ACUTE CORONARY SYNDROME
- ACS may occur with Marfan syndrome; Kawasaki disease; Takayasu arteritis; or cystic medial necrosis with aortic root dilatation, aneurysm formation, and dissection into the coronary artery.
- Anomalous origin of the left coronary artery from the pulmonary artery may occur as unexplained sudden death in a neonate.
- Coronary artery ostial stenosis may occur after repair of a transposition of the great arteries in the neonatal period.
- An aberrant left main coronary artery with its origin at the right sinus of Valsalva may cause ACS, especially with exertion.
- Traumatic myocardial infarction can occur in patients at any age.
- Accelerated atherosclerosis is known to occur in cardiac transplant recipients on immunosuppressive therapy.
- Progeria
Irrespective of the cause of unstable angina, the result of persistent ischemia is myocardial infarction (MI)
Mortality/Morbidity: When the only treatment for angina was nitroglycerin and limitation of activity, patients with newly diagnosed angina had a 40% incidence of MI and a 17% mortality rate within 3 months. A recent study shows that the 30-day mortality from ACS has decreased as treatment has improved, a statistically significant 47% relative decrease in 30-day mortality among newly diagnosed ACS from 1987-2000. This decrease in mortality is attributed to aspirin, glycoprotein (GP) IIb/IIIa blockers, and coronary revascularization via medical intervention or procedures.
Clinical characteristics associated with a poor prognosis include advanced age, male sex, prior MI, diabetes, hypertension, and multiple-vessel or left-mainstem disease.
Sex: Incidence is higher in males among all patients younger than 70 years. This is due to the cardioprotective effect of estrogen in females. At 15 years postmenopause, the incidence of angina occurs with equal frequency in both sexes. Evidence exists that women more often have coronary events without typical symptoms, which might explain the frequent failure to initially diagnose ACS in women.
Age: ACS becomes progressively more common with increasing age. In persons aged 40-70 years, ACS is diagnosed more often in men than in women. In persons older than 70 years, men and women are affected equally.
- Typically, angina is a symptom of myocardial ischemia that appears in circumstances of increased oxygen demand. It usually is described as a sensation of chest pressure or heaviness that is reproduced by activities or conditions that increase myocardial oxygen demand.
- Not all patients experience chest pain. Some present with only neck, jaw, ear, arm, or epigastric discomfort.
- Other symptoms, such as shortness of breath or severe weakness, may represent anginal equivalents.
- A patient may present to the ED because of a change in pattern or severity of symptoms. A new case of angina is more difficult to diagnose because symptoms are often vague and similar to those caused by other conditions (eg, indigestion, anxiety).
- Patients may have no pain and may only complain of episodic shortness of breath, weakness, lightheadedness, diaphoresis, or nausea and vomiting.
- Elderly persons and those with diabetes may have particularly subtle presentations and may complain of fatigue, syncope, or weakness. Elderly persons may also present with only altered mental status. Those with preexisting altered mental status or dementia may have no recollection of recent symptoms and may have no complaints whatsoever.
- As many as half of cases of ACS are clinically silent in that they do not cause the classic symptoms described above and consequently go unrecognized by the patient. Maintain a high index of suspicion for ACS especially when evaluating women, diabetics, older patients, patients with dementia, and those with a history of heart failure.
- Risk factors for ACS should be documented and include the following:
- Male gender
- Diabetes mellitus (DM)
- Smoking history
- Hypertension
- Increased age
- Hypercholesterolemia
- Hyperlipidemia
- Prior cerebrovascular accident (CVA) – These patients constitute 7.5% of patients with ACS and have high-risk features.
