Bioscience Biotechnology Research Communications

An International  Peer Reviewed Refereed Open Access Journal

P-ISSN: 0974-6455 E-ISSN: 2321-4007

Bioscience Biotechnology Research Communications

An Open Access International Journal

Valery P. Kartashev

Russian State Social University, 129226, Moscow, Russia

Corresponding author email: ilmedv1@yandex.ru

Article Publishing History

Received: 08/04/2020

Accepted After Revision: 21/05/2020

ABSTRACT:

Objective: to establish changes in the micro-rheological properties of red blood cells in rats under conditions of inactivity. The experiment was   undertaken for  34 healthy outbred male rats of six months  age. Prior to inclusion in the study, all rats were healthy and did not participate in any earlier studies.  Animals were placed in narrow cages for 1 month to minimize their movements.  The control group consisted of 32 healthy outbred male rats of a similar age. The work was performed using biochemical, hematological and statistical research methods. In rats under hypodynamic conditions, an increase in the free radical oxidation of plasma lipids and red blood cells was noted.  As the duration of hypodynamia in the blood of rats increased, the number of erythrocytes-discocytes decreased, which was most pronounced after a month of observation.  This was accompanied by an increase in their blood levels of altered reversibly and irreversibly erythrocyte forms and an increase in spontaneous aggregation of red blood cells. In rats under hypodynamic conditions, a gradual decrease in the level of antioxidant protection of plasma develops.  Aggregation readiness and the degree of change in the surface properties of red blood cells increased in these rats.  These changes create a risk in animals of increasing morbid burden and weakening of the whole organism in relation to the negative environmental influences.

KEYWORDS:

Rats, Physical Inactivity, Red Blood Cells, Cytoarchitectonics, Aggregation

Download this article as:

Copy the following to cite this article:

Kartashev V. P. The State of Micro-Rheological Properties of Red Blood Cells in Rats on the Background of Physical Inactivity. Biosc.Biotech.Res.Comm. 2020;13(2).


Copy the following to cite this URL:

Kartashev V. P. The State of Micro-Rheological Properties of Red Blood Cells in Rats on the Background of Physical Inactivity. Biosc.Biotech.Res.Comm. 2020;13(2). Available from: https://bit.ly/3cT9Eyw

Copyright © Kartashev This is an open access article distributed under the terms of the Creative Commons Attribution License (CC-BY) https://creativecommns.org/licenses/by/4.0/, which permits unrestricted use distribution and reproduction in any medium, provide the original author and source are credited.


INTRODUCTION

Systematic experiments in science allow us to solve various problems of the reaction of the mammals to the influence of the external environment, (Zavalishina, 2018a; Vatnikov et al., 2019).  The implementation of any processes in the body is associated with the activation of biochemical and functional (Usha et al., 2019; Lenchenko et al., 2019) programs under the influence of external factors (Zavalishina, 2018b; Zavalishina, 2018c). This helps the body to adapt, while maintaining viability in any conditions (Skoryatina and  Medvedev, 2019; Vorobyeva and  Medvedev, 2019).  The dynamics of the rheological parameters of blood and especially its shaped elements, which change under many functional conditions and effects on the body, is very important for maintaining the life support of the body (Zavalishina, 2018d; Bikbulatova, 2018a).Red blood cells are a particularly significant element of the microcirculation process, which,  by changing their cytoarchitectonics and degree of aggregation, can regulate hemodynamics and metabolism in tissues and, thus, the course of all adaptive processes in the body (Stepanova et al., 2018;Medvedev, 2019).

It was established that the rheological parameters of red blood cells change against the background of physiological and pathological processes (Zavalishina, 2018e).  Moreover, strong effects on the body can worsen the properties of red blood cells and, thus, the microcirculation process in organs, exacerbating the course of pathology (Zavalishina et al., 2019).In the process of studying the body’s reactions to various environmental effects on humans (Makhov, Medvedev, 2019), it is difficult to do without evaluating biological processes in an experiment on laboratory animals.  Given the importance of erythrocyte rheological parameters for the development of many dysfunctions (Vorobyeva and  Medvedev, 2020a) and diseases (Glagoleva and  Medvedev, 2020), it is important to study the dynamics of aggregation and cytoarchitectonics of erythrocytes in rats exposed to adverse environmental conditions (Oshurkova and  Medvedev, 2018a).  This information can serve as a basis for a further search for experimental approaches to optimize the rheological characteristics of red blood cells in conditions of low physical activity of the body, including space flight (Oshurkov and  Medvedev, 2018b; Vorobyeva and  Medvedev, 2020b).The  goal  of the present study was set to establish changes in the micro-rheological properties of red blood cells in rats under conditions of inactivity.

