Electrical Power–Line Interference

Electrical power–line interference (60 Hz) is a common environmental problem. Power lines and other electrical devices radiate energy that can enter the monitor by poor electrode contact or cracked or poorly shielded lead cables. Interference can also be induced electromagnetically as these signals radiate through the loop formed by the body, lead cables, and monitor. A line frequency “notch” filter is often used to remove 60-Hz noise.

Electrocautery

Electrocautery units generate radiofrequency currents at very high frequencies (800–2000 kHz) and high voltages (1 kV, which is 100 times greater than the ECG signal). Older units used a modulation frequency of 60 Hz, which spread substantial electrical noise into the QRS frequency range of the ECG signal. Newer units use a modulation frequency of 20 kHz, thus minimizing this problem; however, reports still exist of electrocautery as a cause of artifactual ST-segment changes in intraoperative electrocardiograms. To minimize electrocautery artifact, the RL reference electrode should be placed as close as possible to the return plate, and the ECG monitor should be plugged into a different power outlet from the electrosurgical unit.

Clinical Sources of Artifact

Clinical devices in physical contact with the patient, particularly through plastic tubing, may at times cause clinically significant ECG artifact. Although the exact mechanism is uncertain, two leading explanations are either a piezoelectric effect secondary to mechanical deformation of the plastic or buildup of static electricity between two dissimilar materials, especially those materials in motion (as in the case of cardiopulmonary bypass [CPB] tubing and the roller pump head). In this situation, the electricity generated in the pump flows into the patient through the tubing and is picked up by the electrodes. This artifact is not related to the electricity used to power the CPB pump because it has been reproduced by manually turning the pump heads.

ECG interference during CPB has been recognized for many years. It is manifested by marked irregularity of the baseline, similar to ventricular fibrillation, with a frequency of 1 to 4 Hz and a peak amplitude up to 5 mV. Uncorrected, it may make effective diagnosis of arrhythmias and conduction disturbances very difficult ( Fig. 9.2 ), especially during the critical period of weaning from CPB, and it may also make accurate determination of asystolic arrest from cardioplegia difficult. Accumulation of static electricity is assumed to be the major etiologic factor. Khambatta and colleagues recommended maintaining ambient temperature higher than 20°C.

(Top) Baseline artifact simulates atrial flutter in a cannulated patient. (Middle) This patient had stable arterial pressure just before institution of full cardiopulmonary bypass, similar to that described by Kleinman and associates. (Bottom) The “pseudo-flutter waves” are corrected by application of the grounding cable.

(From London MJ, Kaplan JA. Advances in electrocardiographic monitoring. In: Kaplan JA, Reich DL, Konstadt SN, eds. Cardiac Anesthesia . 4th ed. Philadelphia: Saunders; 1999.)

Detection of Myocardial Ischemia

The ST segment is the most important portion of the QRS complex for evaluating ischemia. It may come as a surprise that no gold standard criteria exist for the ECG diagnosis of myocardial ischemia. Many anesthesiologists, when evaluating an electrocardiogram for signs of ischemia, look for signs of repolarization or ST-segment abnormalities. Many other signs of myocardial ischemia may also be seen in the electrocardiogram, including T-wave inversion, QRS and T-wave axis alterations, R- or U-wave changes, or the development of previously undocumented arrhythmias or ventricular ectopy. None of these, however, is as specific for ischemia as ST-segment depression or elevation. Depending on the location of the infarction, and the observed leads, the ST-segment changes have a specificity of 84% to 100% and a sensitivity of 12% to 66% for myocardial ischemia.

The origin of the ST segment, at the J point, is easy to locate. However, J-point termination, which is generally accepted as the beginning of any change of slope of the T wave, is more difficult to determine. Physiologically normal persons may have no discernible ST segment because the T wave starts with a steady slope from the J point, especially at rapid heart rates. The TP segment has been used as the isoelectric baseline from which changes in the ST segment are evaluated, but with tachycardia, this segment is eliminated, and, during exercise testing, the PR segment is used. The PR segment is used in all ST-segment analyzers.

Repolarization of the ventricle proceeds from the epicardium to the endocardium, opposite to the vector of depolarization. The ST segment reflects the midportion, or phase 2, of repolarization during little change in electrical potential. It is usually isoelectric. Ischemia causes a loss of intracellular potassium, resulting in a current of injury. With subendocardial injury, the ST segment is depressed in the surface leads. With epicardial or transmural injury, the ST segment is elevated ( Figs. 9.3 and 9.4 ). Although myocardial ischemia may manifest in PR-segment, QRS complex, ST-segment, or T-wave changes, the earliest ECG signs of ischemia are typically T-wave and ST-segment changes. With myocardial ischemia, repolarization is affected, resulting in downsloping or horizontal ST-segment depression. Various local effects and differences in vectors during repolarization result in different ST-segment morphologic features that are recorded by the different leads. It is generally accepted that ST-segment changes in multiple leads are associated with more severe degrees of coronary artery disease (CAD).

