lungs
Swelling or tenderness of the liver
Fluid retention in legs and abdomen
Elevation of pressure in the veins of the neck

Laboratory Tests

Both blood and urine tests are used to check for problems with the liver and kidneys and to detect signs of diabetes. Lab tests can measure:

Complete blood counts to check for anemia
Kidney function blood and urine tests
Measurements of sodium, potassium, and other electrolytes
Cholesterol and lipid levels
Blood sugar (glucose)
Red blood cell count (to rule out anemia)
Blood sugar levels
Thyroid function

Electrocardiogram

An electrocardiogram (ECG) cannot diagnose heart failure, but it can indicate underlying heart problems. It is sometimes called an EKG. The test is simple and painless to perform. It may be used to diagnose:

Enlargement of the heart muscle, which may help to determine long-term outlook
The presence of coronary artery disease
Abnormal cardiac rhythms
A finding called a prolonged QT interval may predict people with heart failure who are at risk for severe complications and would need more aggressive therapies.

If a patient has a completely normal ECG they are unlikely to have heart failure.

The electrocardiogram (ECG, EKG) is used extensively to diagnose heart disease, from congenital heart disease in infants to myocardial infarction and myocarditis in adults. There are several different types of electrocardiograms.

Exercise Stress Test

The exercise stress test measures heart rate, blood pressure, electrocardiographic changes, and oxygen consumption while a patient is performing physically, usually walking on a treadmill. It is an important diagnostic component in determining heart failure symptoms. Doctors also use exercise tests to gauge long-term outlook and the effects of particular treatments.

Echocardiography

The best diagnostic test for heart failure is echocardiography. Echocardiography is a noninvasive, entirely safe test that uses ultrasound to image the heart as it is beating. Cardiac ultrasounds provide the following information:

Accurate indications of valve function
Important measurements about how well the heart is pumping, especially a measurement called left ventricle ejection fraction (LVEF)
The location of the failure and where it has occurred
Changes in the structure of the heart that may be a result of heart failure

Doctors use information from the echocardiogram for calculating the ejection fraction (how much blood is pumped out during each heartbeat), which is important for determining the severity of heart failure. Stress echocardiography may be needed if coronary artery disease is suspected.

Imaging Tests

Radionuclide Ventriculography. Radionuclide ventriculography is an imaging technique that uses a tiny amount of radioactive material (called a trace element). The substance is injected into the patient, and as it passes through the bloodstream it is picked up on x-rays. It is very sensitive in revealing heart enlargement or evidence of fluid accumulation around the heart and lungs. It is typically done at the same time as coronary artery angiography. It can help diagnose or exclude the presence of coronary artery disease and helps demonstrate how the heart works during exercise.

Magnetic Resonance Imaging. Magnetic resonance imaging (MRI) scans that use contrast dyes to improve resolution are proving helpful for identifying whether there is any heart muscle that can be helped by opening up the arteries feeding it. Damage appears as very bright areas on the scan.

Angiography

Doctors may recommend angiography if they suspect that blockage of the arteries is contributing to heart failure. This procedure is invasive.

A thin tube called a catheter is inserted into one of the large arteries in the arm or leg.
It is gently guided through the artery until it reaches the heart.
The catheter measures internal blood pressure at various locations, giving the doctor a comprehensive picture of the extent and nature of the heart failure.
Dye is then injected through the tube into the heart.
X-rays called angiograms are taken as the dye moves through the heart and arteries.
These images help locate problems in the heart's pumping action or blockage in the arteries.

Major complications of angiography are rare (about 0.1%) but can occur. They include stroke, heart attacks, and kidney damage. The more experienced the medical center in this procedure, the lower the risk.

Click the icon to see an image of cardiac catheterization.

Tests for Markers

Researchers are looking for biologic factors (called biomarkers) that will confirm a diagnosis or suggest a better or worse prognosis. Many are under investigation.

Tumor Necrosis Factor. Elevated levels of tumor necrosis factor (TNF) may be a very strong and accurate predictor of a poor outlook. This immune substance is known to be a potent substance in the inflammatory process.

Natriuretic Peptides. Natriuretic peptides are substances that help regulate salt and water balance in the body. Levels of these peptides increase as heart failure symptoms worsen. Blood tests for brain natriuretic peptide (BNP) are now used to help diagnose heart failure. BNP testing can be very helpful in correctly diagnosing heart failure in patients who come to the emergency room complaining of shortness of breath (dyspnea).

Brain Metabolites. High levels of a compound called N-acetylaspartate, generated as a byproduct of chemical processes in the brain, may indicate a poor outlook.

Treatment

Guidelines for evaluating the severity of heart failure and determining treatments follow a staging system similar to the one used for major cancers.

Management of Risk Factors and Causes

According to expert guidelines, the first step in managing or preventing heart failure is treating the primary conditions causing or complicating heart failure. This is particularly true for patients who are thought to be at high risk for heart failure, but who have no evidence of structural damage to the heart (Stage A). Risk factors include high blood pressure, heart diseases, diabetes, obesity, metabolic syndrome, and previous use of medications that damage the heart (such as some chemotherapy).

