The RV is composed of the inlet, the free wall, and the infundibulum and has a superficial and deep muscle layer. The superficial layer is circumferential and although the fibers are initially parallel to the atrioventricular (AV) groove, they later run obliquely toward the apex [1]. These are continuous with the superficial fibers of the left ventricle (LV). The deep layer runs longitudinally from the base to the apex. The major vector of contraction of the RV is in this longitudinal plane. The RV wall thickness is only 2–5 mm (compared to LV wall thickness 7–11 mm), and the RV mass is 26±5 g/m² (compared with LV mass 87±12 g/m²). The shape and the relatively thin wall make the RV a highly compliant chamber with the ability to adapt to volume overload but not pressure overload [2,3].

The left-sided chambers drain oxygenated blood from the pulmonary veins and then pump this through the high-pressure peripheral circulation. The LV is a complex, truncated ellipsoid structure that can eject approximately 100 mL of blood at pressures of over 200 mmHg against a relatively noncompliant systemic circulation during exercise [4–6]. It consists of three layers of myofibrils that are arranged in counterwoven helical arrangements with a major vector of contraction being both longitudinal and circumferential [5]. The contribution of torsion or rotational motion is specific to the LV, with the basal segments and apical segments moving in opposite direction. This not only helps to eject blood more efficiently but also allows the storage of energy that can then be released during diastole. The LV can then refill at low filling pressures within as short a time as 100 ms [6]. LV diastolic filling starts later and finishes earlier, with higher filling velocities, compared to the RV. The average end-diastolic volume (EDV) indexed to body surface area (BSA) is less in the LV compared to the RV (66 mL/m² compared with 75 mL/m²); therefore, the LV ejection fraction (EF) is greater than the RVEF (LVEF >50% compared with RVEF 40%–45%) [1,2]. LV stroke work index is approximately five times that of the RV (50±20 g/m² compared with 8±2 g/m²), as it is required to pump into a high resistance systemic circuit (average systemic vascular resistance is 1100 dynes s cm^-5 compared with the average pulmonary vascular resistance of 70 dynes s cm^-5) [1,7,8]. The left and right ventricles are separated by the interventricular septum, which is concave towards the (LV). The pressures and oxygen saturation of each cardiac chamber is summarized in Fig. 1.1.

Each side has a thin-walled atrium that acts as a conduit, reservoir, and pump. Atrial myocytes are smaller and have faster repolarization rates and fewer mitochondria than ventricular myocytes. The atria and ventricles act as a functional syncytium with the cardiac myocytes of each chamber interconnected with intercalated discs and gap junctions, which allow the rapid propagation of action potentials, allowing, in turn, synchronized cardiac contraction [9,10]. The efficient pumping of blood depends on the correct electrical activation by excitatory and conductive muscle fibers—namely, the sinus and AV nodes, connected by the internodal tracts, the AV His bundles, and the intraventricular conduction systems [10,11]. Given that the two ventricles anatomically share the interventricular septum, myocardial fibers, and the pericardium, in disease states one ventricle can influence...