RU2461893C2 - Diagnostic technique for toxic encephalopathy in small laboratory animals in chronic action of metallic mercury vapour - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: electroencephalography is performed; β₂ - and δ - rhymes are recorded in F4 and P3 lead; a canonical variate is calculated by formula: Cv=1.6+1.6xa₁-1.2xa₂+0.7xa₃-0.4xa₄-) wherein Cv is the canonical value 1.6; -1.2; 0.7; -0.4 are discriminant coefficients; 1,6 is a constant; a_1,2,3,4 are numerical values of research results of bioelectric cerebral activity: a₁ is a percentage β₂ of P3-lead rhythm, a₂ is a percentage δ of P3-lead rhythm, a₃ is a percentage δ of F4-lead rhythm, a₄ is a percentage β₂ of F4-lead rhythm. If the Cv value is more than 1.6, the absence of chronic action of mercury on the brain is stated; if the Cv is 1.6 or less, toxic encephalopathy is diagnosed in the animal.

EFFECT: method extends the range of the agents for diagnosing of toxic encephalopathy in small laboratory animals in chronic action of metallic mercury vapour.

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Description

The present invention relates to medicine, namely to experimental medicine, and can be used to diagnose toxic encephalopathy in chronic mercury intoxication. One of the most frequent and dangerous manifestations of mercury intoxication is toxic encephalopathy, which often progresses over time and causes the development of a neurodegenerative process, significantly reducing the quality of life. At the same time, the insufficient effectiveness of existing rehabilitation methods determines the need to conduct studies to study the causes and nature of structural and morphological lesions of the nervous tissue during mercury neurointoxications. The solution to this problem is impossible without creating an adequate model in experimental animals and the presence of highly informative criteria for assessing the functional state of the central nervous system (CNS).

To diagnose the functional state of the central nervous system in laboratory animals (white rats, white mice), tests evaluating their behavioral activity are most often used. Known methods for assessing toxic damage to the central nervous system when modeling posthemorrhagic, posthypoxic and toxic encephalopathy by changing the conditioned reflex activity and behavioral activity [2, 7-10]. The prototype is a method for the diagnosis of distant toxic encephalopathy in experimental animals by changing the motor activity and emotional state of white rats, tentatively-research behavior, muscle tone compared to the control group [6]. However, these methods only indirectly confirm the presence of a pathological process in the central nervous system, are quite laborious, and a long period of time (up to 2 weeks) is required to study behavioral activity. While electroencephalography (EEG) significantly increases the reliability of the development of toxic damage to the central nervous system in chronic mercury intoxication and in a shorter time confirms the presence of pathology of the nervous system.

The problem solved by this invention is the development of a method for the diagnosis of toxic encephalopathy in small laboratory animals using electroencephalography (EEG diagnostics).

The problem is solved by measuring electroencephalographic parameters in small laboratory animals after seeding with mercury, followed by determination of the canonical value and assigning the animals to the group with signs of toxic encephalopathy or to the group without signs of poisoning.

The method is as follows.

After seeding with metallic mercury vapor from small laboratory animals and implanting electrodes into the brain 3-4 days after implantation, the rhythmic electrical activity of the cerebral cortex is recorded: β ₂ rhythm in the temporal-occipital lead P3, δ rhythm in the lead P3, δ- rhythm in the parietal lead F4, β ₂ rhythm in the lead F4. The canonical quantity is calculated by the formula:

Qu = 1.6 + 1.6 × a ₁ -1.2 × a ₂ + 0.7 × a ₃ -0.4 × a ₄ , where

Kv - canonical quantity

1,6 - constant

1.6; -1.2; 0.7; -0.4 - discriminant coefficients;

and _1,2,3,4 are the numerical values of the results of the study of the bioelectric activity of the brain: ₁ - the percentage of β ₂ rhythm in lead P3, ₂ - the percentage of δ rhythm in lead P3, and ₃ - percentage δ- rhythm in assignment F4, and ₄ - percentage of β ₂ rhythm in assignment F4.

