RU185204U1 - DEVICE FOR ENDOLUMINAL THERMAL OBLITERATION OF VARICOSE VEINS - Google Patents

Abstract

The utility model relates to surgical instruments and devices for transferring non-mechanical forms of energy to the human body by laser radiation, in particular, for the endoluminal treatment of blood vessels.

The objective of the proposed utility model is to reduce the cost of the treatment process by the claimed device while maintaining its high efficiency due to the possibility of using a laser radiation generator as an optical emitter, regardless of the emitted spectral composition of the radiation.

This is achieved by the fact that the device for endoluminal thermal obliteration of varicose veins containing a flexible waveguide 1, which is an optical fiber having an elongated axis, a proximal end, optically connected to a radiation source, a distal end configured to be placed in a blood vessel and containing an optical tip 2 with an emitting surface made on the quartz fiber core has an optically opaque hollow metal cap 3 with a perfectly ground surface, which is the main heating element of the device mounted on the tip 2. In this case, the glass fiber itself has a double protective sheath 4 along its entire length, the inner layer of which is made of aluminum filament, braiding directly the glass fiber and the outer layer made of a special heat-resistant polymer with a low roughness coefficient, which is rigidly attached to the cap 3.

Description

The utility model relates to surgical instruments and devices for transferring non-mechanical forms of energy to the human body by laser radiation, in particular, for the endoluminal treatment of blood vessels.

A device for conducting endovasal laser coagulation of varicose veins is known (RF Patent No. 2506921, IPC - A61B 18/22; A61N 51/01; A61N 5/06, 2014), which contains a flexible waveguide having an elongated axis, a proximal end, optically connected with a radiation source, a distal end configured to be placed in a blood vessel and containing a tip with an emitting surface and a reflecting surface spaced apart from the emitting surface in the distal direction and facing towards it to reflect the forward radiation I in the direction towards the elongated fiber axis at an angular range extending in the surrounding wall portion of the vessel from about 90 ° to about 360 ° in a ring.

The disadvantages of this device is the insufficient efficiency of laser ablation of large veins, since a narrowly localized and unidirectional radial distribution of laser energy to the inner wall of the vessel, carried out in the form of a local thin ring, at low levels of laser energy supplied to a varicose dilated vein, may be insufficient for reliable endoluminal laser ablation of a vessel of large diameter and can lead to its recanalization, and, consequently, to recurrence of varicose veins.

When this device uses high levels of laser energy, the thin annular distribution of the laser source radiation on the vessel wall creates a narrow local zone of a significant increase in temperature, which causes a rapid process of carbonization of biological tissue, leads to its sticking on the radiating surface of the waveguide, an increase in the depth of the necrosis of the vascular wall and the risk of radiation perforation, which leads to the development of serious complications.

In addition, the disadvantages of this device include its complexity, since the presence at the distal end of the device of a special tip with emitting and reflecting surfaces requires an additional process during the manufacture of the device, which significantly increases the cost of the product.

Closest to the claimed utility model is a device for endoluminal treatment of a blood vessel (Application for utility model No. 2017136624 of 10.17.2017), which contains a flexible waveguide, which is an optical fiber having an elongated axis, a proximal end, optically connected to a radiation source , the distal end, made with the possibility of placement in a blood vessel and containing a tip with an emitting surface that is made on the quartz core of the fiber and has the shape of a part of the sphere truncated konus.Chast minutes in a protective sheath, adjacent to the tip, made of a polymeric reflective layer having a refractive index less than that of silica fiber core, and placed in a stainless steel capillary. The use of this device has shown high efficiency of the process of thermal obliteration of varicose veins.

The disadvantage of this device is the fact that the effectiveness of its use when performing endovasal obliteration of large diameter varicose veins depends on the spectral composition and intensity of laser radiation, which requires the use of modern laser generators operating in the wavelength range from 1000 to 1500 nm, the cost of which is much higher first-generation laser radiation generators with a shorter generation wavelength.

The objective of the proposed utility model is to reduce the cost of the treatment process by the claimed device while maintaining its high efficiency.

This is achieved by the fact that the device for endoluminal thermal obliteration of varicose veins containing a flexible waveguide, which is an optical fiber having an elongated axis, a proximal end, optically connected to a radiation source, a distal end made with the possibility of placement in a blood vessel and containing an optical tip with the emitting surface, made on the quartz fiber core, has an optically opaque hollow metal cap with a perfectly ground surface, a cat The other is the main heating element of the device mounted on the tip. In this case, the fiberglass itself has a double protective sheath over its entire length, the inner layer of which is made of aluminum thread, braiding directly the fiberglass, and the outer layer made of a special heat-resistant polymer with a low roughness coefficient, which is rigidly attached to the cap.