Important risk factors to manage include:

Coronary artery disease. Treatment includes a healthy diet, exercise, smoking cessation, medications, and, possibly, bypass or angioplasty. [For more information, see In-Depth Report #3: Coronary artery disease and angina.]
Cholesterol and lipid problems. Treatments include lifestyle management and medications, especially statins. [For more information, see In-Depth Report #23: Cholesterol.]
High blood pressure. A normal systolic blood pressure is considered below 120 mm Hg, and a normal diastolic blood pressure is below 80 mm Hg. Patients with diabetes, atherosclerosis, or chronic kidney disease should maintain blood pressure readings of 130/80 or less, while other patients with high blood pressure should aim for readings no higher than 140/90. Effective reduction of blood pressure reduces the risk of heart failure by 30 - 50%. [For more information, see In-Depth Report #14: High blood pressure.]
Diabetes. Treating diabetes is extremely important for reducing the risk for heart disease. ACE inhibitors are especially beneficial, particularly for people with diabetes. Recent research suggests that metformin, a drug used to treat diabetes, may also help prevent heart failure. [For more information, see In-Depth Report #60: Diabetes - type 2; and In-Depth Report #9: Diabetes - type 1.]
Obesity. [For more information, see In-Depth Report #53: Weight control and diet.]
Valvular abnormalities, such as aortic stenosis and mitral regurgitation. Surgery may be required.
Abnormal health rhythms (arrhythmias). Ventricular assisted devices, notably biventricular pacers (BVPs), are proving to be important in preventing hospitalizations for patients with these conditions.
Anemia. Giving erythropoietin (EPO) to patients with heart failure and underlying anemia not only reverses the anemia, but may markedly improve heart symptoms as well. [For more information, see In-Depth Report #57: Anemia.] New guidelines call for limiting dosage to the amount needed to maintain hemoglobin levels between 10 and 12 g/dL.
Thyroid function. Various medications are used to treat overactive thyroid (hyperthyroidism) or underactive thyroid (hypothyroidism). [For more information, see In-Depth Report #38: Hypothyroidism.]
Sleep apnea. Continuous positive airway pressure (CPAP) is an effective treatment for sleep apnea. CPAP may help reduce systolic blood pressure and improve left ventricular systolic function. [For more information, see In-Depth Report#65:Sleep apnea.]
Drugs. Avoid drugs that can worsen heart failure symptoms. These include nonsteroidal anti-inflammatory drugs (NSAIDs), calcium channel blockers (verapamil and diltiazem), thiazolidinediones (a drug used for diabetes), antitumor necrosis factors, and some drugs used to treat irregular heart rhythms (arrhythmia).

Click the icon to see an image of CPAP treatment.

Treatment Based on Heart Failure

Stage B. Patients have a structural heart abnormality but no symptoms of heart failure. Abnormalities include left ventricular hypertrophy and low ejection fraction, asymptomatic valvular heart disease, and a previous heart attack. The following types of drugs and devices may be recommended for some patients:

Angiotensin-converting enzyme (ACE) inhibitors, or angiotensin-receptor blockers (ARBs) for patients who cannot tolerate ACE inhibitors .
Beta blockers for patients with a recent or past history of heart attack. Also for patients who have not had a heart attack but who do have reduced LVEF identified in diagnostic tests.

Stage C. Patients have a structural abnormality and current or previous symptoms of heart failure, including shortness of breath, fatigue, and difficulty exercising. Treatment includes:

Restrict dietary salt. Lowering salt in the diet can help diuretics work better.
ACE inhibitors or angiotensin-receptor blockers (ARBs).
Beta blockers (bisoprolol, carvedilol, and sustained release metoprolol).
Diuretics are recommended for most patients, with loop diuretics such as furosemide generally being the first-line choice.
Aldosterone inhibitors or digitalis may be used for some patients.
A hydralazine and nitrate combination (BiDil) may be used for African-American patients who are taking an ACE inhibitor and beta blocker and who still have heart failure symptoms.
Exercise training for appropriate patients.
Biventricular pacemakers may be indicated for patients with worsening heart failure and certain findings on their electrocardiogram (ECG).
Implantable defibrillators may be considered for patients with very low ejection fraction or those who have had dangerous arrhythmias.

Stage D. Patients have end-stage symptoms that do not respond to standard treatments. Treatment includes appropriate measures used for Stages A, B, and C plus:

Heart transplantation referral for appropriate patients.
Left-ventricular assist devices (LVADs) as permanent therapy for patients who are not candidates for heart transplants. LVADs are surgically implanted to help pump blood through the body.
Hospice and end-of-life care information for patients and families.

Management of Precipitating Factors

Whenever heart failure worsens, whether quickly or chronically over time, various factors must be considered as the cause:

Dietary indiscretion. Sometimes as little as eating a sausage or some sauerkraut with extremely high sodium content is enough to precipitate an acute episode. Otherwise, compliance with any fluid and salt restrictions must be considered.
Alcohol. Depending on the severity of a patient's heart failure, one or more drinks may suddenly worsen symptoms.
Medication compliance. Patients may forget or purposely skip a medication, or may not be able to afford or have access to medications.
Angina or heart attack. Worsening of coronary artery disease may make the heart muscle less able to pump enough blood.
Arrhythmias. Increases in the heart rate, or a slowing of the heart rate below normal, may also affect the ability of the heart to function. Likewise, an irregular heart rhythm such as atrial fibrillation may cause a flareup.
Anemia. It is unclear whether anemia causes heart failure or is a symptom of heart failure. Most anemias may be treated with iron replacement therapy. A more significant anemia can cause a worsening of heart failure and should be treated promptly.

Medications

Many different medications are used in the treatment of heart failure. They include:

Angiotensin-converting enzyme (ACE) inhibitors
Angiotensin-receptor blockers (ARBs)
Beta blockers
Diuretics
Aldosterone blockers
Digitalis
Hydralazine and nitrates
Statins
Aspirin and warfarin

ACE Inhibitors

Angiotensin-converting enzyme (ACE) inhibitors are among the most important drugs for treating patients with heart failure. ACE inhibitors open blood vessels and decrease the workload of the heart. They are used to treat high blood pressure but can also help improve heart and lung muscle function. Major studies suggest that ACE inhibitors may reduce the risk of death, heart attack, and hospital admissions by 28% in patients with existing heart failure.

