Disclaimer: This is Untrue.
2.1.16 Mechanism of Resurrection
2.1.16.1 Overview
Rael claims that the Elohim possess the technology of resurrection.
Yahweh says that he experienced death in connection with eternal life.
"And when I saw Him,
I fell at His feet as dead.
But He laid His right hand on me,
saying to me, 'Do not be afraid;
I am the First and the Last.
I am He who lives, and was dead,
and behold, I am alive forevermore.
Amen. And I have the keys of
Hades and of Death'" (Rev 1:17-18 NKJV).
Similarly, it is said that humans on Earth will be resurrected after death.
The core mechanism of resurrection is thought to be
consciousness transfer (also known as mind transfer).
This process enables human resurrection and eternal life.
An outline of consciousness transfer (or mind transfer) is as
follows. (Details are explained later in the chapter on the Human Brain.)
2.1.16.2 Details
2.1.16.2.1 Location of Consciousness
When the brain is severely damaged, consciousness is lost.
Consciousness resides in the human brain.
The Human Brain
*Attribution:
https://en.wikipedia.org/wiki/File:Skull_and_brain_normal_human.svg
2.1.16.2.2 An Outline of a Neuron
Neurons are the key players in the human brain.
The human brain is mostly composed of neurons.
Neurons are a type of cell. In the following diagram, a neuron is shown in red-purple and is
being deformed for explanation. The largest part is the cell body, also called the soma.
Its diameter is approximately 10 μm. It contains essential components, including the nucleus.
The long fiber is called the axon. The axon transmits signals to its terminal end.
The end of the axon branches into many tips. These tips are called axon terminals, or
synaptic terminals. The terminals make contact with other
neurons (shown in blue-green in this case). The short extensions are called dendrites.
The terminal of a nerve cell can move and elongate through the action of actin filaments
and other factors.
*Attribution:
https://en.wikipedia.org/wiki/File:Blausen_0657_MultipolarNeuron.png
A neuron sends electrical signals from the dendrites and cell body to the axon
terminals (synaptic terminals) as shown below. When the axon terminals of a
neuron (red-purple above) touch the dendrites of another neuron (blue-green above), the sending neuron (red-purple) is called the presynaptic neuron, and the receiving neuron (blue-green) is called the postsynaptic neuron.
*Attribution:
https://en.wikipedia.org/wiki/File:Action_Potential.gif
2.1.16.2.3 Mechanism of Creating Basic Electric Potential Difference
Like other cells, the surface of neurons consists of cell membranes, which are primarily made up of a phospholipid bilayer. Electric elements cannot easily penetrate the phospholipid bilayer. However, specific enzymes called ion transporters (ion pumps) and ion channels are embedded within the phospholipid bilayer, connecting the inside and outside of the cell.
Na+ / K+ -ATPase (Sodium-Potassium Transporter) is one
such enzyme. It plays a central role in establishing the electric potential difference between
the inside and outside of the cell. The mechanism by which the Sodium-Potassium
Transporter creates this electric potential difference (or electric charge) between the extracellular fluid (outside) and intracellular fluid (inside) is as follows.
The central wall below represents the phospholipid bilayer (cell membrane). The left side represents the inside of the cell (neuron), and the right side represents the outside of the cell (neuron). A Sodium-Potassium Transporter is embedded within the phospholipid bilayer.
Initially, a simplified state is assumed, as shown in (A). In this initial assumption, the concentrations of Sodium ions (Na+: pink circles) and Potassium ions (K+: red-violet ovals) are the same on both the inside and outside of the cell. Other major electrolytes, such as Chloride ions (Cl-) and Hydrogen Phosphate ions (HPO42-), are placed according to their respective concentrations.
In (A), the Sodium-Potassium Transporter attracts Sodium ions.
Secondly in (B), 3 Sodium ions are housed in the Sodium-Potassium Transporter.
Thirdly in (C) and (D), the outside opens and 3 Sodium ions are released to the outside.
In the meantime, 3 Sodium ions are pumped out, and 2 Potassium ions are pumped in.
This results in the "resting state." In this state, the inside of the cell is negatively
charged compared to the outside, and the Electric Potential Difference across the
membrane is about -70 mV (millivolts). This is called the "resting potential."
2.1.16.2.4 Rapid Rise and Fall of Electric Potential Difference
However, when a presynaptic neuron's axon terminal touches a postsynaptic neuron's
dendrite and the electric potential difference of the presynaptic neuron's axon terminal
becomes positive, specific substances are released from the presynaptic axon terminal.
