WO2011087410A1 - Methods to measure pathogens - Google Patents

Abstract

A method to measure the presence and characteristics of organisms, wherein said organisms create resonance when exposed to electromagnetic energy at the periods 24/2¹⁸ hour, 24/3·2¹⁷ hour, 24/5·2¹⁶ hour, 24/7·2¹⁶ hour and 24/9·2¹⁵ hour and the absorbed energy at resonance is measured and where the resonance period is organism specific and one of said periods and where said organisms include all types of organisms including all types of disease-causing pathogens, all types of bacteria, all types of viruses, all types of cancer cells and tumors, all types of mould and all types of fungal microbes.

Description

Methods to Measure Pathogens

Technical Field

The present invention relates to the fields of resonance in organisms including pathogens, and more specific to methods to create and measure resonance in organisms in vitro and in vivo and according to the preamble of claim 1.

Background and Prior Art

It's known that the rotation of the earth creates currents with the period 24 hours in the magnetosphere, known as the Birkeland currents.

The global electric circuit is known since the 1920ies and it supplies the earth crust and the air with charge; electrons, negative and positive ions. The 200 kV potential between the atmosphere and earth creates a vertical current density of * 3 pA/m².

It's known that H₂0 forms molecule structures (ex. tetrahedral structure), that water is polar in nature and dissolves salts (ex. NaCI) into ions where Na⁺ is attracted to ^δΌ and CI^" to ^δ+Η and H₂0 molecules are bonded by the extremely weak hydrogen bond.

It's known that some biological processes such as the water channel, ion channels, receptors and the blood-brain-barrier depend on specific H₂0/ion molecule structures and that these processes are influenced by low frequency electromagnetic energy.

There exist no methods which allow measurement of extremely low amplitude and very low frequency electromagnetic displacement and conduction current {< 10 Hz). Therefore the above phenomena and their mutual relationship are poorly understood.

Summary of the Invention: Enabier

The inventor has developed methods which enable measurement and description of processes based on extremely small amplitude current and transverse EM waves having very low frequency. Many electromagnetic biological processes operate at extremely low amplitude and low frequency and the invention is based on the understanding of electromagnetic processes that have not been described or reported before.

Summary of the Invention: object of the invention

The object of this invention is to create a method to measure the presence and characteristics of organisms by measuring the energy absorbed at the resonance period of said organisms.

This is achieved with the method according to the invention as defined in claim 1.

Organisms in organic and inorganic matter create resonance with electromagnetic waves of conduction current (e.g. current) present in the air. Said current is generated by the rotation of the earth and thus it has the period 24 hours and harmonics. Therefore period instead of frequency is used in the invention. Organisms create resonance at the following periods, however, one kind of organism creates resonance only at one specific period: 24/2¹⁸ hour (3.03 Hz), 24/3-2¹⁷ hour (4.55 Hz), 24/5-2¹⁶ hours (3.79 Hz), 24/7-2¹⁶ hour (5.31 Hz) or 24/9-2¹⁵ hour (3.41 Hz). The method is to measure the energy absorbed by said organisms at their resonance period. One method is to measure the absorbed current present in the air and which connects to the organisms. The other method is to generate electromagnetic energy having the same period as the resonance period of the organisms, and expose said organisms to said energy in order to create resonance whereby the absorbed energy is measured.

The invention encompasses all types of organisms including all types of types of disease-causing pathogens causing infections and inflammations, all types of bacteria, all types of viruses, all types of cancer cells and tumors, all types of mould and all types of fungal microbes.

Summary of the Invention: short description

The invention builds on the observation that the air contains extremely low amplitude and low frequency electromagnetic waves of conduction current, and from now on called current, having periods equal to harmonics of the period 24 hours, e.g. the periods 24/m-2ⁿ hours. Water creates resonance with electromagnetic energy in the 2-10 Hz range. Water can be described as forced damped oscillators and in order to create resonance electromagnetic energy must be injected and the energy needed to maintain resonance is extremely small. Once water is in resonance, the resonance is maintained by electromagnetic energy in the air. Living species, including humans, have used this to their benefit. Specific cell types contain oscillators that create resonance at the period 24/3-2¹⁷ hours (4.55 Hz) and current in the air connects to the oscillators (cells). However, this current also creates resonance in the surrounding water contained in body fluids, blood and cells. This decreases the impedance of said water which increases the amplitude of the current causing a chain reaction where eventually all water is in resonance. This resonance creates frequency specific water molecule structures. Some biological processes (e.g. ion channels and receptors) depend on these stable water molecule structures. Pathogens contain a similar type of oscillator which creates resonance at a deviating period (often at the period 24/5-2¹⁶ hours (3.79 Hz)) and current in the air connects to the oscillators/pathogens. However this current also creates resonance in the surrounding water contained in body fluids, blood and cells causing a chain reaction where eventually water in the infected area has resonance at the pathogen resonance period and deviating from the host's resonance period. This disturbs biological processes in the host, including the immune system. Thus the pathogens can be detected and their position determined by measuring the current that connects to the infected area and the amplitude of said current is approximately proportional to the number of pathogens, e.g. the seriousness of the infection or illness. Two different methods are used. One is to measure current, present in the air and which connects to the pathogens and the water in the infected area. The other method is to generate electromagnetic energy at the pathogen specific period whereby this energy creates resonance and then the energy absorbed by the pathogens and the water in the infected area is measured.

