DE3936716C2 - Device for influencing material by pulsed light irradiation and use therefor - Google Patents

Description

The invention relates to a device for Influencing and in particular structurally differentiated change in material properties, with a light source and a switching device that the light beam generated by the light source in time or spatially controls.

Such devices are intended according to the invention Influencing material, especially for thermal change, d. H. Coagulation, of  biological tissue can be used, creating a spatial limitation or spatial selectivity of the Influences on the direct absorption structures and their immediate surroundings through the action of re petiting pulsed light on the one to be influenced Material area can be reached so as not to cover the whole Change material evenly, just that Spaces around the absorption structures.

The device according to the invention is used in particular Influencing tissue structures at the back of the eye, for the treatment of functional disorders in the area of the fundus, for selective sclerotherapy of small blood vessels, e.g. B. in the skin, for spatial limited change of naturally occurring in the tissue existing or pathological or artificial stored absorbent substances.

Currently influencing Material properties primarily as light sources Laser emitter used. The emission times (pulse lengths) the laser emitters are between femtoseconds and continuous radiation and thereby cover the entire technologically possible range. Together However, all of these previous methods is that the choice of pulse length and corresponding to it the pulse energy to achieve different types Material changes (material effects) such. B. thermal effects, mechanical effects or phototechnical effects to be influenced Material area is used, however, afterwards not followed the path of the invention by a Variety of individual pulses, e.g. B. a repetitive  Pulse operation with certain, on the spatial and spectral properties of the absorption structures coordinated pulse times, pulse repetition frequencies and Pulse energies a change in material in the direct Absorption structures and their immediate surroundings to effect spatially limited. Although z. B. for Coagulation, d. H. for the thermal change of Material as well as from biological tissue continuous intensive light irradiation as well so-called quasi-continuous light radiation ver turns. Like the name "quasi-continuous radiation" says, but is always intended to be the case of simulate continuous radiation, d. H. Light sources that are either technically simpler or about work only in pulsed mode, such as B. pulse laser to use to create material changes, which is also generated with continuous light sources can be.

From DE 33 00 041 A1 it is known that Material changes on light-absorbing Structures from repeated radiation with light pulses through a temporal Switching device of a light source is generated, are caused. In the presented device is a pulsed laser, by means of which fine structures on IC′S, such as etching residues, spatially can be removed to a limited extent without the underlying structure is damaged. In this However, publication is only Material removal reveals and not the change the material properties.

From the applied mathematics and Physics 16 (1965), p.  138 is used in connection with material removal Lasers performed that the length of the pulses one Influences the spread of heat. At this However, publication will only be a laser pulse based on.

The characterization of repetitive radiation is However, it cannot be derived from the prior art. Furthermore, it is not known on spatial and spectral properties of the absorption structures coordinated pulse times, pulse repetition frequencies and To use pulse energies and a material change in the direct absorption structures and their immediate to bring about a spatially limited environment.

The invention has for its object a direction to influence material properties create and through special, based on the material stored absorption structures coordinated choice of irradiation time, repetition frequency and on cell radiation energy, certain light-induced Material changes on absorption structures and to limit their immediate surroundings.

This object is achieved with the content of Technically solved claims.

The invention is based on the knowledge that the space of course existing or limited Artificially introduced absorption structures in the Material to a also spatially limited Perform energy deposition, this energy Energy propagation mechanisms, such as B. heat conduction, Heat convection, propagation of acoustic waves,  is spatially expanded and thus the light induced material effects spatially equalized will. After the energy flow due to this off spreading mechanisms can depend on time Shortening the irradiation time the spatial extent material changes can be reduced. However, the option is through a pulse pulse irradiation with shortened irradiation time to achieve sufficient material changes, be borders. Because the necessary with shortening the pulses Increasing the peak power can become undesirable Side effects such as B. local evaporation or Cause tears in the material.

The core idea of the invention is therefore that repetitive pulsed radiation the deposited lei Power and energy densities in and near the direct Absorption structures are extremely different and reinforced by the non-linear relationship between the physical effect, e.g. B. temperature increase on the one hand and the change in material, e.g. B. the thermal coagulation effect, on the other hand, the repetitive pulsed radiation for a better spatial limitation of the desired material effects leads without risk of undesirable side effects, such as it is to be feared with single irradiation.

According to the invention, the leg device is therefore flow and especially for structural differentiated change in material properties, with a light source and a switching device that the light beam generated by the light source in time or controls spatially, in such a way that the switching device to increase the spatial  Selectivity of influencing a repetitive loading radiation of a material generated so that only the irradiated, light-absorbing structures of the influencing material influenced spatially limited be, the pulse time, pulse energy, pulse frequency and the number of repetitive radiation pulses on the spatial and spectral properties of the Materials are matched.

The invention is described below using an exemplary embodiment from with reference to FIGS. 1 to 3. Show it:

Fig. 1 is a block diagram of a device according to the invention,

Fig. 2, the temperature increases directly adjacent within an absorbent structure and 1 microns removed from the absorbent structure, during and after a (continuous) light irradiation with an exposure time of 20 ms,

FIG. 3 shows the temperature increases as in FIG. 2, but with short repeating light pulses, the average power being the same as in FIG. 2.

