UA143614U - METHOD OF EVALUATION OF ELECTRODE CONTACT WITH MYOCARDIAL TISSUE IN RADIO FREQUENCY CATHETER ABLATION OF ARRHYMOGENIC ZONES OF HEART - Google Patents

Abstract

The method of assessing the contact of the electrode with myocardial tissue during radiofrequency catheter ablation of arrhythmogenic zones of the heart includes the construction of an anatomical map of the heart chamber, localization of the catheter and radiofrequency ablation points (RFA) in the navigation system Ensite Velosity NavX (St. Jude medical, USA) x, y, z). Data with coordinates (x, y, z) are transferred to the obtained model of the constructed individual anatomy of the heart chamber in the Matlab software environment, a three-dimensional model of the inner surface of the heart is reproduced and radiofrequency points in the color spectrum corresponding to different electrode distances from myocardial tissue ablation time, and the points of the RFA are divided into four groups, depending on how far the electrode is from the myocardium: from 0.05 to 2 mm - red dots - good contact force; from 3 to 5 mm - green dots - middle contact; from 6 to 8 mm - blue dots - weak contact; from 9 to 12 mm - purple dots - no contact.

Description

The useful model belongs to the field of medicine and medical technology, in particular to cardiac surgery and cardiology, and can be used when performing catheter radiofrequency ablation (RFA) of arrhythmogenic zones of the heart to assess the contact of the electrode with the myocardial tissue in order to predict the effectiveness of the procedure.

Recovery of myocardial activity in the zone of destruction is the main cause of arrhythmia recurrence after RFA. Regulation of the depth of destruction, as a rule, is carried out by choosing the standard size of the electrode for ablation, the optimal power of the current, the duration of the application and reaching the required temperature in the area of interaction. An important factor in the efficient delivery of RF energy to the myocardial tissue and the formation of reliable destruction is a good and stable contact of the electrode with the surface of the heart |11.

Until recently, there were only indirect indicators for assessing the contact of the electrode with the myocardial tissue, among which - the movement of the tip of the catheter together with the wall of the heart in the X-ray mode, the rise of the 5T segment on the monopolar electrogram and the change in the impedance of the tissue during the application of radiofrequency ablation |2)І. These methods remain the most widely used in clinical practice due to their simplicity and versatility, do not require additional specialized equipment, but are not sufficiently accurate.

To date, there are two technologies for quantifying and visualizing the contact force between the electrode tip and myocardial tissue, provided by different companies: based on spring deformation (Viozepze UWebzivg, USA) and resistance change (51 Ucde Medisai Ips., USA).

ZtapToysp m Saineieg (Viosepze Merciei, USA), is a contact force monitoring technology integrated into the tip of the Peptosoo irrigation catheter (Du Ztaptoysi mmM and SAVTOF 3 electro-anatomical mapping system. A tiny spring is installed in the distal tip of this catheter to connect the distal dome tip with proximal second electrode ring The degree of spring compression and/or extension is determined every 50ms using three receiving sensors located at the base of the spring Contact force values are visualized by various methods in the SAVTO 3 system, in the form of real-time graphs of value, direction and contact force Quantitative contact force is visualized on the Sapo Z screen as the average or maximum value within a given time window, and the direction of force is displayed as a color-coded arrow vector on the tip image

From the catheter; the real-time force graph is displayed in a separate window to visualize chronological changes during the cardiac cycle |41.

Epoie Sopiasi Tnegaru "M (51 Dide Medisai, USA) presents information on the contact force obtained from measuring the impedance between the tip of the catheter and the myocardial tissue.

Radio frequency energy reaching the human body creates an alternating current circuit. In this model, in addition to the active component, there is also a reactive component of the capacitor type of cell behavior (the charge gradient created by the lipid bilayer) to create resistance to the electric current.

Impedance is represented as the derivative of the complex number of active and reactive resistances. To measure impedance, this system applies a marginal (100 μA at 20 kHz) alternating current between the tip of the catheter and two indifferent plates on the body surface.

The equivalent circuit for this configuration is modeled in the form of three networks, each of which contains a resistor and a capacitor (ANSsottop, BSA, VSV, respectively). If the two indifferent plates are physically close to each other, the HCsotop network represents not only the local impedance at the catheter tip-to-tissue interface, but also includes the thoracic impedances between the heart and the body surface. On the other hand, if the plates are placed further from each other,

VShottop displays only the impedance of the catheter tip and the tissue. The local active and reactive resistances derived from the value of the local resistance on the Vsottop are again integrated mathematically into one value, which is called the electrical connection index. The index of electrical communication is displayed in the Ep5ye Mauch"M system in three ways: in the form of scrolling of the signal; numerical value; and in the form of color coding of the active electrode of the catheter |5I.

