Classifications

• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
  • A61N2/00—Magnetotherapy
  • A61N2/02—Magnetotherapy using magnetic fields produced by coils, including single turn loops or electromagnets
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
  • A61N1/00—Electrotherapy; Circuits therefor
  • A61N1/40—Applying electric fields by inductive or capacitive coupling ; Applying radio-frequency signals

Definitions

• This invention relates to apparatus for treating biological ailments, for example cancer, in tissue matter. More specifically, the invention relates to apparatus for treating ailing tissue matter through the application of a magnetic field to the affected area of the tissue matter.
• the types of magnetic application that have been used so far, are: steady state magnetic application for a length of time from a singular direction; pulsed application from a singular direction for a length of time; and rotary application in a singular plane.
• the present invention provides apparatus for treating biological ailments in tissue matter, the apparatus being adaptable for radiating three separate pole-controllable magnetic or electromagnetic fields from directions that cross perpendicular one another at an area of the body under treatment.
• the poles of radiations and their sequence of radiation are then controlled in an order such that, the radiated field at said area changes in direction lying successively, and with 180 degree polar reversals along a plurality of lines of orientation, which occur in at least three mutually perpendicular planes, for rotating the depolarized electrons in the tissue to their normal polar orientations, as cure of the ailment.
• Atomic arrangement of the molecule A living molecule consists of a series of interrelated generators which operate in a specific sequence for generating specifically oriented magnetic fields at the periphery of the molecule. These complex mangetic fields are so timed and oriented that adjacent molecules control each other's triggering actions of generation alternately, so that an operational interrelationship is created between adjacent molecules for binding only similar operating molecules in the tissue structure, and rejecting alien molecules.
• Each generator consists of a pair of atoms and a functional electron entrapped between the two atoms.
• This electron rotates back and forth within a limited arc of 45 degrees under the control of RNA (rlbonucleic acid) and DNA (deoxyribonucleic acid) for generation of the required magnetic field.
• RNA read-only RNA
• DNA deoxyribonucleic acid
• the electrons from the RNA source are released and drawn toward the functioning electron by the initial magnetic force of the pair of atoms, and regenerated by processional (wobble) feed-back of the functioning electron.
• This electron rotates up to 45 degrees while processing from the lowest processional resonance of about 12 centimeter wavelength, up to 3 centimeter at 45 degree rotation.
• a storage mechanism responslvely resonant to 3 centimeter wavelength, stores and produces a pulsed voltage to trigger the DNA source for release of DNA atoms.
• a single DNA atom and a single positive RNA atom are released simultaneously, which travel toward each other to the center of released string of RNA electrons.
• the travel motion of the DNA and RNA atoms toward each other causes sufficient magnetic flux for a single released electron to travel to the positive RNA atom, and the two atoms move away for elimination, or reuse.
• RNA and DNA sources to the generator are attached to respective RNA and DNA main supply atoms, so that whan one of these sources releases an atom it must be replenished by an atom from its string at the same.time, because when this string is broken the source will not release an. atom, no matter how much it may be stimulated to do so.
• the RNA source will release electrons without being replenished by electrons, but when the magnetic tie of the string is broken, it D ⁇ comes incapable of releasing electrons.
• RNA source is stimulated unnaturally (for example, by cancer causing agent) for releasing far greater number of electrons than required for normal generation.
• the charge of the storage mechanism cannot start triggering action of the DNA source for reverse regeneration, and the functioning electron is regenerated toward rotation to 90 degrees (at this point electron precession stops completely), which is the maximum regeneration, and all operations stop at this point with no possibility of pole reversal.
• This is the stage in which strong paramagnetic resonance at about 3 cm. wavelength can be obtained by an external magnet.
• RNA and DNA sources in a molecule become separated from their strings of supply atoms only after some number of molecules from normal molecules become inoperative, because of a threshold volume in which they are forced to lose their magnetic hold of their supply strings.
• those inoperative molecules that are in the vicinity of normally operating molecules have their RNA and DNA sources still intact with their respective strings of atoms, so that an external influence upon these functioning electrons from a direction at right angle to the pole disoriented positions will rotate these electrons to 90 degree angle by the regenerative help of released RNA electrons.
