The influence of low-intensity millimeter electromagnetic emission on the vital activity of Saccharomyces cerevisiae cells

Two mechanisms of the interaction of low-intensity millimeter electromagnetic emission (bubble and resonance) with model cellular systems (by the example of Saccharomyces cerevisiae) have been investigated. It was shown that the effect of stimulation of cell activity by electromagnetic emission has a clearly pronounced resonance character. A similar effect was evoked by the stimulation of activity of yeast cells by thermal pulse influence, which can be described in terms of the bubble mechanism. It was shown that the electromagnetic emission can affect biological objects by both mechanism.     

The effect of low-intensity coherent extremely high frequency electromagnetic radiation on growth parameters for <Emphasis Type="Italic">Enterococcus hirae</Emphasis> bacteria

It is found that for Enterococcus hirae ATCC9790 bacteria grown in anaerobic conditions, one-hour exposure to low-intensity (radiant power of 0.06 mW/cm²) coherent extremely high frequency electromagnetic radiation (from 45 to 53 GHz), or millimeter electromagnetic radiation, leads to an appreciable increase in latent growth time and to a decrease in specific growth rate; herein, the effects intensify as the frequency increases from 49 to 53 GHz. The result is enhanced at an increase in the radiation duration from 30 min to 1 h; however, a further increase in the exposure time up to 2 h does not lead to intensification of the effect. It is shown that the effect of extremely high frequency electromagnetic radiation on Enterococcus hirae does not depend on pH of the medium (pH 6.0 or 8.0). It may be expected that these bacteria have protective or reparation mechanisms that compensate long-term action of this radiation; it is not improbable that various mechanisms of pH regulation are present as well.     

Functional Activity of the Sympathoadrenal System and Behavioral Indices of Rats: Changes Induced by Millimeter-Range Electromagnetic Radiation

We examined the ability of low-intensity millimeter-range (mmR) electromagnetic radiation (EMR) to modify the functional activity of the sympathoadrenal system (SAS) and the behavioral reactions in intact rats and rats with an experimentally induced stress reaction. Adaptation of the organism to mmR EMR has been shown to limit SAS activation; this is considered one of the mechanisms of the antistressor effect of such radiation.     

The effect of microwaves on the bioelectric brain activity

The experiments on rats have shown that the effect of millimeter range electromagnetic radiation on the bioelectric brain activity is dependent on the initial functional state of central nervous system. Microwaves are able to cause a nonspecific electroencephalographic reaction of synchronization and probably the lower the bioelectric brain process dynamics of active rats. Enrichment of electrocorticograms with high-frequency rhythms and increase in degree of bioelectric brain dynamics can be observed in narcosis conditions. The appearance of biological resonance in the brain of narcotized rats preliminary injected aminazin by pulse-modulated microwaves is noted. This is expressed as epileptiform convulsive activity in electrocorticogram. It has been shown that the nonlinear dynamics method may provide a reliable characterization of changing bioelectric brain activity under of nonionized electromagnetic fields. It is possible to modulate the bioelectric brain activity by microwaves to change the functional state of central nervous system and probably of the whole organism.     

NADPH氧化酶在电磁辐射生物效应中的作用

电磁辐射是一种复合电磁波,而人体生命活动包含一系列的生物电活动,这些生物电对环境的电磁波敏感,因此,电磁辐射可对人体造成危害.关于电磁辐射诱导的生物效应研究虽多,然而其具体机制尚不清楚.近年来,发现烟酰胺腺嘌呤二核苷酸磷酸氧化酶(NADPH氧化酶),又称呼吸爆发氧化酶(respiratory burst oxidase homologue,Rboh)在电磁辐射产生的生物学效应中扮演重要角色,电磁辐射可直接或间接活化NADPH氧化酶复合体,然后NADPH氧化酶可以将细胞内NADPH的电子转移而形成活性氧,或者通过一系列炎症因子和相关基质金属蛋白酶等参与炎症、防御以及组织修复等生命过程.本文对NADPH氧化酶在电磁生物学效应中的作用进行了综述.     

