Coronary circulation
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Coronary circulation
An anterior view of the heart shows the
right coronary artery and the anterior descding branch of the
left coronary artery.
The coronary circulation consists of the blood vessels that supply blood to, and remove blood from, the heart muscle itself. Although blood fills the chambers of the heart, the muscle tissue of the heart, or myocardium, is so thick that it requires coronary blood vessels to deliver blood deep into the myocardium. The vessels that supply blood high in oxygen to the myocardium are known as coronary arteries. The vessels that remove the deoxygenated blood from the heart muscle are known as cardiac veins.
The coronary arteries that run on the surface of the heart are called epicardial coronary arteries. These arteries, when healthy, are capable of autoregulation to maintain coronary blood flow at levels appropriate to the needs of the heart muscle. These relatively narrow vessels are commonly affected by
atherosclerosis and can become blocked, causing angina or a heart attack.
The coronary arteries are classified as "end circulation", since they represent the only source of blood supply to the myocardium: there is very little redundant blood supply, which is why blockage of these vessels can be so critical.
•1 Coronary anatomy
o1.1 Variations
o1.2 Coronary artery dominance
•2 Blood supply of the papillary muscles
•3 Coronary flow
•4 See also
•5 External Link
Coronary anatomy
The exact anatomy of the myocardial blood supply varies considerably from person to person. A full evaluation of the coronary arteries requires
cardiac catheterization.
In general there are two main coronary arteries, the left and right.
•Right coronary artery
•Left coronary artery
Both of these arteries originate from the beginning (root) of the aorta, immediately above the aortic valve. As discussed below, the left coronary artery originates from the left aortic sinus, while the right coronary artery originates from the right aortic sinus.
Variations
Four percent of people have a third, the posterior coronary artery. In rare cases, a patient will have one coronary artery that runs around the root of the aorta.
Occasionally, a coronary artery will exist as a double structure (ie there are two arteries, parallel to each other, where ordinarily there is one). Dana Carvey has this variation, which led to a mishap during his CABG operation.
Coronary artery dominance
The artery that supplies the posterior descending artery (PDA) and the posterolateral artery (PLA) determines the coronary dominance.
•If the right coronary artery (RCA) supplies both these arteries, the circulation can be classified as "right-dominant".
•If the left circumflex artery (LCX) supplies both these arteries, the circulation can be classified as "left-dominant".
•If the RCA supplies the PDA and the LCX supplies the PLA, the circulation is known as "co-dominant".
Approximately 70% of the general population are right-dominant, 20% are co-dominant, and 10% are left-dominant. [1]
Blood supply of the papillary muscles
The papillary muscles tether the mitral valve (the valve between the left atrium and the left ventricle) and the tricuspid valve (the valve between the right atrium and the
right ventricle) to the wall of the heart. If the papillary muscles are not functioning properly, the mitral valve leaks during contraction of the left ventricule. This causes some of the blood to travel "in reverse", from the left ventricle to the left atrium, instead of forward to the aorta and the rest of the body. This leaking of blood to the left atrium is known as
mitral regurgitation.
The anterolateral papillary muscle receives two blood supplies: the LAD and LCX, and is therefore somewhat resistant to
coronary ischemia. On the other hand, the posteromedial papillary muscle is supplied only by the PDA. This makes the posteromedial papillary muscle significantly more susceptible to ischemia. The clinical significance of this is that a
myocardial infarction involving the PDA is more likely to cause mitral regurgitation.
Coronary flow
During contraction of the ventricular myocardium (systole), the subendocardial coronary vessels (the vessels that enter the myocardium) are compressed due to the high intraventricular pressures. However the epicardial coronary vessels (the vessels that run along the outer surface of the heart) remain patent. Because of this, blood flow in the subendocardium stops. As a result most myocardial perfusion occurs during heart relaxation (diastole) when the subendocardial coronary vessels are patent and under low pressure. This contributes to the filling difficulties of the coronary arteries.
