Physical Examination

Surgical dressings, chest tubes attached to suction, fluid in the mediastinum and pleural spaces, peripheral edema, and temperature gradients can distort or mask information obtained by the classic techniques of inspection, palpation, and auscultation in the postoperative period. However, the physician should not be deterred from applying these basic techniques in view of the potential benefit. Physical examination may be of great value in diagnosing gross or acute pathology, such as pneumothorax, hemothorax, or acute valvular insufficiency, but it is of limited value in diagnosing and managing ventricular failure. For example, in the critical care setting, experienced clinicians (e.g., internists) using only physical findings often misjudge cardiac filling pressures by a large margin.²⁷ Low CO, in particular, is not consistently recognized by clinical signs, and systemic BP does not correlate with CO after cardiac surgery. Oliguria and metabolic acidosis, classic indicators of a low CO, are not always reliable because of the polyuria induced by hypothermia, oxygen debts induced during CPB causing acidosis, and medications or fluids given during or immediately after bypass.²⁸

Although clinicians are taught that the adequacy of CO can be assessed by the quality of the pulses, capillary refill, and peripheral temperature, there is no relationship between these indicators of peripheral perfusion and CO or calculated systemic vascular resistance (SVR) in the postoperative period.²⁹ By the first postoperative day, there is a crude correlation between peripheral temperature and cardiac index (CI; r = −0.60). Many patients arrive in the ICU in a hypothermic state, and residual anesthetic agents can decrease the threshold for peripheral vasoconstriction in response to this condition.³⁰ A patient’s extremities may therefore remain warm despite a hypothermic core or a decreasing CO. Even after temperature stabilization on the first postoperative day, the relation between peripheral perfusion and CO is too crude to be used for hemodynamic management.

Invasive Monitoring

Concepts regarding invasive monitoring with a pulmonary artery catheter (PAC) have been revolutionized in the past decade because of several studies in a variety of settings that fail to show a benefit from its use. In addition, there is a poor relation between filling pressures and end-diastolic volume, stroke volume (SV), or volume responsiveness. A recent review of patients admitted to medical ICUs in the United States demonstrated a reduction of more than 40% in PAC use in the 10 years before 2004.³¹ The same trend was evident in surgical patients, including those undergoing cardiac surgery. The PAC rarely is used in cardiac surgery patients in many other countries. Greater availability of high-quality bedside echocardiography, often performed by intensivists, has made this modality a technique of choice in the postoperative period. Measures of volume responsiveness in mechanically ventilated patients, such as pulse pressure or SV variability (from arterial waveform analysis devices), are widely recognized as more sensitive and specific indicators of the need for intravascular volume expansion than filling pressures.³²

Despite the lack of a proven benefit with PAC use, many patients in North America continue to have this monitor placed for cardiac surgery. Cardiac anesthesiologists believe the lack of evidence about the PAC may reflect the lack of a well-designed randomized trial. There are no such trials in cardiac surgery patients, probably attesting to the reluctance of cardiac surgeons and anesthesiologists to manage their patients without what they consider to be important information. After surgery, many cardiac surgical centers do not have in-house physicians, and surgeons believe the “objective” PAC data obtained over telephone are valuable. As less invasive tools such as echocardiography or arterial waveform analysis devices become better known and available, it seems likely that PAC use will diminish in cardiac surgery patients.