All organisms that the inventor has investigated create resonance with said energy in the air and the presence of organism in organic and inorganic matter can be measured using the same methods as described above in connection with pathogens. The resonance amplitude is proportional to the number of organisms, implying that only populations above a certain size can be detected.

This is explained in the chapter Detailed Theory. Summary of the Invention: Achieved Results

Disease-causing organisms, e.g. pathogens such as pathogenic bacteria, pathogenic viruses, fungal microbes and cancer create resonance at a period deviating from the host and in most cases at one of the following periods 24/5-2¹⁶ hour (3.79 Hz), 24/7-2¹⁶ hour (5.31 Hz) or 24/9-2¹⁵ hour (3.41 Hz). The inventor has used the methods described in the invention to locate pathogens in humans. More than 50 persons have been investigated and among others the following types of illnesses/pathogens have been located: viruses (two different types of herpes), cancer (diagnosed intestine metastasis), skin cancer (actinic keratosis), stomach bacterial infections, infections caused as secondary effect of arthritis, ear infections and eye infections. In all cases the area of illnesses/pathogens can be located by measuring where the current enters the body and by turning the body creating at least two coordinates. It enables detection of some pathogens which are not possible to detect with methods used in medicine. It enables detection of pathogens inside the body by measuring current outside the body, e.g. without any type of disturbance to the patient or biological processes. The methods have also been used to detect and locate pathogens in trees and plants.

Organisms, other than pathogens, i.e. bacteria, fungal microbes and mould create resonance at one of the following periods 24/2¹⁸ hour (3.03 Hz), 24/3-2¹⁷ hour (4.55 Hz), 24/5-2¹⁶ hour (3.79 Hz), 24/7-2¹⁶ hour (5.31 Hz) or 24/9-2¹⁵ hour (3.41 Hz). The presence and relative number of such organisms have been measured in a large variety of food, beverages, see water, pool water etc. For instance it facilitates continuous and passive monitoring of organisms in processes (e.g. food industry) without need for any type of measurement of samples, agar bacteria growth etc.

Detailed Theory: introduction

The air contains low frequency and extremely low amplitude electromagnetic waves of conduction current (e.g. current) in the air, called l_Air. l_Air contains large amounts of harmonics, among others at the following periods: 24/2¹⁸ hour (3.03 Hz), 24/3-2¹⁷ hour (4.55 Hz), 24/5-2¹⁶ hour (3.79 Hz), 24/7-2¹⁶ hour (5.31 Hz) and 24/9-2¹⁵ hour (3.41 Hz) and this energy influences a number of processes in the human body and in other species. Water creates resonance in the same frequency range as l_Air and that is explained in the first part: Water. Some cell types contain oscillators that create resonance with l_Air and thus the cell absorbs the energy in l_Air. Cluster of cells and the absorbed energy create resonance in water in their vicinity and this influence a number of biological processes. This is explained in the second part: Cells. It's essential to understand the nature of l_Alrand that is explained in the part: Air. The last part explains how resonance is created and measured in organisms including pathogens.

Detailed Theory: water

Water creates electromagnetic resonance in the 2-10 Hz range, e.g. the same frequency range as harmonics of l_Air. Water contains angular molecules (H₂0) in which hydrogen and oxygen is joined by single covalent bonds where electron pairs making up the covalent bond create a small residual or partial positive charge (δ+) on the hydrogen atom, and a partial negative charge (δ-) on the oxygen atom. Water can dissolve a large number of ionic substances because of the interaction between the appropriate polarized end of the water molecule and ions. For example sodium chloride (Na⁺Cl^") solve in water with Na⁺ attracted to and CI^" to ^δ+Η. The polarized ends of H₂0 create an extremely small force that bonds H₂0 molecules called the hydrogen bond and this bond is elastic. Thus water can be described as a dielectric media having charge, mass and elasticity and the classical model based on a damped oscillator can be used, as described by Melrose and McPhedran¹. Consider a classical oscillator that corresponds to a mass m with charge q at a displacement X(t) from its mean position. Let the frequency of the oscillator be ω₀, and let it be damped with the decay constant y. The oscillator is assumed to be forced by an electric field E(t). The equation of motion is

X"(t)+ X'(t)+u)²oX(t) = qE(t)/m (1)

