RU2619875C1 - Method for oxidative stress correction under conditions of ultraviolet irradiation - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: laboratory rats receive daily oral administration of the herb infusion of corn grassworm at a rate of 5 ml/kg of mass 20 minutes before exposure to ultraviolet rays, under ultraviolet irradiation conditions. The infusion is obtained by infusion of 5 g of herbs for 200 ml of boiling water for 60 minutes.

EFFECT: method provides oxidative stress correction based on reduced content of lipid peroxidation products in irradiated rats and increased activity of antioxidant system with a shortened phytocorrection course.

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Description

The invention relates to medicine, in particular to pharmacology, can be used to correct oxidative stress under ultraviolet radiation and find application in experimental medicine and clinical practice.

Activation of lipid peroxidation processes of biomembranes, disruption of the functioning of antioxidant defense systems lead to the formation of oxidative stress in the body, for the correction of which substances with a wide spectrum of antioxidant action are used. Known methods for the correction of oxidative stress and increase the antioxidant status of a warm-blooded organism under the influence of prooxidant factors by the introduction of synthetic preparations of antioxidant action - dibunol, tocopherol acetate [1, Mashkovsky MD, Medicines, 2010], emoxipine [2, Dorovskikh V.A. , Antioxidants in the prevention and correction of cold stress, 2000], Mexidol [3, Stepanova MS, author. dis. Cand. biol. Sciences, 2009]. The disadvantages of these methods are the need for the use of pharmacological preparations of synthetic origin, having a number of side and toxic effects and a relatively high cost.

A known method of correction of lipid peroxidation processes in the experiment, including irradiation of the xiphoid process of the sternum of white rats with electromagnetic waves of the terahertz range at frequencies of 150.176-150.664 GHz with a power density of 0.2 mW / cm ² for 30 minutes [4, RF Patent No. 2393891]. The disadvantage of this method is the mandatory availability of special equipment for irradiation with electromagnetic waves.

There is also known a method of correcting oxidative stress and impaired NO production of endothelial function in case of vascular complications of diabetes mellitus in an experiment, which includes a preliminary single dose administration of a 5% aqueous solution of alloxan to an organism of a rat on an empty stomach at a dose of 15 mg / kg of the animal, followed by the administration of the drug afobazole subcutaneously in 10 mg / kg of body weight once a day for 30 days at the background of daily administration of L-arginine, 10 mg / kg body weight or on the background of N ^G -methyl -nitroarginin Vågå ester (L-NAME) inhibitor of the enzyme NOS-3 at 25 mg / kg body weight [5, RF Patent №2521279]; a method for the treatment and prevention of oxidative stress in animals with the help of the microelement preparation chelavit, administered at a dose of 0.02 ml per 1 kg of animal weight for 30 days [6, RF Patent No. 2229793]; a method for the correction of oxidative stress in neuropsychiatric and mental disorders, including, in addition to basic therapy, the administration of carnosine in doses of 1.5 and 2.0 g / day for 30 days [7, Yarygina EG et al., Advances in Modern Natural Science, 2015, No. 4]. The disadvantage of this method is the significant duration of the correction course (30 days).

There is also a known method for the correction of oxidative and nitrosylating stress, including the introduction of a combination of drugs: antioxidant complex (ascorbic acid - 0.5 g in the table, alpha-tocopherol acetate - 100 mg in caps., Retinol acetate - 33000 ME in caps.) 5- 7 days inside by 2 doses, an inhibitor of the system of synthesis of nitric monoxide (pentoxifylline) 0.08% - 250 ml 5-7 days intravenously, phleboprotector and phlebotonic from the group of saponins (L-lysine escinate) 5 ml 5-7 days intravenously [ 8, Sushkov S.A. et al., Surgery News, 2010]; a method of nutritional correction (diets high in foods with antioxidant orientation) of oxidative stress in laboratory animals, which includes replacing 100 g of the grain mixture every other day with a mixture of cabbage 50 g, carrots 50 g, beets 25 g, apples 25 g, kiwi 10 g, pomegranate 10 g per 1 rabbit [9, A. Basov et al., Nutrition Issues, 2013]. The disadvantage of this method is the multicomponent measures of the course aimed at achieving therapeutic efficacy, which has a significant impact on pharmacoeconomic indicators.

