HU191836B - Device for stimulating biological processes - Google Patents

Abstract

The method and device is designed for biostimulation (for example wound-healing, acupuncture, rheumatologic and cosmetic purposes). The device includes a light source connected to a power supply, the light source consists of one or more light emitting diodes. The said light emitting diodes which have advantageously polarized light or are equipped with a polarizer are connected to a power supply which includes a modulator.

Description

FIELD OF THE INVENTION The present invention relates to an apparatus for the simulation of biological processes, in particular for wound healing, acupuncture and cosmetic purposes.

It is known that laser is used in clinical practice for the treatment of difficult to heal wounds. The light source is usually an iie-Ne laser or an Ar ion laser. During the treatment, the laser beam is guided to the wound by appropriate optical means and the entire wound surface is scanned by moving the beam. Many contradictory theories have been developed to explain the biological stimulating effect of laser light, but no scientifically accepted explanation has yet been found. Most of the published publications are about the results of the treatments and only a few attempts have been made to determine which specific properties of the laser light are associated with the biostimulatory effect. Based on the results reported, laser-light treatment would have a wide application range, but practical experience has shown that this treatment is not as widespread as its effects warrant.

The proliferation of laser treatment is hindered by the fact that continuous-mode lasers, which provide the correct beam diameter and performance, are expensive, have complex structures, operate at high voltages, and require high levels of expertise in handling. A further disadvantage is that there are technical limitations to increasing the beam cross-section to provide a power density of 2-10 mW / cm ^z commonly used in the treatment, and therefore wound scanning requires greater care when healing larger wounds.

There is considerable literature on the healing effects of laser treatment. It can be considered as a summary work eg. Mester Endre; .Del · Laser 'c. müve (Springer Verlag, 1981).

For the treatment of difficult-to-heal wounds, successful experiments were carried out with projection equipment which, in addition to the usual optical system, contained a polarizer and an infrared light-retaining filter (Bazsó, Crow, Szegő, Rose, Apai;. . These projectors, although cheaper than lasers, are large, generally require cooling, and operate at low efficiency.

A solution similar to the above is disclosed in U.S. Patent No. 2,105,195. U.S. Patent No. 4,123,125, which uses linearly polarized non-coherent light to stimulate biological processes. Infrared components are generally filtered out of the high spectral bandwidth light to reduce the heat load on the treated surface unless a reflection polarizer is used which is capable of polarizing the radiation components in the infrared range and therefore, these components need not be screened. Considering the weight and dimensions of a reflection polarizer with the proper polarization efficiency and the complicated optical radiation path, no significant weight and size reduction of the device can be expected.

It is an object of the present invention to provide an apparatus for stimulating biological processes which, while obviating the disadvantages of prior art devices, is capable of producing an equivalent biostimulatory effect which is simple in design, inexpensive, small, reliable, long-lasting and highly effective beyond medical applications. for cosmetic purposes or. can be widely used for home treatments.

SUMMARY OF THE INVENTION According to the present invention, there is provided an apparatus comprising a power supply, a light source emitting polarized light or a light source having a polarizer connected to the power supply, and preferably an optical means for influencing the beam path of light emitted from the light source. The light source operates in the infrared range, consisting of one or more light emitting diodes of low spectral bandwidth, preferably arranged in a matrix manner. The power supply includes a modulator for pulse-motion of the light emitting diode current.

The subject of the present invention will now be described in more detail with reference to embodiments and drawings. The drawing is a schematic diagram of an embodiment of the apparatus according to the invention

Figure 2 is a schematic diagram of another embodiment of the apparatus of the invention, a

Figure 3 is a detail of the modulator, a

Fig. 4 is a waveform corresponding to Fig. 3, a

Figure 5 is another embodiment of the modulator portion of Figure 3, a

Fig. 6 is a waveform corresponding to Fig. 5, and a

Figure 7 is a detail of an embodiment of the apparatus of the invention.

1, the matrix-like infrared light emitting diodes 2 of the light source are arranged in the holder 3. The light emitting diodes 2 are powered by the power supply 1. In front of the light emitting diodes 2, the polarizer 4, e.g. infrared film polarizers · - are placed. If the light emitting diodes 2 emit polarized light, the polarizer 4 is not required. The matrix-like arrangement of the light emitting diodes 2 is particularly advantageous when irradiating larger surfaces, since it allows the entire surface to be treated quickly without the need for a scan.

In the embodiment shown in Fig. 2, the polarizer 4 is a dividing prism preceded by a collecting lens. Depending on the characteristics of the light source and the purpose of the treatment, the device may have other optical paths influencing the beam path instead of or adjacent to the collecting lens 5

It may also contain a G device.

