RU2395082C1 - Rapid bioindication method - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: method involves continuous measurement of behavioural and/or physiological reactions of aquatic organisms in natural conditions using measuring devices connected to a self-recording device or a computer and a signalling device. Bioindication takes place based on results of complex changes in functional characteristics of indicator organisms. Values of measured parametres are processed by the computer in real time separately for each specific indicator organism with subsequent averaging and integration of the results. Changes are evaluated from measurements of not less than three main parametres of behavioural and/or physiological reactions of indicator organisms and their fluctuation frequency. By comparing the current state of the indicator organism with its normal state and analysing the integrated measurement results, an alarm signal is generated automatically. The said signal indicates changes in conditions of the aquatic medium and degree of deviation from normal conditions. Bioindication is carried out using not less than two types of indicator organisms for one and/or more biotopes, where the biotopes used are different water layers or bodies.

EFFECT: increased reliability and efficiency.

3 dwg

Description

The invention relates to the field of ecology and environmental protection and can be used for continuous biological monitoring and operational bioindication to improve the efficiency and reliability of the assessment of environmental changes, including the indication of natural water pollution in real time.

Currently used microbiological, biochemical, physiological and other well-known laboratory indicators are not suitable for operational biological control, since they have a certain inertia (from several days to months), as well as traditional biomonitoring (from 1 to several years). Their delay in relation to pollution is due to both the time taken for sampling and / or conducting experiments, and the inevitable lag of these indicators from changing situations.

It is known that the behavior of attached (sedentary) bivalve mollusks is determined mainly by the movement (rhythm of opening and closing) of the valves of their shells. Under normal conditions, the valves are open most of the time to provide continuous nutrition and absorption of oxygen from the water. In response to water pollution or other deterioration in its quality, the mollusks initially close the shells, then the pattern of their behavior, the rhythm of alternating periods of closed and open leaves, change. The behavior of bivalve mollusks is so far the only functional indicator (in addition to growth) that can be continuously recorded in natural conditions. The main parameter of mollusk behavior is the level of valve opening (URS). URS is often the only parameter currently used abroad in on-line quality control of coastal and fresh waters. There is also known a method and apparatus for biomonitoring the aquatic environment (patents WO 9514925, FR 271298.4 EP 0730736 of 06/01/1995), designed to monitor in real time the physical and chemical parameters of the aquatic environment according to the behavior of animals using electrical signals generated fish or shellfish. The disadvantages of these methods are that they can be used only for limited conditions, sufficiently leveled (such as drinking water) and calm (in quiet coastal places), in real environmental conditions they cannot be used, since they do not take into account the natural variability of behavioral or other recorded reactions. For example, it was found that in a clean environment, mussels and other mollusks are able to significantly change the URS and close the valves for a long time, up to values recorded as dangerous and therefore provoking false alarms. Even in the productive coastal zone, mussels in some months are open at only 5-10% of the maximum URS, that is, they are practically (visually) closed due to the lack of sufficient food in the water. In the Barents Sea, for example, this situation may continue for up to six months. Therefore, by changing one parameter - URS or any other - it is difficult to judge the change in the environmental quality of the environment. The reliability of currently used or patented methods of biomonitoring using the monitoring of the state of organisms of one species according to 1 (rarely 2) behavior parameters is low, reliable bioindication based on them is impossible.

The closest is the method of biological monitoring based on bioindication according to the application of the Russian Federation for invention No. 2007138865 of 10.19.07, including long-term, short-term and operational bioindication. Operational bioindication is carried out according to the physiological and behavioral reactions of the aquatic organism in natural conditions, including motor activity and cardioactivity. Moreover, the detection of significant differences in indicator parameters by more than 30% relative to reference trends indicates a steady change in the state of the environment.

The objective of the proposed method is the development and improvement of one of the types of the above bioindication - operational bioindication in order to reliably identify environmentally significant and, above all, dangerous changes in the environment that can cause biologically depressive changes in organisms at the sublethal level and lead to the death of organisms.

