CN113288404A

CN113288404A - Ablation catheter with multiple cage-shaped structures and multiple electrodes and equipment thereof

Info

Publication number: CN113288404A
Application number: CN202110538711.4A
Authority: CN
Inventors: 戴宇峰; 潘炳跃; 唐瑜珅; 董宇国
Original assignee: Shanghai Hanyu Medical Technology Co ltd
Current assignee: Shanghai Hanyu Medical Technology Co ltd
Priority date: 2021-05-18
Filing date: 2021-05-18
Publication date: 2021-08-24

Abstract

The invention relates to a multi-cage multi-electrode ablation catheter and equipment thereof, belonging to the technical field of medical instruments. Comprises an electrode, an electrode supporting belt, a current lead, a catheter, a guide head, an initial head, a middle-end restraining head, a driving wire, a driving adjusting button and a handle; the catheter is connected with a handle, and a driving adjusting button is arranged on the handle; one end of the conduit far away from the handle is provided with an initial head; a driving wire penetrating through the starting head is arranged in the conduit, one end of the driving wire is provided with a guide head, and the other end of the driving wire is connected with a driving adjusting button; a middle-end restraining head is arranged on the driving wire between the guide head and the starting head; a protrudable electrode supporting belt is respectively arranged between the guide head and the middle-end restraining head and between the middle-end restraining head and the starting head, and electrodes are arranged on the electrode supporting belt; the electrode supporting belt is provided with current leads connected with the electrodes in a penetrating way. The invention can be suitable for blood vessels of different organs and different diameters, can simultaneously ablate different parts, and has simple structure and convenient operation.

Description

Ablation catheter with multiple cage-shaped structures and multiple electrodes and equipment thereof

Technical Field

The invention relates to a multi-cage multi-electrode ablation catheter and equipment thereof, belonging to the technical field of medical instruments.

Background

In a high voltage electrical pulse ablation system (PFA), ablation catheter electrodes are used as the key devices for contacting or approaching the body tissue being treated and performing electrical pulse-forming electric field release. The electric pulse electrode is used for converting high-voltage direct current electric pulse into an electric field, and irreversible perforation is formed on cells through the electric field to eliminate the focus. In the operation process, whether the electrode on the ablation catheter adheres to the wall plays an important role in the treatment effect of the ablation operation. In addition, when parts such as pulmonary veins and the like are ablated, different parts such as the inside of a blood vessel and the opening of the blood vessel need to be ablated, and if a catheter capable of ablating different parts simultaneously is provided, the medical operation can be greatly simplified and the operation difficulty can be reduced.

In the ablation catheter, an electrode is arranged on a bracket at the front end of the ablation catheter, the bracket is used for bearing the electrode, the wall adhesion is expanded before ablation begins, and the bracket is retracted after ablation is finished. Since the catheter ablation operation is directly conducted in the human blood vessel, the telescopic size of the stent is suitable for the diameter of the human blood vessel. The diameter of the blood vessel of the human body varies from person to person, and the diameter of the blood vessel in the human body also varies due to different ablation organs and parts, and the diameter of the blood vessel of different organs of the human body is about 2-20mm, and the difference is large.

Chinese patent No. CN104224315A applies for an ablation catheter electrode structure, which is a radio frequency ablation catheter with a mesh tubular support structure, wherein one or more electrodes are fixed on the middle section of the mesh tubular support, the mesh tubular support has a certain flexibility, and can be applied to blood vessels within a certain diameter range, but the processing technology is complex, and there is a risk of ablation failure due to structural failure.

Chinese patent nos. CN201780005770 and CN201880033278 disclose an ablation catheter electrode structure, which distributes electrodes on different splines, and a typical structure thereof adopts 5 sets of splines, and 4 electrodes are distributed on each set of splines, and when the structure is used for ablation of pulmonary vein orifices, the structure is unfolded into a petal-shaped structure with a larger diameter; when the device is used for ablation inside pulmonary veins, the device is unfolded into a spherical structure with a smaller diameter. However, the structure is complicated to operate, a doctor needs to continuously adjust the unfolding shape of the electrode, and needs to operate the stopping and maintaining structure for enabling the unfolding shape of the electrode, so that the structure is complex, the risk of ablation failure caused by structural failure exists, and the catheter is thick, can be only used for pulmonary vein ablation and cannot be used for other organs and parts.

