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Published byEverett Barnett Modified over 9 years ago
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Dr. M. A. Sofi MD; FRCP (London); FRCPEdin; FRCSEdin
ATRIAL SEPTAL DEFECT Dr. M. A. Sofi MD; FRCP (London); FRCPEdin; FRCSEdin
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Atrial septal defect Atrial septal defect is characterized by a defect in the interatrial septum allowing pulmonary venous return from the left atrium to pass directly to the right atrium. Depending on the size of the defect, size of the shunt, and associated anomalies, this can result: No significant cardiac sequelae Right-sided volume overload Pulmonary arterial hypertension Atrial arrhythmias. The subtle physical examination minimal symptoms during the first 2-3 decades contribute to a delay in diagnosis until adulthood Majority (more than 70%) of which is detected by the fifth decade.
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Atrial septal defect Frequency
The 3 major types of atrial septal defect (ASD) account for 10% of all CHD and as much as 20-40% of congenital heart disease presenting in adulthood Ostium secundum: The most common accounting for 75% of all ASD cases Ostium primum: The second most common accounting for 15-20% ASDs Sinus venosus: The least common of the three, accounting for 5-10% ASDs Sex: female-to-male ratio of approximately 2:1. Age: Patients with ASD can be asymptomatic through infancy and childhood Timing of clinical presentation depends on the degree of left-to-right shunt. By the age of 40 years, 90% of untreated patients have symptoms of Exertional dyspnea Fatigue, palpitation Sustained arrhythmia Heart failure
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CLASSIFICATION — ASDs are classified according to their location and the nature of the embryologic defect: Isolated ASDs include patent foramen ovale (PFO), ASD at the fossa ovalis (secundum ASD), superior sinus venosus defect, inferior sinus venosus defect, and coronary sinus defects Secundum ASD — Defects in the foramen ovalis are classified as secundum type ASD. This type of ASD can result from poor growth of the secundum septum or excessive absorption of the primum septum This defect accounts for 70 to 75 percent of all ASDs and is more common in females. The rare combination of an ASD with mitral stenosis, the result of rheumatic valvulitis, is known as Lutembacher syndrome Primum ASD — The primum type ASD develops if the primum septum does not fuse with the endocardial cushions, leaving a defect at the base of the interatrial septum that is usually large . This type of defect accounts for 15 to 20 percent of ASDs. It has been suggested that both partial and complete AV canal defects are related to maldevelopment of the ventricular septum rather than a decrease in atrial septal tissue
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CLASSIFICATION — ASDs are classified according to their location and the nature of the embryologic defect: Isolated ASDs include patent foramen ovale (PFO), ASD at the fossa ovalis (secundum ASD), superior sinus venosus defect, inferior sinus venosus defect, and coronary sinus defects Primum ASD — The primum type ASD develops if the primum septum does not fuse with the endocardial cushions, leaving a defect at the base of the interatrial septum that is usually large . This type of defect accounts for 15 to 20 percent of ASDs. It has been suggested that both partial and complete AV canal defects are related to maldevelopment of the ventricular septum rather than a decrease in atrial septal tissue Secundum ASD — Defects in the foramen ovalis are classified as secundum type ASD. This type of ASD can result from poor growth of the secundum septum or excessive absorption of the primum septum This defect accounts for 70 to 75 percent of all ASDs and is more common in females. The rare combination of an ASD with mitral stenosis, the result of rheumatic valvulitis, is known as Lutembacher syndrome
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Atrial septal defects The normal atrial septum
Secundum ASD is formed by the poor growth of the septum secundum or excessive absorption of the septum primum. Primum ASD is formed by the failure of the septum primum to fuse with the endocardial cushions. The fossa ovalis is normal. Sinus venosus ASD is caused by the malposition of the insertion of the superior or inferior vena cava and is outside the area of the fossa ovalis.
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Clinical presentation
ASD malformation can go undiagnosed for decades Isolated defects of moderate-to-large size may also be asymptomatic All patients with ASD beyond the sixth decade are symptomatic. Clinical deterioration in older patients results from: Age-related decrease in LV compliance augments the left-to-right shunt Atrial arrhythmias, especially AF, atrial flutter or PAT, increase in frequency after the fourth decade and can precipitate right ventricular failure Adults older than 40 years have mild-to-moderate pulmonary hypertension in the presence of a persistent large left-to-right shunt; the right ventricle is burdened by both pressure and volume overload.
