An evaluation of the biological action of increased doses of EMI in the UV range on the functional state and productivity of sheep

The effect of increased UV-radiation doses modeling 25 and 50% of ozone layer depletion on sheep's organisms was studied in the field experiment. The character of changes in animal organisms was found to depend on irradiation doses, sensitivity of individual system of living organism to electromagnetic radiation and physiological peculiarities of protection.     

Free thymidine in the blood serum of irradiated rats with different levels of cellular depletion of the thymus and spleen

The levels of the postirradiation thymidinemia, with an equal degree of the proceeding cell depletion of lymphoid organ tissues caused by the administration of dexamethasone and exposure of rats to 3 Gy radiation, markedly varied. Three days after the injection of the hormone, the organism responded to irradiation by an increase in the concentration of thymidine in blood serum in the same manner as intact animals did. The preirradiation with a dose of 3 Gy reduced sharply the ability of the organism to respond the repeated irradiation (after 3 days) by thymidinemia. There was a lesser increase in the thymidine concentration in the blood after the injection of dexamethasone than after irradiation inducing the same cell depletion of the thymus and spleen.     

Capillary electrophoresis method optimized with a factorial design for the determination of glutathione and amino acid status using human capillary blood

Plasma aromatic and sulfur containing amino acids are good indicators of protein anabolism/catabolism, while blood reduced and oxidized glutathione reflect oxidative status in an organism. Using a full factorial design for screening important variables (pH, concentration, temperature) we developed a capillary zone electrophoresis method permitting their measurements in the single run, without any derivatization procedures. The best separations were obtained within less than 30min employing a 10mmol/l phosphate buffer, pH 2.8, 18 degrees C, 15kV voltage. Fairly good precision with a linear relationship between peak area and concentrations (r=0.995-0.999) were obtained. The method was used to analyze human capillary blood.     

A combined micro-resonance Raman and absorption set-up enabling in vivo studies under varying physiological conditions: The nerve globin in the nerve cord of Aphrodite aculeata

We hereby report on the design of a set-up combining micro-resonance Raman and absorption spectroscopy with a microfluidic system. The set-up enabled us to study the nerve globin of Aphrodite aculeata in the functional isolated nerve cord under varying physiological conditions for extended periods of time. The oxygenation cycle of the organism was triggered by utilizing the microfluidic system that allowed for a fast switch between aerobic and anaerobic conditions. The nerve globin was found to very easily shift from a penta-coordinated high spin ferrous form to the oxy state upon a change from anaerobic to aerobic conditions. The observed fast reaction to varying O(2) concentrations supports an oxygen-carrying and/or -storing function of the nerve globin. In addition, by combining resonance Raman and absorption spectroscopy, the physiological response could be distinguished from light-induced effects.     

Coupled evolution of digestive,respiratory, circulatory,and excretory systems: A model investigation

A model is developed of evolution of an organism with digestive, respiratory, circulatory, and excretory systems as the single system. The model is realized on the basis of the language STEL-LA 8.0. A balance is found between perfection of each individual physiological system and necessary energy expenditures for survival of the organism as a whole. The model is based on a coupled development of several visceral systems. There is analyzed effect of a change of consumption of substances with food and of oxygen amount on their oxidation, a branching of blood flow to organs, specifically to kidneys, to excrete final products of metabolism from blood. The energy expenditures for circulation are believed to be proportional to blood flow in a given organ. An increase of efficiency of renal excretion from blood of final metabolic products and toxic substances has a favorable effect on inner medium and activity of each cell of an individual, but increases the organism energy expenditures. Interrelation of these factors under conditions of adaptation to changing environmental conditions determines peculiarities of evolution of each physiological system in an individual.     

Adenovirus-mediated gene transfer into the brain stem to examine cardiovascular function: role of nitric oxide and Rho-kinase

The central nervous system plays an important role in the regulation of blood pressure via the sympathetic nervous system. Abnormal regulation of the sympathetic nerve activity is involved in the pathophysiology of hypertension. In particular, the brain stem, including the nucleus tractus solitarii (NTS) and the rostral ventrolateral medulla (RVLM), is a key site that controls and maintains blood pressure via the sympathetic nervous system. Nitric oxide (NO) is a unique molecule that influences sympathetic nerve activity. Rho-kinase is a downstream effector of the small GTPase, Rho, and is implicated in various cellular functions. We developed a technique to transfer adenovirus vectors encoding endothelial nitric oxide synthase and dominant-negative Rho-kinase into the NTS or the RVLM of rats in vivo. We applied this technique to hypertensive rats to explore the physiological significance of NO and Rho-kinase.     