Chinese patent No. CN201680046257 discloses an irreversible electroporation ablation electrode structure, which sets the electrode into a circular ring structure, has simple structure and convenient operation, but the electrode of the structure has a single deployed diameter, and the ablation of blood vessels with different diameters needs to be frequently replaced, and the pulmonary vein opening and the inside cannot be ablated simultaneously, and the electrode cannot be used for other organs and parts.

Therefore, there is a need in the art to design an electrode structure that is suitable for blood vessels of different organs such as heart and kidney, can ablate different parts simultaneously, has a simple structure and is convenient to operate, and can effectively realize irreversible electroporation ablation.

Disclosure of Invention

The invention aims to solve the technical problems of designing an electrode structure which can be suitable for blood vessels of different organs and diameters, can simultaneously ablate different parts, has simple structure and convenient operation, can effectively realize irreversible electroporation ablation and an electric pulse generator suitable for different organs and parts.

In order to solve the above problems, the present invention provides a multiple-cage multi-electrode ablation catheter, which comprises an electrode, an electrode support band, a current lead, a catheter, a guide head, an initial head, a middle restraint head, a driving wire, a driving adjustment knob and a handle; the catheter is connected with a handle, and a driving adjusting button is arranged on the handle; one end of the conduit far away from the handle is provided with an initial head; a driving wire penetrating through the starting head is arranged in the conduit, one end of the driving wire is provided with a guide head, and the other end of the driving wire is connected with a driving adjusting button used for adjusting the length of the driving wire extending out of the conduit; a middle-end restraining head is arranged on the driving wire between the guide head and the starting head; electrode supporting bands with bendable bulges are respectively arranged between the guide head and the middle-end restraining head as well as between the middle-end restraining head and the starting head, and electrodes are arranged on the electrode supporting bands; the electrode supporting belt is provided with current leads connected with the electrodes in a penetrating way.

Preferably, the end of the handle far away from the catheter is provided with a multi-core electric connector, and the current lead is connected with the multi-core electric connector.

Preferably, one end of the starting head is fixedly connected with the guide pipe, and the other end of the starting head is fixedly connected with the electrode supporting belt; the guide head is fixedly connected with the electrode supporting belt; the two ends of the middle-end restraining head are fixedly connected with the electrode supporting belt.

Preferably, the electrodes are disposed at the middle of the electrode supporting band between the leading head and the middle-end restraining head, and at the middle of the electrode supporting band between the middle-end restraining head and the starting head.

Preferably, a plurality of electrode supporting bands are respectively arranged between the guide head and the middle-end restraining head and between the middle-end restraining head and the starting head, and the plurality of electrode supporting bands are uniformly arranged on the periphery of the driving wire.

Preferably, a plurality of middle-end restraining heads are arranged on the driving wire between the guide head and the starting head; an electrode supporting belt is arranged between the middle-end restraining heads; and the middle part of the electrode supporting belt between the middle-end restraining heads is provided with an electrode.

Preferably, the middle-end restraining head is sleeved on the periphery of the driving wire and movably connected with the driving wire.

Preferably, the handle is provided with a plurality of driving adjusting buttons, and the catheter is provided with a plurality of driving wires; the plurality of middle-end restraining heads are respectively connected with different driving adjusting buttons through driving wires.

The invention provides ablation equipment consisting of an ablation catheter with multiple cage-shaped structures and multiple electrodes, wherein the ablation equipment further comprises an electric pulse generator or a radio frequency ablation system; the ablation catheter is connected with an electric pulse generator or a radio frequency ablation system.

Compared with the prior art, the invention has the following beneficial effects:

1. the ablation catheter can be attached to the ablation of blood vessels with different diameters of various organs, so that a more effective ablation effect is realized, and ablation catheters with different models do not need to be frequently replaced in an operation;

2. the invention can simultaneously ablate different parts without multiple ablations, thereby reducing the operation difficulty and improving the success rate of the operation;

3. the invention can be adapted to different energy generators.

Drawings

Fig. 1 is a first structural diagram of the present invention.

