DE4108146A1 - DEVICE FOR REMOVING MATERIAL WITH LASER LIGHT - Google Patents

Abstract

A device for paring material, in particular biological tissues, has a laser system that generates laser pulses and a fiber-optic light guide system with fiber-optic light guides (1) gathered into a bundle (2) to which the laser pulses (6) are coupled and that guide the laser pulses (6) to the spot where material is to be pared. The bundle (2) is subdivided into at least two groups of fiber-optic light guides (1) and each laser pulse (6) is not coupled to at least one group of fiber-optic light guides (1).

Description

The invention relates to a device for Removal of material and especially biological Tissue, with a laser system that generates laser pulses, the optical fibers combined in a bundle can be coupled, the laser pulse in place direct where material is to be removed.

For example, laser systems are used in laser surgery me used because of their high light output Vaporize tissue in such a short time that practical  no heat load for the non-irradiated, healthy Tissue occurs. For such laser-induced processes A wide variety of laser systems, including for some time so-called excimer lasers, which Emit light in the UV range.

The removal processes described above will also called photoablation mechanisms and fin especially in microsurgery (angioplasty, Oph thalmology, orthopedics etc.) application to possible on very gentle way to remove tissue.

They are usually used in microsurgical operations so-called surgical handpieces, for example catheters used in which the laser light in so-called Optical fibers are routed to the point where Material, d. H. for example, tissue can be removed should. The ability of optical fibers to laser light transport, however, is limited because from a spec fish power density the fibers by the laser light be destroyed.

Because - for example, to get a flexible catheter ten - thin fibers must be used, which form bundles are summarized, have the surgical hand usually cut a lot of fibers so that laser pulses high energy can be transported so that poss can be operated as quickly and efficiently as possible.

Especially in the field of angioplasty, i.e. H. the vessel surgery, however, the following problem arises: everyone Laser pulse only detects and removes a limited amount of tissue depth. This tissue-specific depth, which is roughly the Penetration depth of the laser light is only  a few µm. So far, efforts have been made to as high a surface density of energy or power as possible To reach fiber output. The operation speed speed does not only depend on the energy per laser pulse, but also from the repetition rate (repetitions rate) of the laser pulses. This is known in front directions for removing material and in particular of biological tissue with a laser system Values of less than approx. 25 Hz limited, as at high The pulse rates are too high for the tissue becomes.

To achieve high operating speeds is you've been striving in the past so much Energy as possible per laser pulse through the fiber bundle to lead. For example, in angioplasty Excimer lasers worked at the fiber bundle exit (depending on the fiber bundle diameter) total energies between between 30 and 80 mJ. The individual fibers in the Bundles become the same and as similar as possible moderately exposed to the laser beam. With laser system men with other wavelengths, such as Neo dym-YAG lasers, holmium or dylaser, however, must who uses much higher laser pulse energies to achieve an ablation effect.

Because of the rapid evaporation of the tissue - the Evaporation processes typically take place in the microscope customer area - a shock wave forms penetrates into the surrounding tissue. Which occurs in the process high pressure gradients can lead to considerable Disruptions and damage in the environment. Damage to the tissue and cell layers, the rela tiv far from the ablated area  is therefore inevitable. Traumatic ver Changes that lead to considerable tissue irritation can. As a result, the growth of Cell layers observed, causing restenosis (How constriction).

The laser, originally as the atraumatic tool praised, proves to be quite in the µm range harmful. The reason for this should be - how fiction has been recognized - not the ablation process by se, but the one with the ablation process conventional shock wave associated laser systems.

The invention has for its object a Vorrich device for removing material and in particular to indicate biological tissue with a laser system, in which the removal process is carried out gently, so that he has no or only a negligibly small one harmful effect on the healthy tissue environment sits.

An inventive solution to this problem is in Claim 1 specified. Developments of the invention are the subject of the subclaims.

The invention is based on the basic idea that it to solve this task, the ore is necessary avoid shock waves during ablation.