• the polar orientation of the electron can be controlled by electric, magnetic, or electromagnetic field.
• the electron will oscillate (not process ) in a wobbling fashion, and tilt its pole in a direction that is exactly opposite to the direction of the alternating poles of the applied field.
• Fig. 1 illustrates a perspective arrangement of three electromagnets Ml to M3, and their physical relationships to each other, and their field projections into area e in the body for treatment.
• Fig. 2 is a chart showing exemplary modes of controlling the sequence of electromagnet energization of Fig. 1.
• Fig. 3 is a detail of a pyramidal magnetic fieldattracting plate for correcting inherent curvature of field projection from the electromagnets of Fig.1.
• Fig. I4. is an exemplary arrangement for controlling the distributory switchings of the energization of the electromagnets of Fig. 1.
• Fig. 5 is similar to the arrangement of Figl 1, except that instead of three electromagnets, there are used three microwave radiators Ra-1 to Ra-3 for projecting their radiations to the area e for the required treatment.
• the apparatus of Fig. 1 shows an assembly of three electromagnets Ml, M2 and M3.
• the magnetic field projections of these electromagnets are directed to an ailing area e in the body to be treated, from angular directions such that, if these projections were simultaneous, they would cross the area £ at right angles relative to each other.
• the polar orientations of the depolarized electrons in the area e could be made to rotate two-dimen- sionally in three mutually perpendicular planes, by a special sequence of energization of the ele ctromagnets, in the form as shown in the chart of Fig. 2.
• the first step shows that a positive voltage is applied to Ml for energization, the projected field of which causes the polar orientations of those depolarized electrons that are positioned at right angles with respect to the direction of the arriving field at e to rotate toward said projection.
• a positive voltage is applied to M2
• the electromagnets Ml and M2 receive negative voltages, and in this case, those electrons that had been depolarized in 180 degree reverse directions from the former positioned depolarized electrons, are pole normalized, completing a two dimensional polar normalization.
• the electromagnets M3 and M2 are energized by positive voltages, so that now the direction of polar normalization changes in a third dimension. If we continue this sequence of electromagnet energization down to the twelvth step, then a complete two dimensional angular rotation of the field at e in three mutually perpendicular planes can be established. In the case that said 180 degree pole reversals are desired to be obtaine in 45 degree steps, then the sequence of thirteenth to the sixteenth steps can be used, as example - but simultaneous availability of oppositely polarized a-c voltage, as required in the step of 16, is not shown in the drawing of Fig. 4. Also, if rotation of the field in more than three mutually perpendicular planes are desired, then the steps of seventeen to twentyfour, as example, may be used.
• the magnetic field of the electromagnet does not project in straight lines from its pole face. But if we place a magnetic field-attracting plate opposite the pole face of the magnet, the magnetic field will be mostly concentrated between this plte and the pole face of the magnet. Since there are three electromagnets used in Fig. 1, the field attracting plate 1 may be placed underneath the patient to be treated, as shown. The field-attracting side of the plate may be fashioned in small pyramidal facets 28, cut at 45 degree angles, such as shown in Fig. 3. The pyramidal facets of the plate may be of soft iron, which will attract the projected magnetic field and pull the curving lines of the flux into substantially straight lines.
• Fig. 1 The drawing of Fig. 1 is made partly diagramatic and partly sross-sectionally, so that the skilled in the art of making it can understand its structure at a glance.
• the electromagnets M2 and M3 are drawn cross-sectio- nally to show the iron cores 3 and 4, and the coil windings
• each electromagnet is assembled in their proper mutual orientations relative to each other in the frame 9, and tightened securely by bolts and nuts (not shown) through holes 10 and 11.
• the outer casing of each electromagnet may have a flange 12, so that the magnet assembly will rest in position over the frame housing, as shown.
• the horizontal arm of a right angle bar 13 may be secured rotatably to the center of the frame 9, and the vertical arm inserted in the vertical housing section llj. of the base support 15, which is mobile on the roller casters l6 and 17.
• the assembly may be raised and lowered by the hand crank 18, which rotates the gear 19 coupled to the gear rack mounted on the vertical portion of the arm 13.
• rollers 21 may be included for fri ⁇ tionless up and down movement of the arm 13, because the electromagnets may represent an appreciable weight.
