EP1227864A1

EP1227864A1 - Device and method for determining biological information and for controlling biological systems

Info

Publication number: EP1227864A1
Application number: EP00971383A
Authority: EP
Inventors: Dietrich Reichwein; Olaf Peters
Original assignee: Individual
Current assignee: Individual
Priority date: 1999-11-11
Filing date: 2000-10-16
Publication date: 2002-08-07
Also published as: WO2001034096A1; AU1025501A

Abstract

The invention relates to a device and a method for determining biological information and for controlling biological systems. These types of devices and methods are used for example, to intervene in biological processes, for eliminating harmful cell states, in the reduplication of cells and organisms and in the manipulation of the genetic material of an organism. In particular, the inventive device has a sensor (6) for electromagnetic longitudinal waves which produces a data signal for longitudinal waves.

Description

Biological detection device and method

Information and for the control of biological systems

The present invention relates to an apparatus and a method for acquiring biological information and an apparatus and a method for controlling biological systems, such as for example for interfering in biological processes, for removing harmful cell states, for the reduplication of cells and organisms, and for Manipulation of an organism's genetic material can be used.

The influencing of biological processes by means of electromagnetic devices is widely known from the prior art. For example, biophoton spectral analysis, biological resonance nance techniques, the application of magnetic fields for faster germination or to accelerate vital processes in general. All these facilities have in common that their control sequences are based on empirical values, are therefore empirically determined and that a biological response is to be brought about through field effects.

In applied technology, Nikola TESLA gave a detailed talk for the first time in 1895 about information transmission in open circuits with single conductors without a return line, but also wirelessly over large distances. As a result, however, data transfer over Hertz's waves prevailed, and longitudinal waves were no longer considered until biological distortions due to technical waves were observed; This is not least because lateral waves (transverse waves) could be completely described using Maxwell's equations. In comparison, potential vortices (longitudinal waves) have so far not been measured, so that instead of the vortex, any effects originating from the potential vortex have been measured and evaluated. Such effects can be eddy losses or repercussions on the stimulating field. However, such measurements require that the effect actually occurs.

It is therefore an object of the present invention to provide devices and methods for recording biological information and for controlling biological systems, as well as uses of such devices. This object is achieved by the devices according to claim 1 and claim 14, the methods according to claims 29 and 37 and by the uses according to claim 40. Advantageous developments of the devices and methods according to the invention are given in the respective dependent claims.

Fundamental to the present invention is the recognition that cellular control pulses in the form of potential vortices, ie longitudinal waves, as data are transfer support not only in the cell structure, but also within a single cell effectively .. Vofausset- ^"requisite for data transfer in the cell area is that the vortex really disintegrates after a relaxation time to make room for the next data-transferring potential vortex.

As the vortex of the dielectric, the potential vortex within the cell fluid will find defined relationships through its magnetic and electrical permeability.

Because of the fundamental prerequisite for vertebral decay at the receptor with detachment of a subsequent vortex with extended data content within the relaxation period and coupling to the triggering lateral field, the basics of the physical nature of the present invention are mathematically derived below:

1. Flood Law:

With Ohm's law: j = σ * E

Dielectric shift: D = s * E relaxation

Equation 1:

2. Induction law (according to B dB

Duality rules expanded): -rotE = - + - ^k 2 Ct

With induction: B = μH

Equation 2: - red E =

Insert Equation 1

-red red E = ΔΞ-graddivE = ΔE da: div E = 0 1

Abbreviation: ^ε - ^~ τ

3rd Fundamental field equation:

Ref .: Prof. Dr. Konstantin Meyl: Electromagnetic environmental compatibility, causes, phenomena and scientific consequences, reprint for the lecture ISBN 3-9802-542-9-1 and ISBN 3-9802-642-8-3. Potential Vortex Vol. 1 and 2 by Prof. Dr. Konstantin Meyl., ISBN 3-9802-542-1-β and ISBN 3-9802-542-2-4.

Due to the law on flooding, the current density within the cell volume is the same and corresponds to the vortex density of the magnetic field strength.

Hence: rotH = i + -

^J dt

Ohm's Law = σ * E

Dielectric shift

D = ε * E

Relaxation time: ε The relaxation time indicates how quickly the eddies disintegrate. To this extent, known relationships can be used (potential eddies Vol. 1 and 2, Prof. Dr. Konstantin Meyl, see above).