Insulin function in rats at early terms after 4 Gy whole-body irradiation

In the present study we made an attempt to estimate changes of insulin function at early terms after external irradiation of rats. Experimental conditions: male albino rats were studied 7; 14; 21; 28 days after the external whole-body gamma-irradiation (137Cs; 4 Gy). For this purpose the kinetics of 125I-insulin disappearance from blood plasma was investigated. Simultaneously dynamics of insulin blood concentration was studied in practically full and fasting animals. On the basis of the data received the following basic pharmacokinetic parameters were designed according to the two-compartmental model: central and peripheral compartment volumes, transfer and elimination rates, turnover and metabolic clearance rates. No substantial changes in insulin clearance were found compared to controls in all the postirradiation terms investigated. Hence, the changes in the turnover rate of insulin are proportional to blood hormone concentration. The significant increase of concentration and turnover was observed only 7 days after irradiation in rats with free access to food. The data received suggest that the insulin function of a pancreas in an organism exposed to a 4 Gy dose is maintained at a level sufficient for ensuring adequate regulation of the glucose homeostasis and of the carbohydrate metabolism.     

Developmental and Stress-Induced Remodeling of Cell–Cell Communication in the Adrenal Medullary Tissue

The adrenal medullary tissue contributes to maintain body homeostasis in reaction to stressful environmental changes via the release of catecholamines into the blood circulation in response to splanchnic nerve activation. Accordingly, chromaffin cell stimulus-secretion coupling undergoes temporally restricted periods of anatomo-functional remodeling in response to prevailing hormonal requirements of the organism. The postnatal development of the adrenal medulla and response to stress are remarkable physiological situations in which the stimulus-secretion coupling is critically affected. Catecholamine secretion from rat chromaffin cells is under a dual control involving an incoming initial command arising from the sympathetic nervous system that releases acetylcholine at the splanchnic nerve terminal-chromaffin cell synapses and a local gap junction-mediated intercellular communication. Interestingly, these two communication pathways are functionally interconnected within the gland and exhibit coordinated plasticity mechanisms. This article reviews the physiological and molecular evidence that the adrenal medullary tissue displays anatomical and functional adaptative remodeling of cell–cell communications upon physiological (postnatal development) and/or physiopathological (stress) situations associated with specific needs in circulating catecholamine levels.     

Coupled evolution of digestive, respiratory, circulatory, and excretory systems: a model investigation

A model is developed of evolution of an organism with digestive, respiratory, circulatory, and excretory systems at the single system. The model is realized on the basis of the language STELLA 8.0. A balance is found between perfection of each individual physiological system and necessary energy expenditures for survival of the organism as a whole. The model is based on a coupled development of several visceral systems. There is analyzed effect of a change of consumption of substances with food and of oxygen amount on their oxidation, a branching of blood flow to organs, specifically to kidneys, to excrete final products of metabolism from blood. The energy expenditures for circulation are believed to be proportional to blood flow in a given organ. An increase of efficiency of renal excretion from blood of final metabolic products and toxic substances has a favorable effect on inner medium and activity of each cell of an individual, but increases of the organism energy expenditures. Interrelation of these factors under conditions of adaptation to changing environmental conditions determines peculiarities of evolution of each physiological system in an individual.     

Neural Circuit Recording from an Intact Cockroach Nervous System

The cockroach ventral nerve cord preparation is a tractable system for neuroethology experiments, neural network modeling, and testing the physiological effects of insecticides. This article describes the scope of cockroach sensory modalities that can be used to assay how an insect nervous system responds to environmental perturbations. Emphasis here is on the escape behavior mediated by cerci to giant fiber transmission in Periplaneta americana. This in situ preparation requires only moderate dissecting skill and electrophysiological expertise to generate reproducible recordings of neuronal activity. Peptides or other chemical reagents can then be applied directly to the nervous system in solution with the physiological saline. Insecticides could also be administered prior to dissection and the escape circuit can serve as a proxy for the excitable state of the central nervous system. In this context the assays described herein would also be useful to researchers interested in limb regeneration and the evolution of nervous system development for which P. americana is an established model organism.     

Cardiovascular effects of nerve growth factor (analytical literature review) Part I. NGF-indirect intracellular signal pathways

Traditionally, nerve growth factor (NGF) is considered as chemoattractant that participates in the regulation of cell proliferation, differentiation and myelination of neurons. However, currently available data suggest that the physiological role of NGF in the organism is much wider. This review discusses the features of the influence of NGF on the functional activity of the cardiovascular system, as well as signaling pathways by which activated NGF TrkA and p75(ntr) receptors regulate the functional state of endothelial and vascular smooth muscle cells and cardiomyocytes. In addition, the review observes the theoretical perspectives of agonists and antagonists of TrkA and p75(ntr) receptors for the treatment of various diseases of the heart and blood vessels.     