When the decay constant y is small the mass (and charge) oscillates at its natural frequency

where k is the elasticity (spring constant) which in this case corresponds to the elasticity of the hydrogen bond. It is the electromagnetic energy E(ij acting on the charge q that supplies the oscillator with energy and the oscillator resonance frequency ω₀ is determined by its mechanical properties m and k. The oscillator is in resonance with the applied energy when the energy E(tj has a frequency ω = ω₀ and the absorbed energy and oscillator amplitude is maximized. An adaptive media, like water, can change its natural frequency ₀ and the normal state is where the absorbed energy is maximized, e.g. ω₀ = ω and the media is then in resonance with the applied energy. The number of possible resonance frequencies in water containing ions is very large. Consider an overall tetrahedral water molecule structure as reported by Chaplin² and Head-Gordon et al.³. Positive ions (e.g. Na⁺) and negative ions (e.g. CI^") can form molecule structures together with H₂0 molecules where the structures creating resonance have small mass m and short distances (few hydrogen bonds equal to high spring constant k) giving high resonance frequency according to Eq. (2) or the opposite giving low resonance frequency. The hydrogen bond and its corresponding spring constant k depend on the force F between two residual charges following Coulombs law and it has a certain size in the longitudinal direction.

A small angular twist between two H₂0 molecules creates a twist in the hydrogen bond and the "angular" spring constant k_tw-_tst is magnitudes smaller than k. Thus the resonance frequency depends on how the molecule structure is oriented relative to the applied energy E according to Eq. (1). The number of possible molecule structures is very large and the number of resonance modes within each molecule structure is also large enabling a large number of resonance frequencies creating a continuous frequency response in the 2-10 Hz frequency range.

Detailed Theory: Cells

All living species including organisms, that the author has investigated, create resonance with one of the harmonics of the energy in the air i_r and therefore some cells must contain some kind of forced oscillator. The exact nature of this oscillator is not known and it may vary between species. Therefore the proposed mechanism is open for discussion. Nature often reuse and the mechanism used in the ion channel can explain the oscillator mechanism, MacKinnon R et al.^4,5,6. In its simplest form, and only as an example, it can consists of two oxygen O^" atoms embedded in the cell wall at a distance equal to two H₂0 molecules. ^δ+Η of one H₂0 molecule attaches to each O^" atom and therefore there are two H₂0 molecules locked to the 0^" atoms and on these two H₂0 molecules one Na⁺ ion can attach to the free ^δΌ and one CI^" ion can attach to the free ^δ+Η. This constitutes a forced oscillator having a fixed natural frequency ω₀ (e.g. fixed resonance frequency). A different pattern of embedded atoms create a different molecule structure and resonance frequency or period and thus cells can create resonance at the harmonics of l_Air having the periods 24/m-2" hours, m = 1, 3, 5, 7 and 9.

Humans have cells containing oscillators embedded in the skull bone, centered in the middle (top) of the skull and the cell oscillators are oriented so that they create resonance with l_Alr perpendicular (vertically) to the skull and at the period 24/3-2¹⁷ hour (4.55 Hz). In normal situations current l_Air always connects to the top of the skull of a healthy human and it creates resonance in the water contained in the brain fluids and cells and a specific molecule structure is created and the blood circulation distributes this water to the rest of the body. The human body and its water is in resonance with l_Air at the period 24/3-2¹⁷ hour. In trees and plants the cells containing oscillators are embedded in the upper part of the root system, creating similar resonance in their water.

The spectrum of bacteria is enormous and the inventor has found bacteria that create resonance (contain oscillators) at the periods 24/2¹⁸ hour (3.03 Hz), 24/3-2¹⁷ hour (4.55 Hz), 24/5-2¹⁶ hour (3.79 Hz), 24/7-2¹⁵ hour (5.31 Hz) and 24/9-2¹⁵ hour (3.41 Hz). For instance a piece of fouled meat or polluted water contains a broad spectrum of bacteria that create resonance at all of the above periods. As an example the bacteria Lactobacillus acidophilus, Lactobacillus plantarum 299v and Shigella sonnei create resonance at the period 24/5-2¹⁶ hour (3.79 Hz). A bacteria culture (e.g.

Lactobacillus acidophilus or Lactobacillus plantarum 299v) positioned in water makes the conduction current l_Air propagate into the water and it creates resonance in the water and the water molecule structure is changed. Thus bacteria indirectly change the molecule structure of water in their vicinity. A few types of viruses (ex. herpes) have been investigated and they create resonance at the period 24/5-2¹⁶ hour (3.79 Hz). Two type of cancer (malignant tumors) have been investigated, they create resonance at the period 24/5-2¹⁶ hour (3.79 Hz). Skin cancer (actinic keratosis) creates resonance at the period 24/9-2¹⁵ hour (3.41 Hz). Bacterial infections normally create resonance at the period 24/5-2¹⁵ hour (3.79 Hz) but sometimes at 24/7-2¹⁶ hour (5.31 Hz) or 24/9-2¹⁵ hour (3.41 Hz).