 MATERIAL AND METHODS

This study was carried out in full compliance with the ethical standards outlined by the European Convention for the Protection of Vertebrate Animals, which are used for experimental and other scientific purposes (adopted in Strasbourg on 03/18/1986 and confirmed in Strasbourg on 06/15/2006).The study took 34 healthy outbred male rats at the age of 6 months.  They were placed in narrow individual cells, excluding free movement of animals for 1 month.  Prior to inclusion in the study, all rats were healthy and did not participate in the studies.

The control group consisted of 32 healthy outbred male rats at six months of age.  Rats were obtained at the age of two months from the laboratory animal nursery of the Branch of the Institute of Bioorganic Chemistry of the Russian Academy of Sciences.  Prior to the experiment, the rats were under vivarium conditions in spacious cages (the cell area per rat was 200 cm2).  Throughout the time, natural lighting was used, the temperature was maintained at 18-22 ºС, the relative humidity was kept at the level of 50-65%.  Prior to being taken into the experiment and in its process, all animals received a full-ration ration from compound feed for laboratory animals of the PK-120 brand (Laboratorykorm, Russia).  Rats had free access to water throughout the experiment.

 RESULTS AND DISCUSSION

The initial values ​​in experimental rats and in the control group were comparable.  Under conditions of physical inactivity in rats, an increase in the external manifestations of a deterioration in their general condition was noted — tarnishing and thinning of the coat, a decrease in interest in the environment, and a decrease in appetite.  With an increase in the duration of inactivity in rats, an increase in body weight was found, which amounted to 269.5±4.86 g by the end of the observation. At the same time, a decrease in their endurance level was revealed in the test of forced swimming with weights – after a month of inactivity by 43.9% (table).

Table 1. Showing some haematological  parameters of  the rats  under investigation  compared with well Matched controls Legend: reliability of differences in indicators between control and aging rats – *<0.05;  **- p<0.01.

Indicators Rats in conditions of physical inactivity, M±m Control,

n=32, M±m

Exodus,

n=34

2 weeks,

n=34

4 weeks,

n=34

Body mass, g 232.4±3.26 248.5±4.27 269.5±4.86* 232.4±4.96
Swimming time, s 158.3±2.16* 136.2±3.32* 110.0±3.04** 161.2±3.62
Acyl hydroperoxides plasma, D233/1 ml 1.46±0.016 1.71±0.012* 1.89±0.025** 1.45±0.009
Thiobarbituric acid products, μmol/l 3.38±0.018 3.97±0.019* 4.23±0.027** 3.42±0.014
Antioxidant activity, % 36.0±0.30 31.3±0.24 28.2±0.23* 35.1±0.07
Erythrocyte acyl hydroperoxides,

D233/1012 erythrocyte

2.82±0.017 3.52±0.012* 4.12±0.024** 2.82±0.015
Erythrocyte malondialdehyde,

nmol/1012 erythrocyte

1.10±0.013 1.37±0.011* 1.58±0.012** 1.11±0.010
Erythrocyte catalase, ME/1012 erythrocyte 8850.0±12.9 8000.0±13.6* 7100.0±19.8** 8960.0±16.2
Erythrocyte superoxide dismutase,

IU/1012 erythrocyte

1590.0±7.16 1470.0±8.23* 1320.0±6.35** 1650.0±13.15
Discocytes, % 84.2±0.14 77.1±0.16* 71.4±0.17** 84.1±0.14
Reversibly altered red blood cells, % 9.5±0.12 11.8±0.07* 15.0±0.09** 9.5±0.11
Irreversibly altered red blood cells, % 6.3±0.07 11.1±0.13** 13.6±0.12** 6.4±0.12
The amount of red blood cells included in the aggregates 31.2±0.15 37.2±0.14* 42.6±0.08** 30.2±0.06
Number of units 6.3±0.09 7.0±0.12* 8.2±0.08** 6.1±0.05
The number of free red blood cells 292.3±0.18 257.0±0.26* 229.2±0.29** 292.8±0.22

In rats in a state of physical inactivity, an increase in the activity level of free radical oxidation processes in plasma lipids was found (the level of acylhydroperoxides and thiobarbituric acid-active products increased by 29.4% and 25.1%, respectively) with a decrease in antioxidant activity by 27.6%. Comparable changes in lipid peroxidation in experimental rats were noted in red blood cells — the number of acyl hydroperoxides and malondialdehyde in them increased.  After 4 weeks of inactivity, their number in rats prevailed over the outcome by 46.1% and 43.6%, respectively.  The activity of erythrocyte catalase and superoxide dismutase in rats decreased by 24.6% and 20.4% in 4 weeks of inactivity, respectively (Table 1).

