The aortic valve sits at the junction of the left ventricular outflow tract (LVOT) and the ascending aorta, within the aortic root. Understanding its structure is essential because AR can arise from disease of the valve cusps or the root.

• Three semilunar cusps (right coronary, left coronary, and non-coronary cusps) — named for the coronary ostia that arise from the corresponding sinuses of Valsalva above them.
• Annulus: The fibrous ring to which the cusps attach; dilation of this ring → cusps cannot coapt → AR.
• Sinuses of Valsalva: Three outpouchings of the aortic root behind each cusp; they create space for cusp opening and house the coronary ostia.
• Sinotubular junction (STJ): The transition from the sinuses to the tubular ascending aorta; dilation here also prevents cusp coaptation.
• Commissures: Where adjacent cusps meet; they are suspended at the level of the STJ.

• During systole: LV pressure exceeds aortic pressure → cusps open → blood ejected into aorta.
• During diastole: Aortic pressure exceeds LV pressure → cusps fall back and coapt, sealing the outflow tract → no backward leak. The coronary arteries fill primarily in diastole because the cusps are closed and diastolic aortic pressure drives blood into the coronary ostia.

Why does diastolic coronary perfusion matter in AR? In AR, diastolic aortic pressure drops (blood leaks back into the LV instead of staying in the aorta), reducing the driving pressure for coronary filling. This is a key mechanism of angina in AR.

When the aortic root dilates, the annulus and STJ stretch apart → the cusps can no longer meet in the middle during diastole → central regurgitant jet.

1. Volume overload: During diastole, blood leaks back from the aorta into the LV. The LV must now handle normal venous return (preload) PLUS the regurgitant volume.
2. Eccentric LV hypertrophy (dilation): To accommodate the increased end-diastolic volume (EDV), the LV dilates. New sarcomeres are laid down in series (lengthening myocytes) → eccentric hypertrophy. This is in contrast to aortic stenosis, where concentric hypertrophy occurs (sarcomeres in parallel).
3. Increased stroke volume (SV): By the Frank-Starling mechanism, the dilated LV ejects a much larger total SV (up to 2–3× normal ^[2]) to maintain forward cardiac output despite the regurgitant fraction being "wasted."
4. LV EDV is increased but LV EDP (end-diastolic pressure) remains relatively normal initially — the LV is compliant because it has had time to remodel ^[2].
5. Widened pulse pressure: The large total SV raises systolic BP, while the regurgitant leak lowers diastolic BP → characteristic wide pulse pressure → all the eponymous peripheral signs (Corrigan's, de Musset's, Quincke's, etc.) ^[1][2].
6. The "largest heart in cardiology": Chronic severe AR produces the most dilated LV of any valvular lesion (the so-called cor bovinum — "ox heart").

Why is the patient asymptomatic for so long? Because the dilated, compliant LV maintains a normal forward cardiac output and normal filling pressures for years — even decades. Asymptomatic patients with severe AR develop symptoms or LV dysfunction at only ~5% per year ^[2].

1. Failing compliance: Eventually, the LV can no longer dilate without raising filling pressures. LV EDP rises → transmitted backward → pulmonary congestion → dyspnoea.
2. Reduced forward cardiac output: The LV begins to fail → ↓CO → fatigue, exercise intolerance.
3. Further decline is rapid: Once symptomatic or once LVEF falls, the mortality rate is 10–20% per year without intervention ^[2].

AR causes angina through two simultaneous mechanisms ^[1][2]:

Angina in AR is characteristically worse at night ^[1]. Why? During sleep, heart rate drops → longer diastole → more time for regurgitation per beat → more volume overload, lower diastolic BP, and worse coronary perfusion.

In acute AR (e.g., aortic dissection, IE, trauma), the LV is of normal size and compliance. A sudden large regurgitant volume floods a non-dilated, non-compliant LV → dramatic rise in LV end-diastolic pressure → immediately transmitted to the pulmonary veins → acute pulmonary oedema.

Key differences from chronic AR:

• Acute AR: Sudden onset, non-dilated LV, presents as acute pulmonary oedema / cardiogenic shock.
• Chronic AR: Gradual onset, compensatory LV dilation, long asymptomatic phase before decompensation.

• Type 1 — Normal cusp motion, but defective coaptation due to root/annular dilation: e.g., Marfan, HTN, aortitis.
• Type 2 — Cusp prolapse (excessive motion): e.g., bicuspid AV with prolapsing raphe, myxomatous degeneration, IE with flail cusp.
• Type 3 — Cusp restriction (reduced motion): e.g., rheumatic fibrosis/retraction, calcific degeneration.