There is also known a method for the correction of oxidative stress in critical conditions caused by massive blood loss and purulent-septic complications, accompanied by multiple organ failure, the use of ceruloplasmin (intravenous infusion at a dose of 500-1000 mg / day) for 4-6 days in combination with traditional therapy, Laprot drug based on human lactoferrin (infusion therapy at a dose of 50-100 mg / day, course dose 250-1000 mg) [10, Osipova N.A. et al., General Reanimatology, 2008, Vol. Iv]; A method for the correction of oxidative stress under ultraviolet radiation by intramuscular injection of arabinogalactan at a dose of 500 mg / kg [11, Li ON et al., Bulletin of Physiology and Respiratory Pathology, vol. 57]; a method for the correction of oxidative stress in the prevention and treatment of calf iron deficiency anemia under conditions of chronic incorporated exposure, including the intramuscular injection of a complex iron-dextran preparation ferranimal-75M on the 5th day of a calf’s life, at a dose of 3 ml, simultaneously with an intramuscular injection of a 10 ml hydropeptone preparation, while the injection of ferranimal-75M is repeated after 10 days at a dose of 2 ml, also simultaneously with the intramuscular injection of 5 ml of hydropeptone in different places [12, RF Patent No. 2535086]. The disadvantages of the methods are the mandatory compliance with the requirements for dosage forms for injection (sterility, pyrogen-free, lack of mechanical impurities, stability during manufacture and storage); the risk of infection through injection systems (hepatitis, HIV infection, etc.); risk of embolism due to ingress of particulate matter or air bubbles; soreness of the injection method of drug administration; the availability of special tools (syringe, system for infusion, etc.) and certain qualifications of medical personnel.

There is also a method of correcting the processes of lipid peroxidation (POL) of biomembranes under ultraviolet irradiation, including daily oral administration of laboratory animals an infusion of starfish grass at a rate of 5 ml / kg weight 20 minutes before exposure to ultraviolet rays for 14 days [13, RF Patent No. 2550016]. This technical solution was taken by us as a prototype.

The objective of the present invention was to expand the arsenal of tools that allow for the correction of oxidative stress against the background of increased activity of the antioxidant system of a warm-blooded organism under ultraviolet radiation, based on available domestic raw materials and to increase the persistent pharmacological effect in the face of a reduced rate of phytocorrection.

The problem is solved by developing a new method for the correction of oxidative stress under ultraviolet radiation by introducing the infusion of field bindweed grass (Convolvulus arvensis L.). Field bindweed is widespread in Russia, contains a wide range of biologically active substances (glycosides, vitamins C, E, flavanoids, saponins, enzymes, coumarins, proteins) [14, V. A. Dorovskikh et al., Medicinal plants of the Amur region, 2016]. The raw materials used for manufacturing are available, the production technology is cost-effective, and the range of applications is wide.

The essence of the invention lies in the fact that in a method for the correction of oxidative stress under ultraviolet irradiation, including daily oral administration of laboratory animal infusion of herbs at a rate of 5 ml / kg of body weight 20 minutes before exposure to ultraviolet rays, animals are infused with infusion of bindweed obtained by insisting for 60 minutes 5 g of raw materials per 200 ml of boiling water, while the duration of the course of phytocorrection is 6 days.

The implementation of the method. Experimental animals (rats or mice) under standard vivarium conditions, 20 minutes before exposure to the ultraviolet chamber [15, RF Patent No. 2348079], are infused daily with infusion of bindweed grass at the rate of 5 ml / kg weight for 6 days. On the 7th day of the experiment, the animals were killed by decapitation.