Hematopoietic cell renewal systems: mechanisms of coping and failing after chronic exposure to ionizing radiation

On the occasion of the first international workshop on systems radiation biology we review the role of cell renewal systems in maintaining the integrity of the mammalian organism after irradiation. First, 11 radiation emergencies characterized by chronic or protracted exposure of the human beings to ionizing irradiation were “revisited”. The data provide evidence to suggest that at a daily exposure of about 10–100 mSv, humans are capable of coping with the excess cell loss for weeks or even many months without hematopoietic organ failure. Below 10 mSv/day, the organisms show some cellular or subcellular indicators of response. At dose rates above 100 mSv/day, a progressive shortening of the life span of the irradiated organism is observed. To elucidate the mechanisms relevant to tolerance or failure, the Megakaryocyte–thrombocyte cell renewal system was investigated. A biomathematical model of this system was developed to simulate the development of thrombocyte concentration as a function of time after onset of chronic radiation exposure. The hematological data were taken from experimental chronic irradiation studies with dogs at the Argonne National Laboratory, USA. The results of thrombocyte response patterns are compatible with the notion of an “excess cell loss” (compared to the steady-state) in all proliferative cell compartments, including the stem cell pool. The “excess cell loss” is a function of the daily irradiation dose rate. Once the stem cell pool is approaching an exhaustion level, a “turbulence region” is reached. Then it takes a very little additional stress for the system to fail. We conclude that in mammalian radiation biology (including radiation medicine), it is important to understand the physiology and pathophysiology of cell renewal systems in order to allow predicting the development of radiation induced lesions.     

Physiological premises and mechanisms of normalizing effect of normobaric hypoxia and inhalation therapy]

Pathogenetic and physiological aspects of hypoxia problems have been considered. An opinion is stated that normalizing effect of intermittent normobaric hypoxia (INH) with short-term respiration of gaseous mixture containing at least 10% of oxygen in nitrogen is based on biorhythm inherent in all the living organisms with replacement of the high functional activity periods by the periods of rest and restoration with temporary physiological hypoxia as their typical companion. It is shown that for numerous diseases the course of INH or sessions of staying in the chamber of artificial mountain climate normalize the state of central nervous system, blood circulation, respiration, hemopoiesis and immunological reactivity, activate natural protective mechanisms and increase functional reserves of the organism. Allowing for anthropogenic pollution of the environment and its consequences for the health, it is advisable to widely adopt hypoxytherapy and orrhotherapy.     

电刺激兔肾脏传入神经对血压,心率及加压素释放的影响

本工作以兔为实验对象,观察电刺激肾脏传入神经（ＡＲＮ）对血压、心率、颈交感神经放电、以及加压素（ＡＶＰ）合成和释放的影响,并对ＡＲＮ进入中枢的通路作了观察。结果显示,电刺激ＡＲＮ可以引起血压下降、心率减慢、颈交感神经放电抑制等反应,ＡＲＮ的兴奋还可使下丘脑的视上核、室旁核中的ＡＶＰ含量增加,垂体中ＡＶＰ含量下降,血浆ＡＶＰ水平升高。硝普钠的降压实验和静脉注射ＡＶＰ受体阻断剂ＡＶＰａ的实验均证实了Ａ     

Energy-supply of the muscular activity at boys of 13-14 years in dependence from rates of puberty

In work on the basis of use functional and ergometric working capacity indicators specificity of power supply of muscular activity of healthy boys of 13-14 years (n = 162) with various at puberty stages (PSs). It is established, that the boys, being on II-IV PSs, considerably differ on indicators of power, capacity and efficiency of energy systems. Three groups of the bioenergy systems indicators differing on an orientation of their changes at teenagers depending on rates of puberty stages. The first group includes the physiological variables which most considerable levels are observed at children with high rates of development. All of them concern to anaerobic alactic and anaerobic glycolytic to components of physical working capacity. The second group unites the physiological variables which highest values are marked at teenagers with average rate of development, and the least--at children with the accelerated rate of maturing. These indicators reflect, mainly, set of aerobic possibilities of an organism. The third group includes the indicators which highest levels are marked at teenagers with low rate of development, and the least--at boys with the accelerated rate of maturing. They reflect the maximum aerobic power and endurance to power work. It is revealed, that teenagers of 13-14 years with average rates of development are characterised in comparison with children with the accelerated maturing, higher indicators of power and capacity of aerobic system of energy-supply, and in comparison to teenagers to the slowed down development--lower maximum aerobic power against higher capacity and profitability of functioning of aerobic system. Adolescents with average rates of maturing surpass also schoolboys with the accelerated and slowed down development concerning capacity of work in mixed anaerobic-aerobic a mode. In turn boys of 13-14 years with the accelerated development differ from schoolboys with the average and slowed down rates of maturing, high anaerobic productivity of an organism, rather low aerobic possibilities and increase of a tone of parasympathetic department of autonomic nervous system (AHC). The given circumstance is necessary for considering at realisation of the differentiated approach to rationing of loadings in the course of physical education and sports training of adolescents of 13-14 years.     

