RU2528655C1 - Fibre-optic tool with curved distal working part - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: distal portion of an optical fibre is placed in a ferrule with spacing on the entire length and the end of the optical fibre is welded onto the inner surface of the welded portion of the ferrule. The required radiation distribution at the output of the tool can be obtained by varying the thickness of the welded portion of the ferrule and the shape of the external optically refracting surface.

EFFECT: simple design.

6 cl, 3 dwg

Description

Technical field

The invention relates to the field of technology intended for laser processing of materials in hard-to-reach areas, as well as to the field of medical equipment, namely, devices used during laser surgical and therapeutic procedures in hard-to-reach departments of internal organs, including laser vaporization and coagulation prostate adenomas.

State of the art

In many intracavitary operations, various soft tissues are removed, such as tumors, plaques, fat, etc. For example, with the appearance of prostate adenoma, the resulting tumor must be removed. Surgical methods for removing adenomas are divided into open, with access through the bladder, and minimally invasive - without an incision, through the urethra.

Various devices are used to perform minimally invasive operations, including fiber-optic instruments using laser radiation or radiation from powerful diodes. The principle of operation of such tools is based on thermal coagulation and ablation (evaporation) by radiation of pathological tissues. Due to the ability to concentrate the energy of optical radiation in a small volume, fiber-optic instruments can more accurately affect diseased tissue areas without affecting healthy ones.

US Pat. No. 5,366,456 proposes a design of a laser fiber scalpel in which radiation emerging from an optical fiber is reflected at an angle from a special element — an insert having a reflective surface. The disadvantage of this design is that part of the radiation is absorbed on the reflective surface of the insert, which leads to undesirable heating of the tool and requires cooling. Another disadvantage is the complexity of the design, consisting of several complex elements.

US 6,699,239 discloses a fiber optic instrument consisting of two parts: an optical fiber and a tip. The tip has a straight section and a section deflected at a certain angle to the axis of the optical fiber. The radiation emerging from the optical fiber propagates inside the tip, undergoing complete internal reflection at its boundaries. The disadvantage of this design is that when working in a liquid medium at the bend, the condition of total internal reflection on the outer surface of the tip may be violated, which will lead to radiation losses at the bend and irradiation of healthy tissues. In this case, less radiation energy will be delivered to the desired exposure zone.

US Pat. No. 5,416,878 proposes a fiber tool in which a bent tip directs radiation at an angle to the axis of the optical fiber. This design has two drawbacks: the flat emitting end of the optical fiber does not allow focusing the radiation, and the bare thin core of the optical fiber can break, so it becomes necessary to use optical fibers with a large core diameter (of the order of 1000 μm), which limits the scope of the tool.

As a prototype taken the tool described in patent application US 2011/0160713 A1. In this design, the tip with a bent end is contacted in a fixed manner on the distal portion of the optical fiber exposed from the sheath. It is indicated that the optical fiber and the tip are made of quartz or glass and are fused with each other along the length of the exposed portion, and the end of the optical fiber in the tip may either not reach the end outer surface of the tip, or be part of the outer surface, reaching contact with the surrounding tip of the external environment. Such a design of a fiber-optic instrument is more reliable than previously proposed, since the tip in it has a more mechanically strengthening role than an optical one. However, it also has several disadvantages.

The first disadvantage of the prototype is that the optical fiber and the tip are welded to each other along the length of the exposed section. Since the radiation in the tip extends to the end located at the end of the bent part, in order for the radiation not to extend beyond the tip at the bend, the condition for total internal reflection at the interface between the materials: core, fiber sheath, tip and the environment must be met. The condition of total internal reflection is determined by the ratio of the refractive indices of the contacting media, but due to the fact that the refractive indices of these materials cannot vary greatly, the design of the instrument has significant limitations regarding the angle of inclination of the bent part, the divergence of radiation introduced into the fiber, and also the materials of the instrument.

For example, when using a typical quartz optical fiber with a numerical aperture of 0.22 and a tip made of quartz with a typical refractive index of 1.45, the conditions for the delivery of radiation to the emitting end face without loss (when the tip is operating in an aqueous medium) will be fulfilled at an inclined angle parts not exceeding 20 degrees. When using an optical fiber with a larger numerical aperture, for example 0.33, the maximum angle of inclination of the bent part does not exceed 15 degrees.