The inventive method, as well as known, provides for the continuous recording of behavioral and / or physiological reactions of aquatic organisms in natural conditions using measuring instruments connected to a recorder or computer and a signaling device.

The technical result of the method is to increase the efficiency and reliability of assessing environmental changes, increasing the reliability of the method and eliminating errors such as "false alarm". The technical result of the method is also the possibility of continuous indication of the quality of water in places of development of oil and gas and other fields (drilling platforms), transportation and handling of hydrocarbons and other minerals or substances (terminals).

The technical result is achieved by the fact that bioindication is carried out according to the results of complex changes in the functional characteristics of indicator organisms. The values of the measured parameters are processed by the computer continuously in real time individually for each individual organism of the indicator, followed by averaging and integration of the results. Assessment of changes is made by measuring at least three basic parameters of behavioral and / or physiological reactions and the frequency of their fluctuations. Based on a comparison of the current state of the indicator organism with its normal state and analysis of the integrated measurement results, an alarm is automatically generated to alert you to changes in the quality of the aquatic environment and the degree of deviation from the norm. Bioindication is carried out on at least two types of indicator organisms for one or more biotopes, and different water layers or masses are used as biotopes.

An analysis of the sources of information revealed during the search showed that the claimed combination of essential features is unknown from the prior art, which confirms the compliance of the claimed solution with the criterion of "novelty."

Since the claimed combination of essential features allows you to get a new technical result, different from what the known methods provide, it can be argued that the claimed technical solution meets the criterion of "inventive step".

The inventive method is based on continuous registration of the functional state of the biosensor organism, which varies depending on changes in the environment, and is aimed at operational, i.e. quick and reliable assessment of current environmental changes by biological indicators. In the inventive method uses three basic principles of operational bioindication - multiparametric, statistical-integral and multi-species.

The use of the multiparameter principle is explained by the fact that for operational bioindication, it is not enough to change only the URS or any other one behavior parameter or other function. To increase the reliability of operational control and eliminate errors of the type of “false alarm”, it is necessary to know the nature (pattern or pattern) of the function in normal and pathological conditions and to produce bioindication by a set of activity parameters, including behavioral and / or physiological reactions. It is the principle of multiparametricity or multiparametricity, that is, the simultaneous use in bioindication of not one or a maximum of two parameters, but registration and joint accounting of several - at least three - parameters, that provides a reliable and adequate assessment of changes in the nature of the pattern of behavior or another function and detection real-time environmentally significant levels of changes in water quality and hazardous anthropogenic impacts on biological systems.

The choice of indicators (behavior, cardiac activity, etc.), their parameters and devices or devices for their measurement are determined by the task and local conditions, but behavior is the main indicator of the state of the body. In addition to behavioral reactions, parameters of physiological parameters can be used, for example, functions such as heart rate, nutrition, growth, respiration. At the same time, behavior remains the main indicator integrally reflecting the combined influence of both internal and external factors. Firstly, because with any exposure and change in the environment, the behavior of the body changes first. Secondly, because the behavior is not determined by any one function or system of the body, the reactions of all systems are manifested in it. In the behavioral reactions of mollusks, the combined effect of external and internal factors is integrated, the functional state of the organism is reflected, and, most importantly, the degree of general (cumulative) biological favorable / unfavorable environment.

