2. • Leonardo da Vinci wrote, “I have found from left auricle to right auricle the
perforating channel.”
• Leonardo’s account of a true atrial septal defect is thought to be the first
record of a congenital malformation of the human heart
3.
4.
5.
6.
7.
8. Atrial septation
( a ) Formation of primary atrial septum at the atrial roof .(posterosuperior aspect ,medial to
the entrance of the common venous sinus )
( b ) The primary septum ( asterisk ) continuous to grow and separates the right and left
atrium. The space between the leading edge of the primary septum and fusing atrioventricular
cushions ( yellow ) is the primary atrial foramen ( solid arrows ). This transient defect is closed
when the anterior and the posterior medial endocardial cushions fuse. Before closure of the
primary atrial foramen, a number of fenestrations develop at its dorsal portions to form the
secondary atrial foramen ( dashed arrows ).
( c ) Formation of the true secondary atrial septum ( arrows ). , the septum secundum appears
to the right of the septum primum. It also descends from the roof of the primitive atrium and
it fuses with the septum primum except for an area in the posterosuperior part of the septum
primum which continues to exist as the fossa ovalis
( d ) The primary septum forms the flap valve of the oval foramen ( arrow ).
( e ) When formed the secondary foramen in part has no rim, with a border formed by the
atrial roof. Much later, subsequently due to separation of the right and left pulmonary veins
and incorporations of their orifices to the left atrium, the deep infolding forms the so called
secondary septum.
9.
10.
11.
12. CLASSIFICATION
• Ostium primum ASD: caused by lack of fusion of the two endocardial cushions. The defect is in the caudal aspect of both the septum primum
and secundum.
• Ostium Secundum ASD: occur as a result of either excessive resorption of the septum primum or deficient growth of the septum secundum
and are occasionally associated with an anomalous pulmonary venousconnection (<10%).
• Sinus venosusASD (svc type): results from failure of formation (or resorption) of the septum secundum. This defect is located at the junction
of the superior vena cava with the right atrium and is associated with anomalous drainage of the pulmonary veins. they are almost always
associated with an anomalous pulmonary venous connection (right ≫ left)
• Sinus venosus–inferior vena cava– type defects are very uncommon and abut the junction of the inferior vena cava inferior to the fossa ovalis
,
• Coronary sinus ASD: results from failure of development of the terminal section of the coronary sinus. It is located in the caudal posterior
atrium, above the normal site of drainage of the coronary sinus. Coronary sinus septal defects are rare and arise from an opening of its wall
with the left atrium ,thereby allowing left-to-right atrial shunting.
• Single atrium ASD: failure of complete formation of the atrial septum.
13.
14. OSTIUM SECUNDUM ASD
• The most common type
• lie in a folded area rather than on a flat plane.
• Their anatomy is more complex on the right side
• Ostium secundumdefects result from shortening of the valve of the foramen
ovale, excessive resorption of the septum primum, or deficient growth of the
septum secundum openings less than 5 mm in diameter.
• the overall rate of spontaneous closure to be 87%.
• ASD smaller than 3 mm in size diagnosed before 3 months of age, spontaneous
closure: in 100% of patients at 1½ years of age.
• Spontaneous closure : more than 80% of the time in patients with defects between
3 and 8 mm before 1½ years of age
• An ASD with a diameter larger than 8 mm rarely closes spontaneously.
• Spontaneous closure is not likely to occur after 4 years of age.
15. ostium primum defects
• Next in frequency are ostium primum defects,
• Also called atrioventricular septal defects
16. Sinus venosus atrial septal defects
• uncommon, but not rare, (2% to 3% of interatrial communications). During normal
embryogenesis, the inferior vena cava and the right superior vena cava are incorporated into
the right horn of the sinus venosus.
• Faulty resorption results in a communication near the orifice of the superior or the inferior
cava.
• The right valve of the sinus venosus is a broad membrane that almost partitions the
developing right atrium.
• Both vena cavas are located on the left side of the membrane.
• superior vena caval sinus venosus defects : The orifice of the superior vena cava may override
the defect, which is therefore biatrial.
• Inferior vena caval sinus venosus defects are located below the foramen ovale and merge with
the floor of the inferior cava. As the valve of the inferior vena cava resorbs, its rudiment
becomes the fetal eustachian valve that directs inferior caval blood across the foramen ovale.
