DE19912992A1 - Laser irradiation method for medical or cosmetic purposes, or for use on animals, plants or cell culture; involves using laser diode, with pulse characteristics varied to alter effective illumination - Google Patents

Abstract

The method involves varying the pulse height, pulse length, repetition frequency of average pulse height of a pulsed laser or light diode (2), either manually or automatically, or as a function of another parameter, e.g. patient blood pressure, to produce a constant average power. Functions simulating continuous wave functions may also be used to drive the laser diode. The method can use a predetermined or adjustable parameter level, a time variation of one or more parameters or a variation of a parameter with respect to data or measured values.

Description

The invention (method for irradiation with light pulses with one or more predefined or specifically variable parameters (average power, peak power, Pulse duration, repetition frequency), for example for therapeutic or cosmetic Application) relates to processes for irradiation with visible or invisible light from Objects, but also of humans, animals, plants or cells (e.g. generated by LEDs or laser diodes). This radiation can be medical or cosmetic Serve purposes, but also z. B. Accelerate or control growth processes. At the People are e.g. B. selective applications (e.g. acupuncture) or local applications (flat, e.g. acceleration of healing of burns) in use.

Furthermore, the method can also be used in other technical areas, e.g. B. for image acquisition of one of several light sources using the method Illuminated area, the area from different locations with light pulses different repetition frequencies, but comparable average powers irradiated becomes. The method can be used for example with a lock-in Night vision device or correspondingly equipped computer an image of the viewed object under different lighting (and corresponding, for example different Shadow cast), and thus a spatial image from a computer getting produced. For example, in a factory building, e.g. B. 100 light sources with pulsating light of comparable average power, but significantly different Repetition frequencies (e.g. 50 Hz to 100 kHz) is illuminated, machines or moving Robots through methods of image recognition a three-dimensional image of their respective gain closer surroundings and thereby move without collision.

State of the art

The medical application of weak laser light (medium power roughly between 0.1 mW and 300 mW) was and is characterized by the available ones Laser diodes. Gas lasers no longer play a major role today. It started many years ago Use of pulse laser diodes which, in the case of very short times in which they emit laser light, can deliver very high powers of approx. 1 W to 200 W. The average power results from the pulse length (of approximately 200 ns = 0.0000002 s) and the repetition rate of the pulses of approximately 100 Hz to 10 kHz, for average power in the order of about 0.1 to 10 mW. On the one hand, by setting the repetition rate of the pulses, the average power changed. This method is used e.g. T. to achieve various medical effects  used.

On the other hand, the repetition rate of the laser pulse itself apparently affects that medical effects, d. H. to achieve a certain effect there is a repetition rate predefined (e.g. frequencies according to Nogier, Bahr, or Elias, between approximately 1 Hz and 20 kHz). With a fixed control of the laser diode (e.g. 10 W) and a fixed pulse duration (e.g. 150 nsec) the mean power is thus fixed (here 0.0015 mW at 1 Hz or 30 mW at 20 kHz repetition rate) and different depending on the repetition frequencies.

Targeted studies on the differences in the medical effects of Light pulses of the same average power, either with duty cycles close to 1, or below 0.01 and each corresponding services are given, and for which the Repetition frequency of the pulses is varied, are not quite without prior art considerable effort possible.

State of the art are also laser devices that work with "cw" laser diodes. This laser diodes to be operated continuously (cw = continuous wave) operated with amplitude modulation, usually with a square wave signal Duty cycle 0.5 is operated (i.e. at a frequency of 1 kHz 0.5 ms each Light emission and 0.5 ms pause). The average power is then half "Peak performance" regardless of frequency. For some devices, the middle one is also Power adjustable. However, frequency and pulse duration vary in a constant, reciprocal Relationship.

The therapeutic effect of laser light is presumably through absorption of the light in molecules in cells that lead to (possibly locally) slightly changed electro-chemical Conditions. These can influence the regulating mechanisms of the cell. For explanation of the observed effects of different repetition frequencies one of the Repetition frequency-dependent effect on the control mechanisms of the cell, or else the Organism. Then this could also be influenced by other parameters of light, about the pulse length in relation to the average power.