ACE inhibitors are particularly important for patients with diabetes. A large study reported that patients with diabetes who took these drugs had fewer heart attacks and lower overall mortality rates than patients who took other types of high blood pressure medications. ACE inhibitors may also help slow progression of kidney disease, in addition to controlling blood pressure.

Brands and Indications. ACE inhibitors treat Stage A high-risk conditions such as high blood pressure, heart disease, and diabetic nerve disorders (neuropathy). They also treat Stage B patients who have had a heart attack or who have left ventricular systolic disorder, and Stage C patients with heart failure. Specific brands of ACE inhibitors include:

Benazepril (Lotrel)
Captopril (Capoten)
Enalapril (Vasotec)
Fosinopril (Monopril)
Lisinopril (Prinivil, Zestril)
Moexipril (Univasc)
Perindopril (Aceon)
Quinapril (Accupril)
Ramipril (Altace)
Trandolapril (Mavik)

Side Effects of ACE Inhibitors:

Low blood pressure is the main side effect of ACE inhibitors. This can be severe in some patients, especially at the start of therapy.
Irritating cough is a common side effect, which some people find intolerable. All ACE inhibitors can have this side effect, but angiotensin-receptor blockers do not.
Although ACE inhibitors can protect against kidney disease, they also increase potassium retention by the kidneys. This increases the risk for cardiac arrest if potassium levels become too high. Because of this action, they are not generally given with potassium-sparing diuretics or potassium supplements.
A rare but severe side effect is granulocytopenia, an extreme reduction in infection-fighting white blood cells.
In very rare cases, patients suffer a sudden and severe allergic reaction called angioedema that causes swelling in the eyes and mouth and may close off the throat.

Patients who have difficulty tolerating ACE inhibitor side effects are usually switched to an angiotensin-receptor blocker (ARB).

Angiotensin-Receptor Blockers (ARBs)

ARBs, also known as angiotensin II receptor antagonists, are similar to ACE inhibitors in their ability to open blood vessels and lower blood pressure. They may have fewer or less-severe side effects than ACE inhibitors, especially coughing, and are sometimes prescribed as an alternative to ACE inhibitors. Some patients with heart failure take an ACE inhibitor along with an ARB.

Brands and Indications. ARBs are used to treat Stage A high-risk conditions such as high blood pressure and diabetic nerve disorders (neuropathy). They are also used to treat Stage B patients who have had a heart attack or who have left ventricular systolic disorder, and Stage C patients with heart failure. Specific brand include:

Candesartan (Atacand)
Valsartan (Diovan)
Losartan (Cozaar)
Eprosartan (Teveten)
Irbesartan (Avapro)
Olmesartan (Benicar)
Telmisartan (Micardis)

Common Side Effects

Low blood pressure
Dizziness and lightheadedness
Raised potassium levels
Drowsiness

Beta-Blockers

Beta-blockers are almost always used in combination with other drugs, such as ACE inhibitors and diuretics. They help slow heart rate and lower blood pressure. When used properly, beta-blockers can reduce the risk of death or rehospitalization.

Brands and Indications. Beta-blockers treat Stage A high blood pressure. They also treat Stage B patients (both those who have had a heart attack and those who have not had a heart attack but who have heart damage). Recent guidelines identify three drugs best for treating Stage C patients with heart failure:

Carvedilol (Coreg)
Bisoprolol (Zebeta)
Metoprolol succinate (Toprol XL)

Beta-Blocker Concerns

Do not abruptly stop taking these drugs. The sudden withdrawal of beta-blockers can increase the risk of angina and even a heart attack. If you need to stop your beta-blocker, your doctor may want you to slowly decrease the dose before stopping completely.
Beta-blockers are categorized as non-selective or selective. Non-selective beta-blockers, such as carvedilol and propranolol, can narrow bronchial airways. Patients with asthma, emphysema, or chronic bronchitis should not use these beta-blockers.
Beta-blockers can lower HDL (good) cholesterol, although the benefits they provide for coronary artery disease and heart failure outweigh any detriments on cholesterol.
These drugs can hide warning signs of low blood sugar (hypoglycemia) in patients with diabetes, especially those who take insulin.

Common Side Effects

Fatigue and lethargy
Vivid dreams and nightmares
Depression
Memory loss
Dizziness and lightheadedness
Reduced ability to exercise
Coldness in extremities (legs, toes, arms, hands)

Check with your doctor about any side effects. Do not stop taking these drugs on your own.

Diuretics

Diuretics cause the kidneys to rid the body of excess salt and water. Fluid retention is a major symptom of heart failure. Aggressive use of diuretics can help eliminate excess body fluids, while reducing hospitalizations and improving exercise capacity. These drugs are also important to help prevent heart failure in patients with high blood pressure. In addition, certain diuretics, notably spironolactone (Aldactone), block aldosterone, a hormone involved in heart failure. This drug class is beneficial for patients in late stages of heart failure (Stages C and D).

Patients taking diuretics usually take a daily dose. Under the directions and care of a doctor or nurse, some patients may be taught to adjust the amount and timing of the diuretic when they notice swelling or weight gain.

Diuretics come in many brands and are generally inexpensive. Some need to be taken once a day, some twice a day. Treatment is usually started at a low dose and gradually increased. Diuretics are virtually always used in combination with other drugs, especially ACE inhibitors and beta blockers. There are three main types of diuretics:

Potassium-sparing diuretics.

