CN212395037U - Ablation catheter - Google Patents

Abstract

The utility model provides an ablation catheter, which comprises an ablation electrode and a catheter body, wherein the ablation electrode is positioned at the end part of the catheter body and is used for generating radio frequency current so as to perform radio frequency ablation treatment on a focus part, the ablation electrode is provided with a cavity, an injection port communicated with the cavity and a plurality of cooling holes, and cooling liquid is sprayed out of the cooling holes so as to cool the ablation electrode; the outer surface of the ablation electrode is provided with a groove, and a cooling hole is also arranged in the groove. The body is equipped with the visual electrode that is used for monitoring the body form. According to the utility model discloses an ablation catheter, through set up the recess at the surface that melts the electrode, has increased the effective heat radiating area who melts the electrode. In addition, the ablation electrode is provided with a plurality of cooling holes, cooling liquid can be sprayed out of the cooling holes to cool the ablation electrode, the cooling and radiating effect of the ablation electrode is improved, in addition, the tube body is provided with the visible electrode, an operator can timely and conveniently obtain the form of the ablation catheter, and the reliability and the safety of the operation are improved.

Description

Ablation catheter

Technical Field

The utility model relates to the technical field of medical equipment, especially, relate to an ablation catheter.

Background

Catheter radio frequency ablation is the most common minimally invasive interventional technique for treating arrhythmia at present, and the basic principle is as follows: the radiofrequency ablation catheter is sent to a target heart cavity through sheath tubes with different lengths, the focus of origin of arrhythmia is accurately positioned under the guidance of a three-dimensional mapping technology, a columnar ablation electrode at the head end of the catheter is contacted with the focus tissue with effective contact force, and then radiofrequency current is sent through a loop electrode attached to the skin of the body surface of a patient. Radio frequency current flows through lesion tissues below the electrodes through the electrodes to generate heat in the tissues, and when the temperature reaches the degree of coagulation necrosis, the tissues permanently lose electrophysiological activity, and the arrhythmia is cured.

When the ablation electrode sends current to cause the tissue to generate heat, the tissue is passively heated due to the temperature rise of the tissue due to the heat conduction and heat absorption performance of the electrode material. When an electrode is overheated and the blood circulation around the electrode is insufficiently cooled, the underlying tissue of the electrode is easily scabbed, carbon deposits, and even knocking. Therefore, on one hand, the impedance between the electrode and the tissue is increased, and the ablation depth and effect are influenced; on the other hand, it may cause complications such as embolism and perforation.

In order to prevent the ablation electrode from overheating, in the related art, the ablation electrode is mostly cooled by a unidirectional circulation saline injection cooling method. Meanwhile, the cooling effect and the saline water perfusion amount in unit time are adjusted by controlling the number of the spray holes on the surface of the electrode. However, the above-mentioned related art has the problems of large input amount of cooling brine and poor cooling effect.

In addition, in the related art, when the front end of the catheter is twisted, angled or inverted, the operator cannot timely obtain the corresponding shape of the front end of the catheter.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is how to improve the cooling effect of the ablation electrode of the ablation catheter and how to acquire the front end form of the ablation catheter, the utility model provides an ablation catheter.

According to the utility model discloses melt pipe, include:

the ablation electrode is used for generating radio frequency current so as to carry out radio frequency ablation treatment on a focus part, the ablation electrode is provided with a cavity, an injection port and a plurality of cooling holes, the injection port is communicated with the cavity, and cooling liquid is injected into the cavity through the injection port and is sprayed out of the cooling holes so as to cool the ablation electrode; the outer surface of the ablation electrode is provided with the cooling hole and a groove, wherein the cooling hole is also arranged in the groove;

the ablation electrode is connected to the end of the tube body, and the tube body is provided with a visible electrode for mapping and displaying the shape of the tube body.