So far, it has not been possible for a user with conventional devices, the two characteristic factors of light irradiation with laser pulses (the repetition rate and the average power) to be varied individually and specifically. This is possible with the here given invention. This not only improves the handling of the Laser therapy enables, but z. B. by increasing the average power low frequencies shorten the therapy time. This gives z. B. Savings in Practice operation. This is essentially without increased electrical power and without use  enables new, more expensive laser diodes.

Presentation of the invention

Fig. 1 is a sketch of the allowed behavior pulse power of a laser diode as a function of the pulse duration (by the manufacturer). The dashed line is also considered in a simplified manner. The maximum permitted value of the pulse power P _{max is} inversely proportional to the root of the pulse duration t:

P _max = P _{max (t = 150 ns)} . (T / 150 ns) ^-1/2 (1)

Vary the parameters t and P for each repetition frequency f selected by the user as follows:

t proportional to f ^-2 and thus P proportional to f (2)

then the average power P _m that is

P _m = ftP proportional to ff ² .f = f ⁰ (3)

is given when choosing the parameters according to ( 2 ) regardless of f.

In contrast to this, according to the prior art, there would be an average power P _m with fixed t (typically 150 ns) and fixed P = P _{max (t = 150 ns)}

P _m = ftP = 150ns.P _{max (t = 150 ns)} proportional f (4)

given, varies in proportion to the repetition frequency f selected by the user.

Fig. 2 shows a block diagram of a possible technical implementation of a laser irradiation device according to claim 1. The patient is irradiated with laser light which is generated by a laser diode ( 1 ) and the beam geometry and course of which may be influenced by optics. The laser diode ( 1 ) emits short light pulses, the strength of which depends on the level of the applied voltage U. This voltage U is set by a voltage regulator ( 2 ) which controls the charging of a capacitance C. This voltage regulator is in turn controlled by control electronics ( 3 ) (such as a microcontroller). The current flow is controlled by a current switch ( 4 ) (z. B. MOS-FET), which releases the discharge of the capacitor C via the laser diode ( 1 ) for a period determined by the timer ( 5 ). The control of the timer (S) in terms of time and duration is also carried out by the control electronics ( 3 ). This can determine the pulse duration, pulse power and the time of each pulse. This definition will be made by the control electronics according to the specifications of the user who, for. B. specifies the repetition frequency of the pulses and the average power. The control electronics must take into account:

• The maximum permitted pulse power of the laser diode as a function of the pulse duration,
• - the dependence of the pulse power on the applied voltage,
• - required breaks between two pulses,
  everything z. B. also depends on
• - the temperature of the housing of the laser diode, if any,
• - The measured light intensity of the laser diode (also as a possibility for determination the temperature inside the laser diode),
• - If necessary, the measured or expected state of charge of the capacitor C or its Change during a pulse.

An alternative technical implementation of the method considered here is also included Laser diodes available today are possible, the high powers (e.g. 1 W) continuously (i.e. in "cw-" operation). These laser diodes can be operated modulated by they z. B. with the above frequencies on and off in such a way that the duty cycle one retains a fixed value (e.g. 0.01) and the pulse power is constant. This is how short times arise Laser activity that corresponds to the above laser pulses (e.g. 0.01 s at repetition rates of 1 Hz or 0.000005 s at 20 kHz). This gives you a variable repetition rate at fixed medium power. The latter can e.g. B. additionally varied by varying the duty cycle become. These laser diodes enable a relatively simple technical solution to this Invention presented method, however, are compared to pulse laser diodes disproportionately expensive and large. Less expensive and smaller laser diodes are smaller cw power available, which is higher to achieve comparable medium performance Duty cycle (e.g. = 0.5) required. This compares with the one presented here Procedure significantly increases the pulse duration. This can e.g. B. to changed photo-electrical Chemical reactions within a cell during the pulse duration result in a medically desired stimulation. When capturing images, would such a system with high duty cycles, compared to the one presented here Processes, overlaying and practically continuously overlaying many of the light "pulses" from different sources thereby complicating an evaluation.

In particular, the method presented here does not claim any significant additional financial or spatial expense compared to devices with pulse Laser diodes, at least considerably less than when using cw laser diodes Power that is in the order of magnitude of the pulse power of the pulse laser diodes.