Preparation of infusion of bindweed herb. The bindweed grass was crushed, poured with boiling water at the rate of 5 g per 200 ml of water, infused for 60 minutes, filtered, the precipitate was removed, the infusion was cooled.

The results were taken into account by the ratio of lipid peroxidation products (lipid hydroperoxides, diene conjugates, malondialdehyde), the main components of the antioxidant system (AOS) - ceruloplasmin, vitamin E, glucose-6-phosphate dehydrogenase, catalase - in the blood plasma of rats of the experimental group in comparison with animals of the intact , the control group and the prototype group, processed by standard parametric methods using t-student criterion.

The method allowed for the correction of oxidative stress under ultraviolet irradiation, based on a decrease in the content of lipid peroxidation products in the body of irradiated rats and an increase in the activity of the antioxidant system, while reducing the duration of the course of phytocorrection to 6 days in comparison with the prototype.

The content of lipid peroxidation products in the blood plasma of intact rats, control groups, prototype groups and experimental animals was studied on the 7th day of the experiment (table 1). As a result of the studies, the content of lipid hydroperoxides in the blood of control (irradiated) animals was significantly higher by 24.3% relative to intact rats (p <0.01), diene conjugates - by 22.7% (p <0.01), malondialdehyde - by 28.6% (p <0.05), which indicates an increase in the intensity of peroxidation processes in the conditions of daily ultraviolet radiation on the 7th day of the experiment.

The level of lipid hydroperoxides in the blood plasma of rats treated with an infusion of bindweed grass was significantly lower by 12.2% than in the control (irradiated) group of animals (p <0.05), diene conjugates by 13.3% (p <0.05), malondialdehyde - by 27.8% (p <0.05). Comparing the results of studies of the content of lipid peroxidation products in the blood of animals of the experimental group with the prototype, it can be stated that the proposed method has a more pronounced effect on the stabilization of peroxidation processes: the level of lipid hydroperoxides in the blood plasma of experimental animals relative to rats of the prototype group is 5.0% lower than diene conjugates - by 4.2%, malondialdehyde - by 7.2%.

An increase in the intensity of LPO processes of biomembranes under ultraviolet irradiation is accompanied by a decrease in the activity of AOS components in the blood of irradiated animals compared to intact rats (table 2): the level of ceruloplasmin in the blood of control (irradiated) animals is lower by 18.6% (p <0.05) , vitamin E - by 18.7% (p <0.05).

In the blood of experimental animals, the content of ceruloplasmin was significantly higher by 19.8% compared with the control group of rats (p <0.05), the level of vitamin E - by 21.6% (p <0.05). A comparative evaluation of the results of the study of the activity of AOS components in the blood of animals of the experimental group and the prototype group shows a more pronounced increase in antioxidant status in the conditions of the introduction of infusion of bindweed (ceruloplasmin content is higher by 6.4%, vitamin E - by 12.6%).

The activity of AOS enzymes under ultraviolet irradiation changes according to the nature of the variability of the main components at the end of the experiment (table 3): the activity of glucose-6-phosphate dehydrogenase in the blood of control rats is 13.5% lower relative to the intact group (p <0.05), and catalase - 15.9% (p <0.01).

The activity of glucose-6-phosphate dehydrogenase in the blood of the experimental group of animals was significantly higher by 14.1% compared with the control (p <0.05), catalase - by 13.2% (p <0.05). The comparative effectiveness of the infusion of bindweed grass and the infusion of stellate grass (prototype) indicates the predominant activating effect on the state of the antioxidant system in the claimed method.

Thus, the stabilizing effect of the infusion of bindweed grass on the LPO processes of biomembranes under ultraviolet irradiation has been experimentally established, based on a decrease in the content of peroxidation products and an increase in the activity of the main components of AOS in the blood of irradiated animals, which gives reason to recommend the infusion for use to correct oxidative stress against the background of ultraviolet exposure.

In general, based on the obtained experimental results, the proposed method (the introduction of infusion of bindweed grass) provides a reduction in the duration of the course of correction of oxidative stress under ultraviolet radiation up to 6 days in comparison with the prototype, showing a more pronounced pharmacological (antioxidant) effect.

