RU2116089C1 - Method for treating biological objects - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves treating biological objects with modulated optic bandwidth radiation carrying 10^-6 W/10^-1 power density. Modulation is carried out by means of irregular analog oscillations which spectral components belonging to cm² Hz range. Transient process currents or voltages in electric circuits like flicker noise are applied as the irregular analog oscillations. EFFECT: improved biostimulating and therapeutic action; increased productivity of plants. 3 cl

Description

 The invention relates to human activity dealing with objects of wildlife, in particular, to medicine and agriculture.

 A known method of exposure to biological objects, including their irradiation with low-intensity continuous optical radiation [1]. The disadvantage of this method is the weak biostimulating effect, since outside the direct exposure to optical radiation are numerous bioresonance structures.

 There is a method of influencing biological objects with frequency-modulated laser radiation (by scanning the modulation frequency by 20-30% relative to the central one) [4]. Modulation of this type is called by the authors noise-like or quasi-noise-like. The disadvantage of this method is also a weak biostimulating effect.

There is a method of influencing biological objects by amplitude-modulated laser radiation, the modulation frequency of which is selected in the frequency range 10 ^-1 -10 ⁶ Hz [5]. This method has the same drawback as the two above.

Closest to the proposed one is a method of influencing biological objects, including their irradiation with pulsed optical radiation at an average power density of 10 ^-6 - 2 • 10 ^-1 W / cm ² incident on biological objects [2]. The disadvantage of the prototype method is a weak biostimulating effect, due to the fact that the discrete spectrum of the modulating signal, occupying a relative frequency band of up to two orders of magnitude, has an additional effect with respect to continuous optical radiation only on those biostructures whose resonant frequencies coincide or are close to the spectral components of the signal or multiple to them.

 The technical result, the achievement of which the proposed solution is aimed at, is to enhance the biostimulating effect (due to the acceleration and normalization of processes in biological objects).

This is achieved by the fact that in the known method of influencing biological objects, including their irradiation with modulated optical radiation at an average density of incident power of 10 ^-6 - 2 • 10 ^-1 , the modulation is carried out by irregular analog vibrations, the spectral components of which are in the frequency range 10 ^-4 - 10 ⁶ Hz. As irregular analog oscillations in special cases, use voltages or currents of transient, for example, exponential, processes in electrical circuits or amplified random processes in electrical circuits, for example, flicker noise.

The value of the lower cutoff frequency of the spectrum of the modulating signal - 10 ^-4 Hz - was chosen from the consideration that for most biological objects, in particular seeds, no stimulation time longer than 2.5-3.0 hours is required (the duration of the exposure determines the lower cutoff frequency spectrum). Longer exposure in most cases is difficult for technological reasons. The value of the upper frequency spectrum of the modulating signal — 10 ^-6 Hz — was chosen because the frequencies of conformational changes in the structure of proteins, including enzymes, reach 10 ⁶ Hz [3]. The spectral components of the modulating signal, which coincide with the frequencies of conformational vibrations of the enzymes, enhance the activity of the latter.

 The components of the modulation spectrum (bioobjects that are nonlinear systems) emitted (detected) in bioobjects affect the physicochemical processes occurring in them, changing, in particular, the effective reaction rate. They can lead to a restructuring of the kinetic regime, to the opening and / or closing of certain particular reaction pathways, and to qualitative changes in the products resulting from these reactions.

 Irregular analog vibrations are taken as modulating ones because they have a continuous amplitude-frequency spectrum and affect all biostructures whose resonant frequencies are in the spectral region of the modulated oscillations.

 An irregular analogue signal occurs in certain frequency ranges (frequency "windows"), the distribution of which on the frequency axis is individual in nature for each biostructure. The biostructure “chooses” the vibrational components it needs to activate. The lower the frequency of the “window”, the longer it takes to get the same result with the same amplitudes of the acting signals (spectrum components) or a larger signal amplitude with the same exposure times. This condition is largely satisfied by exponential oscillations and flicker noise, the amplitudes of the spectral components of which increase with decreasing frequency.

 Devices that implement the proposed method can be performed on the basis of lasers or LEDs in the visible and / or infrared ranges. As a generator of irregular oscillations used to modulate the radiation intensity, linearly increasing, sinusoidally increasing or exponentially increasing voltage generators, flicker noise generator and other devices can be used. As a source of flicker noise, zener diodes of the glow and corona discharges and semiconductor zener diodes (when operating the latter on the initial part of the reverse branch of the current-voltage characteristic) can be used.

 The use of the proposed method for phototherapy and to accelerate the growth and development of plants does not differ from the use of analogue methods.

 A device was manufactured for implementing the proposed method based on emitting semiconductor diodes; three red and one infrared ranges. Radiation at ultra-low frequencies was modulated due to the flicker noise of the AC network (an unstabilized constant voltage source was used to power the device), at low and high frequencies due to the amplified flicker noise of the semiconductor zener diode.

Using the device, in July-August 1996 the seeds of cucumbers of the 1993 crop were irradiated for one hour at an average power flux density of about 5 • 10 ^-4 W / cm ² . Tests showed a statistically significant increase in seed germination by 20-30% in relation to seed irradiation with a device with pulsed modulation of optical radiation (to the prototype method). Currently, the device has been transferred to the Siberian State Medical University to determine the best therapeutic methods for irradiating human tissues.

 The technical effect of the proposed method compared to the prototype method is to enhance the therapeutic effect when it is used in medicine and to increase the productivity of plants when it is used in crop production.

 References.

 1. Kozlov V.I., Builin V.A. Laser therapy using ALT "Mustang". M .: Aspect Press, 1995, p. 27.

 2. Ibid., P. 28 (prototype).

 3. In the same place, with. thirteen.

 4. Antonov S. N. Problems of low-intensity laser therapy and new trends in the development of equipment, Laser Market, 1994, N3, p. 17.

 5. Laser therapeutic apparatuses of the Luch series (information message about a new technique and its application), Laser Market, 1994, N1, p.9.

Claims (3)

1. The method of exposure to biological objects, including irradiation of biological objects with modulated optical radiation at an average density of the incident power of 1 • 10 ^-6 - 2 • 10 ^-1 W / cm ² , characterized in that the modulation is carried out by irregular analog vibrations, spectral components which are in the frequency range 10 ^-4 - 10 ⁶ Hz.  2. The method according to claim 1, characterized in that the voltage or currents of transient, for example exponential, processes in electrical circuits are used as irregular analog oscillations.  3. The method according to claim 1, characterized in that as the irregular analog vibrations use enhanced random processes in electrical circuits, for example flicker noise.