RU2617206C2 - Method for physical fatigue simulation in rats under desynchronosis - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: animal is stressed in two stages. At the first stage, experimental desynchronosis is induced by keeping the rats under artificial light or in complete darkness around the clock for 12 days. After that, the animals are forced to swim under natural light with a load attached to the tail, the weight of which is 10% of the animal body weight. A rectangular glass aquarium with dimensions of 100 cm × 100 cm × 20 cm is used. The aquarium is divided into sections, connecting at the bottom and is provided with two valves - above and below one of the side walls. The water temperature is 26-28ºC. The animals swim until complete exhaustion, the criterion which is three unsuccessful attempts to rise to the surface, or rejection of such attempts with sinking to the bottom.

EFFECT: method allows to create a model in which the animals reach the state of fitness and resistance to stress, and that reflects the problems of sports physiology, associated with body adaptive reserves violation due to transmeridianal flights and subsequent athletic training.

1 tbl

Description

The invention relates to experimental medicine and can be used to model physical fatigue in rats under desynchronosis.

The training and competitive regime of highly qualified athletes requires constant movements in different time zones. As a result of such transmeridian displacements, disturbances inherent in the evolution of circadian biorhythms of physiological functions — desynchronosis — develop.

Desynchronosis is a process that occurs in the body in connection with significant violations of biological rhythms caused by a mismatch between the physiological rhythms of the body and external time sensors, of which social factors are of particular importance. The manifestations of desynchronosis are diverse and often multidirectional. For all types of movements in contrasting climatic-temporal and social conditions, the first short-term reaction is manifested in a decrease in working capacity and an increase in the energy consumption of the body. This reaction can be considered as a phase of stress. At the same time, specific adaptive reactions develop, determined by the ecological and social characteristics of the environment. The process is accompanied by a mismatch of the activity of physiological systems and the subordination of physiological functions. For normal life in the new conditions, a sufficiently long time (days) is needed for the restructuring of the spatio-temporal interactions of body functions, the development of special programs and regulatory mechanisms that have their own characteristics with different types of movements.

Desynchronization of biorhythms leads to the depletion of adaptive reserves of the body and is accompanied by chronic fatigue syndrome, which requires the development of programs for the gentle rehabilitation of athletes during the competition and the recovery of the body from training and competition loads. An experimental verification of their effectiveness is necessary to justify the structures of rehabilitation programs.

There are several approaches to experimental modeling of physical fatigue, where the object is small mammals (mice, rats). One of these methods is to determine the speed of physical endurance by the duration of the mice running in a 10-track treadmill equipped with an electric stimulator (70 V) at a speed of 40 m / min [Determining the safety and effectiveness of biologically active food additives, 1999]. There is a known technique of strength endurance assessment, where they determine the time of hanging mice on a pole from the beginning of retention to the moment of fall [Arbuzov S.Ya. et al., 1960]. The disadvantages of these models are that they do not adequately reflect the problems in sports physiology associated with the violation of the adaptive reserves of the body due to transmeridian flights and subsequent sports training.

There is a known method of modeling desynchronosis - in constant lighting conditions in which experimental animals are kept for several days (from 10 days to 6 months) in inverted light mode or in round-the-clock lighting or darkness [Zamoshchina T.A., 2000; Labunets I.F., Bondarenka L.A., 2013; Zhurakovsky I.P. et al., 2014].

However, in the known method was evaluated only desynchronosis between the rhythms of the same name with different functional parameters without examining the physical performance of animals.

Closest to the proposed is a modeling method, which consists in the fact that the experimental animal is subjected to "forced swimming". The principle of the method is to assess the life expectancy of animals under physical stress (swimming) at a relatively low water temperature (17-20 ° C below average body temperature) [Experimental modeling and laboratory assessment of adaptive reactions of the body / V.A. Volchegorsk [and others]. - Chelyabinsk: ChSPU, 2000. - 167 p.]. The test is carried out both on mice and on rats. Animals are forced to swim at low water temperatures for 30 minutes. Record swimming time before death and assess mortality (as a percentage of the total number of mice) for the observation period. For the test on mice, glass chromatographic chambers of 29 × 19 × 40.5 cm in size or plastic buckets of similar sizes are used. When conducting a "forced swimming" test on mice, the height of the water column should be at least 20 cm.

