Congenital Heart Disease I and II

Question 1

Congenital Heart Disease

• General
• Etiology
• Genetic factors
• Environmental factors

Answer 1

• General
  
  • Leading cause of neonatal mortality
• Etiology
  
  • Cardiac malformations arise during the development of the heart tube morphogenesis at 4-7 weeks gestation
• Genetic factors
  
  • Critical role
  • > 10% have an identified chromosomal abnormality or single gene defect
• Environmental factors
  
  • Maternal health (ex. rubella infection)
  • Infection (ex. diabetes
  • Drug exposure (ex. lithium, alcohol)

Question 2

Down Syndrome

• Genetics
• Other
• Cardiac abnormalities

Answer 2

• Trisomy 21
• Hypotonia & developmental delay
• AV or ventricular septal defects

Question 3

Turner’s Syndrome

• Genetics
• Cardiac abnormalities

Answer 3

• Female XO karyotype
• Coarctation of the aorta & bicuspid aortic valve

Question 4

William’s Syndrome

• Genetics
• Other
• Cardiac abnormalities

Answer 4

• Abnormality in elestan gene (7q11)
• Developmental delay, loquacious personality, & facial dysmorphology (flat nasal bridge, long philtrum, wide mouth)
• Supravalue aortic stenosis, pulmonary artery stenosis, & renal artery stenosis

Question 5

Noonan’s Syndrome

• Genetics
• Other
• Cardiac abnormalities

Answer 5

• Autosomal dominant genetic abnormality (12q)
• Turner’s phenotype, short stature, webbed neck, hypertelorism, & developmental delay
• Pulmonary valve stenosis & hypertrophic cardiomyopathy

Question 6

Diagnosis & Classification of Congenital Heart Disease

• Diagnosis
• Classification
  
  • Acyanotic lesions
  • Cyanotic lesions

Answer 6

• Diagnosis
  
  • History & physical exam
  • Lab tests: ECG, chest x-ray
  • Analysis: echo, MRI, CT, angiography
  • Therapeutic interventional procedures: cardiac catheterization
• Classification
  
  • Acyanotic lesions
    
    • Septal defects
      
      • ASD
      • VSD
      • AV septal defect
      • Patent ductus arteriosus
    • Obstruction
      
      • Smilunar valve (pulmonic & aortic stenosis)
      • Coarctation of the aorta
  • Cyanotic lesions
    
    • Abnormal connection
      
      • Transposition of the great arteries
      • Total anomalous pulmonary venous return
    • Septal defect + obstruction to pulmonary blood flow
      
      • Tricuspid atresia
      • Pulmonary atresia
      • Tetralogy of Fallot
    • Complete mixing
      
      • Aortic atresia / hypoplastic left heart syndrome
      • Truncus arteriosus
      • Single ventricle

Question 7

Atrial Septal Defect

• Defect
• Types
• Physiology
• Clinical findings
• Lab findings
  
  • Chest x-ray
  • ECG
  • Echo
• Natural history & complications
• Management

Answer 7

• Defect
  
  • Acyanotic septal defect
• Types
  
  • Secundum defect: in the fossa ovalis region (most common)​
  • Sinus venosus defect: adjacent to the SVC or IVC
  • Ostium primum (part of AV septal defect)
• Physiology
  
  • Left to right shunt
  • Volume overload of RA & RV
• Clinical findings
  
  • Increased parasternal impulse
  • Fixed splitting of S2
  • Grade II-III ejection murmur mid to upper left sternal border
  • Mid diastolic murmur low left sternal border
    
    • Due to flow across the tricuspid & pulmonic valves resulting in tricsupid & pulmonic stenosis
    • Not due to flow across the atrial septum b/c this is low velocity w/ minimal turbulence
• Lab findings
  
  • Chest x-ray
    
    • Cardiomegaly
    • Increased pulmonary vascularity
  • ECG
    
    • Right axis deviation
    • RVH
  • Echo
    
    • Defines the type & size of the defect
    • Provides indirect evidence of the degree of left to right shunting by the degree of RA & RV enlargement
• Natural history
  
