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The bioelectromagnetic field is a material carrier of biogenetic information that can be transmitted from one organism to another. A rejuvenation technique based on this discovery has great promise in treating cancer and immunological disorders. he bioelectromagnetic radiation of every living being is now no longer in ques- _ tion. Up to now, however, it was considered that genetic information is transmit- ted by DNA (deoxyribonucleic acid), known to contain the genetic code in its molecules. Advances in modern physics have led me to assume that DNA is, in fact, only a 'cas- sette’ with ‘recorded information’, whose actual material carriers are bioelectromagnetic signals. In other words, the electromagnetic field and DNA together make up com- bined genetic material, which exists in two forms: a passive (DNA) form, and an active (bioelectromagnetic field) form. The passive form preserves the genetic code; the active (transmitting) form is able to modify it. In what part of the spectrum is the bioelectromagnetic radiation emitted during the - organism's vital activities? Bioelectromagnetic signals (signals transmitting energy and information simultaneously) are moving photons, which, according to quantum theory, possess corpuscular and wave properties. The corpuscular properties of the photon presuppose the use of the low-frequency band, for in that case the organism receives the largest amount of information. It is known that the lower a photon's frequency, the smaller is its energy and, hence, the organism's limited energy can excite the most photons. The photon's wave properties, on the other hand, dictate the need to study the highest- frequency portion of the spectrum, which has a big transmission bandwidth. This would make possible the reception of a large body of information and a high quality of transmis- sion. Consequently, the bioelectromagnetic field, i.e., the material carrier of energy and infor- mation, exists in both the microwave and the infrared (IR) range in the middle portion of the electromagnetic spectrum. Laboratory experiments with the ‘biomicrowave communications’ installation yielded positive results in the field transmission of genetic information. The work was conducted in several areas: in agriculture (plant and animal selection), in medicine (fighting dis- eases, organism rejuvenation), and in other fields of genetics. PLANT AND ANIMAL SELECTION: EXPERIMENTAL RESULTS 1. The effect produced by the bioelectromagnetic field of green wheat mass (the donor, placed in the receiver) on germinated maize kernels (the recipient, in the transmitter). (See Fig. 2, 3.) The grown maize had many side stalks. In place of the cob heads there formed original ears with grains like those of both wheat and maize. Besides, the tested maize was found to be superior to a reference lot by 200 per cent in kernel yield and by 300 per cent in mass. Furthermore, the acquired changes were inherited by subsequent generations. 2. The effect produced by the bioelectromagnetic field of donor melons on germi- nated cucumber recipient seeds. (See Fig. 5.) The. grown cucumbers had the taste of melon. Biochemical analysis proved the pres- ence of DNA modifications. The acquired changes were passed on from one generation to another. . 3. The effect produced by the bioelectromagnetic field of donor peanuts on recipi- ent sunflower sprouts, . The sunflower seeds underwent a change of shape; part of them acquired a peanut taste. 4, The effect produced by the bioelectromagnetic field of a donor duck on recipi- ent hen's eggs. (See Fig. 4.) © 1993 by Dr Chiang Kanzhen Reprinted from AURA-Z Journal (vol. 1, no. 3, 1993) PO Box 224 Moscow 117463, Russia Phone: +7 (0)95 925 7679 Fax: +7 (0)95 422 0960 Reprinted from AURA-Z Journal (vol. 1, no. 3, 1993) PO Box 224 Moscow 117463, Russia Phone: +7 (0)95 925 7679 Fax: +7 (0)95 422 0960 NEXUS © 47 DECEMBER 1995 - JANUARY 1996