Cardiac cycle

Heart revolution' describes a single cardiac cycle in which systole (contraction of the myocardium) and diastole (relaxation of the myocardium) alternate periodically. The different phases are characterized by pressure and volume changes in the ventricles.

Filling phase
Includes systole of the atrium and late diastole of the ventricule, when the ventricules fill with blood. Pressure in the ventricles is (almost) constant, volume is increasing. The intraventricular pressure drops to zero during this phase (diastolic pressure of the ventricles), rising slightly during filling (up to 16 mmHg) - final (end)diastolic pressure in the left ventricle). The blood is driven by the influence of inertia of the blood flow and positive pressure in the atria (maximum 16 mmHg) into the ventricles (the pressure drops almost to zero). There are three successive phases: This pumps blood from the atria into the ventricles, ends ventricular diastole and begins the next phase. Normally, atrial systole contributes little to ventricular filling (about 8%). However, it becomes more important at elevated heart rates when diastole becomes shorter and without atrial systole there would be insufficient filling of the ventricles. It lasts 400-500 ms.
 * 1) phase of rapid filling of the ventricles (accumulated blood from the atria suddenly flows into the ventricles in a short time),
 * 2) the slow ventricular filling phase (blood from the veins flows through the atria and open valves straight into the ventricles),
 * 3) atrial systole.

Phases of isovolumic contraction
Ventricular volume does not change, intraventricular pressure increases'. This is the first part of ventricular systole. Myocardial contraction occurs. The onset of contraction appears on the ECG as the peak of the R rhythm. The semilunar valves are also closed, which we hear as systolic echo. Ventricular pressure continues to rise due to myocardial contraction around incompressible fluid. Phase duration 60 ms.

Ejection phase
The pressure in the chambers does not change, the volume decreases. The final part of ventricular systole. Occurs when ventricular pressure exceeds the diastolic pressure in the aorta (80 mmHg) and pulmonary (10 mmHg).Semilunar valves open and ventricular contents are expelled into the arteries. Maximum pressure in the left ventricle is 120-140 mmHg (up to 300 mmHg under load), in the right 20-30 mmHg. The volume of the ventricles is drained by the expulsion of the pulse volume at the minimum value. After reaching a lower value of pressure in the ventricles than in the arteries, the semilunar valves close. Phase duration 200 ms. An important concept is ejection fraction: EF = HRV / EDV (heart rate volume/end diastolic volume). It indicates the mechanical function of the left ventricle, physiologically EF is greater than 60%.
 * With the ejection of blood from the ventricles into the aorta, two phases can be described: first, the ejection is fast - the so-called fast ejection phase, then it slows down - the so-called slow ejection phase.

Isovolumic relaxation phase
It occurs after ventricular contraction has peaked. Intraventricular pressure gradually decreases, semilunar valves close. Once they close, ventricular pressure begins to fall rapidly without changing ventricular volume. It lasts '50 ms and ends when the pressure in the ventricles drops below the pressure in the atria (the valves open and the next filling phase occurs).

Contraction
The Myocardium is similar to the skeletal muscle in its mechanics of contraction. In the heart, there is isotonic contraction (tension does not change, but the length of the muscle shortens) - a change in the volume of the ventricles at the same force of contraction, and isovolumic contraction - a change in the force of contraction of the ventricles at the same volume filling. Two types of loads are distinguished:
 * afterload - the load on the myocardium during the transition from isovolumic contraction to isotonic contraction (pressure to open the semilunar valves),
 * preload - the load on the relaxed myocardium that determines its initial length for the start of contraction (pressure at the end of filling).

Used literature

 * TROJAN, Stanislav, et al. Lékařská fyziologie. 4. vydání. Praha : Grada, 2003. 772 s. s. 239-245.  ISBN 80-247-0512-5.