According to the utility model discloses melt pipe, the surface of the electrode that melts of body head end sets up the recess, can increase the outer surface area of melting the electrode under the condition that does not increase the electrode volume to increase the effective heat radiating area who melts the electrode, improved the heat dissipation cooling effect who melts the electrode. Moreover, the outer surface of the ablation electrode comprises a plurality of cooling holes arranged in the grooves, and the ablation electrode can be cooled down through cooling liquid sprayed out of the cooling holes, so that the cooling and heat dissipation effects of the ablation electrode are further improved. In addition, the tube body is provided with a visible electrode, so that an operator can timely and conveniently acquire the form of the ablation catheter, and the operator can conveniently monitor and control the form of the ablation catheter, thereby improving the reliability and safety of the operation.

According to some embodiments of the utility model, the visualization electrode is a plurality of, and is a plurality of the visualization electrode all is located being close to of body the one end of ablation electrode, and is a plurality of the visualization electrode is followed the axial direction interval of body sets up.

In some embodiments of the present invention, the distance between any two adjacent visualization electrodes is not less than 1 cm.

According to some embodiments of the invention, the distance between the visualization electrode closest to the ablation electrode and the ablation electrode is in the range: 3cm-7 cm.

In some embodiments of the present invention, the ablation electrode is a column, the groove is disposed on a side surface of the ablation electrode, and the groove is an annular groove disposed along a circumferential direction of the ablation electrode.

According to some embodiments of the invention, the ablation electrode is provided with a plurality of annular grooves at intervals along an axial direction of the ablation electrode.

In some embodiments of the present invention, the cooling hole comprises:

the spray cooling hole is positioned in the groove, and cooling liquid in the cavity is sprayed out in a mist shape through the spray cooling hole;

and the jet cooling hole is positioned on the side surface of the ablation electrode except the groove, and the cooling liquid in the cavity is ejected in a ray form through the jet cooling hole.

According to some embodiments of the utility model, the spray cooling hole with the efflux cooling hole is followed a plurality of that the even interval of circumference direction of ablation electrode set up, the aperture of spray cooling hole is less than the aperture of efflux cooling hole.

In some embodiments of the present invention, the top wall and the side wall of the ablation electrode are both provided with a plurality of temperature sensors for detecting the temperature of the ablation electrode.

According to some embodiments of the invention, the ablation catheter further comprises: and the circulating pipe is communicated with the injection port and is used for injecting cooling liquid into the cavity.

Drawings

Fig. 1 is a schematic structural view of an ablation electrode according to an embodiment of the present invention;

fig. 2 is a partial structural cross-sectional view of an ablation electrode according to an embodiment of the present invention;

fig. 3 is a top view of an ablation electrode according to an embodiment of the present invention;

fig. 4 is a schematic structural view of an ablation catheter according to an embodiment of the present invention;

fig. 5 is an axial cross-sectional view of a partial structure of an ablation catheter according to an embodiment of the present invention;

fig. 6 is a transverse cross-sectional cut-away view of an ablation catheter according to an embodiment of the present invention;

fig. 7 is an exploded view of a partial structure of an ablation catheter according to an embodiment of the present invention;

fig. 8 is a partial schematic structural view of an ablation catheter in accordance with an embodiment of the present invention.

Reference numerals:

an ablation catheter (100) is provided,

ablation electrode 10, chamber V1, injection port 110, cooling holes 120, spray cooling holes 121, jet cooling holes 122, grooves 130, temperature sensor 140,

a tube body 20, a first navigation magnet 310, a second navigation magnet 320, a third navigation magnet 330, a distal positioning chip 410, a proximal positioning chip 420, a flow tube 70, a tail 90,

a first ring electrode 101, a second ring electrode 102, a third ring electrode 103, a visualization electrode 106, a lead 107.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined objects, the present invention will be described in detail below with reference to the accompanying drawings and preferred embodiments.