Claims (11)

1.Procedures for selective or areal light irradiation (e.g. of humans, animals for medical or cosmetic purposes or for the purpose of the increased introduction of a substance through a skin area; of animals, plants, cells for process engineering or growth-promoting purposes) in pulse technology; characterized in that a variation of the pulse power and / or the pulse duration and / or the repetition frequency and / or the average power can be carried out by the user in a targeted or automatic manner, or one or more other parameters can be changed by changing a parameter in a fixed or adjustable manner can, so that with constant or adjustable repetition frequency a constant (or differently than with the repetition frequency) average power can be delivered. The method can include a predetermined or to be set variation of one or more of the parameters, a change over time of one or more of the parameters, or a change of one or more of the parameters on the basis of data or measured values (such as the patient's blood pressure values). Methods are not included in which essentially only one of the above parameters (for example the repetition frequency) can be varied, for example the variation or setting of the repetition frequency with the pulse power and duration remaining the same, which leads to an average power which varies with the repetition frequency, and methods, who use a "cw" -like operation of the light sources, for example if the pulse duration is comparable to the duration of the pause between the pulses. 2. The method according to claim 1, characterized in that using one or several pulse laser diodes or pulse light emitting diodes light pulses of approximately 10 ns to 20 ms duration are generated. 3. The method according to claim 2, characterized in that an adjustment to a Repetition frequency (or a combination of frequencies, e.g. 3 frequencies in time alternating) automatically a setting of pulse power and each frequency Pulse duration takes place, which are not both constant for all repetition frequencies. 4. The method according to claim 3, characterized in that the automatic setting of pulse power and pulse duration leads to an average power that is monotonous from the Repetition rate depends, but varies less than proportional to the repetition rate. 5. The method according to claim 3, characterized in that the automatic setting of pulse power and pulse duration leads to an average power that hardly differs from that Repetition frequency depends. 6. The method according to claim 1, characterized in that it z. B. for cancer therapy  could be used (photodynamic therapy). Compared to conventional ones A method could, by using methods according to claim 1, the effect of such Therapy can be increased or its side effects reduced if the Irradiation with pulsating light takes place, which is generated according to claim 1; e.g. B. by one or more (e.g., 100 high power laser diodes feeding into coupled fiber) and / or high pulse power. A targeted research in this direction is through the Invention only possible (e.g. double blind studies with different pulse parameters with same average power and thus z. B. also the same apparent brightness). 7. The method according to claim 1, characterized in that to achieve a medicinal effect in particular to avoid habituation effects Irradiation with light of constant average power, one with short light pulses varying repetition frequencies or varying time intervals between two pulses, however approximately constant average power is carried out. 8. The method according to claim 1, characterized in that the time intervals between two pulses are not constant, such that several without targeted user intervention Frequencies are used alternately, or the time intervals of the pulses in a fixed Depend on each other (e.g. exponential frequency response), or on a measured variable depend (e.g. pulse rate of the patient). 9. The method according to claim 1, characterized in that light sources different Illuminate or illuminate the wavelength of an object, and by detecting scattered, transmitted, or fluorescent or similar light properties of the loading or illuminated object can be measured. For example, B. in the screening of a human fingers with pulse light sources of different wavelengths and Repetition frequencies, and a (common) detector and evaluation with lock-in Technology the optical absorption of the object, in this example z. B. the Blood oxygen saturation and other parameters are measured. The procedure would be achieved by operating several pulse light sources with different pulse durations and / or repetition frequencies applied, each individual light source having a fixed one Parameter set could have. 10. The method according to claim 1, characterized in that an illumination of spatial areas or objects with light generated by the method according to claim 1 he follows. 11. The method according to claim 10, characterized in that by use different repetition frequencies and lighting from different directions and  targeted evaluation of the resulting images (using the eye, if necessary under With the help of appropriate devices such. B. more suitable, according to the lock-in principle working night vision devices; or by means of devices such as night vision devices or Video cameras whose images are evaluated by electronic or numerical methods a) three-dimensional reconstruction of the illuminated object or area, or parts thereof, in whole or in part.