EA005704B1 - Waveguide for intravascular thrombectomy of thrombi and thromboemboli - Google Patents

Abstract

The invention relates to medicine, particular to endovascular surgery, and permits to increase the amplitude longitudinal oscillation of a working head, and to improve operation reliability of the tool at the expense of smooth voltage change along the whole length of the waveguide, since the waveguide is designed as a cross-sectional core with successive decrease the diameter between proximal, middle and distal parts, wherein the diameter of the working head exceeds the diameter of the distal part by 1.5 times. The method of making the waveguide permits to obtain the predetermined tapered curvatures, of Fourier concentrator type, between the proximal, middle and distal parts by plasma electrolyte treatment of the cylindrical core blank and this is achieved by placing the blank in electrolyte at 0 to 90 degrees relative to the electrolyte plane, after which the blank is set to rotate around the longitudinal axis, then the blank is moved from the electrolyte along the longitudinal axis and for providing a tapered curvature of the Fourier concentrator type to a smaller diameter the blank is moved from the electrolyte along its longitudinal axis with displacement feed 1 mm according to the displacement values and obtaining the diameter.

Description

The invention relates to medicine, to the section of endovascular surgery and can be used in cardiovascular surgery.

A device for intravascular removal of athereblashes is known, consisting of a catheter with an ultrasound transfer unit located in the inner part of the catheter and directly connected to the ultrasound-generating device. The node is a spherical head enlarged from the distal side, which can be extended from the distal side of the catheter. The head can be provided with a neck or a radial groove and a cutting edge (European patent No. 0835644A2. Publication date 15.04.1998).

This device is a prototype in relation to the claimed waveguide. Common signs for the proposed waveguide and the prototype is that they consist of a metal cylindrical rod and a working head located at the end of the distal part of the rod.

However, the prototype has the following disadvantages. The design of the waveguide does not allow to increase the amplitude of the longitudinal oscillations of the working head, which makes it impossible to obtain complete fine destruction of intravascular formations, as well as the relatively low reliability in operation due to faults in the waveguide.

The objective of the proposed waveguide is to increase the amplitude of the longitudinal oscillations of the working head, as well as increase the reliability in operation due to the smooth change in voltage along the entire length of the waveguide.

The task is achieved by the fact that the proposed waveguide for intravascular thrombectomy of blood clots and thromboembolus, consisting of a metal cylindrical rod and a working head located at the end of the distal part of the rod, while the waveguide is made in the form of a rod of variable cross section with a consistent decrease in diameter between the proximal, middle and distal parts, and the diameter of the working head is 1.5 times the diameter of the distal part, and the length of the proximal part of the waveguide is from 2 to 4 λ, where λ is the length ultrasonic wave of longitudinal oscillations in the waveguide material. The length of the middle and proximal parts is at least 1/2 λ, and the transitions between the proximal, middle and distal parts of the waveguide are in the form of a Fourier concentrator with a ratio of cross-sectional areas of not more than 1.5: 1 and conical transitions are made at the points of the antinode of longitudinal oscillations waveguide.

The inventive waveguide is illustrated in FIG. 1, where 1 is the proximal part, 2 is the middle part, 3 is the distal part, 4 is the working head, 5 and 6 are Fourier concentrator transitions between the proximal, middle and distal parts.

Waveguide works as follows. From the ultrasonic transducer, the mechanical vibrations of the ultrasonic frequency are transmitted to the proximal part 1 of the waveguide and through it to the middle 2 and distal 3 parts and further to the working head 4.

Smoothly changing the frequency of ultrasonic vibrations increases the amplitude of the longitudinal oscillations of the working head 4. This makes it possible to obtain complete fine destruction of blood clots and thromboemboles and reduce the probability of destruction of the waveguide itself.

A known method of surface treatment of metal products by plasma electrolytic processing of a cylindrical billet rod [2].

This method is a prototype in relation to the stated. A common feature for the proposed method and the prototype is plasma electrolytic processing of a cylindrical core rod. However, the prototype method does not allow to obtain specified conical transitions like a Fourier concentrator between the proximal, middle and distal part of the core rod, since its technology does not provide for only polishing the surface and does not provide for the creation of complex surface forms.

The objective of the proposed method is to obtain the specified conical transitions of the type of Fourier concentrator between the proximal, middle and distal parts of the rod-billet.

