Tetralogy of Fallot
James A. DiNardo
A 5-month-old infant recently adopted from South America is being evaluated for stable persistent cyanosis with arterial oxygen saturation (SaO2) of 70% to 80% since birth. She eats well and is in the 70th percentile for weight (6.5 kg). An echocardiogram, done before her arrival at your institution, suggests that she has tetralogy of Fallot (TOF). Although she has never been noted to have a “Tet spell,” her SaO2 was noted to decrease to 60% during a recent febrile episode. A repeat echocardiogram reveals TOF with severe valvular pulmonary stenosis (PS) and mild subvalvular PS, secondary to anterior deviation of the conal septum into the right ventricle outflow tract (RVOT). There is a peak instantaneous pressure gradient of 70 mm Hg across the RVOT, as determined by continuous wave Doppler.
A. Medical Disease and Differential Diagnosis
What is tetralogy of Fallot (TOF)?
What is the pathophysiology of TOF with pulmonary stenosis (TOF/PS)?
What is shunting and how is QP:QS calculated?
What is the pathophysiology of TOF with pulmonary atresia?
How is arterial O2 saturation determined in single ventricle physiology?
What is a “pink Tet”?
What are hypercyanotic spells? How are they treated?
What palliative surgical procedures are available for treating this patient with TOF/PS?
What definitive surgical procedures are available for treating this patient with TOF/PS?
What palliative and definitive surgical procedures are available for treating a patient with TOF with pulmonary atresia?
B. Preoperative Evaluation and Preparation
What preoperative history and physical examination information do you want?
Which other abnormalities need to be considered in this patient?
In general, what nothing by mouth (NPO) guidelines will you follow and what premedication will you give to a child with congenital heart disease?
C. Intraoperative Management
How will you induce anesthesia in this patient if intravenous (IV) access cannot be obtained?
Why would end-tidal carbon dioxide (ETCO2) monitoring be of particular use in a patient with TOF/PS?
What is near-infrared spectroscopy (NIRS) and what does it measure?
What are the important management issues during creation of a palliative shunt?
What is the effect of inhalation anesthetics on airway reflexes, myocardial contractility, systemic vascular resistance (SVR), and pulmonary vascular resistance (PVR) in children?
What are the pre-cardiopulmonary bypass (CPB) anesthetic goals for a patient undergoing definitive surgical correction of TOF/PS?
What interventions will reliably reduce PVR?
How does heparin administration and activated coagulation time (ACT) monitoring differ in children as compared with adults?
How is heparin reversed?
What is the incidence of protamine reactions in children?
What is the role of transesophageal echocardiography (TEE) in this patient?
What effect would a residual ventricular septal defect (VSD) have in this patient following separation from CPB?
D. Postoperative Management
How should postoperative ventilation be managed in this patient following placement of a transannular patch for TOF/PS?
Following complete repair of TOF/PS in an infant, what arterial oxygen saturation (SaO2) is acceptable?
Following placement of a modified Blalock-Taussig shunt (MBTS) for TOF/PS in an infant, what SaO2 is acceptable?
What is junctional ectopic tachycardia (JET)?
A. Medical Disease and Differential Diagnosis
A.1. What is tetralogy of Fallot (TOF)?
In 1888, Fallot described a congenital heart defect composed of four characteristics: (1) large VSD, (2) right ventricular (RV) outflow obstruction, (3) overriding aorta, and (4) right ventricle hypertrophy (RVH). Broadly defined, TOF is a complex of anatomic malformations consisting of a large, misaligned conoventricular VSD; a rightward and anterior displacement of the aorta, such that it overrides the VSD; and a variable degree of subvalvular RVOT obstruction due to anterior, superior, and leftward deviation of the conal (infundibular) ventricular septum. In addition, abnormalities in the septal and parietal bands of the crista supraventricularis further exacerbate the infundibular RVOT obstruction. RVH is the result of chronic RVOT obstruction. The most common associated lesion is a right aortic arch with mirror image arch vessel branching (innominate artery gives rise to left carotid and left subclavian arteries; right carotid and right subclavian arise separately) present in 25% of patients. Two broad subsets of TOF exist: TOF with PS (TOF/PS) and TOF with pulmonary atresia. A third much less common type of TOF known as TOF with absent pulmonary valve will not be considered here.
Tetralogy of Fallot with Pulmonary Stenosis
TOF/PS involves the features of TOF in conjunction with varying degrees of valvular PS. At one end of the spectrum of TOF/PS, the pulmonary valve may be mildly hypoplastic (reduced annulus size) with minimal fusion of the pulmonary valve leaflets (Fig. 38.1A). The pulmonary valve is almost always bileaflet. At the other end of the spectrum, the pulmonary annulus may be very small with near fusion of the pulmonary valve leaflets. It is important to point out that a valvular obstruction is a fixed obstruction, while a subvalvular obstruction is dynamic. If left uncorrected, RVOT obstruction from either valvular or subvalvular obstruction will progress to subvalvular obstruction, as compensatory RVH increases the mass of the RV and infundibulum. The anatomy of TOF/PS can almost always be definitively delineated (including coronary anatomy) by two-dimensional echocardiography. Cardiac catheterization is rarely necessary or indicated.