  • Children: rarely symptomatic
  • Adults: complications
    
    • Right heart failure from chronic volume overload
    • Atrial arrhythmias from chronic atrial stretching
    • Pulmonary hypertension from excessive pulmonary blood flow over a long period of time
    • Paradoxical emboli related to intermittent right ot left shutnign across the defect
• Management
  
  • Surgical closure
  • Transcatheter closure (avoid open heart surgery)

Question 8

Ventricular Septal Defect

• Defect
• Anatomy
• Physiology
• Clinical implications dependent on…
• Clinical findings
  
  • Small VSD
  • Large VSD
• Large VSD shunt variability
  
  • Newborn
  • First few weeks of life
  • Tetralogy of Fallot
• Lab findings
  
  • Chest x-ray
    
    • Small defect
    • Large defect
  • ECG
    
    • Small defect
    • Large defect
  • Echo
  • Catheterization
• Natural history & complications
  
  • Small defects
  • Large defects
• Management

Answer 8

• Defect
  
  • Acyanotic septal defect
• Anatomy
  
  • Perimembranous region
  • Muscular septum
  • Doubly committed or supracristal (immediately subjacent to the aortic & pulmonary valves)
• Physiology
  
  • Left to right shunt
  • Volume overload of LV, LA, & RV
  • Pressure &/or volume overload to right heart
• Clinical implications dependent on…
  
  • Size of the hole
  • Downstream resistance to flow
    
    • Pulmonic stenosis
    • Pulmonary vascular resistance
• Clinical findings
  
  • Small VSD
    
    • Left to right shunt
    • Normal intracardiac pressures
    • No symptoms
    • High pitched, pansystolic murmur at LLSB
    • Normal S2
  • Large VSD
    
    • Pulmonary hypertension
    • CHF
    • Failure to thrive in infancy
    • Ejection murmur due to equal pressures in the two ventricles
    • Loud, single S2
• Shunt is variable in large VSD due to presence & degree of pulmonary stenosis & level of pulmonary vascular resistance
  
  • Newborn
    
    • Very small shunt b/c neonatal pulmonray vascular resistance is high, providing almost as much resistance to flowa s the systemic vascular bed
  • First few weeks of life
    
    • As pulmonary resistance falls, left to right shunt increases w/o changing the defect size
  • Tetralogy of Fallot
    
    • Predominant right to left shunt due to severe pulmonary stenosis
• Lab findings
  
  • Chest x-ray
    
    • Small defect
      
      • Normal
    • Large heart
      
      • Cardiomegaly & increased vascularity
  • ECG
    
    • Small defect
      
      • Normal
    • Large defect
      
      • LVH +/- RVH
  • Echo
    
    • Diagnostic
  • Catheterization
    
    • Rarely necessary
• Natural history
  
  • Spontaneous closure or decrease in size common
  • Small defects
    
    • Don’t require any intervention
  • Large defects
    
    • CHF & failure to thrive
    • Pulmonary HTN & vascular disease
    • Bacterial endocarditis
• Management
  
  • Surgical repair
  • Medical therapy for CHF
  • Prevention of pulmonary vascular disease

Question 9

AV Septal Defect

• Defect
• Anatomy
• Physiology
  
  • General
  • Partial defect
  • Complete defect
• Clinical findings
  
  • Common in…
  • Partial defect
  • Complete defect
• Lab data
  
  • ECG
  • Chest x-ray
  • Echo
  • Catheterization
• Complications
• Management

Answer 9

• Defect
  
  • Acyanotic septal defect
• Anatomy
  
  • Deficiency of the AV (lower atrial & ventricular) septum
  • Affects the atrial septum, AV valves, & ventricular septum
• Physiology
  
  • General
    
    • ASD + VSD
    • Left to right shunts w/ volume overload of RA, RV, & LV
  • Partial defect: physiology of an atrial defect
    