The result is

As an extension, the new electric field vortices require the introduction of a corresponding time constant τ ₂ , which should describe the decay of the potential vortices. The expanded law of induction describes a potential density that corresponds to the electric field strength at every point in the cell space:

B 6B

-rotE => et

The result fulfills the required duality for equation 1:

According to the rules of vector analysis, it can be further simplified:

red red E = ΔΞ - grad div E

it should be noted that the divergence disappears when the corresponding field vortex is formed.

The cell behavior of living cells can be understood from the above derivation. The potential vortex will caused by the lateral wave field, with a strict coupling of both components, lateral wave field and longitudinal wave field, during the relaxation time. The formation and decay of the potentials cause electrical fields of a considerable order of magnitude on a cell membrane

V n— (cell membrane potential). m

These interplay of electrical field sizes and magnetic field sizes are now expressions of life of animated material structures. The effects of potential vortices can be measured as electromagnetic waves due to the coupling derived above.

Thus, the cellular electromagnetic system control (ZES) in the formation of potential vortices and their delivery with data absorption at the receptor can be measured in their mode of operation by means of measurement technology, decoded by computer-aided signal analysis and applied to cells in the sense of the present invention by means of technical binding systems.

A cause-finding of the processes of the cellular electromagnetic system control resulted in a function course which is based on the proton oscillation of the protein molecule. Because only amino acids have the prerequisite to enable animation-required signal emissions as protein molecule chains - combined into cells. Because proton oscillations of the protein molecules are a prerequisite for the design of animatable material structures.

1 schematically shows a protein molecule 1 as a chain molecule, based only on charge carriers. in whose structure a proton is alternately not compensated by an adequate number of electrons n * e ^~ at one end of a chain of amino acids 2.

As a result, the electrons n * e ^~ migrate from proton "A" at the beginning of the amino acid chain to proton "E" at the end of the amino acid chain molecule.

For the formation of potential vortices, it should be noted that an electrical charge, when it is moved in space, generates a magnetic field orthogonal to the direction of the orbit.

This applies to protein molecule 1 for the charge fluctuation of n * e ^~ . The resulting ultra-weak electromagnetic fields, as far as caused by the charge fluctuation n * e ^~ , obey Maxwell's equations. In addition, one proton remains alternately uncompensated at the respective end of said chain molecule and appears as proton oscillation. However, this oscillation is only virtual, since the position of the charge in the field is not changed, only a fluctuation of compensated charge n * e ^~ and uncompensated charge n * e ⁺ occurring alternately at different positions, gives the impression of an oscillation with measurement technology (not really) position change from "A" to "E". This rhythmic charge change replaces a ring-shaped potential vortex by slightly overriding the actual movement of the charges n * e ^~ , which functions as a data transfer with the sequence vortex formation - vortex path - »data transfer to the receptor with vortex decay -» vortex formation at the receptor with data expansion of the receptor data field through data taken from the absorbed and zeptor collapsed vertebrae takes over. The data content or data identification is the vortex package with variable vortex density. This formation of the vertebral packets represents eo ipso a stimulus-response sequence as an expression of life in the environment (stimulus), the response being environment-penetrating, as far as it can be observed as a metabolic event within the scope of the cell's active range. It is only this potential vortex detachment with subsequent sequence course, as explained above, in the association of complex amino acid compounds in the form of encoded vertebral packets, which enables the animation of cell structures. Metabolic processes controlled in this way cover the energy requirements of the cells and, in addition, the ability to procreate with ideal reduplication of the cell structure. If the data transmission is disturbed during the procurement process, aberrations or mutations occur when new cells form, as is sufficiently known from the processes of cooking technology (yeast).

It can now be explained that the individual frequencies of the protein molecules within a cell and beyond within the cell groups should not form any interferences with one another. A cell cluster, the individual frequencies of which the protein molecules emit consonant and non-dissonant fields to form a sum frequency, is called lying according to the norm of the expected vitality level, and it forms the Cellular Electromagnetic Basic System (ZEB) within the framework of the Cellular Electromagnetic System Control (ZES). If the individual frequencies become dissonant to each other, the vital potential decreases with increasing dissonance. This corresponds to a qualitatively and quantitatively changed cellular electromagnetic base system (ZEB) in the direction of aberration. Diverges the total frequency due to dissonance Zero, the Cellular Electromagnetic Base System (ZEB) collapses. This is a collapse of all expressions of life and thus the end of the animation.