Persistence of a large eustachian valve channels inferior vena caval blood across an ostium
secundum atrial septal defect or across an inferior vena caval sinus venosus defect
17. Coronary sinus atrial septal defects
• Unroofed coronary sinus ASD is rare, (less than 1 %) of all atrial septal defects
• failure of separation of the superior wall of the coronary sinus with the left atrium
• usually associated with a persistent left superior vena cava (LSVC). Persistent LSVC occurs in 0.1–0.5 % of the
general population and 8 % of anomalies drain into the left atrium.
• An unroofed coronary sinus ASD is seen in 75 % of patients with persistent LSVC that drains into the left atrium.
• Unroofed coronary sinus is classified into four groups. (Type I is a completely unroofed coronary sinus with
persistent LSVC. Type II is a completely unroofed coronary sinus without persistent LSVC. Type III is a partially
unroofed midportion coronary sinus defect. Type IV is a partially unroofed terminal portion coronary sinus
defect).
• The fenestration from the coronary sinus into the left atrium typically occurs between the left atrial appendage
and the left upper pulmonary vein
• A relatively rare combination consists of absence of the coronary sinus, a defect in the atrial septum in the
location of the ostium of the coronary sinus, and a left superior vena cava connected to the left atrium. This
combination is necessarily cyanotic because blood from the left superior vena caval enters the left atrium
directly
18.
19. COMMON ATRIUM
• rare
• The right-sided portion of the common chamber has features of a morpholright atrium, The
left-sided portion of the common chamber has features of a morphologic left atrium.
• Absence of the atrial septum necessarily includes the ostium primum(atrioventricular
septal) location,
• resemble a nonrestrictive atrial septal defect except for obligatory venoarterial mixing
• a cyanotic malformation with increased pulmonary arterial blood flow
• Despite absence of the atrial septum, venoarterial mixing is usually no more than
moderate, with systemic arterial oxygen saturations that are often above 90%.
20. EPIDEMIOLOGY
• The female: male ratio is at least 2:1 in ostium secundumatrial septal defect,in sinus venosus defects and in
ostium primumdefects is approximately equal.
• Ostium secundum atrial septal defects are sometimes familial, Familial scimitar syndrome has been
reported
• Autosomal dominant inheritance is a feature of atrial septal defect with the Holt-Oram syndrome.
• Autosomal dominant inheritance tends to be the mode in inheritance in ostium secundumdefects with
prolonged atrioventricular conduction In some members of a family, the atrial septal defect occurs with PR
interval prolongation; other family members have PR prolongation with an intact atrial septum71; and still
others experience sudden death. Mutations in the NKX2.5 gene have been associated with familial atrial
septal defect and progressive prolongation of atrioventricular conduction.
• Concordant familial segregation of atrial septal defect has been reported with the Axenfeld-Reiger
Anomaly (see section Physical Appearance).
21. Which will have less RV failure?
1. 8 y/o girl with severe MS and moderate size ASD.
2. 23 Y/O male with severe PS and moderate TR and large ASD
3. 35 Y/O female with uncontrolled HTN and coarctation of aorta
4. 50 y/o male with recent extensive MI
22. Pathophysiology
In any type of ASD, the degree of left-to-right atrial shunting depends on
1. size of the defect
2. the relative diastolic filling properties of the two ventricles.
Any condition causing reduced left ventricular compliance (e.g., systemic
hypertension, cardiomyopathy, myocardia linfarction) or increased left atrial pressure
and/or regurgitation) tends to increase the left-to-right shunt.
If similar forces are present in the right side of the heart, this will diminish the left-to-right
shunt and promote right-to-left shunting.
23. • The fetal circulation is not altered by an atrial septal defect.
• At birth, there is little or no shunt in either direction across an atrial septal defect.
• The right ventricle gradually becomes thinner and more compliant ,so left atrial blood then
flows across the atrial septal defect into the more compliant right ventricle.
• Pulmonary blood flow that is received by the right pulmonary veins is channeled into the
right atrium because of proximity of the right pulmonary veins to the rim of the atrial septal
defect). Pulmonary blood flow received by the left pulmonary veins is channeled directly
into the left atrium and is then shunted across the atrial septal defect. Accordingly, the
right ventricle is volume overloaded and the left ventricle is volume underloaded
24. • Pulmonary vascular disease with a right-to-left shunt at sea level occurs in
less than 10% of patients with an atrial septal defect ( R/O PPH)
• Right ventricular function is usually maintained through the fourth decade.