• an opposing spring 22 may also be included. For simplicity of drawing, I have shown only one spring, but more can be used.
• the shaft 26 is mounted in fixed position centrally of the frame 9, for holding the entire assembly of the electromagnets M1-M3, rotat.ably in the bearing head 27 of the arm 13, for body contour adjustment by the technician in charge of the machine's operation.
• a retractable graduated pointer 24 is included for the technican to be able to measure the distance of field projections of the three electromagnets to the area e.
• the block 29 represents a source of alternating sine wave voltage, which may be provided by the ordinary consumer a-c line, when it is conveniently available.
• electromagnet energization may be performed in numerous different ways, the choice of utilizing the commercial a-c line is purely for practical convenience.
• the pulse-formers in blocks 30 and 31 derive pulse signals from the a-c source in block 29, as shown graphically by the waves at the right hand side of blocks 30 and 31.
• the output pulses of blocks 30 and.31 are mixed in the OR-gate in block 33, and applied to the input of the distributor 34, which operates at the crossing points of the upper and lower lobes of the a-c sine waves.
• the distributor 34 counts the half cycles of the a-c source to a predetermined count, and the last two outputs of the predetermined counts are mixed at the two- inputs of the OR-gate in block 34. Tne last output is applied to one of the OR-gate 35, for impressing upon its clear input, for a new start of counting.
• OR-gate 34 is applied to the input of the distributor in block 36, which makes two distinct operations at every predetermined count of the counter 33. This provides two output operations of the distributor 36, at every predetermined count coincident with the timings of the positive and negative half cycles of the a-c input. Thus, at any required timing of energization of the coils M1-M2, either the positive or negative lobe of the a-c source is available, even though there occurs a half cycle timing difference between the two separate operations at the output of the distributor 36.
• the electtomagnets M1-M3 may be connected to either the positive or negative voltage of the a-c line source, by se-b cting the proper timing during which the particular outputs of the distributor 36 coincide with a positive or negative lobe of the alternating cycle - disregarding the timing difference that occurs between the positive and negative lobes.
• the set-reset triggers 38, 45 and 46 operate in reset states for releasing the operation of the relays RY1-RY3, by way of the amplifiers 39, 47 , 48 .
• the contact points of the relays open, and current to the electromagnets M1-M3 stop.
• a pulse signal is derived from the last output (marked 59) °f the distributor 36, by the one-shot in block I4.9, which applies this pulse signal to the clear input of the distributor 36, and simultaneously to the clear input of the distributor 33 by way of the OR-gate 35, so that the starting time periods of both distributors become coincident.
• the numerals just below the output terminals are shown for the purpose to indicate which output terminals are coupled to inputs of OR-gate in block 44 , and which outputs are left open, in order to select the proper timings of the positive and negative lobes of the a-c sine wave, for energization of the electromagnets Ml to M3.
• the differentiating capacitors Cl to C13 are used to avoid direct connections from the outputs of the distributor to the inputs of the 0R-gates 37, 50 and 51. This use, however, is not imperative, and they may be dispensed with, with the proper selection of available integrated circuits.
• the a-c source in block 29 can be a source of different frequency. It may also be a bipolar d-c source, and sampled by the distri butor action, operated by some clock pulses at a predetermined frequency. Also, in reference to the distributor 36 and the chart of Fig. 2, it may be desired that only up to the twelvth switching is used for the energization of the electro magnets M1-M3. Thus, the auxiliary one-shot 49 may be connected to the thirteenth output terminal of the distributor 36, and a manual switch to select either the one-shot 49 or the auxiliary one-shot.
• the OR-gate 35 may have three inputs, so that the output of auxiliary one-shot can be connected to the third input of gate 35.
• the outputs of oneshot 49 and the auxiliary one-shot may then be mixed in a two input OR-gate for connecting to the clear input of the distributor 36.
• Fig. 5 shows three microwave radiators A-l, A-2 and A-3, which are assembled in such orientations relative to each other that, their field radiations are directed toward an area e, at which point the three radiations cross each other's fields at right angles.
• the patient to be treated is placed on a table 62, so that the ailing area is positioned at the area e.
• the radiators are energized by the R-F generator in block 63 by way of the coaxial cables (Partly shown) through three pairs of normally off-state switching means in blocks 67, 68; 69, 70; and 71, 72, respectively.