Surprisingly, this basic idea can be realized that continue from a device for the removal of material and especially biological chemical tissue with a laser system, the laser pulse generated in a bundle of light  Conducting fibers can be coupled, which the laser pulse to the Manage the point at which material is to be removed, is assumed.

According to the invention, such a device is thereby further developed that the bundle in at least two groups pen is divided by optical fibers, and that everyone Laser pulse in at least one group of optical fibers is not coupled.

In other words, the light is coupled in the optical fiber bundle so temporally and spatially separately that the individual optical fibers or group pen separated in time and in serial spatial order follow at least one laser pulse each time are irradiable.

The invention is based on the idea that the formation of the shock wave is a direct result of the high energy per laser pulse, which is applied to the tissue over the entire cross-sectional area of the catheter. If only a single fiber from the laser fiber bundle is irradiated with the laser light, significantly less energy is released at the catheter outlet; consequently, the shock wave is significantly reduced. The same also applies to the amount of tissue that is ablated. In order to compensate for this effect, the fibers of the bundle are sequentially irradiated with laser light with the device according to the invention, ie each fiber is acted upon individually in a time sequence with light. The time interval between two laser pulses must be chosen so that the shock wave of the first laser pulse has already been thinned so far that an overlay with the pressure wave emitted by the adjacent fiber can be excluded. Since pressure waves typically travel at a few 1000 m / sec. spread out and the tissue depth within which damage is to be avoided is a maximum of 1 mm, a minimum time between two pulses of approx. 10 ^-6 seconds is calculated. On the other hand, if the individual fibers with a frequency of less than 10 ⁶ Hz supplied with light, the pressure waves that form will not be able to overlap. Every single pressure wave will be much smaller, since it is only generated by the energy of a single fiber.

The idea of the invention is therefore that individual fibers of the bundle sequentially with laser pulse, in the area of angioplasty each fiber no more than 25 laser pulses per second should receive. This way, the same effect achieved as if all fibers had 25 lasers simultaneously received pulse per second. The frequency of the laser pulses must be increased accordingly, the energy of the individual laser pulse is down accordingly puts.

The above consideration is said to follow Numerical example will be clarified:

Approx. 50 optical fibers are arranged in a typical angioplasty catheter. With a single fiber frequency of 25 Hz, the laser would have to be operated at a repetition rate of 1250 Hz. At the same time, the individual pulses must be mapped onto each individual fiber. The laser beam must be scanned over the fiber bundle, so to speak. The laser pulse frequency is of the order of magnitude below the limit frequency of 10 ⁶ Hz estimated above. The device according to the invention can be implemented in practice, for example, by arranging a scanning device on the light entry-side (proximal) end of the optical fibers, which deflects the laser pulses in such a way that that the laser pulses "scans" the light entry surfaces of the individual fibers.

Because the operating data, for example, of excimer lasers this form of operation is possible gentle treatment with known laser systems possible.

The invention is hereinafter without limitation general inventive concept based on execution examples with reference to the drawing exempla risch described on the rest of the Revelation of all not explained in the text explicitly referenced details becomes. It shows

Fig. 1 is a simplified diagram for explaining the operation for tissue ablation with a conventional multi-fiber bundle,

Fig. 2 shows a conventional arrangement for simultaneous Laserstrahleinkopplung in a multi-fiber bundle,

Fig. 3 is a simplified representation for explaining the function of a device according to the invention with mirror deflection and

Fig. 4 shows a cross section through a device according to the invention with a rotating prismatic lens.

The device for removing tissue 4 shown in FIG. 1 has a catheter 2 , inside which a multiplicity of optical fibers 1 are guided. In the previously used photoablation techniques, the individual fibers in the bundle are simultaneously exposed to the laser beam. Due to the light energy exiting per laser pulse at the output of the fiber, the tissue layers immediately adjacent to the catheter head are subjected to such a high thermal load that the tissue evaporates. Because of the explosive expansion of tissue material 3 , the abla tated material in front of the catheter head is pushed to the side on the one hand, and on the other hand, a shock wave 5 spreads into the surrounding tissue area, which leads to said tissue and cell damage.

