DE19916653A1 - Laser cyclo-photocoagulation for treatment of the cilary body in cases on intractable glaucoma uses opto-acoustic tissue differentiation so that tissue type is more accurately determined and an appropriate dose applied - Google Patents

Abstract

Pressure transients generated in the target tissue are used as measurement values to determine the optical qualities of the tissue in pre-operative preparation by the person carrying out the operation. The process can be automated by comparison of the measured values with calibration or characteristic curves.

Description

field of use

The invention relates to a device according to the preamble of the claim 1. It takes place in the medical field, especially ophthalmology at the laser surgical glaucoma therapy ("glaucoma") using trans-scleral laser Cyclophotocoagulation application.

State of the art

Laser light is used in many areas of medicine to tissue influence. This ranges from induction of photochemical processes to heating until evaporation or plasma formation. Find specifically in ophthalmology Treatment methods using laser have been used for a long time. In the established method of transcleral laser cyclophotocoagulation is used in tissue Area of the inner eye (ciliary body) deliberately destroyed to the intraocular pressure to lower [Beckmann et al. 72, Gloor et al. 94]. With this method it is Treatment area not visible. Manual tracking of the laser parameters by the surgeon due to the very fast running processes possible. Only one system (1) is currently in clinical use [Preussner 98], which is the automatic on-line adjustment of laser parameters (Laser pulse duration) to the course of the treatment. This method measures the laser energy reflected from the inside of the eye (retina) and assesses it temporal course as an input variable for the connected control loop.

Another method [Freese et al. 96, patent publication no. US 5533998] deals with the possibility of online monitoring for laser Cyclophotocoagulation using ultrasound biomicroscopy (2). Here, the Tissue condition at the same time as the laser tissue treatment with inserted and reflected ultrasound can be analyzed. The change in reflectivity during the Coagulation process should act as an input variable for the connected control loop serve for laser control.

The aim is to apply an optimal amount of energy to achieve one reliable coagulation result in the target tissue, especially without occurrence of tissue tearing of the inner epithelial layers ("popcorn effect").

A method for determining optical material properties in technology or characterization of biological tissue in medicine is the detection laser-induced pressure transients [Mandelis 94, Esenaliev et al. 98 patent Published no. US 5840023]. Here is a short laser pulse in the  Subablative area of energy deposited in the tissue, which leads to heating of the Volume leads. The consecutive volume expansion leads to the coupling of one acoustic signal of high spectral bandwidth into the surrounding medium. Becomes these pressure transients after their spread in the tissue by means of sensitive Pressure sensors (e.g. piezoelectric detectors, optical detectors on the Basis of changes in the refractive index), Back calculation from the height and shape of the amplitude of the tissue condition characterize. This requires knowledge of the acoustic properties of the Media for simulating sound propagation and light propagation in the tissue depending on the optical properties to be determined. Tissue differentiation is possible with this method, provided there are tissue types or states in their optical properties (absorption, scattering behavior) differentiate.

Disadvantages of the prior art

The method described as (1) above does not detect any direct changes in the Area of treated tissue (ciliary body). It only registers the Laser energy that is not absorbed in the irradiated tissue, but after it Transmission and several scattering and reflection processes the inside of the eye leaves through the pupil. The path of the transmitted laser radiation from Exit from the ciliary body until it is received in the detector is essentially from Condition of the clear media of the eye (vitreous, lens, anterior chamber, Cornea), as well as the reflective behavior of the surfaces, especially the retina, influenced. Because these optical properties are not correctly predetermined in vivo is the exact calculation of the state changes of the Target tissue not possible during the course of therapy. Also preoperative Condition determination (localization, optical properties) enables the method not because the required energies are not yet intended thermal Would cause damage.

The method described in (2) for feedback control of the Laser treatment uses the reflection of ultrasound and delivers therefore only information about acoustic properties of the tissue. The optical properties remain the basis of the laser-tissue interaction disregarded. A publication in the medical literature on the We are not aware of the use of such a possible control loop.

Object of the invention

The object of the invention is in the context of the above-mentioned form of treatment of glaucoma using laser cyclophotocoagulation to create a mechanism which is the application of the optimal amount of energy necessary for the success of the treatment is necessary, guaranteed and the adjustment of the laser parameters on-line to the Treatment course allows.

In particular, the preoperative measurement of the optical properties can better therapy planning and to localize the target region. A repeat treatment that might be necessary could already area to be spared.  

Solution of the task

The object is achieved by a device having the features of claim 1.

Advantages of the invention

The use of optoacoustic pressure transients as input variables for control the laser parameter during treatment offers the advantage that phenomena be considered directly from the optical properties of the Treatment region are dependent. Form exactly these optical properties also the basis for the laser tissue interaction that occurs during the Treatment for the desired warming of the target tissue ciliary body in the eye leads to destruction when temperatures above approx. 60 ° C are reached (by coagulation) of primarily healthy tissue. During the Coagulation process change due to the ongoing changes in the Tissue absorption and scattering properties and thus the Lichtver division ratios for the newly arriving therapy laser radiation. Because of these processes change the response of the treated tissue under the Laser application.