    • Atrial defect only & cleft (abnormal) AV/mitral valve
    • No intraventricular communication
    • Volume overload of RA & RV
    • Cleft AV valve –> mitral regurgitation
  • Complete defect: physiology of a ventricular defect
    
    • Atrial & ventricular defects
    • Large left to right shunt
    • Volume overload of the RA, RV & LV
• Clinical findings
  
  • Common in…
    
    • Down syndrome
  • Partial defect
    
    • Findings of an ASD
    • Murmur of mitral regurgitation
  • Complete defect
    
    • Findings of a large VSD
    • Pulmonary HTN & CHF
• Lab data
  
  • ECG
    
    • Superior or left axis deviation
  • Chest x-ray
    
    • Large heart w/ increased markings / vascularity
  • Echo
    
    • Diagnostic
  • Catheterization
    
    • Rarely needed
• Complications
  
  • AV valve regurgitation
  • CHF
  • Pulmonary HTN & eventual vascular disease
  • Endocarditis
• Management
  
  • Surgical repair / closure

Question 10

Patent Ductus Arteriosus

• Defect
• Anatomy
• Physiology
• Clinical findings
• Complications
• Management
• Lab findings
• Management

Answer 10

• Defect
  
  • Acyanotic septal defect
• Anatomy
  
  • Normal component of fetal circulation: extension of main pulmonary artery to descending aorta
  • Failure of the normal process of spontaneous closure of the ductus arteroisus immediately after birth
• Physiology
  
  • Left to right shunt due to run off from aorta to pulmonary artery
  • Volume overload of LA & LV
  • Increased pulmonary blood flow
• Clinical findings
  
  • Continuous murmur at LUSB
  • Bounding pulses due to diastolic run-ff from the aorta to the pulmonary artery
  • If duct is large: CHF & pulmonary HTN
• Complications
  
  • Endocarditis
  • CHF
  • Pulmonary HTN & pulmonary vascular disease
• Management
  
  • Surgical ligation
  • Transcatheter coil embolization
• Lab findings
  
  • Chest x-ray
    
    • Large heart & increased vascularity
  • Hemodynamics
    
    • CHF
    • Pulmonary HTN
• Management
  
  • Most are successfully closed in the cath lab w/ transcatheter coil or device placement

Question 11

Left to Right Shunt Summary

• Result in…
• Chest x-ray
• If the degree of shunting is hemodynamically significant…
• Eisenmenger’s syndrome

Answer 11

• Result in…
  
  • Increased pulmonary blood flow –> volume overload of various heart chambers
• Chest x-ray
  
  • Cardiomegaly
  • Increased pulmonary vascularity
• If the degree of shunting is hemodynamically significant…
  
  • CHF + pulmonary HTN
• Eisenmenger’s syndrome
  
  • Long standing increased pulmonary blood flow & pulmonary HTN
  • –> damaged pulmonary vasculature at the arterioles
  • –> increased pulmonary vascular resistance to the point where it exceeds systemic vascular resistance
  • –> reversed direction of the shunt from left-to-right to right-to-left
  • –> cyanosis

Question 12

Pulmonic Stenosis

• Defect
• Anatomy
• Physiology
• Clinical findings
• Lab data
  
  • ECG
  • Chest x-ray
  • Echo
  • Catheterization
• Complications
• Management

Answer 12

• Defect
  
  • Acyanotic obstruction defect
• Anatomy
  
  • Fusion &/or thickening of valve leaflets
  • Dysplastic pulmonic vavle leaflets (seen in Noonan syndrome)
• Physiology
  
  • Obstruction to RV outflow
  • Elevated pressure in the RV
  • RVH
• Clinical findings
  