The primary determinant of coronary blood flow is the level of myocardial/cardiac oxygen consumption. As the heart beats more vigorously, ATP is consumed at a greater rate due to the increased force and/or frequency of contraction and the depolarization and repolarization of the cardiac membrane potential. The increase in oxygen consumption results in the release of a vasodilator substance, the identity of which remains unknown. The vasodilator reduces vascular resistance and allows more blood to flow through the heart during each diastole. Systolic compression remains the same. Failure of oxygen delivery via increases in blood flow to meet the increased oxygen demand of the heart results in tissue ischemia, a condition of oxygen debt. Brief ischemia is associated with intense chest pain, known as angina. Severe ischemia can cause the heart muscle to die of
oxygen starvation, called a myocardial infarction. Chronic moderate ischemia causes contraction of the heart to weaken, known as myocardial hibernation.
In addition to metabolism, the coronary circulation possesses unique pharmacologic characteristics. Prominent among these is its reactivity to adrenergic stimulation. The majority of circulation in the body constrict to norepinephrine, a sympathetic
neurotransmitter the body uses to increases blood pressure. In the coronary circulation, norepinephrine elicits vasodilation, due to the predominance of beta-adrenergic receptors in the coronary circulation. Agonists of alpha-receptors, such as phenylephrine, elicit very little constriction in the coronary circulation.
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1. Normal Coronary Anatomy
Anatomic
Left and right coronary artery
Surgical
Left main, left anterior descending
Left circumflex and right coronary artery
Variability in the origin of the posterior descending artery is expressed by the term dominance
Left dominance is less common (10-15%). More frequent in males
Left main coronary artery absence (1%)
Left anterior descending artery variations (4%)
Right coronary artery variations common (dual origin, immediate bifurcation)
Left circumflex coronary artery variations common
2. Blood Supply to Specialized Areas of the Heart
Ventricular septum
Predominantly from the left anterior descending via septals with a small portion (posterior septum) from the posterior descending
Sinus Node
Right coronary artery 55%
Left circumflex main 45%
AV Node
Right coronary artery 90%
Left circumflex artery 10%
3. Proximal HIS Bundle
AV node artery (posterior)
Kugels artery (anterior)
Distal HIS Bundle
Septal arteries from left anterior descending
Anterolateral papillary muscle
Branches of left coronary artery (LAD, diagonal, circumflex)
Posteromedial papillary muscle
Branches of right and circumflex coronary arteries
4. Minor Coronary Anomalies
Definition
Clinically and hemodynamically insignificant anomalies due primarily to an abnormal origin from the aorta or unusual distribution Circumflex artery arising from the right coronary artery or sinus. Most common anomaly (0.5%).
May be associated with transposition Left anterior descending from right coronary artery or right sinus. Most common coronary artery anomaly associated with
Tetralogy of Fallot (2%) Right coronary artery from noncoronary sinus
Multiple coronary ostia
5. Major Coronary Anomalies
Anomalous origin of a main coronary artery from the aorta
Left main coronary artery from right sinus
Right coronary artery from left sinus (more common)
Single coronary ostia
Clinical events related to course between
pulmonary artery and aorta resulting in compression, stretching or angulation (especially during exercise)
Symptoms
Myocardial infarction
Angina
CHF
Sudden death, as high as 15%
Natural history is controversial
Treatment is revascularization
Unroofing of intramural segment of the anomalous coronary artery
6. Hemodynamically Significant Coronary Artery Anomalies
Coronary artery aneurysms
Congenital (rare)
Atherosclerotic more common (3-5%)
Complications: Ischemia, thrombosis, distal embolization, infarction
Coronary artery atresia/hypoplasia (severe LV dysfunction and sudden death, not surgically correctable)
Coronary artery stenosis (occurs with other congenital lesions)
Coronary artery fistulas (most common)
Anomalous origin of left or right coronary artery from the pulmonary artery
7. Congenital Arteriovenous Fistulas
Definition
A direct communication between a coronary artery and any one of the four cardiac chambers, coronary sinus, SVC, pulmonary arteries or veins.
Right coronary most commonly involved (55%)
Left anterior descending (35%), combined (5%)
Site of connections
90% drain into the right heart
Right ventricle 40%
Right atrium 30%
Pulmonary artery 20%
Fistulous opening most commonly is single