The dynamics of the manifestation of behavioral audiogenic seizure activity in rats under the action of a modulated and a nonmodulated electromagnetic field

It was shown that the electromagnetic field of low intensity modifies the evoked epileptiform seizure activity in rats. Cumulative effect of the electromagnetic field persisted over the course of 6 months. It was suggested that inhibition of the increased motor activity under exposure to electromagnetic field is caused by the involvement of dopaminergic brain systems and development of the resonance effects in cortico-subcortical brain structures under the influence of modulated electromagnetic fields.     

Some approaches to the activation of antitumor resistance mechanisms and functional analogs in the categories of synergetics

The methods for activating antitumor resistance mechanisms that were developed using the concept of the periodic system of general nonspecific adaptational reactions of the body are briefly reviewed. The principles that allow effective impacts with electromagnetic radiation and biologically active substances are described. The criteria and concepts of the theory of adaptational reactions are compared to some of the concepts and categories of synergetics. The specific features in the dynamics of the studied parameters that are induced by effective impacts are considered. The antistress nature of the systemic effect that is caused by ferromagnetic nanoparticles on animals with grafted tumors is shown. Possible mechanisms that underlie the regression of large tumors that is caused by two different factors, viz., modulated electromagnetic radiation and magnetite nanoparticles, are discussed. The cases where the order parameter changed with the development of antistress unresponsiveness and regression of experimental tumors caused by a combined electromagnetic exposure are analyzed.     

Effect of modified SHF and acoustic stimulation on spectral characteristics of the electroencephalograms of the cat brain

The effect of modulated electromagnetic fields on the spectral parameters of bioelectric brain activity in awake cats was studied by registering the electroencephalogram from the skin surface in the vertex area using carbon electrodes. In the normal electroencephalogram, spectral components in the range above 20 Hz predominated. It was shown that, upon irradiation with electromagnetic field (basic frequency 980 MHz, power density 30-50 microW/cm2), spectral components in the range of 12-18 Hz begin to prevail. A similarity in the redistribution of the power of spectral components upon both acoustic and modulated electromagnetic influences was revealed. The results suggest that there is a a common neurophysiological mechanism by which modulated electromagnetic radiation and acoustic stimulation affect the electrical activity of the brain. This ia consistent with the assumption that the effect of the electromagnetic field on the central nervous system is mediated through the acoustic sensory system.     

Information EHF-interactions in a system of live objects (human platelets)

The molecular informational interaction has been first detected in a system that involves human platelets, exposed to electromagnetic EHF-fluctuations at frequencies of molecular spectra of radiation and absorption of nitric oxide (150.176-150.644 HHz), and native platelets. It has been established that the incubation of a native platelet rich plasma with a similar plasma, exposed to a 5-minute effect of electromagnetic EHF-fluctuations at frequencies of molecular spectra of radiation and absorption of nitric oxide at a mode of peak and frequent modulation of a signal under in vitro conditions, causes a significant (P < 0.05) inhibition of platelet functional activity in the native plasma, in comparison with control. This was displayed by a decreased platelet activation and falling platelet aggregation ability. Some possible mechanisms of interaction are suggested to explain the described effect.     

The action of low-intensity extremely high-freguency electromagnetic radiation on growth parameters for bacteria Enterococcus hirae

It has been found that the exposure of Enterococcus hirae ATCC9790, grown under anaerobic conditions for 30 min or 1 h, to low-intensity (flux capacity 0.06 mW/sm2) coherent electromagnetic radiation (EMI) of extremely high-frequency 45 - 53 GHz), or millimeter waves causes a marked prolongation of the lag-growth phase and a decrease in their specific growth rate, the inhibitory effect increasing in the frequency range from 49 to 53 GHz. The effect enhanced as duration of expocure was encreased from 30 min to 1 h; however, further increase in exposure duration to 2 h did not cause an enhancement of the effect. It has been shown that the action of extremely high-frequency EMI on these bacteria does not depend on medium pH (pH 8.0 or pH 6.0). It is proposed that these bacteria have defensive or reparation mechanisms which compensate for the action of radiation; the occurrence of different mechanisms for pH regulation is not ruled out.     

