UA80902U - Radial light-guide - Google Patents

Abstract

A radial light-guide for three-dimensional irradiation of the cavities of organs and blood vessels with high intensity laser radiation is made of quartz fiberglass. At the distal end, the conical end-face is shaped with the aid of electric arc welding. The angle at the apex of the cone approximates 60 °.

Description

The useful model belongs to medicine, namely to surgery, and can be used for volumetric irradiation of hollow organs and vessels with high-intensity laser radiation. An example of the use of this model can be endovenous laser coagulation (EVLC).

For the effective performance of a number of surgical operations, for example EVLK, it is necessary that most of the energy of laser radiation be used for direct impact on biological tissues, in the case of EVLK - on vessel walls. To carry out this procedure, a light guide is inserted through a puncture of the skin into a varicose vein along the entire length of the pathological area, and when the light guide is slowly removed from the vessel, laser coagulation is performed. The essence of the operation consists in local thermal damage of the vein by laser radiation, which leads to the exclusion of the vein from the pathological blood flow, obliteration of the affected area and, subsequently, its complete resorption |11.

When performing EVLC, a light guide made of quartz-quartz (0/0) or quartz-polymer (O/R) glass fiber with different diameters, a polymer shell and an inner glass fiber core is usually used to deliver laser radiation from the device to the intervention area.

The proximal end of the optical fiber is mounted in the ZMA-905 connector. When laser radiation exits the end of the light guide, if it is in the "air" environment (refractive index n corresponds to 1), the aperture angle is 35-40" (Fig. 1). After the introduction of the light guide into the vein, the aperture angle decreases to 20-25" , as the refractive index of blood n corresponds to 1.35-1.38 (Fig. 2). When applying laser energy to such a light guide, the rays spread along and pass almost tangentially to the walls of the vessel. This does not provide sufficient heating of vessels for thermal damage to their walls. The procedure is performed due to the steam bubbles formed when the laser radiation is absorbed by the blood, which create a high temperature inside the vessel and ensure thermal damage to the endothelium |2)|. This requires high laser power, the energy absorption of which is sufficient to "boil" the blood in the vessel and indirectly damage the inner wall. If the beam coming out of the end of the light guide is perpendicular to the vessel wall (about 90-95"), the energy is received directly by the vessel walls, so the obliteration process occurs faster when using a lower laser power. For this, there are light guides with a wide opening of the beam and at

During the operation, the energy of the laser radiation is dispersed in the form of a ring along the entire diameter of the vein (Fig. 3). The use of such a light guide also makes it possible to successfully process veins of any diameter, to make the vein treatment process accurate and uniform.

Kaidiai EIme5 radial light guides (VioShes AS, Germany) with a formed microlens at the distal end are known. Such a light guide provides uniform photothermal destruction of the vessel walls, avoids vessel perforations and minimizes complications. The disadvantage of this fiber optic cable is that the fiber optic cable can cause burns if it is placed close to the skin. Also, the disadvantage of this light guide is the feature of fixing the microlens on the end of the glass fiber, which causes the high cost of such a light guide.

There is also a device for isotropic irradiation of walls of cavities, including vessels |Z).

The invention relates to devices for irradiating cavities using a catheter containing a glass fiber with a conical tip and a sleeve that expands when a liquid is supplied. Such light guides are used in cavity organs, where it is important that the light spreads evenly along the walls of the cavity. The end of the glass fiber, which is attached to the catheter, is formed in the form of a cone. The disadvantages of this device are that the conical tip must be securely fixed in the catheter. The place of transition from the glass fiber in the protective shell to the distal end with the catheter is very fragile and there is a danger of breaking it during the operation. Also, it is not always necessary to use a hose for liquid during various operations, it only complicates the design of the device. Also, such a light guide cannot be used in hard-to-reach places with a small cavity diameter. In the radial light guide that is being developed, we also use a conical tip to spread laser radiation to the walls of vessels and cavities, but the design of the light guide is simplified and there is no such sleeve for supplying liquid.