- Inherited metabolic disorders
- Occupational stress
- Connective tissue disease
TREATMENT
| How is a heart attack treated? Special treatments to open up your arteries Heart attack treatment begins immediately. Once symptoms are identified, call 9-1-1 to set in motion rapid diagnosis and treatment. Medications
The knowledge gained in the past years regarding acute coronary syndromes and what happens in the artery during a heart attack has helped guide medical treatment. The goals of medication therapy are to break up or prevent blood clots, prevent platelets from gathering and sticking to the plaque, stabilize the plaque, and prevent further ischemia. These medications must be given as soon as possible (within 30 minutes from the start of heart attack symptoms) to decrease the amount of damage to the heart muscle. The longer the delay in starting these drugs, the more damage that occurs and the less benefit they can provide. Medications given right after the start of a heart attack may include:
Other drugs, given during or after a heart attack lessen your heart’s work, improve the functioning of the heart, widen or dilate your blood vessels, decrease your pain, and guard against any life-threatening heart rhythms. Your doctor will prescribe the appropriate medications for you. Interventional procedures During or shortly after a heart attack, you may go to the cardiac catheterization laboratory to directly evaluate the status of your heart, arteries and the amount of heart damage. In some cases, procedures (such as angioplasty or stents) are used to open up your narrowed or blocked arteries. These procedures may be combined with thrombolytic therapy to open up the narrowed arteries, as well as to break up any clots that are blocking them. Coronary artery bypass surgery If necessary, bypass surgery may be performed to restore the heart muscle’s supply of blood. |
HEART ATTACK : an ACUTE CORONARY SYNDROME
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Acute Coronary Syndrome is a name given to three types of coronary artery disease that are associated with sudden rupture of plaque inside the coronary artery: unstable angina, Non-ST segment elevation myocardial infarction or heart attack (NSTEMI), or ST segment elevation myocardial infarction or heart attack (STEMI). The location of the blockage, the length of time that blood flow is blocked and the amount of damage that occurs determines the type of acute coronary syndrome. These life-threatening conditions require emergency medical care. Unstable angina is a new symptom or a change from stable angina. The angina may occur more frequently, occur more easily at rest, feel more severe, or last longer. Although this angina can often be relieved with oral medications, it is unstable and may progress to a heart attack. Usually more intense medical treatment or a procedure is required. Unstable angina is an acute coronary syndrome and should be treated as a medical emergency. Heart attack: Non-ST segment elevation myocardial infarction (NSTEMI): This heart attack, or MI, does not cause changes on an electrocardiogram (ECG). However, chemical markers in the blood indicate that damage has occurred to the heart muscle. In NSTEMI, the blockage may be partial or temporary, and so the extent of the damage relatively minimal. Heart attack: ST segment elevation myocardial infarction (STEMI): This heart attack, or MI, is caused by a prolonged period of blocked blood supply. It affects a large area of the heart muscle, and so causes changes on the ECG as well as in blood levels of key chemical markers.
Other terms associated with a heart attack: Stunned myocardium: If blood flow is returned to an area of heart muscle after a period of ischemia (lack of blood supply), the heart muscle may not pump normally for a period of days following the event. This is called “stunned” heart muscle or myocardium. Hibernating myocardium: After a heart attack, some areas of heart muscle do not pump as they should. Some areas will have permanent damage. Other areas are able to return to their normal function if blood flow is returned to that area (by medications or a procedure). Hibernating myocardium is heart muscle that is “resting” and may possibly return to normal function. |
HEART ATTACK SYMPTOMS
WHAT HAPPENS DURING A HEART ATTACK?