  • SEM at the LUSB radiating to the back
  • Ejection click
• Lab data
  
  • ECG
    
    • RVH
  • Chest x-ray
    
    • Dilated main pulmonary artery due to post-stenotic dilation
  • Echo
    
    • Diagnostic
    • Quantitates the degree of stenosis
  • Catheterization
    
    • For intervention
• Complications
  
  • Right heart failure
  • Cyanosis if right to left atrial shunt
  • Endocarditis (rare)
• Management
  
  • Surgery
  • Transcatheter balloon valvuloplasty

Question 13

Aortic Stenosis

• Defect
• Anatomy
• Physiology
• Clinical findings
• Lab data
  
  • ECG
  • Echo
  • Catheterization
• Complications
• Management

Answer 13

• Defect
  
  • Acyanotic obstruction defect
• Anatomy
  
  • Thickened leaflets, fused commissures
  • Bicuspid aortic valve
• Physiology
  
  • Obstruction to LV outflow
  • LVH
• Clinical findings
  
  • SEM at the RUSB
  • Apical ejection sound
  • Decreased upstroke of the carotid & peripheral pulses (if severe)
  • Commonly associated w/ coarctation of the aorta
• Lab data
  
  • ECG
    
    • LVH
  • Echo
    
    • Diagnostic
    • Quantitates the degree of stenosis
  • Catheterization
    
    • For intervention
• Complications
  
  • CHF
  • Sudden death
  • Exertional syncope
  • Endocarditis
• Management
  
  • Transcatheter balloon valvuloplasty (initial palliative procedure)
  • Surgical replacement of their aortic valve (eventually later in childhood or adulthood)

Question 14

Coarctation of the Aorta

• Defect
• Anatomy
• Etiology
• Clinical presentation
• Clinical findings
  
  • ECG
  • Chest x-ray
  • Echo
  • MRI

Answer 14

• Defect
  
  • Acyanotic obstruction defect
• Anatomy
  
  • Obstruction of aortic arch adjacent to insertion of the ductus arteriosus
• Etiology
  
  • Closure of hte ductus arteriosus shortly after birth
  • –> migration of ductal tissue into the descending aorta
  • –> precipitous manifestation of arch obstruction from coarctation
  • –> severe CHF & cardiogenic shock
• Clinical presentation
  
  • Cardiogenic shock in the newborn period
  • Asymptomatic
    
    • Upper extremity HTN
    • Decreased lower extremity pulses
• Clinical findings
  
  • Discrepancy in blood pressure: normal or hypertensive upper extremity pulses w/ weak or absent femoral pulses
  • Systolic murmur at the LUSB, axilla, & back
  • Associatd lesions: bicuspid aortic valve, VSD
• Lab data
  
  • ECG
    
    • Infants: RVH (related to increased fetal pulmonary HTN)
    • Children/adults: LVH
  • Chest x-ray
    
    • Figure “3” in the descending aorta
    • If unrepaired for >5 years: rib notching due to collateral flow through dilated intercostal arteries
  • Echo
    
    • Diagnostic in infants
  • MRI
    
    • Diagnostic in older children
• Management
  
  • Surgical repair
  • Transcatehter balloon dilation
  • Stent placement for therapy of post-operative recurrent coarctation

Question 15

Cyanotic Heart Disease

• Pathophysiology
• Hyperoxia test
• Three mechanisms of cyanotic heart disease

Answer 15

• Pathophysiology
  
  • Desaturated venous blood enters systemic circulation through intracardiac mixing
  • Normal saturation = 95%
  • Depressed pO2 (to 60 mmHg) = 90% saturation
  • Cyanotic saturation < 85-90%
• Hyperoxia test
  
  • Expose patient to 100% O2 to differentiate cardiac & pulmonary causes of desaturation
  • Airway or pulmonary etiology: pO2 will rise above 100 mmHg
  • Cyantoic heart disease: pO2 barely or doesn’t increase due to fixed right-to-left shunt that’s not exposed to alveolar oxygen
• Three mechanisms of cyanotic heart disease
  
  • Abnormal connections of the great vessels to the heart
  • Septal defect + obstruction to pulmonary blood flow
  • Complete mixing of desaturated ysstemic venous & saturated pulmonary venous return