These substances open ion channels in the postsynaptic neuron's dendrite,
causing its electric potential difference to become more positive. Subsequently,
this change in electric potential propagates along the postsynaptic neuron's axon,
reaching its axon terminals. In turn, these axon terminals release specific substances
that open ion channels in the next neuron's dendrite.
The most common type of synapse is the chemical synapse, while the other type is the
electrical synapse.
Chemical Synapse
*Attribution:
https://en.wikipedia.org/wiki/File:SynapseSchematic_lines.svg
Consequently, a rapid rise and fall in intracellular Electric Potential Difference occurs.
This phenomenon is called a "signal" or "firing," and its details will be explained later
in the chapter about the human brain.
*Attribution:
https://en.wikipedia.org/wiki/File:Action_potential_vert.png
2.1.16.2.5 Formation of Logical Processing Systems
Neurons interconnect to form logical processing systems where signals propagate.
The fundamental unit of a logical processing system is logical operation processing.
Examples of simplified logical operation processing models are shown below.
Here, it is assumed that a cell body requires signals from three presynaptic neurons'
axon terminals to generate a signal.
In the example below, a signal from either "a" or "b" is sufficient to trigger a signal in the
postsynaptic neuron.
In contrast, in the example below, signals from both "a" and "b" are required to
trigger a signal in the postsynaptic neuron.
There are other complex logical operation processing models, which will be
explained in detail later in the chapter about the human brain.
These models function in the same way as computers. All information is binarized,
and by accumulating these logical operation processing models, neurons form logical
processing systems where binarized signals circulate. The brain operates like a
computer or artificial intelligence—this process is called thinking.
As mentioned above, any logical operations and logical processing systems can be
assembled using neurons.
Logical processing systems, composed of these logical operations, are present
throughout the brain. However, their primary functions vary depending on their location.
A schematic diagram of the main functions is shown below, based on a side view
of the brain. The Logical Systems region is primarily responsible for logical reasoning.
Additionally, certain regions, such as Semantic Memory Systems, are responsible for
memory storage. The term "semantic" refers to "meaningful" information.
2.1.16.2.6 Formation of Logical Processing Networks
Logical processing systems then form advanced logical processing networks,
enabling higher-level thinking.
For example, when the expression "HOW MANY DEGREES FAHRENHEIT IS IDENTICAL
TO 10 DEGREES CELSIUS?" is received, it is encoded in binary, processed, and
sent to the Logical Systems region. Upon encountering the binarized question,
the Logical Systems send signals to other neurons to determine the
meaning of "DEGREES FAHRENHEIT."
If the Long-Term Semantic Memory Systems or Long-Term Semantic Network
Systems contain memories related to "DEGREES" and "FAHRENHEIT," these neurons
receive the signals and respond with relevant information. The Logical Systems then
interpret the retrieved data, ultimately producing the correct answer: "50℉."
2.1.16.2.7 Outline of Perception (Visual System)
As an example of a perceptual system, an outline of the visual system is shown below.
In the case of the left eye, the image (light) is reflected onto the retina, where it
appears rotated 180 degrees. Photoreceptor cells in the retina respond to
the light and generate electrical signals in the optic nerves (visual neurons).
Optic nerves corresponding to the left side of the image are connected to the right
hemisphere of the brain, where their signals are sent for analysis and recognition.
Optic nerves corresponding to the right side of the image are connected to the left
hemisphere, where their signals are processed similarly.
2.1.16.2.8 Hallucination
It should be noted that if signals in specific optic nerves are directly induced by external devices (rather than by photoreceptor cells in the retina), the brain perceives visual hallucinations.
Similarly, auditory hallucinations can occur when signals are directly generated in specific auditory nerves through external devices, bypassing the auditory receptor cells in the ear.
Additionally, if external devices are used to manipulate signals in specific neurons, thoughts, emotions, and mental states can potentially be influenced or controlled.
2.1.16.2.9 Mind Transfer (Consciousness Transfer)
Consciousness can be considered an aggregation of neural networks and
memories. This leads to the question of whether—and how—one's consciousness can
be preserved through death and resurrection for eternal life. One possible method involves
wireless transmission of information within the brain. Telepathy, for instance, could
be regarded as a form of wireless transmission.
Eternal consciousness for eternal life could be conceptualized as follows:
(1) Identical twins each have an independent consciousness.
Since there is no information transfer between their brains, they possess two separate
conscious entities.