The following is observed. A healthy person always creates resonance at the period 24/3-2¹⁷ hour (4.55 Hz) and the resonance amplitude is relatively large which can be measured by means of l_Air (typically 0.2 -0.5 pA) connecting to the person's skull. A pathogenic bacteria or virus infection makes l_Alr, having a different period (usually 24/5-2¹⁶ hour (3.79 Hz)), connect to the infected area and it creates resonance. At serious infections the amplitude increases and at the same time the amplitude of resonance in the body water decreases at the period 24/3-2¹⁷ hour (4.55 Hz) because of the interference caused by the two resonance mechanisms. Serious infections, inflammations and malignant tumors causes the resonance at the period 24/3-2¹⁷ hour (4.55 Hz) to cease almost completely. The resonance at the period 24/3-2¹⁷ hour (4.55 Hz) gradually regains its amplitude as the person cures.

An interesting observation is that beneficial bacteria (e.g. intestine bacteria), which live in symbiosis, create resonance at the period 24/3-2¹⁷ hour (4.55 Hz), e.g. the same period as the host.

Detailed Theory: Air

Interaction between low frequency plane transverse electromagnetic waves, called EM waves and electrons in the air creates a low frequency resonance phenomenon in the air and current l_Air having the basic period 24 hours and harmonics with periods 24/m-2ⁿ hours. The earth's geomagnetic fields rotate in the sun wind and this creates current density J with 24 hours period in the magnetosphere and the current propagates along the magnetic field lines. It is called Birkeland current and is described by Potemra⁷. The relationship between the magnetic field strength H, the current density J and displacement D is according to Maxwell's equation

curl H = i+dD/dt (4)

and thus the current density J creates plane transverse EM waves as described by Bleaney⁸ and Hallen⁹. The EM waves are square wave shaped having the period 24 hours and a large number of harmonics and propagates along the geomagnetic field lines towards the earth.

The global electric circuit describes how lightning transfers electrons to the earth crust and how the 200 kV potential between the atmosphere and earth crust transfers the charge back to the atmosphere and thus the air contains * 500 pC/m³ electrons as reported by Israel¹⁰, Israelsson et al.¹¹, Roble¹² and Rycroft et al.¹³. The EM waves, having electric field vectors E, create an electric body force pE on the charge density p (electrons) in the air and it makes the electrons drift in an oscillating motion and create current l_Alr in the air. The electrons in the air can accumulate (-q) and deplete (q) and drift (l_Air). Two charges -q/q at some distance with l_Air in between is a forced oscillator with time constant q/l_Air and when qr/l_Air equals the period of the applied EM waves (or harmonics) the forced oscillator oscillates (is in resonance). Air is an adaptive media: its charge has large freedom in distribution. An adaptive media strives to maximize the absorbed energy, e.g. the oscillators adapt their charge so that they create resonance with applied energy. The global electric circuit supplies the air and the oscillators with charge until q/\_Mr has a value that creates resonance and from that point on surplus charge is transferred to the atmosphere. It's self regulating.

Being an adaptive media air strives to organize the oscillators so that the absorbed energy is maximized: the oscillators are organized into a 3D matrix where the oscillators are mutually coupled. The 3D matrix has a logical structure and it consists of only one repetitive basic element: four charges are organized into a horizontal quadrant as illustrated in Figure 4. Two charges, -q and q (115), and conduction current l_Air (116) between the charges comprise one oscillator. Thus the four charges comprise four oscillators (mutually coupled and oscillating in two dimensions). The starting point of the 3D matrix is one quadrant oscillating at the period 24 hours, consisting of a quadrant of four oscillators at the period 24 hours, each denoted 24i in Figure 5. This quadrant is divided into four new quadrants, each containing four oscillators, denoted 24₂, and which oscillate at the period 24/2 = 12 hours. Each of these quadrants is divided into four new quadrants, each containing four oscillators, denoted 24₄, and which oscillate at the period 24/4 = 6 hours and so it continues until a fine meshed grid is created because the process is non linear. This pattern is repeated in all four geographical directions forming a large 2D grid as illustrated in Figure 5. Figure 5 shall be interpreted in the following way. The "line" denoted 24_x consists of a long chain of oscillators (q, -q, q, -q, q etc.) at the period 24/1 hours and super positioned there are oscillators at the periods 24/2, 24/4 etc. hours; altogether 24_x consists of a chain of super positioned oscillators and super positioned conduction currents having the periods∑24/2ⁿ, n = 0, 1, 2, 3, 4, ....hours. 24₂ consists of a chain of super positioned oscillators and super positioned conduction currents having the periods∑24/2ⁿ, n = 1, 2, 3, 4, ....hours, and so it continues. Thus the electrons in l_Air only have to bridge the distance of the shortest oscillator/dipole in the chain and that explains why conduction current having extremely long period can be transported in a stable way in the air. The air contains one horizontally positioned 2D grid approx. 1 meter above ground and then every 3 meter there is another (phase shifted) horizontal 2D grid. Figure 6 illustrates how layers of 2D grids (117) form a 3D matrix (118). In those nodes where the energy or amplitude is sufficiently high there is also resonance in the vertical plane, thus the horizontal 2D grids are interconnected (and mutually stabilized) by vertical oscillators and current l_Air (119). Thus the 3D matrix oscillates in 3 dimensions.