Specialized PACs have been developed that permit continuous mixed venous oxygen saturation (So₂) monitoring, continuous CO measurement, calculation of RV volumes and ejection fraction, or have either imbedded electrodes or channels to pass atrial or ventricular pacing wires. The ability to pace through a PAC is particularly valuable in patients undergoing “minimally invasive” procedures in which the surgeon does not have adequate access to the heart to place epicardial leads. The Svo₂ catheter helps evaluate the adequacy of Do₂ and allows continuous assessment of the response to therapy, which may affect Do₂ or o₂ (e.g., PEEP therapy). The trend in the Svo₂ may function as an early warning signal of worsening in the oxygen supply/demand relation as Do₂ declines or VO₂ increases. In the postoperative period, the Svo₂ does not correlate with CO because the latter is only one of the factors in the oxygen supply/demand relation.³³ On the continuous CO catheter, a wire coil warms the blood, passing by it at time intervals determined by an algorithm, and the measured changes in temperature at the tip of the catheter are used to provide a continuous display of the CO. Although the CO displayed needs gathering of information over several minutes and is therefore not as quick as conventional thermodilution, and it does not provide beat-to-beat SV, it avoids having to give injected volumes to the patient (which can add up to a significant amount every 24 hours) and provides trends that may give earlier warning than intermittent injections. The “volumetric” PAC-computer system (REF-1; Edwards Lifesciences, Irvine, CA) uses a high-sensitivity thermistor to permit calculation of accurate right-sided volumes³⁴ (see Chapter 14).

Echocardiography

Echocardiography is the technique of choice for acute assessment of cardiac function. Just as transesophageal echocardiography (TEE) has become essential for intraoperative management in various conditions, several studies document its utility in the postoperative period in the presence and absence of the PAC.^35–38 It provides information that may lead to urgent surgery or prevent unnecessary surgery, gives important information about cardiac preload, and can detect acute structural and functional abnormalities. Although transthoracic echocardiography can be performed more rapidly in this setting, satisfactory images can be obtained only in about 50% of patients in the ICU³⁹ (see Chapters 11 to 14).

Postoperative Arrhythmias

Patients with preoperative or newly acquired noncompliant ventricles need a correctly timed atrial contraction to provide satisfactory ventricular filling, especially when they are in sinus rhythm before surgery (see Chapters 4, 5, 10, 19, and 25). Although atrial contraction provides around 15% to 20% of ventricular filling, this may be more important in postoperative patients, when ventricular dysfunction and reduced compliance may be present. For example, in medical patients with acute MI, atrial systole contributed 35% of the SV.⁶⁶ The SV is relatively fixed in patients with ventricular dysfunction, and the HR is an important determinant of CO. Rate and rhythm disorders need to be corrected when possible, using epicardial pacing wires. Approaches to postoperative rate and rhythm disturbances are listed in Table 34-1. The use of a PAC with atrial or ventricular pacing electrodes or use of lumens for pacing wires can facilitate temporary pacing if epicardial wires are not functioning. Failing that, temporary transvenous pacing wires can be placed (see Chapter 25).

TABLE 34-1 Postoperative Rate and Rhythm Disturbances

Later in the postoperative period (days 1 through 3), supraventricular tachyarrhythmias become a major problem, with atrial fibrillation (AF) predominating. The overall incidence rate is between 30% and 40%, but with increasing age and valvular surgery, the incidence rate may be in excess of 60%.⁶⁷ There are many reasons for this, including genetic factors, inadequate atrial protection during surgery, electrolyte abnormalities, change in atrial size with fluid shifts, epicardial inflammation, stress, and irritation.⁶⁸ Randomized trials of off-pump coronary artery bypass have found a similar incidence of postoperative AF compared with on-pump CABG.^69,70

Advanced age, a history of AF, and valvular heart surgery are the most consistently identified risk factors for AF.⁶⁸ Because AF is difficult to treat and potentially increases duration and cost of hospitalization, there is a great interest in effective therapy and prophylaxis.⁶⁷ Many studies have showed that β-blockade significantly reduces the incidence of postoperative AF and that withdrawal of β-blockers in patients receiving them before surgery is an important risk factor. Guidelines published by the American Heart Association, American College of Cardiology, and North American Society of Pacing and Electrophysiology recommend administration of β-blockers to prevent postoperative AF if there are no contraindications.⁷¹ Sotalol, which also has some class III actions, is also effective⁷² and is currently available in the intravenous form in North America (see Chapters 4 and 10).