Question 16

Transposition of the Great Arteries

• Defect
• Pathophysiology
• Clinical findings
• Lab data
  
  • ECG
  • Chest x-ray
  • Echo
  • Catheterization
• Natural history
• Management

Answer 16

• Defect
  
  • Cyanotic abnormal great vessel connection
  • Most common cyanotic anomaly in newborns
• Pathophysiology
  
  • Normal atrial & ventricular connections
  • Reversal of the great vessel relationships so that the aorta arises from the RV & the pulmonary artery from the LV
  • Parallel systemic & pulmonary circuits
    
    • Systemic venous blood goes from the RA to the RV & out the aorta w/o exposure to oxygenated blood
  • Requires intracardiac or great vessel mixing to be compatible w/ life
    
    • All newborns have some interatrial connection through the foramen ovale
    • Foramen ovale allows enough satured pulmonary venous blood from the LA to mix w/ the systemic venous return in the RA to achieve a survivable level of systemic saturation
  • Inherently unstable situation: infants become critically hypoexmic within the first hours after birth
• Clinical findings
  
  • Extreme cyanosis w/o labored respirations in a newborn
  • Single S2
  • Unimpressive or no murmur
• Lab data
  
  • ECG
    
    • Normal for age
  • Chest x-ray
    
    • Narrow base
      
      • Due to the aorta being directly anterior to the pulmonary artery
      • Minimizes the usual shadow from the pulmonary artery which is normally positioned to the left of the aorta
  • Echo
    
    • Diagnostic
  • Catheterization
    
    • For atrial septostomy if the patient doesn’t have a reasonable large atrial communication
• Natural history
  
  • High mortality if untreated due to severe hypoxemia
• Management
  
  • Prostaglandins to maintain ductal patency
    
    • Increase pulmonary venous return to the LA
    • Facilitate left-to-right shunting
  • Balloon atrial septostomy (Rashkin procedure)
    
    • Catheter w/ a deflated balloon is advanced across the atrial septum
    • Inflate balloon –> pull back from the LA to the RA –> enlarge atrial communication
    • Allows systemic arterial saturations to increase to a level high enough to maintain homodynamic stability
    • Allows recovery from the initial stress until stable enough to under go open heart surgery
  • Arterial switch operation
    
    • Done in the first week of life
    • Removes the aortic & pulmonary trunks from their semilunar valves & attaches them to the appropriate ventricle
    • Transposes coronaries from the original aortic root to the posterior pulmonary root which will become the aortic outflow track

Question 17

Total Anomalous Pulmonary Venous Return

• Defect
• Pathophysiology
  
  • Blood mixing
  • Pulmonary venous return
  • RA flow
  • 3 main avenues of drainage of the pulmonary venous confluence into the systemic veins
  • All avenues
• Clinical presentation
  
  • Depends…
  • Descending vein to the portal circulation
  • Other forms of pulmonary venous return
  • Opperative approach

Answer 17

• Defect
  
  • Cyanotic abnormal great vessel connection
• Pathophysiology
  
  • Complete mixing of pulmonary & systemic venous return
    
    • All pulmonary veins return to a systemic vein
    • Appropriately connected atria, ventricles, & great vessels
  • Pulmonary veins return to a confluence behind the LA & don’t enter the heart directly
    
    • Abnormal vein forms from this confluence & enters the systemic venous circulation
    • Results in total mixture of the pulmonary venous return w/ the sytemic venous return when flow reaches the RA
  • RA flow
    
    • Most will pass through the tricuspid valve into the RV & pulmonary artery
    • Some will pass across the atrial septum w/ right-to-left shunting entering the LA, LV, & aorta to provide systemic cardiac output
  • 3 main avenues of drainage of the pulmonary venous confluence into the systemic veins
    
    • Vertical vein –> innominate vein –> SVC
    • Vein that descends below the diaphragm –> portal circulation
      
