RU2155335C1 - Method determining impact of harmful effects on biological objects - Google Patents

Abstract

FIELD: biology, ecology, biological monitoring of degree of impact of harmful effects on biological objects. SUBSTANCE: invention consists in measurement of frequency of vibrations of biological object and in evaluation of degree of impact of harmful effects by it comparison with calibration curve. After measurement of frequency of vibrations of biological object it is subjected in addition to action of alternating electric voltage in range of frequencies close to frequency of vibrations of biological object. Value of additional action is raised by frequency of additional action till effect of synchronization of frequency of vibrations of biological object takes place. Dependence of amplitude of alternating electric action on value of sought-for ( known ) harmful effect is used in the capacity of calibration curve. EFFECT: increased accuracy and authenticity of evaluation of degree of impact of harmful effect on biological objects are achieved thanks to controlled action on biological object and to measurement of parameter changing in wider range. 3 dwg

Description

 The invention relates to the field of biology and ecology, can be used for biological control of the degree of influence of harmful effects on biological objects.

 There is a method of determining the effect of harmful effects on biological objects and assessing the toxicity of wastewater by recording electrocardiograms in fish and measuring RR-intervals (see AS N 1573376, MKI G 01 N 33/18).

 The disadvantage of this method is the duration of the analysis.

 A known method of biological assessment of water toxicity by changing the physical activity of Daphnia in the reference (non-toxic) and control (toxic) environments (see AS USSR N1413525, class G 01 M 33/18). However, this method does not provide reliable data on the degree of toxicity of the aquatic environment due to the ambiguity of the behavior of daphnia depending on the type of substances and their concentration, since their motor activity can both increase or decrease.

 A known method for determining the effect of harmful effects on biological objects and assessing toxicity of wastewater, based on a change in light flux due to contraction of the pectoral legs or heart in daphnia, which cause a change in the electrical characteristics of the photosensor (see Kolupaev B.I., Andreev A.A., Samoilenko YK Optical method of recording heart rhythm in daphnia. - Hydrobiological Journal, vol. XIII, issue 3, 1977, pp. 119-120).

 However, this method is not accurate enough.

 The closest in technical essence to the proposed one is the biotesting method, which includes the measurement of respiration and cardiac activity in daphnia under the influence of toxic substances and the assessment of the degree of influence of harmful effects by comparison with the calibration curve. A luminous flux is passed through the body of daphnia, which changes as a result of the contraction of the heart or the movement of the pectoral legs. The respiratory rate and heart rate are recorded. A decrease or increase in the luminous flux causes a change in the current strength at the photodetector, a change in the electrical characteristics of the photodetector is amplified and recorded on the electrocardiograph. A significant deviation (P <0.05) of the respiratory rhythm or heartbeat from the control (see Kolupaev B.I. Biotesting methods for changes in respiration and cardiac activity in Daphnia. - Methods of water biotesting, pp. 103-104) is taken as a toxicity indicator.

 However, this method is not sufficiently reliable.

 The objective of the invention is to improve the accuracy and reliability due to the adjustable effects on the biological object and measuring the parameter, changing over a wider range.

 The problem is achieved in that in a method for determining the influence of harmful effects on biological objects, including measuring the vibration frequency of a biological object and assessing the degree of influence of harmful effects by comparison with a calibration curve, after measuring the vibration frequency of a biological object, it is additionally exposed to alternating electric voltage in a frequency range close to the vibration frequency of the biological object, increase the amplitude of the additional action until the effect of synchronization of the vibration frequency of the biological object and the frequency of the additional exposure, while the dependence of the amplitude of the alternating electrical exposure on the magnitude of the desired (known) harmful effect is used as a calibration curve.

 The originality of the proposed solution lies in the use of the synchronization effect to change the frequency of the heartbeat of a biological object.

 Compared with the known, the proposed method allows to increase the reliability of measurements for a wider range of types of harmful effects without resorting to a significant increase in the number of lengthy biological tests. A similar set of actions entailing the ability to control the effects of harmful effects is not known.

 The proposed method is illustrated by drawings.

In FIG. 1 is a diagram of an experimental setup, where 1 is a night vision device, 2 is a power source, 3 is a bio-object, 4 is a channel for a bio-object, 5 is a transparent table, 6 is a lens, 7 is a semiconductor laser, 8 is a current source, 9 is a photo detector , 10 - amplifier, 11 - analog-to-digital converter, 12 - computer, 13 - glass, 14 - electrodes;
in FIG. 2 - dependence of the minimum value of the amplitude of the alternating voltage U applied to the bioobject, at which the effect of synchronizing the heartbeat frequency of the bioobject with the frequency of the additional exposure occurred on the concentration of the harmful effect (phenol) N in the aquatic environment (the frequency of the additional exposure is 9 Hz);
in FIG. 3 - the dependence of the minimum value of the amplitude of the alternating voltage U applied to the bioobject, at which the effect of synchronizing the heartbeat frequency of the bioobject with the frequency of the additional impact occurred on the heart rate of daphnia previously subjected to any harmful effect (the frequency of the additional exposure is 9 Hz).

