WO2022204772A1

WO2022204772A1 - Method for acting on arthropods and/or nematodes using sequences of extremely low frequencies and guide frequencies

Info

Publication number: WO2022204772A1
Application number: PCT/BR2022/050111
Authority: WO
Inventors: Luzo DANTAS JUNIOR
Original assignee: Dantas Junior Luzo
Priority date: 2021-04-03
Filing date: 2022-03-30
Publication date: 2022-10-06
Also published as: BR102021006436A2; AU2022251148A1

Abstract

Method for acting on chemical elements and combinations thereof, including proteins, DNA, RNA, hormones and neurotransmitters of arthropods and/or nematodes that cause and/or transmit diseases, and/or that cause productivity losses, and/or stimulating the defence of the hosts thereof against such arthropods and/or nematodes by transmitting sequences of extremely low frequencies defined using targets and a set of specific guides that act on specific sequences of amino acids and/or nucleotides, inter alia, of the arthropods and/or nematodes and/or hosts thereof. The desired effect is to strengthen or weaken the bonds between the chemical elements and the combinations thereof, including the component elements of the nucleotides, amino acids, hormones and neurotransmitters, inter alia, related to the arthropods and/or nematodes and/or the hosts thereof.

Description

PROCESS FOR WORKING ON ARTHROPODS AND/OR NEMATOIDS THROUGH EXTREMELY LOW FREQUENCY SEQUENCES AND DRIVING FREQUENCIES

DESCRIPTIVE REPORT FIELD OF THE INVENTION

[0001] Process for acting on chemical elements and their combinations, including proteins, DNA, RNA, hormones and neurotransmitters of arthropods and/or nematodes causing and/or transmitting diseases, and/or causing productivity losses, and/ or acting by stimulating the defense of their hosts against these arthropods and/or nematodes, through the transmission of extremely low frequency sequences defined from targets and a set of specific drivers that will act on certain sequences of amino acids and/or nucleotides, among others, of arthropods and/or nematodes and/or their hosts. The desired effect is achieved by strengthening or attenuating the bonds between chemical elements and their combinations, including the constituent elements of nucleotides, amino acids, hormones and neurotransmitters, among others, related to arthropods and/or nematodes and/or their hosts.

[0002] In general, the degree of genetic mutation of arthropods and/or nematodes, the main cause of their resistance to chemicals, makes it quite complex and costly to define a solution for eliminating or reducing their impact on human, animal and plant health , and crop productivity. There are currently two most common types of solutions for arthropod and/or nematode control available: chemical and biological. Both have been used, but they can present undesirable effects such as, diverse side effects in humans, leaving residues in food of plant and animal origin (with the potential to cause diseases in humans and animals), contamination of soils, rivers, lakes and groundwater, intoxication of professionals who apply the products to crops and animals, among others. In addition, they may have low efficiency due to frequent mutations of arthropods and/or nematodes and high selection pressure for populations resistant to chemicals.

[0003] The invention filed on 10/30/2018, under number BR102017023442-8 and title "Product and Process for Generating Extremely Low Frequencies for Chemical Equalization" describes a process and product for chemical equalization, based on the transmission of frequencies that will act in the equalization of chemical elements or a substance, providing, consequently, the adjustment of strengthening or attenuation of its properties and physical-chemical characteristics as desired, improving quality, increasing productivity and efficiency of industrial processes.

[0004] By strengthening the properties and physicochemical characteristics of an element, it is possible to use it in significantly smaller doses, without, however, impacting the results obtained. This invention, however, does not have the structure of drivers, capable of guiding frequency sequences to specific targets, nor the ability to act on biological organisms. [0005] The invention filed on 10/30/2018, under number BR102017023442-8 and title "Product and Process for Generating Extremely Low Frequencies for Chemical Equalization" describes a process and product for chemical equalization, and is based on the transmission of frequencies that will act in the equalization of chemical elements or a substance, providing, consequently, the adjustment of strengthening or attenuation of its properties and physical-chemical characteristics as desired, improving quality, increasing productivity and efficiency of industrial processes. By strengthening the properties and physicochemical characteristics of an element, it is possible to use it in dosages significantly smaller, without, however, impacting the results obtained. This invention, however, does not have the structure of drivers, capable of guiding frequency sequences to specific targets, nor the ability to act on biological organisms.