In the related art, the radio frequency ablation catheter is cooled by saline infusion, and the disadvantages are as follows:

due to the limitation of the area of the side of the columnar ablation electrode at the head end of the catheter, the cooling efficiency is still low although the number of holes for spraying saline outside is increased continuously. Under the premise of a certain area of the side of the columnar ablation electrode, in order to achieve a better cooling effect, the saline perfusion flow rate must be increased. The perfusion flow rate of the current 12-hole radio frequency ablation catheter is 17ml/min, and the perfusion flow rate of the 56-hole radio frequency ablation catheter is 8 ml/min. Thus, a 3 hour procedure requires the infusion of 1000-. Obviously increase the burden of the heart of the patient and have the risk of inducing heart failure.

In response to the above-mentioned deficiencies of ablation catheters in the related art, the present invention provides an ablation catheter 100. The ablation catheter 100 includes: an ablation electrode 10 and a catheter body 20.

The ablation electrode 10 is used for generating radio frequency current to perform radio frequency ablation treatment on a focus part. As shown in fig. 1 and 2, the ablation electrode 10 has a chamber V1 and an injection port 110 and a plurality of cooling holes 120 communicating with the chamber V1, and a cooling fluid is injected into the chamber V1 through the injection port 110 and ejected from the cooling holes 120 to cool the ablation electrode 10. The outer surface of the ablation electrode 10 is provided with cooling holes 120 and a recess 130, wherein the recess 130 is also provided with cooling holes 120 therein.

According to some embodiments of the present invention, as shown in fig. 1 and 2, the ablation electrode 10 is cylindrical, the groove 130 is formed on the side surface of the ablation electrode 10, and the groove 130 is an annular groove 130 formed along the circumferential direction of the ablation electrode 10. It should be noted that, by providing the circumferential annular groove 130 on the outer surface of the ablation electrode 10, the processing and manufacturing of the groove 130 are facilitated, and the production cost of the ablation electrode 10 is reduced. Moreover, the area of the groove 130 can be increased, and the cooling and heat dissipation effects of the ablation electrode 10 can be improved.

In some embodiments of the present invention, a plurality of annular grooves 130 are provided at intervals along the axial direction of the ablation electrode 10. It can be understood that by providing a plurality of annular grooves 130, the effective heat dissipation area of the ablation electrode 10 can be further increased, thereby further improving the cooling and heat dissipation effects of the ablation electrode 10.

According to some embodiments of the present invention, as shown in fig. 1, the cooling hole 120 includes: spray cooling holes 121 and jet cooling holes 122.

The spray cooling holes 121 are located in the grooves 130, and the cooling liquid in the chamber V1 is sprayed in a mist form through the spray cooling holes 121. The jet cooling holes 122 are positioned on the side surface of the ablation electrode 10 except the grooves 130, and the cooling liquid in the chamber V1 is ejected in a ray form through the jet cooling holes 122.

When the ablation electrode 10 is cooled, the cooling liquid in the chamber V1 may be sprayed in a mist form from the spray cooling holes 121, so as to increase the spraying range of the cooling liquid and improve the cooling effect; the cooling liquid in the chamber V1 can also be ejected in a radial form through the jet cooling holes 122 to drive the surrounding blood to flow, thereby increasing the cooling and heat dissipation efficiency of the ablation electrode 10.

In some embodiments of the present invention, as shown in fig. 1 and 2, the spray cooling hole 121 and the jet cooling hole 122 may be a plurality of holes that are uniformly spaced along the circumferential direction of the ablation electrode 10, so as to improve the uniformity of the cooling liquid injection to improve the uniformity of the heat dissipation of the ablation electrode 10. The diameter of the cooling holes 120 of the spray cooling holes 121 is smaller than that of the jet cooling holes 122. For example, the spray cooling holes 121 may have a pore size of less than 50um and the jet cooling holes 122 may have a pore size of less than 100 um.

