Dear Editor:
The contribution of the Mexican School of Electrocardiography is based mainly on its deductive nature. Its main contributions include the description of the normal ventricular activation, the study of intraventricular conduction disorders1-2, description of the electrophysiological phenomena in acute acute myocardial infarction3 and the effect of the pressure and volume overloads in the heart. The first electrocardiographic description of volume overload in our institution was done by Dr. Cabrera when he observed changes in repolarization in V5-V6 in a patient with a peripheral arteriovenous fistula when he intermittent occluded and recorded it4-5. We discuss the ECG of a patient with mitral regurgitation as an example of the left ventricle’s volume overload and resolution of the abnormalities after surgical correction. Later, we conducted a review of the electrophysiopathological processes involved in the hemodynamic overloads with ECG as examples.
Case report
A 46-year-old male with 1-month dyspnea of exertion and non-productive cough; 3 weeks later, the dyspnea increased until presenting orthopnea. He was admitted to our institution with HR 112 bpm, RR 18 pm, BP 114/81 mm Hg, temperature 36.5°C, and SatO2 of 92%. The physical findings revealed a regurgitant systolic murmur in the left sternal border, with irradiation to the axilla. ECG showed tall pointed and symmetrical T waves in V5-V6 (Fig. 1a). Chest X-ray revealed dilation of the left cavities with pulmonary venocapillary hypertension. Transthoracic echocardiogram (TTE) showed severe mitral regurgitation (due to flail of the P2 segment of the posterior leaflet) with dilation of the left atrium and left ventricle and left ventricular end-diastolic volume of 140 ml/m2. The patient underwent mitral valve repair and annuloplasty with a prosthetic ring with adequate post-operative evolution; post-surgical electrocardiogram revealed resolution of the repolarization abnormalities (Fig. 1b), with an important reduction of the telediastolic volume of the left ventricle 101.8 mL/m2 determined by TTE.
Discussion
Abnormalities in T wave have been defined as “primary” when they are the consequence of alterations in repolarization, such as in myocardial ischemia or electrolyte imbalances or “secondary” when they are the result of alterations in the intraventricular conduction process, such as in branch blockages or hypertrophies6.
In his landmark paper, Dr. Enrique Cabrera (at the Electrocardiography Department of Instituto Nacional de Cardiología) established the following principles regarding the effect of pressure and volume overload on the electrocardiogram: (1) Starling mechanism is the main determinant of volume overloads, (2) each type of hemodynamic overload has its electrocardiographic representation, (3) right bundle branch block (RBBB) appears in the right ventricle’s (RV) volume overload, (4) there are tall R waves and secondary T waves in V1-V2 in the RVs pressure overload, and (5) there are primary T waves (tall, pointed, and symmetrical) in V5-V6 in the left ventricle’s volume overload5,6.
Left ventricular pressure overload
This electrocardiographic manifestation occurs in entities with increased systolic wall stress of the left ventricle (aortic stenosis, systemic arterial hypertension, hypertrophic cardiomyopathy). There are a ST-segment and asymmetric negative T wave in V5-V6 (Fig. 2a). This phenomenon is consequence of the greater wall thickness of the left ventricle wall, which delays the activation of the muscle near the epicardium and consequently repolarization, so the repolarization vector points from epicardium to endocardium, away from V5-V6; conditioning T-axis deviation opposite to the QRS axis7.
Left ventricular volume overload
This electrocardiographic changes occur in entities with increased diastolic wall stress of the left ventricle (Aortic regurgitation, mitral regurgitation, and ventricular septal defect). Its electrocardiographic expression is the presence of tall, pointed, and symmetric T waves in V5-V6 (Fig. 2b)5. There could be concave ST-segment elevation. It has been suggested that these findings may be a consequence of increased end-diastolic volume, end-diastolic pressure, and the consequent decrease in subendocardial coronary perfusion in diastole.
Right ventricular pressure overload
A similar phenomenon takes place in the RV when there is pressure overload. In this case, there are tall R waves with ST-segment depression and secondary asymmetric T waves in V1-V2, in addition to T-axis left deviation, opposite to the QRS axis5. This phenomenon can be observed in patients with pulmonary hypertension of different etiologies or in congenital heart diseases (Fig. 2c).
Right ventricular volume overload
Given the greater compliance and capacitance of the RV, entities with volume overload (atrial septal defect and tricuspid regurgitation) present the right RBBB instead of T wave abnormalities since RV tolerates great volume overloading without increasing its end-diastolic pressure (Fig. 2d)8.
Conclusions
The ECG is a low cost, accessible, and non-invasive tool. However, during the past decades, its interpretation has been limited to the recognition of electrocardiographic patterns. The Mexican School of Electrocardiography, established accurate diagnoses through deductive analysis. This method should be the one that predominates in the evaluation of the patient with suspected heart disease.