" If the wave flows responsible for interorganismal correction of embryonic development are of electromagnetic nature, then it is logical to assume that it is possible to change the nature of the correction using the means and methods used in optics and radio electronics of high and ultra-high frequencies, which affect the optical characteristics of the radiation. The disadvantage of such methods is that the effective operating frequencies are selected empirically and they may not coincide with the natural frequencies of the bio-objects themselves. Therefore, auto-transformation methods become no less effective actions when the biological object receives its own radiation back. This radiation can be transformed and filtered in a certain way. Metallic and dielectric mirrors, as well as units and devices based on them (multimirror systems) were used for this purpose." {Credits 1} " A sufficient amount of experimental and clinical material has already been obtained, indicating the possibility of regulating the physiological state of biosystems through interorganismal wave correction." {Credits 1} " A number of studies have shown that changing the optical parameters of bioradiation, for example, the use of polarizers or light filters, leads to a change in the consequences of distant interactions of embryos [1]." {Credits 1} " The autooptical effect of bioradiation (or the effects of optical interactions of embryos of the same age), reflected from mirrors, allows us to assume that the radiation of a biological object returns back with some change in optical parameters, which makes it informative for the object." {Credits 1} " Particularly noteworthy are the effects obtained using corner light reflectors (CR), which are expressed most strongly in comparison with similar results obtained using single mirrors [4]." {Credits 1} " A number of studies have shown that changing the optical parameters of bioradiation, for example, the use of polarizers or light filters, leads to a change in the consequences of distant interactions of embryos [1]." {Credits 1} " The choice of this particular type of retroreflector as a device for controlling remote interaction is explained by the fact that it enables parallel transfer of incident radiation, with the fronts of incident and reflected light waves being parallel (Fig. 1), unlike mirrors, where this condition is met only at normal incidence." {Credits 1} " In the first series of experiments [4], experimental groups of embryos, placed in closed spectrophotometric quartz cuvettes (rectangular, 40x10x10 mm in size), were located at a distance of 1 cm from the USV so that they could optically contact each other only through the USV, and the image of one group was strictly projected onto the other (Fig. 2)." {Credits 1} " As it turned out, the interaction of embryos through the USV for 20-24 hours changed the dynamics of their further development in comparison with the control groups. Firstly, the interaction of same-age groups was reliably observed, which had never been observed with direct optical contact of such embryos. Secondly, the consequences of optical contact through the USV for loach eggs of low fish-breeding quality (low percentage of fertilization, which is characterized by the death of up to 100% of developing embryos in the first day of development) were sharply different. Thus, when placing cuvettes with embryos under the USV, survival was observed. ≈60% of embryos (Fig. 3)." {Credits 1} " The remote consequences of optical interactions of embryos were also studied. In both groups interacting through the USV, the formation of a number of developmental anomalies of some organs and tissues was observed, subsequently leading to a further increase in the mortality of embryos in these groups." {Credits 1} " The USV always returns the incident radiation back to the source. In this case, the radiation from the biological object interacts with the radiation reflected from the mirror faces of the USV. Coherent addition of the emitted and reflected electromagnetic waves occurs, as a result of which the phase image of the electromagnetic field of the biological object, its spatial and polarization characteristics change. The interaction of embryos at the same stage of development, the mutual influence of different ages and different types of organisms can be explained by the fact that the proper electromagnetic field is suppressed by direct reflection from the corner reflector. In all cases, the USV plays the role of a distorting factor, introducing a certain imbalance into the proper electromagnetic field of the selected objects. In the process of transmission from one biological object to another, information about the nature of the development of the biological system changes. A biological object with a suppressed self-field is ready to accept the radiation of a neighboring object as significant." {Credits 1} {Credits 1} 🎪 Бурков В. Д., Бурлаков А. Б., Капранов Ю. С., Куфаль Г. Э., Перминов С. В., Першин И. М., Шалаев В. С. Влияние электромагнитных полей на конфигурацию биологических объектов // Вестник МГУЛ – Лесной вестник. 2013. №7 (99). © 2013 The Author(s). This is an open access article distributed under the terms of the Creative Commons Attribution License. |
Last modified on 01-Feb-25 |