The method of constructing an electroanatomical model of the heart and drawing points on it was used as the closest analogue for the development of a method of assessing the contact of the electrode with the myocardial tissue

RF destruction in the navigation system of Eps5ii Meiosiu Mauch (51. University of Technology, USA). In it, the anatomical model of the heart chamber is represented by a set of points in three-dimensional space with coordinates (5 В; 7), connected by a polygonal grid into a three-dimensional structure. The points of RF destruction are also displayed in the coordinate system in two versions - the position of the electrode at the time of ablation (ХХ У 21) and the projection of the application on the surface of the heart model (2 У 22),

The disadvantages of these systems for assessing the strength of contact between the electrode and the heart tissue are the impossibility of using them without a specialized RFA catheter.

The useful model is based on the task of developing a method of independent automated complex quantitative assessment of electrode contact with myocardial tissue during radiofrequency ablation, which, when using all types of catheters and digital data of maps of individual heart anatomy and points of destruction obtained from existing electroanatomical mapping systems, will allow forecasting the effectiveness of RF applications by displaying them on the surface of the heart in different colors.

The task is solved by the fact that the method of assessing the contact of the electrode with the myocardial tissue during radiofrequency catheter ablation of arrhythmogenic zones of the heart, which includes the construction of an anatomical map of the heart chamber, localization of the catheter and points of radiofrequency ablation (RFA) in the navigation system of Ep5zie Meiosyu MakkhX (51. Utsde tedisa! , USA) in the form of points with coordinates (5 У, 7), according to the useful model, the data with coordinates (С У; 7) are transferred to the obtained model of the built individual anatomy of the heart chamber in the Maiyab software environment, a three-dimensional model of the inner surface of the heart is reproduced and applied on it, the points of radio frequency destruction in the color spectrum corresponding to the different distance of the electrode from the myocardial tissue during ablation, and the RF points are divided into four groups, depending on the distance at which the electrode is from the myocardium: from 0.05 to 2 mm - red dots - good contact force; from Z to 5 mm - green dots - middle contact; from b to 8 mm - blue dots - weak contact; from 9 to 12 mm - purple dots - no contact.

An original approach of exporting the data of the built individual anatomy of the heart chamber in the digital form of points with coordinates (5 В; 7) from the Epwie system is proposed.

Meiosyu Mauch (51. Dide TeisaI, USA) in the Maiar software environment. With the help of the "ezpnare" function, data is reorganized into a matrix and "zipase" - reproduction of a three-dimensional model of the inner surface of the heart using the finite element method. The "rioi3" function is applied to the model of radio frequency destruction points in the color spectrum, which corresponds to the different distance of the electrode from the myocardial tissue during ablation. It is determined by the formula for calculating the distance (I ; Mm) between two points in space:

SM -hou (y - y) (227

RFA points are divided into four groups, depending on the distance the electrode is from the myocardium: from 0.05 to 2 mm - red points - good contact force; from Z to 5 mm - green dots - middle contact; from b to 8 mm - blue dots - weak contact; from 9 to 12 mm - purple dots - no contact.

The differential separation of the numerical values of the distance according to the degree of contact was determined in the course of experimental studies on the removed heart of a pig and in the course of clinical observations when applying other criteria for assessing the force of contact and the size of the destruction (a drop in the amplitude on the endogram of the ablation electrode by half, a change in the impedance of the tissue during

RFA) |IbY.

The method of using this technique is as follows:

From the navigation system Epvziie Meiosyu MaukhX (51, Utsde Tedisai, USA), which is used to build an anatomical map of the heart chamber, localization of the catheter and RFA points, the data of the operation in the digital form of points with coordinates are exported to the Mayarb software environment.

A three-dimensional model of the heart chamber is being constructed, which is a mathematical reproduction of the constructed anatomical map in the Epsier Meiozpyu Mach system.

RFA points are applied to the obtained heart model in the color spectrum, which characterizes the distance of the electrode to the myocardial tissue and gives an estimate of the point contact with effective and insufficient destructive influence.

Blue and violet RFA points are present, which indicates that the contact force in these places is weak and absent, and therefore the destruction in them is not effective enough. In this situation, it is expedient and recommended to re-apply the RF application in these areas of the heart.

The method is illustrated by the following example of use.

Example 1. Patient N., 54 years old, was admitted to the State Institution "National Institute of Cardiovascular Surgery named after M.M. Amosov of the National Academy of Medical Sciences of Ukraine" due to a recurrence of atrial fibrillation after 1 year. after successful RU isolation of the pulmonary veins from the atrium, which was verified by the absence of conduction between them in the operating room.