A combined micro-resonance Raman and absorption set-up enabling in vivo studies under varying physiological conditions: The nerve globin in the nerve cord of Aphrodite aculeata

We hereby report on the design of a set-up combining micro-resonance Raman and absorption spectroscopy with a microfluidic system. The set-up enabled us to study the nerve globin of Aphrodite aculeata in the functional isolated nerve cord under varying physiological conditions for extended periods of time. The oxygenation cycle of the organism was triggered by utilizing the microfluidic system that allowed for a fast switch between aerobic and anaerobic conditions. The nerve globin was found to very easily shift from a penta-coordinated high spin ferrous form to the oxy state upon a change from anaerobic to aerobic conditions. The observed fast reaction to varying O₂ concentrations supports an oxygen-carrying and/or -storing function of the nerve globin. In addition, by combining resonance Raman and absorption spectroscopy, the physiological response could be distinguished from light-induced effects.     

Effects of extremely high-frequency electromagnetic radiation on the immune system and systemic regulation of homeostasis

Low-intensity of electromagnetic radiation of extremely high frequencies (EHF EMR) is effectively used in medical practice for diagnostics, prevention and treatment of a broad spectrum of diseases of different etiology. However, in spite of existence of many hypotheses about mechanisms of EHF EMR effects on the molecular and cellular levels of organization of living systems, there is not conception that could explain all diversity of the EHF-therapy effects from unified approach. In our opinion, the problem of determination of mechanisms of EHF EMR effects on living organism is divided into two basic tasks: first, determining subcellular structures which can receive radiation, and, second, studying physiological reactions of the organism which are caused by radiation. It is obviously, that investigation of functions of single cells and subcellular elements can not entirely explain therapeutic effects and mechanisms of EHF EMR influence on multicellular organism on the whole. Plenty of functional relationships between organs and systems of organs should be taken into account. In the present review, a realization of the EHF-therapy effects due to the influence on immune system functions and start of system mechanisms of maintenance of the homeostasis on the organism level is hypothesized. Potential targets for EHF EMR acception on the level of different systems of the organism are analysed. The material is formed so that functional relations between immune system and other regulatory systems (nervous and endocrine systems) are traced.     

Influence of deuterium depleted water on the organism of laboratory animals in various functional conditions of nonspecific protective systems

The influence of deuterium depleted water with the modified isotope composition on an organism of animals is studied in physiological conditions and development of chronic endogenous intoxication of hepatorenal genesis. The influence of this water on isotope composition of plasma and tissues (the liver and kidneys) in laboratory animals is shown. The impact of this water on biochemical indicators (AST, ALT, alkaline phosphatase, creatinine, bilirubin) and dynamics in body weight of laboratory animals within 42 days is established. As a result of studies the possibility of the preventive use of deuterium depleted water for correction of metabolic processes is shown in various conditions of the functional system of the body’s detoxification.     

Mechanism of the effect of weak electromagnetic fields on the living body]

By using the model conceptions of the dielectric polarization theory, a new mechanism for the effect of electromagnetic field was proposed. The model enables one to explain the experimentally observed influence of low-frequency weak electromagnetic field on biological objects. It was shown that, at the cellular and subcellular levels, an increase in the intensity of the electric component of external electromagnetic field can occur. The magnitude of this increase is determined by the ratio of the contributions of the medium polarization and the depolarizing factor (which depends on body shape) to the total effect. As a result of this increase, a potential comparable with intrinsic biological values can be generated on neuron membranes, which must elicit nervous and physiological responses of the organism.     

Free amino acids in the spinal cord, ganglia and ischiadic nerve of the dog after ligature of the abdominal aorta

The effect of occlusion of the abdominal aorta for 10, 20 and 40 minutes on the concentration of aspartic and glutamic acids, glutamine, glycine, alanine and gamma-amino butyric acid in the anterior and posterior horns of the lumbosacral spinal cord was studied in the dog, further, concentration of amino acids (except GABA) in lumbosacral spinal ganglia and in the ischiadic nerve following 40 minutes of occlusion. The changes were most marked after 40 minutes of occlusion with a rise in concentration of alanine, glutamine and glutamic acid in the dorsal part of grey matter. Striking was also the simultaneous elevated concentration of Glu and Gln in spinal ganglia. The significance of these changes is discussed from the aspect of metabolism and function of nerve cells. Under physiological conditions the free amino acid pool in the central nervous system remains essentially constant. Under pathological conditions, however, like ischemic-hypoxic states, various changes occur.