ERO = effective regurgitant orifice

Why does pressure half-time shorten in severe AR? Pressure half-time (PHT) measures how quickly the aortic-LV diastolic pressure gradient decays. In severe AR, there is a large regurgitant orifice → blood pours back into the LV rapidly → LV pressure rises quickly → the gradient between aorta and LV disappears fast → short PHT (< 200 ms). In mild AR, only a trickle leaks back → the gradient is maintained for longer → long PHT (> 500 ms).

What is ERO? The effective regurgitant orifice area is the cross-sectional area of the "hole" through which blood regurgitates. It is calculated using the PISA (proximal isovelocity surface area) method on Doppler echocardiography. A larger ERO = a bigger leak = more severe AR.

ECG: LVH ± strain ^[1][2]

The ECG is not diagnostic for AR — it shows the consequences of AR on the LV. It is a baseline investigation that provides supporting evidence and helps exclude other pathology (e.g., AF, ischaemia).

CXR: cardiomegaly ^[1], dilated aortic arch ^[2]

The mid-portion of the ascending aorta is difficult to visualise by echocardiography ^[1] — this is why CXR (and more importantly CT) is essential for assessing aortic root and ascending aortic dimensions when root dilation is the mechanism of AR.

CT thorax ^[1] — Essential when echocardiography cannot fully visualise the aorta.

CT vs. MRI for aortic assessment: Both are excellent. CT is faster, more widely available, and preferred in acute settings (dissection). MRI avoids radiation and iodinated contrast, making it preferred for serial follow-up of young patients (e.g., Marfan). Both are superior to echo for the mid-ascending aorta.

CMR is increasingly used when echo findings are equivocal or discordant:

Coronary angiogram ^[1]

Why is coronary angiography needed before valve surgery? Patients with severe AR, especially those with risk factors for atherosclerosis, frequently have coexistent CAD. If you replace the valve but leave a 90% LAD stenosis untreated, the patient may have a perioperative MI. Therefore, coronary angiography (or CT coronary angiography in lower-risk patients) is a routine part of the pre-operative workup ^[1].

Blood: VDRL, blood culture (IE) ^[2]

Vasodilators for HT: ACEI/ARB/CCB ^[1]

Why does afterload reduction help in AR? Think of it from first principles: in AR, blood can either go forward into the systemic circulation or backward through the leaky valve into the LV. This is a competition between two pathways. If you reduce systemic vascular resistance (afterload), you make it "easier" for blood to go forward → proportionally less blood regurgitates backward → ↓regurgitant fraction → ↓LV volume overload.

Diuretics ^[1]

Diuretics provide symptomatic relief by reducing pulmonary and systemic congestion, but they do not alter the natural history of AR. They are a bridge — if the patient needs diuretics for AR-related HF, they likely need surgery.

ACEI/ARB + BB for symptomatic or LV dysfunction if surgery is not contemplated ^[2]

Unlike the mitral valve (where repair is often preferred and technically feasible), the aortic valve is a much more demanding structure to repair. The three cusps must coapt perfectly under high diastolic pressures, and any imperfection → residual AR. However, in select centres with expertise, aortic valve repair is increasingly performed for:

• Bicuspid aortic valve with cusp prolapse
• Root dilation with normal cusps (valve-sparing root replacement — David or Yacoob procedures)
• Cusp perforation from IE (pericardial patch repair)

For the majority of patients, aortic valve replacement remains the standard surgical treatment ^[2].

Approach: mid-sternotomy (traditional), hemisternotomy, thoracotomy (smaller incisions) ^[2]

Technique: homograft (from external), PV autotransplant ± root replacement and CABG ^[2]

The choice of valve prosthesis is one of the most important shared decisions in valve surgery:

The Ross procedure in detail: "Ross" = pulmonary valve autotransplant. The patient's pulmonary valve (which is under lower pressure and less prone to degeneration) is moved to the aortic position. A homograft then replaces the pulmonary valve. Advantages: living tissue that can grow (ideal for children), no anticoagulation, excellent haemodynamics. Disadvantages: technically demanding, two valves at risk instead of one, potential for autograft dilation in the aortic position.

When the aortic root is dilated (Marfan, bicuspid aortopathy, etc.), replacing the valve alone is insufficient — you must also replace the diseased aorta.

Transcatheter AVR CANNOT be done (relies on stenotic AV to hold prosthetic valve in place) ^[2]

This is a very important point. TAVI/TAVR works by deploying a stent-mounted valve inside the calcified native aortic valve. The calcified, stenotic valve acts as an anchor — the new valve is wedged into it. In pure AR without significant stenosis/calcification, there is nothing to anchor the transcatheter valve against → it will migrate or embolise. Therefore, TAVI is contraindicated in isolated AR.

Emerging evidence (2023–2025) from newer-generation devices (e.g., JenaValve, J-Valve) shows promise for TAVI in pure AR using clipping mechanisms that grasp the native leaflets, but this is not yet standard practice and remains investigational or limited to selected centres.