In the case of active cell events, the emitted lateral waves ensure that the individual frequencies correspond to a resulting sum frequency, i.e. Consonance the vital potential of the life unit.

The potential vortices emitted primarily by the nucleus and also by the other cell organelles with the functionally relevant relaxation times ti and τ ₂ are the determining variables of the cellular electromagnetic system control. The coding of the frequency pattern is given by the quantitative packet density and qualitative formation of the potential vortex processes. By means of said coding, individual cells differ from one another and pass the respective data content to the neighboring cells by means of vortex induction. Vortex packets are thus formed on the one hand by potential vortex detachment as a result of virtual proton oscillation and on the other hand by induction processes of existing vertebrae which release their energy content (= data content) to the induced subsequent vortex during the vortex resolution. Vortex packets formed in this way, variable in packet density and formation in a stimulus-response sequence, together form the Cellular Electromagnetic Basic System (ZEB) in the cell structure. This can now (see above mathematical explanations) in correlation with a variable lateral wave field and associated information content - in the sense of the inventive concept - be ascertainable as a measurable expression of life of cells and cell groups and can be decoded with the aid of a computer. Thus, the specific species-specific properties are clearly defined in the cell structure.

Distortions of biological and abiological nature of different genesis, as well as noxae of all kinds cause changes in the electrical and magnetic permeability of the cell fluid, and consequently in the relaxation times, i.e. they prematurely or protract an aberrated cellular electromagnetic system control (ZES).

In the knowledge of the detailed processes, technical precautions can now be taken to intervene arbitrarily in a controlled manner in the Cellular Electromagnetic System Control (ZES) and thus also in the Cellular Electromagnetic Basic Control (ZEB), for example in order to rule out undesirable mutations in cloning processes, in gene manipulations the risk of randomness and selection by means of technical specifications - Exclude empty or cell-significant information patterns, such as in seed development or seed production. The invention can furthermore advantageously be used in the pharmaceutical industry for the research and development of new medicaments, in particular on the basis of histological samples, as a result of which lengthy animal experiments are avoided.

Some examples of devices according to the invention are described below:

Show it:

1 shows the charge oscillation of a protein molecule;

Fig. 2 shows a device for detecting biological

Information; 3 shows a further device for recording biological information; Fig. 4 shows a device for controlling biological

systems; 5 shows an AC / DC amplifier as a coil feed device; 6 shows a small double sink; Fig. 7 a bifilar small 'see coil, and

Fig. 8 shows the winding scheme of two different bifilar Klein's coils.

1, as described above, schematically shows the charge oscillation of a protein molecule 1 (protein). As mentioned above, said electromagnetic emissions consist of two components:

Once from a pure lateral waveform caused by the fluctuating negative charges n * e ^~ ,

on the other hand as potential vortices in longitudinal wave form, which are caused by the alternate exposure of positively charged protons n * e ⁺ .

2 shows how the lateral waves generated by a biological system in an eprovette, which for the sake of clarity is only shown twice as eprovette 5a and 5b, are detected by a sensor in coil form, while the potential vortices in longitudinal wave form are detected by means of a single-wire sensor 6, advantageously made of ferromagnetic material and / or gold-plated. Amplifier circuits 8 and 9 amplify the respective signals while suppressing background noise. Since the lateral wave field as exciter and the longitudinal wave component as potential vortex formation are strictly coupled to one another during the relaxation period, it is also advantageous to record both components and to present them as a measured variable and, by means of an integrator 10, combined to be passed on to an amplifier.

3 shows such a device for recording biological information, in which the longitudinal waves and the transverse waves in an eprovette, shown as 5a and 5b, measured and fed to an integrator 10 via a sensor unit 4, as shown in FIG. 2, then amplified in an amplifier 11 and decoded via a computer-aided decoder 12. The decoded signals are now supplied with correction data from a computer-aided correction data input device 16 to a further integrator 13 and are stored as a corrected signal with defined data content in a memory 14, for example a hard disk memory. This memory is connected to a diskette writing device 15, in which the corrected data can be stored.

FIG. 4 shows a device for controlling biological systems, which contains a diskette unit 17, from which corrected or uncorrected data can be read and fed to an AC / DC amplifier 18. This AC / DC amplifier 18 feeds an application coil 100, which converts the amplified signals into scalar fields (longitudinal waves, potential eddies). These potential waves can now be applied to cellular systems and information can be supplied to them. In this way, these systems can be brought to non-aberrated behavior with, even corrected, data.