The presence of a hollow metal cap on the laser-emitting tip allows it to be used as the main heating element of the device for conducting endoluminal thermal obliteration of varicose veins. Moreover, the use of laser radiation for heating the energy completely eliminates the potential danger of the patient getting under the influence of an electric current, the energy of which is used during endovasal electrocoagulation of varicose veins. In addition, the metal tip provides a more uniform and direct contact of the surface of the main heating element of the device with the inner surface of the vessel, which contributes to a more effective subsequent obliteration of the lumen of the vein and eliminates the development of complications inevitably encountered during endovasal laser coagulation.

The presence on the fiberglass of a double protective sheath over the entire length, the inner layer of which is made of aluminum thread, braiding directly the fiberglass along the entire length, on the one hand, reliably fixes the metal cap to the fiberglass, and on the other hand, protects the fiberglass itself from possible damage during advancing inside the vein and performing other manipulations.

The presence of the outer layer of the protective shell made of a special polymer with a low roughness coefficient, in combination with a perfectly polished surface of the metal cap (the friction coefficient tends to 0), provides ideal (maximum) sliding along the inner surface of the vessel, which ensures uniform distribution of thermal effect during the endoluminal thermal obliteration of varicose veins.

Experimental studies have shown that the use of this device for thermal obliteration of varicose veins allows you to use any laser radiation generators as an optical emitter, regardless of the spectral composition of radiation emitted by them, since the temperature regime proposed for a particular case directly depends on the main controlled energy parameter, measured in watts (W) regardless of the radiation wavelength, pulse duration repetition rate, allowing the use of low-power laser light sources of the simplest designs that significantly reduce the cost of medical treatments when compared with the prototype. In addition, the possibility of sterilization and, as a consequence, reusable use of the device can further reduce the cost of the procedure.

The figure shows a general view of the device.

A device for endoluminal thermal obliteration of varicose veins contains an optical fiber 1 with an elongated axis, on the quartz core of which an optical tip 2 is made with an emitting surface, on which a perfectly ground metal cap 3 is mounted. The optical fiber has a double protective sheath 4 throughout, the inner layer of which made of aluminum thread that braids directly fiberglass 1 and rigidly attaches it to the metal cap 3. The outer layer of the shell, made made of a special heat-resistant polymer, also connected to a metal cap 3.

A device for endoluminal thermal obliteration of varicose veins works as follows. After connecting the optical fiber to the device, the required laser power in watts (W) is set. After the intravenous catheter is inserted, an endoluminal thermal obliteration device is endovasally inserted. Ultrasonic visualization of the position inside the vessel at the distal end of the device increases the metal cap 3. After the device is inserted into a vein, laser radiation with a given intensity is supplied to the distal end of the optical fiber where the optical tip 2 is located. In this case, an energy flux of laser radiation is formed on the emitting surface of the optical tip 2, which, being transmitted to the inner surface of the metal cap 3, heats it. In this case, the inner layer of the protective shell adjacent to the metal cap made of aluminum filament reliably fixes the metal cap to the optical fiber, which prevents the cap 3 from tearing off the optical fiber 1 when it is heated and moving along the vein. The outer layer of the protective shell adjacent to the metal cap 3, made of a special heat-resistant polymer, on the one hand, additionally fixes the metal cap 3 to the optical fiber 1, creating a single integral device, and on the other hand, provides maximum glide together with the perfectly ground surface of the metal cap the entire device while it is moving inside the vein.

Gradual endoluminal thermal obliteration of varicose veins is performed as the device is removed again under direct ultrasonic visualization of the positioning of the metal cap 3. The device for endoluminal thermal obliteration of varicose veins ends with its simultaneous extraction from the lumen of the vessel. Thus, the endoluminal thermal obliteration of varicose veins is performed gradually throughout the vein as the device is removed.

Claims (1)

A device for endoluminal thermal obliteration of varicose veins, containing a flexible waveguide, which is an optical fiber having a proximal end, optically connected to a radiation source, a distal end configured to be placed in a blood vessel and containing a tip with an emitting surface, made on the quartz fiber core, characterized in that it has an optically opaque hollow metal cap mounted on the tip of the distal end of the fiber, while of the fiber is provided with double protective sheath, the inner layer of which is made of a metallic braid and the outer one - of heat-resistant polymer coating on its entire length and is rigidly attached to the cap.

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