Abstract
The aim of the study was to describe the boundary between the phases of rapid and slow ejection in the cardiac cycle and to define the exact location of the j point on ECGs.Materials and Methods.The work is based on the theory of heart cycle phase analysis using mathematical equations of hemodynamics. The balance of phase diastolic and systolic blood volumes depending on the duration of the cardiac cycle phases has been verified by these equations. The interrelation of phase duration and phase blood volumes was employed to exactly define the cardiac cycle boundaries on ECGs. Synchronous recording of the ECG and rheogram was used to determine the precise location of the j point.Results.The exact boundary between the phases of rapid and slow ejection has been defined. A new point L determining the boundary between SL–Lj phases was introduced for its designation.Conclusion.The j point was previously considered to be part of an ECG depending on the body temperature and which does not always appear. It had an ambiguous definition: Osborn wave or j wave. At the same time, the precise boundary between the rapid and slow ejection phases, the blood volumes of which in the total amount are equal to the blood stroke volume, has not been identified exactly. The work performed allows for accurate definition of criteria for recording rapid and slow ejection phases and j point location on the ECG.
Highlights
An important place is occupied by an ECG interpretation based on the analysis of intervals, segments, and waves [1, 2]
Understanding of the boundaries of the systolic part of the ECG cardiac cycle structure has been formed from multiple contradictions
Voronova were used in our work [9]. These equations are based on the indirect methods of calculating phase blood volumes
Summary
An important place is occupied by an ECG interpretation based on the analysis of intervals, segments, and waves [1, 2]. Though this analysis has been used for a long time, no well-defined criteria of defining their beginning and end have been established so far. Understanding of the boundaries of the systolic part of the ECG cardiac cycle structure has been formed from multiple contradictions. This is referred to as the ST segment, the structure of which is poorly studied. To compensate for the knowledge, high-resolution electrocardiography was proposed [3], it failed to achieve the goal and the ST segment remained terra incognita in the perception of the investigators
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