(2) However, a single human brain consists of 2 cerebral hemispheres—the left and
the right. These hemispheres are largely independent and are only connected by
the corpus callosum. For example, the left hemisphere processes information from the
right visual field, while the right hemisphere processes information from the
left visual field. Despite their separation, a person typically experiences a single unified
consciousness because information is continuously exchanged between the 2 hemispheres
via the corpus callosum.
Consider a scenario where a figure resembling the number "4" is displayed in the left
visual field (processed by the right hemisphere), while a different image with no
acute-angled corner appears in the right visual field (processed by the left hemisphere).
Although each hemisphere perceives a different image, the individual still experiences a
single, unified consciousness due to information transfer through the corpus callosum.
*Attribution:
https://en.wikipedia.org/wiki/File:Corpus_callosum.png
(3) As mentioned earlier, neural signals can be represented using the binary system. If neural signals from the cerebrum can be wirelessly detected from outside the body, they can be converted into binary data.
These detected binary signals can then be transmitted to an intelligent machine,
such as a computer.
Furthermore, if the binary signals from the intelligent machine can be wirelessly
transmitted back to the neurons of the cerebrum, the cerebrum and the intelligent
machine would effectively form a single consciousness. In relation to this, Rael
suggests that long hair functions as a telepathic antenna for the brain, similar to
the biblical story of Samson.
*Attribution:
https://en.wikipedia.org/wiki/File:Corpus_callosum.png
Additionally, if a cloned body (with a cloned brain) or another suitable
body (with an appropriate brain) is prepared and wirelessly linked to the intelligent
machine, then the original brain, the intelligent machine, and the cloned
brain (or second brain) would together form a unified consciousness.
In addition, if the original brain fades and ceases to function, consciousness would
continue to exist within the second brain and the intelligent machines. If the
intelligent machines weaken and eventually shut down, consciousness would persist in
the second brain.
Thus, consciousness can be transferred to another brain. The film "Avatar"
depicts the transfer of consciousness from a human to a reptilian-like extraterrestrial
with long hair.
*
"Avatar (2009 film) on Wikipedia"
https://en.wikipedia.org/wiki/Avatar_(2009_film)
This process is referred to as Mind Uploading, Mind Transfer, or Consciousness Transfer.
*
"Mind Uploading on Wikipedia"
https://en.wikipedia.org/wiki/Mind_uploading
It could be the fundamental mechanism of the Tree of Life.
2.1.16.2.10 Simple Wireless Brain Signal Detection and Modulation
2.1.16.2.10.1 Injection of Micro/Nano Devices into the Cerebrospinal Fluid System
A simple and realistic method for wirelessly detecting and modulating (causing)
electric signals in specific neurons of the brain involves distributing "micro/nano
devices" into the brain.
The primary component of these micro/nano devices would be a micro/nano
chip equipped with magnetism, an inner receiving antenna conductor, an outward
transmitting antenna conductor, an outer receiving antenna conductor, an inward
transmitting antenna conductor, an electricity-generating antenna conductor, and an
electronic circuit semiconductor.
A conductor is a type of material that efficiently conducts electric current,
while a semiconductor allows or restricts the flow of electric current depending on
the conditions. Complex electronic circuits are typically made of semiconductors.
*
"Electric Conductor on Wikipedia"
https://en.wikipedia.org/wiki/Electrical_conductor
*
"Semiconductor on Wikipedia"
https://en.wikipedia.org/wiki/Semiconductor
Each micro/nano chip would have a unique identification number.
These chips would be primarily coated with biocompatible materials such
as liposomes and would partially contain ligands (e.g., N-cadherin) and cell-penetrating
substances (e.g., cell-penetrating peptides).
These are referred to here as "micro/nano devices."
(A liposome is a spherical vesicle with at least one lipid bilayer, commonly
used as a drug delivery system.)
*
"Liposome on Wikipedia"
https://en.wikipedia.org/wiki/Liposome
*
"Cadherin on Wikipedia"
https://en.wikipedia.org/wiki/Cadherin
*
"CDH2 on Wikipedia"
https://en.wikipedia.org/wiki/CDH2
*
"Cell-Penetrating Peptide on Wikipedia"
https://en.wikipedia.org/wiki/Cell-penetrating_peptide
The micro/nano devices would be injected into the cerebrospinal (cerebral spinal)
fluid system, where the brain and neurons are immersed.