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Clinical presentation
Significant mitral regurgitation is associated with septum primum ASD Its incidence, extent, and degree of dysfunction increases with age. Mitral valve insufficiency leads to further increase in left atrial pressure and a higher degree of left-to-right shunt. Most common presenting symptoms include: Dyspnea fatigability Palpitations Arrhythmia Syncope Stroke Heart failure
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PHYSICAL FINDINGS — The classic physical findings of an atrial septal defect (ASD) are related to the size and location of the defect, the size of the shunt at atrial level, and the pulmonary arterial pressure. Heart sounds — The characteristic finding in ASDs is fixed splitting of the second heart sound (S2). Heart murmurs — A midsystolic pulmonary flow or ejection murmur loudest over the second left intercostal space A murmur of mitral regurgitation may also be heard due to a cleft mitral valve in ostium primum defects and mitral valve prolapse in secundum defects. A diastolic rumble due to the increased flow across the TV Precordial palpation — large left-to-right shunts can lead to one or more of the following findings: An enlarged and hyperdynamic right ventricle can produce a right ventricular heave. It can also cause chest wall deformity with a left precordial bulge. Enlargement of the pulmonary artery may be associated with a palpable pulmonary artery impulse at the left upper sternal border. This may be more pronounced in patients with pulmonary hypertension.
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Clinical presentation
Atrial arrhythmias — Atrial arrhythmias are a common manifestation of an ASD. The risk of atrial arrhythmias increases with increasing age and pulmonary artery. Patients with AF are at risk for embolic events. Stroke due to paradoxical embolization — Patients with a PFO or, much less often, an ASD with a right-to-left shunt are at risk for stroke due to paradoxical embolization (stroke, transient ischemic attack, or peripheral emboli). Migraine headache — Evidence is conflicting whether migraine is associated with right to left shunt via PFO or ASD Pulmonary hypertension and Eisenmenger syndrome — The development of pulmonary vascular injury is related to the degree and duration of right heart volume overload. Cyanosis — Cyanosis in patients with ASD is usually associated with either concomitant pulmonary valve stenosis resulting in elevated right heart pressures, and thus right-to-left shunt, or Eisenmenger syndrome
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Physical examination S2 is often widely split and fixed
Systolic ejection murmur in the second intercostal space Ostium primum defect an apical systolic regurgitant murmur of mitral regurgitation may be present. Depend on the degree of left-to-right shunt Hyperdynamic right ventricular impulse due to large stroke volume Pulsation of the pulmonary artery and an ejection click can be detected S1 is typically split, and increased in intensity second component
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Laboratory Studies Routine laboratory studies should for ASD include:
Complete blood count/LFT/TFT/BUN/ Metabolic profile or chemistry Coagulation studies (prothrombin time [PT] and activated partial thromboplastin time [aPTT]) Electrocardiogram — The ECG may be normal with an uncomplicated ASD and small shunt. Atrial arrhythmias often occur beyond the third decade (especially atrial fibrillation but also atrial flutter and supraventricular tachycardia). Echocardiogram — is the imaging modality of choice for ASD diagnosis Apical four chamber view showing a defect in the secundum atrial septum (red arrow). The right heart chambers (RV and RA) are enlarged, demonstrating right heart volume overload from left-to-right shunting at atrial level.
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Imaging Studies Chest radiography may reveal:
Cardiomegaly because of dilatation of the right atrium and right ventricular chamber. Prominent Pulmonary artery and pulmonary vascular markings Left atrial enlargement is rare only if clinically significant mitral regurgitation Dilatation of the superior vena cava can be seen in sinus venosus defect. Transthoracic and Trans esophageal echocardiography can provide excellent definition of the atrial septum. TEE is also useful in guiding device placement during catheter ASD occlusion procedures and in providing immediate intra-operative assurance that defect closure is accomplished.
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Atrial septal defect with pulmonary arterial hypertension
Normal chest radiograph Posteroanterior view of a normal chest radiograph. CXR of a patient with ASD demonstrates enlarged right atrium and right ventricle with marked prominence of the hilar or proximal pulmonary arterial vasculature (arrows).
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Treatment The decision to repair any kind of atrial septal defect (ASD) is based on clinical and echocardiographic information The size and location of the ASD Hemodynamic impact of the left-to-right shunt The presence and degree of pulmonary arterial hypertension Elective closure is advised for all ASDs with right ventricular overload or with a clinically significant shunt The widespread use of catheter closure of secundum ASD with lower mortality has raised the question regarding the need to close even small defects
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Contraindications to surgical repair
Closure of ASD is not recommended in patients with a clinically insignificant shunt Those who have severe pulmonary arterial hypertension or irreversible pulmonary vascular occlusive disease Those who have a reversed shunt with at-rest arterial oxygen saturations of less than 90%. In addition to the high surgical mortality and morbidity risk, closure of a defect in the latter situation may worsen the prognosis. Those patients whose condition is diagnosed well in the sixth decade of life would benefit from surgical closure remains controversial.
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