With a Qb greater than 1.6, they conclude that there is no evidence of a chronic effect of mercury on the brain; with a Sv less than or equal to 1.6, the animal is diagnosed with toxic encephalopathy.

The use of electroencephalography for studying the state of the central nervous system of laboratory animals is known. So, in the work of Murik S.E. the level of constant potential (SCP) and omega potential of EEG from the surface of the neocortex in rats during ischemia were recorded for fine differentiation of the metabolic and functional state of nervous tissue [3]. S.V. Krapivin et al. carried out, using encephalography, a neurophysiological analysis of the action of antihypoxants in comparison with psychotropic drugs in the study of antihypoxic activity of drugs [4]. Other researchers studied the effect of a nootropic agent of cerebrocrast on EEG in waking rats with cerebral ischemia [5].

In this method, electroencephalography is used to diagnose signs of mercury intoxication. We have identified the most informative electroencephalographic indicators that allow us to determine the canonical value for assigning animals to the group with signs of toxic encephalopathy or to the group without signs of poisoning.

It was found that a reliable differentiation of white rats without mercury intoxication and animals with neurointoxication with metallic mercury vapor was made possible by the combination of the following most informative EEG parameters: β ₂ rhythm in the temporal-occipital lead P3, δ rhythm in the lead P3, δ rhythm in the parietal lead F4, β ₂ rhythm in lead F4.

The reliability of the obtained informative EEG indicators of animals with mercury intoxication and without it according to the results of discriminant analysis is presented in the table.

Reliability of informative EEG indicators of animals with chronic mercury intoxication and control white rats No. Indicators F inclusion R one. β ₂ rhythm in lead P3 6.14 0.017 2. δ-rhythm in assignment P3 8.2 0.003 3. δ rhythm in lead F4 12.8 0.002 four. β ₂ rhythm in lead F4 16.3 0,00007

The proposed method was applied in an experiment on outbred white rats in an amount of 16 individuals weighing 180-240 g (8 - individuals from the experimental group, 8 individuals - from the control group). Dynamic inhalation inoculation with metallic mercury vapor of the experimental group of animals was carried out for 7 weeks. Stereotactic manipulations were performed under anesthesia. The electrodes were implanted in the temporal-occipital (P3 lead) and parietal (F4 leads) areas of the cortex of white rats, an indifferent electrode was attached to the nasal bones [1]. The rhythmic electrical activity of the cortex of white rats was recorded 3-4 days after implantation. We recorded the β ₂ rhythm in the temporal-occipital lead P3, the δ rhythm in the lead P3, the δ rhythm in the parietal lead F4, and the β ₂ rhythm in the lead F4.

Then the canonical value was calculated according to the above formula and an appropriate conclusion was made.

Example 1: a rat from an experimental group of animals. After seeding with mercury vapor, the animal had behavioral reactions with a high level of negative emotional state in the form of a lack of a “stand with emphasis” pattern, an increase in the duration of the grooming act, with pronounced aggressiveness in the form of completed attacks on a “stranger”, with a violation of species-specific tentatively - research behavior, manifested in a decrease in the number and duration of the mink act. After implantation of the electrodes, the white rat was subjected to EEG; the following numerical values were determined:

and ₁ - 5.5%; and ₂ - 15.5%; and ₃ - 16%; and ₄ - 46%

Kv = 1.6 + 1.6 × 5.5-1.2 × 15.5 + 0.7 × 16-0.4 × 6 = 0.6

Conclusion: 0.6 <1.6, in this case, there are signs of the effects of mercury on the central nervous system, toxic encephalopathy, which manifests itself in a disorganization of the bioelectric activity of the brain.