Several studies have examined the use of amiodarone for prophylaxis or treatment and report both oral and intravenous amiodarone. Intravenous amiodarone is most often used in clinical practice because “acute” loading with oral therapy often is not feasible. Two pivotal studies of amiodarone deserve mention.

In the PAPABEAR study, oral amiodarone (10 mg/kg daily) or placebo was given 6 days before surgery through 6 days after surgery (13 days).⁷³ Atrial tachyarrhythmias occurred in fewer amiodarone patients (48/299; 16.1%) than in placebo patients (89/302; 29.5%) overall, in patients younger than 65 years (19 [11.2%] vs. 36 [21.1%], in patients older than 65 years (28 [21.7%] vs. 54 [41.2%]), in patients who had CABG surgery only (22 [11.3%] vs. 46 [23.6%]), in patients who had valve replacement/repair surgery (25 [23.8%] vs. 44 [44.1%]), in patients who received preoperative β-blocker therapy (27 [15.3%] vs. 42 [25.0%]), and in patients who did not receive preoperative β-blocker therapy (20 [16.3%] vs. 48 [35.8%]), respectively. Postoperative sustained ventricular tachyarrhythmias occurred less frequently in amiodarone patients (1/299; 0.3%) than in placebo patients (8/302; 2.6%) (P = 0.04).⁷³

In another study, Guarnieri et al⁷⁴ evaluated 300 patients randomized in a double-blind fashion to intravenous amiodarone (1 g/day for 2 days) or to placebo immediately after cardiac surgery. The primary end points of the trial were incidence of AF and length of hospital stay. AF occurred in 67 (47%) of 142 patients on placebo versus 56 (35%) of 158 on amiodarone (P = 0.01). Length of hospital stay for the placebo group was 8.2 ± 6.2 days, and 7.6 ± 5.9 days for the amiodarone group.

After AF or other supraventricular arrhythmias develop, treatment often is urgently needed for symptomatic relief or hemodynamic benefit. The longer a patient remains in AF, the more difficult it may be to convert, and the greater the risk for thrombus formation and embolization.^68,72 Treatable underlying conditions such as electrolyte disturbances or pain should be corrected while specific pharmacologic therapy is being instituted. Paroxysmal supraventricular tachycardia (uncommon in this setting) can be abolished or converted by intravenous adenosine, and atrial flutter can sometimes be converted by overdrive atrial pacing by temporary wires placed at the time of surgery. Electrical cardioversion may be necessary if hypotension is caused by the rapid rate; however, atrial arrhythmias recur in this setting.⁶⁷ Rate control for AF or flutter can be achieved with various atrioventricular nodal blocking drugs, and conversion is facilitated by many of these drugs as well. Table 34-2 summarizes the various treatment modalities for supraventricular arrhythmias. If conversion to sinus rhythm does not occur, electrical cardioversion in the presence of antiarrhythmic drug therapy should be attempted or anticoagulation with warfarin started (see Chapters 4, 10, and 25).

TABLE 34-2 Treatment Modalities for Supraventricular Arrhythmias

* See specific drug monographs for full description of indications, contraindications, and dosage. Doses are for intravenous administration; use lowest dose and administer slowly in patients with hemodynamic compromise.

† Verify pacer is not capturing ventricle.

‡ Infusion may provide better control. This drug is less useful than diltiazem because of myocardial depression.

§ Limited experience; may cause less hypotension than verapamil.

¶¶ When diagnosis is unclear (ventricular vs. supraventricular) and there is no acute hemodynamic compromise (i.e., cardioversion not indicated).

¶ Rate of administration depending on urgency of rate control.