To perform the “forced swimming” test on rats, a larger tank was used, for example, according to the description, a metal tank of circular cross section, 63 cm in diameter, 72 cm high. Water column at least 50 cm, height of the part of the tank that is not occupied by water, at least 22 see. Water temperature for "forced swimming" rats ranges from 17-18 ° C. The rest of the test is carried out similarly to the method described above for mice. Subject to the conditions described, according to the authors, the mortality rate of rats is 93.87% for a 30-minute observation period, the average latency of animal death is 18.88 ± 2.2 minutes. These test parameters should be regarded as deficiencies, since, firstly , according to the description, the model provides for a high percentage of death of animals, which does not fully meet modern principles of humane treatment of animals, and, in addition, increases the consumption of animals for the experiment, respectively increasing costs; secondly, the indicated observation period is quite long, which increases the time spent on the experiment. According to the description, the “forced swimming” test is intended for an integrated assessment of the mechanisms of a resistant (ie stressful) adaptation strategy.

A new technical result is the expansion of the arsenal of experimental models, which to a greater extent reflect the problems of sports physiology associated with the violation of the adaptive reserves of the body due to transmeridian flights and subsequent sports training, while reducing animal mortality and shortening the model formation time.

To achieve a new technical result in a method for simulating physical fatigue in rats under desynchronosis, including exerting a load using forced swimming of an animal in a tank of water, the load is carried out in two stages: at the first stage, experimental desynchronosis is induced by keeping rats for 12 days round the clock with artificial lighting or in complete darkness, after which the animals under natural lighting are forced swimming for 5 days, with a load, fixed on the tail, whose weight is 10% of the body weight of the animal, at a water temperature of 26 ° -28 ° C until fatigue, the criterion of which are three unsuccessful attempts to surface or refusal of such attempts with lowering to the bottom.

The method is as follows.

At the first stage, for the induction of experimental desynchronosis, the animals of the experimental groups were kept around the clock for 24 days under conditions of artificial bright lighting of 150 LX (group No. 1) or complete blackout 2-3 LX (group No. 2) on a normal diet with free access to water and food . At the second stage, under natural light, the rats were forced to swim for five days in a rectangular glass aquarium with dimensions of 100 cm × 100 cm × 20 cm, divided into compartments connecting at the bottom and equipped with two valves: one on top and bottom of one of the side walls, with with a weighting weight equal to 10% by weight of the body of a particular individual at a water temperature of 26 ° -28 ° C until complete fatigue, the criterion of which were three unsuccessful attempts to float to the surface or refusal of such attempts with lowering to the bottom, after his animal was removed from the aquarium.

The proposed method is based on the analysis of experimental research data.

The experimental study was performed on 30 sexually mature male Wistar rats weighing 280-300 g, contained in standard vivarium conditions on a normal diet with free access to water and food. The vivarium premises are completely isolated from other divisions of the Branch of TNIIKiF FSBI SibFNCC FMBA of Russia. The floors are made of waterproof material, the walls are covered with glazed tiles. All rooms of the vivarium are heated using a central heating system, have natural and artificial lighting, are connected to hot and cold water supply and to the sewage system, equipped with forced supply and exhaust ventilation, providing the necessary air exchange rate and microclimatic conditions. Year-round indoor vivarium maintains 50-65% relative humidity and air temperature 20-25 ° С. Closed bactericidal irradiators-recirculators are used to reduce microbial contamination.

All procedures with animals were performed in accordance with international rules and regulations (European Communities Council Directives of November 24, 1986, 86/609 / EEC).

All animals were randomly divided into 3 groups of 10 individuals:

1) rats under natural lighting conditions and subjected to simulation of physical fatigue; control group;

2) rats on which physical fatigue was modeled after the formation of experimental desynchronosis in the form of round-the-clock lighting; group number 1;

3) rats on which physical fatigue was modeled after the formation of experimental desynchronosis in the form of round-the-clock darkness; group number 2.

At the first stage, for the induction of experimental desynchronosis, the animals of the experimental groups were exposed to artificial light or complete darkness around the clock for 12 days. Then, in the second stage, the rats were subjected to physical exertion in natural light. Physical activity is realized by forced swimming of rats in a glass aquarium with a load of 10% of body weight at a water temperature of 26 ° -28 ° C until complete fatigue for 5 days.