These include amiloride (Midamor) and triamterene (Dyrenium).
Potassium-sparing diuretics have their own risks, which include dangerously high levels of potassium in people with existing elevated levels of potassium or in those with damaged kidneys. However, all diuretics are generally more beneficial than harmful.
Patients should not take potassium supplements at the same time as this type of diuretic without their doctor's knowledge, and may need to avoid foods with high potassium content.

Thiazide diuretics. These include chlorothiazide (Diuril), chlorthalidone (Hygroton), indapamide (Lozol), hydrochlorothiazide (Esidrix, HydroDiuril), and metolazone (Mykrox, Zaroxolyn).

Loop diuretics. These are considered the preferred diuretic type for most patients with heart failure.

Loop diuretics include bumentanide (Bumex), furosemide (Lasix), and torsemide (Demadex).
Loop and thiazide diuretics deplete the body's supply of potassium, which, if left untreated, increases the risk for arrhythmias. (Arrhythmias are heart rhythm disturbances that can, in rare instances, lead to cardiac arrest). In such cases, doctors will prescribe lower doses of the current diuretic, recommend potassium supplements, or use potassium-sparing diuretics either alone or in combination with a thiazide.
Dehydration (loss of too much fluid) is also another concern.

Common Side Effects

Fatigue
Depression and irritability
Urinary incontinence
Reduced sexual drive

Aldosterone Blockers

Aldosterone is a hormone that is critical in controlling the body's balance of salt and water. Excessive levels may play important roles in hypertension and heart failure. Drugs that block aldosterone are prescribed for some patients with symptomatic heart failure. They have been found to reduce mortality or death rates for patients with heart failure and coronary artery disease, especially after a heart attack. These blockers pose some risk for high potassium levels. Brands include:

Spironolactone (Aldactone, Spirinol)
Eplerenone (Inspra)

Elevated levels of potassium in the blood are also a concern with these drugs. Patients should not take potassium supplements at the same time as this drug without their doctor's knowledge and may need to avoid foods with high potassium content.

Digitalis

Digitalis is derived from the foxglove plant. It has been used to treat heart disease since the 1700s. Digoxin (Lanoxin) is the most commonly prescribed digitalis preparation. Digoxin decreases heart size and reduces certain heart rhythm disturbances (arrhythmias).

Unfortunately, digitalis does not reduce mortality rates, although it does reduce hospitalizations and worsening of heart failure. Controversy has been ongoing for more than 100 years over whether the benefits of digitalis outweigh its risks and adverse effects.

Digitalis may be useful for select patients with left-ventricular systolic dysfunction who do not respond to other drugs (diuretics, ACE inhibitors). It may also be used for patients who have atrial fibrillation.

Side Effects and Problems. While digitalis is generally a safe drug, it can have toxic side effects due to overdose or other accompanying conditions. The most serious side effects are arrhythmias (abnormal heart rhythms that can be life threatening). Early signs of toxicity may be irregular heartbeat, nausea and vomiting, stomach pain, fatigue, visual disturbances (such as yellow vision, seeing halos around lights, flickering or flashing of lights), and emotional and mental disturbances.

Many factors increase the chance for side effects.

Advanced age
Low blood potassium levels (which may be caused by diuretics)
Hypothyroidism
Anemia
Valvular heart disease
Impaired kidney function

Digitalis also interacts with many other drugs, including quinidine, amiodarone, verapamil, flecainide, amiloride, and propafenone.

A blood test that monitors drug levels in patients taking the drug can limit the rate of toxicity to about 2%. For most patients with mild-to-moderate heart failure, low-dose digoxin may be as effective as higher doses. If side effects are mild, patients should still consider continuing with digitalis if they experience other benefits.

Hydralazine and Nitrates

Hydralazine and nitrates are two older drugs that help relax arteries and veins, thereby reducing the heart's workload and allowing more blood to reach the tissues. They are used primarily for patients who are unable to tolerate ACE inhibitors and angiotensin receptor blockers. In 2005, the FDA approved BiDil, a drug that combines isosorbide dinitrate and hydralazine. BiDil is approved to specifically treat heart failure in African-American patients. African-Americans have a particularly high risk for heart failure.

Statins

Statins are important drugs used to lower cholesterol and to prevent heart disease leading to heart failure. These drugs include lovastatin (Mevacor), pravastatin (Pravachol), simvastatin (Zocor), fluvastatin (Lescol), atorvastatin (Lipitor), and rosuvastatin (Crestor). In 2007, the Food and Drug Administration (FDA) approved atorvastatin to reduce the risks for hospitalization for heart failure in patients with heart disease.

In a 2006 Journal of the American Medical Association study, patients with heart failure who began taking a statin drug had a 24% lower relative risk of death and a 21% lower relative risk of hospitalization for heart failure than patient who did not take a statin. Statins appeared to help these patients regardless of whether or not they had co-existing coronary heart disease.

Anticoagulation or Anti-Platelet Drugs

Aspirin. Aspirin is a type of non-steroid anti-inflammatory (NSAID). Aspirin is recommended for preventing death in patients with heart disease, and can safely be used with ACE inhibitors, particularly when it is taken in lower dosages (75 - 81 mg).

Warfarin (Coumadin). Warfarin is recommended only for patients with heart failure who also have:

Atrial fibrillation
A history of blood clots to the lungs, stroke, or transient ischemic attack
A blood clot in one of their heart chambers

Other Drugs

Nesiritide (Natrecor). Nesiritide treats patients who have arrived at a hospital with decompensated heart failure. Decompensated heart failure is a life-threatening condition in which the heart fails over the course of minutes or a few days, often as the result of a heart attack or sudden and severe heart valve problems. However, nesiritide may cause serious kidney damage.