[0006] The invention BR 1020190259582 - PRODUCT AND PROCESS FOR ACTION IN BIOLOGICAL ORGANISMS THROUGH EXTREMELY LOW FREQUENCIES of 12/07/2019 reveals a product and process for using extremely low frequency sequences for use in organisms. However, said invention does not define specific processes for the use of this procedure in the case of arthropods and/or nematodes that cause and/or transmit diseases, and/or cause productivity losses, in humans, animals and plants. [0007] The invention CN211482636 - INSECT EXPELLING CIRCUIT AND WATER PURIFIER of 08/21/2019 reveals a utility model referring to the field of insect expelling control, and features an insect expulsion circuit and a water purifier. An ultrasonic frequency signal and a low frequency signal are respectively output to an ultrasonic driving circuit and a low frequency electromagnetic wave excitation circuit through a processor; and the ultrasonic transducer and transmission circuit are driven to transmit ultrasonic waves and transmit low frequency electromagnetic waves, and the ultrasonic waves and low frequency electromagnetic waves can be transmitted simultaneously or alternately, so that the effects caused by a single Ultrasonic insect expulsion can be effectively avoided, continuous insect expulsion effect is achieved, and user experience is improved. However, said invention does not deal with the use of Extremely Low Frequency (ELF) sequences in the range of 0 to 100Hz, and does not specify the molecular targets that are reached by the frequencies, which can also act collaterally on beneficial arthropods and/or nematodes when environment to which it will be applied. [0008] The invention NZ588814 - METHOD OF INSECT CONTROL of 10/27/2010 discloses a method of controlling insects by diffusing frequency sweep sound waves to cause malfunction of the wing beating system of flying insects. The method comprises determining the frequency range of insect wing beats, then generating a series of single frequency sound waves that cover the entire frequency range of insect wing beats. Single frequency sound waves being from low frequency to high frequency are linked to form an ascending, descending and random ordered sound series. The sound series are also linked together to form frequency-swept sound tracks that can be recorded digitally. The diffusion of sound tracks is carried out in such a way that the SPL (sound pressure level) of the sound waves reaches a value greater than 2.0 Pa (ie 100 dB). However, said invention does not deal with the use of Extremely Low Frequency (ELF) sequences in the range of 0 to 100Hz, and does not specify the molecular targets that are reached by the frequencies, which can also act collaterally on beneficial arthropods and/or nematodes when environment to which it will be applied.

[0009] The invention US20060198245 - ELECTRONIC INSECT REPELLING DEVICE of 02/03/2005 discloses a personal electronic device for repelling insects and is an electronic circuit supported on the underside of a hat of a hat that produces an acoustic signal directed towards the body of a person wearing the hat. The sonic signal has a frequency that repels insects, particularly mosquitoes. The sonic signal is generated by a battery-operated oscillator circuit, which drives an electro-acoustic transducer to generate the acoustic signal. The acoustic transducer is mounted relative to the hat so that substantially all exposed areas of the person wearing the hat are radiated with sonic energy. The sonic signal has essentially the same characteristics as the sound of a male mosquito. However, said invention is restricted to the emission of a sound signal with the function of repelling insects and does not explore other ways of attack such as reproduction, motility and other biological functions.

GENERAL DESCRIPTION

[0010] Due to the gaps found in the state of the art to deal specifically with arthropods and/or nematodes, among them the causes and/or transmitters of diseases, and/or causes of productivity losses, it was necessary to develop a new technique as revealed below. In the case of arthropods and/or nematodes, including those that cause and/or transmit diseases, and/or cause loss of productivity, there are three main attack strategies: [0011] 1 . Act on specific sequences of amino acids that make up specific sites of proteins of arthropods and/or nematodes or host. In this case, the aim is to alter the natural biological function of the target proteins with the objective of stimulating the development or inhibiting the infection (infestation and/or occurrence) and/or multiplication of the arthropod and/or nematode and/or modifying the defense mechanisms of the animal. host against the arthropod and/or nematode.

