A normal aortic valve is comprised of three semilunar cusps that attach to the aortic wall. Aortic regurgitation (AR), also known as aortic insufficiency, is a form of valvular heart disease that allows for the retrograde flow of blood back into the left ventricle. Chronic AR was initially described by Corrigan in the 19th century by observing syphilitic patients. In AR, retrograde blood flow from the aorta into the left ventricle occurs in ventricular diastole and, with time, will result in stress of the left ventricle. The clinical presentation and management of AR depend on the acuity of the regurgitant flow. This activity will review the evaluation and management of aortic regurgitation and explains the role of the interprofessional team in managing patients with this condition.
Identify the etiology of aortic regurgitation.
Review the appropriate evaluation of aortic regurgitation.
Describe the management options available for aortic regurgitation.
Outline the interprofessional team strategies for improving care coordination and communication to advance aortic regurgitation management thereby improving outcomes.
Aortic regurgitation (AR), also known as aortic insufficiency, is a form of valvular heart disease in which the integrity of the aortic valve is compromised and leads to inadequate closure of the valve leaflets. A normal aortic valve is comprised of three semilunar cusps that attach to the aortic wall. Loss of function occurs when the valves themselves become diseased or if there is aortic root involvement. In AR, there is retrograde blood flow from the aorta into the left ventricle which occurs in diastole in the cardiac cycle. Chronic AR was initially described by Corrigan in 1832 in syphillitic patients who suffered from aortic root dilation. The clinical presentation of AR depends on it's acuity of onset.
As described above, aortic regurgitation may occur due to dysfunction linked to the aortic valve leaflets, aortic root, annulus, or ascending aorta. Typical etiologies responsible for acute AR include infective endocarditis, traumatic and non-traumatic rupture of the ascending aorta with aortic cusp prolapse, iatrogenic AR due to percutaneous aortic balloon valvuloplasty, prosthetic valve dysfunction, and perivalvular leak or dehiscence of a prosthetic valve . Atypical causes of AR also include certain medications. For example, patients taking dopamine agonists such as bromocriptine (or other ergot alkaloids) have increased cardiac contraction, and increased stress is placed on the aortic valve, this is known to cause valvular fibrosis thereby putting them at higher risk for complications such as AR.
The etiologies responsible for chronic AR may be extensive, they include rheumatic heart disease (the most common cause in the developing world ), infective endocarditis, myxomatous valve degeneration, congenital valve abnormalities (most commonly a bicuspid aortic valve while unicuspid and quadricuspid have also been reported), senile valvular calcifications, age-related dilatation of the aorta, ectasia of the aortic annulus, aortic dissection, aortitis/aortic root dilatation secondary to syphilis or giant cell arteritis, trauma, systemic hypertension, drug-induced valvulopathy, Whipple disease, osteogenesis imperfecta, Crohn disease .
Other rheumatologic processes involved are antiphospholipid syndrome, systemic lupus erythematosus, rheumatoid arthritis, ankylosing spondylitis, Reiter syndrome, psoriatic arthritis, relapsing polychondritis, Takayasu vasculitis, Marfan and Ehler-Danlos syndromes, Behcet disease .
Correlations have also been made between AR and Turner Syndrome. In one study of 253 patients with Turner syndrome from 7 to 67 years of age, AR was trivial, mild, and moderate to severe in 55%, 30%, and nearly 15% of the study population, respectively.
The Framingham Heart Study was a prospective epidemiologic study that began in 1948 as a means of determining risk factors for coronary heart disease. The original study cohort included 5,209 men and women from 28 to 62 years of age. In this patient cohort, AR had a prevalence of 4.9%, and 0.5% of patients were found to have moderate or greater severity AR. The incidence and severity of AR increased with age, peaked in the fourth to sixth decades of life, occurs in 2% of people older than 70 years of age, and has been seen in 13% of men and 8.5% of women in the Framingham Offspring Study analyses. The presentation of AR globally varies between industrialized countries and developing countries. AR can often be seen in industrialized countries more commonly in older patients as a consequence of degenerative, insidious disease processes and linked to patients' comorbidities that put them at risk for developing AR. In developing countries, AR can present more commonly in younger patients with rapid onset, and rheumatic heart disease and infective endocarditis are two major contributors to AR development. Figures on the frequency of AR globally differ based on sex and geographic location.
Acute Aortic Regurgitation
In acute AR, the retrograde backflow of blood results in a quick rise in the left ventricular end-diastolic volume. The acute increase in preload and afterload do not allow the time for the left ventricle to acclimate to the rapid increase in volume during diastole, and this also results in a sharp rise in left ventricular diastolic pressure. When the left ventricular diastolic pressure rises above the level of left atrial pressure, premature mitral valve closure and mitral regurgitation can be seen. Additionally, there will be increases in left atrial pressure and pulmonary capillary wedge pressure that cause pulmonary edema. Compensatory tachycardia may occur to blunt the decline in anterograde stroke volume, and concentric hypertrophy with increased wall thickness can occur.