In 2005, the FDA released recommendations from an expert panel concerning the appropriate and inappropriate use of nesiritide. The panel emphasized that nesiritide should be used to treat only patients with decompensated heart failure who have shortness of breath (dyspnea) and trouble breathing. The drug should not be a replacement for diuretics.

Despite these warnings, some doctors have prescribed nesiritide off-label to treat patients with severe heart failure outside of a hospital setting. Research presented at the 2007 American College of Cardiology annual conference criticized this practice by demonstrating that nesiritide plus standard treatment does not reduce the risk of heart- or kidney-related death or hospitalization. In addition, the research suggested some concerns about nesiritides overall safety.

Erythropoietin. Many patients with chronic heart failure are also anemic. Treatment of these patients with erythropoietin has been shown to provide some benefit for heart failure control and hospitalization risk. However, erythropoietin therapy can also increase the risk of blood clots. The exact role of this drug for the treatment of anemia in patients with heart failure is not yet decided.

Tolvaptan. Tolvaptan is an investigational drug that is being studied in combination with standard therapy for treatment of heart failure. It is especially being investigated for acute decompensated heart failure, a type of heart failure categorized by fluid build-up in the lungs (pulmonary edema) for which there are few available treatments. In patients hospitalized with heart failure, tolvaptan plus standard drugs has been shown to improve breathing problems (dyspnea) and reduce fluid accumulation (edema) and body weight. However, the drug does not appear to reduce the risk of re-hospitalization or death.

Levosimendan. Levosimendan is an experimental inotropic drug that is being investigated as a treatment for severely ill patients with heart failure. It belongs to a new class of drugs called calcium sensitizers that may help improve heart contractions and blood flow. Clinical trials suggest that levosimendan may improve survival in patients hospitalized for heart failure. The drug also appears to reduce levels of BNP (brain natriuretic peptide), a chemical marker for heart failure severity.

Surgery and Devices

Revascularization Surgery

Revascularization surgery helps to restore blood flow to the heart. It can treat blocked arteries in patients with coronary artery disease and may help selected patients with heart failure. Surgery types include coronary artery bypass graft (CABG) and percutaneous coronary intervention (PCI). CABG is a traditional type of open heart surgery. PCI, also called angioplasty, uses a catheter to inflate a balloon inside the artery. A metal stent may also be inserted during a PCI procedure. [For more information, see In-Depth Report #03: Coronary artery disease.]

A 2006 study suggested that early treatment with revascularization surgery may be particularly important for patients with systolic heart failure, a condition that occurs when the heart does not pump out enough blood. This condition has a very high death rate. Researchers found that CABG or PCI surgery halved the risk of dying compared to standard drug therapy. Patients in the study first underwent a positron emission tomography (PET) test to determine if they would be good candidates for surgery.

Coronary artery balloon angioplasty - series

Click the icon to see an illustrated series detailing coronary artery balloon angioplasty.

Click the icon to see an illustrated series detailing heart bypass surgery.

Valve Surgery

In appropriate patients, valve surgery may significantly reduce the severity of heart failure. Mitral and aortic valve problems more commonly cause or worse heart failure.

Ventricular Assist Devices

A growing array of heart devices and machines are changing the face of heart failure treatment. Ventricular assist devices are machines that help improve pumping actions. They have gained widespread acceptance for use as a bridge to transplant in patients who are on medications but still have severe symptoms and are awaiting a donor heart. Increasingly, though, doctors are exploring the possibility that such devices may be satisfactory treatments themselves, forestalling the need for a transplant altogether in some patients. Therefore they may be used as short-term (less than 1 week) or longer term support.

Ventricular assist devices include:

Left ventricular assist devices (LVADs) are used for patients whose heart beat has slowed dangerously to help take over the pumping action of the failing heart. Until recently, these machines required remaining in the hospital. Smaller battery-powered implanted LVAD units are now allowing many patients to leave the hospital while they wait for a transplant.
Intra-aortic balloon pumps are helpful for maintaining heart function in patients with left-side failure who are waiting for transplants and for those who develop a sudden and severe deterioration of heart function. The IABP is an implanted thin balloon that is usually inserted into the artery in the leg and threaded up to the aorta leading from the heart. Its pumping action is generating by inflating and deflating the balloon at certain rates.
Fully implanted miniature artificial pumps that assist the heart are also being tested.

Short-term support may be provided for patients who have reached end-stage disease in order to bridge them until an appropriate heart for transplantation is available. Some patients may require short-term support while the heart muscle recovers after a serious cardiac event. Permanent use to chronically support a patient is also increasing.

Complications after implantation of these devices are not insignificant, as are some of the long-term complications in patients who make it through after surgery. The risks involved with many of these devices include bleeding, blood clots, and right-side heart failure. Infections are a particular hazard.

Pacers (Pacemakers)

Pacers, or pacemakers, help regulate the hearts beating action, especially when the heart beats too slowly. Biventricular pacers (BVPs) are a special type of pacemaker used for patients with heart failure. Because BVPs help the hearts left and right chambers beat together, this treatment is called cardiac resynchronization therapy (CST).

BVPs are recommended for patients with moderate-to-severe heart failure that is not controlled with medication therapy and who have evidence of left-bundle branch block on their EKG. Left-bundle branch block is a condition in which the electrical impulses in the heart do not follow their normal pattern, causing the heart to pump inefficiently.