FIG. 2 is a second schematic structural diagram of the present invention.

FIG. 3 is a schematic view of the radial structure of the present invention.

FIG. 4 is a schematic view of an electrode support strip according to the present invention.

FIG. 5 is a schematic diagram of the structure of two sets of electrode supporting strips with different diameters according to the present invention.

Fig. 6 is a morphology of the invention ablating thinner vessels.

Fig. 7 is a morphology of the invention ablating thicker vessels.

FIG. 8 is a schematic view of different portions of the ablation of two sets of electrode support bands of different diameters according to the present invention.

FIG. 9 is a schematic diagram of different types of electrodes according to the present invention.

Fig. 10 is a schematic diagram of the ablation device of the present invention including an electrical pulse generator.

Fig. 11 is a schematic diagram of a high voltage pulse waveform capable of producing irreversible electroporation with the ablation device of the invention.

Reference numerals: 1. an electrode; 2. an electrode supporting strap; 21. a framework; 3. a conduit; 4. a guide head; 5. a middle restraint head; 6. a drive wire; 7. driving the adjusting knob; 71. driving a first adjusting button; 72. driving an adjusting button II; 8. a handle; 9. a multi-core electrical connector; 10. a current lead; 11. and starting the head.

Detailed Description

In order to make the invention more comprehensible, preferred embodiments are described in detail below with reference to the accompanying drawings:

as shown in fig. 1-11, the invention provides a multiple cage-structured multi-electrode ablation catheter, which comprises an electrode 1, an electrode supporting band 2, a current lead 10, a catheter 3, a guide head 4, a starting head 11, a middle-end restraining head 5, a driving wire 6, a driving adjusting button 7 and a handle 8; the catheter 3 is connected with a handle 8, and a driving adjusting button 7 is arranged on the handle 8; the end of the conduit 3 far away from the handle 8 is provided with an initial head 11; a driving wire 6 penetrating through the starting head 11 is arranged in the conduit 3, one end of the driving wire 6 is provided with a guide head 4, and the other end of the driving wire 6 is connected with a driving adjusting button 7 for adjusting the length of the driving wire 6 extending out of the conduit 3; a middle-end restraining head 5 is arranged on the driving wire 6 between the guide head 4 and the starting head 11; electrode supporting bands 2 which can be bent and raised are respectively arranged between the guide head 4 and the middle end restraining head 5 and between the middle end restraining head 5 and the starting head 11, and electrodes 1 are arranged on the electrode supporting bands 2; the electrode support strap 2 is provided with a current lead 10 penetrating therethrough and connected to the electrode 1. The end of the handle 8 remote from the catheter 3 is provided with a multi-core electrical connector 9, and a current lead 10 is connected to the multi-core electrical connector 9. One end of the starting head 11 is fixedly connected with the guide pipe 3, and the other end is fixedly connected with the electrode supporting belt 2; the guide head 4 is fixedly connected with the electrode supporting belt 2; the two ends of the middle-end restraining head 5 are fixedly connected with the electrode supporting belt 2. The electrodes 1 are disposed at the middle of the electrode supporting strap 2 between the lead head 4 and the middle-end confining head 5, and at the middle of the electrode supporting strap 2 between the middle-end confining head 5 and the start head 11. A plurality of electrode supporting belts 2 are respectively arranged between the guide head 4 and the middle-end restraining head 5 and between the middle-end restraining head 5 and the starting head 11, and the plurality of electrode supporting belts 2 are uniformly arranged on the periphery of the driving wire 6. A plurality of middle-end restraint heads 5 are arranged on the driving wire 6 between the guide head 4 and the starting head 11; an electrode supporting belt is arranged between the middle-end restraining heads 5; the middle part of the electrode supporting band 2 between the middle end restraining heads 5 is provided with an electrode 1. The middle-end restraining head 5 is sleeved on the periphery of the driving wire 6, and the middle-end restraining head 5 is movably connected with the driving wire 6. Or the handle 8 is provided with a plurality of driving adjusting buttons 7, and the catheter 3 is provided with a plurality of driving wires 6; the plurality of middle-end restraining heads 5 are respectively connected with different driving adjusting knobs 7 through driving wires 6.