** Less useful than other drugs because of slow onset and modest effect.

In summary, AF is a frequent complication of cardiac surgery, but the incidence can be significantly reduced with suitable prophylactic therapy. β-Adrenergic blockers should be administered to patients without contraindication, and prophylactic amiodarone can be considered for patients at high risk for postoperative AF. Patients who are poor candidates for β-blockade may not tolerate sotalol, whereas amiodarone does not have this limitation. More studies need to be performed to better assess the role of prophylactic therapy in off-pump cardiac surgery. After AF occurs, there is a high incidence of recurrence, so treatment with specific continuing pharmacologic therapy is usually necessary.

Preload

The Frank-Starling law states that myocardial work increases as the resting length of the myocardial fiber increases.⁷⁵ In vivo, this implies that SV will increase with increasing end-diastolic volume, although there is a limit at which SV reaches a plateau (and possibly decreases), with further increases in end-diastolic volume caused by excessive muscle stretch. In the normal myocardium, the Frank-Starling mechanism is the most important mechanism for increasing CO, and hypovolemia is a common cause of decreased CO and hypotension in the perioperative period. Assessment of preload is probably the single most important clinical skill for managing hemodynamic instability. Preload rapidly changes in the postoperative period because of bleeding, spontaneous diuresis, vasodilation during warming, the effects of positive-pressure ventilation and PEEP on venous return, capillary leak, and other causes.

Direct assessment of preload is clinically feasible using echocardiography. Several studies have demonstrated a fair-to-good correlation between echocardiographic and radionuclide measures of end-diastolic volume, and there is a good correlation between end-diastolic area by TEE and SV.^76–79 Although the use of echocardiography to assess preload must always be tempered by the realization the clinician is viewing a two-dimensional image of a three-dimensional object, this is the most direct technique clinically available. Increased awareness of the value of TEE in the ICU and increased availability of echocardiography in general have made this modality a first choice in acute assessment of preload in the setting of unexplained or refractory hypotension. Without echocardiography, pressure measurements are used as surrogates for volume measurements. For example, in the absence of mitral valve disease, left atrial pressure is almost equal to LV end-diastolic pressure, and pulmonary artery occlusion pressure (PAOP) is almost equivalent to these two pressures. In patients without left atrial pressure catheters, the PAOP or, when shown to be equivalent to this latter number, the pulmonary artery diastolic (PA_d) pressure is used (see Chapters 5 and 14).

The use of PAOP as a measure of preload may be misleading in various settings, including after cardiac surgery, when changes in pressure may not accurately reflect changes in ventricular end-diastolic volume. Studies by Ellis et al⁸⁰ and Calvin et al⁸¹ suggest that fluid therapy in postoperative patients could cause a large increase in LV end-diastolic volume, with minimal or no change in PAOP. Mangano et al^45,82 reported that fluid loading after CPB can uncover LV dysfunction and have also shown there is little benefit to be derived from exceeding a PAOP of about 12 mm Hg. Whether this is secondary to an open pericardium, which allows overdistention of the left ventricle, the use of PEEP causing RV distention, or other factors is unclear. Breisblatt et al⁸³ evaluated changes in ventricular pressure-volume relations after CABG surgery while keeping a low-to-normal PAOP (10 to 15 mm Hg). The increase seen in LV end-diastolic volume was not significant enough to explain the degree of ventricular dysfunction they noted. Bouchard et al⁸⁴ compared ventricular performance assessments from the PAC (i.e., LV stroke work index) with fractional area change and regional wall motion score index from TEE in 60 patients during and after cardiac surgery. They found no correlation between LV stroke work index and fractional area change and postulated that changes in ventricular compliance, loading conditions, and ventricular function alter the pressure-volume relation of the left ventricle in a manner that leads to discordant interpretations between the two techniques.