The first odd harmonic having the period 24/3 = 8 hours creates a similar 2D grid oriented east-west (i.e. 45 degrees to the above 2D grid) having oscillators at the periods 24/3-2" hours and since the two grids emanate from the EM waves they are in phase in some nodes, theses nodes contain vertical oscillators (that oscillate at the periods 24/2" and 24/3-2" hours) and vertical I_Air (119) and therefore the two grids are linked by mutual resonance creating a common 3D matrix. The 3D matrix also contains oscillators and l_Air at the periods 24/5-2", 24/7-2" and 24/9-2" hours. Thus the 3D matrix oscillates in three dimensions and in many modes. It's a complex but logical structure.

The amount of harmonics in the 3D matrix is very large. Thus l_AIr contains harmonics having the following periods: 24/2¹⁸ hour (3.03 Hz), 24/3-2¹⁷ hour (4.55 Hz), 24/5-2¹⁶ hour (3.79 Hz), 24/7-2¹⁶ hour (5.31 Hz) and 24/9-2¹⁵ hour (3.41 Hz). These periods/frequencies coincides with the frequency range 2 - 10 Hz where water creates resonance.

Detailed Theory: Creating and measuring current in air

Resonance in organisms and water, created by electromagnetic energy, occurs at low frequency and extremely low amplitude. Low frequency (≤ 10 Hz) and extremely low amplitude (< 1 pA)

electromagnetic energy is not possible to measure using conventional methods and therefore a novel technique is used. The method builds on basic principles and laws of electromagnetism as follows.

Figure 7 shows two electrodes (120) and (121) that are spaced at some distance (e.g. 2 m)and connected, via wires, to a voltage source (122) (e.g. 1 - 10 V). The voltage source creates the electric field E (123) between the electrodes. The air contains approximately 500 pC/m³ electrons, e.g. charge q caused by the global electric circuit causing approximately 3 pA/m² vertical current density in the air. Thus the air has a certain conductivity a creating a current density J between the electrodes according to ohms law, Bleaney⁸, Hallen³

J = oE (5)

According to Biot-Savarts law the magnetic induction B from a current I and the current element ds is

B = ( o/47t) Jldsxr/r³ (6)

Eq. (6) can be written in a more generalized form using the current density J and integrating over the volume v as described by Hallen⁹

B = (n₀/4n) JJJ(Jxr/r³)dv (7)

Thus the current density J created by the electric field (123) induces a magnetic field B according to Eq. (6) and according to Eq. (7) the magnetic field B increases with increasing volume v. The normal state is where B is minimized causing the electrons and current I (124) to propagate in a narrow flow or a narrow "current tube".

The force dF exerted on an element of wire ds, carrying a current I in a magnetic field Boa is

dF = KdsxB_Exr) (8)

Thus an external perpendicular magnetic field BEXT (127) exerts a force on the current I (124) which makes the current I move sideways (125) and empirically it has been found that for moderate magnetic fields the distance d (126) is proportional to the current I and the magnetic field Boa according to Eq. (7) and Eq. (8). The external magnetic field can be created by for instance a permanent magnet (127) or a conductor carrying current and creating a field according to Eq. (6).

The following experiment, Figure 8, explains the measurement method. Two electrodes (128) and (129) are positioned at some distance (e.g. 2 m) in the air. The electrodes are connected via wires to a signal generator (130). The generator is set to 5 Hz sinus and the output amplitude is 0.5 mV RMS. This creates the current I in the same way as described above in connection with Figure 7, however, this current is alternating and can thus be regarded as two separate, parallel, current components Ii (131) and l₂ (132) propagating in opposite directions. When an external magnetic field Βεχχ (134) is applied between the two current directions, Ι_χ and l₂ are each influenced by a force according to Eq. (9) and as described in connection with Figure 7. Thus the distance cf^ (133) is proportional to h (131) and d₂ (140) is proportional I₂ (132), measured as instant values. The peak value of άχ respectively d₂ are measured and correspond to the peak value of l_x respectively l₂. Typically the distance d_x is 1-2 m at generator amplitude 0.5 mV (e.g. I = 0.5 pA) and B = 1 mT. Thus extremely small currents can be accurately measured by measuring its position (e.g. (131) or 132)).

l_Air behaves in the same way, e.g. l_A,_r propagates in a controlled way according to Eq. (7) and it explains why the 3D matrix is stable having low loss. The amplitude and periods of l_Aircan be measured using the above method, e.g. inserting a permanent magnet (a magnetic field) between the two current directions and measuring the deviation as function of time.