Example 2: a rat from an experimental group of animals. The animal had signs of impaired behavioral reactions with a high level of negative emotional state, with a pronounced aggressiveness. The animal was EEG. The following numerical values are defined:

and ₁ - 3%; and ₂ - 10%; and ₃ - 12%; and ₄ - 3%

Kv = 1.6 + 1.6 × 3-1.2 × 10 + 0.7 × 12-0.4 × 3 = 1.6

Conclusion: 1.6 = 1.6, in this case there are also signs of the effects of mercury on the central nervous system, manifested in a disorganization of the bioelectrical activity of the brain, diagnosis: toxic encephalopathy.

Example 3: rat from the control group of animals. The behavior of the animal corresponded to the species-specific behavior characteristic of rodents with a normal level of orientational research activity (with the implementation of the acts “mink”, “vertical stance”, “stance with emphasis”), emotional state (with the corresponding number of executions and the duration of the grooming pattern) , with the absence of attacks on the "stranger". EEG was performed on a white rat; the following numerical values were determined:

and ₁ - 3%; and ₂ - 5.5%; and ₃ - 6%; and ₄ - 2%

Kv = 1.6 + 1.6 × 3-1.2 × 5.5 + 0.7 × 6-0.4 × 2 = 3.2

Conclusion: 3.2> 1.6, in this case there are no signs of the effects of mercury on the central nervous system.

The method expands the range of criteria and methods for assessing the pathological process in the central nervous system when modeling toxic encephalopathy. The proposed method allows to diagnose the organic lesions of the brain of white rats with mercury neurointoxication with less time spent on the examination compared with the study of the behavioral reactions of laboratory animals.

Literature

1. Buresh J. Methods and basic experiments on the study of the brain and behavior. / Ya. Buresh, O. Bureshova, D.P. Houston. - M.: Higher School, 1991.

2. Modeling focal cerebral ischemia. / Chekhonin V.P., Lebedev S.V., Petrov S.V. et al. // Vestnik RAMS, 2004. - No. 3. - S. 47-54.

3. Murik S.E. Omegaelectroencephalography is a new method for assessing the functional and metabolic state of nervous tissue. / S.E. Murik // Bulletin of the VSSC SB RAMS. - 2004. - T.3. - No. 1. - From 188-194.

4. Neurophysiological analysis of the action of antihypoxants in comparison with psychotropic drugs. / S.V. Krapivin, A.Yu. Malyshev, A.V. Kharitonov, O.S. Yermishina and others // Vestnik RAMS. - 2002. - No. 8. - S. 32-37.

5. Plotnikov M.B. The effect of cerebrocrast on local cerebral blood flow and EEG in awake rats with cerebral ischemia. / M.B.Plotnikov, O.E. Vaizova, N.I. Suslov // Bulletin of experimental biology and medicine. 1995 .-- v. 117. - Number 3. - S.296-298.

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Claims (1)

A method for the diagnosis of toxic encephalopathy in small laboratory animals with chronic exposure to metallic mercury vapor, including an assessment of the functional state of the central nervous system, characterized in that the animals undergo electroencephalography and β ₂ and δ rhythms are recorded in leads F4 and P3, the canonical value is calculated by the formula :
Kv = 1.6 + 1.6 · a ₁ -1.2 · a ₂ + 0.7 · a ₃ -0.4 · a ₄ ,
where Kv is the canonical quantity;
1.6; -1.2; 0.7; -0.4 - discriminant coefficients;
1,6 is a constant;
and _1,2,3,4 are the numerical values of the results of the study of the bioelectric activity of the brain: ₁ - the percentage of β ₂ rhythm in lead P3, ₂ - the percentage of δ rhythm in lead P3, and ₃ - percentage δ- rhythm in assignment F4, and ₄ - percentage of β ₂ rhythm in assignment F4;
and with a CV greater than 1.6, they conclude that there is no evidence of a chronic effect of mercury on the brain; with a Sv less than or equal to 1.6, the animal is diagnosed with toxic encephalopathy.