Chronic Aortic Regurgitation
In chronic AR, the left ventricle compensates for the diastolic regurgitation of blood from the aorta into the left ventricle by remodeling of the left ventricle via eccentric hypertrophy of the cardiomyocytes and left ventricular dilatation to allow for an increase in left ventricular stroke volume and a lesser increase in wall thickness than that which would be seen in acute AR. However, the left end-diastolic volume and pressure rise to a high degree such that the sarcomeres can become maximally stretched, left ventricle remodeling and compensation mechanisms fail, and interstitial fibrosis and a drop in left ventricular compliance occur. The composite result of these changes is a decline in the initially compensated and elevated left ventricular stroke volume.
History and Physical
A thorough history and physical exam are essential parts of the diagnostic process. Upon history taking, patients with acute AR may complain of cough, palpitations, dyspnea on exertion, and chest pain. However, patients with chronic aortic regurgitation can often be asymptomatic for a lengthy amount of time before they exhibit exertional dyspnea, orthopnea, palpitations, paroxysmal nocturnal dyspnea, syncope, and/or chest pain.
In general, aortic regurgitation diastolic murmurs are accentuated by maneuvers that increase afterload such as handgrip. Patients with acute AR can present as if they are experiencing a rapid onset of cardiogenic shock. They appear ill, hypotensive, and tachycardic. They can present with a normal or mildly elevated pulse pressure, normal apical impulse, diminished S1 from early mitral valve closure or an S3.
Patients with chronic AR will have a widened pulse pressure, may likely have a laterally and inferiorly displaced apical impulse, a high-frequency decrescendo diastolic murmur best heard at the 3rd or 4th intercostal space at the left sternal border, Austin Flint murmur, diminished S1, soft S2. If the pulse pressure is noticed to become more narrow and the patient has an S3, this may be a sign the patient has developed heart failure.
Listed below are various eponymous signs that have been described and associated with AR, but these may or may not always be seen .
Austin Flint murmur: This is believed to occur due to the regurgitant jet of the aortic regurgitation causing premature closing of the mitral valve. This mimics a functional mitral stenosis and is described as a low-pitched and rumbling mid to late diastolic or presystolic mitral murmur best heard at the apex
Pulsus bisferiens: a biphasic pulse with two systolic peaks seen on pressure tracings
Corrigan sign: a bounding pulse in large arteries such as the carotids that expands and suddenly collapses and empties between beats
de Musset sign: head nodding with every heartbeat
Muller sign: systolic pulsation of the uvula
Quincke sign: repeatedly alternating blushing and blanching of capillaries in the nail folds upon palpation
Traube's sign: pistol shot sounds heard on the femoral artery upon compression of the artery
Waterhammer Pulse: Peripheral arterial pulses are rapidly dissipated or "bounding". This finding can be accentuated by raising the extremities.
The classification of aortic regurgitation, based on the 2017 American Society of Echocardiography guidelines, is as follows:
In type I AR, the valve leaflets are functioning normally, but there is aortic dilation or perforation of the cusp(s). In type Ia AR, the sinotubular junction and ascending aorta are enlarged. In type Ib AR, the sinuses of Valsalva and the sinotubular junction are dilated. In type Ic AR, the aortic annulus is dilated. In type Id AR, aortic cusp perforation is present.
Type II AR is due to excessive leaflet tissue or commissural disruption that results in aortic cusp prolapse.
Type III AR is due to various processes that result in restriction of the motion of the aortic leaflets.
Chronic AR is classified into four different stages:
Stage A: patients at risk for AR
Stage B: patients with progressive mild to moderate AR
Stage C: patients with asymptomatic and severe AR
Stage C1 patients have a left ventricular ejection fraction >50% and mild to moderate left ventricular dilation with an end-systolic dimension <50 mm).
Stage C2 patients have a left ventricular ejection fraction <50% and severe left ventricular dilation with an end-systolic dimension >50 mm or an indexed left ventricular end-systolic dimension >25 mm/m2.
Stage D: patients with symptomatic and severe AR
An electrocardiogram would show nonspecific ST-T wave changes, signs of left ventricular hypertrophy, or ST elevations or depressions if a myocardial infarction were associated with the patient's AR. A chest x-ray can show signs of pulmonary congestion or a widened mediastinum suggestive of aortic dissection.