Fig. 1 shows a block diagram of an inventive device, which is suitable for example for the coagulation of biological material with high spatial selectivity. The device has a light source ( 1 ), which is used either as a continuous radiation source by a subsequent switching device ( 3 ) or primarily by a pulsed control ( 5 ) (in the case of a laser as a beam source, e.g. by means of so-called pulsed pumping ( 4 )) directs short light irradiations with a certain pulse repetition frequency to the material area to be influenced. The switching device generates an irradiation sequence either by temporal or spatial modulation, the individual duration and frequency of which is matched to the spectral and spatial absorption structure in such a way that the material coagulation generated by pulsed light exposure remains limited to the absorption structure and its immediately adjacent areas, i.e. not the entire area irradiated material area is changed homogeneously, but only the absorption structures and their adjacent spatial areas.

According to the invention it has now been recognized that the radiation parameters, radiation duration, repetition frequency and number of irradiations together with the radiation energy determine the strength and the spatial extent of the material coagulation that arises around the absorption structures. To demonstrate this relationship, the temperature profiles after a 20 ms long continuous irradiation are compared to those of a short-pulse repetitive irradiation of the same central line in Fig. 2 and Fig. 3, so the different spatial expansions of the material effects from the different temperature profiles in the Absorption structure (I) and somewhat distant from it (II). While in the "continuous case" ( Fig. 2), the temperature curves and thus the thermal effects within the absorption structure (curve I) and defined away from it (curve II) differ only slightly from one another, are in the case of repetitive pulsed light radiation ( Fig. 3), although the mean values of the light-induced temperature increases at the two locations I and II are identical to the case of continuous radiation, the temperature peaks and thus the essential contributions to the thermal material change are, however, directly in the absorption structure (I) and directly next to it (II) substantially different. This means that in the case of repetitively pulsed light irradiation with a suitable pulse duration, pulse repetition frequency and pulse energy for the spatial profile and the spectral properties of the absorption structure of the material, the light-induced material changes remain much more limited to the spatial absorption structure and its immediate surroundings than this continuous radiation is the case.

The Vorrich described in the individual claims is the common basic idea of the increase spatial selectivity by using suitable ones repetitively short light irradiation.

Claims (11)

1. Device for influencing and in particular for structurally differentiated change in material properties, with

• - a light source and
• a switching device that controls the light beam generated by the light source in terms of time or space,

characterized in that the switching device for increasing the spatial selectivity of the influencing generates repetitive irradiation of a material in such a way that only the irradiated, light-absorbing structures of the material to be influenced are influenced in a spatially limited manner, the pulse time, pulse energy, pulse frequency and the number of pulses the repeating radiation are matched to the spatial and spectral properties of the material. 2. Device according to claim 1, characterized in that the repetitive loading radiation not by a switching device unmoving on the material area to be influenced directed light beam is realized, but by a switching device that over the light beam spatially moving material area in such a way that the desired right at every point in space petitioned radiation is generated. 3. Use of the device according to claim 1 or 2, for influencing biological material. 4. Apparatus according to claim 1 or 2, characterized in that the light source ( 1 ) is a laser, the beam either by an external switching device ( 3 ) or by a switching device in the laser resonator ( 4 ) or by a switching device in the pump device ( 5 ) of the laser is controlled. 5. Device according to one of claims 1, 2 or 4, characterized in that the pulse time, pulse energy, Pulse rate and the number of repetitive pulses Irradiation in this way on the spatial and spectral Properties of the material are matched that the Material, especially tissue changes pure are of a thermal nature, in such a way that lich induced temperature changes only in the absorber structures and their immediate surroundings succeeded. 6. Device according to one of claims 1, 2 or 4 characterized in that the pulse time, pulse energy, Pulse rate and the number of repetitive pulses Irradiation in this way on the spatial and spectral Properties of the material are matched that the Material, especially tissue changes pure are mechanical in nature in such a way that light induced acoustomechanical effects only on the absor structures and their immediate surroundings stay restricted. 7. Device according to one of claims 1, 2 or 4 characterized in that the pulse time, pulse energy, Pulse rate and the number of repetitive pulses Irradiation in this way on the spatial and spectral Properties of the material are matched that the Material, especially tissue changes pure  are photochemical in nature in such a way that lich induced chemical reactions on the absorbent Structures and their immediate surroundings are limited stay. 8. Device according to one of claims 1, 2 or 4 to 7, characterized in that the light beam is not direct is directed to the material to be influenced, but via an optical transmission system, in particular light guide fibers on the material area to be influenced is aimed. 9. Device according to one of claims 1, 2, or 4 to 7, characterized in that the light beam is not direct, but focused, defocused via optical systems or mapped to the material area to be influenced is directed. 10. Use of the device according to one of the claims 1, 2, or 4 to 9, for the irradiation of Absorption structures that are artificially incorporated into the be trading material, especially biological tissue are introduced.