For bivalve mollusks, for example, behavioral parameters such as URS, ADD (adduction is the frequency of closure of the valves), AMP (amplitude of opening of the shells), T (total time of closing of the valves) and H (vibration frequency of the URS), as well as their Standard deviation - standard deviations. Oscillations of URS have the character of a hierarchical system of biorhythms (from ultradian to circadian and infraradian). Most of the above parameters (amplitude, level, frequency) relate to vibrations of any function - these are universal or mandatory characteristics of complex rhythms. The frequency (rhythm) of URS (B) oscillations in mussels, for example, also reflects the proportion or ratio of the relative phases of “activity” and “rest”, the change of which is an essential sign of their behavior. The changes in biorhythm parameters and the ratio of activity and rest phases observed in comparison with control values reflect the degree of change in environmental conditions. Only on the basis of the joint use of several vibration parameters (for example, URS, ADD, AMP, T, H) and the nature of the rhythm or the type of curve of movements of the valves, it is possible to distinguish with confidence the anthropogenic effects from natural environmental changes, and toxic, and cumulatively complex hazardous effects non-hazardous and non-toxic. Therefore, bioindication according to the claimed method is carried out according to the results of complex changes in the functional characteristics of indicator organisms. The values of the measured parameters are continuously processed by the computer in real time for each individual organism of the indicator individually, followed by averaging and integration of the results. The condition of each individual of the test animal with the help of appropriate software is compared with its state in the norm for the corresponding period of time, the closest or similar (reference) to the average weather, temperature and other conditions. After that, the data for the entire group of animals are averaged and the change in dispersion and rhythm is estimated. Assessment of changes in the state of objects of observation is made in comparison with the range of natural variability of the parameters of aquatic organisms in natural conditions. The range of natural variability of the parameters is the boundary of the behavioral norm of the indicator organism in the form of the average, maximum and minimum acceptable values of the measured parameters and their dispersions, determined on the basis of statistical processing of the results of parameter measurements in natural conditions that correspond to sanitary standards. A significant deviation from the norm is an indication of a change in environmental conditions. The hazard warning signal is activated only when at least three parameters and / or the rhythm of their fluctuations have changed significantly. Moreover, the critical levels of changes, that is, the danger levels and the corresponding gradation of signals, are determined by the number of changed parameters and the degree of their deviation from the norm.

The use of the multi-species principle is the bioindication of at least two types of indicator aquatic organisms for one and / or more biotopes, while different water layers and masses (surface layer, bottom layer, near the shore, on the platform, etc.) are considered biotopes. ), - is explained by the fact that the complex of local conditions within the boundaries of habitats is different. Certain species of mollusks are found and can not survive everywhere, therefore, the claimed method provides for the use of at least two local species of aquatic animals as bioindicators.

When using the proposed method in each case for certain local conditions and in accordance with the measured parameters and types of aquatic animals, various instruments and devices are used. Operational bioindication can be carried out using a bioindication system, including, for example, measuring instruments connected to a recorder, a computer and / or a signaling device, ensuring the observance of the principle of multiparameter measurements.

The proposed technical solution is feasible, which is confirmed by the following information.

For continuous recording of the behavioral reactions of mollusks in natural conditions, for example, a pilot installation developed and successfully tested by the author can be used, which is a platform with equipment installed on it, connected to measuring instruments and sensors mounted on mollusks. This installation of continuous registration (UNR) is used in two versions: autonomous and stationary. The stand-alone option, with the placement of equipment on a raft, is designed for biomonitoring the waters of the coastal zone. All signals from sensors mounted on mussels or other mollusks are continuously recorded in real time by the recorder and / or processed by a computer using the appropriate program. Cardiac activity and the behavior of mollusks can also be measured in flowing aquariums located, for example, on the oil or other platform itself, where water is pumped from the sea surface by a pump. For different conditions and different aquatic animals from different biotopes, several different devices can be used. For example, for mollusks at a depth, a video surveillance system can be used; near the coast, a system for recording behavioral responses and cardiac activity of mussels can be used, including sensors attached to mussels, the information from which is recorded by recorders, electrical and / or electronic devices with step-by-step computer processing of incoming signals from various discreteness, including in real time. In addition to mussels, the following can be used as test organisms of the coast: mollusks - mia, scallop, modiolus or cardium (behavior, cardiac activity); holothuria - cucumaria (video surveillance), etc. About exceeding the threshold readings by certain types of animals and the degree of their deviation from the norm is notified by a light, sound or other signal device connected to the computer or built into it.