However, the primary diagnostic test of choice for diagnosing AR is echocardiography, as it will provide a wealth of information about the aortic valve leaflets and surrounding apparatus, aorta, and the left ventricle. Echocardiography can identify the underlying cause of AR, the severity of regurgitant blood flow, and estimates of left ventricular size and systolic function. Transthoracic echocardiography assessment with color Doppler is necessary to characterize the regurgitant jet. Transesophageal echocardiography should be performed in cases with concern for aortic dissection or infective endocarditis. Some various echocardiographic measurements with different techniques combined, as mentioned below but not limited to this list, can help in accurately defining disease severity:
Acute Aortic Regurgitation
M-mode echocardiography showing early deceleration time on the mitral flow velocity curve and early mitral valve closure are indicative of elevated left ventricular end-diastolic pressure.
An aortic velocity curve with a short half-time of <300 milliseconds indicates that there is rapid equilibration of the left ventricular and aortic diastolic pressures.
Chronic Aortic Regurgitation
Chronic AR is broked down in stages B, C, and D using the following valve hemodynamic information: jet width related to the left ventricular outflow tract, regurgitant blood volume (ml/beat), the regurgitant fraction (%), vena contracta measurement of the effective regurgitant orifice (cm), and effective regurgitant orifice area measurement (cm^2).
In AR patients with little to symptoms, exercise stress testing can assess the presence of symptoms and their functional capacity. CT imaging, cardiac MRI, and coronary angiography may be useful in certain instances as well. CT imaging can help evaluate aortic disease. Cardiac MRI has a class I indication in stage B, C, and D moderate to severe chronic AR patients when suboptimal information is obtained from echocardiography, or the information obtained is discordant with clinical information. Cardiac catheterization can be used when noninvasive diagnostic modalities provide insufficient information, or are unavailable or contraindicated. If no cardiac MRI is available or is contraindicated due to the presence of implanted devices, the catheterization would help to understand the severity of AR.
Treatment / Management
Acute Aortic Regurgitation
Hypertension can be controlled with angiotensin-converting enzyme inhibitors, angiotensin receptor blockers, or dihydropyridine calcium channel blockers. Beta-blockers are recommended for managing aortic dissection, but they should be avoided in patients with severe AR as they can increase diastolic filling time and thereby allow for increased regurgitant blood flow. They block the compensatory tachycardia that is necessary to maintain adequate cardiac output. Antibiotics should be given for treating infective endocarditis; these patients should have their antibiotics tailored to the causative pathogens noted on blood cultures, and echocardiographic information should be reviewed to determine the need for any surgical interventions in addition to aortic valve replacement (AVR). Patients with acute AR due to infective endocarditis, aortic dissection, or trauma with hemodynamic instability require urgent surgical intervention.
Chronic Aortic regurgitation
Medical therapy in chronic depends on the stage of the AR. Angiotensin-converting enzyme inhibitors, angiotensin receptor blockers, or dihydropyridine calcium channel blockers have a class I recommendation for managing hypertension in stage B and C AR patients. For stage C2 and D AR patients with symptoms and/or left ventricular dysfunction who cannot undergo surgery due to their comorbidities, angiotensin-converting enzyme inhibitors, angiotensin receptor blockers, and beta-blockers have a class IIa recommendation as reasonable options.
Based on the 2014 valvular heart disease guidelines, AVR has a class I recommendation for patients with stage D AR, stage C2 AR with an ejection fraction <50%, or asymptomatic stage C AR but requiring cardiac surgery for other indications. Patients with stage C2 AR with an ejection fraction greater than or equal to 50% and left ventricular end-systolic dimension >50 mm have a class IIa recommendation for AVR. Patients with stage C AR with an ejection fraction greater than or equal to 50%, left ventricular end-diastolic dimension >65 mm, and low surgical risk have a class IIb recommendation for AVR. Patients with stage C AR with left ventricular end-systolic dimension >50 mm have a class IIa recommendation for AVR. Patients with stage C AR with an ejection fraction greater than or equal to 50%, left ventricular end-systolic dimension less than or equal to 50 mm, and left ventricular end-diastolic dimension less than or equal to 65 mm do not need AVR acutely. These patients, along with stage B AR patients not requiring cardiac surgery for another indication, should be watched carefully with periodic monitoring. However, stage B AR patients who need cardiac surgery for other indications have a class IIa recommendation for AVR.
AVR is not recommended in patients with a left ventricular ejection fraction <35% and left ventricular end-diastolic dimension ≥70 mm due to poor postoperative outcomes. While intervening in patients with symptoms or a decline in left ventricular ejection fraction has been validated, further work is needed to determine the optimal time to consider surgical consultation patients with asymptomatic AR, and if earlier intervention would benefit patients and provide good postoperative outcomes.
One study evaluating transcatheter aortic valve replacement (TAVR) and aortic valve repair in patients with isolated AR showed the following: (1) patients with bicuspid aortic valves had open surgical AVR more commonly than those with tricuspid aortic valves, but aortic root dilatation in either group and cusp prolapse in the bicuspid group favored aortic valve repair and (2) patients with tricuspid aortic valve cusp prolapse and restriction/retraction had an AVR. This study highlights the notion that underlying etiologies and pathophysiological mechanisms affect clinical decision making on the types of surgical interventions considered for different patients with AR.