Implantable Cardioverter Defibrillators (ICDs)

Patients with enlarged hearts are at risk for having serious cardiac arrhythmias that are associated with sudden death. Implantable cardioverter defibrillators (ICDs) have been shown to reduce the incidence of sudden-death in patients with symptomatic heart failure and an ejection fraction less than 30%. Generally, patients should also be on full medical therapy. Studies have also found ICDs effective in preventing sudden death from severe rhythm disturbances in patients with a history of these serious arrhythmias and in patients with genetic hypertrophic cardiomyopathy. Patients who have an ICD should avoid taking fish oil supplements.

ICDs have many benefits, and recent expert guidelines recommend that they be used in more patients with heart failure. However, in June 2005, certain ICD models and biventricular pacemaker-defibrillators were recalled by the manufacturer because of a circuitry flaw that prevents the devices from delivering therapeutic electrical shocks when needed. The problem may result in patient death. Although the FDA did not make any specific recommendations, the agency encourages patients who may have such a device to ask their doctor if they should have it removed or replaced.

In October 2006, the U.S. Heart Rhythm Society issued recommendations for doctors, manufacturers, and the FDA to help improve communication concerning performance and recalls of ICDs and pacemakers. Experts stress that the chance of an ICD or pacemaker saving a persons life far outweigh the possible risks of these devices failing.

Heart Transplantation

Patients who suffer from severe heart failure and whose symptoms do not improve with drug therapy or mechanical assistance may be candidates for heart transplantation. Some 3,600 people are awaiting a transplant, although only about 2,000 operations are performed each year.

The most important factor for heart transplant eligibility is overall health. Chronological age is less important. Most heart transplant candidates are ages 50 - 64 years. About 72% of transplant patients are male, and 70% are white.

While the risks of this procedure are high, the 1-year survival rate is about 86% for men and 84% for women. The 3-year survival rate is 78% for men and 75% for women. Five years after a heart transplant, about 71% of men and 67% of women remain alive. In general, the highest risk factors for death 3 or more years after a transplant operation are coronary artery disease and the adverse effects (infection and certain cancers) of immunosuppressive drugs used in the procedure. The rejection rates in older people appear to be similar to those of younger patients.

Implantable Artificial Heart

In 2004, the FDA approved a temporary artificial heart (Syncardia) intended to keep patients alive in the hospital while they waited for a heart transplant. In 2006, the FDA approved the first permanent implantable artificial heart (AbiCor). The AbiCor is available only for patients who are not eligible for a heart transplant and who are not expected to live more than a month without medical treatment. The device requires a large chest cavity, which means that most women will not be eligible for it. Of the 14 men who have received the AbiCor, the average survival was less than 5 months after surgery. Only one patient was discharged from the hospital. The devices manufacturer is working on a new model that it hopes will extend survival by as long as 5 years.

Devices to Remove Fluids

Ultrafiltration devices are used in hospitals to pump excess water and salt from the body. Catheters are inserted into several of the patients veins. The catheters are connected to a blood filter device. Blood is withdrawn through one of the catheters and filtered in the device to remove excess fluid. The filtered blood is then returned to the patient through another catheter. Ultrafiltration devices have been evaluated in patients with acute decompensated heart failure (ADHF) -- heart failure that has rapidly deteriorated so that patients need immediate hospitalization. Small studies have shown that these devices have some benefit, but their exact role in the use of patients hospitalized with heart failure remains unclear.

Ventricular Remodeling and Restoration

Ventricular Remodeling. Ventricular remodeling (also called partial left ventriculectomy or the Batista procedure, after its inventor) involves the following:

The surgeon first performs ventriculectomy, the removal of a section of healthy heart muscle weighing about 3 ounces.
The surgeon then reshapes the heart to a more normal size and form.
Any faulty heart valves are repaired.

Ventricular remodeling is still relatively new, and mortality rates are very high. Studies on long-term improvement are mixed. More research is needed to target the patients who would most benefit. Current guidelines from the American Heart Association and the American College of Cardiology discourage use of this procedure.

Lifestyle Changes

Between 30 - 47% of patients hospitalized for heart failure are back in the hospital within 6 months. Many people return because of lifestyle factors, such as poor diet, failure to comply with medications, and social isolation.

Home Support and Rehabilitation Programs

In one study, elderly people who had no emotional support at home had triple the risk of a heart attack after hospitalization for heart failure than those who did have such support. (Women had eight times the risk.) In another study, the greatest risk factor for death and readmission to the hospital after a first hospitalization was being single, regardless of the health of the patient at discharge. A third study confirmed that a strong marriage predicted long-term survival. Evidence continues to mount that programs that offer intensive follow-up to ensure that the patient complies with lifestyle changes and medication regimens at home are reducing rehospitalization rates and improving survival. Patients without available rehabilitation programs should seek support from local and national heart associations and groups.

Monitoring Weight Changes

Patients should weigh themselves each morning and keep a record. Any changes are important:

A sudden increase in weight of more than 2 - 3 pounds may indicate fluid accumulation and should prompt an immediate call to the doctor.
Rapid wasting weight loss over a few months is a very serious sign and may indicate the need for surgical intervention.

Dietary Factors

Salt Restriction. People with high blood pressure should restrict salt intake, although certain people may be more susceptible to its effects than others. For example, a high intake of salt may be an independent risk factor for the development of heart failure in people who are overweight. All patients with heart failure should limit their salt intake, and in severe cases, very stringent salt restriction may be necessary. Patients should not add salt to their cooking and their meals. They should also avoid foods high in sodium. These salty foods include ham, bacon, hot dogs, lunch meats, prepared snack foods, dry cereal, cheese, canned soups, soy sauce, and condiments. Some patients may need to reduce the amount of water they consume. People with high cholesterol levels or diabetes require additional dietary precautions. [For more information on diet and heart health, see In-Depth Report #43: Heart-healthy diet. ]

Exercise

People with heart failure used to be discouraged from exercising. Now, experts think that exercise, when performed under medical supervision, is extremely important for many patients with stable conditions. Studies have reported that patients with stable conditions who engage in regular moderate exercise (three times a week) have a better quality of life and lower mortality rates than those who do not exercise.