      • Almost associated w/ severe obstruction to pulmonary venous return
    • Confluence –> coronary sinus
  • All avenues
    
    • Increase pulmonary blood flow
    • Pulmonary HTN
    • Obligatory right-to-left hsunt across the atrial communication providing cardiac output
• Clinical presentation
  
  • Depends on degree of obstruction to pulmonary venous return
  • Descending vein to the portal circulation
    
    • Almost always –> pulmonary venous obstruction –> severe pulmonary edema immediately after birth –> urgent need to surgically repair
  • Other forms of pulmonary venous return
    
    • Eventually cause severe heart failure & pulmonary HTN –> need for early surgical intervention
  • Opperative approach
    
    • Oppose the pulmonary venous confluence to the back wall of the LA
    • Create a wide anastomosis b/n these chambers
    • Ligate the anomalous vein that connects the confluence to the systemic venous circuit

Question 18

Tricuspid Atresia

• Defect
• Pathophysiology
• Clinical presentation
• Degree of cyanosis
  
  • Small VSD
  • Large VSD
• Lab data
• Management

Answer 18

• Defect
  
  • Cyanotic septal defect + obstruction to pulmonary blood flow
• Pathophysiology
  
  • Obligatory right to left atrial shunt across foramen ovale or ASD
    
    • Total mixture of systemic & pulmonary venous return in the LA
    • Flow goes from the LA to the LV out into the aorta
  • VSD allows some flow from the LV to the RV to provide a source of pulmonary blood flow
  • Hypoplastic RV b/c it doesn’t receive the normal amount of inflow during fetal life to promote normal development of the chamber
• Clinical presentation
  
  • Cyanosis
  • Systolic murmur related to pulmonary stenosis or VSD
  • Single 2nd heart sound
• Degree of cyanosis
  
  • Inversely related to amount of pulmonary blood flow
  • Small VSD
    
    • Pulmonary outflow track obstruction
    • Most of the flow from the LV will go out the aorta
    • Pulmonary blood flow will be diminished –> significant hypoxemia
  • Large VSD
    
    • Modest pulmonary stenosis
    • Enough pulmonary blood flow –> mild cyanosis
    • Prominent systolic murmur from pulmonic stenosis or VSD & a single S2
• Lab data
  
  • ECG
    
    • LAD (unusual in a newborn)
    • LVH due to under-developed of the RV
  • Chest x-ray
    
    • Decreased pulmonary vascularity
  • Echo
    
    • Diagnostic
• Management
  
  • Prostaglandins if cyanosis is severe & ductal dependent
    
    • Allows opening of the ductus arteriosus to provide adequate pulmonary blood flow to achieve a sustainable systemic arterial saturation
  • Aorta to pulmonary artery shunt if cyanosis is severe

Question 19

Pulmonary Atresia

• Defect
• Pathophysiology
• Lab data
  
  • EKG
  • Chest x-ray
• Management

Answer 19

• Defect
  
  • Cyanotic septal defect + obstruction to pulmonary blood flow
• Pathophysiology
  
  • Complete obstruction to outflow from the RV –> tricuspid regurgitation
  • Right to left shunt across the atrial septum
  • Systemic venous return mixes w/ pulmonary venous return in the LA & flows into the LV & out into the aorta
  • Patent ductus arteriosus provides some pulmonary blood flow
    
    • Otherwise condition would be letal
  • Hypoplastic RV b/c blood can’t flow easily into or out of the RV
• Lab data
  
  • EKG
    
    • LV predominance due ot RV hypoplasia
  • Chest x-ray
    
    • Variable heart size
    • Decreased pulmonary vascularity
• Management
  
  • Prostaglandins maintain ductal patency
  • Aorta to pulmonary shunt eventually needed