Ischemic heart disease and systemic hypertension conspire to reduce left
ventricular compliance and thus to increase the left-to-right shunt. The
additional volume overload of the right atrium provokes atrial fibrillation
and atrial flutter, which further increase the left-to-right shunt and result in
heart failure)
25. • Left ventricular end-diastolic volume, stroke volume, ejection fraction, and cardiac
output are decreased in infants and adults with an atrial septal defect, and ejection
fraction tends to fall with exercise.
• Diminished left ventricular functional reserve is related to the mechanical effects
of right ventricular volume overload, which displaces the ventricular septum into
the left ventricular cavity, reducing its size and changing its shape from ovoid to
crescentic
• coronary reserve is compromised in the volume-overloaded right ventricle if the
left main coronary artery is compressed by a dilated pulmonary trunk.
26. • Increased resistance to right ventricular discharge can also result from massive
occlusive thrombus in dilated hypertensive proximal pulmonary arteries .
• Older adults experience a moderate rise in pulmonary artery pressure with
persistence of the left-to-right shunt. Thus, pulmonary hypertension with a
nonrestrictive atrial septal defect at sea level is bimodal and is represented in
young females with coexisting primary pulmonary hypertension or in older adults,
male or female, who have moderate pulmonary hypertension with a persistent left-to-
right shunt.
27. Clinical Features
• Symptoms are rare in childhood, and the decision to close an ASD is usually based on the presence of right-sided heart
volume overload and as prophylaxis against later adverse outcomes in patients with a significant defect (>10 mm).
• The most common initial symptoms in adults are exercise intolerance (exertional dyspnea and fatigue) and palpitations
(typically from atrial flutter, atrial fibrillation, or sick sinus syndrome).
• Right ventricular failure can be the initial symptom in older patients.
• The presence of cyanosis should alert one to the possibility of shunt reversal and Eisenmenger syndrome or, alternatively,
to a prominent eustachian valve directing inferior vena cava flow to the left atrium via a secundumASD or sinus venosus
ASD of the inferior vena cava type.
• Examination shows “left atrialization” of jugular venous pressure (A wave = V wave). A hyperdynamic right ventricular
impulse may be felt at the left sternal border at the end of expiration or in the subxiphoid area on deep inspiration. A
dilated pulmonary artery trunk may be palpated in the second left intercostal space. A wide and fixed split of S2 is the
auscultatory hallmark of ASD, although it is not always present. A systolic ejection murmur, usually grade 2 and often
scratchy, is best heard at the second left intercostal space, and a mid-diastolic rumble, from increased flow through the
tricuspid valve, may be present at the left lower sternal border. When right ventricular failure occurs, a pansystolic
murmur of tricuspid regurgitation is usual.
28. POINTS
• large ASD (pulmonary artery blood flow relative to systemic blood flow [Qp/Qs] >2.0:1.0) may cause congestive heart
failure and failure to thrive in an infant or child.
• An undetected ASD with a significant shunt (Qp/Qs >1.5:1.0) probably causes symptoms over time in adolescence or
adulthood, and symptomatic patients usually become progressively more physically limited as they age.
• Effort-related dyspnea is seen in approximately 30% of patients by the third decade and in more than 75% by the fifth
decade.
• Exercise intolerance on cardiopulmonary testing is even more common and reflects the fact that such patients often
do not know what “normal” feels like.
• Supraventricular arrhythmias (atrial fibrillation or flutter) and right-sided heart failure develop by 40 years of age in
approximately 10% of patients and become more prevalent with aging.
• Paradoxical embolism resulting in a transient ischemic attack or stroke can call attention to the diagnosis.
• The development of pulmonary hypertension, although probably not as common as originally thought, can occur at
an early age.
• If pulmonary hypertension is severe, a second causative diagnosis should be sought.
• Life expectancy is clearly reduced in patients with an ASD, although not as severely as was quoted in earlier papers
because only patients with large ASDs were reported.
29. Auscultation
• Split S1, Load T1 , pulmonary ejection sound is uncommon,
• The pulmonary midsystolic flow murmur , grade 2/6 or 3/6, maximal in the second left intercostal space over the pulmonary trunk,, impure
and superficial , crescendo-decrescendo, peaking in early or mid systole and ending well before the second heart sound .
• The pulmonary component of the second sound is prominent
• Wide fixed splitting is an auscultatory hallmark of atrial septal defect.
