RU2741236C1 - Light guide instrument with microfocusing - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention refers to medical equipment, namely to lightguide devices for delivery of radiation from a source to an object with point focusing. Light guide instrument with microfocusing consists of a fiber-optic light guide arranged in a sapphire capillary channel having a closed working part with a combined profile, in which smooth narrowing with transition to rod of smaller diameter ends with hemispherical microlens with diameter of not more than 500 mcm.EFFECT: technical result consists in reduction of losses when delivering radiation for creation of point radiation volumes, increase in the range of occurrence depth of objects of laser point action performed by the device.1 cl, 5 dwg

Description

SUBSTANCE: invention relates to devices for laser medicine, in particular to light guide devices for delivering radiation from a source to an object with point focusing. The invention can be used for laser surgery, therapy, diagnostics, photostimulation in various fields of clinical medicine: in ophthalmology, neurosurgery, etc., as well as in biomedical optical spectroscopy, experimental medicine.

Focusing light guide devices require a combination of high spatial resolution and low transmission loss for high energy radiation.

A known device for obtaining a micron laser beam waist at the exit of a flexible waveguide, intended for precision laser surgery, is a contact focusing microprobe [Astratov V.N. Patent US 2012091369 A1 Focusing multimodal optical microprobe devices US 2012091369 A1 2012-04-19]. The device includes from 1 to 20 sapphire microspheres located in a hollow tube, at the other end of which the distal end of a light-guide fiber connected to a radiation source is fixed. The diameters and the number of spheres are chosen so that at the exit of the last sphere the laser beam has a minimum waist size (from 2.5 μm for 1 sphere to 0.8 μm for 15 spheres).

The disadvantages of the device are significant energy losses when the radiation passes through several interfaces between the "air-sapphire" media, where the latter has a high refractive index. The high curvature of the surface of the balls leads to a significant proportion of radiation scattered in the lateral direction to a fraction of useful energy (from a 1: 1 ratio for one ball to a ratio of 100: 1 for 10 balls and more), while the fiber acts as a diffuser, and only a small part of the radiation forms the working beam. In the case of transmission of radiation of high power required for surgical treatment, this will inevitably lead to heating of the probe and thermal damage to the tissues adjacent to the tip, especially during contact interstitial use. In addition, the presence of a boundary between the first microsphere and the tube that emerges on the working surface of the device imposes restrictions on the modes of transmitted power, since all compounds must remain non-toxic and not degrade at high operating temperatures, and also makes it difficult to completely sterilize the device.

The device closest to the proposed invention is an interstitial irradiator based on a sapphire closed capillary [Kurlov V.N. and other RF Patent 2379071 Device for interstitial irradiation of biological tissue with laser radiation / publ. 20.01.2010. bull. No. 2]. The device is a fiber-optic light guide placed in the channel of a closed sapphire capillary. The device, designed for volumetric interstitial irradiation, has a closed cone-shaped part that is used to insert the instrument deep into the tissue, and also forms a beam uniformly distributed into the hemisphere at the exit from the cone. The high physicochemical stability of sapphire, as well as thermal conductivity, allows avoiding overheating zones (opaque for radiation) on the tip and in the irradiated volume and, thus, contributes to the irradiation of the planned volume in the vicinity of the irradiator in the required radiation power density mode. The volume of the irradiation zone significantly exceeds the transverse dimensions of the feed.

The technical result, to which the invention is directed, consists in reducing the losses in the delivery of radiation to create point volumes of irradiation, increasing the range of the depth of the objects of point laser action carried out by the device.

The technical result is achieved due to the fact that in a light guide instrument with microfocusing consisting of a fiber optic light guide placed in the channel of a sapphire capillary having a closed working part, the working part of the capillary has a combined profile, in which a smooth narrowing with a transition to a rod of a smaller diameter ends in a hemispherical microlens with a diameter of not more than 500 microns.

