RU2519725C2 - Method of assessment of action on animal organism of low intensity laser irradiation of blood - Google Patents

Abstract

FIELD: veterinary medicine.

SUBSTANCE: venous blood sampling from the animal is carried out prior to, during, and after the low intensity laser irradiation of blood, the plasma is obtained from it. In the thermostat the environment phase is prepared at a temperature equal to the body temperature of the animal and examined by the method of light microscopy. In case of destruction the impact is considered as excessive, and in case of ordering the structure - positive.

EFFECT: method enables to assess quickly and accurately the impact on the animal organism of low-intensity laser irradiation of blood.

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Description

The invention relates to the field of veterinary medicine, and in particular to a control method that ensures the prevention of negative effects on the body with low-intensity laser irradiation of animal blood.

It was established that in the process of low-intensity laser irradiation of blood, the activity of its constituent elements of red blood cells, white blood cells, platelets and plasma changes. However, the beneficial effect is within certain dose limits. Extreme dose limits vary among individuals within the species group. This is due to the different initial functional state of their organs and organ systems, including blood. In addition, pathological processes occurring in the body during the period of the disease have an additional effect that changes the course of metabolic processes, and, consequently, the functioning of all organs and their systems. Thus, the dose of laser exposure depends not only on the task assigned to the doctor (prevention or therapy of the existing pathology), but also on the initial functional state of the patient’s body. Therefore, the selection of the dose should be carried out individually. Based on the foregoing, it is optimal to monitor changes in the properties of blood plasma under the influence of low-intensity laser radiation, as a direct object of exposure, immediately after the exposure, and not to evaluate the delayed clinical effect in the future.

In humane medicine, several qualitative and quantitative biochemical methods for determining the therapeutic course dose of laser radiation are known.

Determining the state of the antioxidant system of blood serum, determining the activity of xanthine oxidase and catalase enzymes, the appearance of the phenomenon of “scarlet blood” with the intravenous method of laser therapy, monitoring the deformability of erythrocyte membranes during laser therapy [RU 2262106, C2, 10.10.2005].

All these methods, except for identifying the phenomenon of “red blood”, are not implemented in the wide practical activity of doctors because of their complexity, high cost, and significant delay in the results from the moment the material was taken. And the identification of the phenomenon of “red blood” can only be used for intravenous laser irradiation of blood.

A group of methods of structurally optical evaluation of blood serum under the action of laser radiation is also known.

Currently, in humane medicine there is a known method for evaluating the effectiveness of the use of combined drug-laser treatment [RU 2208461, C2, 07.20.2003]. When implementing the method, the liquid crystal structure is investigated in a model system with L- ^α- lecithin, 10% albumin in 0.9% sodium chloride and native body fluids after irradiation with a low-intensity laser, as well as with drug additives and in cases of their synergistic effect on the liquid crystal structure and native body environments recommend combined use. Structural-optical methods (refractometry, polarization photometry, and polarization microscopy) are used to study and evaluate the effect. In this case, the nature and amount of liquid crystal structures formed in dried blood serum, as well as their optical refractive indices, are estimated.

The disadvantages of this method is the difficulty associated with the need to use special equipment necessary for the implementation of refractometric and polarization-photometric microscopy for research. Another disadvantage is the difficulty of interpretation associated with the set of evaluation criteria used by the authors (small and medium structures of spherodendrites, lamellar, thin needle crystals, dendrites, concentration waves, birefringent and non-birefringent structures, oily grooves and liquid crystal lines and strands, spherulites, fan texture).

A known method of determining individual sensitivity to low-intensity laser exposure, including polarization-optical examination of blood plasma [SU 1635999, A1, 03/23/1991].

The disadvantage of this method is the duration of its implementation and the complexity of the implementation. Plasma crystallization occurs within 10-30 hours at a temperature of 17-30 ° C in the presence of a weak solution of lecithin deposited on a glass slide and a cover slip. The optical cells thus obtained are placed between crossed polarizers, and then the relative intensity of the light passing through them is determined by instrumentation. With a difference in blood plasma throughput of more than 15% before and after irradiation, the organism is susceptible to radiation.

A known method of selecting an individual laser therapy course for children [RU 2262106, C2, 10.10.2005]. The method is based on the determination of albumin test parameters (albumin binding capacity reserve and toxicity index) using a K-35 fluorescent albumin probe.

The disadvantage of this method is that the reagent kit manufactured by the company "Probe" (Moscow), "Probe-Albumin", including including a fluorescent albumin probe K-35, is currently not adapted for use in the study of animal blood. Also, when carrying out the analysis, it is necessary to use special equipment analyzer-fluorimeter ″ AKL-0.1 Probe ″. In addition, it is not always possible to control the intake of food by a specific individual on a farm at a group keeping of animals, while a blood test should be performed only on an empty stomach.