[0012] 2. Act on nucleotide sequences in order to prevent or stimulate the gene expression of proteins important for physiological processes essential for life, multiplication and/or infection (infestation and/or occurrence) of the arthropod and/or nematode and/ or modify the host's defense mechanisms against the arthropod and/or nematode.

[0013] 3. Act on elements other components of arthropods and/or nematodes, such as hormones, lipids and neurotransmitters, among others from chemical elements and/or specific chemical compounds and/or their combinations for each arthropod and/or nematode or group of arthropods or nematodes, including their variations and/or mutations, and/or their hosts, in order to stimulate or inhibit, totally or partially, their biological function. All these strategies use the same technique used here.

[0014] The purpose of the technique demonstrated here is to inhibit or stimulate biological functions or modify the properties of the elements, or chemical compounds, defined in the attack strategies listed above by applying extremely low frequency sequences and a set of predefined driving frequencies. [0015] The way of acting developed and revealed in this technique is based on the application of the technique of extremely low frequency sequences, that is, frequencies in the open range between 0 and 100 Hertz (limits not included). Each set of frequency sequences is composed of one or more targets and one or more specific drivers for each arthropod and/or nematode species and/or its variations and mutations. This makes this set of specific application of arthropods and/or nematodes and of biological and/or physiological functions chosen in them. This invention discloses those application processes which are illustrated in Figures 2 and 4. Each target and driver combination is designed to define a mathematically unique solution.

[0016] In case 1, above, this invention makes use of one or more sequences of previously determined frequencies (each with target and driver determining a unique solution) and validated in the laboratory, to generate the decrease or increase of the interatomic distance of the elements chemicals that form the target amino acids, altering the conformation of the protein in question and consequently its biological function.

[0017] In case 2, above, this invention makes use of one or more sequences of frequencies previously determined (each with target and driver determining a unique solution) and validated in the laboratory, to generate the decrease or increase of the interatomic distance of the elements chemicals that form the target nucleotides, altering the conformation of these nucleotides and consequently their biological function.

[0018] In case 3, above, this invention makes use of one or more sequences of previously determined frequencies (each with target and driver determining a unique solution) and validated in the laboratory, to generate the decrease or increase of the interatomic distance of the target chemical elements and/or chemical compounds (such as hormones, lipids and neurotransmitters, among others), altering their conformation and consequently their biological properties and/or functions.

[0019] The three strategies described above can be used individually and/or concurrently in the same implementation of the technique disclosed herein.

PREFERRED MODALITIES

[0020] A first preferred embodiment deals with the application of strategy 1 (acting on amino acids) that targets the amino acid sequences of the Acetylcholinesterase (AChE) enzyme of arthropods and/or nematodes. In this case, the frequency sequences will act according to their driving frequencies on the amino acid sequences that form the different possibilities of active site (binding site) of the Acetylcholinesterase (AChE) enzyme of arthropods and/or nematodes. As a result of this action, the action of the Acetylcholinesterase (AChE) enzyme of arthropods and/or nematodes will be prevented or hindered, causing hyperexcitation in nerve synapses due to the large amount of the neurotransmitter acetylcholine, damaging the nerve transmission of arthropods and/or nematodes.

[0021] A second preferred modality deals with the application of strategy 1 (acting on amino acids) that targets the amino acid sequences of the chloride channel activated by GABA (Gamma-aminobutyric acid) of arthropods and/or nematodes. In this case, the frequency sequences will act according to their driving frequencies on the amino acid sequences that form the different possibilities of active site (binding site) of GABA (gamma-aminobutyric acid) to the chloride channel of arthropods and/or nematodes. As a consequence of this action, the binding of GABA to the chloride channels of arthropods and/or nematodes will be prevented or difficult, causing hyperexcitation in nerve synapses, damaging the nervous transmission of arthropods and/or nematodes.