The technical result of using the invention is to reduce the duration of the course of correction of oxidative stress under ultraviolet radiation up to 6 days in comparison with the prototype under the conditions of oral administration of infusion of bindweed grass with antioxidant activity.

INFORMATION SOURCES

1. Mashkovsky M.D. Medicines: a manual for doctors. - M .: Medicine, 2010 .-- 685 p.

2. Dorovskikh V.A., Borodin E.A., Tseluyko S.S. Antioxidants in the prevention and correction of cold stress. - Blagoveshchensk, 2000 .-- 183 p.

3. Stepanova M.S. Correction of oxidative stress of the brain using natural and synthetic antioxidants: abstract. dis. Cand. biol. sciences. - Moscow, 2009 .-- 24 p.

4. Kirichuk V.F., Tsymbal A.A., Krenitsky A.P., Mayborodin A.V. A method for correcting lipoperoxidation processes in an experiment. - RF patent for invention No. 2393891. - Posted: 07/10/2010.

5. Dzugkoeva F.S., Takoeva E.A., Dzugkoev S.G. A method for correcting oxidative stress and impaired NO producing endothelial function in vascular complications of diabetes mellitus in an experiment. - RF patent for invention No. 2521279. - Posted: 06/27/2014.

6. Bakhta A.A., Ryzhov A.A. et al. A method for the treatment and prevention of oxidative stress in animals. - RF patent for invention No. 23239793. - Posted: 07/27/2008.

7. Yarygina EG, Prokopyeva VD, Bohan N.A. Oxidative stress and its correction with carnosine // Successes in modern science. - 2015. - No. 4. - S. 106-113.

8. Sushkov S.A., Nebylitsin Yu.S., Solodkov A.P. Correction of oxidative and nitrosylating stress in patients with deep vein thrombosis of the lower extremities // Surgery News. - 2010. - T. 18, No. 1.

9. Basov A.A., Bykov I.M. Change in the antioxidant potential of blood in experimental animals with nutritional correction of oxidative stress // Nutrition Issues. - 2013. - No. 6.

10. Osipova N.A., Edeleva N.V., Yakubovskaya R.I., Nemtsova E.R., Chissov V.I. Oxidative stress in critical conditions and its correction // General resuscitation. - 2008. - No. IV (2). - S. 98-102.

11. Lee O.N., Dorovskikh V.A., Simonova N.V. Correction of oxidative stress by arabinogalactan under ultraviolet radiation // Bulletin of physiology and respiratory pathology. - 2015. - Issue. 57. - S. 65-69.

12. Sodboyev Ts. Ts., Antipov A.A., Deltsov A.A. A method for the correction of oxidative stress in the prevention and treatment of iron deficiency anemia in calves under conditions of chronic incorporated exposure. - RF patent for invention No. 2535086. - Posted: 12/10/2014.

13. Simonova N.V., Dorovskikh V.A., Lee O.N., Anokhina R.A., Dorovskikh V.Yu. A method for the correction of lipid peroxidation processes of biomembranes under ultraviolet radiation. - RF patent No. 2550016. - Posted: 01/27/2015.

14. Dorovskikh V.A., Simonova N.V., Anokhina R.A. Medicinal plants of the Amur region: a training manual. - Blagoveshchensk, 2016 .-- 266 p.

15. Dorovskikh V.A., Simonova N.V. Method and device for experimental modeling of activation of lipid peroxidation processes of biological membranes. - RF patent for invention No. 2348079. - Posted: 02/27/2009, bull. No. 6.

Claims (1)

A method for correcting oxidative stress under ultraviolet irradiation, including daily oral administration of laboratory animals an infusion of grass at a rate of 5 ml / kg of weight 20 minutes before exposure to ultraviolet rays, characterized in that the infusion is obtained by infusing 5 g of field bindweed grass for 60 minutes ml of boiling water.