The closest in technical essence to the claimed invention is a method for determining the type of low-intensity radiation that effectively acts on the patient's body [RU 2173458, C1, 09/10/2001], including the study of blood serum placed in equal volumes in a set of tubes, which, in addition to the control, are irradiated with various types of low-intensity radiation, followed by storage for 18-20 hours at 5-8 ° C. After that, droplets with a volume of 0.01-0.03 ml from each tube are applied to the surface of a glass slide and dried at 20-30 ° C. Evaluation of the dried droplets is carried out using light microscopy. In the presence of the most pronounced radial sectors and nodules in a dry drop, in comparison with the control, the type of radiation optimally acting on the patient's body is determined before exposure.

The disadvantage of this method is that it determines the type of radiation that favorably affects the patient, but does not reveal the doses necessary to obtain a pronounced positive clinical effect from exposure not exceeding the maximum allowable. In addition, when preparing a dried drop of blood serum from animals with the indicated temperature regime, the drop dries out without cracking at all. An important minus is the duration of the test, which is at least 24 hours.

The technical result of the invention is a quick and simple assessment of the impact on the body of animals of low-intensity laser irradiation of blood.

This is achieved using the method of assessing the impact on the body of animals of low-intensity laser irradiation of blood.

The method is as follows. Venous blood is collected from an animal before, during and after low-intensity laser irradiation of blood, plasma is obtained from it, a facies is prepared in a thermostat at a temperature equal to the body temperature of the animal being examined, and examined by light microscopy; in the case of its destruction, they consider the impact excessive, and in the case of ordering the structure, positive.

Venous blood is taken from an animal of any kind before, during and after low-intensity laser irradiation of blood. The minimum amount of blood suitable for obtaining plasma sufficient for the study by the specified method is 1 ml. Plasma is obtained from blood according to the generally accepted technique. To prepare the facies using an automatic pipette-dispenser, a drop of blood plasma with a volume of 0.01 ml is applied to a clean slide. It is dried in a thermostat at a temperature equal to the body temperature of the animal being examined. Complete drying of a drop of blood plasma with the formation of a facies with a specific pattern occurs after 1-3 hours (depending on the temperature in the thermostat). The study of the facies is carried out using a light microscope with an increase in the lens 2.5-4x. As the changing structural elements of the facies, radial and transverse cracks, sectors, separately, and nodules are taken into account.

Therapeutically sound doses of laser radiation have a positive biostimulating effect on the body. However, doses exceeding therapeutic ones cause a decrease in the activity of enzyme systems, immunity, metabolic processes, and other negative changes in the body.

Researchers distinguish 3 phases of the action of laser energy on the body: the phase of adaptation, the phase of the therapeutic effect, the phase of the damaging effect.

The duration of each phase is individual for each organism. However, in the existing recommendations, methods and guidelines, the doses proposed for use vary greatly depending on the radiation power from 1.5 to 30 mW, the duration of exposure from 5 to 20 minutes and the therapeutic course of 5-10 days.

The phase of the damaging effect has clinical manifestations, delayed in time, but it is preceded by changes at the molecular level, the determination of which will allow the doctor to prevent the negative effect of laser radiation on the body.

To achieve this goal, we used the possibility of an integrated assessment of the state of the body’s metabolism based on determining changes in the crystallization properties of blood plasma. To assess the effect of low-intensity laser blood irradiation, a facies prepared from blood plasma was used. For this, blood was taken from the animal’s vein before laser irradiation, during and at the end of laser irradiation. Plasma was obtained from it according to the generally accepted technique. The preparation of the blood plasma facies was carried out by the modified method of wedge-shaped dehydration, which differs from the method known in humane medicine. In this case, a drop of plasma was used to prepare the facies, and not blood serum deposited on a glass slide. Its drying was carried out not at 18-30 ° C, but at a temperature equal to the body temperature of the examined animal. This is due to the fact that protein and other structures of blood plasma are adapted specifically to the physiological temperature of the animal’s body and can change their conformational properties when it decreases or increases. This fact affects the crystal lattice of the blood plasma facies formed during drying, and failure to take it into account will lead to errors in obtaining and subsequent interpretation of the research results. So, during the experiments it was noted that at a temperature of 18-30 ° C cracks in the facies of the blood plasma of cows can form weakly or even completely (Photo 1-2). In photo 1 - the complete absence of cracks in the facies of the blood plasma of a cow obtained at a temperature of 18 ° C. In photo 2 - the appearance of cracks in the facies of the blood plasma of a cow obtained at a temperature of 30 ° C.

Whereas at 39 ° C they form in full (Photo 3).

Using the method allows to simplify the selection of an individual dose of laser therapy for animals and to adapt it as much as possible to the working conditions of veterinary specialists.

Our proposed method for assessing the effect on the body during low-intensity laser irradiation of animal blood compares favorably with the known methods in that for the first time in veterinary medicine it was the adapted and modified for animals method of wedge-shaped dehydration of blood plasma.

The method successfully eliminates the disadvantages of the currently used methods and can be used for animals of any species. The method is simple to perform, effective, allows you to fully assess the state of the animal at the end of the laser therapy session. In addition, the implementation of the proposed method provides greater reliability of the results in relation to animals than the prototype taken as a basis, and provides a real possibility of execution when carrying out research in a production environment.