Outcome and Cx: mortality 1–5%, complications ~5% ^[2]

General: CVA, bleeding, infection, multiorgan failure. Specific: heart block, heart failure, MI ^[2]

This is the most important and most common complication of severe chronic AR. It is the final common pathway of the disease.

Pathophysiology from first principles:

• Chronic volume overload → LV dilates (eccentric hypertrophy, sarcomeres added in series) → initially compensated (normal LVEDP, ↑SV via Frank-Starling) ^[2].
• Over years, the myocardium exhausts its compensatory reserve → contractile dysfunction develops → LVEF falls below 50% ^[1].
• As the LV fails: ↑LVEDP → transmitted backward to LA → pulmonary veins → pulmonary congestion (dyspnoea, orthopnoea, PND) → eventually pulmonary arterial hypertension → right heart failure ^[1][2].
• Once symptomatic HF develops, mortality without surgery is 10–20% per year ^[2]. This is the point of no return if left untreated.

Clinical features of LV failure in AR:

• SOB on exertion → orthopnoea → PND → resting dyspnoea ^[1]
• Fatigue from ↓forward cardiac output ^[1]
• Peripheral oedema, elevated JVP, hepatomegaly (when RV failure ensues)
• S₃ gallop (reflecting rapid filling of a volume-overloaded, failing ventricle) ^[1]
• Pulmonary congestion on CXR, pulmonary hypertension on echo ^[1]

Why does the LV eventually fail? There is a limit to how much the LV can dilate. According to LaPlace's law (wall stress = pressure × radius / 2 × wall thickness), as the radius increases, wall stress increases — the heart has to work harder with each beat. Eventually, the hypertrophy cannot keep up with the dilation, wall stress exceeds the compensatory capacity, and contractile function declines irreversibly.

Chest pain (↓DBP, LVH) more at night (↓HR) ^[1]

AR causes angina through a double-hit mechanism — unique among valvular lesions:

Why worse at night? During sleep, heart rate drops → longer diastole → more time per beat for blood to regurgitate → lower diastolic BP, higher regurgitant volume, worse coronary perfusion. This is characteristic of AR angina and is a classic exam point ^[1].

This angina can occur even without epicardial coronary artery disease — it is a supply-demand mismatch caused by the haemodynamics of AR itself. However, coexistent CAD is common, especially in older patients with degenerative AR, and must always be considered.

Pulmonary HT ^[1]

Pathophysiology:

• LV failure → ↑LVEDP → ↑LA pressure → ↑pulmonary venous pressure → passive (post-capillary) pulmonary hypertension
• Chronic elevated pulmonary venous pressure → reactive pulmonary vasoconstriction + pulmonary vascular remodelling → the pulmonary hypertension becomes mixed (pre- and post-capillary) and eventually fixed
• Once fixed pulmonary vascular disease develops → RV pressure overload → RV failure → biventricular failure

This cascade — LV failure → pulmonary HTN → RV failure — is the final common pathway of all left-sided valvular diseases. In AR, it typically occurs late because the LV compensates for so long.

Pathophysiology:

• Severe LV dilation → the mitral annulus stretches (it sits at the base of the LV) → the mitral leaflets can no longer coapt → central MR develops
• Additionally, LV dilation displaces the papillary muscles laterally → tethers the mitral leaflets → further prevents coaptation

This creates a vicious cycle: AR → LV dilation → functional MR → additional volume overload on the LV → more dilation → more MR. This is one of the reasons why surgery should not be delayed until the LV is massively dilated.

Infective endocarditis despite optimal medical therapy (an indication for surgery) ^[1]

Why is an AR valve susceptible to IE?

• The regurgitant jet creates turbulent flow → damages the endothelial surface of the valve cusps → exposes subendothelial collagen and tissue factor → promotes platelet-fibrin deposition (non-bacterial thrombotic endocarditis, NBTE) → a nidus for bacterial seeding during transient bacteraemia
• The aortic valve is the second most commonly affected valve in IE (after the mitral valve) ^[1]

Consequences of IE on an AR valve:

• Cusp destruction/perforation → acute worsening of AR → acute pulmonary oedema
• Vegetation formation → systemic embolisation (stroke, splenic infarct, renal infarct, mycotic aneurysm, Janeway lesions, Osler nodes)
• Perivalvular abscess → conduction system damage (AV block, bundle branch block) → this is a strong indication for urgent surgery
• Persistent infection despite antibiotics → indication for surgical debridement and valve replacement ^[1]

When AR is caused by aortic root dilation (Marfan, bicuspid aortopathy, HTN, aortitis), the root itself is a source of additional complications:

• Uncommon in AR (more typical of AS), but can occur due to:
  • Ventricular arrhythmias (VT/VF) triggered by myocardial fibrosis or ischaemia
  • Acute aortic dissection with tamponade
  • Acute IE with cusp rupture → acute severe AR → refractory pulmonary oedema/shock