According to some embodiments of the present invention, as shown in fig. 3, the top wall and the side wall of the ablation electrode 10 are each provided with a plurality of temperature sensors 140 for detecting the temperature of the ablation electrode 10. Therefore, the temperature of each part of the ablation electrode 10 can be obtained in real time, and when the temperature reaches a preset value, the ablation electrode 10 is cooled by spraying cooling liquid.

The ablation electrode 10 is connected to the end of the tube 20, and as shown in fig. 4, 5 and 7, the tube 20 is provided with a visualization electrode 106 for displaying the shape of the tube 20 by mapping.

By providing the visualization electrode 106 on the catheter 20, the shape of the catheter 20 near the end of the catheter 20 near the ablation electrode 10 can be displayed on the display module in cooperation with a three-dimensional coordinate device. Therefore, when the front end of the ablation catheter 100 has winding, twisting, angulation, reverse and other forms, the operator can timely acquire the corresponding form of the ablation catheter 100, so as to timely make corresponding adjustment on the ablation catheter 100.

According to the utility model discloses ablation catheter 100, the surface of the ablation electrode 10 of body 20 head end sets up recess 130, can increase the external surface area of ablation electrode 10 under the condition that does not increase ablation electrode 10 volume to increase the effective heat radiating area of ablation electrode 10, improved the heat dissipation cooling effect of ablation electrode 10. Moreover, the outer surface of the ablation electrode 10 includes a plurality of cooling holes 120 arranged in the groove 130, and the cooling liquid can be sprayed out through the cooling holes 120 to cool the ablation electrode 10, so that the cooling and heat dissipation effects of the ablation electrode 10 are further improved. In addition, the tube body 20 is provided with the visible electrode 106, so that an operator can timely and conveniently obtain the shape of the ablation catheter 100, and the operator can conveniently monitor and control the shape of the ablation catheter 100, thereby improving the reliability and safety of the operation.

According to some embodiments of the present invention, as shown in fig. 4, 5 and 7, the visualization electrode 106 may be plural, the plural visualization electrodes 106 are all located at one end of the tube 20 close to the ablation electrode 10, and the plural visualization electrodes are spaced apart along the axial direction of the tube 20.

It is understood that by spacing a plurality of visualization electrodes 106 near the ablation electrode 10, a more accurate configuration of the front end of the ablation catheter 100 can be obtained by the plurality of visualization electrodes 106 in conjunction with a three-dimensional mapping device to facilitate monitoring and adjustment of the configuration of the ablation catheter 100 by the operator.

In some embodiments of the present invention, the distance between any two adjacent visualization electrodes 106 is not less than 1 cm. It will be appreciated that the smaller the distance between two adjacent visualization electrodes 106, the smaller the length of the catheter body 20 that can be acquired and displayed by the two adjacent visualization electrodes 106, which is not conducive to viewing the overall morphology of the ablation catheter 100. When the distance between two adjacent visualization electrodes 106 is set to be not less than 1cm, the morphology of the ablation catheter 100 can be easily and reliably acquired.

According to some embodiments of the present invention, the distance between the visualization electrode 106 closest to the ablation electrode 10 and the ablation electrode 10 is: 3cm-7 cm. It should be noted that, the distance between the visualization electrode 106 and the ablation electrode 10 is too small, and interference and influence of heat conduction are easily generated between the visualization electrode 106 and the ablation electrode 10; the distance between the visualization electrode 106 and the ablation electrode 10 is set too large to effectively obtain the shape of the ablation catheter 100 near the front end of the ablation electrode 10. Experiments prove that when the distance between the visualization electrode 106 closest to the ablation electrode 10 and the ablation electrode 10 is set to be 3-7 cm, the influence between the visualization electrode 106 and the ablation electrode 10 can be effectively avoided, and the shape of the front end of the ablation catheter 100 can be conveniently and reliably acquired. For example, the distance between the visualization electrode 106 closest to the ablation electrode 10 and the ablation electrode 10 may be set to 5 cm.