• These three pairs of switches are used in their on-states to distribute the R-F voltage to the radiators from either the output terminal 73 or 74 which carry the R-F voltage in opposite polarities.
• the terminal 73 of generator 63 is connected to the first inputs of the first of the two-input pairs of switches in blocks 67, 69 and
• the output terminal 74 is connected to the first inputs of the second of the two-input pairs of switches in blocks 68, 70 and 72.
• the second inputs of these switches 67 to 72 are normally biased to a level that the switches are normally renered inoperative, and they are individually impressed upon by distribution voltages for operation, so that the R-F voltage from either terminal 73 or 74 of the generator 63 is admitted to respective radiators for radiation.
• the distributor in block 75 has plurality of sequentially operating outputs 1 through the nth number, which are mixed in different combinations at the three pairs of multiinput Or-gates 76, 77; 78, 79; and 80, 81, the singular outputs of which are coupled to the one-shots 82 to 87, respectively.
• the outputs of one-shots 82 to 87 are then applied to the con trol inputs of the switching means in blocks 67 to 72, respec tively, for effecting the required generator output of distri bution to the radiators A-l to A-3.
• the OR-gate 76 In operation, and starting from the number one output of the distributor 75, the OR-gate 76 operates in on-state (from its normal off-state) and the one-shot 82 produces an output pulse for operation of the switch in block 67, which admits the R-F output from terminal 73 to the radiator A-l, to tilt some functional electrons in the area e to 90 degree angle from their depolarized polar orientations.
• the OR-gate 78 operates, and the one-shot 84 applies an output pulse to the input of switch 69 for operation, and it admits the R-F output from terminal 73 to the radiator A-2.
• the field radiation from A-2 now rotates some of the functional electrons that have already been rotated to 90 degree angles, to complete 180 degree polar normalization.
• the frequency of the radiated wave can preferably be at decimeter wavelength, the frequency of which is a little higher than the lowest precessional resonance of the functioning electron, which is at 12 centimeter wavelength.
• the field strength of the radiat wave is not critical, and a radiation intensity level of 100 to 300 milliwatts (in continuous state) per square centimeter at the treatment area would be considered as satisfactory, although variation of these values is allowable.
• the pulsed application of the radiation reduces the internal heat generation appreciably, and higher field intensity application becomes allowable.
• the block diagrams of various parts in the arrangement of Fig, 5 represent conventionally available devices, and therefore, detailed description of these parts isnotnecessary.
• the proximity of the radiators with respect to the body to be treated is not an important factor, as long as their radiations meet at the area e crossing each other's fields at right angles.
• pole reversal of the depolarized functional electron is a regenerative act, and all that is necessary, is to start that regeneration at the beginning of each 90 degree rotation.
• energization of the electromagnets by the. arrangement of Fig. 4 during a single half cycle wave current of the a-c source can be considered as being sufficient to start that regeneration, although several half cycles, or continuous energization of the electromagnets by half cycle currents during the entire 90 degree polar rotation will not cause harmful effects.
• the distributor arrangement of Fig. 4 can be easily modified for any number of half cycle energization of the electromagnets during 90 degree rotation of the electron.
• the time period for a complete 180 degree polar rotation of the functional electron will vary from half a second to one eighth of a second, and therefore, the choice of slower speed of treatment would offer assurance of complete cure of the ailment involved, although the use of higher speeds will depend on the choice of the physician in charge of a particular case.

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• Health & Medical Sciences (AREA)
• Engineering & Computer Science (AREA)
• Biomedical Technology (AREA)
• Nuclear Medicine, Radiotherapy & Molecular Imaging (AREA)
• Radiology & Medical Imaging (AREA)
• Life Sciences & Earth Sciences (AREA)
• Animal Behavior & Ethology (AREA)
• General Health & Medical Sciences (AREA)
• Public Health (AREA)
• Veterinary Medicine (AREA)
• Magnetic Treatment Devices (AREA)

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• 1980
  • 1980-12-01 EP EP19810901377 patent/EP0048757A4/de not_active Withdrawn
  • 1980-12-01 WO PCT/US1980/001602 patent/WO1981002833A1/en not_active Application Discontinuation

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