The invention provides ablation equipment consisting of an ablation catheter with multiple cage-shaped structures and multiple electrodes, wherein the ablation equipment further comprises an electric pulse generator or a radio frequency ablation system; the ablation catheter is connected with an electrical pulse generator or a radio frequency ablation system.

Examples

As shown in fig. 1 to 11, the ablation catheter of the present invention is composed of an electrode 1, an electrode support band 2, a catheter 3, a guide head 4, a middle-end restriction head 5, a drive wire 6, a drive adjustment knob 7, a handle 8, a multi-core electrical connector 9, a current lead wire 10, etc., wherein: the electrode 1 has a ring structure, which may be a complete ring structure, or may also be a semicircular structure, 1/3 circular structure, 1/4 circular structure, and the like, and refer to fig. 1 and 2 specifically; the outer layer of the electrode supporting band 2 is of a hollow insulating tube structure, is made of TPU and the like, and can bear 2000V high voltage without breakdown; the middle part is a framework 21 made of materials such as nickel-titanium wires, spiral braided wires and the like, and provides elasticity and support, and the framework is shown in figure 4; the electrode supporting band 2 can also be integrally in a metal band shape such as nickel titanium and the like, the surface of the electrode supporting band is coated with an insulating layer, and the voltage resistance is 2000 v; the electrode 1 is located in the middle of the electrode supporting band 2 and is located at the maximum diameter in the radial direction after being unfolded, see fig. 1, 2 and 3; the current lead 10 is insulated on the surface, can bear 2000V high voltage and is not broken down, is positioned in the hollow insulating tube of the electrode supporting belt 2, and is welded with the electrode 1 by laser through the open hole of the hollow insulating tube, and is shown in detail in figure 4; the electrode supporting bands 2 are uniformly distributed at the far end of the catheter 3, the number of the electrode supporting bands is more than 2, the number of the electrode supporting bands can be even number and odd number, and the electrode supporting bands are uniformly distributed in 8 number; in this embodiment, 8 electrode support bands form a group, the distal end is connected with the middle-end restraining head 5, there may be multiple groups of electrode support bands, and this embodiment adopts 2 groups; the distal ends of the second group of electrode supporting belts are connected with a guide head 4, and the guide head 4 is connected with a driving wire 6; the driving wire 6 is made of nickel-titanium wires and the like, has certain hardness and elasticity, penetrates through the middle-end restraining head 5 and the catheter 3, and is connected with the driving adjusting button 7 in the handle 8; the driving adjusting button 7 drives the driving wire 6 to move forwards or backwards through the operation of up-and-down pushing, so that the expansion diameter of the electrode supporting band 2 is controlled to adapt to blood vessels with different diameters; in the initial state, the driving adjusting button 7 is positioned at the farthest end, the electrode supporting band 2 is completely contracted, and the radial diameter is 4 mm; the driving adjusting button 7 is pushed towards the direction of the guide head 4, so that the electrode supporting band 2 starts to expand to form a cage shape, and after the electrode supporting band is completely expanded, the radial diameter is 25 mm; the two sets of electrode support bands 2 are the same size in this embodiment, and the two sets of electrode support bands 2 are synchronously adjusted by the same drive adjustment knob 7;

in another embodiment, the two sets of electrode support bands 2 are different in size, the radial diameter of the distal end after full expansion is 25mm, the radial diameter of the proximal end after full expansion is 31mm, and the two sets of electrode support bands 2 are respectively adjusted by two different driving adjustment buttons one 71 and two driving adjustment buttons two 72, as shown in detail in fig. 5;

when ablating a thinner blood vessel, the diameter of the expanded electrode supporting band 2 is smaller by operating the drive adjusting button 7, and the electrode 1 can be attached to the blood vessel wall, as shown in detail in fig. 6;

when a thicker blood vessel is ablated, the driving adjusting button 7 is operated to ensure that the expanded diameter of the electrode supporting band 2 is larger, so that the electrode 1 is attached, and the detailed view is shown in fig. 7;

