Arasys Perfector - iPico Ion Magnum

Every organ and cell in the human body uses
ionic currents in the performance of critical daily
functions. Electricity is the common denominator
of all parts composing the Gestalt of a living
organism. Except that the electricity it takes to
run a cell is so miniscule that it is estimated to
be below the nano ampere range- i.e. less than
one over a billion of an ampere (Neher, Nobel
Prize 1991). Every cell generates a voltage of
roughly 70 mV (millivolt — one thousandth of
a volt) across its outer membrane, which is used
for a variety of signaling and transport functions
(R. Nuccitelli, 2003). Many organ functions are
coordinated with electrical signals, such as the
wave of depolarisation that sweeps over the heart
to trigger a synchronous contraction to pump
blood efficiently. Abnormalities in this electrical
signal can lead to fibrillation and heart attacks.
The voltages generated by the contracting heart
are so large that they can be easily detected at
the surface of the body and this signal, called the
electrocardiogram or EKG, is routinely used to
diagnose heart disease. With this abundant use
of electrical signals in cellular and organ function,
it should not be a surprise that endogenous electric
fields are also important for normal development,
cellular regeneration and wound healing.
Endogenous wound electric fields were determined
first more than 150 years ago by the German
physiologist Emil Du-Bois Reymond. Such
electric fields have been shown to exist naturally
at the site of a lesion. Several recent experiments
support a role for electric fields in the stimulation
of wound healing in the developing frog neurula,
and adult mammalian cornea. Some experiments
indicate that when the electric field is removed
the wound healing rate is 25% slower. In addition,
nearly every clinical trial using electric fields to
stimulate healing in mammalian wounds reports a
significant increase in the rate of healing from 13
to 50% (Nuccitelli, 2003). Nucciteli (2003) studied
electric fields in embryos during development,
regeneration and wound healing. He found that
all embryos that were investigated drive ionic currents
through themselves and these currents will
generate internal electric fields.
ELECTRICAL CONDUCTIVITY OF PROTEINS
Transport of ions through biological membranes requires
special channel proteins. One specific channel protein,
ATPase, uses up as much energy as it creates, turning the
cell into a constantly recharging biological battery.
The contour of a protein backbone that determines its
shape is largely determined by the interaction of electromagnetic
charges among the linked amino acids. Most
amino acids have positive and negative charges which act
like magnets. The final shape, or conformation of a protein
reflects a balanced state among its electromagnetic
charges. The distribution of the electromagnetic charge
within a protein, and therefore its shape, can be altered by
electromagnetic fields or electric signals coming in from
the organism’s environment. Protein assemblies are responsible
for functions such as respiration, digestion,
muscle contraction and the energy generating Krebs cycle.
Cells use the movements of protein assemblies to empower
specific metabolic and other biological functions. The
constant shape-shifting movements of proteins, which
can occur thousands of times in a single second, are the
movements that propel life.
ELECTRIC DNA
Many researchers have attempted to measure the electrical
conductivity of DNA. However, it is very difficult to
control all the parameters that may affect the conductivity
of DNA, e.g., length, conformation, ionic environment,
humidity, experimental protocols, and many other factors.
Inomata et al (2007) measured the electrical conductivity
of DNA using fine electrodes with a gap of about 200
nanometers and found that DNA contained both conducting
and insulating parts. Electrical conduction in
DNA appeared to be temperature dependent.
DRUG FREE THERAPY FOR SKIN TUMORS
Nucciteli et al (2006) discovered a new, drug-free
therapy for treating solid skin tumors. Pulsed
electric fields greater than 20kV/cm (1,000 volts
per centimeter) with rise times of 30 nanoseconds
and durations of 300 nanoseconds penetrate into
the interior of tumor cells and cause tumor cell
nuclei to rapidly shrink and tumor blood flow to
stop. Melanomas shrink by 90% within two weeks.