The unit can operate in continuous and modulated operation. Since the light source is a light emitting diode, the modulation of the light can be accomplished by modulating the diode current. In this case, the diodes emit a series of light pulses. Advantageously, two basic cases of modulation are distinguished, and circuitry examples with associated waveforms are provided in Figures 3, 4 and 5, 6, respectively.

A timing diagram of a modulating pulse sequence for a base case of modulation is shown in Figure 4. In this case, the impulse fill factor is approx. May vary from 10% to 90%, i.e. r

$ 0.1 - $ 0.9

T where Τ 'is the pulse time, and

T: period time.

The current of the light emitting diode 2 connected to the collector circuit of the transistor 7 and connected to the supply voltage + Ut through the resistor 6, and the light emitted by it, is varied according to the modulating signal. The peak current flowing through the light emitting diode may vary as a function of the fill factor, but does not substantially exceed the maximum continuous current that is allowed on the diode.

This variant can be advantageously used in acupuncture treatment, where the frequency of irradiation plays a role. Experience has shown that when acupuncture points are stimulated, ca. Frequencies between 100 and 1000 Hz show the highest sensitivity. The frequency of the modulating pulse sequence may be selected accordingly.

In the other basic case of modulation (Fig. 6), the charge factor of the modulation current is approx. Less than 1%, ie

T - $ io- ²

T

In this case, the peak current of the diode and the light emitted may be 50-100 times the nominal value. Such modulation can be accomplished by a switch according to its price 5, which differs from the circuit shown in Fig. 3 in that a capacitor 8 is connected between the light emitting diode 2 and the middle point of the resistor 6 and the earth point.

During the impulse break, the capacitor 8 is charged through the resistor 6. When the pulse opens transistor 7, capacitor 8 is discharged through light emitting diode 2 and transistor 7, so that the current is limited only by these two components. The peak current depends on the type of diode - e.g. The light output power can be 0.5 A and 0.5 Vi, respectively. 6 resistors R and capacitance C! Charging time constant defined by capacitor 8 and pulse time T is open during this time transistor 7 and period T are given by:

T '' RC << T

The specific values should be selected depending on the diode, e.g. T = 10 ms, T? = 100ps.

This version of modulation should be used in depth irradiation (eg rheumatism treatment), when the highest power output should be provided. The use of infrared light with a high penetration depth and modulation that allows for a peak power that is much higher than average power allows deep penetration without significant heat effects.

Figure 7 shows a preferred embodiment of the apparatus according to the invention, showing in detail the power supply 1 containing the modulator. An astable multivibrator constructed from ICi integrated circuits, Rio, Rn, Riz resistors and Ce, Cio capacitors provides the control signal of FIG. This coupling member, made up of an R13 resistor and a Cn capacitor, is placed on an emitter rocket consisting of a Tn transistor and a Ris resistor, which plays a phase reversal and matching role. Through a coupling element consisting of a resistor Rje and a capacitor C12, the signal is transmitted to a C class power setting consisting of transistors Tr2 and transistors 7, which modulates the current flowing through the light emitting diode 2. (See first for details.) By closing the Off switch, the base of transistor Tn is grounded via resistor R14. The transistor Tri will then open and open to control the Darlington switching transistors Tr2 and 7, so that the current of the light emitting diode 2 will be continuous, as determined by the resistor 6. The dashed-line second complex of light emitting diodes 2, resistors 6 and capacitors 8 illustrates the possibility of increasing the number of light emitting diodes 2 and thereby increasing the brightness.

The diode Di emits continuous light as a result of the current determined by the resistor R9. This makes it easier to target with a multi-infrared lamp.

The light emitting diodes work efficiently and require cooling only at high light output, which can usually be achieved by air cooling.

Its simple, secure construction, low cost, high reliability and long life allow the equipment to be widely used and thus, for example. it can also be used as a home appliance for home medicine or cosmetic treatment. Due to its small size and light construction, bone fractures heal-37

To speed up 1918.36, there is also a variant that can be incorporated into the plaster and used again after removal of the plaster. Designed in miniature form, it is suitable for insertion into body cavities, which until now has been very costly, using a combination of laser and fiber optics.

Claims (1)

Apparatus for stirring biological processes, in particular for wound healing, acupuncture and cosmetic purposes, which is capable of influencing a power supply, a light source having a polarized light connected to the power supply or a polarizer, and preferably a radiation beam emitted from a light source. Contains 5 optical devices, characterized in that the light source is formed by one or more light emitting diodes (2) operating in the infrared region and having a low spectral bandwidth, and the power supply (1) is connected to the current of the light emitting diode (2). includes a modulator suitable for pulse modulation.