[0022] A third preferred modality deals with the application of strategy 1 (acting on amino acids) that target the amino acid sequences of the sodium channels of arthropods and/or nematodes. In this case, the frequency sequences will act according to their driving frequencies on the amino acid sequences that form the different possibilities of active site (binding site) of the regulatory neurotransmitters to the sodium channels of arthropods and/or nematodes. As a consequence of this action, the binding of neurotransmitters regulating the sodium channels of arthropods and/or nematodes will be prevented or hindered, causing hyperexcitation and/or blockage in nerve synapses, damaging the nerve transmission of arthropods and/or nematodes.

[0023] A fourth preferred modality deals with the application of strategy 1 (acting on amino acids) that targets the amino acid sequences of the ATP synthase enzyme of arthropods and/or nematodes. In this case, the frequency sequences will act according to their driving frequencies on the amino acid sequences that form the different possibilities of active site (binding site) of the ATP synthase enzyme of arthropods and/or nematodes. As a consequence of this action, the action of the ATP synthase enzyme of arthropods and/or nematodes will be prevented or hindered, causing inhibition of ATP synthesis in mitochondria, damaging the nerve transmission of arthropods and/or nematodes.

[0024] A fifth preferred embodiment deals with the application of strategy 1 (acting on amino acid) which targets the amino acid sequences of the Acetyl CoA Carboxylase enzyme of arthropods and/or nematodes. In this case, the frequency sequences will act according to their driving frequencies on the amino acid sequences that form the different possibilities of active site (binding site) of the Acetyl CoA Carboxylase enzyme of arthropods and/or nematodes. As a consequence of this action, the action of the Acetyl CoA Carboxylase enzyme of arthropods and/or nematodes will be prevented or hindered, causing inhibition of the first stage of lipid biosynthesis, damaging the synthesis of lipids in arthropods and/or nematodes. [0025] A sixth preferred modality deals with the application of strategy 2 (action on nucleotides) that targets the sequence of nucleotides (Figure 3) that participate in the metabolism of nucleic acids of arthropods and/or nematodes. In this case, the frequency sequences will act according to their driving frequencies on the nucleotide sequences, preventing the translation (Figure 4) of the coding region of proteins that participate in the metabolism of nucleic acids of arthropods and/or nematodes.

[0026] A seventh preferred modality deals with the application of strategy 3 (acting on chemical elements and/or chemical compounds, such as hormones, lipids and neurotransmitters, among others) that targets the juvenile hormone (Figure 5) of arthropods and/or arthropods. or nematodes. In this case, the frequency sequences will act according to their driving frequencies on the chemical sequences that form the juvenile hormone of arthropods and/or nematodes. As a consequence of this action, the action of the juvenile hormone (Figure 6) of arthropods and/or nematodes will be stimulated or prevented, causing inhibition or stimulation of metamorphosis, damaging the process of metamorphosis of arthropods and/or nematodes when applied at the correct stage of their growth. life cycle.

[0027] An eighth preferred embodiment deals with the application of strategy 1 (acting on amino acids) that targets the amino acid sequences of the chloride channel blocked by Glutamate of arthropods and/or nematodes (Figure 1). In this case, the frequency sequences will act according to their driving frequencies on the amino acid sequences that form the different possibilities of active site (binding site) of Glutamate to the chloride channel of arthropods and/or nematodes. As a consequence of this action, the binding of Glutamate to the chloride channels (Figure 2) of arthropods and/or nematodes will be prevented or difficult, causing paralysis of nerve synapses, damaging the nerve transmission of arthropods and/or nematodes.

[0028] A ninth preferred modality deals with the application of strategy 3 (acting on chemical elements and/or chemical compounds, such as hormones, lipids and neurotransmitters, among others) that target the ecdysone hormone of arthropods and/or nematodes. In this case, the frequency sequences will act according to their driving frequencies on the chemical sequences that form the ecdysone hormone of arthropods and/or nematodes. As a result of this action, the action of the ecdysone hormone of arthropods and/or nematodes will be stimulated or prevented, causing inhibition or stimulation of the molt, damaging the process of ecdysis of arthropods and/or nematodes when applied at the correct stage of their life cycle. .

