DE3901931A1 - LIGHT-GUIDE FIBER FOR THE RADIAL RADIATION OF TUBULAR CAVE SYSTEMS WITH LASER BEAMS - Google Patents

Abstract

A fibre optical waveguide having a core region (2) and a casing (3). For the purpose of radiate irradiation of tubular hollow systems by laser beams introduced axially at one of its ends, at least one reflecting surface (4) is provided at the exit end of the waveguide. The reflecting surface (4) formed in the core region (2) and delimits a hollow space (5), open towards the exit end, in the core region (2). <IMAGE>

Description

The invention relates to an optical fiber with a core area and a jacket, which for the radiative irradiation of tubular migen hollow systems with axially coupled at one end Laser beams at their exit ends with at least one reflector ting surface is provided, and a method for their Manufacturing.

The method of radial irradiation, especially of low-volume tubular hollow systems with laser beams are not only found in technology, but also its application in medicine in many cases, especially in laser balloon angioplasty at Rekanalisa tion and dilation of narrowed blood vessels through thermal coagulation lation.

With this method, during opening or Stretching closed or narrowed blood vessels of a balloon catheter in the area of the balloon surrounding stretched vessel wall thermally welded with laser beams, which significantly reduces the risk of reclosure is set. The laser beams are in the catheter over a Optical fiber, which ends in the balloon, to be irradiated guided the vascular area, the exit end of the Lichtleitfa This must be prepared in such a way that a uniform radial deviation radiation of the laser beams is effected.

One way to get a uniform radial radiation len consists of having the exit end of the optical fiber to provide suitable scattering bodies.

Such a measure is described in W085 / 05 262. The W 085/05 262 relates to a laser probe, especially for surgery applications is suitable. This laser probe consists of essentially from an optical fiber which the laser beams from a laser to one end of the optical fiber  optically coupled tapered in the beam direction Sapphire body leads within which the laser beams Taking advantage of total reflection focused on the cone walls before they emerge from the cone tip. In a particular Ren embodiment is now provided in W085 / 05 262 to which Cone tip still another essentially spherical Section consisting of a sapphire material which stray tren in the form of finely divided gas bubbles Men, depending on the geometry of the arrangement of the divergence angle the radiation emerging from the sapphire tip is increased as desired can be.

A disadvantage of this arrangement, however, is that the Attachment as well as the optical coupling of the sapphire tip the fiber end is difficult and technically complex. In particular is a significant widening of the diameter of the laser probe connected. Furthermore, there is an increased risk of breakage in the Coupling area of the flexible optical fiber and the rigid Sapphire tip, creating applications that have flexible guidance the laser probe in curved hollow systems, not possible are.

The aforementioned disadvantages are partly with that from the GB-PS 11 54 761 A known arrangement overcome, which is thereby is characterized by the fact that a uniform radial radiation is achieved that the core area of the optical fiber itself on Exit end is formed into a cone, but in the opposite set to the arrangement from the W085 / 05 262 the geometry of the cone so is chosen that the laser beams do not point to the fiber tip focused, but radially across the entire cone surface be radiated outside.  

However, the optical fibers prepared in this way show in practice a high susceptibility to mechanical loads, especially re in the area of their unprotected cone tip, so that also at careful handling can be expected to break frequently. For applications in the medical field, this results in one unreasonable burden on the patient. But also with others Applications make the associated additional time, mate rial and labor the use of such an optical fiber unprofitable.

The object of the present invention is now a Lichtleitfa to create water of the type described above, which the before does not have the disadvantages described above, and a procedure to provide for their manufacture.

This object is ge with an optical fiber according to claim 1 solves.

The invention is described in detail below.

The optical fiber according to the invention is characterized by a increased breaking and bending strength compared to the prior art due to the protective jacket surrounding the core area over the entire length of the optical fiber, also in the area of the Exit end, remains intact.

In a preferred embodiment of the invention, it is provided hen, the cavity delimited by the reflecting surface Core area of the optical fiber to give the shape of a cone, the base of which faces the exit end of the optical fiber. Such an inner cone has compared to that of the prior art nik known outer cone due to a higher surface area moment the advantage of an incomparably higher mechanical Stability.  

When using a full core optical fiber, a good reflect Effect of xion achieved when the opening angle of the cone is between 45 ° and 90 °. According to the invention it is provided that the height of the cone does not exceed 2 mm, so that a good mecha African stability is guaranteed. Because of their good optical and physical properties, a quartz is preferred glass fiber with a core diameter of 200 to 600 µm puts.