An ablation catheter 100 according to the present invention is described in detail below in one specific embodiment with reference to the drawings. It is to be understood that the following description is only exemplary, and not restrictive of the invention.

As shown in fig. 4-7, the ablation catheter 100 includes: a catheter body 20, an ablation electrode 10, a flow tube 70, a lead 107, and a tail 90.

The ablation electrode 10 is a cylindrical electrode, and is located at the head end of the tube body 20, and is used for delivering radio frequency current for ablation. The ablation electrode 10 may be self-cooled by spraying cooling saline. The diameter of the ablation electrode 10 can be 6F (2.00mm), 8F (2.67mm), 10F (3.34mm) and 12F (4.00mm), which is convenient for the operator to select according to the actual application.

The ablation electrode 10 has a chamber V1 and an injection port 110 and a plurality of cooling holes 120 in communication with the chamber V1. The ablation electrode 10 is provided with a temperature sensor matrix, which comprises more than three temperature sensors 140 arranged on the top wall of the chamber V1 and more than two temperature sensors 140 arranged on the inner side wall of the chamber V1, and is used for sensing the temperature change of the head end of the ablation electrode 10 in the ablation process. The operator can increase the ablation energy, reduce the ablation time and improve the ablation efficiency by automatically monitoring the temperature of the ablation electrode 10.

The side surface of the ablation electrode 10 is provided with a plurality of annular grooves 130 at intervals along the axial direction, the depth of the grooves 130 is more than 0.5mm, and the width of the grooves 130 is more than 0.5mm, so that the heat dissipation capacity of the surface of the ablation electrode 10 is increased.

The plurality of spray cooling holes 121 are uniformly distributed in the groove 130 at intervals, the diameter of each spray cooling hole is less than 50 microns, and the spray cooling holes are used for spraying cooling saline water to the surface of the ablation electrode 10 in a cloud form and forming circulation cooling with blood around the ablation electrode 10, so that the one-way circulation cooling effect is enhanced.

An injection port 110 for cooling saline is located at the rear of the ablation electrode 10 and communicates with the chamber V1 of the ablation electrode 10 for delivering cooling saline into the ablation electrode 10. The cooling saline is injected into the chamber V1 at the saline flow rate within 5ml/min by matching the number (more than 120) and the distribution of the cooling holes 120, so that the cooling effect on the ablation electrode 10 is ensured.

The part of the side surface of the ablation electrode 10 except the groove 130 is provided with a jet flow cooling hole 122 with the diameter below 100 um. The jet cooling holes 122 are oblique holes arranged in a one-way clockwise direction and are used for spraying cooling saline water into peripheral blood to form circulating cooling with the peripheral blood of the ablation electrode 10.

As shown in fig. 4 and 5, the tube body 20 is provided with a distal positioning chip 410 and a proximal positioning chip 420 for positioning the tip of the ablation catheter 100 in three dimensions. Wherein the distal positioning electrode 410 is about 102mm from the ablation electrode. The first navigation magnet 310, the second navigation magnet 320 and the third navigation magnet 330 are disposed in the tube 20 for driving the head end of the ablation catheter 100 to change direction and move in the magnetic field. Wherein, the first navigation magnet 310 is about 2mm away from the ablation electrode.

The visualization electrode 106 is arranged at one end of the tube body 20 close to the ablation electrode 10, so that an operator can accurately judge whether the front end of the ablation catheter 100 has winding, twisting, angulation, reverse and other forms on the three-dimensional map.

The plurality of visualization electrodes 106 are arranged at intervals along the axial direction of the catheter body 20, and more than 1 three-dimensional visualization electrode 106 is arranged at a distance of more than 1cm from 5cm of the head end of the ablation catheter 100, and is used for displaying the shape of the catheter body 20 at the head end of the ablation catheter 100 on a three-dimensional map.