In Fig. 2 the previously used in laser surgery light coupling is shown in so-called multi-fiber bundles. Here, the laser beam 6 coming from the laser system passes through an optical imaging lens 7 , which adjusts the light beam in size and shape to the geometrical conditions of the coupling surface of a multifunctional bundle 8 . All individual optical fibers that are guided within the multi-fiber bundle are irradiated simultaneously and as evenly as possible with laser light.

A device for sequentially coupling light into individual optical fibers contained in a multifiber bundle is shown in FIG. 3. The laser beam 9 is spatially imaged by an imaging lens 10 and by means of a mirror rotatably mounted about the axis of rotation D onto individual optical fibers or groups. In order to make the mirror guidance as simple as possible, the individual optical fibers, which come together to form a multi-fiber bundle 12 , are arranged linearly. Any deviating, regular spatial arrangement of optical fibers is also conceivable (e.g. triangle, rectangle, etc.). By clockwise rotation of the mirror 11 about the axis of rotation D who in succession in accordance with the repetition rate of the pulse laser thus illuminated all optical fibers or groups.

The clock frequency of the mirror adjustment must, however not necessarily with the repetition rate of the Laser system match, d. i.e., per beam image more than one can be on an optical fiber or group Light pulse are transmitted.

Another device according to the invention is shown in FIG. 4. The laser beam 13 also passes through an optical imaging lens 14 and then passes a specially in the edge region of a rotating disc 16 rotating around the axis R prism 15 , which focuses the beam 13 on a fiber optic fiber or group 17 . The radial attachment of a plurality of prisms (in the cross-sectional view only two are shown - 15 , 15 ') is provided in the edge region of the disc 17 such that the laser beam the prisms ( 15 , 15 ',...) In time one behind the other penetrates, with the beam image capturing each optical fiber or group in succession during the rotation of the disk 16 . The Rotationsgeschwin speed of the disc then indicates the average pulse rate of the arrangement.

The methods of sequential scanning can also only parts of the cross section of the catheter are used to activate. Optical fibers are targeted here exempt from radiation, which is technically in the shown devices is easy to implement. This is of particular interest if one Appropriate detection method is used, which he leaves the tissue in front of the catheter to know.

Another advantage of this beam deflection method Added to this is the fact that every single fiber with the same energy can be applied. This is at a simultaneous illumination of the bundle only very much difficult because every laser beam more or less has pronounced inhomogeneities. The entire mitt performance that is thus transported through a fiber can be increased significantly in this way be, so that there is a significant increase in Cutting speed results.

Claims (8)

1. Device for removing material ( 4 ) and in particular of biological tissue, with a laser system that generates laser pulses that can be coupled into a bundle of optical fibers ( 1 ) that guide the laser pulse to the place on the material to be removed, characterized in that the bundle is divided into at least two groups of optical fibers and that each laser pulse is not coupled into at least one group of optical fibers. 2. Device according to claim 1, characterized in that the individual groups of Apply optical fibers successively with laser pulses be hit. 3. Device according to claim 1 or 2, characterized in that the maximum repetition rate te per optical fiber or group is 25 Hz. 4. Device according to one of claims 1 to 3, characterized in that the optical fibers rule moderate, preferably linear, within the light guide fiber bundle are arranged. 5. Device according to one of claims 1 to 4, characterized in that the light coupling into each individual optical fiber or group can be carried out via a mirror ( 11 ). 6. Device according to one of claims 1 to 5, characterized in that the light coupling into each individual optical fiber or group by a, on a rotating disc ( 16 ) attached prism arrangement ( 15 , 15 ',...) Can be performed. 7. Device according to one of claims 1 to 6, characterized in that the energy of each laser pulses is such that the depth of its effect in the Tissue approximately corresponds to the spot diameter. 8. Device according to one of claims 1 to 7, characterized in that the laser system a Has excimer laser.