Vector dynamocardiography

Vectordynamocardiography: basics and applications

Vector dynamocardiography (VDCG) is a method for diagnosing the cardiovascular system, which allows you to measure the electrical activity of the heart and determine its movement vectors in space. VDKG is a synthesis of two methods - vector ECG and dynamic ECG.

Vector ECG allows you to define each ECG lead as a vector with amplitude and direction values. Dynamic ECG, in turn, allows you to measure changes in the electrical activity of the heart over time.

VDKG uses these two methods in combination, which allows a more accurate determination of the electrical activity of the heart in three dimensions. This method is more sensitive than a regular ECG and can detect earlier changes in heart function.

The use of EDCG makes it possible to identify various disorders of the heart, such as rhythm and conduction disturbances, ischemia, cardiomyopathies, as well as other diseases associated with disturbances in the electrical activity of the heart.

VDCG can also be used to evaluate the effectiveness of treatments for heart disease and myocardial infarction, as well as to monitor patients with heart disease over the long term.

Although DCCG is a more accurate method for diagnosing the cardiovascular system, it is still not a common method in clinical practice. This is due to the fact that this method requires more complex equipment and special training of specialists.

However, DCCG is a powerful tool for diagnosing cardiovascular disease and may lead to more accurate diagnosis and treatment of patients with heart disease.

Vector dynamography is a method for studying cardiac activity based on the study of changes in the cardiac vector. This method allows you to assess the functional state of the heart muscle and its ability to contract and relax. This method is used in medicine to diagnose heart diseases and determine the effectiveness of treatment.

The essence of the method is that special sensors are applied to the patient’s body, which record signals that arise during the work of the heart muscle. These signals are then processed using a special computer program, which allows you to construct a vector diagram reflecting changes in cardiac condition over time.

This technique is one of the most modern methods in cardiology. It allows you to quickly and accurately determine the presence of pathology and its location, determine the function of the heart wall, and the degree of influence of disorders on blood circulation.

The use of vector-dynamic cardiography allows us to identify