The current Ιχ and l₂ are measured using the following method. Ii (and l₂) consist of electrons and the charge density p is significantly higher within li than in the surrounding air: thus there is an abrupt change of charge. Ij. can be described as distributed charges £¾and the force F between charges q_p and charges q_k in l_x follows Coulomb's law according to Eq. (3) but modified for many charges

Figure 9 illustrates how current in the air can be measured. A short wire, called a probe (135), is utilized. The probe contains the charges ¾ and the probe is moved through Ii ( or l₂ or ΙΑ_ΪΓ) · It creates an impulse on the charges ¾, which results in a current pulse. The probe is connected to a high gain JFET amplifier (136), the pulse is band pass filtered (137) to remove DC and AC noise, further amplified (138) and displayed (139). Thus accurate measurements can be made on a number of parameters by simply measuring the deviation of I. The measurement accuracy is < +/- 5%. Detailed Theory: Creating and measuring resonance in organisms and pathogens.

The presence of organisms and pathogens and the resonance they create can be measured using two different methods.

Using the first method the presence of organisms and pathogens is determined by the resonance created by l_A]r. The current l_Alr which connects to the organisms or the pathogens and the water in their vicinity is measured. l_Air always propagates from a specific spot in the 3D matrix to the area in resonance. The infected area can be precisely located by marking the entrance to the body and then turning the body 90 degrees and calculating the crossing point of the two l_Air inside the body. Period, amplitude and position can be determined. Using the second method the presence of organisms and pathogens is determined by resonance created by electromagnetic energy generated by a low frequency electromagnetic energy source. This energy has preferably higher amplitude than the corresponding _r so that the resonance is dominated by the generated energy instead of U_r. Since the two sources have slightly different period and phase the connection to U_r ceases. The energy absorbed by the organisms or pathogens and the water in their vicinity is measured. This energy can consist of electric fields, magnetic fields, current or a combination of said energies having one of the periods 24/2¹⁸ hour (3.03 Hz), 24/3-2¹⁷ hour (4.55 Hz), 24/5-2¹⁶ hour (3.79 Hz), 24/7-2¹⁶ hour (5.31 Hz) or 24/9-2¹⁵ hour (3.41 Hz) and depending of the resonance period of the organisms.

Detailed Theory: conclusions

There is a reason that so many different types of species including organisms (e.g. all species that the inventor has investigated with no exception) create resonance and absorb low frequency energy present in the air. Advanced life forms create resonance at the period 24/3-2¹⁷ hour (4.55 Hz) while pathogens such as pathogenic bacteria, pathogenic viruses and cancer but also mould and fungus create resonance at other periods, usually 24/5-2¹⁶ hour (3.79 Hz). Evolution of life has developed some biological processes where the processes are controlled or influenced by specific water molecule structures. Therefore advanced life forms have cells containing oscillators embedded at a strategic place (e.g. the skull bone) which certifies that its water always is in resonance with _r and that the proper molecule structures are maintained. Organisms also contain oscillators and they use the complete spectrum of available harmonics. Disease-causing organisms (e.g. pathogens) contain oscillators having a period different to the host since that enables the pathogenic bacteria, pathogenic viruses, cancer or fungal microbes to disturb biological processes in the host and this enhances their chance of survival.

Pathogens can be detected and in most cases accurately located by measuring the energy they absorb at resonance. Their resonance period and resonance amplitude can be determined.

Organisms in organic and inorganic matter can be detected and their resonance period and resonance amplitude can be determined.

Detailed Theory: References

1. Melrose D. B, McPhedran R. C. Electromagnetic processes in dispersive media. Cambridge University Press, Cambridge, pp 106-110 (1991).

2. Chaplin M. A proposal for structuring of water. Biophysical Chemistry. 83, 211-221 (1999).

3. Head-Gordon T, Johnsson M. E. Tetrahedral structure or chains for liquid water. Available online http://www.pnas.org/cgi/doi/10.1073/pnas.0510593103 (2006).

4. MacKinnon R, Morais-Cabra J. H, Zhou Y, Mann S. Potassium channel receptor site for the inactivation gate and quaternary amino inhibitors. Nature. 411, 657-661 (2001).

5. MacKinnon R, Morais-Cabra J. H, Zhou Y. Energetic optimization of ion conduction rate by K⁺ selectivity filter. Nature. 414, 37-42 (2001).

6. MacKinnon R, Morais-Cabra J. H, Zhou Y, Kaufman A. Chemistry of ion coordination and hydration revealed by a K* channel-Fab complex at 2.0 A resolution. Nature. 414, 43-48 (2001).

7. Potemra T. A. Observation of Birkeland currents with the TRIAD satellite. Astrophysics and Space Science. 58, 207-226 (1978). 8. Bleaney, B.I. Electricity and Magnetism. Oxford at the Clerendon Press (1965).