• As diastole shortens, the split narrows, and as diastole lengthens, the split widens
• Fixed splitting means that the width of the split remains constant throughout active respiration and during the Valsalva’s maneuver.
• Persistent splitting means that the split widens during inspiration and narrows during expiration.
• These patterns of splitting do not apply when partial anomalous pulmonary venous connection occurs with an intact atrial septum Increased
venous return during inspiration is not accompanied by a reciprocal fall in left-to-right shunt because the atrial septum is intact
• Tricuspid flow murmurs are medium frequency, impure, soft, short, presystolic or mid-diastolic, and localized at the lower left sternal border
and do not increase with inspiration despite their right-sided origin.
• PERICARDIAL RUB
• Continuous murmurs through restrictive atrial septal defects are rare.
• Atrial septal defects with pulmonary vascular disease and reversed shunts are accompanied by auscultatory signs of pulmonary
hypertension
30.
31. PHYSICAL APPEARANCE
• Children with an atrial septal defect may have a delicate gracile habitus,
• weight more affected than height
• left precordial bulge with Harrison’s grooves
32. Close-up view of the fingers of a 53-year-old woman with dwarfism with Ellis-van Creveld
syndrome and hypoplasic nails
33. SVC TYPE ASD
• Negative P waves in the inferior
leads indicate a low atrial rhythm
• RBBB
34. Electrocardiogram
• Sinus rhythm or atrial fibrillation or flutter may be present.
• The QRS axis is typically rightward in secundumASD, and “crochetage” of the QRS complex may be seen in
the inferior leads. when the rSr prime pattern occurs with crochetage in each of the inferior limb leads, the
specificity of the electrocardiographic diagnosis of atrial septal defect is remarkably high
• Negative P waves in the inferior leads indicate a low atrial pacemaker, often seen in sinus venosus–superior
vena cava–type defects, which are located in the area of the sinoatrial node and render it deficient.
• Complete right bundle branch block appears as a function of age. Tall R or R′ waves in V1 frequently
indicate pulmonary hypertension.
• The QRS axis is vertical with clockwise depolarization that writes q waves in leads 2, 3, and aVF
• sinus arrhythmia does not occur in adults with an atrial septal defect
35. COMMON ATRIUM
• Negative P waves in the inferior
leads indicate a low atrial
• RBBB
• LAD
36. Chest Radiography
• The classic radiographic features are cardiomegaly(from right atrial and
right ventricular enlargement),
• Dilated central pulmonary arteries with pulmonary plethora indicating
increased pulmonary flow, and a small aortic knuckle (reflecting a chronic
low–cardiac output state).
41. X-Ray
• Increased pulmonary arterial vascularity extends to the periphery of the lung fields
• The pulmonary trunk and its proximal branches are dilated The left branch is
usually obscured by an enlarged pulmonary trunk , but the lateral view discloses
dilation of both branches
• The ascending aorta is seldom border forming because the intracardiac shunt does
not traverse the aortic root .
• In young adults with pulmonary vascular disease and a balanced or reversed shunt,
the pulmonary trunk and its branches are strikingly enlarged and calcified (Right
atrial enlargement is characteristic
42.
43.
44. Echocardiography
• The functional importance of the defect can be estimated by the size of the right ventricle,
• The presence or absence of right ventricular volume overload (paradoxical septal motion),
• (less accurately) estimation of Qp/Qs.
• Indirect measurement of pulmonary artery pressure can be obtained from the Doppler velocity of the tricuspid
regurgitation jet.
• In ostium secundum atrial septal defects, : The mitral valve abnormalities consist of thickening and fibrosis of leaflets and
chordae tendineae .
• TEE permits better visualization of the interatrial septum and is usually required when device closure is contemplated,
partly to ensure that pulmonary venous drainage is normal
• ICE can be used instead of TEE during device closure to help guide insertion of the device, thereby reducing fluoroscopic
and procedural time and forgoing the need for general anesthesia.
45.
46.
47.
48.
49.
50.
51.
52. Which one is against the diagnosis of pure ASD?
1. Systolic murmur (IV/VI) on LUSB
2. Orthopnea
3. Ortostatic dyspnea
4. Friction rub
5. Reduced LV function
Platypnea-orthodeoxia is a rare syndrome characterized
by orthostatic provocation of a right-to-left shunt across
an atrial septal defect or a patent foramen ovale.