Under conditions of physical inactivity in the blood of experimental rats, a decrease in the level of erythrocyte-discocytes to 71.4±0.17% after a month of observation was observed, which led to a gradual increase in their level of changed reversibly and irreversibly erythrocyte forms by 57.9% and 2.1  times. In rats under conditions of physical inactivity, a gradual increase in erythrocyte aggregation was revealed with an increase in their number in the composition of the aggregates and the number of aggregates themselves with a decrease in the blood level of unaggregated red blood cells (229.2 ± 0.29), compared with the level of control and outcome (table).

Any indicators of the body that are significant for its viability respond to the influence of adverse factors from the external environment (Mal et al., 2018).  Of great importance in this is the reaction to the action of the hemostatic and rheological characteristics of the blood (Vorobyeva, Medvedev, 2018). It is they who largely determine the volume of tissue perfusion, and, consequently, their trophic (Bikbulatova, 2018b; Boldov et al., 2018). For successful microcirculation, the parameters of the shaped elements, which are controlled by the vessel walls (Zavalishina, 2018f) and lipid peroxidation processes (Karpov et al., 2018), are very important.

It was found that in rats under conditions of physical inactivity, the antioxidant activity of plasma weakens, leading to an increase in the level of acyl hydroperoxides and thiobarbituric acid-active products in it.  High lipid peroxidation in plasma damages the walls of blood vessels and the outer surfaces of erythrocyte membranes, negatively affecting their state (Vorobyeva et al., 2018).  Moreover, in red blood cells of rats experiencing physical inactivity, the antioxidant defense weakens, which stimulates lipid peroxidation processes in them.High lipid peroxidation in the plasma and in the erythrocytes violates the structural and functional characteristics of membranes and protein of the cytoskeleton of red blood cells. With increased peroxide oxidation of lipids in erythrocytes occurs the weakening of the synthesis of ATP, lowering the activity of ion pumps that in these circumstances, no longer cope with the removal of the erythrocyte cytoplasm of excess Ca2+ and Na+ and are unable to maintain an optimum level of K+ (Mal et al., 2018).

In these circumstances, in the blood of rats develops a gradual increase in the number of red blood cells that do not have a biconcave shape. The resulting changes in the red blood cells ensures the growth of content in their blood reversible and irreversible changes of their species. So, the animals in the conditions of inactivity by increasing the level of red blood cells in a state of echinocytosis with very variable form and changed to stomatita having the form of a one-sided full drive. Further transformation of these red blood cells rapidly leads to the appearance of steroidica, serotoninocytes and in the end of spherocyte, which in a short time is lysed.

Found in rats in conditions of hypodynamy increased aggregation of red blood cells is provided by the emerging changes in the magnitude of the charge of their membranes due to active degradation on the surface part of glycoproteins as a result of the excess products of lipid peroxidation. Increased synthesis of reactive oxygen species in rats in conditions of hypodynamia causes oxidative alteration of erythrocyte membranes and plasma damage to plasma proteins, having the ability to link with each other erythrocytes in the process of aggregation. In addition, the increasing lipid peroxidation in plasma and in red blood cells impairs the ability of erythrocytes to disaggregate due to the large force of red blood cells in aggregates and increase the speed of the process (Makhov, Medvedev, 2018).

The increase in the number of free aggregates in rat blood under conditions of physical inactivity contributes to damage to the vascular endothelium, which contributes to greater contact of the subendothelium and blood with activation of hemostasis due to this process, significantly worsening hemodynamics in the capillaries (Bikbulatova, 2018a). An increase in the number of aggregates in the blood of experimental rats can impede blood flow in parts of small vessels and in their vasa vasorum, which causes degeneration of the vessel walls and weakening of the synthesis of disaggregants in the vessels, providing control over the aggregation of red blood cells (Zavalishina,  (2018e;  Zavalishina et al., 2019).