[0029] A tenth preferred embodiment deals with the application of strategy 1 (acting on amino acids) that targets the amino acid sequences, in whole or in part, that make up the proteins of the cellular respiration complex. In this case, the frequency sequences will act according to their driving frequencies on the amino acid sequences that form the active site (binding site) of the proteins mentioned above. As a consequence of this action, the cellular respiration of arthropods and/or nematodes will be inhibited, impeded or hampered, totally or partially.

[0030] An eleventh preferred embodiment deals with the application of strategy 1 (acting on amino acids) that targets the amino acid sequences, in whole or in part, that make up the proteins that act in the synthesis of amino acids and proteins. In this case, the frequency sequences will act according to their driving frequencies on the amino acid sequences that form the active site (binding site) of the proteins that act in the synthesis of amino acids and proteins of the arthropod and/or nematode. As a consequence of this action, the synthesis of amino acids and proteins of arthropods and/or nematodes will be prevented or hindered.

Claims

1\2 CLAIMS

1 . Process for acting on arthropods and/or nematodes through sequences of extremely low frequencies and driving frequencies characterized by making use of frequency sequences that are unique for each target determined by the driving frequencies in one or more arthropods and/or nematodes (including their variations and/or mutations) and/or their host organisms, to act on specific amino acid sequences stimulating or inhibiting, totally or partially, their biological function.

Process according to claim 1, characterized in that it targets the amino acid sequences, in whole or in part, that make up the proteins of the cellular respiration complex, stimulating or inhibiting, totally or partially, the cellular respiration of arthropods and/or nematodes.

Process according to claim 1, characterized by targeting the amino acid sequences, in whole or in part, that make up the proteins of the nervous and/or muscular system complex, stimulating or inhibiting, totally or partially, the nervous transmission and movement of arthropods and/or nematodes.

Process according to claim 1, characterized by targeting the amino acid sequences, in whole or in part, that make up the proteins that act in the synthesis of amino acids and proteins, stimulating or inhibiting, totally or partially, the synthesis of amino acids and proteins of arthropods and/or nematodes.

5. Process for acting on arthropods and/or nematodes through sequences of extremely low frequencies and driving frequencies characterized by making use of frequency sequences that are unique for each target determined by the driving frequencies in one or more arthropods and/or nematodes ( including variations and/or mutations thereof) and/or their host organisms, to act on specific nucleotide sequences, stimulating or inhibiting, totally or partially, their biological function.

Process according to claim 5, characterized in that it targets the sequences 2\2 of nucleotides, in whole or in part, which may or may not be transcribed and/or translated into proteins that act in vital functions for arthropods and/or nematodes, stimulating or inhibiting, totally or partially, the synthesis of amino acids, peptides and proteins from arthropods and/or nematodes.

7. Process according to claim 5 characterized by targeting nucleotide sequences, in whole or in part, that may or may not be transcribed and/or translated into proteins that act in the induction of host defense, improving the induction of their defense mechanisms against disease-causing arthropods and/or nematodes.

8. Process for acting on arthropods and/or nematodes through sequences of extremely low frequencies and driving frequencies characterized by making use of frequency sequences that are unique for each target determined by the driving frequencies in one or more arthropods and/or nematodes ( including their variations and/or mutations) and/or their host organisms, to act on chemical elements and/or chemical compounds, such as hormones, lipids and neurotransmitters, among others, stimulating or inhibiting, totally or partially, their biological function.

9. Process according to claim 8, characterized by targeting chemical elements and/or chemical compounds, in whole or in part, that make up the hormones that act in the growth and development processes of arthropods, such as juvenile hormone and ecdysone, stimulating or inhibiting, totally or partially, the action of juvenile hormone and/or ecdysone of arthropods and/or nematodes.