INACTIVATING THE AIDS VIRUS
In March 1991, William D. Lyman and his colleagues
at the Albert Einstein College of Medicine found
that treatment durations as short as 6 minutes substantially
incapacitated the AIDS virus, halting its
ability to reproduce. In this study, 10 microliters
of HIV-1 infected blood containing 105 infectious
particles per ml were exposed to an electric current
passing between two platinum electrodes placed in
direct contact with blood in vitro. Currents ranged
from 25 to 100 microamperes and exposure times
ranged up to 12 minutes. Exposing the virus to direct
electric current suppressed its capacity to induce
the formation of syncytia, an indicator that
quantifies the production of infectious particles.
Passing 25 microamperes for 8 minutes through the
blood reduced the number of syncytia from 50 to
65% while a charge of 50 microamps for 6 minutes
through the blood reduced the number of syncytia
by 90%; Also reverse transcriptase assay, an index
of viral protein production, was found to be negatively
impacted. Reverse transcriptase activity was
almost totally ablated (reduced by 94%) with an
exposure to 100 microamps for 6 minutes. Steven
Kaali (1992) reported that in addition to inactivating
the AIDS virus, this microcurrent treatment
also left the patients’ blood samples free of hepatitis.
The blood cells themselves were unharmed by
the treatment. COMPLEX SQUARE WAVEFORM
THE LANGUAGE OF CELLS
Communication systems are based on the serial order
of signs and symbols. This organization is evidenced
in language in the form of syntax and word morphology.
Waveform formation is for electrical configurations
what syntax is for verbal communication. While
studying single channel ion currents, Neher (Nobel
Lecture, 1991) reported “blimps which resembled
square pulses” reflecting “signals of biological significance.”
(See below)
Square waveform electrical currents are known to be
effective for promoting healing and anti-aging (Pollock,
2007). A complex square waveform is formed
out of several sine waveforms. Sine waveform is the
shape of an ideal alternating electrical signal and results
from the voltage smoothly increasing from the
negative maximum to the positive maximum and back
again.
A simple square waveform is fairy inexpensive and is
the result of the voltage shifting rather abruptly from
negative to positive. Unlike the simple square waveform,
a sine waveform requires fairly expensive components.
A device that combines several sine waveforms composing
what is termed a “complex square waveform” will be admittedly
the product of diligent work and great expense. A complex
square waveform, however, will be necessary to provide
a high definition signal that can resonate and become assimilated
by the intricate network of biological communications.
An example of such a biological signal is the Hippocampal
Place cells (O’keefe, 1976; 1978; 2007). These cells are the
principal cells in each of the layers that fire in complex bursts
in the Hippocampus, every time an animal is moving.
Inside its firing-field (i.e. the region in which a cell fires the
most), a place cell may have a maximum rate of 20Hz or
more, whereas outside its firing-field, a place cell may fire less
than 0.1 Hz. The above waveform of the place cell’s pattern
of firing could be resonated by the complex square waveform
emitted by an electronic device. Resonance, however, would
occur only if the device’s complex square waveform was
composed by sine frequencies ranging from 0.1Hz to 20 Hz
combined to reflect the firing pattern of place cells. A complex
square waveform is made out of a minimum of five sine
frequencies. A signal that demonstrates a certain degree of
clarity requires a waveform that is made out of at least 60-100
of sine waveforms. Every added sine waveform, however, increases
the expense of the electronic apparatus, which is why
most manufacturer’s avoid building shaped waveforms out
of sine waves. The difference between a simple square waveform
and a complex square waveform made out of sine frequencies
is respectively equivalent to virtual memory versus
RAM, or Morse code versus the telephone. Both types of
waveforms may appear identical in an oscilloscope. However,
the least difference inspected by an oscilloscope may trigger
an unwanted response within the organism. That unwanted
response is most often an aspect of biological resistance, a
shutting of the door to the foreign agent that has triggered
a automatic biological safety mechanism. Even in the case
when an outside signal is rendered benign by the organism’s
cellular defences, communication between a simple square
waveform and a biological signal will be as futile as trying to
exchange opinions with a “talking toy” that invariably repeats
itself over and over. Due to unsurpassed limitations in communication,
the organism will soon discard the simple square
waveform signal and the results provided by the device may
end up clinically mediocre and short lasting.