The following guidelines are critical:

Experts warn that exercise is not appropriate for all patients with heart failure. If you have heart failure, always consult your doctor before starting an exercise program.
People who are approved for, but not used to, exercise should start with 5 - 15 minutes of easy exercise with frequent breaks. Although the goal is to build up to 30 - 45 minutes of walking, swimming, or low-impact aerobic exercises three to five times every week, even shorter times spent exercising are useful.

Studies report benefits from specific exercises:

Progressive strength training may be particularly useful for patients with heart failure since it strengthens muscles, which commonly deteriorate in this disorder. Strength training typically uses light weights, weight machines, or even the body's weight (leg raises or sit-ups, for example). Even performing daily handgrip exercises can improve blood flow through the arteries.
Patients who exercise regularly using supervised treadmill and stationary-bicycle exercises can increase their exercise capacity. In one study, patients as old as 91 years increased their oxygen consumption significantly after 6 months of supervised treadmill and stationary bicycle exercises. Exercising the legs may help correct problems in heart muscles. In one study, patients who did leg extension exercises for 8 weeks had higher levels of an enzyme involved in forming new blood vessels. Exercise has also been associated with reduced inflammation in blood vessels.
Dancing may be a fun and beneficial alternative to standard aerobic exercise, according to research presented at the 2006 annual meeting of the American Heart Association. In a study of patients with stable chronic heart failure, dancing helped improve cardiopulmonary fitness, arterial elasticity, and quality of life. Patients in the study danced fast and slow waltzes for 21 minutes, three times a week.

Bed Rest

Some people with severe heart failure may need bed rest. To reduce congestion in the lungs, the patient's upper body should be elevated. For most patients, resting in an armchair is better than lying in bed. Relaxing and contracting leg muscles is important to prevent clots. As the patient improves, a doctor will progressively recommend more activity.

Warm Baths and Saunas

Experts have traditionally recommended that people with heart failure avoid warm baths, which can increase the heart rate. Some studies now report that carefully controlled bathing for short periods may not be harmful and may actually be beneficial, reducing irregular heart beats and increasing cardiac output and ejection fraction. Warm water may behave like a vasodilating drug, opening up the vessels gently and improving circulation. In clinical trials, patients sat in warm water or a dry sauna for 10 minutes, with their bodies tilted at a 45 degree angle.

Warning Note: Prolonged periods in hot or even warm conditions can be dangerous. Any patient with heart failure should consult their doctor first, not bathe unaccompanied, and be sure that the temperature does not go above 106 F for water bathing, or 140 F for dry saunas.

Stress Reduction

Stress reduction techniques, such as meditation and relaxation response methods, may have direct physical benefits for lowering stress hormones. These hormones include cortisol, which suppresses the immune system, and norepinephrine (also known as adrenaline), the chemical messenger associated with heart dysfunction.

Alternative Remedies

Patients with heart failure may resort to alternative remedies. Such remedies are often ineffective and may have severe or toxic effects. Of particular note for patients with heart failure is an interaction between St. John's wort (an herbal medicine used for depression) and digoxin (a heart drug). St. John's wort can significantly interfere with this drug.

Coenzyme Q10 and Vitamin E. Small studies have suggested that coenzyme Q10 (CoQ10) may help patients with heart failure, particularly when combined with vitamin E. CoQ10 is a vitamin-like substance found in organ meats and soybean oil. More recent studies, however, have found that CoQ10 and vitamin E do not help the heart or prevent heart disease. According to a study published in 2005 in the Journal of the American Medical Association, vitamin E supplements can actually increase the risk of heart failure, especially for patients with diabetes or vascular diseases.

Crataegus Extract. An herbal remedy, Crataegus Extract WS1442, which is made from the leaves of the Crataegus tree, may have antioxidant properties that can help patients with heart failure. In a study presented at the 2007 American College of Cardiology annual meeting, over 2,000 patients with severe heart failure were randomized to receive either Crataegus Extract or placebo (plus standard drug treatment) for 2 years. The researchers noted a 20% reduction in heart-related deaths among patients who received the extract, and suggested that the herb extended patients lives by 4 months during the first 18 months of the study.

Other Vitamins and Supplements. A wide variety of other vitamins (thiamin, B6, and C), minerals (calcium, magnesium, zinc, manganese, copper, selenium), nutritional supplements (carnitine, creatine), and herbal remedies (hawthorn) have been proposed as treatments for heart failure. None have been adequately tested. There is no evidence that a particular vitamin or supplement can cure heart failure. In any case, vitamins are best consumed through the food sources contained in a healthy diet.

Herbs and Supplements

Generally, manufacturers of herbal remedies and dietary supplements do not need FDA approval to sell their products. Just like a drug, herbs and supplements can affect the body's chemistry, and therefore have the potential to produce side effects that may be harmful. There have been several reported cases of serious and even lethal side effects from herbal products. Always check with your doctor before using any herbal remedies or dietary supplements.