There are also light guides for laser vascular anastomosis with radial opening of the beam |4|. The distal end of such a light guide is formed in the form of a cone. A laser beam that falls on the interface between air and fiber is reflected by total internal reflection and, falling on the opposite side of the fiber wall, exits into the air. In this way, the laser beam is reflected from the opposite wall and forms radiation in the form of a ring. Opening the rays in the form of a ring allows for uniform photothermal destruction of vessel walls, optimal use of the power of laser radiation, because perforations of vessels are avoided and complications in the postoperative period are minimized.

allows you to safely close the vessels, avoiding burns and nerve damage. The conical tip is formed while drawing the glass fiber, then it is polished under difficult technological conditions to achieve a perfectly smooth quartz surface. The disadvantages of this invention are the lack of protection of the end of the light guide, the complexity of the manufacturing technology and polishing of the ends. This patent was chosen as the prototype for our radial light guide.

An example of the opening of the rays of the optical fiber, which is used for EVLK /1|, is shown in fig. 1, where: 1 - quartz vein fiberglass. Opening of the rays at 407 is possible when the glass fiber is in the air environment, p-1. In fig. 2 shows the opening of the rays of the light guide (1) when it is inserted into a vein, which is only 20", where: 1 - a quartz vein of fiberglass, C - a vessel.

In fig. C shows the developed radial light guide, where: 1 - quartz vein, 2 - polymer shell of the light guide, C - vessel, GI. - rays that fall directly on the vessel walls.

The same parts of the optical fiber are marked with the same numbers in fig. 1-5.

In fig. 4 shows the path of ray 11 in more detail. A ray from a medium with a refractive index n (air) enters a quartz vein 1 with a refractive index n' and is subjected to total internal reflection at the boundary with a shell 2, which has a refractive index n".

The refractive index pi of quartz, 1.54, is only slightly higher than the refractive index p2 of the shell, 1.495, so the light entering the core from the end of the fiber is completely reflected from the interface between the quartz and the shell and propagates only in it.

Ray I 1 passes with the maximum aperture for this fiber. As an example, a glass fiber with a quartz vein diameter of 2-400 μm was taken, MA is 0.37. We determine the bit angle - the critical angle of incidence of the light flux. Rays of light falling on the interface at an angle smaller than the critical one enter the shell and are subsequently absorbed by the coating (protective shell). Rays of light that have reached the interface at an angle greater than the critical angle are completely reflected, constantly repeating, which ensures the propagation of radiation along the optical fiber (5-7|.

Ov agsvipi/pe -p I- V lah,

O«khah agovipitAvy -147 I- 216" bitah-21.6"7, at the same angle we pass ray 1. Since the light ray 11

If it passes from a medium with a lower refractive index to a medium with a higher index, then this ray is refracted. We determine the angle of refraction of ray 11 incident on the air-fiber interface. We use the law of refraction of rays:

Zip(ie) p - -'e- -- 85 - 3-5

Vip(ye) n v-agovip RP Zip(v) - agovip 1. vip) Zipig16 -1388 p 1.54 "In this case, the angle of incidence U corresponds to angle 8. We draw the normal to the point of incidence of the beam. We determine the angle of incidence from a right triangle, from is 7627". At the same angle 9dtah, which is equal to 21.6", ray 11 exits from the distal end of the optical fiber.

The figures given above show that a conventional optical fiber does not allow to open the laser radiation in the form of a ring, as required for EVLC operations.

We will get the maximum opening of the beam no more than the critical angle.

For the manufacture of the developed radial light guide, you can use quartz glass fiber with different diameters of the quartz vein. For example, to show in comparison the opening of the rays at the end of the developed radial light guide and a conventional light guide (11 in Fig. 2, we used a glass fiber with a quartz vein diameter of 400 μm, MA is 0.37.

The angle of entry into the glass fiber 9 of the beam 12 and the angle of refraction in the fiber corresponds to the angles of the beam

Y1 in fig. 4.

In fig. 5 shows: the distal part of the developed radial light guide with a polymer shell 2, a quartz vein 1 and an end made in the form of a cone 4. Also shown is the course of the beam 12, which passes through the quartz vein and is refracted in the quartz-air medium at an angle a. The angle of incidence of the laser beam 12 with the line normal to the cone at the first point of incidence is called a. Also shown is an IR laser beam incident on the quartz-air interface, reflected by the law of total internal reflection at an angle of 9/2 and emerging from the opposite wall of the fiber with the maximum angle of refraction B, at an angle of 90" to the conical part.