电磁场曝露对生物组织电磁特性的影响

电磁辐射严重影响着人体的健康.电磁场生物效应的发生机制与电磁场本身的特性相关,同时也与生物组织在电磁场作用下电磁特性的改变密切相关.生物体内的信号分子、自由基以及磁颗粒等处于外加电磁场中时其电磁特性会发生变化,尤其是不同频率电磁场曝露作用下生物组织的导电、介电以及磁学等特性会有非常显著的区别.明确不同频率电磁场作用下生物组织电磁特性的变化规律是研究电磁场生物效应发生机制以及预防问题的关键.综述了近年来电磁场对于生物组织电磁特性影响的研究成果,并对未来的研究方向做了展望.     

Thermoelastic excitation of acoustic waves in biological models under the effect of the high peak-power pulsed electromagnetic radiation of extremely high frequency

The capability of high peak-power pulsed electromagnetic radiation of extremely high frequency (35,27 GHz, pulse widths of 100 and 600 ns, peak power of 20 kW) to excite acoustic waves in model water-containing objects and muscular tissue of animals has been experimentally shown for the first time. The amplitude and duration of excited acoustic pulses are within the limits of accuracy of theoretical assessments and have a complex nonlinear dependence on the energy input of electromagnetic radiation supplied. The velocity of propagation of acoustic pulses in water-containing models and isolated muscular tissue of animals was close to the reference data. The excitation of acoustic waves in biological systems under the action of high peak-power pulsed electromagnetic radiation of extremely high frequency is the important phenomenon, which essentially contributes to the understanding of the mechanisms of biological effects of these electromagnetic fields.     

Dependence of anti-inflammatory effects of high peak-power pulsed electromagnetic radiation of extremely high frequency on exposure parameters

A pronounced anti-inflammatory effect of high peak-power pulsed electromagnetic radiation of extremely high frequency was shown for the first time in a model of zymosan-induced footpad edema in mice. Exposure to radiation of specific parameters (35, 27 GHz, peak power 20 kW, pulse widths 400-600 ns, pulse repetition frequency 5-500 Hz) decreased the exudative edema and local hyperthermia by 20% compared to the control. The kinetics and the magnitude of the anti-inflammatory effect were comparable with those induced by sodium diclofenac at a dose of 3 mg/kg. It was found that the anti-inflammatory effect linearly increased with increasing pulse width at a fixed pulse repetition frequency and had threshold dependence on the average incident power density of the radiation at a fixed pulse width. When animals were whole-body exposed in the far-field zone of radiator, the optimal exposure duration was 20 min. Increasing the average incident power density upon local exposure of the inflamed paw accelerated both the development of the anti-inflammatory effect and the reactivation time. The results obtained will undoubtedly be of great importance in the hygienic standardization of pulsed electromagnetic radiation and in further studies of the mechanisms of its biological action.     

Changes in physico-chemical parameters of homeopathic remedies ferrum metallicum CH6 and ferrum metallicum CH30 after exposure to high frequency electromagnetic radiation of low intensity

It is considered the microwaves electromagnetic radiation do not affect the materials, alive or not, when used in low power. In high power, the interaction effects would be the material warming (thermal effect). However, in the last years, the studies about electromagnetic radiation with low power (non thermal effect) in the human being have been increasing. It was found out the electromagnetic radiation, even with low power, can affect the living organisms and biosubstratum. In the present work the influence of electromagnetic radiation (2.45 GHz 500 W/cm2), on physical and chemical parameters of the homeopathic pharmaceutics products in shown.     