Tetralogy of Fallot with Pulmonary Atresia
TOF with pulmonary atresia involves the features of TOF and infundibular and pulmonary valvular atresia in conjunction with varying degrees of pulmonary arterial atresia. Four groups are said to exist. Group 1 patients have isolated infundibular and pulmonary valve atresia with a main pulmonary artery (PA) and distal PAs of near normal size and architecture. In some of these patients, the main PA may extend to the atretic infundibulum. In others, atresia involves a short segment of the main PA (Fig. 38.2). Patients in this group have pulmonary blood flow supplied from a patent ductus arteriosus (PDA). In group 2 patients, the main PA is absent, but the PAs are in continuity and supplied by a PDA. Group 3 patients have severely hypoplastic native PAs; the left and right PA may not be in continuity. There are major aortopulmonary collateral arteries (vessels from the aorta to the PA) known as MAPCAs. A PDA may be present as well. Some segments of lung may be perfused from MAPCAs, some only by the native PAs, and others by both sources (Fig. 38.3). Group 4 patients have no native PAs and all pulmonary blood flow is derived entirely from MAPCAs.
The anatomy of MAPCAs in TOF with pulmonary atresia can almost never be clearly delineated by two-dimensional echocardiography alone. Cardiac catheterization and/or magnetic resonance imaging or magnetic resonance angiography are necessary to delineate collateral anatomy and determine QP:QS.
DiNardo JA, Zvara DA. Congenital heart disease. In: DiNardo JA, Zvara DA, eds. Anesthesia for Cardiac Surgery. 3rd ed. Oxford: Blackwell Publishing; 2008:167-251.
Jonas RA, ed. Tetralogy of Fallot with pulmonary atresia. In: Comprehensive Surgical Management of Congenital Heart Disease. London: Arnold; 2004:440-456.
A.2. What is the pathophysiology of TOF with pulmonary stenosis (TOF/PS)?
TOF/PS is a disease with a complex shunt in which a communication (VSD) and a partial obstruction to RV outflow (RV infundibular and valvular stenosis) are present. In complex
shunts, the resistance to outflow is a combination of the resistance from the obstructive lesions and the PVR. If the resistance from the RV obstructive lesions is high, changes in PVR will have little effect on shunt magnitude and direction. In most patients with TOF/PS, there is a fixed and a dynamic component to RV outflow obstruction. The fixed component is produced by the valvular stenosis. The dynamic component is produced by variations in the caliber of the RV infundibulum. The pathophysiology present in TOF/PS is physiologic rightto-left (R-L) shunting induced by the presence of a VSD and RVOT obstruction. In addition, because the aorta overrides the VSD and the RV, desaturated systemic venous blood tends to stream out of the aorta, even in the presence of mild RVOT obstruction.
shunts, the resistance to outflow is a combination of the resistance from the obstructive lesions and the PVR. If the resistance from the RV obstructive lesions is high, changes in PVR will have little effect on shunt magnitude and direction. In most patients with TOF/PS, there is a fixed and a dynamic component to RV outflow obstruction. The fixed component is produced by the valvular stenosis. The dynamic component is produced by variations in the caliber of the RV infundibulum. The pathophysiology present in TOF/PS is physiologic rightto-left (R-L) shunting induced by the presence of a VSD and RVOT obstruction. In addition, because the aorta overrides the VSD and the RV, desaturated systemic venous blood tends to stream out of the aorta, even in the presence of mild RVOT obstruction.
The SaO2 is determined by the relative volumes and saturations of recirculated systemic venous blood and effective systemic blood flows that have mixed and reached the aorta. This is summarized in the following equation:
This is demonstrated in Figure 38.4 where the SaO2 = [(98 × 0.5) + (65 × 0.5)] / 1 = 81. Notice that the patient has a QP:QS = 0.5:1.
A.3. What is shunting and how is QP:QS calculated?