As shown in fig. 4, 5 and 7, the pipe body 20 is provided with: a first ring electrode 101, a second ring electrode 102, and a third ring electrode 103. The first annular electrode 101 is located about 2mm from the head end of the catheter body 20, the width of the first annular electrode 101 is within 2mm, the thickness of the first annular electrode 101 is within 0.3mm, and the first annular electrode 101 and the ablation electrode 10 are matched to record bipolar potential at the distal end of the ablation catheter 100.

The second ring electrode 102 and the third ring electrode 103 are located at the distal end of the body 20 and form a proximal electrode pair. The second ring-shaped electrode 102 and the third ring-shaped electrode 103 each have a width of 2mm or less and a thickness of 0.3mm or less. The second ring electrode 102 and the third ring electrode 103 are spaced within 5mm of each other for recording bipolar potentials at the proximal end of the ablation catheter 100.

The catheter body 20 includes a flexible section of the catheter body between the ablation electrode 10 and the first ring electrode 101 for controlling lateral deformation of the tip of the ablation catheter 100.

As shown in fig. 8, the tail of the ablation catheter 100 is provided with a tail 90 for connection to a host machine.

The working flow and principle of the ablation catheter 100 of the present invention are as follows:

s1, connecting the tail wire 90 of the ablation catheter 100, connecting the saline perfusion tube joint, and fully exhausting the ventilation tube 70.

S2, the tip of the ablation catheter 100 is advanced through the pre-positioned long sheath into the intended heart cavity.

And S3, balancing the zero point of the contact pressure, and displaying contact vector arrows of the tube body of the ablation catheter 100 and the head end of the ablation catheter 100 on the preset three-dimensional image of the heart cavity.

And S4, confirming that the size and the direction of the contact vector of the head end of the ablation catheter 100 are in a preset safety range.

S5, the catheter is advanced by directing the interface to the ablation catheter 100 so that its ablation electrode 10 contacts the endocardial tissue. The contact quality is judged by the pressure contact force checking function of the head end of the ablation catheter 100.

And S6, the host computer calculates the magnitude and direction of the contact force comprehensively and displays the contact force and the quality thereof respectively with the vector arrow of the head end of the ablation catheter 100 and the form of a screen display window.

S7, the operator sets ablation parameters and cooling pump parameters.

S8, the operator completely adjusts the positioning and contact quality of the ablation electrode 10 at the head end of the ablation catheter 100 through the catheter manipulator according to the vector parameters at the head end of the ablation catheter 100.

S9, when the radio frequency is emitted: the spray cooling holes 121 in the groove 130 of the ablation electrode 10 spray mist water flow to cool the tube body 20. The jet cooling holes 122 in the side wall of the ablation electrode 10 spray saline, which completes circulation cooling together with the blood around the ablation electrode 10. The surface grooves 122 of the ablation electrode 10 increase the effective heat dissipation area, enhance the cooling effect and save the saline infusion amount.

The utility model provides an ablation electrode 10 and ablation catheter 100 have solved following problem:

1. on the premise of keeping the side area of the columnar ablation electrode 10 at the head end of the catheter unchanged, the heat dissipation area is increased, and the heat dissipation efficiency is improved.

2. Jet holes with different apertures are manufactured on the side surface of the columnar ablation electrode 10, and mist saline cooling is respectively carried out on the adjacent part of the ablation electrode 10 and jet flow scouring saline cooling is carried out on the periphery of the ablation electrode 10.

3. The number of the apertures on the side surface of the columnar ablation electrode 10 is increased to more than 120, and the diameter of a single aperture is reduced by more than 50%, so that the saline input is reduced by more than 50% on the premise of not reducing the existing cooling efficiency.

4. The ablation catheter 100 with different ablation electrode 10 diameters and matching cooling holes 120 is designed to increase the selectivity of the operator for different individual patients, different sites and different ablation efficiencies.

5. The tube 20 is provided with a visualization electrode for obtaining the tube shape of the tip of the ablation catheter 100.