To determine the range of natural variability of the parameters of test organisms in natural conditions, studies were conducted on mussels, modioluses and other marine bivalves of the Barents Sea. Changes in their behavior under natural and experimental conditions were recorded in different seasons of the year. Based on the results of the study, a classification of elementary behavioral acts of the movement of mollusk folds was developed. The main quantitative parameters (the level of valve openings - URS, amplitude - AMP and adduction frequency - ADD) of their motor activity were determined, and the presence of periodic components of the movements of the mussel valves under natural fluctuation of environmental factors was investigated. It was found that mussels are able to respond even to insignificant periodic fluctuations of environmental factors: for example, temperature - by 0.1 ° С (in winter), salinity - by 0.2 ‰ (in spring), depending on the season. The analysis of the possibilities of mathematical methods for processing time series in the detection and objective analysis of the periodic components of the behavior of mussels was conducted, the dependences of some behavioral reactions of mussels on relatively weak continuous fluctuations (tidal and diurnal) of the main environmental factors, such as temperature, salinity, phytoplankton / seston concentration, were studied. with their joint action. Quantitative dependences of the main parameters of the behavior of mussels on environmental factors are determined, which allows you to record changes in the activity of an aquatic animal in real time, continuously monitoring its behavior. It has been established that the frequency of changes in the level of opening of the mussel valves is determined by small in amplitude but stable tidal fluctuations of environmental factors (temperature, salinity, suspension).

To study the possibility of using operational bioindication directly in the conditions of water bodies, comparative studies (biotests) of the reactivity of several types of marine bottom invertebrates were carried out. At the first stage, the possibilities of biotesting were studied under conditions as close as possible to natural ones. In connection with the increasing exploitation of shelf deposits, biotesting of pollution from drilling processes was carried out. The effect of various concentrations of drilling fluids (BR), their components and the water-soluble fraction of the mud of drilling fluids of a ferrochrome-lignosulfonate type was studied in flowing aquariums on model test objects - bottom invertebrates of the Barents Sea. We analyzed the physiological (respiration and filtration rate) and behavioral (locomotor activity) reactions of mussels Mytilus edulis, respiration and behavior of holothurians Cucumaria frondosa, survival rate and caloric content of Gammasus duebeni amphibians, and mortality of Dynamena pumila hydroids.

The motor activity of mussels was recorded as the activity of movement of the valves, the level of their average opening (URS). According to this indicator, mussels had significant differences with respect to the control, even at a 0.001% concentration of drilling mud (BR). At the same time, significant changes in the rate of oxygen consumption and the rate of water filtration by mussels were observed only at 1% concentration of BR.

Holothurians were most sensitive to changes in the chemical composition of water. Their oxygen consumption increased rapidly, starting with the smallest (3 μl / l) concentrations of drilling reagents (Petrosila-2M, Lignosila). At high concentrations of reagents, a sharp drop in the respiration rate of holothurians was usually observed.

The amphipods, which were in running water for a month at 0.002% concentrations of water-soluble sludge extracts of three industrial drilling fluids: lignosulfonate, potassium-alumina and calcareous type, underwent a tissue calorie drop of 14-30%.

All hydroids died within 5 days at 1.2% concentration of BR. In this case, a gradual decrease in the number of active hydroteks was observed.

Studies have shown that the movement of mollusk folds, considered not only as locomotor, locomotor activity, but, above all, as their adequate response to changes in environmental conditions and internal processes of the body, is the main aspect of behavior, especially in relation to attached bivalve mollusks. The behavior is closely related both to the physiological state of mollusks, to the level of their filtration activity, and to environmental factors, with the concentration of food and inorganic substances suspended in water. Thus, in the behavioral reactions of mussels recorded by EOS and other parameters, the combined influence of environmental factors is integrated. Behavior is an integral state of the body, an indicator of the favorable environment for mollusks (Fig. 1), it reflects the degree of contact of the mollusks with the habitat and depends to the greatest extent on the chemical composition of the water and the amount of substances suspended in it. Changes in behavior are usually detected already at the lowest concentrations of test substances.