Our invention enables simultaneous detection of optoacoustic Pressure transients caused by the separate application of short diagnostic laser pulses Energies in the range of a few parts per thousand of the therapy energy dose, be induced. There is no additional heating of the Tissue, so that therapy and diagnostic procedures are separated in principle can be viewed. However, since it is about bringing in electromagnetic radiation in the same wavelength range is one Coupling of therapy and diagnostic laser radiation possible. First, it can same optical fiber as well as application handpiece for radiation transport or Coupling the laser light can be used, resulting in an identical spatial Propagation pattern of therapy and diagnostic radiation leads. this makes possible exactly the treatment of the measured area, or exactly the characterization of the irradiated tissue. Second, using the same wavelength both modes, a modulation of short diagnostic pulses to the Coagulation introduced longer laser pulses take place, which is the use of only one Laser source with appropriate control makes it possible.

Overall, this method offers the advantage of treatment patient-specific circumstances (e.g. degree of pigmentation, scleral thickness, Ciliary body condition) can be adjusted.

literature

[Beckmann et al. 72] Beckmann H, Kinoshita A, Rota A. et al. (1972) Transscleral ruby laser irradiationb of the ciliary body in the treatment of intractable glaucoma. TransAmer Ophthalmol Otol 76: 423
[Esenaliev et al. 98] Esenaliev RO, Jacques SL and Oraevsky AA (1998) Optoacoustic imaging for medical diagnosis. Patent publication number US 5840023
[Freese et al. 96] Freese M, Lasser T and Reimer P (1996) Apparatus and method for laser cyclo-photocoagulation. Patent publication number US 5533998
[Gloor et al. 94] Gloor H and Fankhauser F (1994) Glaucoma surgery in detail. Enke Verlag, Stuttgart
[Mandelis 94] Mandelis A (1994) Non-destructive evaluation (NDE). Prentice Hall
[Preussner 98] Preußner R. (1998) Controlled cyclophotocoagulation. Ophthalmologist 95: 645-650

Description of exemplary embodiments

Exemplary embodiments of the invention are described in more detail below and are also shown in the drawings (see extra sheets).

Fig. 1 system diagram for implementing a control circuit for controlling the laser parameters or diagnostic imaging in laser cyclophotocoagulation (glaucoma therapy)

Fig. 2 sectional drawing of a possible handpiece for laser application and detection of pressure transients

Laser radiation from one or two laser sources ( FIG. 1) is fed to an application handpiece ( FIG. 2) by means of an adapted optical fiber, which is specially configured for the application of therapy and diagnostic radiation, as well as for the detection of pressure transients that arise. In the contact procedure of the laser cyclophotocoagulation, the handpiece is placed directly on the conjunctiva of the eye with slight pressure a few millimeters peripheral to the corneo-scleral limbus.

Directly next to the flat fiber end (alternatively: focusing micro-optics) there are one or more measuring points for pressure detection ( Fig. 2), which, for. B. from the active surface of a specially manufactured piezoelectric pressure transducer (possible alternatives: PVDF (polyvinylidene fluoride) film, quartz, piezo oxides, lithium niobate LiNbO ₃ ). The voltage built up in the active volume is tapped via the electrodes vapor-deposited on the film and their contacting on the handpiece and fed to a processor.

Alternatively there is an optical method for pressure detection by measuring Refractive index changes due to pressure transients.

The fast processor is used to process the incoming voltage curves (Measured variables for calculating the optoacoustic pressure transients) according to a Control algorithm that controls the laser parameters to be adjusted (e.g. Pulse duration, power) on-line to the currently running course of treatment enables.

The laser light can be used to generate short diagnostic laser pulses a separate "diagnostic laser" of the same or different wavelength in the to couple common optical fiber.

Alternatively, when using identical frequencies with the therapy laser generates a diagnostic pulse and, for example, the relatively long "therapy pulse" (± 1 sec. Depending on the selected power) one or more short pulses lower Energy is sent ahead or modulated.

Claims (9)

1. Optoacoustic tissue differentiation for patient-specific dosing of the laser radiation in the transcleral laser cyclophotocoagulation of the eye, characterized in that the pressure transients generated in the target tissue of the treatment are used as a measurement of the optical properties in order to enable the surgeon to plan the treatment preoperatively through the visual output of the optical . 2. Device according to claim 1, characterized in that those generated in the target tissue of the treatment Pressure transients are used as a measure of the optical properties be to the further course of treatment by comparing it specifically determined characteristics with regard to the course of the changes in the optical Computer-assisted properties during therapy are fully automated on-line to control. 3. Device according to claim 1, characterized in that to generate short diagnostic pulses with lower Energy simultaneous to therapy laser radiation of identical wavelength one Pulse shape is generated, in which the temporal intensity profile of the basic Therapy laser pulses Diagnostic laser pulses modulated or in advance sent. 4. The device according to claim 1, characterized in that the detection of the optoacoustic Pressure transients using a piezoelectric pressure sensor is realized. 5. The device according to claim 1, characterized in that for the detection of the pressure transients at the Surface of the treated eye changes in refractive index in one transparent optical medium take place, which changes about the Total reflection behavior measured with respect to a detection laser beam can be (optical detector). 6. The device according to claim 1, characterized in that the detection of the acoustic signal via a Array of measuring points in different geometries that are parallel or serial can be controlled, is realized to a two-dimensional information about the treatment area, in the sense of a visualization analogous to the ultrasound Imaging. 7. The device according to claim 1, characterized in that a special application handpiece use finds which the application of the Laser radiation using optical fiber and the detection of laser-induced  optoacoustic pressure transients by means of piezoelectric or optical Detectors. 8. The device according to claim 1 and 6, characterized in that the handpiece described in an endoscope is integrated to be suitable even under inner surfaces after identification To be able to treat characteristic curves online. 9. The device according to claim 1, characterized in that it is the tissue to be treated other than the ocular tissue described above.