Question 20

Tetralogy of Fallot

• Defect
• 4 features
• Physiology
• Clinical findings
• Lab data
  
  • ECG
  • Chest x-ray
  • Echo
  • Catheterization
• Management

Answer 20

• Defect
  
  • Cyanotic septal defect + obstruction to pulmonary blood flow
• 4 features
  
  • (1) VSD
  • (2) Pulmonic stenosis
  • (3) Overriding aorta
  • (4) RVH
• Physiology
  
  • Pulmonary stenosis + VSD –> right ot left shunt across VSD
  • Anterior deviation of outlet septum
    
    • –> aorta overrides the VSD & partially arises from the RV
    • –> narrowed RV outflow tract –> subvalvular & valvular pulmonic stenosis
  • Right aortic arch in 25%
  • Main variability: degree of pulmonary stenosis determines…
    
    • Severity of right-to-left ventricular shunting
    • Degree of cyanosis
• Clinical findings
  
  • Variable cyanosis
  • SEM from pulmonary stenosis
  • Single S2
  • Flow across non-restrictive VSD is silent b/c the defect is large & RV systolic pressure = LV systolic pressure
    
    • Murmur inversely related to severity of pulmonary stenosis
    • Severe pulmonary stenosis –> increased right-to-left shunt across VSD w/ small amount of flow across the pulmonary stenosis –> soft murmur
    • Moderate pulmonary stenosis –> large amount of flow across the outflow tract –> turbulent flow –> loud murmur
• Lab data
  
  • ECG
    
    • RAD
    • RVH
  • Chest x-ray
    
    • Small, “boot” shaped heart due to absent main pulmonary artery shadow at LUSB
    • Right aortic arch may be present
    • Decreased pulmonary vascularity
  • Echo
    
    • Diagnostic
  • Catheterization
    
    • Rarely needed prior to intervention
• Management
  
  • Almost always complete repair w/ open heart surgery to close the VSD & relieve pulmonray stenosis (repair)
  • In low birth weight infants or infants w/ severe anatomy, pulmonary artery shunt (palliative)
  • Repair: close VSD & relieve the pulmonary stenosis

Question 21

Septal Defect + Obstruction to Pulmonary Blood Flow Summary

Answer 21

• May be ductal dependent
• Prostaglandins provide dramatic improvement in oxygenation
• Aorta to pulmonary shunt for palliation

Question 22

Aorta to Pulmonary Shunts

• Classic Blalock Taussig Shunt
• Modified Blalock Taussig Shunt
• Waterston Shunt
• Potts Shunt
• Central Shunt

Answer 22

• Classic Blalock Taussig Shunt
  
  • Division of left subclavin artery with end to side anatomosis of the proximal subclavisn artery to the pulmonary artery
• Modified Blalock Taussig Shunt
  
  • Gore-tex tube connecting the subclavian artery to the pulmonary artery with bilateral end to side anastomoses
• Waterston Shunt
  
  • Creation of an aorto-pulmonary window connecting the posterior ascending aorta to the anterior right pulmonary artery
• Potts Shunt
  
  • Creating an aorto-pulmonary window by connecting the anterior wall of the descending aorta to the posterior wall of the left pulmonary artery
• Central Shunt
  
  • Gore-tex tube connecting any portion for the aorta to the pulmonary artery

Question 23

Septal Defect + Obstruction to Pulmonary Blood Flow Summary

• Lesions
• Prostaglandins
• Aorta to pulmonary shunts

Answer 23

• Lesions
  
  • May be dependent on ductal flow in the newborn period to maintain adequate levels of systemic arterial saturation in the setting of greatly diminished pulmonary blood flow
• Prostaglandins
  
  • Provide dramatic improvement in oxygenation by increasing ductal flow to the pulmonary artery
• Aorta to pulmonary shunts
  
  • May be required for palliation proir to complete repair

Question 24

Aortic Valve Atresia

• Defect
• Pathophysiology
• Clinical findings
• Lab data
  
  • EKG
  • Chest x-ray
  • Echo
• Management

Answer 24

• Defect
  
  • Cyanotic complete mixing of systemic venous & pulmonary venous return at atrial, ventricular, or great vessel level
• Pathophysiology
  