When ventricular compliance is normal and the ventricle is not distended, small changes in end-diastolic volume are usually accompanied by small changes in end-diastolic pressure. In patients with noncompliant ventricles from preexisting congestive heart failure (HF), chronic hypertrophy resulting from hypertension or valvular disease, postoperative MI, or ventricular dysfunction, small increases in ventricular volume may produce rapid increases in end-diastolic pressure, requiring therapeutic intervention.^83–89 Increased intraventricular pressure will increase myocardial oxygen demand (Mo₂) and decrease subendocardial coronary blood flow.⁹⁰ Myocardial ischemia may be the result. Increases in LV end-diastolic pressure are transmitted to the pulmonary circulation, causing congestion and, possibly, hydrostatic pulmonary edema. Although PAOP or left atrial pressure may not always show true preload, there are still good reasons to monitor them. The periods when patients are at particular risk for increases in end-diastolic pressure include awakening, endotracheal suctioning, and rapid-volume resuscitation. If myocardial ischemia or acute HF occurs, sudden increases in the end-diastolic pressure may result.

Many drugs may be used to reduce cardiac preload. Direct-acting vasodilators, especially nitroglycerin, increase venous capacitance, decreasing end-diastolic volume and pressure.^89–91 Intravenous furosemide, besides its diuretic effect, increases venous capacitance.⁹² Diuretics are important to help remove the fluid that is mobilized in the days after surgery. In patients who may not tolerate the acute volume loss that is induced by the loop diuretics, a furosemide infusion allows a more gradual diuresis. Such infusions have been shown to be effective in patients with renal dysfunction.^93,94 In a patient who appears refractory to diuresis, it is important to evaluate the circulatory state. Such refractoriness may suggest that a renal insult has been suffered, but it may also suggest underperfusion of the kidneys. In the latter case, the preload must be kept at the upper range of normal and CO augmented.

A new agent used in treatment of acute decompensated left-heart failure is recombinant B-type natriuretic peptide (nesiritide). The mechanism of action occurs by specific cell-surface receptors, stimulation of which increases levels of intracellular cyclic guanosine monophosphate (cGMP). The physiologic effects are mainly vasodilation, natriuresis, and renin inhibition. The result is balanced vasodilation, reducing preload and afterload, while simultaneously increasing SV and CO and promoting diuresis.⁹⁵ Nesiritide has not been studied widely in the cardiac surgery population, but it has been used anecdotally in patients with poor ventricular function and high filling pressures, pulmonary hypertension, or RV failure.⁹⁶ A related drug, human atrial natriuretic peptide, was shown in a small, randomized trial to reduce the need for dialysis and to improve dialysis-free survival after complicated cardiac surgery.⁹⁷

Angiotensin-converting enzyme (ACE) inhibitors also can cause venodilation and reduce preload. Alternatively, opioids or benzodiazepines, or both, used to reduce endogenous catecholamine release, should be considered in the patient who needs mechanical ventilation. Morphine causes histamine release, which directly induces venodilation. In the patient with oliguria and renal failure who is fluid overloaded, peritoneal dialysis, hemodialysis, or continuous hemofiltration or dialysis may be needed.^98,99

Contractility

Contractility is a well-defined concept in vitro, where it can be measured by the velocity of shortening of isolated muscle strips. However, it has been more complex to quantify the contractility of the intact heart because it has been difficult to find a variable to measure contractility that is also independent of preload and afterload. The pioneering work of Suga and Sagawa^100,101 has shown that contractility can be measured by the end-systolic elastance of the ventricle, defined as

in which P_ES is the end-systolic pressure, V_ES is the end-systolic volume, and V₀ is a dead-space term. E_ES is strictly determined by evaluating ventricular pressure-volume loops for different preloads or afterloads and by defining end-systole as the point in time at which the time-varying elastance is maximal.¹⁰² The slope of the line connecting the points at end-systole is E_ES. This parameter varies with changes in inotropic state but is nearly independent of preload and afterload. Routine measurement of end-systolic elastance is not clinically feasible. However, consideration of the above definition underscores the utility of TEE for the qualitative evaluation of contractility in the clinical setting. A decrease in contractility is manifested as some combination of a decrease in pressure or an increase in V_ES (i.e., a decrease in SV). End-systolic volume can be estimated using TEE. A large V_ES (implying a low ejection fraction) with a low or normal BP suggests a low value for E_ES and poor contractility. If BP is high, a large value of V_ES may be seen even if contractility is normal. By interpreting end-diastolic volume, end-systolic volume, and ejection fraction in the context of BP, an assessment of contractility is possible with TEE (see Chapters 5 and 12 to 14).