However, the shape of the reflective surface is by no means on limited the cone jacket described above.

According to the invention, any surface is possible, as far as they emit an even radial radiation of the laser beams outside effect.

Because of the easier production, reflective surfaces are which have a constant curvature, those with defined ones Discontinuities, such as points or edges, preferable. Such surfaces can be ellipsoidal, paraboloid or spherical, but also intermediate represent shapes of various basic geometric types.

A preferred embodiment of the invention provides that Shape the reflective surface so that the cavity in the core the optical fiber has the shape of a cone with a rounded shape Has peak. This embodiment has the advantage that an even radial radiation of the laser beams is achieved and that on the other hand in the manufacture of this There is no need for complicated and complicated cone tips.

To increase the scattering effect is another preferred Embodiment of the invention provided the cavity on its  Inner surface with a layer of reflective or sprinkle to line the material that does not absorb the laser radiation the. It is technically simple to manufacture the cavity play with a metal film by means of vapor deposition, sputtering or similar processes or on the inner surface to apply a powder of a suitable material. Especially ders advantageous in terms of the effort involved in applying a It is even powder layer, just the entire cavity to fill with the powder.

Because of its high reflectivity, this is particularly important Suitable for metal dust. In a preferred embodiment the use of barium sulfate as a scattering material hen, since its effect is known as an efficient phase spreader and to get it very easily and inexpensively fen is.

The powder made of reflective or scattering mate rial not only increases the spreading capacity, but also the mecha African strength of the exit end of the optical fiber. Here will also relate to the powder layer introduced into the cavity the powder volume against mechanical stress of effectively protected on the outside.

Preferably, the cavity is closed at its open end with a Metal balls sealed, which also causes the part of the laser radiate, which continues in the axial direction from the fiber end exits a back reflection. In a preferred embodiment form is used because of its good corrosion resistance a gold ball.

The reflective surfaces can be easily Laser material processing, preferably by means of a pulsed,  in the UV range emitting laser in the core area of light fiber can be molded into it. Chemical etching processes are in suitable in the same way.

The optical fiber according to the invention can preferably be used in the laser Balloon angioplasty are used, being thermal Welding the stretched vessel wall in the area of the balloon using laser beams in the central channel of a balloon cathe ters is introduced. The mechanical stability at the same time great flexibility, the special radiation characteristics on Exit ends make them just as suitable as those in Ver equal to the optical fibers known from the prior art with a pointed end of the discharge, significantly reduced risk of injury for the balloon material or the surrounding soft tissue.

However, the optical fiber according to the invention is not only in terms of of their use in angioplasty of interest, but can also be used in the field of photodynamic therapy for the irradiation of multifocal tumors in narrow lumens directly in palliative tumor recanalization in the respiratory or digestive tract are used. Likewise is one such optical fiber in the neurosurgical field of Inter eat.

The invention is based on various embodiments shapes described in connection with the drawings.

Fig. 1 shows a schematic longitudinal sectional view of the exit end of an optical fiber, which is provided according to the invention with a conical cavity and playful for some laser beams whose beam path at the exit end;

FIG. 2 shows, in the same representation as FIG. 1, the exit end of an optical fiber, the reflecting surface being continuously curved;

FIG. 3 shows the same view as FIG. 1, the inner surface of the conical cavity being lined with a layer of a powder made of a scattering material;

FIG. 4 shows the same view as FIG. 1, the conically shaped cavity being completely filled with a powder of a scattering material;

Fig. 5 shows the same view as Fig. 1, wherein the conically shaped cavity is closed at its open end with a metal ball and

Fig. 6 shows an application example of the optical fiber according to the invention from Fig. 3 in balloon catheter angioplasty.

Fig. 1 shows the exit end for the laser beams of an optical fiber 1 according to the invention, which has a core region 2 and a cladding 3 . The reflective surface 4 delimits a cavity 5 in the core region 2 of the optical fiber 1 , which according to a preferred embodiment of the invention has the shape of a cone. The arrow indicates the direction of radiation of the laser beams. Laser beams 6 , 7 , 8 , which are guided in the optical fiber 1 in the axial direction and strike the reflecting surface 4 at the exit end, are totally reflected on this and emerge sideways from the optical fiber.

In Fig. 3, the reflecting surface 4 is lined with a powder of scattering material 10 to increase the scattering effect, whereby a penetrating through the reflecting surface 4 into the cavity 5 laser beam 11 is scattered several times on the powder 10 before it from the optical fiber exit.

