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ELECTRON
THERAPY RESEARCH
John
Crane
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1
This
report on Electron Therapy is primarily concerned with the
detection and cure of cancer and related diseases. It is
presented for research only.
It
is a matter of record that, while orthodox medical and surgical
methods have had limited success with cancer discovered in the
early stage, they have had little or no success with treatment
of the more advanced cases. The cause of cancer is still listed
in some of the current medical textbooks as unknown.
Since
research to determine the cause and effect a cure of cancer is
being carried out in many and various directions, it seems
reasonable to explore every possible avenue toward a true
understanding of the cause of cancer and hence, its proper
treatment
This
report concerns itself with the discovery of a virus causing
cancer and a method of treatment which excited considerable
interest among reputable doctors and laboratory specialists as
long ago as 1934. This theory has stood up under hundreds of
controlled laboratory tests and has been applied to treat human
cancer in dozens of cases.
Rife
Virus Microscope Institute, in conjunction with various doctors
throughout the United States and Canada, is at the present time
(1960-ed.) engaged in carrying out a controlled series of tests
in order to re-establish the finding of Dr. Royal R. Rife in his
life study of the cause and cure of cancer.
Dr.
Royal Raymond Rife first conceived the idea of the Frequency
Instrument in conjunction with his work in developing the Rife
Universal Microscope. Since the determining of the cancer
requires the high power of the Rife Microscope, a brief
description of the construction and theory of operation of the
Rife Microscope will be included in this report.
THE
UNIVERSAL MICROSCOPE
Dr.
Royal R. Rife over a period of 30 years designed and built in
his own laboratory five microscopes of power and resolution far
beyond the so-called law of optical physics. In their power
magnification these instruments vary from 9,000 to 50,000 times,
far beyond the limits of the standard research instrument. The
commercial microscope being manufactured today is inadequate for
the observation of filterable viruses of disease (as these
minute, live, living entities are less that 1/20 of one micron
in dimension). Thus the need for a device which would carry us
farther into this important field of endeavor. We will describe
in some detail the most powerful of these microscopes, known as
the Universal Microscope.
The
Universal Microscope, which is the largest and most powerful of
the light microscopes, developed in 1933, consists of 5,682
parts.
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2
This
microscope derives its name from its adaptability to all fields
of microscopical work. The microscope is fully equipped with
separate substage condenser units for transmitted and mono
chromatic beam, darkfield, polarized, and slit-ultra
illumination, and includes a special device for crystallography.
The entire optical system of lenses and prisms as well as the
illuminating units are made of block-crystal quartz.
The
illuminating unit used for the examination of the filterable
form of disease organisms contains 14 lenses and prisms, three
of which are in the hi-intensity incandescent lamp, four in the
Risley prism, and seven in the achromatic condenser system. Two
circular, wedge-shaped prisms are suspended between the source
of light and the specimen being examined. The two prisms are
used for changing the angle of incidence of the light passing
through the specimen being examined. When the light passes
through these prisms, it is divided or split into two beams, one
of which is refracted to such an extent that it is reflected to
the side of the prism while the second beam is permitted to pass
through the prism and illuminate the specimen owing to its
chemical constituents.
The
mounting arrangement on the Universal Microscope permits each of
the two prisms to be rotated in opposite directions by a vernier
control throughout 360 degrees. This vernier adjustment permits
bending the transmitted beam of light at variable angles of
incidence while, at the same time, a small portion of the
spectrum is projected into the axis of the microscope owing to
the chemical constituents of the microorganism. The vernier
adjustment permits only a small portion of the spectrum to be
visible at any one time, but it is possible to select any
portion from one end of the spectrum to the other. When that
portion of the spectrum is reached where both the organism and
the color band vibrate in exact accord, a definite
characteristic spectrum is emitted by the organism.
PRINCIPLE
OF PARALLEL RAYS
In
the case of the filter-passing form of the Bacillus Typhosus, a
turquoise blue color is emitted and the plane of polarization
deviated plus 4.8 degrees. The predominating chemical
constituents of the organism are next ascertained after which
the quartz prisms are adjusted by means of the vernier control
to minus 4.8 degrees so the opposite angle of refraction may be
obtained. A monochromatic beam of light corresponding exactly to
the frequency of the organism is then passed through the
specimen along with the direct transmitted light. This beam
permits the observer to view the organism stained in its true
chemical color and reveals its own individual structure in a
field which is brilliant with light.
The
rays of light refracted by the specimen enter the objective lens
and are carried up the tube in parallel rays through twenty-one
light bends to the ocular lens. A tolerance of less that one
wave length of visible light is permitted in the core beam of
illumination. Iii the standard optical microscope, the light
rays tend to converge as they rise higher and finally cross each
other, arriving at the ocular lens, separated by a considerable
distance.
This
microscope derives its name from its adaptability to all fields
of microscopical work. The microscope is fully equipped with
separate substage condenser units for transmitted and mono
chromatic beam, darkfield, polarized, and slit-ultra
illumination, and includes a special device for crystallography.
The entire optical system of lenses and prisms as well as the
illuminating units are made of block-crystal quartz.
