DE10063029A1 - Laser surgical applicator and method for its manufacture - Google Patents

Abstract

The applicator consists of a light guide 1 and a glass envelope 5. The light guide 1 and the glass envelope 5 are fused together. The glass envelope 5 is initially opaque and scatters incident light. When fused with the light guide 1, the glass envelope 5 in the fusing area 6 becomes transparent. The remaining area of the glass envelope 5 remains opaque.

Description

The invention relates to a laser surgical applicator and method for the same Production according to the preamble of the respective main claims.

Such a laser surgical applicator and such a method is for example known from DE 195 46 447 A1. In the laser surgery described there Applicator, the glass envelope consists of homogeneous quartz glass.

The laser radiation emerging from the light guide is partially in the quartz glass recycled. At the proximal end of the glass envelope is this with the jacket of the light guide connected. Usually this connection is an adhesive connection with limited Temperature resistance. Through the described return of the radiation in the glass envelope can especially when using higher laser light powers the adhesive bond between the glass envelope and the jacket.

It is an object of the invention to further develop the known applicator and a method to specify that the heating of the connection point by the absorbed laser light is reduced.

This object is solved by the characterizing feature of claims 1 and 7.

The respective subclaims relate to further developments and / or particularly advantageous Embodiments of the invention.

The considerations that led to the development of the present invention assumed that by using a glass envelope made of scattering material the laser light to the outside is emitted and is not absorbed within the glass envelope. The while absorbing the Advantageously, laser light heating does not take place. The glue will not thermally stressed.

Furthermore, the inventive consideration was made that the material properties of the Glass envelope when the actual light guide consisting of a glass fiber is melted  changed. It is spoken of "the actual light guide" because here only the Glass fiber and not the other parts such as cladding and protective cover with the glass cover get connected.

The invention is explained in more detail below with reference to two figures.

Show it:

Fig. 1 shows an optical fiber and the glass sleeve before assembly

Fig. 2 shows the optical fiber and the glass envelope after assembly.

The optical waveguide 1 consists of a glass fiber 2 , which is surrounded by a cladding 3 , the cladding 3 is surrounded by the protective jacket 4 of the optical waveguide 1 . A glass envelope 5 is partially hollow. The broken line indicates the cavity 6 , into which the optical waveguide 1 can be inserted.

In the example shown, the distal end of the optical waveguide is prepared to be inserted into a glass envelope 5 sintered from glass powder.

The cladding 3 has been removed from the glass fiber 2 and part of the protective jacket 4 has also been removed. The optical waveguide 1 prepared in this way can be inserted into the cavity 6 up to the distal end 7 of the glass envelope 5 .

The distal end of the glass fiber 2 is then in a not shown here. Process fused to the distal end 7 of the glass envelope 5 .

Fig. 2 shows the applicator of the present invention after fusion of fiber optic 2 and glass sheath 5. The partial change in the material property in the area of the fusion now leads to the distal end 7 of the glass envelope becoming transparent and the laser light 10 being able to leave the glass envelope 5 there distally.

The proximal end 8 of the glass envelope 5 is glued to the protective jacket 4 . The glue point is designated 9.

The remaining area 10 of the glass envelope 5 remains in the original, opaque state. In this state, the remaining area 10 is highly scattering and the laser light is emitted to the outside. As a result, the laser light is not returned in the glass envelope 5 , and there is no increased temperature at the adhesive point. This has the advantage that the adhesive, which is only temperature-resistant to a limited extent, does not dissolve or become soft under the influence of heat and therefore no longer has any adhesive strength.

This is particularly an advantage if the laser applicator is used in a lumen of the human body. Due to the thermally unloaded glue point 9 , the risk is reduced that when trying to remove the applicator from the lumen, the light guide detaches from the glass envelope 5 and this glass envelope 5 then remains in the lumen.

The glass envelope 5 can consist of so-called "sintered" glass which, due to the porous structure, scatters the incident light. The sintered body runs through several sintering phases from powdery to homogeneously transparent, so that the scattering properties can be set almost arbitrarily.

During the melting process, the glass material of the glass envelope 5 can also be shaped again. For example, the distal end 6 of the glass envelope 5 can be rounded off or can be shaped into a lens with certain optical properties.

Claims (9)

1. Laser surgical applicator having an optical fiber with a glass core, at its distal end a contact tip made of a glass sleeve is disposed, wherein the glass core is inserted in the glass sleeve and the distal end of the glass core is connected to the distal end of the glass sleeve to a point characterized that the glass sleeve ( 5 ) consists of a material that scatters the light. 2. Laser surgical applicator according to claim 1, characterized in that the glass sleeve ( 5 ) is optically transparent in the partial area in which it is connected to the distal end of the glass core ( 2 ). 3. Laser surgical applicator according to claim 1 or 2, characterized in that the glass sleeve ( 5 ) consists of sintered material. 4. Laser surgical applicator according to one of claims 1 to 3, characterized in that the glass sleeve ( 5 ) consisting of sintered material is fused in the distal connection area with the glass core ( 2 ). 5. Laser surgical applicator according to one of claims 1 to 4, characterized in that the proximal end of the glass sleeve ( 5 ) is connected to the protective jacket ( 4 ) of the light guide ( 1 ). 6. Laser surgical applicator according to claim 5, characterized in that the proximal end of the glass sleeve ( 5 ) is glued to the protective jacket ( 4 ) of the light guide ( 1 ). 7. A method for producing a laser surgical applicator with an optical fiber with a glass core, at the distal end of which a contact tip made of a glass sleeve is arranged, the glass core being inserted into the glass sleeve and the distal end of the glass core with the distal end of the glass sleeve to a tip is connected, characterized in that an opaque sintered glass is used as the material for the glass sleeve ( 5 ) and at. Connecting the distal end of the glass core ( 2 ) of the light guide ( 1 ) to the glass sleeve ( 5 ), the opaque sintered glass of the glass sleeve ( 5 ) in its distal region ( 6 ) assumes a transparent, homogeneous state. 8. The method according to claim 7, characterized in that the distal end ( 6 ) of the glass sleeve ( 5 ) is deformed into a specially shaped tip when fusing. 9. The method according to claim 7 or 8, characterized in that when melting the distal end ( 6 ) of the glass sleeve ( 5 ) is deformed into a lens with optical properties.