In FIG. 4, the entire cavity 5 is completely filled with the powder material 10 from scattering. In particular, the portion of the laser beams that would continue to leave the optical fiber 1 at the exit end in the axial direction undergoes several changes in direction, as shown in the example of the laser beam 12 .

Fig. 5 shows another preferred embodiment of the inven tion. The conical cavity 5 is closed in this embodiment by a metal ball 16 , whereby a Rückre flexion of the entire laser beam emerging through the cone opening occurs. This is illustrated using the example of the beam path of a laser beam 18 .

Fig. 6 shows an application example of an optical fiber according to the invention whose use in laser balloon angioplasty. An optical fiber 1 according to the invention, the outlet end 20 of which corresponds to the embodiment shown in FIG. 4, is inserted into the central channel of a balloon catheter 22 to such an extent that the outlet end lies in the region of the balloon 24 . The balloon catheter 22 is directed into the narrowed blood vessel 26 , which is dilated again by dilating the balloon 24 . In the area of the dilated balloon 24 , the optical fiber 1 to which laser radiation is applied is moved back and forth, the laser radiation 28 radially radiated from the exit end 20 of the optical fiber 1 thermally welding the surrounding tissue 30 of the vessel wall 32 .

The following is a preferred embodiment of the invention described using an exemplary embodiment.

A quartz glass fiber with an outside diameter of 450 and a core diameter of 400 µm was used. The height of the cone with a rounded tip formed into the core area by means of a chemical etching process was 480 µm. The cavity was filled with a powder of BaSO ₄ and then closed with a gold sphere with a radius of 250 µm. The gold bead was attached to the end of the optical fiber using an adhesive transparent to laser radiation.

With the optical fiber end prepared as described above a good uniform radial emission was achieved.

Claims (18)

1. Optical fiber with a core area and a cladding, which is provided for the radial irradiation of tubular hollow systems with axially coupled at its proximal end laser beams, at its outlet end with at least one reflecting surface, characterized in that the reflecting surface ( 4 ) in the Core area ( 2 ) of the optical fiber ( 1 ) is formed and borders an open towards the exit end cavity ( 5 ) in the core area ( 2 ) of the optical fiber ( 1 ) be. 2. Optical fiber according to claim 1, characterized in that the cavity ( 5 ) has the shape of a cone, the base of which faces the exit end of the optical fiber ( 1 ). 3. Optical fiber according to claim 2, characterized in that the optical fiber ( 1 ) is a solid core optical fiber and the opening angle of the cone is between 45 and 90 °. 4. Optical fiber according to claim 3, characterized in that the height of the cone is 2 mm. 5. Optical fiber according to claim 4, characterized in that it is a quartz glass fiber and the diameter of the core is between 200 and 600 µm. 6. Optical fiber according to claim 1, characterized in that the reflecting surface ( 4 ) is continuously curved. 7. Optical fiber according to one of claims 1 to 6, characterized in that the cavity ( 5 ) is lined on the inside with a layer ( 10 ) of reflective or scattering material which does not absorb the laser radiation. 8. Optical fiber according to claim 7, characterized in that the layer is a metal film. 9. Optical fiber according to claim 7, characterized in that the layer of a reflective or scattering powder consists. 10. Optical fiber according to one of claims 1 to 6, characterized in that the cavity ( 5 ) is completely filled with a powder ( 10 ) from a material that does not absorb the laser radiation, scattering or reflecting material. 11. Optical fiber according to one of claims 9 or 10, characterized characterized in that the reflective powder is a metal dust is. 12. Optical fiber according to one of claims 9 or 10, characterized characterized in that the scattering powder is a barium sulfate Powder is. 13. Optical fiber according to one of claims 1 to 12, characterized in that the cavity ( 5 ) is closed at its open end by a body with a reflective surface. 14. Optical fiber according to claim 13, characterized in that the body is a metal ball. 15. Optical fiber according to claim 14, characterized in that gold is used as metal. 16. A method for producing an optical fiber according to claim 1, characterized in that the cavity ( 5 ) in the core region ( 2 ) of the optical fiber ( 1 ) is formed by means of a pulsed laser emitting in the UV range. 17. A method for producing an optical fiber according to claim 1, characterized in that the cavity ( 5 ) in the core region ( 2 ) of the optical fiber ( 1 ) is generated by means of a chemical etching process. 18. Use of the optical fiber according to one of claims 1 to 15 in laser balloon angioplasty for thermal welding Ver a stretched vessel wall ( 32 ) in the region of the balloon ( 26 ) by means of laser beams, wherein the optical fiber ( 1 ) in the central channel Balloon catheter ( 22 ) is inserted.