The
illuminating unit used for the examination of the filterable
form of disease organisms contains 14 lenses and prisms, three
of which are in the hi-intensity incandescent lamp, four in the
Risley prism, and seven in the achromatic condenser system. Two
circular, wedge-shaped prisms are suspended between the source
of light and the specimen being examined. The two prisms are
used for changing the angle of incidence of the light passing
through the specimen being examined. When the light passes
through these prisms, it is divided or split into two beams, one
of which is refracted to such an extent that it is reflected to
the side of the prism while the second beam is permitted to pass
through the prism and illuminate the specimen owing to its
chemical constituents.
The
mounting arrangement on the Universal Microscope permits each of
the two prisms to be rotated in opposite directions by a vernier
control throughout 360 degrees. This vernier adjustment permits
bending the transmitted beam of light at variable angles of
incidence while, at the same time, a small portion of the
spectrum is projected into the axis of the microscope owing to
the chemical constituents of the microorganism. The vernier
adjustment permits only a small portion of the spectrum to be
visible at any one time, but it is possible to select any
portion from one end of the spectrum to the other. When that
portion of the spectrum is reached where both the organism and
the color band vibrate in exact accord, a definite
characteristic spectrum is emitted by the organism.
PRINCIPLE
OF PARALLEL RAYS
In
the case of the filter-passing form of the Bacillus Typhosus, a
turquoise blue color is emitted and the plane of polarization
deviated plus 4.8 degrees. The predominating chemical
constituents of the organism are next ascertained after which
the quartz prisms are adjusted by means of the vernier control
to minus 4.8 degrees so the opposite angle of refraction may be
obtained. A monochromatic beam of light corresponding exactly to
the frequency of the organism is then passed through the
specimen along with the direct transmitted light. This beam
permits the observer to view the organism stained in its true
chemical color and reveals its own individual structure in a
field which is brilliant with light.
The
rays of light refracted by the specimen enter the objective lens
and are carried up the tube in parallel rays through twenty-one
light bends to the ocular lens. A tolerance of less that one
wave length of visible light is permitted in the core beam of
illumination. Iii the standard optical microscope, the light
rays tend to converge as they rise higher and finally cross each
other, arriving at the ocular lens, separated by a considerable
distance.
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The
Rife microscopes, as the rays are about to cross each other, a
specially designed quartz prism is inserted which serves to
separate the light rays to a near parallel line again.
Additional prisms are inserted each time the rays are ready to
cross.
These
prisms, located in the tube, are adjusted and held in alignment
by micrometer? screws in special tracks made of magnelium a
metal having the closest expansion coefficient of any metal to
quartz. These prisms are separated by a distance of only 30
millimeters. Thus, the greatest distance that the image in the
Universal Microscope is projected through any one media, either
quartz or air, is 30 millimeters instead of the 160 to 190
millimeters employed in the air-filled type of the ordinary
microscope.
It
is this principle of parallel rays used in the Universal
Microscope and the resultant shortening of projection distance
between any two blocks or prisms plus the fact that objective
lenses can thus be substitutes for oculars, (these oculars being
three matched pairs of lO-mm, 7-mm and 4-mm objectives in short
mounts) which make possible not only the unusually high
magnification and resolution but which serve to eliminate
virtually all chromatic and spherical aberration.
The
universal stage is a double rotating stage graduated through 360
degrees in quarter-minute arc divisions. The upper segment
carries the mechanical stage having a movement of 40 degrees,
and the body assembly which can move horizontally over the
condenser and provide an angular tilt of 40 degrees + or -.
The
microscope stands 24 inches high and weighs 200 pounds. The base
is composed of cast nickel-steel plate, accurately surfaced and
equipped with three leveling screws and two spirit levels set at
90 degrees. The course adjustment, a clock thread screw with 40
threads to the inch, slides in a 11/4 dovetail which gibs
directly onto the pillar post. The stage, in conjunction with a
hydraulic lift, acts as a lever in operating the fine
adjustment.
A
6-guage screw, having 100 threads to the inch, is worked through
a gland into a hollow glycerine-filled post, the glycerine being
displaced and replaced at will as the screw is turned clockwise
or counterclockwise allowing a 5 to 1 ratio on the lead screw.
This hydraulic action assures complete absence of drag or
inertia.
The
fine adjustment being 700 times wore sensitive than the ordinary
microscopes, requires a length of time from ten minutes to
one-half hour to focus. This time at first glance seems a
disadvantage, but it is felt that, for the overall results
obtained, the time required is only a slight inconvenience
compared to the many years' research and the actual results
obtained in isolating and looking upon disease-causing organisms
in their true form (to be continued)
A
45 minute video (VHS) of Royal Raymond Rife in his laboratory is
available from BSRF and this tape shows the inflicting of cancer
in laboratory mice, their cure with Rife's ray tube frequency
instruments. It is transferred from a 16mm film and is narrated
by John Crane. This film is proof that the cure for cancer (one
of many) has been covered up!
John
Crane can be contacted at 4246 Pepper Drive; San Diego, CA
92105. He is dedicated to preserving and promoting the work of
Royal Raymond Rife and the Rife Virus microscope Institute.
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