  • Underdeveloped left heart –> hypoplatic left heart syndrome
  • Obstruction to outflow from the LV
    
    • –> blood returning to the LA is divered across the atrial septum
    • –> complete mixing of pulmonary & systemic venous return in the RA
  • All of the venous return crosses the tricuspid valve –> RV –> main pulmonary
    
    • –> branch pulmonary arteries
    • –> shunt right-to-left across the patent ductus out into the systemic circulation
  • Abnormal fetal flow –> under-developed LV, mitral valve, & ascending aorta
  • Systemic perfusion is completley dependent on ductal patency
• Clinical findings
  
  • Constricting ductus –> cardoigenic shock within first several days of life
  • Hyperactive precordium w/ weak or absent pulses
• Lab data
  
  • EKG
    
    • RVH
  • Chest x-ray
    
    • Cardiomegaly
    • Increased pulmonary vascularity
  • Echo
    
    • Diagnostic
• Management
  
  • Prostaglandins maintain ductal patency & allow adequate systemic perfusion
  • Norwood operation
    
    • After the infant is stable, redirect the outflow across the pulmonary artery to the aorta to provide an alternate source of pulmonary blood flow via an aorta to plumonary shunt
  • Heart transplant

Question 25

Truncus Arteriosus

• Defect
• Pathophysiology
• Clinical findings
• Management

Answer 25

• Defect
  
  • Cyanotic complete mixing of systemic venous & pulmonary venous return at atrial, ventricular, or great vessel level
• Pathophysiology
  
  • A single arterial trunk arises from the heart overriding a large VSD & receives outflow from both the RV & LV
  • Pulmonary arteries arise directly from the root of the “truncus” (ascending aorta)
    
    • No pulmonary valve –> ungarded pulmonray arteries –> icnreased pulmonary blood flow from the aorta
  • Complete mixing of systemic & pulmonary venous return
• Clinical findings
  
  • Increased pulmonary blood flow
  • Pulmonary HTN
  • CHF
• Management: Rastelli procedure (surgical)
  
  • Closure of the VSD such that only the LV outflow reaches the aorta
  • B/c there’s no outlet form the RV after closure, a conduit is placed from the RV to the pulmonary artery

Question 26

Single Ventricle

• Defect
• Pathophysiology
• Clinical presentation w/ pulmonary stenosis
• Clinical presentaiton w/o pulmonary stenosis
• Management

Answer 26

• Defect
  
  • Cyanotic complete mixing of systemic venous & pulmonary venous return at atrial, ventricular, or great vessel level
• Pathophysiology
  
  • One dominant ventricle + hypoplastic chamber via a ventricular communication
  • Both the pulmonary artery & aorta arise from a “functionally common” chamber
  • Both right 7 levt AV valves empty into the common chamber –> “double inlet ventricle”
• Clinical presentation w/ pulmonary stenosis
  
  • Blood diverts out into the aorta –> pulmonary blood flow will be insufficient –> systemic desaturation –> cyanosis
  • Sometimes, just enough pulmonary stenosis allows balanced pulmonary & aortic flow
• Clinical presentation w/o pulmonary stenosis
  
  • Pulmonary over-circulation
  • Lower pulmonary vascular resistance compared to systemic resistance –> pulmonary HTN
  • CHF
• Management
  
  • ​Early surgical intervention

Question 27

Congenital Heart Disease Summary

• Timing of presentation
• Modes of presentation
• Management

Answer 27

• Timing of presentation
  
  • Presents from fetal life to adulthood
  • Severe cyanosis or cardiogenic shock in newborn period (aortic atresia, transposition)
  • Asymptomatic w/ murmur in an adult (ASD)
• Modes of presentation
  
  • Murmur
  • Abnormal pulses or BP
  • CHF
  • Cyanosis
• Management
  
  • Surgery
  • Interventional cath
  • Prevent endocarditis