Shunting is the process whereby venous return into one circulatory system is recirculated through the arterial outflow of the same circulatory system. Flow of blood from the systemic venous atrium (right atrium) to the aorta produces recirculation of systemic venous blood. Flow of blood from the pulmonary venous atrium (left atrium) to the PA produces
recirculation of pulmonary venous blood. Recirculation of blood produces a physiologic shunt. Recirculation of pulmonary venous blood produces a physiologic left-to-right (L-R), whereas recirculation of systemic venous blood produces a physiologic R-L shunt. A physiologic R-L or L-R shunt commonly is the result of an anatomic R-L or L-R shunt. In an anatomic shunt, blood moves from one circulatory system to the other through a communication (orifice) at the level of the cardiac chambers or great vessels. Physiologic shunts can exist in the absence of an anatomic shunt; transposition physiology is the best example.
recirculation of pulmonary venous blood. Recirculation of blood produces a physiologic shunt. Recirculation of pulmonary venous blood produces a physiologic left-to-right (L-R), whereas recirculation of systemic venous blood produces a physiologic R-L shunt. A physiologic R-L or L-R shunt commonly is the result of an anatomic R-L or L-R shunt. In an anatomic shunt, blood moves from one circulatory system to the other through a communication (orifice) at the level of the cardiac chambers or great vessels. Physiologic shunts can exist in the absence of an anatomic shunt; transposition physiology is the best example.
Effective blood flow is the quantity of venous blood from one circulatory system reaching the arterial system of the other circulatory system. Effective pulmonary blood flow is the volume of systemic venous blood reaching the pulmonary circulation, whereas effective systemic blood flow is the volume of pulmonary venous blood reaching the systemic circulation. Effective pulmonary and effective systemic blood flows are the flows necessary to maintain life and are always equal, no matter how complex the lesions. Effective blood flow usually is the result of a normal pathway through the heart, but it may occur as the result of an anatomic R-L or L-R shunt.
Total pulmonary blood flow (QP) is the sum of effective pulmonary blood flow and recirculated pulmonary blood flow. Total systemic blood flow (QS) is the sum of effective systemic blood flow and recirculated systemic blood flow. Total pulmonary blood flow and total systemic blood flow do not have to be equal. Because QS (systemic cardiac output) tends to remain constant to supply end organs, a physiologic L-R shunt (pulmonary recirculation) causes pulmonary volume overload while a physiologic R-L shunt (systemic recirculation) allows QS to be maintained at the expense of SaO2.
Calculation of QP:QS (the ratio of total pulmonary blood flow to systemic blood flow) is greatly simplified when the determination is made using low inspired concentrations of oxygen (fraction of inspired oxygen [FIO2]). This allows the contribution of oxygen carried in
solution (PO2 × 0.003) to be ignored. Failure to account for this component when determination of QP:QS is made using an FIO2 of 1.0 will introduce substantial (100%) error. If the FIO2 is low, the determination of QP:QS can be simplified to the following equation using just oxygen saturations:
solution (PO2 × 0.003) to be ignored. Failure to account for this component when determination of QP:QS is made using an FIO2 of 1.0 will introduce substantial (100%) error. If the FIO2 is low, the determination of QP:QS can be simplified to the following equation using just oxygen saturations:
(SAO2 – SSVCO2) / (SPVO2 – SPAO2)
where A = arterial, SVC = superior vena cava, PV = pulmonary vein that can be assumed to be 98% in the absence of significant pulmonary disease, and PA = pulmonary artery.
DiNardo JA. Anesthesia for congenital heart surgery. In: Jonas RA, ed. Comprehensive Surgical Management of Congenital Heart Disease. London: Arnold; 2004:45-65.
A.4. What is the pathophysiology of TOF with pulmonary atresia?
The pathophysiology of TOF with pulmonary atresia is similar to the single ventricle physiology. Single ventricle physiology describes the situation wherein complete mixing of pulmonary venous and systemic venous blood occurs at the atrial or ventricular level and the ventricle(s) then distributes output to both the systemic and pulmonary beds. As a result of this physiology, the following are observed:
Ventricular output is the sum of pulmonary blood flow (QP) and systemic blood flow (QS).
Distribution of systemic and pulmonary blood flow is dependent on the relative resistances to flow (both intracardiac and extracardiac) into the two parallel circuits.
Oxygen saturations are the same in the aorta and the PA.
This physiology can exist in patients with one well-developed ventricle and one hypoplastic ventricle as well as in patients with two well-formed ventricles. In the case of a single anatomic ventricle, there is always obstruction to either pulmonary or systemic blood flow as the result of complete or near complete obstruction to inflow and/or outflow from the hypoplastic ventricle. In this circumstance, there must be a source of both systemic and pulmonary blood flow to ensure postnatal survival. In some instances of a single anatomic ventricle, a direct connection between the aorta and the PA through a PDA is the sole source of systemic blood flow (hypoplastic left heart syndrome) or of pulmonary blood flow (PA with intact ventricular septum). This is known as ductal dependent circulation. In other instances of a single anatomic ventricle, intracardiac pathways provide both systemic and pulmonary blood flow without the necessity of a PDA. This is the case in tricuspid atresia with normally related great vessels, a nonrestrictive VSD and minimal or absent PS.