when the inside of a blood vessel and the opening of the blood vessel are simultaneously ablated when the pulmonary vein and the like are ablated, the inside of the pulmonary vein and the opening of the pulmonary vein are simultaneously ablated through two groups of electrode supporting bands 2 with different diameters, and the detailed description is shown in figure 8;

as shown in fig. 10, the catheter can be connected to an electrical pulse generator, which generates electrical pulses of different amplitudes of high voltage, pulse width and frequency, connected to the handle 8 of the catheter through a connector, the electrical pulses being transmitted to the electrodes through current leads, the electrodes generating an electrical field for irreversible electroporation ablation of the attached blood vessel, the waveform of the pulses being detailed in fig. 11;

in another embodiment, the catheter may be connected to a radio frequency ablation system, releasing the radio frequency at the electrodes to create a thermal effect for ablation.

While the invention has been described with respect to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention. Those skilled in the art can make various changes, modifications and equivalent arrangements, which are equivalent to the embodiments of the present invention, without departing from the spirit and scope of the present invention, and which may be made by utilizing the techniques disclosed above; meanwhile, any changes, modifications and variations of the above-described embodiments, which are equivalent to those of the technical spirit of the present invention, are within the scope of the technical solution of the present invention.

Claims

1. A multiple cage multi-electrode ablation catheter characterized by: comprises an electrode, an electrode supporting belt, a current lead, a catheter, a guide head, an initial head, a middle-end restraining head, a driving wire, a driving adjusting button and a handle; the catheter is connected with a handle, and a driving adjusting button is arranged on the handle; one end of the conduit far away from the handle is provided with an initial head; a driving wire penetrating through the starting head is arranged in the conduit, one end of the driving wire is provided with a guide head, and the other end of the driving wire is connected with a driving adjusting button used for adjusting the length of the driving wire extending out of the conduit; a middle-end restraining head is arranged on the driving wire between the guide head and the starting head; electrode supporting bands with bendable bulges are respectively arranged between the guide head and the middle-end restraining head as well as between the middle-end restraining head and the starting head, and electrodes are arranged on the electrode supporting bands; the electrode supporting belt is provided with current leads connected with the electrodes in a penetrating way.

2. The multiple cage multiple electrode ablation catheter of claim 1 wherein: and a multi-core electric connector is arranged at one end of the handle, which is far away from the catheter, and the current lead is connected with the multi-core electric connector.

3. The multiple cage multi-electrode ablation catheter of claim 2 wherein: one end of the starting head is fixedly connected with the guide pipe, and the other end of the starting head is fixedly connected with the electrode supporting belt; the guide head is fixedly connected with the electrode supporting belt; the two ends of the middle-end restraining head are fixedly connected with the electrode supporting belt.

4. The multiple cage multi-electrode ablation catheter of claim 3 wherein: the electrode is arranged in the middle of the electrode supporting band between the guide head and the middle-end restraining head, and in the middle of the electrode supporting band between the middle-end restraining head and the starting head.

5. The multiple cage multiple electrode ablation catheter of claim 4 wherein: a plurality of electrode supporting belts are respectively arranged between the guide head and the middle-end restraining head and between the middle-end restraining head and the initial head, and the plurality of electrode supporting belts are uniformly arranged on the periphery of the driving wire.

6. The multiple cage multiple electrode ablation catheter of claim 5 wherein: a plurality of middle-end restraining heads are arranged on the driving wire between the guide head and the starting head; an electrode supporting belt is arranged between the middle-end restraining heads; and the middle part of the electrode supporting belt between the middle-end restraining heads is provided with an electrode.

7. The multiple cage multiple electrode ablation catheter of claim 6 wherein: the middle-end restraining head is sleeved on the periphery of the driving wire and is movably connected with the driving wire.

8. The multiple cage multiple electrode ablation catheter of claim 7 wherein: the handle is provided with a plurality of driving adjusting buttons, and the catheter is internally provided with a plurality of driving wires; the plurality of middle-end restraint heads are respectively connected with different driving adjusting buttons through driving wires.

9. The ablation device formed by the multiple cage-like structure multiple electrode ablation catheter of any of claims 1-8, wherein: the ablation device further comprises an electrical pulse generator or a radiofrequency ablation system; the ablation catheter is connected with an electric pulse generator or a radio frequency ablation system.