MUSCULAR ACTIVITY AND BUBBLE FORMATION IN ANIMALS DECOMPRESSED TO SIMULATED ALTITUDES

1. Muscular activity during decompression causes bubble formation in the blood of intact bullfrogs. The amount of gas liberated depends on the degrees of muscular activity and supersaturation (as influenced by altitude). In decompressed dissected bullfrogs, bubbles appear in veins leading from active but not from inactive muscles. 2. Muscular activity during decompression similarly causes bubble formation in rats. Bubbles appear in veins coming from muscles, and often in the lymphatic system. Quiescent rats do not form bubbles. 3. Violent muscular activity before decompression favors bubble formation in bullfrogs during ensuing decompression, but it is less effective than exercise during decompression. The effect persists in large frogs for about an hour. 4. Pre-oxygenation for 2 to 4 hours before decompression reduces the incidence of bubble formation in decompressed bullfrogs. It thus has the same effect on bubble formation in bullfrogs as it does on the "bends" in man. The effect is presumably due to removal of nitrogen. 5. Possible mechanisms by which muscular activity causes bubble formation are discussed. The effects of mechanical agitation and of metabolic CO₂ are considered to be the dominant factors.     

Sensitive model with which to detect athermal effects of non-ionizing electromagnetic radiation

To clarify the potential of non-ionizing electromagnetic radiation to cause biological effects by athermal mechanisms, and to initiate elucidation of those mechanisms, a model system amenable to scrutiny at the molecular level has been designed and characterized. Assessment of beta-galactosidase activity in E. coli JM101 containing the plasmid pUC8 provides a sensitive assay with many important advantages. The ability to examine at the molecular level each of the processes involved in producing beta-galactosidase should permit elucidation of the molecular mechanism(s) that give rises to an observed effect.     

Influence of electromagnetic radiation on molecular solitons

The soliton model of charge and energy transport in biological macromolecules is used to suggest one of the possible mechanisms for electromagnetic radiation influence on biological systems. The influence of the electromagnetic field (EMF) on molecular solitons is studied both analytically and numerically. Numerical simulations prove the stability of solitons for fields of large amplitude, and allow the study of emission of phonons. It is shown that in the spectra of biological effects of radiation there are two characteristic frequencies of EMFs, one of which is connected with the most intensive energy absorption and emission of sound waves by the soliton, and the other of which is connected with the soliton photodissociation into a delocalized state.     

Helical water wires

A helitetrahedral model has been proposed to help explain reports of low-frequency oscillations in pure water following electromagnetic excitation at the hydronium ion cyclotron resonance frequency. The Lorentz force and the intrinsic structure constrain the motion of the H₃O⁺ ion so that it enjoys a unique form of proton-hopping, one whose path is helical. This model may also explain the numerous previously observed cyclotron resonance (ICR) biological couplings for cations other than hydronium by merely substituting hydrogen-bonded versions of these for hydronium in the tetrahedral structure. Thus the effectiveness of resonance stimulation in biological systems is explained in terms of the enhanced conductivity and reduced scattering associated with proton-hopping. It is further shown that the addition of charge-balancing hydroxyl ions act to enable oscillatory electric dipole moments that propagate along the helical axis, giving rise to weak power (≈ femtoWatts) radiation patterns. It is conceivable that the radiation associated with this process may play a role in the interactions at the interface between water and living matter.     

The influence of electromagnetic radiation of extremely high frequencies on the pro- and antioxidant status of blood in experiments

The influence of electromagnetic radiation of extremely high frequencies in the noise mode on the level of the activity of proand antioxidant systems in a model of skin-flap ischemia was studied in vivo. Rats of the Wistar line were used in this work. The cutaneous reflex projection field of the animals was exposed once a day for 7 days in the post-operative period to electromagnetic radiation of an extremely high frequency in the range from 53.57 to 78.33 GHz with a dose of 1.2 mJ in the noise mode. The dynamics of proand antioxidant protection were compared to those of intact animals that were not irradiated. Using data on induced biochemiluminescence and estimation of malondialdehyde activity it was shown that irradiation in a course mode contributed to a decrease in the intensity of lipid peroxidation. In parallel we observed an increase in the total antioxidant reserves of blood and the activity of bioradical protection enzymes. Our findings suggest that electromagnetic radiation at extremely high frequencies in a noise mode has a regulatory impact on the state of proand antioxidant systems of the body; this can be used for the correction of postoperative ischemic disorders and the restoration of disturbed homeostasis.