A complex profile, which is a combination of several bodies of revolution, makes it possible to concentrate the light energy at the output of the feed in a submillimeter volume. Since the value of the refractive index of sapphire is higher than that of water, focusing is maintained when exposed to an irradiator inserted deep into the tissue. In the case when the diameter of the microlens at the end of the sapphire capillary is 500 μm or less, the diameter of the waist formed by the radiation at the output of the device does not at least exceed this value, and when using a fiber with a small numerical aperture, the diameter of the waist can be significantly reduced for special applications. The sapphire capillary does not have surfaces with large angles of inclination with respect to the radiation propagation path, which makes the reflection loss and, accordingly, the lateral emission to a minimum. Thus, the fraction of radiation involved in the formation of point focusing is maximum. The absence of heating of the non-working part of the light-guiding instrument guarantees safe exposure to biological objects located in the tissue at a depth of up to 300 mm.

The invention is illustrated by drawings:

FIG. 1 diagram of the irradiator;

FIG. 2 external view of the working end of the irradiator;

FIG. 3 modeling the propagation of radiation through the device into an optically dense medium using fiber-optic light guides with different parameters;

FIG. 4 photograph of the coagulated volumes of a liver fragment at different power of the laser radiation used;

FIG. 5 dependence of the volume of the coagulated area on the power of the transmitted laser radiation with an irradiation duration of 20 seconds.

The device is designed to produce collimated and point-focused beams with a submillimeter transverse spot size, which is preserved when used in optically dense media. To create a point-like waist of a laser beam delivered from a radiation source 1 by means of an optical fiber 2, the working end of which is located in the channel of a sapphire tip 3, the latter has a convex bottom of the capillary channel 4, a light guide part 5 and a focusing element (hemispherical lens) 6, Fig. one.

An embodiment of the working end of the light guide tool according to the present invention is shown in FIG. 2. Modeling of radiation propagation through this embodiment of the device is shown in FIG. 3. The radiation emerging from the quartz fiber in the form of a diverging beam enters the sapphire capillary through the concave end of the channel with reduced losses to Fresnel reflection. Further, the beam passes through the rod part of the capillary, where the rays propagating at a large angle experience several reflections from the side walls. The paraxial rays enter the focusing element directly and form a waist at its output. Beams that have experienced one, two or more total internal reflections form annular conical beams around the paraxial beam with a significantly lower brightness. FIG. 3a shows the production of a collimated beam with a waist diameter of less than 500 μm using a fiber with NA equal to 0.22 (300 μm). The production of a focused beam with a waist diameter of about 100 μm using a fiber with a NA of 0.05 (14 μm) is shown in FIG. 3b.

As an example of the use of a focusing light guide instrument, ex-vivo soft local coagulation of the liver using radiation with a wavelength λ equal to 1080 nm, having a large penetration depth into biological tissues, is shown.

The view of the coagulation zones obtained by interstitial irradiation is shown in FIG. 4. With an increase in the radiation power from 3.5 W to 5.0 W (the power density on the surface of the microlens of the device is 2.3 and 3.3 W / mm ² , respectively), the volume of tissue coagulated within 20 seconds proportionally increases on average from 10 to 50 mm ³ , Fig. 5. The shape of the obtained coagulation areas corresponds to the shape of the scattered radiation field, where the highest power density is created in the tissue volume at a distance of 0.3 ... 1 mm from the outer surface of the microlens (indicated by arrows). This avoids overheating and burning of the tissue, maintains the cleanliness of the contact surface and promotes controlled photothermal destruction with high radial homogeneity. The absence of drying and adhesion of tissue to the contact surfaces of the irradiator to the tissue ensures its safe removal and reduces the potential for injury during its use.

Claims (1)

An optical fiber instrument with microfocusing, consisting of an optical fiber placed in the channel of a sapphire capillary having a closed working part, characterized in that the working part of the capillary has a combined profile, in which a smooth narrowing with a transition to a rod of smaller diameter ends in a hemispherical microlens with a diameter of not more than 500 μm ...

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