COMPLEX SQUARE WAVEFORM:
HANDMADE DEVICES
After seventeen years of research the coinventor of the
Pacemaker (Pollock, 1990; 1993; 1996; 2004; 2005;
2006; 2008) developed the Arasys. The Arasys emits
an analogue complex square waveform composed out
of up to 1,000 sine frequencies. In 2008, the Pacemaker
co-inventors engineered the Ion Magnum that
emits an even more complex analogue waveform than
the Arasys. Arasys and Ion Magnum analogue complex
square waveform has been proven useful in treating
muscle atrophy and nerve wasting conditions such
a Multiple Sclerosis. In these conditions, myelinforming
glial cells which wrap around nerve fibres are
compromised by the disease. Speed and intensity of
neuronal signals over long distances deteriorate. The
brain does not replace these myelin-forming glial cells
very effectively because the communication between
neuron and brain has been interrupted. Therefore,
the brain has hardly any access to these neuron cells.
Here is a situation where a complex square waveform
could substitute the weak or absent neuronal
signals travelling from the neuron to the brain. Such
a waveform would be successful in completing the
mission provided that its complexity had the clarity
and communication capacity of a naturally occurring
neuronal signal that would allow it to unlock all kinds of biological
gates, whispering the required passwords. The reason
why Pollock’s complex square waveform has had dramatic,
long lasting and irreversible results in body building, in
helping muscle wasting conditions, and in several anti-aging
treatments, is (1) building the waveform on the basis of diligent
research on neuron-firing signals and (2) the handmade
composition of this waveform that surpasses any computerized
program. Apart from muscle building, neuronal signal
restoration and enhancement, as well as acting as an antioxidant,
the Arasys Perfector and Ion Magnum signal offers a
significant increase in blood circulation and lymphatic drainage
than leaves the body with an overall sense of increased
health and wellbeing. Arasys Perfector and Ion Magnum
specifications and waveforms were formulated on the basis
of two decades of research. Why is it that these devices cannot
be duplicated? Because as Gerry Pollock, coinventor of
the pacemaker, stated, “when you copy something from the
outside, you do not know how or why it was created.” A
biological system has the instinctual sensitivity or cellular
intelligence to distinguish between nourishment and harmful
agents or between malevolent bacteria and bacteria that
are necessary for certain biological functions– e.g. digestion.
Every cell is empowered with intelligence that helps it nourish
and protect itself against any danger. In the absence of
cellular intelligence all types of viruses and parasites would
enter and take over an organism and all life would be abolished
a few hours after birth. A simple square waveform is
too impoverished to resonate the harmonious complexity of
a biological system, the way a two piece band is insufficient
in delivering the musical richness of a symphony. It would
be unrealistic to expect a large audience in a symphony performed
by only two instruments and it would be even more
unrealistic to expect a big applause. Similarly, not too many
cells will respond to the impoverished simple square waveform
that is striving to deliver the timbre of a complex signal
in a rough, sketchy fashion to minimize the project expense.
Such simple square waveform will most likely be experienced
by the biological system like a static radio station or an incomprehensible
telegram missing a few words. The waveform
composition is the most crucial factor in turning an electronic
device into a communication system emitting signals that
become assimilated by a biological organism, thus enhancing
or completing significant life functions. The waveform
is as important in cellular resonance as language is in verbal
communication. Language is confined by grammar and syntax
rules in order to convey a message correctly. Similarly, a
waveform is restricted by the specific sequence of a multiplicity
of sine waveforms composing the necessary signal to resonate
and spatial organization of endogenous electrical signals
that cells use in their multifaceted networking. Ion Magnum,
Arasys and Perfector are designed to resonate the communication
signals of the biological organism within the intricate
spatial organization and rhythm of electrically excitable cells,
to produce results similar to those resulting from the reparative
capacities of the body in its ideal state of existence where
age is not a factor.
© 2008 Xanya Sofra-Weiss, Ph.D
Ion Magnum, Arasys, Perfector Research
www.arasysperfector.com

Tags: Xanya Sofra Weiss

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