| A closer look inside your coronary arteries
Your heart muscle needs to receive a good supply of blood at all times to function properly. Your heart muscle gets the blood it needs to do its job from the coronary arteries. What is coronary artery disease? Coronary artery disease is the narrowing or blockage of the coronary arteries caused by atherosclerosis. Atherosclerosis (sometimes called “hardening” or “clogging” of the arteries) is the buildup of cholesterol and fatty deposits (called plaque) on the inner walls of the arteries that restricts blood flow to the heart. Without adequate blood, the heart becomes starved of oxygen and the vital nutrients it needs to work properly. This can cause chest pain called angina. When one or more of the coronary arteries are completely blocked, a heart attack (injury to the heart muscle) may occur. A closer look at coronary artery disease |
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 When fat builds up inside your arteries it causes slight injury to your blood vessel walls. In an attempt to heal the blood vessel walls, the cells release chemicals that make the blood vessel walls stickier. Other substances traveling through your blood stream, such as inflammatory cells, cellular waste products, proteins and calcium, begin to stick to the vessel walls. The fat and other substances combine to form a material called plaque. |
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 Over time, the inside of the arteries develop plaques of different sizes. Many of the plaque deposits are soft on the inside with a hard fibrous “cap” covering the outside. If the hard surface cracks or tears, the soft, fatty inside is exposed. Platelets (disc-shaped particles in the blood that aid clotting) come to the area, and blood clots form around the plaque. |
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 If a blood clot totally blocks the blood supply to the heart muscle, called a coronary thrombus or coronary occlusion, the heart muscle becomes “starved” for oxygen and nutrients (called ischemia) in the region below the blockage. Within a short time, an acute coronary syndrome can occur. Acute Coronary Syndrome is a name given to three types of coronary artery disease that are associated with sudden rupture of plaque inside the coronary artery: unstable angina, Non-ST segment elevation myocardial infarction or heart attack(NSTEMI),or ST segment elevation myocardial infarction or heart attack(STEMI). |
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A heart attack can also occur less frequently by a spasm of a coronary artery. During coronary spasm, the coronary arteries constrict or spasm on and off, causing lack of blood supply to the heart muscle (ischemia). It may occur at rest and can even occur in people without significant coronary artery disease. If coronary artery spasm occurs for a long period of time, a heart attack can occur. |
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Each coronary artery supplies blood to a region of the heart muscle. If an artery is occluded (blocked) there is no blood supply to that region. |
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dark red = artery
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blue = outlines region of heart affected by blockage
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Circumflex occlusion |
Left anterior descending (LAD) occlusion
front of heart |
Right coronary artery (RCA) occlusion
front of heart |
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| The amount of damage to the heart muscle depends on the size of the area supplied by the blocked artery and the time between injury and treatment.
Quick treatment to open the blocked artery is essential to lessen the amount of damage. Learn the symptoms of a heart attack and what to do if they occur. Healing of the heart muscle begins soon after a heart attack and takes about 8 weeks. Just like a skin wound, the heart’s wound heals and a scar will form in the damaged area. The new scar tissue does not contract or pump as well as healthy heart muscle tissue. So, the heart’s pumping ability is lessened. The amount of lost pumping ability depends on the size and location of the scar. |
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HEART ATTACK
What is heart attack
A heart attack, or myocardial infarction (MI), is permanent damage to the heart muscle. “Myo” means muscle, “cardial” refers to the heart, and “infarction” means death of tissue due to lack of blood supply.
Heart Beat
A heartbeat is a two-part pumping action that takes about a second. As blood collects in the upper chambers (the right and left atria), the heart’s natural pacemaker (the SA node) sends out an electrical signal that causes the atria to contract. This contraction pushes blood through the tricuspid and mitral valves into the resting lower chambers (the right and left ventricles). This part of the two-part pumping phase (the longer of the two) is called diastole.
The second part of the pumping phase begins when the ventricles are full of blood. The electrical signals from the SA node travel along a pathway of cells to the ventricles, causing them to contract. This is called systole. As the tricuspid and mitral valves shut tight to prevent a back flow of blood, the pulmonary and aortic valves are pushed open. While blood is pushed from the right ventricle into the lungs to pick up oxygen, oxygen-rich blood flows from the left ventricle to the heart and other parts of the body.
After blood moves into the pulmonary artery and the aorta, the ventricles relax, and the pulmonary and aortic valves close. The lower pressure in the ventricles causes the tricuspid and mitral valves to open, and the cycle begins again. This series of contractions is repeated over and over again, increasing during times of exertion and decreasing while you are at rest. The heart normally beats about 60 to 80 times a minute when you are at rest, but this can vary. As you get older, your resting heart rate rises. Also, it is usually lower in people who are physically fit.
Your heart does not work alone, though. Your brain tracks the conditions around you—climate, stress, and your level of physical activity—and adjusts your cardiovascular system to meet those needs.
The human heart is a muscle designed to remain strong and reliable for a hundred years or longer. By reducing your risk factors for cardiovascular disease, you may help your heart stay healthy longer
Heart Valves
Four valves regulate blood flow through your heart:
* The tricuspid valve regulates blood flow between the right atrium and right ventricle.
* The pulmonary valve controls blood flow from the right ventricle into the pulmonary arteries, which carry blood to your lungs to pick up oxygen.
* The mitral valve lets oxygen-rich blood from your lungs pass from the left atrium into the left ventricle.