Fibers with a numerical aperture of 0.22 and 0.33 are preferred in use, since they are widespread and relatively inexpensive. In addition, it is easier to introduce radiation of higher power into an optical fiber with a larger numerical aperture.

These design features limit the use of common optical fibers, impose restrictions on the angle of inclination of the emitting end, or require special selection of materials with a large ratio of refractive indices.

Another disadvantage of the prototype is that the divergence of radiation at the output of the tool is set by the curvature of the surface of the radiating end of the optical fiber. In one implementation of the prototype, the radiating end face of the optical fiber having a given surface curvature is simultaneously a radiating surface. Such a configuration does not allow the best use of the focusing properties of the refracting surface, since It is known that, along with setting the surface curvature in optical systems, the distance from the refracting surface to the emitting object is set for optimal focusing.

In another implementation of the prototype introduced additional refractive surface located at a distance from the radiating end. These surfaces can increase the degree of focusing of the radiation, but introduce unwanted losses.

Disclosure of invention

The aim of the invention is to reduce losses in the transmission of radiation to the exposure zone, increasing the angle of deviation of the radiation beam at the output of the tip while increasing the fraction of radiation power delivered to the processing zone, as well as the formation of the required spatial and energy parameters of laser radiation in the area of influence. An additional goal is to simplify the design of the tip and enable the use of optical fibers with a larger numerical aperture.

This is achieved by the fact that, in contrast to the known technical solution, the distal portion of the optical fiber is located inside the bent tip with a gap along the entire length of the tip, including the bending region, the end face of the distal portion of the optical fiber is welded to the inner surface of the brewed portion of the tip, forming with the outer optically refracting surface of the tip optical element, and from the side of the open part the tip is hermetically attached to the protective sheath of the optical fiber.

Description of drawings

Figure 1 shows a cross section of a tool.

Figure 2 shows the main dimensions of the structure.

Figure 3 shows a design variant in which the optical fiber is offset from the axis of the tip. An enlarged view of the curved part of the tool is shown.

The implementation of the invention

Fiber-optic instrument (1) contains (Fig. 1): optical fiber (2), the distal portion of the optical fiber (3) exposed from the protective sheath, the tip (4), the gap (5) between the surface of the distal portion and the inner surface of the tip, the curved portion of the tip (6), the brewed portion of the tip (7), the adhesive seam (8), the end face of the distal portion of the optical fiber (9), the optically refracting surface of the brewed portion of the tip (10).

The device operates as follows.

Radiation is introduced into the optical fiber 2, the input end of which is connected to a laser or a main optical cable (not shown in the figures). The radiation propagates along the fiber towards the tip 4.

Inside the tip 4, the radiation emerging from the fiber 2 continues to propagate in the distal portion 3 exposed from the protective sheath. The distal portion is located with a gap 5 inside the cavity of the tip 4. A vacuum can be created in the gap 5, it can be filled with air or other gas . The size of the gap H (figure 2) should be greater than the wavelength of radiation.

The distal portion 3 may be a continuation of the core and the optical sheath of the fiber, and also (in the case of a quartz-polymer fiber) a continuation of only the core of the fiber without an optical polymer sheath.

Due to the fact that the refractive index of the material of the distal portion 3 is significantly greater than the refractive index of its environment in the gap 5, the condition of total internal reflection is not violated in the bent portion of the tip 6 and the radiation is delivered without loss to the end of the distal portion of the optical fiber 9. The angle of inclination A of the bent plot to the axis of the fiber lies in the range from 20 to 90 degrees.

After passing through the curved section 6, the radiation from the distal section 3 enters the brewed section 7.

The end face of the distal portion of the optical fiber 9 is welded to the inner surface of the brewed portion 7.

It is known that during welding, residual stresses are formed due to thermal deformations of the materials being welded. Residual stresses can lead to destruction of the weld. Therefore, the materials of the distal portion of the fiber 3 and the tip 4 have close values of the coefficients of thermal expansion.