9. Hallen, H. Elektricitetslara. Almqvist &Wiksell, Upppsala. (1968).

10. Israel H. Atmospheric Electricity. U.S. Department of Commerce, Springfield (1973).

11. Israelsson S, Knudsen E, Anisimov S. V. Vertical profiles of electrical conductivity in the

lowermost part of the turbulent boundary layer over flat ground. Journal of Atmospheric and Terrestrial Physics. 56, No. 12: 1545-1550 (1994).

12. Roble R. G. On modelling component processes in the Earth's global electric circuit. Journal of Atmospheric and Terrestrial Physics. 53, 831-847 (1985).

13. Rycroft M. J, Israelsson S, Price C. The global atmospheric electrical circuit, solar activity and climate change. Journal of Atmospheric and Solar-Terrestrial Physics. 62, 1563-1576 (2000).

Brief Description of the Drawings

The invention will be described in more detail in the following, with reference to the appended drawings, in which:

Figure 1 describes a method to create current in the air.

Figure 2 describes the equivalent electric circuit of Figure 1.

Figure 3 describes a method to measure absorbed electromagnetic energy.

Figure 4 describes the resonance mechanism of current in air.

Figure 5 describes the forming of even harmonics of current in air.

Figure 6 describes how 2D grids of current form a 3D matrix.

Figure 7 describes the principle of creating DC current in air.

Figure 8 describes the principle of creating AC current in air.

Figure 9 describes a method to measure current in air.

Description of the Invention

The object of this invention is to create a method to measure the presence and characteristics of organisms by measuring the absorbed energy at the resonance period of said organisms.

The method is to expose said organisms to electromagnetic energy which creates resonance in said organism and where the period is always one of the periods 24/2¹⁸ hours (3.03 Hz), 24/3-2¹⁷ hours (4.55 Hz), 24/5-2¹⁶ hours (3.79 Hz), 24/7-2¹⁶ hours (5.31 Hz) or 24/9-2¹⁵ hours (3.41 Hz) and where one kind of organism have resonance at one of said periods. Said organisms include all types of organisms including all types of types of disease-causing pathogens causing infections and inflammations, all types of bacteria, all types of viruses, all types of cancer cells and tumors, all types of mould and all types of fungal microbes.

Said electromagnetic energy can consist of electric fields, magnetic fields, current or a mixture of said electromagnetic energies. Initially the amplitude must be below the level where water in the vicinity of the organisms creates resonance and at the same time above the level where the organisms create resonance which is usually easy to achieve since the difference in amplitude is at least one magnitude. At resonance the absorbed energy increases dramatically since the impedance of the organisms and the water in the vicinity of the organisms decreases many magnitudes enabling measurement of the absorbed energy. The invention includes the following method as described in Figure 1. An electrode or oscillator (e.g. resonance mechanism) (100) is connected to a signal generator (101). The organisms (102) which for instance can be a sample of bacteria in vitro or the patient having a pathogenic infection is positioned preferably 0.5 - 2 m from the electrode (100). The generator output voltage is preferably 0.1 - 1 mV RMS and the period equal to the resonance period of the organisms, for instance the period 24/5-2¹⁶ hour (3.79 Hz). This creates an electric field and current which is far below the amplitude needed to create resonance in the water contained in the sample in vitro or the patient, however, sufficient to create resonance in said organisms (102). This decreases the impedance creating low amplitude current between the electrode (100) and said organisms (102). This current is sufficient to create resonance in some water in the vicinity of said organisms which further decreases the impedance and increases the current causing a chain reaction where eventually all water in the sample in vitro has resonance at the period 24/5-2¹⁶ hour. The situation in vivo is different because the host strives to create resonance at the period 24/3-2¹⁷ hour (4.55 Hz) and this creates equilibrium where the amount of water in resonance at the pathogen period depends on the number of pathogens or the seriousness of the illness. The current components l_x (103) and I₂(104) are measured and preferably using the methods described in the chapter Detailed Theory in connection with Figure 8 and Figure 9 and as described below. The pathogens can be located by noting the crossing point where the current enters the body while turning the patient 90 - 360 degrees. The equivalent electric circuit is shown in Figure 2. The equivalent of the organisms and pathogens including water in their vicinity is a serial LC circuit (107) having low impedance at the resonance frequency, the impeda nee of the air is Z_Ai_r (108) and electrons in the air constitute the return path having the impedance Z_Retpath (109). At resonance the impedance of (107) is small relative to the impedances of the air (108) and (109) and generator amplitude must be kept at low amplitude, otherwise the transfer function of air becomes non linear.

The invention includes a method using current l_Air, which is naturally present in the air, when measuring the presence and characteristics of organisms including pathogens. l_Air connects to the organisms and can be measured in the same way as described in connection with Figure 1. It is beneficial to position the sample or the patient at a fixed location because l_Alr having a specific period always propagates from a specific position within the 3D matrix as illustrated in Figure 5 and Figure 6. Thus the period of l_Air can be empirically decided by noting its origin or from which direction it propagates towards the sample or patient. In some cases the sample, for instance fouled meat, contains a broad spectrum of bacteria having resonance at many periods. In that case many l_Air, having different periods, connect to the sample and propagating from different directions.