Swimming was carried out in a special boxed installation, which was a rectangular glass aquarium 100 cm × 100 cm × 20 cm in size, divided into five compartments connecting at the bottom and equipped with two valves - one on top and bottom of one of the side walls, with a weight equal in weight to 10% of the body weight of a particular individual, at a water temperature of 26 ° -28 ° C. The parameters of the aquarium and the load, as well as the duration (5 days) of the load, are selected on the basis of experimental observations and can reduce the lethality of animals and, at the same time, obtain a model in a shorter time.

Using a single knot of thread, the animals were fixed on the tail with a calibrated load weighing, respectively, 10% of the individual mass of its body, after which it was placed in the compartment, one individual each. The temperature of the water was monitored every 10 minutes and maintained at 26 ° -28 ° C. Animals swam to exhaustion. The criterion of complete fatigue was three unsuccessful attempts to surface, or the refusal of such attempts with lowering to the bottom. At the same time, the net was picked up and removed from the aquarium.

At the end of the experiment, rats were bred at the same time by decapitation under CO ₂ anesthesia, according to the Helsinki declaration of the World Medical Association on the humane treatment of animals and order of the USSR Ministry of Health No. 577 of 08/12/1977 "Rules for the work using experimental animals."

Statistical processing of the results was carried out on the basis of the StatSoft Statistica v6.0 software package. (nonparametric Mann-Whitney, Wilcoxon, Friedman criteria).

As the experiments showed, with daily physical swimming load until fatigue without modeling circadian biorhythm disturbances in the control group, by the 3rd day of the study, an increase in active swimming time is observed, and by 4 days it is statistically significant with subsequent stabilization of the indicator. The results obtained indicate that the animals have reached the state of fitness and resistance to stress. The described dynamics largely corresponds to a change in the phases of adaptation (anxiety, resistance, exhaustion) (Selye G., 1960; Gorizontov P.D. et al., 1983; Meerson F.Z., 1988), which indicates the dependence of working capacity on the change of stress and stress-limiting neuroendocrine reactions.

Light desynchronosis disrupted the dynamics of indicators of physical performance. A preliminary exposure or deprivation of light caused a breakdown in adaptation to physical activity, expressed in a progressive decrease in the swimming time of rats. According to statistical analysis (paired multiple comparisons with the Friedman nonparametric test), the swimming dynamics of rats in the control group significantly differed from the swimming dynamics of animals kept under round-the-clock lighting (p = 0.003) or round-the-clock dimming (p = 0.05). In this case, physical fatigue in rats after exposure to light was more noticeable in comparison with the group that was in the dark. Thus, the data obtained indicate that in the spring, desynchronosis in the form of excessive exposure to light or darkness accelerated the development of physical fatigue in rats in a swimming test. Table 1 presents data on the physical performance of experimental animals when modeling chronic physical activity against the background of desynchronization of circadian biorhythms in the spring, Me (Q ₁ ; Q ₃ ). Note: p ₁ is the statistical significance of the differences compared with the first day of swimming.

Thus, the proposed method allows you to create a model, during the formation of which animals reach a state of fitness and resistance to stress. The resulting model adequately reflects the problems of sports physiology associated with the violation of adaptive reserves of the body due to transmeridian flights and subsequent sports training, and to a greater extent can serve to find ways and means of prevention and correction of sports overload and maladaptation.

Claims (1)

A method for simulating physical fatigue in rats under desynchronosis conditions, including providing a load by forced swimming of an animal in a tank of water, characterized in that the load is carried out in two stages: at the first stage, experimental desynchronosis is induced by keeping rats for 12 days around the clock with artificial lighting or in total darkness, after which the animals are forced to swim under natural light in a rectangular rectangular glass aquarium 100 cm × 100 cm × 20 cm, divided into compartments connecting at the bottom and equipped with two valves - one above and below one of the side walls, with a load fixed on the tail, whose weight is 10% of the animal’s body weight, at a temperature water 26 ° -28 ° C for 5 days until complete fatigue, the criterion of which are three unsuccessful attempts to surface or refusal of such attempts with lowering to the bottom.