In certain circumstances, single ventricle physiology can exist in the presence of two wellformed anatomic ventricles. This is generally the result of atresia or near atresia of outflow from one of the ventricles. Examples include the following:
TOF with pulmonary atresia where pulmonary blood flow is supplied through a large PDA or MAPCAs
Truncus arteriosus
Severe neonatal aortic stenosis and interrupted aortic arch; in both lesions, a substantial portion of systemic blood flow is supplied through a PDA
Heterotaxy syndrome
DiNardo JA. Anesthesia for congenital heart surgery. In: Jonas RA, ed. Comprehensive Surgical Management of Congenital Heart Disease. London: Arnold; 2004:45-65.
A.5. How is arterial O2 saturation determined in single ventricle physiology?
With single ventricle physiology, the SaO2 will be determined by the relative volumes and saturations of pulmonary venous and systemic venous blood flows that have mixed and reached the aorta. This is summarized in the following equation:
The primary goal in the management of patients with single ventricle physiology is optimization of systemic oxygen delivery and perfusion pressure. This is necessary if end-organ (myocardial, renal, hepatic, splanchnic) dysfunction and failure are to be prevented. This goal is achieved by balancing the systemic and pulmonary circulations. The term balanced circulation is used because both laboratory and clinical evaluations have demonstrated that maximal systemic oxygen delivery (the product of systemic oxygen content and systemic blood flow) is achieved for single ventricle lesions when QP:QS is at or just below 1:1. Increases in QP:QS in excess of 1:1 are associated with a progressive decrease in systemic oxygen delivery because the subsequent increase in systemic oxygen content is more than offset by the progressive decrease in systemic blood flow and by diastolic hypotension due to runoff into the pulmonary circulation. Decreases in QP:QS below 0.7 to 0.8:1 are associated with a precipitous decrease in systemic oxygen delivery because the subsequent increase in systemic blood flow is more than offset by the dramatic decrease in systemic oxygen content.
DiNardo JA. Anesthesia for congenital heart surgery. In: Jonas RA, ed. Comprehensive Surgical Management of Congenital Heart Disease. London: Arnold; 2004:45-65.
A.6. What is a “pink Tet”?
The term pink Tet refers to any noncyanotic patient with TOF/PS or TOF with pulmonary atresia. In these patients, QP:QS is sufficiently high (QP:QS generally greater than 0.8:1 in the presence of a normal mixed venous saturation and pulmonary vein saturation) to maintain a deoxyhemoglobin concentration less than 5 g per dL (SaO2 generally >80%). The designation
of “pink Tet” would apply to TOF/PS patients with minimal valvular and subvalvular PS and to all patients with TOF with pulmonary atresia where pulmonary blood flow is supplied from a large PDA and/or MAPCAs.
of “pink Tet” would apply to TOF/PS patients with minimal valvular and subvalvular PS and to all patients with TOF with pulmonary atresia where pulmonary blood flow is supplied from a large PDA and/or MAPCAs.
DiNardo JA, Zvara DA. Congenital heart disease. In: DiNardo JA, Zvara DA, eds. Anesthesia for Cardiac Surgery. 3rd ed. Oxford: Blackwell Publishing; 2008:167-251.
A.7. What are hypercyanotic spells? How are they treated?
The occurrence of hypoxic spells in TOF patients may be life-threatening and should be anticipated in every patient with TOF/PS and any infundibular obstruction, even those who are not normally cyanotic. The peak frequency of spells is between 2 and 3 months of age; spells occur more frequently in severely cyanotic patients. The onset of spells usually prompts urgent surgical intervention, so it is not unusual for the anesthesiologist to care for an infant who is at great risk for spells during the preoperative period. The etiology of spells is not completely understood, but infundibular spasm or constriction plays a role. Crying, defecation, feeding, fever, and awakening all can be precipitating events. Paroxysmal hyperpnea is the initial finding. There is an increase in rate and depth of respiration, leading to increasing cyanosis and potential syncope, convulsions, or death. During a spell, the infant will appear pale and limp secondary to poor cardiac output. Hyperpnea has several deleterious effects in maintaining and worsening a hypoxic spell. Hyperpnea increases oxygen consumption through the increased work of breathing. Hypoxia induces a decrease in SVR, which further increases the R-L shunt. Hyperpnea also lowers intrathoracic pressure and leads to an increase in systemic venous return. In the face of infundibular obstruction, this results in an increased RV pressure and an increase in the R-L shunt. Treatment of a “Tet spell” is focused on increasing the pulmonary circulation and decreasing the R-L shunt. It includes the following:
Administration of 100% oxygen
Compression of the femoral arteries or placing the patient in a knee-chest position to transiently increase SVR and reduce the R-L shuntFull access? Get Clinical Tree