E/A ratio

Last updated February 27, 2024

The E/A ratio is a marker of the function of the left ventricle of the heart. It represents the ratio of peak velocity blood flow from left ventricular relaxation in early diastole (the E wave) to peak velocity flow in late diastole caused by atrial contraction (the A wave).^[1] It is calculated using Doppler echocardiography, an ultrasound-based cardiac imaging modality. Abnormalities in the E/A ratio suggest that the left ventricle, which pumps blood into the systemic circulation, cannot fill with blood properly in the period between contractions. This phenomenon is referred to as diastolic dysfunction and can eventually lead to the symptoms of heart failure.^[2]

Physiology

The heart is a biological pump designed to move blood through the brain and body. It has four chambers: two "upper" chambers called the atria, and two "lower" chambers called the ventricles. Anatomically, the atria are more posterior to the ventricles, but for ease of understanding, are often drawn "above" them. The atria are separated from the ventricles beneath by the atrioventricular valves, which open to allow blood into the ventricles and close when ventricular pressure exceeds atrial pressure.^{[ citation needed ]}

Blood is transferred into the ventricles in two steps: in the first step, as the ventricle relaxes from the previous systolic phase, the pressure in the ventricle becomes less than the pressure in the atria. This causes the leaflets of the atrioventricular valves (tricuspid on the right, mitral on the left) to open like trap doors, and blood falls into the ventricles. On the left side, the velocity at which the blood moves during this initial action is called the "E" ( for early) filling velocity. Early filling is responsible for roughly 80% of total ventricular filling. Some blood always remains in the atria, so toward the end of ventricular relaxation (diastole), the atria actively contract to empty the rest, causing the ventricle walls to "stretch", which allows for a stronger contraction during the upcoming systolic phase. This is called the "atrial kick". The velocity of the blood filling the ventricle in this step is the "A" (for atrial) filling. ^{[ citation needed ]}

Phases of diastole:^[2]

Isovolumic relaxation time (abbreviated as IVR)
early filling
diastasis
atrial contraction

Influences

The E/A ratio is the ratio of the early (E) to late (A) ventricular filling velocities. In a healthy heart, the E velocity is greater than the A velocity. In certain conditions, especially ventricular hypertrophy, and with aging, the left ventricular wall can become stiff, increasing the back pressure as it fills, which slows the early (E) filling velocity, thus lowering the E/A ratio.^{[ citation needed ]}

The reversal of the E/A ratio ('A' velocity becomes greater than 'E' velocity) is often accepted as a clinical marker of diastolic dysfunction, in which the left ventricular wall becomes so stiff as to impair proper filling, which can lead to diastolic heart failure. This can occur, for instance, with longstanding untreated hypertension.^{[ citation needed ]}

The late phase is dependent upon atrial contraction and is therefore absent in patients with atrial fibrillation due to the lack of forceful atrial contraction, making the E/A ratio very large.^{[ citation needed ]}

The E/A ratio is a first generation test for diastolic performance of the heart.^{[ citation needed ]}

There are a number of factors that influence ventricular filling during each of these phases, but the main factor is the driving gradient between the atrial and ventricular pressure.^{[ citation needed ]}

The E/A ratio is measured by placing a pulsed wave Doppler across the mitral valve and measuring the velocities across the valve. Hence, there are other names for the test, such as transmitral velocity profile, transmitral flow profile, transmitral flow velocity profile or transmitral Doppler waveforms.^{[ citation needed ]}

Pulsed wave Doppler allows measurement of velocities at a specific point but has the disadvantage of aliasing, so it often has to be adjusted (baseline shifted) to best fit the individual point of measurement.^{[ citation needed ]}

Isovolumic relaxation time (abbreviated as IVRT) is measured as the time between the closure of the aortic valve and the opening of the mitral valve.

The normal transmitral flow profile has two peaks – an E and an A wave.^{[ citation needed ]}

The E peak arises due to early diastolic filling. Most filling (70-85%) of the ventricle occurs during this phase. The A peak arises due to atrial contraction, forcing approximately 15-20% of stroke volume into the ventricle. The deceleration time is the time taken from the maximum E point to baseline. In adults, it is normally less than 220 milliseconds.^{[ citation needed ]}

Interpretation

From this, a number of grades of diastolic function can be determined:^{[ citation needed ]}

Normal diastolic function (E > A)
Impaired relaxation (E:A reversal i.e., E is < A)
Pseudonormal (E:A ratio appears normal)
Restrictive filling (E:A ratio often > 2)