The Drifting Region of the Cerebral Spinal (Cerebrospinal) Fluid (light blue) containing the Brain
*Attribution:
https://en.wikipedia.org/wiki/File:Blausen_0216_CerebrospinalSystem.png
The micro/nano devices would be dispersed within the cerebrospinal (cerebral spinal) fluid system,
attracted to neuronal synapses primarily in the brain, and would adhere to the
surface of neurons near synapses, as shown below.
Fig. (1) below shows a simplified diagram of a synapse in its resting (basic) state,
with a micro/nano device adhered to the surface of a postsynaptic neuron.
The upper part of (1) illustrates the axon terminals of 2 presynaptic neurons, while
the lower part depicts a section of the postsynaptic neuron's dendrite.
Regarding positive ions, the intracellular space of neurons is primarily filled with
potassium ions (red-purple ovals). Other major electrolytes (ions) are distributed
according to their analyzed abundance. The extracellular space is predominantly
filled with sodium ions (pink circles), followed by smaller quantities of potassium,
calcium, and magnesium ions. The axon terminals of the postsynaptic neuron are
located to the right of the figure.
Since ions, which carry electric charges, are constantly moving around
synapses, and their motion generates magnetic flux (due to the magnetic effects
of electric current), micro/nano devices with magnetic properties would be
naturally attracted to synapses.
(Details regarding ion movement around synapses are explained later in the chapter on the human brain.)
2.1.16.10.2 Performance of the Micro/Nano Devices
When electrical signals are generated in presynaptic neurons and these signals reach the
axon terminals, the conditions at the synapse change. For example, as
shown in Fig. (7) below, AMPA Receptor Ligand-Gated Sodium Channels open,
allowing sodium ions (positive ions) to pass through. This means that positive ions
first approach the micro/nano device and then move away, generating a magnetic flux.
In general, when an electric current flows, it creates concentric magnetic flux around it.
If the electric current flows to the left (i.e., positive charges move leftward, or negative
charges such as electrons move rightward), the magnetic flux above the current
moves outward, while the flux below the current moves
inward. (A circle with an "X" (wood screw head sign) represents an outward direction,
whereas a circle with a dot (wood screw point sign) represents an inward direction.)
On the other hand, when the strength of magnetic flux penetrating a closed electronic
circuit conductor fluctuates, an electric potential difference (voltage) is induced in the
conductor. As a result, electric current flows (with electrons moving in
the opposite direction) through the circuit to counteract the fluctuation in magnetic flux.
This phenomenon is called Electromagnetic Induction.
Fig. A above shows a closed electronic circuit conductor. Suddenly, as shown in B,
magnetic flux approaching the conductor appears from the outside. This induces an electric
potential difference (voltage) in the conductor, causing electric current to flow
clockwise (with electrons moving counterclockwise). Consequently, as shown in C, a small
magnetic flux is generated in the opposite direction, reducing the overall magnetic flux
penetrating the conductor, as illustrated in D.
*
"Electromagnetic Induction on Wikipedia"
https://en.wikipedia.org/wiki/Electromagnetic_induction
Below is an enlarged view of (7). As a positively charged sodium
ion (pink circle) (representing electric current) approaches the micro/nano device, a
magnetic flux moving inward is generated on the lower side of the current.
Part of this inward-moving magnetic flux penetrates the Inner Receiving
Antenna (a closed circuit conductor). This induces an electric potential
difference (voltage) in the Inner Receiving Antenna, causing electric
current to flow clockwise (with electrons moving counterclockwise).
The electric current then enters the electronic circuit semiconductor, allowing the
micro/nano device to detect the neural electric signals.
After receiving neural electric signals, the electronic circuit semiconductor generates output electric signals. The Outward Transmitting Antenna conductor then creates and emits electromagnetic waves, which are detected by external antennas. This enables wireless detection of signals containing the micro/nano device's identification number and neural electric signal information.
The structure of the neuronal network can be analyzed using information processors.
Conversely, when electromagnetic wave signals are transmitted from external antennas, the Outer Receiving Antenna conductor of the micro/nano device receives them, inducing an electric potential difference (voltage) that causes electric current to flow into the electronic circuit semiconductor. The semiconductor then recognizes the micro/nano device's identification number and processes the instructions.
If the instructions require the generation of an electric signal in the neuron, electric
current flows into the Inward Transmitting Antenna conductor, generating a magnetic
flux around the antenna, including within the neuron.
Then, when the strength of the magnetic flux inside the neuron fluctuates, an electric
potential difference (voltage) is induced within the neuron.
Consequently, specific neural electric signals can be generated wirelessly from an external source.
Thus, Mind Transfer, leading to resurrection and eternal life, can be achieved.
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