 CONCLUSION

In rats under hypodynamic conditions, a gradual weakening of the plasma antioxidant defense occurs.  This is accompanied in rats by an increase in its levels of lipid peroxidation products.  As a result, the alteration of the outer membranes of red blood cells is enhanced in animals, increasing the number of their altered forms.  In rats under conditions of inactivity, the ability to aggregate also increased and the number of red blood cells in the blood increased.  This is very important for reducing the resistance of animals to animals with low physical activity, which makes them very sensitive to the influence of any negative environmental factors.

REFERENCES

Bikbulatova, A.A. (2018a) Creating Psychological Comfort In Women Who Wear Corrective Clothing For A Long Time. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 1112-1121.

Bikbulatova, A.A. (2018b) Functional Features Of Microcirculatory Processes In Obese Women Against A Background Of Long Daily Wearing Of Corrective Clothing. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 785-793.

Boldov, A., Karpov, V. and Gusev, A. (2018) Study on the level of physical development and physical fitness in students of university of psychology and education. 34th International Scientific Conference on Economic and Social Development / 18th International Social Congress (ISC).  Moscow, RUSSIA. International Scientific Conference on Economic and Social Development, 354-366.

Chevari, S., Andyal, T. and Shtrenger I. (1991) Determination of antioxidant blood parameters and their diagnostic value in old age.  Laboratory work, 10 : 9-13.

Glagoleva, T.I. and Medvedev, I.N. (2020) Physiological features of aggregation of the main formed elements of blood in calves at the beginning of early ontogenesis 00161. Published online: 28 February 2020. DOI: https://doi.org/10.1051/bioconf/20201700161

Karkishchenko, V.N., Kapanadze, G.D., Dengina, S.E. and Stankova, N.V. (2011) Development of a methodology for assessing the physical endurance of small laboratory animals to study the adaptive activity of certain drugs.  Biomedicine, 1 : 72-74.

Karpov, V.Yu., Pilosyan, N.A., Stepanova, O.N. and  Bakulina, E.D. (2018) Physical rehabilitation of preschoolers with cerebral paralysis by means of hippotherapy. International Conference on Research Paradigms Transformation in Social Sciences.  Tomsk Polytechn Univ, Tomsk, RUSSIA.  European Proceedings of Social and Behavioural Sciences, 35 : 529-535.

Lenchenko, E.M., Vatnikov, Yu.A., Kulikov, E.V., Lozovoy, D.A., Gavrilov, V.A., Gnezdilova, L.A., Zimina, V.N., Kuznetsov, V.I., Annikov, V.V., Medvedev, I.N., Petryaeva, A.V. and Glagoleva, T.I. (2019) Aspects of Salmonellosis pathogenesis using chicken models. . Bali Medical Journal, 8(1) : 206-210. DOI:10.15562/bmj.v8i1.920

Makhov, A.S. and Medvedev, I.N. (2018) The Effect Of Regular Physical Activity On The Functioning Of The Nervous System. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 794-798.

Makhov, A.S. and Medvedev, I.N. (2019) Functional characteristics of children with Down syndrome and possibilities of their correction with the help of athletic activity in Russia. Bali Medical Journal, 8(2) : 587-591. DOI: 10.15562/bmj.v8i2.1097

Mal, G.S., Kharitonov, E.L., Vorobyeva, N.V., Makhova, A.V. and Medvedev, I.N. (2018) Functional Aspects Of Body Resistance. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 60-65.

Mal, G.S., Vorobyeva, N.V., Makhova, A.V., Medvedev, I.N. and Fayzullina, I.I. (2018) Features Of Physical Rehabilitation After Myocardial Infarction. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 280-285.

Medvedev, I.N. (2019) Physiological peculiarities of thrombocyte activity of candidates into masters of sports in athletics of preadult age. Bali Medical Journal, 8(3): 635-639. DOI: 10.15562/bmj.v8i3.1090

Oshurkova, Ju.L. and Medvedev, I.N. (2018a) Physiological Indicators Of Platelets In Ayrshire Calves During The Dairy Feeding Phase. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 171-176.

Oshurkova, Ju.L. and Medvedev, I.N. (2018b) Functional Features Of Platelets In Newborn Calves Ayrshire Breed. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 313-318.