Pseudonormalisation shows a transmitral profile that appears normal. However, with the use of pulmonary vein pulsed wave Doppler, it can be shown that the relaxation pattern is abnormal (systolic blunting, a decrease in the height of the S wave). In addition, performance of a Valsalva manoeuvre will result in unmasking of the pseudonormal state.^{[ citation needed ]}

Disadvantages

Cursor position is important - if the PW sample window is incorrect, it produces artifact. The cursor should be placed at the level of the open leaflets in diastole.
Presence of mitral valve abnormalities, e.g., mitral stenosis alters the pressure gradients and changes loading conditions of the left ventricle.
Presence of aortic insufficiency - aortic incompetence results in a rapid rise in the left ventricular diastolic pressure, limiting the gradient across the mitral valve during diastole.
Heart rate and rhythm - loss of a normal atrial rhythm (e.g., atrial fibrillation causes loss of the A wave). The height of the E wave becomes dependent on the length of the cardiac cycle (variable) rather than a measure of diastolic function. Similarly, pacing and tachycardia result in alterations, whereas bradycardia increases the E/A ratio.

These are some of the disadvantages of first generation testing methods.^{[ citation needed ]}

Diastolic function should be assessed normally in addition to the twenty views. It is important in establishing a number of cardiac conditions, e.g., pericardial tamponade (where E/A ratios across the tricuspid valve are often more important), restrictive cardiomyopathy vs. constrictive pericarditis.

Related Research Articles

A heart valve is a biological one-way valve that allows blood to flow in one direction through the chambers of the heart. Four valves are usually present in a mammalian heart and together they determine the pathway of blood flow through the heart. A heart valve opens or closes according to differential blood pressure on each side.

Heart sounds are the noises generated by the beating heart and the resultant flow of blood through it. Specifically, the sounds reflect the turbulence created when the heart valves snap shut. In cardiac auscultation, an examiner may use a stethoscope to listen for these unique and distinct sounds that provide important auditory data regarding the condition of the heart.

The mitral valve, also known as the bicuspid valve or left atrioventricular valve, is one of the four heart valves. It has two cusps or flaps and lies between the left atrium and the left ventricle of the heart. The heart valves are all one-way valves allowing blood flow in just one direction. The mitral valve and the tricuspid valve are known as the atrioventricular valves because they lie between the atria and the ventricles.

Systole is the part of the cardiac cycle during which some chambers of the heart contract after refilling with blood.

A ventricle is one of two large chambers located toward the bottom of the heart that collect and expel blood towards the peripheral beds within the body and lungs. The blood pumped by a ventricle is supplied by an atrium, an adjacent chamber in the upper heart that is smaller than a ventricle. Interventricular means between the ventricles, while intraventricular means within one ventricle.

Afterload is the pressure that the heart must work against to eject blood during systole. Afterload is proportional to the average arterial pressure. As aortic and pulmonary pressures increase, the afterload increases on the left and right ventricles respectively. Afterload changes to adapt to the continually changing demands on an animal's cardiovascular system. Afterload is proportional to mean systolic blood pressure and is measured in millimeters of mercury.

Diastole is the relaxed phase of the cardiac cycle when the chambers of the heart are refilling with blood. The contrasting phase is systole when the heart chambers are contracting. Atrial diastole is the relaxing of the atria, and ventricular diastole the relaxing of the ventricles.

Mitral stenosis is a valvular heart disease characterized by the narrowing of the opening of the mitral valve of the heart. It is almost always caused by rheumatic valvular heart disease. Normally, the mitral valve is about 5 cm² during diastole. Any decrease in area below 2 cm² causes mitral stenosis. Early diagnosis of mitral stenosis in pregnancy is very important as the heart cannot tolerate increased cardiac output demand as in the case of exercise and pregnancy. Atrial fibrillation is a common complication of resulting left atrial enlargement, which can lead to systemic thromboembolic complications such as stroke.

Aortic regurgitation (AR), also known as aortic insufficiency (AI), is the leaking of the aortic valve of the heart that causes blood to flow in the reverse direction during ventricular diastole, from the aorta into the left ventricle. As a consequence, the cardiac muscle is forced to work harder than normal.

Mitral regurgitation(MR), also known as mitral insufficiency or mitral incompetence, is a form of valvular heart disease in which the mitral valve is insufficient and does not close properly when the heart pumps out blood. It is the abnormal leaking of blood backwards – regurgitation from the left ventricle, through the mitral valve, into the left atrium, when the left ventricle contracts. Mitral regurgitation is the most common form of valvular heart disease.