 The method is as follows.

 Bioobject 3 (Fig. 1) is placed in an aqueous medium and immobilized by placing it on a transparent plate 5 in a chamber 4. In the glass 13, the aquatic habitat of the bioobject is poured into which electrodes 14 connected to a source of an external electric field are lowered. The vibration frequency of the biological object (heartbeat, respiration, etc.) is estimated either by visually counting the number of periods of movement of the controlled area per unit time, or by electronically counting the periodic changes in optical radiation. To do this, direct optical radiation from the source 7 to the heart region of the biological object 3. The radiation source 7 is supplied from the power source 8. Using the lens 6, precise focusing of the radiation is achieved. Summarize the direct and reflected radiation from the controlled area and act on the radiation source 7. A periodic change in the radiation intensity of the source is recorded by a photodetector 9, the detected signal from which is fed to a computer 12 through an amplifier 10 and an analog-to-digital converter 11. An alternating voltage is additionally applied to the biological object U in the frequency range close to the heart rate of the bioobject. The magnitude of the additional exposure U is increased until the synchronization effect of the heartbeat frequency of the biological object occurs with the frequency of the additional exposure. Moreover, as a calibration curve, the dependence of the magnitude of the current or voltage of an alternating field applied to the bioobject on the magnitude of the desired (known) harmful effect is used (Fig. 2).

 An example of a practical implementation of the method.

 As a biological object, freshwater Daphnia crustaceans (Daphnia magna Straus) cultivated under standard laboratory conditions were used. In the experiments, individuals 0.7–1.5 mm in size were used.

 An aqueous phenol solution with concentrations from 0.5 to 10 mg / L was used as a harmful effect. For control measurements, water was used on which daphnia was cultivated. A single daphnia from an aquarium culture was placed in a transparent chamber restricting the movement of the crustacean as a whole. An ILPN-206 semiconductor laser with a wavelength of 1.3 μm was used as a radiation source. The signal from the integrated photodetector was amplified by a U4-28 amplifier and fed to the input of an analog-to-digital computer converter. From the spectrum of the recorded signal, the heartbeat rate of daphnia was determined, which usually varies in the range of 5 - 7 Hz for daphnia in the control medium.

 The occurrence of the effect of synchronization of the frequency of the heartbeat of a biological object with the frequency of additional exposure was determined at frequencies of 8-10 Hz. The choice of the upper limit of the frequency of the additional exposure was determined by the disappearance of the synchronization effect at a frequency of the additional effect of a significantly higher heart rate of the biological object. The choice of the lower boundary of the frequency of the additional exposure was determined by the ability of the equipment to clearly distinguish the frequencies of the additional exposure and the heartbeat of the biological object.

 From the calibration curve, the value of the desired harmful effect (phenol concentration) was determined.

 We also found that the effect on daphnia of any other harmful effect, for example, another type of toxicant or mechanical effect, can also be evaluated in the described way. It was previously established (see Kolupaev B.I., Andreev A.A., Samoilenko Yu.K. Optical method for recording heart rhythm in daphnia. - Hydrobiological Journal, vol. XIII, issue 3, 1977, pp. 119-120 ) and confirmed by us (Usanov D.A., Skripal Al.V., Vagarin A.Yu., Skripal An.V., Potapov V.V., Shmakova T.T., Mosiyash S.S. Laser autodyne interferometry of dynamic parameters of biological objects // Letters in ZhTF. 1998. V.24. Issue 5. P.39-43) the relationship of changes in heart rate of daphnia from the concentration of toxic factors. It was shown that with an increase in the concentration of toxicants, the heart rate of daphnia decreased. We made measurements and constructed the dependence of the amplitude of an alternating electric field, voltage U, applied to a bioobject, at which the effect of synchronizing the heartbeat frequency of the bioobject with the frequency of the additional effect, on the heart rate of daphnia, previously subjected to any harmful effects.

 Thus, the general nature of assessing the degree of influence of harmful effects on biological objects by the described method was shown.

Claims (1)

 A method for determining the effect of harmful effects on biological objects, including measuring the frequency of vibrations of a biological object and assessing the degree of influence of harmful effects by comparing with a calibration curve, characterized in that after measuring the frequency of vibrations of a biological object, it is additionally exposed to alternating voltage in a frequency range close to the vibration frequency of a biological object increase the amplitude of the additional action until the effect of synchronization of the vibration frequency of the biological object with the frequency of the additional EXPOSURE, wherein as a calibration curve using the amplitude of the alternating electric influence on the magnitude of the desired (known) of exposure.

Images