Skoryatina, I.A. and Medvedev, I.N. (2019) Correction of aggregation level of basic regular blood elements in patients with hypertension and dyslipidemia receiving rosuvastatin and non-medicinal treatment. Bali Medical Journal, 8(1) : 194-200. DOI:10.15562/bmj.v8i1.648

Stepanova, O.N., Stepanova, D.P., Pirogova, A.A. and Karpov, V.Yu. (2018) Women’s weight lifting as sport discriminated against on grounds of gender. International Conference on Research Paradigms Transformation in Social Sciences.  Tomsk Polytechn Univ, Tomsk, RUSSIA. European Proceedings of Social and Behavioural Sciences, 35 : 1325-1332.

Usha, B.V., Zavalishina, S.Y., Vatnikov, Y.A., Kulikov, E.V., Kuznetsov, V.I., Sturov, N.V., Kochneva, M.V., Poddubsky, A.A., Petryaeva, A.V. and Glagoleva, T.I. (2019) Diagnostics of early dysfunctions of anticoagulant and fbrinolytic features of rats’ vessels in the course of metabolic syndrome formation with the help of fructose model. Bali Medical Journal, 8(1) : 201-205. DOI:10.15562/bmj.v8i1.923

Vatnikov, Yu., Rudenko, A., Rudenko, P., Kulikov, Ev., Karamyan, A., Lutsay, V., Medvedev, I., Byakhova, V., Krotova, E. and Molvhanova, M. (2019) Immune-inflammatory concept of the pathogenesis of chronic heart failure in dogs with dilated cardiomyopathy. Veterinary World, 12(9) : 1491-1498.

Volchegorsky, I.A., Dolgushin, II, Kolesnikov, O.L. and Tseilikman, V.E. (2000) Experimental modeling and laboratory assessment of adaptive body reactions.  Chelyabinsk,  167.

Vorobyeva, N.V. and Medvedev, I.N. (2018) Physiological Features Of Platelet Functioning In Calves Of Holstein Breed During The Newborn. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 129-135.

Vorobyeva, N.V. and Medvedev, I.N. (2019) Functional activity of platelets in new-born calves of black-marked breed. Bulgarian Journal of Agricultural Science, 25(3) : 570-574.

Vorobyeva, N.V. and Medvedev, I.N. (2020a) Platelet function activity in black-motley calves during the dairy phase 00167. Published online: 28 February 2020. DOI: https://doi.org/10.1051/bioconf/20201700167

Vorobyeva, N.V. and Medvedev, I.N. (2020b) Functional platelet activity in Dutch newborn calves. IOP Conference Series: Earth and Environmental Science. 421 (2020) 022042. doi:10.1088/1755-1315/421/2/022042

Vorobyeva, N.V., Mal, G.S., Zavalishina, S.Yu., Glagoleva, T.I. and Fayzullina, I.I. (2018) Influence Of Physical Exercise On The Activity Of Brain Processes. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(6) : 240-244.

Zavalishina, S.Y., Vatnikov, Y.A., Kulikov, E.V., Kubatbekov, T.S., Vilkovysky, I.F., Petrov, A.K., Tishchenko, A.L., Drukovsky, S.G., Zharov, A.N., Grishin, V.N. and Glagoleva, T.I. (2019) Effect of a combination of arterial hypertension and insulin resistance on hemostasis activity. Bali Medical Journal, 8(1): 211-215. DOI:10.15562/bmj.v8i1.1151

Zavalishina, S.Yu. (2018a) Functional Properties Of Anticoagulation And Fibrinolysis In Calves Of Plant Nutrition. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(5) : 1082-1087.

Zavalishina, S.Yu. (2018b) Functional Antiaggregatory Properties Of Blood Vessels In Calves During Transition From Dairy To Plant Type Of Nutrition. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(5) : 1110-1116.

Zavalishina, S.Yu. (2018c) Physiological Features Of Vascular Hemostasis In Calves Of Dairy-Vegetative Food. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(5) : 1137-1143.

Zavalishina, S.Yu. (2018d) Functional Features Of Platelets In Newborn Calves With Iron Deficiency. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(5) : 1153-1158.

Zavalishina, S.Yu. (2018e) Functional Activity Of Plasma Hemostasis In Neonatal Calves With Iron Deficiency, Who Received Ferroglucin And Glycopin. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(5) : 1186-1191.

Zavalishina, S.Yu. (2018f) Physiology Of Vascular Hemostasis In Newborn Calves. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(5) : 1037-1044.