Pathophysiology of ischemic ST-segment elevation. Two basic mechanisms have been advanced to explain the elevation seen with acute myocardial injury. (A) Diastolic current of injury. In this case (first QRS-T complex), the ST-segment vector is directed away from the relatively negative, partly depolarized, ischemic region during electrical diastole (TQ interval), and the result is primary TQ-interval depression. Conventional alternating current electrocardiograms compensate for the baseline shift, and an apparent ST-segment elevation (second QRS-T complex) results. (B) Systolic current of injury. In this case, the ischemic zone is relatively positive during electrical systole because the cells are repolarized early and the amplitude and upstroke velocity of their action potentials may be decreased. This injury current vector is oriented toward the electropositive zone, and the result is primary ST-segment elevation.

(From Mirvis DM, Goldberger AL. Electrocardiography. In: Bonow RO, Mann DL, Zipes DP, Libby P, eds. Braunwald’s Heart Disease: A Textbook of Cardiovascular Medicine . 8th ed. Philadelphia: Saunders; 2008:174.)

Current of injury patterns with acute ischemia. (A) With predominant subendocardial ischemia the resultant ST-segment vector is directed toward the inner layer of the affected ventricle and the ventricular cavity. Overlying leads therefore record ST-segment depression. (B) With ischemia involving the outer ventricular layer (transmural or epicardial injury), the ST-segment vector is directed outward. Overlying leads record ST-segment elevation. Reciprocal ST-segment depression can appear in contralateral leads.

(From Mirvis DM, Goldberger AL. Electrocardiography. In: Bonow RO, Mann DL, Zipes DP, Libby P, eds. Braunwald’s Heart Disease: A Textbook of Cardiovascular Medicine . 8th ed. Philadelphia: Saunders; 2008:174.)

The criteria for myocardial infarction (MI) are divided into two categories: ST-segment elevation MI (STEMI), and ST-segment depression/T-wave change MI (NSTEMI). The J point is located at the juncture of the QRS complex and the ST segment, and it is used to measure the magnitude of the ST-segment deflection as compared with the baseline of the electrocardiogram. A new J-point elevation of 0.1 mV or greater is required in all leads except V ₂ and V ₃ to meet the criteria for STEMI. J-point elevations of up to 0.25 mV may be seen in leads V ₂ and V ₃ in healthy men younger than 40 years of age; however, this finding decreases with age and is less prominent in women. The J-point elevations must be seen in two or more contiguous leads for the satisfaction of ST-segment elevation criteria. New horizontal or downsloping ST-segment depressions of 0.05 mV or greater or T-wave inversion of 0.1 mV or greater in two contiguous leads with an R-wave–to–S-wave ratio greater than 1 satisfy the criteria for NSTEMI. However, ST-segment elevations are more specific than ST-segment depressions and/or T-wave inversions for localizing the site of ischemia. ST-segment elevation generally suggests greater degrees of myocardial damage than ST-segment depression or T-wave changes. Previously inverted T waves may pseudonormalize during episodes of acute myocardial ischemia ( Appendix 9.1 ).

Nonspecific ST-segment depression can be related to drug use, particularly digoxin. Interpretation of ST-segment changes in patients with left ventricular hypertrophy is particularly controversial given the tall R-wave baseline, J-point depression, and steep slope of the ST segment.

ST-segment elevation is rarely reported in the setting of noncardiac surgical procedures. However, it is commonly observed during weaning from CPB in cardiac operations and during CABG procedures (on and off pump) with interruption of coronary flow in a native or graft vessel. ST-segment elevation in a lead with a Q wave should not be analyzed for acute ischemia, although it may indicate the presence of a ventricular aneurysm.

Anatomic Localization of Ischemia With the Electrocardiogram

As noted earlier, ST-segment depression is a common manifestation of subendocardial ischemia. From a practical clinical standpoint, it has a single major strength and limitation. Its strength is that it is almost always present in one or more of the anterolateral precordial leads (V ₄ –V ₆ ). However, it fails to “localize” the offending coronary lesion and has little relation to underlying segmental asynergy.

In contrast, ST-segment elevation correlates well with segmental asynergy and localizes the offending lesion relatively well. Reciprocal ST-segment depression often is present in one or more of the other 12 leads. In patients with angiographically documented single-vessel disease, ST-segment elevation (as well as Q waves or inverted T waves) in leads I, aVL, or V ₁ through V ₄ is closely correlated with disease of the left anterior descending coronary artery, whereas similar findings in leads, I, III, and aVF indicate disease of the right coronary or left circumflex arteries (surprisingly, the latter two cannot be differentiated by ECG criteria).