Thus, all laser beams, reflecting, are refracted to the side and form a ring around. Therefore, most of the laser energy required for effective conduction

EVLK, get the walls of the vessels.

For this opening of the rays, it is necessary to form a distal conical end with an angle at the top of the cone f.

Zipa-1/p, (p-1.5); hence 4-42", a-90-f/2; hence f-967.

But, if we assume that the MA of the glass fiber is determined on the basis of the refractive index of the quartz vein and the polymer shell n, laser beams can be conducted in the range of 157 (depending on the type of fiber and the diameter of the vein). Laser beams that fall on the wall at an angle of 15" have total internal reflection, and laser beams that are beyond the critical angle of 15" go beyond the wall of the conical tip. Therefore, it is desirable to reflect all laser beams in total internal reflection. For this purpose, the conical tip should have an angle at the tip of φ-96"-307, assuming that the fiber has its MA. Therefore, the best light guide is the one in which the apex of the tip φ is equal to 60".

The KSS-111 electric arc welding machine was used to form the distal end. In fig. b shows the design of the apparatus for electric arc welding of optical fibers, where: 5 - tungsten electrodes, 6 - drive for the horizontal fixator of the optical fiber, 7 - microscope, 8 - optical fiber, 9 - drive for vertical movement of electrodes, 10 - drive control handle, 11 - tables for alignment, 12 - prepared fiberglass.

Prepared for welding, the optical fiber 12 is fixed in M-shaped grooves for fixing the fiber. The quartz glass fiber 12 is melted by the arc discharge that occurs between the tungsten electrodes 5, at this time, with the help of the control knobs 10, the tables 11 are separated. At the same time, at the end of the quartz fiber, which is in a molten state, a cone-shaped end is formed, with an angle at the top Ф. The angle Ф, which should be close to 60, depends on the strength of the current, the speed of fiber melting, and the movement of the tables.

The advantages of such a light guide: it allows you to successfully process veins of any diameter, to make the process of vein processing accurate and uniform, to reduce the cost of the technology of manufacturing the end

From a radial light guide. Disadvantages: insecurity of the end of the optical fiber, the conical end formed by electric arc welding is disposable and can be used for one operation.

Sources of information: 1. Krysa V.M. Endovenous laser coagulation in the treatment of varicose veins of the lower extremities / Krysa V.M., Pantyo V.I. - Ivano-Frankivsk, Uzhhorod, -2012-8 p. 2. Sokolov A.L., Lyadov K.V., Belyanina E.O., Lutsenko M.M. Application of laser radiation with a wavelength of 0.94-0.98 μm in the treatment of peripheral vein diseases. - Medical technology. - M.: "Izd. I.V. Balabanov", 2009.-32 p. 3. 055354293А ОЕ, AbI1M 506, Arragayizv og pe isoigoris itaadiayop oi samu waiiv LMoiidapad

Veueg, Agtip Neiip2e, Oivsieg dosnat, Kia 5sptiy, Ebeptaga Opzoei|a. - Fish. Wow. 18, 1989. 4. 054625724А ОР AbИ1В 17/36, I azeg mazsshag apaziotov arragaitsy5 / Mazape 5ygiki, Nigozvni

Zpiratoio, Moyupotgi Kapaua-Pisces. Oes. 02, 1986. 5. Vereshchagin I.K. and others. Introduction to Optoelectronics: Textbook. allowance for university students / I.K.

Vereshchagin, L.A. Kosyachenko, S.M. Kokin. - M.: Viessh. Shk., 1991.-191 p. 6. Fiber optic sensors / Ed. T. Okosi: Trans. From Japan. - L.: Energoatomizdat.

Leningrad Otd-nie, 1990, 256 p. 7. Listvyn A.V. Optical fibers for cable communication / Listvin A.V., Listvin V.N., Shviirkin

D.N. - M., 2003-154 p.

Claims (1)

UTILITY MODEL FORMULA A radial light guide for volume irradiation of organ cavities and vessels with high-intensity laser radiation, which is made of quartz glass fiber, which is distinguished by the fact that the conical end is formed by electric arc welding at the distal end, with an angle at the apex of the cone close to 60" .