At a recent evening lecture at the California Institute
of Technology, a neurologist was explaining the ins
and outs of new brain-imaging technology to an audience
composed of Caltech professors, students, and members
of the general public. The audience was rather quiet,
lulled by the technical tone of the lecture. But
when the neurologist mentioned in passing that the
disease afflicting one of his patients was caused
by a brain parasite, the whole room sat up and made
a collective noise of disgust and alarm. Brain parasites!
But, in fact, parasites infect us all the time. They
live in our bodies, even in our cells, and most of
the time we do not even know that they are there.
The brain can provide a pleasant, nurturing environment
for parasites, because it has structures that prevent
many of the immune system’s cells from entering,
at least in the early stages of infection. Add to
that plenty of oxygen and nutrients, and the brain
seems like a rather nice place to live.
Despite its seemingly idyllic home, a brain parasite’s
life does have its hardships. To begin with, the parasite
has to find a way into the brain. Invasion of any organ
is difficult, but the brain is an especially tough
nut to crack due to a protective barrier between the
bloodstream and brain fluid, called the blood-brain
barrier. This barrier is made up of cells that make
a tight seal along any blood vessels so that most stuff
from the bloodstream (including brain parasites) can’t
leak into the brain. If the parasite does manage to
successfully enter the brain, it then has to deal with
the attack of the immune system. The cells of the immune
system act together to rid the body of any foreign
organisms. In humans, the immune system is highly organized
and efficient; parasites’ evasion mechanisms
have evolved to be good enough to thwart the immune
system, at least for a little while. Unfortunately,
the most effective parasites are the ones we really
have to worry about.
In fact, millions of people worldwide are infected
by these efficacious brain parasites. Many
of these brain parasites cause debilitating conditions
and sometimes even death. So, in addition to being
interesting biologically, brain parasites are also
important in the context of human disease.
Two parasites with disease-causing capabilities are
the pork tapeworm, Taenia solium, and the amoeba
Naegleria fowleri. In addition to their medical importance,
these two organisms illustrate the many ways that
brain parasites are able to affect their hosts through
their methods of invasion and survival.
Tapeworm: From Pork Chops to the Brain
The pork tapeworm is one of the most common disease-causing
brain parasites. This parasite infects over 50 million
people worldwide, and is the leading cause of brain
seizures. It is usually contracted from eating undercooked
pork, and once in the gut, it attaches to the intestine,
and then grows to be several feet long. Under certain
circumstances, these worms can also invade the brain,
where thankfully they don’t grow to be quite
so large.
Why does the worm sometimes attach to the intestine
but at other times travel to the brain? It all depends
on what stage of its life cycle the worm is in when
it is swallowed. In its larval stage, the worm will
hook onto the intestine; however, if eggs are swallowed,
they hatch in the stomach. From there the larvae
can enter the bloodstream and eventually travel to
the brain. But in order to reach the brain from the
bloodstream, the larvae must traverse the blood-brain
barrier. Unfortunately, researchers still don’t
know exactly how this happens. Many scientists think
that the larvae can release enzymes that are able
to dissolve a small portion of the blood-brain barrier
to allow the parasite to get through into the brain.
Bob Beck found Parasites can be illiminated Once the larvae reach the brain, they cause a disease
called neurocysticercosis, by attaching to either
the brain tissue itself, or to cavities through which
brain fluid flows. (Brain fluid carries nutrients
and waste to and from the brain, and acts as a cushion
to protect the brain against physical impact.) Once
attached, the larvae develop into cyst-like structures.
The location of the cysts determines the symptoms
exhibited by the host. If the larvae attach to the
brain tissue, then the host often experiences seizures.
This occurs partly because the presence of the larvae
causes the activity of the brain to become wild and
uncontrolled, thereby causing a seizure. On the other
hand, if the larvae attach to the brain-fluid cavities,
the host experiences headaches, nausea, dizziness,
and altered mental states in addition to seizures.
These additional symptoms occur because the flow
of the brain fluid is blocked by the larvae. Often,
the presence of the larvae also causes the lining
of the brain-fluid cavities to become inflamed, further
constricting the flow of the brain fluid. Since the
cavities are a closed system, blockage of the cavities
exerts pressure on the brain. This increased cranial
pressure forces the heart to pump harder in order
to deliver blood to the brain area, increasing the
pressure on the brain even more. If the condition
is not treated, the heart eventually cannot pump
enough blood to the brain, neurons begin to die off,
and major brain damage occurs.
 |
A pork tapeworm (Taenia solium) cysticercus,
the form in which the tapeworm is found in an
infected brain. (Colorized image by P. W. Pappas
and S. M. Wardrop, courtesy of P. W. Pappas,
Ohio State University.) |
Worm on the Brain
Woman Recuperating After Doctors Remove Parasite
Which Parasites
Can Infect The Brain?
There are two known brain parasites, the pork tapeworm, Taenia solium, and
the amoeba Naegleria fowleri.