The task is achieved as follows. A method of manufacturing a metal waveguide by plasma electrolytic processing of a cylindrical billet rod is proposed, when the billet is placed in an electrolyte at an angle from 0 to 90 ° with respect to the electrolyte plane, after which the billet is given a rotation around the longitudinal axis with a frequency of 0 to 30 revolutions per minute per processing time and then carry out its movement from the electrolyte along the longitudinal axis, and to obtain a cylindrical surface, the movement along the axis is stopped for the time it reaches the specified diameter second portion of the waveguide which is immersed in the electrolyte, and to create a tapered transition from the Fourier type concentrator to a smaller diameter preform is moved from the electrolyte along its longitudinal axis with a pitch of 1 mm displacement horizontally according to the values obtained amount of displacement and the diameter given in the table:

one 0 179 180 181 182 183 184 185 390 391 392 393 394 395 396 397 398 399 536 2 2 1.93 1.78 1.68 1.65 1.62 1.61 1.61 1.54 1.39 1.24 1.14 1.10 1.04 1.03 1.01 one one

where 1 is the distance from the proximal end of the waveguide, mm, ά is the current diameter of the waveguide, mm,

- 1 005704 and the manufacture of the waveguide head is carried out by the fact that before processing the core rod, an inert material sleeve is worn at its distal end.

Example. For the manufacture of a stepped cylindrical waveguide with step diameters of 2.01.61-1.0 mm, a metal billet 560-570 mm long and 2 mm in diameter is taken.

Place it in the electrolyte solution at an angle from 0 °, 15 °, 90 ° to a length of 1 = 560-179 = 381 mm (the proximal part is outside the treatment area) and plasma electrolyte processing is performed with a single-element rotation of the workpiece along the longitudinal axis with a frequency of 0 up to 30 revolutions per minute. When this occurs, the formation of the middle part of the waveguide (second stage) with a diameter of 1.61 mm. The processing time in this case is 90 minutes.

After that, the workpiece is moved from the electrolyte along the longitudinal axis to the length of the middle part and the proximal part is made (third stage).

The formation of conical transitions between the steps of the waveguide by the type of Fourier concentrator occurs due to the edge effect.

For the manufacture of the head on the tip of the blank rod wear sleeve of inert material. Due to the edge effect, a smooth transition to the working part of the head is achieved with the formation of a pear shape in it.

Thus, the claimed waveguide and method of its manufacture in comparison with the prototypes provide the following advantages: to increase the efficiency of destruction of blood clots and thromboebols by obtaining full fine grinding with a simultaneous increase in reliability in operation by 2-4 times.

Sources of information taken into account in the preparation of the application:

1. European patent No. 0835644 A2, MKL ⁶ A 61B 17/22, publication date 04/14/1998 - prototype, waveguide.

2. Auth. St. USSR №1314729 A1, MKL ⁴ C 25P 3/16, published in 1987, the prototype of the claimed method.

Claims (3)

CLAIM 1. The waveguide for intravascular thromboectomy of thrombi and thromboembolism, consisting of a metal cylindrical rod of variable cross section and a working head located at the end of the distal part of the rod, characterized in that the length of the proximal part of the rod is from 2 to 4 λ, where λ is the length of the ultrasonic wave of longitudinal vibrations the waveguide itself, and the length of the middle and proximal parts is at least 1/2 λ, and the transitions between the proximal, middle and distal parts of the waveguide are in the form of a Fourier concentrator with the ratio cross sectional area of no more than 1.5: 1, and the conical transitions are made in the field antinodes of the longitudinal vibrations of the waveguide, wherein the diameter of the working head greater than the diameter of the distal part 1.5. 2. A method of manufacturing a metal waveguide by plasma electrolyte processing of a cylindrical rod-workpiece, characterized in that the workpiece is placed in the electrolyte at an angle from 0 to 90 ° relative to the surface of the electrolyte, after which the workpiece is set to rotate around the longitudinal axis with a frequency of up to 30 vol. / min for the processing time and carry out its movement from the electrolyte along the longitudinal axis, moreover, to obtain a cylindrical surface, the movement along the axis is stopped for the time to reach the specified diameter of that part in a duct that is immersed in the electrolyte, and to create a conical transition as a Fourier concentrator to a smaller diameter, the workpiece is moved from the electrolyte along its longitudinal axis with a horizontal step of 1 mm according to the values of the displacement and the resulting diameter shown in the table one 0 179 180 181 182 183 184 185 390 391 392 393 394 395 396 397 398 399 536 6 2 2 1.93 1.78 1.68 1.65 1,62 1,61 1,61 1,54 139 1.24 1.14 1.10 1,04 1 03 1.01 one one where 1 is the distance from the proximal end of the waveguide, mm, 4 - current diameter of the waveguide, mm, and for manufacturing the waveguide head before processing the workpiece rod, a sleeve of inert material is put on its distal end.