Thus, the general behavior of mollusks is a fairly plastic indicator that adaptively and quickly reflects changes in environmental environmental factors. It works well in both acute and chronic conditions, and can be used almost everywhere.

Another indicator suitable for operational bioindication is the cardioactivity of bottom animals (mollusks, crabs). The responses of the cardiac activity parameters are distinguished by great individual and temporal variability even under constant laboratory conditions. It was found that under the influence of low concentrations of toxic chemicals (copper and iron sulfate, cadmium nitrate, ammonia and detergent) in the first minutes, the heart “freezes” and the amplitude decreases, followed by an increase in the heart rate, then the heart rate (heart rate) and its variability increase (RMS), the next 2-3 hours heart rate and amplitude fall, the standard deviation remains high, the rhythm is violated (see figure 2). In the behavior of mussels, these fluctuations of the parameters are less pronounced, the URS decreases steadily (see figure 3).

To measure the cardiac activity of the mussels of the Barents Sea, sublittoral mollusks collected in the estuary zone of the Kola Bay were transported to St. Petersburg, where they conducted experiments in the laboratory and on the equipment of the SRCSE RAS. The device - photoplethysmograph, was used to record heart contractions. Cardiac activity parameters were calculated according to the original programs, among them: Heart rate - average heart rate, i.e. the number of heart beats per minute (beats / min); RMS (SD) is the mean square deviation of the cardio intervals in the sample (sec). The behavioral reactions of the Barents Sea mussels Mytilus edulis were recorded as the movements of their cusps using recorders, and the Black Sea mussels were also recorded using an original automated electronic complex based on strain gauges or Hall sensors with digital recording on a computer in real time.

Heart rate measurements and studies of the relationship between leaf movement parameters and cardiac activity of the Barents Sea and Black Sea mussels were started by the author in December 2006. Over two years of research, evidence was obtained of the connection / correlation of the behavior and physiology of mollusks - URS and heart rate parameters (heart rate, SKO) - and The complex nature of this dependence was observed under experimental conditions. A graphic and correlation analysis technique has been developed, it has been proved that it is more efficient to compare URS and heart rate over long time intervals of averaging (from 30 minutes to 1 hour). The influence of several factors on the behavior and cardiac activity of mussels of the Barents and Black Seas was studied: lighting, vibration, temperature fluctuations, low concentrations of toxic chemicals (copper and iron sulfate, cadmium nitrate, ammonia and detergent). It was found that the correlation between heart rate and URS is unstable, varies from 0.5 to -0.7 and depends on environmental conditions. With a significant (prolonged) lack of food or its absence (during starvation) in laboratory aquariums, the correlation was mostly negative, intensified with moderate stress associated with noticeable changes in the URS. The highest correlation was between the URS and the standard deviation, reaching -0.93. In the calculations of averages and correlations, periods of “cardiac arrest”, ie lack of rhythmic heart contractions. Periods of decrease in heart rate and prolonged (more than 14 hours) cardiac arrest always coincided with long phases (more than 30 minutes) of closure (not necessarily complete) of the valves. At the same time, cardiac arrest was also detected for the first time with wide open sashes.

It is established that there is no direct relationship between URS and heart rate. It is proved that for cardiac activity, the first sign of stress is a change in the amplitude of heart contractions, and not the standard deviation, as previously thought. During the study, the methodology and software for the study of cardiac activity of cancers were applied. Initial measurements of the cardiac rhythm of crayfish and mussels were carried out at the NICEB laboratory in 1-channel and then 7-channel photo plethysmographs (PPG) with signal processing using the VarPulse 5.0 program. All the main parameters of the heart rate were displayed in the program window (see figure 2), and also automatically saved in tabular form as separate files. In mussels, the rhythm of heart contractions has a number of features, including prolonged cardiac arrest, which is why program failures often occurred. For use on mussels, the methodology and software are constantly being developed. Thus, measuring the work of the mollusk heart by a non-invasive method of recording and calculating parameters can be used as an additional indicator for operational bioindication to increase the reliability, accuracy of measurements and the reliability of assessing the degree of environmental change.