* The aortic valve opens the way for oxygen-rich blood to pass from the left ventricle into the aorta, your body’s largest artery, where it is delivered to the rest of your body
Coronary Arteries
Diagram of the Coronary Arteries
Coronary Circulation
The heart muscle, like every other organ or tissue in your body, needs oxygen-rich blood to survive. Blood is supplied to the heart by its own vascular system, called coronary circulation.
The aorta (the main blood supplier to the body) branches off into two main coronary blood vessels (also called arteries). These coronary arteries branch off into smaller arteries, which supply oxygen-rich blood to the entire heart muscle.
The right coronary artery supplies blood mainly to the right side of the heart. The right side of the heart is smaller because it pumps blood only to the lungs.
The left coronary artery, which branches into the left anterior descending artery and the circumflex artery, supplies blood to the left side of the heart. The left side of the heart is larger and more muscular because it pumps blood to the rest of the body.
Bundle Branch Block
Your heart has a natural “pacemaker” called the sinoatrial (SA) node. The SA node is a specialized group of cells at the top of your heart’s upper-right chamber (the right atrium). Anywhere between 60 and 100 times a minute, the SA node sends an electrical impulse throughout your heart to cause it to beat (contract).
When the SA node sends an electrical impulse, that impulse first travels through the heart’s upper chambers (the atria). It then passes through a small group of cells called the atrioventricular (AV) node. The AV node checks the impulse and sends it along a track called the bundle of His. The bundle of His divides into a right bundle branch and a left bundle branch, which lead to your heart’s lower chambers (the ventricles)
Sometimes the electrical impulse cannot travel throughout the heart because part of the heart’s conduction system is “blocked.” If an impulse is blocked as it travels through the bundle branches, you are said to have bundle branch block.
What causes bundle branch block?
For the left and right ventricles to contract at the same time, an electrical impulse must travel down the right and left bundle branches at the same speed. If there is a block in one of these branches, the electrical impulse must travel to the ventricle by a different route. When this happens, the rate and rhythm of your heartbeat are not affected, but the impulse is slowed. Your ventricle will still contract, but it will take longer because of the slowed impulse. This slowed impulse causes one ventricle to contract a fraction of a second slower than the other.
The medical terms for bundle branch block are derived from which branch is affected. If the block is located in the right bundle branch, it is called right bundle branch block. If the block is located in the left bundle branch, it is called left bundle branch block.
The block can be caused by coronary artery disease, cardiomyopathy, or valve disease. Right bundle branch block may also occur in a healthy heart.
What are the symptoms of bundle branch block?
If there is nothing else wrong with your heart, you probably will not feel any symptoms of bundle branch block. In fact, some people may have bundle branch block for years and never know they have the condition. In people who do have symptoms, they may faint (syncope) or feel as if they are going to faint (presyncope).
So why should we worry about bundle branch block? Because it can be a warning sign of other, more serious heart conditions. For example, it might mean that a small part of your heart is not getting enough oxygen-rich blood. Also, researchers have found that people who have left bundle branch block may be at greater risk for heart disease than are people who do not have the condition.
How is bundle branch block diagnosed?
Doctors can use an electrocardiogram (EKG or ECG) machine to record the electrical impulses of your heart. Bundle branch block shows up on the EKG tracing. The electrical patterns recorded by the EKG machine can even show your doctor whether the block is located in the right or left bundle branch.
How is bundle branch block treated?
In most cases, bundle branch block does not need treatment. But patients who have bundle branch block along with another heart condition may need treatment. For example, if bundle branch block develops during a heart attack, you may need a pacemaker. After a heart attack, your heart is fragile, and bundle branch block may cause a very slow heart rhythm (bradycardia). A pacemaker will help regulate the heart’s rhythm after a heart attack.
For patients with both bundle branch block and dilated cardiomyopathy, a new type of pacing called cardiac resynchronization treatment (CRT) may be used. Normally, pacemakers pace only one of the lower heart chambers (the ventricles) at a time. But CRT re-coordinates the beating of the two ventricles by pacing them at the same time. Recent studies have shown that CRT works for certain patients with both bundle branch block and dilated cardiomyopathy.
Even if you do not have other conditions, you should still see your doctor regularly so that he or she can be sure there are no other changes in your heart