Platypnea (dyspnea induced by the upright position and
relieved by recumbency) and orthodeoxia (arterial
desaturation in the upright position with improvement
during recumbency) are features of this rare disorder.
Clinical suspicion may originate from the patient who
reports that dyspnea is provoked by standing upright.
( the supine position
increases the work of
breathing in patients with
reduced lung compliance)
62. Indications for Intervention
• Shunt fractions are now rarely measured and are reserved for “borderline” cases.
• Hemodynamically insignificant ASDs (Qp/Qs <1.5) do not require closure, with the possible
exception of attempts to prevent paradoxical emboli in older patients after a stroke.
• “Significant” ASDs (Qp/Qs >1.5 or ASDs associated with right ventricular volume overload)
should be closed, especially if device closure is available and appropriate.
• For patients with pulmonary hypertension (pulmonary artery pressure >2/3 systemic
arterial blood pressure or pulmonary arteriolar resistance >2/3 systemic arteriolar
resistance), closure can be recommended if there is a net left-to-right shunt of at least 1.5:1
or evidence of pulmonary artery reactivity when challenged with a pulmonary vasodilator
(e.g., oxygen or nitric oxide).
63. DEVICE CLOSURE(T OR F)
• Device closure of secundumASDs percutaneously under fluoroscopy and TEE or with ICE guidance is the
therapy of choice when appropriate
• Indication for device closure are the same as for surgical closure, but the selection criteria are stricter.
• Depending on the device, this technique is available only for patients with a secundumASD that has a
stretched diameter of less than 38mm and adequate rims to enable secure deployment of the device.
• Anomalous pulmonary venous connection or proximity of the defect to the AV valves or coronary sinus or
systemic venous drainage usually precludes the use of this technique.
• major complications (e.g., device embolization, atrial perforation, thrombus formation) occurring in less
than 1% of patients and clinical closure achieved in more than 80%.
• Device closure of an ASD improves functional status in symptomatic patients independent of age and
exercise capacity in asymptomatic and symptomatic patients.
• Intermediate follow-up data have proved device closure of ASDs to be safe and effective with same
preservation of right ventricular function and lower complication rates than reported with surgery.
T
T
F, 41
T
T
T
F,
BETTER
64.
65.
66. SURGERY(T,F)
• ASDs can be closed surgically by primary suture closure or by applying a pericardial or synthetic patch.
• The procedure is generally performed via a midline sternotomy, but the availability of an inframammary or
minithoracotomy approach to a typical secundumASD should be made known to cosmetically sensitive
patients.
• Surgical mortality in adults without pulmonary hypertension should be less than 1%.
• Surgical closure of an ASD improves functional status and exercise capacity in symptomatic patients,
improves and survival, and improves or eliminates congestive heart failure, especially when patients
undergo surgery at an earlier age.
• surgical closure of ASDs in adult life does not prevent atrial fibrillation/flutter or stroke, especially when
patients undergo surgery after the age of 40 years.
• The role of a concomitant Cox-maze procedure in patients with a previous history of atrial flutter or
fibrillation should be considered
• In the setting of preexisting atrial tachyarrhythmias, surgical as well as device closure of an ASD does
decrease the incidence of postoperative atrial tachyarrhythmia
F,
IMPROVES
SURVIVAL
67. Reproductive Issues
• Pregnancy is well tolerated in patients after ASD closure.
• It is also well tolerated in women with unrepaired ASDs, but the risk for
paradoxical embolism is increased (still only very low risk) during pregnancy
and in the postpartum period.
• Pregnancy is contraindicated in those with Eisenmenger syndrome because
of high maternal (≈50%) and fetal (≈60%) mortality.
68. Follow-Up(T,F)
• After device closure, patients require 6 months of aspirin and endocarditis prophylaxis until the
device endothelializes,
• following following which, which,assuming they do not that require no residual any special shunt is precautions present, they or do endocarditis not require any prophylaxis.
special
• precautions or endocarditis prophylaxis.
Patients with sinus venosus defects are at risk for the development of caval and/or pulmonary
vein stenosis and should be kept under intermittent review.
• Patients who have undergone surgical or device repair as adults, patients with atrial arrhythmias
preoperatively or postoperatively, and those with ventricular dysfunction should remain under
long term cardiology surveillance.
• All patients who have undergone device closure should probably have an echocardiogram taken
every 5 years or so because of the possibility of late issues, especially erosion.