Aortic valve repair has also been mentioned as an option for AR. Those who consider aortic vale repair hope to preserve the aortic valve. Some report that aortic valve repair, either done alone or in conjunction with aortic root surgery, is a safe option with satisfactory postoperative outcomes, such as good long term survival and avoidance of repeat operations. However, postoperative concerns are higher in those who undergo aortic valve repair vs. those who undergo AVR. For example, higher re-operation rates in patients with AR who underwent aortic repair than those who underwent AVR have been reported, and this shows that additional studies are needed to further validate aortic valve repair as a safe and effective option.
It is important to consider additional and alternative conditions that can be mistaken or overlooked when diagnosing AR. AR has been reported to be mistaken for sepsis, pneumonia, or nonvalvular heart disease. Additionally, recognizing the presence of AR in conjunction with other coexisting conditions is also important. The retrograde flow of blood in AR may result in congestive heart failure or be a consequence of aortic disease such as aortic dissection, so these must be recognized as well as this can impact clinical decision making. Pulmonary regurgitation can be considered as it too can present with a diastolic murmur, which can be seen with AR. One can differentiate between the two using differences in auscultation findings. A diastolic murmur of AR would increase with expiration, while a diastolic murmur of pulmonary regurgitation with underlying pulmonary hypertension would have a loud P2 and increase with inspiration since it is a right-sided heart murmur. Coronary heart disease resulting in myocardial infarction and/or congestive heart failure must also be considered in the differential.
Prognosis is dependent on the onset of symptoms and the progressions of the patient's AR. Patients with asymptomatic aortic regurgitation have a good outlook unless their disease progresses acutely. Patients with severe AR and preserved left ventricular ejection fraction who undergo prompt aortic valve replacement tend to have good long term outcomes. However, these patients need to be monitored carefully after valve replacement in case they require additional procedures, develop heart failure, or other negative outcomes. Those who develop decreased left ventricular ejection fraction and worsening symptoms have poorer prognoses as they would be deemed unable to undergo aortic valve replacement based on current guideline recommendations.
Clinicians should be wary of multiple complications that can occur in the management of AR. Surgical management of AR is the gold standard for correcting aortic regurgitation, and the implementation of TAVR is influencing post-surgical outcomes. Initially, TAVR was contraindicated in pure native AR due to the lack of aortic valve annular calcification and difficulty with anchoring the implanted valves. Based on a multicenter registry developed in 2017 using 331 patients with AR to evaluate early generation vs. newer generation valve devices for TAVR in this population, TAVR was overall associated with relatively high rates of procedural complications; non-statistically significant post-procedural outcomes of conversion to conventional surgery, coronary obstruction, aortic root injury, and new permanent pacemaker implantation were reported more in the cohort of patients with newer generation devices. The other reported complications reported overall were post-procedural AR, re-intervention, and need for a 2nd valve implantation, stroke, major or life-threatening bleeding, major vascular complications, and acute kidney injury. Although this study shows some improvements in post-procedural outcomes when using TAVR in pure native AR, further studies are needed to if additional improvements in postoperative outcomes are possible that would warrant incorporating TAVR into current guidelines.
Deterrence and Patient Education
Patients should be educated on the symptoms that can be related to their aortic regurgitation. Patients who have note undergone surgery yet should be educated to follow up for serial echocardiograms depending on the severity of their AR. Patients with mild AR echocardiography can be performed every three to five years. Patients with moderate AR should have echocardiography performed every one to two years. Patients with severe AR should have echocardiography performed every six to twelve months or more frequently if left ventricular dilatation is progressively worsening. Patients should be told to follow up after surgery in approximately six weeks to three months to have echocardiography performed.
Enhancing Healthcare Team Outcomes
Patients should be carefully evaluated by primary care doctors, cardiologists, nurses, and other healthcare personnel involved in patients' care to identify symptoms and underlying comorbidities that could be the contributing etiologies for the development of aortic regurgitation or post-interventional risk factors for morbidity and mortality. The difficulty in diagnosing the severity of AR is dependent on the use of various analytical methods via echocardiography by physicians. Cardiologists should establish appropriate follow up with patients based on the presence or lack of symptoms and involve cardiothoracic surgeons or interventional cardiologists for surgical or transcutaneous interventions, respectively, as soon as possible.
(Click Image to Enlarge)
Parasternal long axis echocardiographic view of aortic insufficiency (yellow arrows) striking the anterior mitral leaflet in an 85 year old woman with concomitant aortic stenosis presenting with shortness of breath.
Contributed by Amgad N. Makaryus MD
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