A transthoracic echocardiogram (TTE) is the most common type of echocardiogram, which is a still or moving image of the internal parts of the heart using ultrasound. In this case, the probe is placed on the chest or abdomen of the subject to get various views of the heart. It is used as a non-invasive assessment of the overall health of the heart, including a patient's heart valves and degree of heart muscle contraction. The images are displayed on a monitor for real-time viewing and then recorded.

The cardiac cycle is the performance of the human heart from the beginning of one heartbeat to the beginning of the next. It consists of two periods: one during which the heart muscle relaxes and refills with blood, called diastole, following a period of robust contraction and pumping of blood, called systole. After emptying, the heart relaxes and expands to receive another influx of blood returning from the lungs and other systems of the body, before again contracting to pump blood to the lungs and those systems. A normally performing heart must be fully expanded before it can efficiently pump again. Assuming a healthy heart and a typical rate of 70 to 75 beats per minute, each cardiac cycle, or heartbeat, takes about 0.8 second to complete the cycle.

A pressure–volume diagram is used to describe corresponding changes in volume and pressure in a system. They are commonly used in thermodynamics, cardiovascular physiology, and respiratory physiology.

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In cardiac physiology, isometric contraction is an event occurring in early systole during which the ventricles contract with no corresponding volume change. This short-lasting portion of the cardiac cycle takes place while all heart valves are closed. The inverse operation is isovolumetric relaxation diastole with all valves optimally closed.

A plot of a system's pressure versus volume has long been used to measure the work done by the system and its efficiency. This analysis can be applied to heat engines and pumps, including the heart. A considerable amount of information on cardiac performance can be determined from the pressure vs. volume plot. A number of methods have been determined for measuring PV-loop values experimentally.

$<span class="mw-page-title-main">Heart failure with preserved ejection fraction</span> Medical condition$

Heart failure with preserved ejection fraction (HFpEF) is a form of heart failure in which the ejection fraction – the percentage of the volume of blood ejected from the left ventricle with each heartbeat divided by the volume of blood when the left ventricle is maximally filled – is normal, defined as greater than 50%; this may be measured by echocardiography or cardiac catheterization. Approximately half of people with heart failure have preserved ejection fraction, while the other half have a reduction in ejection fraction, called heart failure with reduced ejection fraction (HFrEF).

Tissue Doppler echocardiography (TDE) is a medical ultrasound technology, specifically a form of echocardiography that measures the velocity of the heart muscle (myocardium) through the phases of one or more heartbeats by the Doppler effect of the reflected ultrasound. The technique is the same as for flow Doppler echocardiography measuring flow velocities. Tissue signals, however, have higher amplitude and lower velocities, and the signals are extracted by using different filter and gain settings. The terms tissue Doppler imaging (TDI) and tissue velocity imaging (TVI) are usually synonymous with TDE because echocardiography is the main use of tissue Doppler.

In clinical cardiology the term "diastolic function" is most commonly referred as how the heart fills. Parallel to "diastolic function", the term "systolic function" is usually referenced in terms of the left ventricular ejection fraction (LVEF), which is the ratio of stroke volume and end-diastolic volume. Due to the epidemic of heart failure, particularly the cases determined as diastolic heart failure, it is increasingly urgent and crucial to understand the meaning of “diastolic function”. Unlike "systolic function", which can be simply evaluated by LVEF, there are no established dimensionless parameters for "diastolic function" assessment. Hence to further study "diastolic function" the complicated and speculative physiology must be taken into consideration.

The main pathophysiology of heart failure is a reduction in the efficiency of the heart muscle, through damage or overloading. As such, it can be caused by a wide number of conditions, including myocardial infarction, hypertension and cardiac amyloidosis. Over time these increases in workload will produce changes to the heart itself:

References

↑ "Tutorial 8 – Assessment of LV diastolic function and filling pressures – ICU Sonography".
1 2 Galderisi, M (2005). "Diastolic dysfunction and diastolic heart failure: diagnostic, prognostic and therapeutic aspects". Cardiovascular Ultrasound. 3: 9. doi: 10.1186/1476-7120-3-9 . PMC 1087861 . PMID 15807887.

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[1] "Tutorial 8 – Assessment of LV diastolic function and filling pressures – ICU Sonography".

[Galderisi-2] 1 2 Galderisi, M (2005). "Diastolic dysfunction and diastolic heart failure: diagnostic, prognostic and therapeutic aspects". Cardiovascular Ultrasound. 3: 9. doi: 10.1186/1476-7120-3-9 . PMC 1087861 . PMID 15807887.

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