The novelty of the method lies in the fact that for the first time in veterinary practice, an animal-modified method of wedge-shaped dehydration of blood plasma was used to evaluate the effects on the body of animals with low-intensity laser blood irradiation.

Example

The experiment was carried out in SPH Agrofirm ″ Grachevskoye ″ Usman district of the Lipetsk region. The experiment involved clinically healthy cows whose quantitative and qualitative morphological and biochemical blood parameters were within the physiological boundaries characteristic of animals of this species. Cows were injected with intravenous and intravenous laser blood irradiation using a KLO4 laser emitting head with a power of 20 mW and VLOK with a power of 1.5 mW.

In animals, body temperature was measured. Then, before laser irradiation, in the process and at the end, blood samples were taken from the jugular vein and plasma was obtained from it. A facies was prepared from plasma, the structure of which was evaluated using light microscopy. Evaluation was carried out according to the following parameters: the shape, number and size of radial and transverse cracks, fragments and nodules, the nature of the edge wave rhythm.

It was found that in the cows selected for the experiment, the initial picture of the blood facies has differences in the shape, quantity and size of radial and transverse cracks, separate and nodules, and the nature of the edge wave rhythm. A sample view is shown in photo 4-5. Photo 4 shows the initial picture of the peripheral part of the blood plasma facies before irradiation. Photo 5 shows the initial picture of the central part of the blood plasma facies before irradiation.

During the irradiation, a gradual change in the structure of the blood plasma facies was noted with a tendency to the greatest structurability, symmetry, and a decrease in the amplitude of the edge wave rhythm (Photo 6-7). Photo 6 shows the optimal picture of the peripheral part of the blood plasma facies formed 7 minutes after the start of irradiation. Photo 7 shows the optimal picture of the central part of the blood plasma facies formed 7 minutes after the start of irradiation.

However, with large doses of radiation received by the animals, there was a general destruction of the picture of the blood plasma facies and complete destruction of the edge wave rhythm (Photo 8-9). Photo 8 shows the complete destruction of the edge wave rhythm, the general destruction of the picture of the blood plasma facies 15 minutes after the start of irradiation. Photo 9 shows a violation of the pattern of the central zone of the blood plasma facies 15 minutes after the start of irradiation.

Both the time of the onset of the best structurability and the time of the onset of destruction differed among the experimental animals, which indicates the need for individual dose selection.

One of the established criteria that objectively assess the influence of any factor, including low-intensity laser radiation on the body, are indicators of the body's antioxidant defense system and lipid peroxidation.

Table Indicators of the body's antioxidant defense system and lipid peroxidation Indicator SI before the experiment 20 mW, 5 minutes 20 mW, 7 minutes 20 mW, 15 minutes Catalase H ₂ O ₂ / L min 20.31 23,2 31.89 25.9 SOD UE / mg Hb 0.75 0.81 1.24 0.85 GPO μmol G-SH / l · min 10 ³ 9.87 11.3 14.37 11.85 GR μmol oxide. glut. / l · min 295.7 301.9 309.4 303.6 AOA plasma l · min ^-1 · 10 ^-3 1.38 1.41 1.87 1.51 DK units opt. S / mg 0.93 0.86 0.57 0.70 MDA mm / l 0.78 0.71 0.46 0.65

Changes in the dynamics of indicators of the body's antioxidant defense system have a directionally favorable upward trend, reaching a maximum value by 7 minutes of exposure. With continued irradiation, an unfavorable decrease in these indicators was noted at 15 minutes. The lipid peroxidation indices were in the opposite relationship and favorably decreased by the 7th minute of irradiation, after which they began to increase again.

Thus, changes in the dynamics of indicators of the body's antioxidant defense system and lipid peroxidation correlate in time with changes in the structure of the blood plasma facies.

The evolutionary mechanism of functioning of human protein systems and various animal species is characterized by a temperature regime. In humans, metabolic processes occur efficiently at 36-37 ° C. As the temperature rises to 41-42 ° C, both the structure and function of the proteins change, primarily the centers of regulation of vital activity, which cease to function, and then the proteins of other structures. In animals, the temperature stability of protein systems differs from humans and has intraspecific features. So, in cattle, proteins function most efficiently at a temperature of 39.5-40.5 ° C, and change their work at 42-43 ° C.

Based on the foregoing, it should be concluded that, with the help of our technical solution, the possibilities of veterinary specialists in assessing the effects on the body of animals with low-intensity laser irradiation of blood have been expanded.

The proposed method for assessing the effects on animals in animals with low-intensity laser blood irradiation was first used in veterinary medicine.

Based on the data obtained as a result of our research, we can conclude that the method is informative, easy to use, does not require special purchase of expensive equipment and can be carried out by a practicing veterinarian directly on the farm.

Claims (1)

A method for assessing the effect of low-intensity laser blood irradiation on an animal organism, characterized in that venous blood is collected from the animal before, during and after low-intensity laser blood irradiation, plasma is obtained from it, a facies is prepared in a thermostat at a temperature equal to the body temperature of the animal, and examine it by light microscopy; in the case of destruction, they consider the impact to be excessive, and in the case of ordering the structure, they are positive.

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