Since there was a recurrence of the arrhythmia, not all points of destruction were effective. During the repeat operation, electroanatomical mapping was performed, a potential map of the left atrium was constructed, which showed in color the presence (purple, red) and absence (gray) of activity in the myocardial tissue. The right lower and left upper pulmonary veins were not completely isolated.

When performing the second RFA operation, the areas of the myocardium, in which a breakdown was registered for the passage of pathological excitation, were repeatedly subjected to destruction by electric current.

Tachycardia stopped and pathological potentials disappeared on the intracardiac endogram, when RFAA was applied in the area shown by the red dots on the model of the left atrium in

Epoye Meiozpu Mahmh.

When evaluating the effectiveness of the contact of the electrode with the wall of the surface of the heart of the patient's first operation

N. in the developed automated complex in Mayar, these areas are defined by blue and purple dots, as with insufficient contact of the electrode with the myocardial tissue.

Sources of information: 1. Ravzi, Shie Rgezepi, apa She Eshige oi Sagaias Atnuiptia Abiaiyop. / U.sh. Apagade, I. Vimaga, Y..

Masiye // Sapadiap doshigpai oi Sagaioiodu. - 2014. - Moishte Z0, Ivvtse 12. - R. 431-441. 2. Veiayopz5Ppir reimeyep saipeieg sopiasi yogse apa gadioitedoepsu Ieviop 5i2e apa ipsidepse oi vivat ror ip Pe reaiyipd sapipe Neag!!: eIesigodgat atriytsaee, itredapse, apa eiIesigode Ietregaiige age roog rgedisyugv oi eIesigo sodei-iv. / A. Ikeda, N. MaKadama, N.

Iatbrepy, O.S. 5Nan, E. EopsK, A. Myigagi, T. 5Nagta, 9.M. Riina, V. and Aglaga, M.M. dasKtap //

Sixxaiop: Agtpuytia apa EIesigorpusioiodu. - 2014. - Moishte 7, Iv5tse 6. - R, 1174-1180.

З. Zuziet apa m/yp Epoiye

MeIosyu Sopiasi buviet (Sopiasi ARI) (pNrz//siiiipisaigiaIv.dom/si2/56pom/МСТ01401361) 5. Saiyeiieg-iiz5ce sopiasi yogse deiegptipev5 aiya! isIestodgat sNagasiegiviis5 reigoge apa Ieeviop eynisasu apyeg apita! rytopagu vyp izoiiayop ip pitapv. / 5. Kitag, M. Spap, U. Iye, M.S. Mopo, M.

Utsai, 9U.V. Mopop, 5.3. 6. Zrepse, K. Naipogap, R.M. Kiveg, U.M. Kaitap // mahtpai oi Sagaiiomazsshiag EIesitorpuzioiodu. - 2014. - Moishte 25. - R. 122-129. 7. Agea ipaeg She gea!-yyte sopiasi yogse sigme (ogse-yyte ipiedga!) rgedisi5 gadioitednepsu Ieviop 5i7e ip ap ip migo sopigasiye toavi!. / O.S. Znap, N. and Atrep, N. MaKadaula, A. | apdepKatr, M. Aebu, a. And eo // doshptai oi Sagaiomazsciag Eiesitorpuzioioadu. - 2010. - Moishte 21, Iz5ce 9. - R. 1038-1043.

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Claims (1)

USEFUL MODEL FORMULA A method of assessing the contact of the electrode with the myocardial tissue during radiofrequency catheter ablation of arrhythmogenic zones of the heart, which includes the construction of an anatomical map of the heart chamber, localization of the catheter and radiofrequency ablation (RFA) points in the navigation system Epeye Meiosiu Mauch (51. Utsde tweeaisa!, USA) in the form of points with coordinates (x, y, 7), which differs in that the data with coordinates (x, y, 2) are transferred to the obtained model of the constructed individual anatomy of the heart chamber in the Maillard software environment, a three-dimensional model of the inner surface of the heart is reproduced and applied on it, the points of radio frequency destruction in the color spectrum corresponding to the different distance of the electrode from the myocardial tissue during ablation, and the RF points are divided into four groups, depending on the distance at which the electrode is from the myocardium: from 0.05 to 2 mm - red dots - good contact force; from Z to 5 mm - green dots - middle contact; from b to 8 mm - blue dots - weak contact; from 9 to 12 mm - purple dots - no contact. 00 Computer keyboardG. Payalnikovo (00000000 Ministry of Economic Development, Trade and Agriculture of Ukraine, St. M. Hrushevskyi, 12/2, Kyiv, 01008, Ukraine SE "Ukrainian Institute of Intellectual Property", str. Glazunova, 1, Kyiv - 42, 01601