An alternative measure of contractility is the preload-recruitable stroke work, which is the slope of the line relating stroke work to preload.¹⁰³ In the operating room or ICU, it often is estimated by the extent of the increase in CO that accompanies an increase in preload and is not dependent on the availability of TEE. If preload is increased by a change in patient position, BP can be a surrogate for CO because it is unlikely that SVR will change in the short time needed for the position change. A change in BP, therefore, is proportional to the change in CO.

Therapy for decreased contractility should be directed toward correcting any reversible causes, such as myocardial depressants, metabolic abnormalities, or myocardial ischemia. If the cause of depressed myocardial contractility is irreversible, positive inotropic agents may be necessary to keep a CO satisfactory to support organ function (see Chapters 5, 10, 28, and 32).

Afterload

Afterload is a concept that is well defined in vitro, where it refers to the added tension imposed on isolated muscle strips with contraction, but it is harder to define in vivo. In analogy with in vitro studies, afterload can be equated with ventricular wall stress, expressed as the product of cavity radius times transmural pressure divided by wall thickness, as described by the law of Laplace. However, many investigators find this definition unsatisfactory because it implies the heart generates its own afterload and because afterload would be viewed as changing during the cardiac cycle.¹⁰⁴ If afterload is viewed as the external forces opposing ejection, possibly the best definition is the aortic input impedance, the complex ratio of pressure to flow, expressed in terms of magnitude, and the phase angle between flow and pressure for any given frequency. However, it has been difficult to quantitatively analyze the impact of impedance on overall cardiac performance (see Chapter 5). Sunagawa et al¹⁰⁵ proposed a simplified theory of ventricular-vascular coupling within the framework of the end-systolic pressure-volume relation. Using the definition of end-systolic elastance produces the following:

This means that an increase in SV implies a decrease in P_ES. The interpretation of this from the perspective of the heart is that the work that can be done is finite, and that a greater SV can only be achieved by decreasing the end-systolic pressure, if contractility (E_ES) is fixed. At the same time, it is known that from the perspective of the vasculature, if the SV increases, BP increases when vascular tone does not change.

The application of an electrical law describing constant voltages and flows to the circulation, in which pulsatile flow is generated by a pump, has resulted in estimates of afterload that are questionable.¹⁰⁴ Although SVR is a component of impedance, it cannot be equated with it. The correct downstream pressure is probably not the CVP.¹⁰⁶ There is instead a critical opening pressure that should be used in calculating SVR that is not measurable in routine clinical care.¹⁰⁶ Clinical use of such calculated resistances is made complex by the relation of CO to body size; the normal resistance of a small patient is much higher than that of a large one. The use of a resistance index (i.e., using CI instead of CO) partly overcomes this problem, but it is not widely used.

Calculated SVR continues to be widely used in guiding therapy or drawing conclusions about the state of the circulation. This should only be done with caution, if at all. SVR is not a complete indicator of afterload. Even if SVR were an accurate measure of impedance, the response to vasoactive agents depends on the coupling of ventricular-vascular function, not on impedance alone. Hemodynamic therapy should be guided based on the primary variables, BP and CO. If preload is appropriate, low BP and low CO are treated with an inotropic drug. If BP is acceptable (and preload appropriate) but CO is low, a vasodilator alone or in combination with an inotropic drug is used. If the patient is hypertensive (with low CO), vasodilators are indicated; if the patient is vasodilated (low BP and high CO), vasoconstrictors are used (Box 34-2).