Clinical Lead Systems for Detecting Ischemia

Early clinical reports of intraoperative monitoring using the V ₅ lead in high-risk patients were based on observations during exercise testing, in which bipolar configurations of V ₅ demonstrated high sensitivity for myocardial ischemia detection (up to 90%). Subsequent studies using 12-lead monitoring (torso-mounted for stability during exercise) confirmed the sensitivity of the lateral precordial leads. Some studies, however, reported higher sensitivity for leads V ₄ or V ₆ compared with V ₅ , followed by the inferior leads (in which most false-positive responses were reported).

Intraoperative Lead Systems

The cardiac anesthesiologist encounters a variety of ECG changes consistent with myocardial ischemia or infarction at many phases of the perioperative period in patients undergoing cardiac operations. In the majority of these patients (ie, those with known CAD), the sensitivity and specificity of the major signs described are high, and few false-positive or false-negative changes are encountered. However, the abnormal physiology of CPB, including acute changes in temperature, electrolyte concentrations, and catecholamine levels can significantly influence sensitivity and specificity. In addition, patients undergoing valve replacement, even those without coronary artery lesions, can develop significant subendocardial and transmural ischemia (ie, coronary artery embolus of valve calcification, vegetations, or air).

Detecting and recognizing the clinical significance of various ECG signs of ischemia or infarction and coordinating the findings with transesophageal echocardiography (TEE) can enhance patient care in the acute setting, as in emergency treatment of coronary artery spasm or air embolus, or by alerting the surgeon that myocardial revascularization may have been inadequate. This may lead to reexploration of a saphenous vein or internal mammary artery anastomosis, especially if the TEE data support the diagnosis of ischemia.

The early reports recommending routine intraoperative monitoring of V ₅ in high-risk patients cited exercise tolerance tests as the source of their recommendations. Subsequently, the recommended leads for intraoperative monitoring, based on several clinical studies, did not differ substantially from those used during exercise testing, although considerable controversy on the optimal leads persists in both clinical settings. The use of continuous ECG monitoring in the coronary care unit has received increasing attention. A clinical study using continuous, computerized 12-lead ECG analysis in a mixed cohort reported that almost 90% of changes involved ST-segment depression alone (75% in V ₅ and 61% in V ₄ ). In approximately 70% of patients, significant changes were observed in multiple leads. The sensitivity of each of the 12 leads in that study is shown in Fig. 9.5 . When considered in combination, sensitivity for the standard clinical combination of leads II and V ₅ was 80%.

Single-lead sensitivity for the intraoperative detection of ischemia based on 51 episodes detected in 25 patients undergoing noncardiac surgical procedures. Sensitivity was calculated by dividing the number of episodes detected in that electrocardiographic (ECG) lead by the total number of episodes. Sensitivity was greatest in lead V5, and the lateral leads (I, aVL) were insensitive.

(Reproduced with permission from London MJ, Hollenberg M, Wong MG, et al. Intraoperative myocardial ischemia: localization by continuous 12-lead electrocardiography. Anesthesiology . 1988;69:232.)

Electrocardiographic Changes Resulting From Electrolyte Disorders

Cardiac myocytes exhibit a long action potential (200–400 ms) compared with neurons and skeletal muscle (1–5 ms). Multiple different channels are involved in cardiac muscle depolarization and repolarization. Sodium and calcium channels are the primary carriers of depolarizing current in both atria and ventricles. Inactivation of these currents and activation of potassium channels are predominantly involved in repolarizing the cardiac cells, thereby reestablishing the negative resting membrane potential. Thus it is not surprising that perturbations in the plasma concentrations of potassium and calcium ions lead to changes in the finely tuned cardiac electrical activity and the surface electrocardiogram. They typically cause changes in repolarization (ST-T-U waves) and can also lead to QRS complex prolongation.

Medications

Many antiarrhythmic medications are used in the perioperative period in patients undergoing cardiac surgical procedures. Generally, drugs that increase the duration of the cardiac action potential prolong the QT interval. These include class Ia and Ic antiarrhythmic drugs (eg, quinidine, procainamide), phenothiazines, antidepressants, haloperidol, and atypical antipsychotic agents. Intravenous amiodarone, commonly used in the management of perioperative arrhythmias, also causes QT-interval prolongation. Other class III antiarrhythmic drugs (eg, sotalol) cause QT-interval prolongation as well. Unlike class Ia and III antiarrhythmic drugs, digitalis glycosides shorten the QT interval and often cause “scooping” of the ST-T wave complex.