However, any issuer of technical waves is also suitable as an application organ. 5 shows an exemplary circuit example of an Ac / DC amplifier as a possible embodiment of a coil feeding device.

With the device according to the invention, any desired results can be reduplicated as required using diskette memories with integrated repair or control sequences. Using a data reading unit and a coil feeding device, as shown in Fig. 4, the data content can e.g. can be converted into a scalar field by means of bifilar Klein 's coils as application coil 100 or also by means of any emitter of technical waves. In a pulsed scalar wave (longitudinal wave) field that is placed on another biological sample, for example on a cell, the desired reduplication, cloning or gene manipulation processes then take place in a manner determined by the scalar wave field and its data content, whereby of course, the user of the device is free to choose arbitrarily certain codes within the scope of the compatibility and successibility of the natural cell or Specify DNA material.

The devices according to the invention can consequently exclude undesirable mutations in cloning processes or largely exclude the risk of randomness and selection in the case of genetic manipulation by means of technical specification of cell-specific or cell-significant information patterns in the generated scalal wave fields. In the same way, any emitter of technical waves can be impressed with a cell-specific information wave and thus biological systems can be influenced, for example repaired. However, a multiple small coil, in particular a bifilar small coil, is advantageously used to generate the scalar longitudinal wave fields.

The Klein 'see winding, or Möbius coil (August Ferdinand Möbius, German mathematician and astonomist, 17.11.1790-26.9.1868), is known from the prior art (Sinichi SEIKE in "The Principles of Ultrarelativity", Space Research Institute, Ninomiya Press 1994).

This coil shape was developed because the magnetic field of this winding, when placed under direct current, creates a field that corresponds to the topology of a Klein bottle (Felix Klein, German mathematician, April 25, 1849 - June 22, 1925). A coil, half of which is wound on the left and half on the right, forms a magnetic quasi single pole with a field strength distribution in which two identical poles are located at the end and the opposite pole in the middle of the coil. In this case, each form ε of the end panel with the _{^1/3 of} the center pole closed field lines. Each ε of the field at the end of the coil has an infinite divergence (div ∞) and therefore behaves like an electrical field line. This behavior leads to a wide variety of phenomena that are equally important for spatial physics and biology.

This winding form occurs when the individual turns are placed in the form of "half strokes" around the coil core.

Such a Möbius coil is shown in FIG. 6, with a coil 101 and a coil body 102 has around which individual windings of an electrical conductor are placed in the manner of a conventional coil. However, in contrast to the prior art, these individual turns are placed in the form of "half strokes" around the coil body 102, so that a V-shaped knot line 112 is formed.

However, this type of winding does not allow a bifilar winding to be created.

The cylindrical coil (multiple small coil) advantageously used to generate scalar longitudinal wave fields has windings of a first electrical line and a further, for example second, electrical line, the lines being interconnected at their ends in a function-appropriate manner, in the case of a bifilar small coil a first and a second line, the lines are electrically connected to one another at one end of the coil, so that in the latter case one line can serve as an outgoing conductor and the second line as a return conductor. The coil is wound in such a way that the individual windings of the individual electrical lines begin offset with respect to one another along the circumference of the coil body. In the case of two lines, this can advantageously take place with an offset of 180 °, so that the individual windings of the first electrical line start opposite the windings of the second electrical line on the coil former.

In this case, a deflection point is formed in each of the individual lines after about one winding cycle, in that the line after itself has circulated carried out, then guided over the other lines adjacent in the coil axis direction and then wound around the coil former parallel to these other lines. As a result, the windings of the first electrical line and the further electrical line alternately follow one another in the direction of the coil axis. The deflection points (nodes) formed in this way can be arranged linearly or else in a zigzag shape, for example in a V-shape, along the axis of the coil. Advantageously, the node line is arranged in a V-shape, with a change in direction of the electrical lines at the tip of the V, so that, for example, previously clockwise windings have been converted into counterclockwise windings.

In other words, in the case of the coil according to the invention with two wires, starting from the diametrical position, in the same direction and alternately one half stroke is laid. The wire ends are connected to one another at the coil end, so that the opposite current direction is specified in two adjacent windings when the voltage is applied. The magnetic fields cancel each other out. In the vector representation the argument of the magnetic field vector is omitted, i.e. it becomes exactly zero, since according to Kirchhoff's second law, current and countercurrent have identical orders of magnitude.