To sum up, the utility model provides an ablation catheter 100 has following advantage:

an annular groove 130 is formed in the side surface of the ablation electrode 10, so that the heat dissipation area is increased; cooling holes 120 with different apertures are manufactured on the side surface of the ablation electrode 10, and mist saline cooling and jet flow scouring saline cooling are respectively carried out on the adjacent part of the ablation electrode 10 and the periphery of the electrode by ablation, so that the heat dissipation efficiency is improved; the number of the side apertures of the ablation electrode 10 is increased to more than 120, the diameter of a single aperture is reduced by more than 50%, and the saline input is reduced by more than 50% on the premise of not reducing the cooling efficiency; the ablation catheter 100 and ablation electrode 10 diameters include a variety of models: 6F (2.00mm), 8F (2.67mm), 10F (3.34mm) and 12F (4.00mm), and increase the selectivity of the operator to different patients, different parts and different ablation efficiencies. In addition, the tube body 20 is provided with a visible electrode, so that an operator can timely and conveniently obtain the shape of the ablation catheter 100, and the operator can conveniently monitor and control the shape of the ablation catheter 100, thereby improving the reliability and safety of the operation.

The technical means and functions of the present invention to achieve the intended purpose will be understood more deeply and concretely through the description of the embodiments, however, the attached drawings are only for reference and illustration, and are not intended to limit the present invention.

Claims (10)

1. An ablation catheter, comprising:

the ablation electrode is used for generating radio frequency current so as to carry out radio frequency ablation treatment on a focus part, the ablation electrode is provided with a cavity, an injection port and a plurality of cooling holes, the injection port is communicated with the cavity, and cooling liquid is injected into the cavity through the injection port and is sprayed out of the cooling holes so as to cool the ablation electrode; the outer surface of the ablation electrode is provided with the cooling hole and a groove, wherein the cooling hole is also arranged in the groove;

the ablation electrode is connected to the end of the tube body, and the tube body is provided with a visible electrode for mapping and displaying the shape of the tube body.

2. The ablation catheter of claim 1, wherein the visualization electrode is a plurality of visualization electrodes, the plurality of visualization electrodes are all located at one end of the tube body close to the ablation electrode, and the plurality of visualization electrodes are arranged at intervals along the axial direction of the tube body.

3. The ablation catheter of claim 2, wherein the distance between any two adjacent visualization electrodes is no less than 1 cm.

4. The ablation catheter of claim 2, wherein the distance between the visualization electrode closest to the ablation electrode and the ablation electrode ranges from: 3cm-7 cm.

5. The ablation catheter according to claim 1, wherein the ablation electrode is cylindrical, the groove is provided on a side surface of the ablation electrode, and the groove is an annular groove provided in a circumferential direction of the ablation electrode.

6. The ablation catheter of claim 5, wherein a plurality of the annular grooves are provided at intervals in an axial direction of the ablation electrode.

7. The ablation catheter of claim 5, wherein the cooling holes comprise:

the spray cooling hole is positioned in the groove, and cooling liquid in the cavity is sprayed out in a mist shape through the spray cooling hole;

and the jet cooling hole is positioned on the side surface of the ablation electrode except the groove, and the cooling liquid in the cavity is ejected in a ray form through the jet cooling hole.

8. The ablation catheter of claim 7, wherein the spray cooling hole and the jet cooling hole are each provided in plurality at regular intervals in a circumferential direction of the ablation electrode, and a diameter of the spray cooling hole is smaller than a diameter of the jet cooling hole.

9. The ablation catheter of claim 1, wherein the top wall and the side wall of the ablation electrode are each provided with a plurality of temperature sensors for sensing the temperature of the ablation electrode.

10. The ablation catheter of any of claims 1-9, further comprising: and the circulating pipe is communicated with the injection port and is used for injecting cooling liquid into the cavity.

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