The optically refractive surface 10 is the outer surface of the brewed portion 7. This surface may have a convex, concave, flat or conical shape. The end face of the distal portion of the optical fiber 9, welded to the inner surface of the brewed portion 7, and the optically refracting surface 10 form an optical element (lens, prism, meniscus), the thickness of which (figure 2) is determined by the formula:

D is the diameter of the brewed area;

d is the diameter of the distal portion of the fiber;

n _with - the refractive index of the material of the fiber core;

n _e is the refractive index of the tip material;

NA is the numerical aperture of the optical fiber;

And - the angle of inclination of the curved section to the fiber axis.

By setting the thickness B and the shape of the surface 10, it is possible to obtain the desired radiation distribution at the output of the tool.

In some implementations of the design, the end of the optical fiber is located with an offset S perpendicular to the axis of the curved section 6 in the direction opposite to the bend (figure 3). This makes it possible to further increase the angle of deviation of the radiation in the tip. The deviation angle K of the radiation relative to the axis of the bent section is determined by the ratio:

f 'is the distance to the focal plane of the refracting surface in the medium surrounding the tip;

S is the magnitude of the displacement of the end of the optical fiber perpendicular to the axis of the curved section.

From the side of the open part, the tip 4 is hermetically attached to the protective sheath of the optical fiber by means of an adhesive seam 8.

During operations, the instrument can be placed in the instrument channel of the endoscope, where the area of laser exposure can be controlled using the visual channel.

An embodiment of the invention

One of the embodiments of the invention shown in figure 2. A quartz-polymer optical fiber with a numerical aperture of 0.33 is used, in which the core is made of quartz glass and the sheath is made of polymer. The distal section inside the tip is a continuation of the fiber core, exposed from the optical polymer sheath and protective sheaths. The diameter of the distal portion d is 0.6 mm. The tip is made of quartz glass. The outer diameter of the tip M is 2 mm, and the diameter of the refractive surface of the tip D is 2.5 mm. The gap H between the distal portion and the inner surface of the tip is 0.2 mm. The angle of inclination A of the curved section is 30 degrees. The thickness of the brewed plot is equal to 0.7 mm The length of the straight part of the tip L ₁ is 13.5 mm, the length of the curved part L ₂ is 4.5 mm.

Claims (6)

1. Fiber optic instrument containing:
optical fiber with a distal portion exposed from the protective shells,
a tip in the form of a curved hollow cylinder made of a material transparent to the radiation used, having a section welded on one side with an external optically refracting surface, located so that the distal portion of the optical fiber is placed inside the tip,
characterized in that the distal portion of the optical fiber is located inside the tip with a gap along the entire length of the cavity of the tip, including the region of its bending, and the gap exceeds the wavelength of the radiation propagating through the fiber,
the end face of the distal portion of the optical fiber is welded to the inner surface of the brewed portion of the tip, forming an optical element with the outer optically refracting surface of the brewed portion of the tip, the thickness of which is determined by the formula:

D is the diameter of the external optically refracting surface of the brewed area;
d is the diameter of the distal portion of the optical fiber;
n _with - the refractive index of the material of the fiber core;
n _e is the refractive index of the tip material;
NA is the numerical aperture of the optical fiber;
A is the angle of inclination of the curved section to the fiber axis;
the coefficients of thermal expansion of the materials of the core of the fiber and the tip have close values. 2. The fiber optic instrument according to claim 1, characterized in that the distal portion of the optical fiber contains only the core, cleaned from the optical shell and protective shells. 3. The fiber optic instrument according to claim 1, characterized in that the tip and the distal portion of the optical fiber are made of the same material. 4. The fiber optic tool according to claim 1, characterized in that the tip is hermetically attached to the protective sheath of the optical fiber by means of an adhesive seam. 5. The fiber optic tool according to claim 1, characterized in that the end of the distal portion of the optical fiber is offset perpendicular to the axis of the tip in a direction opposite to the bend, so that the gap between the distal portion of the optical fiber and the tip does not exceed the radiation wavelength. 6. The fiber optic tool according to claim 1, characterized in that the external optically refracting surface of the brewed portion of the tip may have a convex, concave, flat or conical shape.

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