Fields in which the arguments of the field vectors are equal to zero are referred to as scalar opponents. In the case of the coil according to the invention, these are inevitably present because, due to the energy conservation law, the electrical energy used cannot disappear (K. Meyl: "Electromagnetic environmental compatibility, causes, phenomena and scientific consequences. Reprint for the lecture ", ISBN 3-9802-642-8-3 and ISBN 3-9802-542-9-1, as well as K. Meyl" Potentialwirbel "volume 1 and 2, ISBN 3-9802-542-1-6 and ISBN 3-9802-542-2-4).

FIG. 7 shows a coil 100 with a coil body 102, on which two electrical conductors 103 and 104 are wound in the form of a coil. The conductors 103 and 104 are wound as described above, so that one line 103 next to one line

104 come to lie on one circulation. The nodes of the line 103 are arranged in the form of the V-shaped node line 110, it being noted here in the illustration that the solid lines represent the immediate view of the viewer, while the dashed lines of the node line 110 are on the back of bobbin 102 continue. In the same way, the node line 111 of the line 104 is offset by 180 ° along the circumference of the coil body. The lines 103 and 104 now each have a connection 108 and 109 and are electrical at a reversing loop 107 at the other end of the coil connected with each other.

Figure 8 shows in partial image A and partial image B each the knot formation according to the invention. FIG. 8A shows a knot line which extends linearly in the axial direction of the coil body 102.

The line 103 is wound once more around the bobbin 102 and then pulled through under itself and passed over this line and also over the adjacent second line 104, whereupon it is then passed around the bobbin 102 in a new turn. The same is done symmetrically with line 104 Knots (deflection points) 105. The deflection points 105 are now placed next to one another so that they come to lie in a line m in the axial direction of the coil body 102. In the middle of FIG. 8A it is shown how the line 103 is routed so that it forms a change of direction. That is, the line 103, which was previously wound clockwise, is then wound counterclockwise at the reversal point. The nodes 105, which adjoin this deflection point 114, are produced in the manner described.

The second line 104 is only shown in dashed lines in FIG. For them there is a corresponding knot line on the rear side of the bobbin 102, but this is not shown here.

If the node is guided linearly, the coil generates a magnetic dipole when an electrical current is applied to the coil.

FIG. 8 shows how the knots can also be made in a V shape. Each individual node is offset from the adjacent node by a small distance in the circumferential direction of the coil body 102. In the middle of FIG. 8B it is shown how the typical V-shape is created by the creation of a change of direction 114. The change of direction 114 is the tip of the V's.

If the coil according to the invention, as in FIG. 8B, is designed such that the deflection points 105 have a V-shape, the coil generates a magnetic tripole when an electric current is applied to it.

Claims

claims

1. Device for recording biological information in cells and organisms, characterized by a sensor for electromagnetic longitudinal waves, which generates a data signal for longitudinal waves.

2. Device according to the preceding claim, characterized in that the sensor for electromagnetic longitudinal waves is a single conductor which is connected to a p-n junction.

3. Device according to the preceding claim, characterized in that the p-n junction is a diode.

4. Device according to one of the two preceding claims, characterized in that the p-n junction is a Zener diode.

5. Device according to one of claims 2 to 4, characterized in that the single conductor is made of ferromagnetic material.

6. Device according to one of claims 2 to 5, characterized in that the single conductor is gold-plated.

7. Device according to one of the preceding claims, characterized by a sensor for electromagnetic lateral waves, which generates a data signal for lateral waves.

8. Device according to the preceding claim, characterized in that the sensor for electromagnetic lateral waves is a coil.

9. Device according to one of the preceding claims, characterized by an integrator for generating an integrated signal from the

Data signal for longitudinal waves and / or the data signal for lateral waves.

10. Device according to one of the preceding claims, characterized by a decoder for generating a decoded signal from the

Data signals for longitudinal waves, the data signals for lateral waves and / or the integrated signals.

11. The device according to the preceding claim, characterized in that the decoder one

Has microprocessor.

12. Device according to one of the two preceding claims, characterized by a device for correcting the decoded signal and generating a corrected signal.

13. Device according to one of the preceding claims, characterized by a recording Means for recording the data signal for longitudinal waves, the data signal for lateral waves, the integrated signal, the decoded signal and / or the corrected signal.