Resources

www.nhlbi.nih.gov -- National Heart, Lung, and Blood Institute
www.americanheart.org -- American Heart Association
www.acc.org -- American College of Cardiology
www.hfsa.org -- Heart Failure Society of America
www.heartfailure.org -- Heart Failure Online
www.unos.org -- United Network for Organ Sharing
www.organdonor.org -- National Transplant Society
www.organdonor.gov -- US government organ donor site

References

Battaglia M, Pewsner D, Juni P, Egger M, Bucher HC, Bachmann LM. Accuracy of B-type natriuretic peptide tests to exclude congestive heart failure: systematic review of test accuracy studies. Arch Intern Med. 2006 May 22;166(10):1073-80.

Birks EJ, Tansley PD, Hardy J, George RS, Bowles CT, Burke M, et al. Left ventricular assist device and drug therapy for the reversal of heart failure. N Engl J Med. 2006 Nov 2;355(18):1873-84.

Carlson MD, Wilkoff BL, Maisel WH, Carlson MD, Ellenbogen KA, Saxon LA, et al. Recommendations from the Heart Rhythm Society Task Force on Device Performance Policies and Guidelines Endorsed by the American College of Cardiology Foundation (ACCF) and the American Heart Association (AHA) and the International Coalition of Pacing and Electrophysiology Organizations (COPE). Heart Rhythm. 2006 Oct;3(10):1250-73.

Gheorghiade M, Konstam MA, Burnett JC Jr, Grinfeld L, Maggioni AP, Swedberg K, et al. Short-term clinical effects of tolvaptan, an oral vasopressin antagonist, in patients hospitalized for heartf failure: the EVEREST clinical status trials. JAMA. 2007 Mar 25; [Epub ahead of print]

Go AS, Lee WY, Yang J, Lo JC, Gurwitz JH. Statin therapy and risks for death and hospitalization in chronic heart failure. JAMA. 2006 Nov 1;296(17):2105-11.

Guazzi M, Samaja M, Arena R, Vicenzi M, Guazzi MD. Long-term use of sildenafil in the therapeutic management of heart failure. J Am Coll Cardiol. 2007 Nov 27;50(22):2136-44. Epub 2007 Nov 13.

Hare JM. The dilated, restrictive, and infiltrative cardiomyopathies. In: Libby P, Bonow RO, Mann DL, Zipes DP, eds. Libby: Braunwald's Heart Disease: A Textbook of Cardiovascular Medicine. 8th ed. Saunders; 2007: chap 64.

Haykowsky MJ, Liang Y, Pechter D, Jones LW, McAlister FA, Clark AM. A meta-analysis of the effect of exercise training on left ventricular remodeling in heart failure patients: the benefit depends on the type of training performed. J Am Coll Cardiol. 2007 Jun 19;49(24):2329-36. Epub 2007 Jun 4.

Hess OM and Carroll JD. Clinical assessment of heart failure. In: Libby P, Bonow RO, Mann DL, Zipes DP, eds. Libby: Braunwald's Heart Disease: A Textbook of Cardiovascular Medicine. 8th ed. Saunders; 2007: chap 23.

Hildebrandt P. Systolic and nonsystolic heart failure: equally serious threats. JAMA. 2006 Nov 8;296(18):2259-60.

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Palazzuoli A, Silverberg D, Iovine F, Capobianco S, Giannotti G, Calabr A, et al. Erythropoietin improves anemia exercise tolerance and renal function and reduces B-type natriuretic peptide and hospitalization in patients with heart failure and anemia. Am Heart J. 2006 Dec;152(6):1096.e9-15.

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Review Date: 4/20/2008
Reviewed By: Harvey Simon, MD, Associate Professor of Medicine, Harvard Medical School; Physician, Massachusetts General Hospital. Also reviewed by David Zieve, MD, MHA, Medical Director, A.D.A.M., Inc.

The information provided herein should not be used during any medical emergency or for the diagnosis or treatment of any medical condition. A licensed medical professional should be consulted for diagnosis and treatment of any and all medical conditions. Call 911 for all medical emergencies. Links to other sites are provided for information only -- they do not constitute endorsements of those other sites. 1997- A.D.A.M., Inc. Any duplication or distribution of the information contained herein is strictly prohibited.

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Health Topics A-Z

Heart failure

Highlights

Introduction

Description of Heart Failure

Causes

High Blood Pressure

Coronary Artery Disease

Valvular Heart Disease

Cardiomyopathy

Lung Disease

Pulmonary Hypertension

Medications Associated with Heart Failure

Corrective Mechanisms, Remodeling, and the Failing Heart

Symptoms

Risk Factors

Advancing Age

Gender

Ethnicity

Family History and Genetics

Diabetes

Obesity

Thyroid Problems

Complications

Diagnosis

Laboratory Tests

Electrocardiogram

Exercise Stress Test

Echocardiography

Imaging Tests

Angiography

Tests for Markers

Treatment

Management of Risk Factors and Causes

Treatment Based on Heart Failure

Management of Precipitating Factors

Medications

ACE Inhibitors

Angiotensin-Receptor Blockers (ARBs)

Beta-Blockers

Diuretics

Aldosterone Blockers

Digitalis

Hydralazine and Nitrates

Statins

Anticoagulation or Anti-Platelet Drugs

Other Drugs

Surgery and Devices

Revascularization Surgery

Valve Surgery

Ventricular Assist Devices

Pacers (Pacemakers)

Implantable Cardioverter Defibrillators (ICDs)

Heart Transplantation

Implantable Artificial Heart

Devices to Remove Fluids

Ventricular Remodeling and Restoration

Lifestyle Changes

Home Support and Rehabilitation Programs

Monitoring Weight Changes

Dietary Factors

Exercise

Bed Rest

Warm Baths and Saunas

Stress Reduction

Alternative Remedies

Herbs and Supplements

Resources

References

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