The invention includes the following method to measure the amplitude of current in air. Current in air propagates as two separate parallel current components l_x (103) and l₂ (104) having opposite directions and separated at a distance (105) when exposed to a magnetic field (106) as illustrated in Figure 1. Said distance is measured and said distance is proportional to the peak-to-peak amplitude of said current. This method allows accurate measurement {≤ +/- 5%) of extremely small conduction current (0.05 -1 pA) by simply measuring the position of li (103) or l₂ (104) using the method and apparatus described in connection with Figure 8 and Figure 9. The invention includes variants of this method where for instance the current (103) is measured at fixed positions and where the magnetic field (106) is changed until a certain deviation is reached or variants where the magnetic field is applied at different positions relative to li and l₂. The invention includes a method where the energy absorbed by the organisms and water in resonance is measured by means of the electromagnetic energy that the absorbed energy emits and preferably the emitted electric fields. The organisms and water in resonance create electric fields having the same period as the resonance period of said organisms. These fields can be measured in the vicinity of said organisms preferably using an apparatus containing a sensitive E-field probe (an apparatus that measures electric fields) and where the signal is preferably band pass filtered at one of the following periods and selecting the resonance period of said organisms: 24/2¹⁸ hour (3.03 Hz), 24/3-2¹⁷ hour {4.55 Hz), 24/5 ·2¹⁵ hour (3.79 Hz), 24/7-2¹⁶ hour (5.31 Hz) or 24/9-2¹⁵ hour (3.41 Hz). The method can be implemented as illustrated in Figure 3 consisting of an apparatus containing an E- field probe (110), a high gain amplifier (111), a digital band pass filter (112), further amplification (113) and a display (114). This method facilitates relatively good location of for instance pathogenic infections, its amplitude and period.

In general it is preferable to use current created by a generator according to Figure 1 because this method allows better control of the process and the amplitude of the current can be controlled and also monitored at the source. This method also allows injection of more energy into the organisms or the infected area yielding larger resonance amplitude and higher amplitude current which simplifies measurements.

Claims

A method to measure the presence and characteristics of organisms, characterized by that said organisms create resonance when exposed to electromagnetic energy at the periods 24/2¹⁸ hour, 24/3-2¹⁷ hour, 24/5-2¹⁶ hour, 24/7-2¹⁶ hour and 24/9-2¹⁵ hour, < +/- 1 %, causing resonance also in water in the vicinity of said organisms which leads to that a part of said electromagnetic energy is absorbed by said organisms and said water and where said absorbed electromagnetic energy is measured by means of its period, amplitude and position and where said organisms include all types of organisms including all types of disease-causing pathogens causing infections and inflammations, all types of bacteria, all types of viruses, all types of cancer cells and tumors, all types of mould and all types of fungal microbes and where one kind of organism creates resonance at one of said periods. The method according to claim 1, characterized by exposing said organisms to generated electromagnetic energy having one of the periods 24/2¹⁸ hour, 24/3-2¹⁷ hour, 24/5-2¹⁶ hour, 24/7-2¹⁶ hour or 24/9-2¹⁵ hour,≤ +/- 0.1 %, whereby the resonance period of the examined organisms is selected.

The method according to claim 2, characterized by that said electromagnetic energy consists of current in the air created by an electrode or oscillator connected, preferably via a wire, to a signal generator and where said electrode or oscillator is positioned at some distance, preferably 0.2 - 2 m, from said organisms and where the location of said organisms, including pathogens, is determined by measuring the position where said current enters the object or biological agent containing said organisms and where the amplitude of said current is measured and where said amplitude is approximately proportional to the number of pathogens or seriousness of the illness.

The method according to claim 1, characterized by that said organisms create resonance with current which is naturally present in the air and where the amplitude of the absorbed current is measured and where the location of said organisms, including pathogens, is determined by measuring the position where said current enters the object or biological agent containing said organisms and where said amplitude is approximately proportional to the number of pathogens or seriousness of the illness.

The method to measure the amplitude of current according to claims 3 - 4, characterized by that said current consists of two current components having opposite directions and where each current component changes direction of propagation when exposed to a magnetic field and where said change of direction is measured and where said change of direction is approximately proportional to the amplitude of said current and the amplitude of said magnetic field and where the amplitude of said magnetic field can be varied.

The method to measure the absorbed energy at resonance according to claims 1-4, characterized by that said organisms and said water emit electromagnetic energy and where said energy is measured and where preferably the emitted electric fields are measured using an E-field probe and where the amplified signal is preferably band pass filtered at one of the periods 24/2¹⁸ hour, 24/3-2¹⁷ hour, 24/5-2¹⁶ hour, 24/7-2¹⁶ hour or 24/9-2¹⁵ hour and where the resonance period of the examined organisms is selected.