14. Device for controlling biological systems, characterized by a device for generating scalar electromagnetic fields as a function of a data signal.

15. The device according to the preceding claim, characterized by a device for reproducing a recorded signal to the device for generating scalar fields.

16. Device according to one of the two preceding claims, characterized by a device for recording biological information in cells and organisms according to one of claims 1 to 13.

17. Device according to one of the three preceding claims, characterized in that the device for generating scalar fields is any technical emitter of electromagnetic waves.

18. Device according to one of the four preceding claims, characterized in that the device for generating scalar fields is a multiple-small 'see coil.

9. The device according to claim 18, characterized in that the multiple-small 'see coil:

Windings of a first electrical line and windings of at least one further electrical line, the electrical lines being interconnected at their individual ends in a functionally appropriate manner, the individual windings of the first electrical line and the at least one further electrical line starting offset with respect to one another along the circumference of the coil former , and each of the lines, after about one winding revolution, forms a deflection point among itself, is guided over the other lines adjacent in the longitudinal direction of the coil, and is wound around the coil body in parallel with the other lines in such a way that the windings differ in the axial direction of the coil body. whose lines alternately follow each other in a predetermined sequence.

20. Device according to the preceding claim, characterized in that a first electrical line and a second electrical line are wound as a further electrical line around the coil body, the two electrical lines being electrically connected to one another at one end of the coil.

21. Device according to one of claims 19 and 20, characterized in that the direction of the winding of at least one of the electrical lines is reversed at least once in the axial direction of the coil.

22. The device according to the preceding claim, characterized in that the direction of the winding is reversed at a deflection point.

23. Device according to one of claims 19 to 22, characterized in that the deflection points of the first electrical line are offset relative to the deflection points of the further electrical line along the circumference of the coil by approximately 180 °.

24. Device according to one of claims 19 to 23, characterized in that the deflection points of the first line and / or the further line form a straight line in the axial direction of the coil.

25. Device according to one of claims 19 to 24, characterized in that the deflection points of the first and / or the further line are arranged in a zigzag shape in the axial direction.

26. The device according to the preceding claim, characterized in that the deflection points of the first and / or the further line are arranged in a V-shape in the axial direction.

27. Device according to one of claims 25 and 26, characterized in that at the points at which the deflection points meet at an angle, the direction of the winding of the respective deflected line is reversed.

28. Device according to one of the preceding claims, characterized in that the coil is cylindrical.

29. A method for detecting biological information in cells and organisms, characterized in that electromagnetic longitudinal waves are detected from the cells and organisms and a data signal is generated from the detected electromagnetic longitudinal waves.

30. The method according to the preceding claim, characterized in that the electromagnetic longitudinal waves are detected by means of a single conductor which is connected to a p-n junction.

31. The method according to any one of the two preceding claims, characterized in that electromagnetic lateral waves are detected from the cells and organisms and a data signal for lateral waves is generated from these.

32. The method according to the preceding claim, characterized in that the electromagnetic lateral waves are detected by means of a coil.

33. The method according to any one of claims 29 to 32, characterized in that an integrated signal is generated from the data signal for longitudinal waves and / or the data signal for lateral waves.

34. The method according to any one of claims 29 to 33, characterized in that a decoded signal is generated from the data signal for longitudinal waves, the data signal for lateral waves and / or the integrated signals.

35. The method according to the preceding claim, characterized in that the decoded signal is corrected and a corrected signal is generated.

36. The method according to any one of claims 29 to 35, characterized in that the data signal for longitudinal waves, the data signal for lateral waves, the integrated signal, the decoded signal and / or the corrected signal are recorded and stored.

37. Method for controlling biological systems, characterized in that scalar electromagnetic fields are generated as a function of a data signal and are given to the biological system.

38. The method according to the preceding claim, characterized in that the data signal according to a method according to any one of claims 29 to 36 is generated.

39. Method according to one of the two preceding claims, characterized in that the scalar electromagnetic fields are generated by means of any technical emitter of electromagnetic waves and / or a multiple-small 'see coil.

40. Use of a device for detection according to one of claims 1 to 13, a method for detection according to one of claims 29 to 36, a device for controlling biological processes according to one of claims 14 to 28 or a method for controlling biological processes according to one of the Claims 37 to 39 for intervening in biological processes, for removing and correcting harmful cell states, for reduplicating cells and organisms and for manipulating the genetic material of an organism.