The inventive method of operational bioindication provides the maximum level of control of the ecological safety of waters by continuously recording the functional parameters of organisms and bioindicating changes in the ecological state of marine, fresh and mixed waters, including real-time detection of environmentally significant levels of anthropogenic impacts on biological systems. The inventive method can also be used for operational bioindication of wastewater in places of wastewater discharge or dumping, in recreation areas (beaches), in aquaculture areas (fish, invertebrates, algae) or keeping animals (marine mammals, fish, crabs, etc.) in drinking water (water intakes) and tap water.

Information sources

1. Borcherding J., Volpers M. The Dreissena-monitor -1 ^st results on the application of this biological early warning system in the continuous monitoring of water quality // Water science and Technology. 1994. V.29. P.199-201.

2. De Zwart D, Kramer K.J.M., Jenner H.A. Practical experiences with the biological early warning system "Mosselmonitor" // Environ. Toxicol. Water quality. 1995. V. 10. P.237-247.

3. Gudimov A.V. Operational biological monitoring - a modern approach to environmental safety control // Oil and gas of the Arctic shelf, - 2008. Fourth International Conference (Murmansk November 12-14, 2008). Murmansk.

4. Matishov G.G., Gudimov A.V., Denisov V.V. Multilevel bioindication in the system of modern monitoring technology: on the example of zoobenthos of the estuary zone of the Kola Bay // DAN. 2008.V. 418. No. 1. S.134-137.

5. Gudimov A.V., Gudimova E.N. Behavioural and physiological responses of two benthic invertebrates in bioassay of the sublethal effects of coastal pollution (Chapter 13) // Natural Wetlands for Wastewater Treatment in Cold Climates. Boston: WITpress. 2002. P.225-248.

6. Gudimov A.V. The behavior of mussels (Mytilus edulis L.) under conditions of fluctuations in environmental factors // DAN. 2006.V. 409. Number 3. S.419-421.

7. Bouget J.-F., Mazurie J. Biological monitoring of water quality in an estuarine shellfish area, using a biosensor recording valve movements of oysters and mussels // Tech. Sci. Methodes. Genie Urbain-Genie Rural. 1997.No.11. P.71-75.

8. Gudimov A.V. Problems of studying cardioactivity and behavior of mussels for the purpose of operational bioindication // Modern problems of marine engineering ecology (survey, EIA, socio-economic aspects): Materials of an international scientific conference (Rostov-on-Don, June 9-11, 2008). Rostov N / A: Publishing House of the UNC RAS, 2008. P.269-272.

9. Gudimov A.V. New biomonitoring technology based on operational bioindication // Mater. Vseros. conf. with int. participation “Northern territories of Russia: problems and development prospects” (Arkhangelsk, June 23-26, 2008). Arkhangelsk, 2008. P.365-368.

Claims (1)

A method of operational bioindication, which provides for the continuous recording of behavioral and / or physiological reactions of aquatic organisms in natural conditions using measuring instruments connected to a recorder or computer and a signaling device, characterized in that bioindication is carried out according to the results of complex changes in the functional characteristics of indicator organisms, values the measured parameters are processed by the computer in real time individually for each individual organ indicator indicator, followed by averaging and integration of the results, changes are assessed by measuring at least three basic parameters of the behavioral and / or physiological reactions of indicator organisms and their oscillation frequency, based on a comparison of the indicator’s current state with its normal state and analysis of integrated The measurement results automatically generate an alarm signaling a change in the conditions of the aquatic environment and the degree of their deviation from the norm, conduct bioindication no less than two types of indicator organisms for one and / or more biotopes, and different water layers or masses are used as biotopes.

Images