Taenia solium: The pig tapeworm, Taenia solium,
is responsible for the condition known as neurocysticercosis,
the most common brain parasitic infection. Neurocysticercosis
affects more than fifty million people all over
the world, and it is the leading cause of brain
seizures. This disease develops when larvae from
Taenia solium enter the body via the ingestion
of diseased pork meat. Once inside the body,
the tapeworm migrates to the small intestine
and remains there until it reaches maturity.
From here the parasite makes its way to the brain
where it attaches either to the brain tissues
or to the cavities within the brain.
The parasite will then form cystic lesions that
can also affect the eyes, muscles and spinal
cord. The exact location of the cysts will determine
the symptoms of the disease. Brain parasites
can interrupt the normal activity of the brain
and cause brain seizures. On the other hand,
parasites that attach to the brain-fluid cavities
will cause symptoms such as headaches, nausea,
and dizziness, as well as brain seizures. These
additional symptoms may occur because the parasite
is interrupting the normal flow of brain fluid
within the brain. Over time, this blockage of
fluid may cause pressure to build up that can
lead to permanent brain damage.
Naegleria fowleri: Unlike the pork tapeworm,
Naegleria fowleri brain parasites have only infected
about 175 people in the world; therefore it is
not as easily known or understood. This brain
parasite causes a condition called primary amoebic
meningo-cephalitis. Of the 175 cases of this
disease that have been reported, only six patients
have survived. For this reason, scientists are
eagerly searching for more answers as to these
particular brain parasites can be treated.
Naegleria fowleri is an amoeba that is commonly
found in the wild, especially in warm freshwater
lakes and ponds. It can also survive in heated
swimming pools. This parasite can infect a human
host that is swimming in contaminated waters
by attaching to the inside of its host's nose
and then traveling up the nose and into the brain.
Once in the area of the brain, the amoeba releases
an enzyme that allows it dissolve the host's
tissues, and enter the tissues of the brain.
Naegleria fowleri can then into feast on the
valuable nutrients with the neurons of the brain.
This is why this particular parasite causes such
rapid death.
In addition to the brain damage caused by destroying
the brain's neurons, the presence this parasite
can also cause inflammation of the tissues within
the brain. This inflammation can lead to additional
brain damage and even death.
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T. solium cysticerci in the brain of a nine-year-old
girl who died during cerebrospinal fluid extraction
to diagnose her headaches. This was in the 1970s—if
it had happened 10 years later, noninvasive computerized
tomography would have given an accurate diagnosis,
and the parasites could have been killed .
(Image courtesy of Dr. Ana Flisser, National Autonomous
University of Mexico.)
colloidal silver acts as a "second immune
system" according to Bob Beck. It has been
shown in numerous studies to be the only substance
known to eliminate hundreds of viruses, bacteria,
fungus, etc., more than any modern antibiotic or "miracle
drug" yet developed by the pharmaceutical
companies.
More Here |
It is
interesting to note that some of these symptoms, such
as seizures, are caused not only by the presence
of the brain parasites, but also by the immune system.
In general, parasites do not want to be detected
by the immune system, because then they will most
likely be eaten and killed. They try to do everything
they can to avoid eliciting a strong immune response.
Parasites also don’t want to do anything that
can kill the host. If the host dies, then the parasites
die too. For this reason, people can have parasites
for years and not show any symptoms at all. But then,
as the larval defenses break down, the host immune
system is able to have a greater effect, and the
symptoms become more obvious. What does the host
immune system do to defend against the parasites,
and why do its actions elicit harmful effects on
its own body?
Defending the Body from Invaders
The main function of the immune system is to make sure
that any foreign object in the body is destroyed,
including brain parasites. Many of the symptoms arising
from brain parasite infection are due to the interactions
between the immune system and the parasite. There
are two main methods by which the immune system tries
to rid the brain of the parasite. First, certain
cells of the immune system make antibodies specifically
against the parasite. Antibodies are molecules that
can attach to a foreign organism and act like a signal
flare, telling the rest of the immune cells that
this organism is foreign and should be destroyed.
There are also other immune cells, called phagocytes,
which travel around the body eating anything that
isn’t recognized as belonging to that body.
These cells are much more effective at destroying
germs that are labeled by antibodies.
Second, there are proteins in the body that are able
to recognize some general characteristics of many
germs. These proteins make up the complement system.
The complement proteins are able to attach to the
germ and also act as signal flares to attract other
immune cells that can destroy the germ. However,
these proteins are sometimes also able to kill the
germ themselves by forming a structure on the surface
that can cut the germ open.
Universal detoxification is accomplished by oxidation
of dead and neutralized pathogens, without the
need for colonics, heat, hot tubs, exercise, liver
and kidney flushing, herbs or other modalities.
While these treatments have their uses, Bob Beck
feels they are not necessary if ozonated water
is used daily with the other three protocols he
recommends.
More Here |
Why the Immune System
Can’t “See” Tapeworm
Cysts
The interaction between the immune system and the cysts
is quite amazing; it is a great example of how evolution
can produce two complementary systems. The immune
system is seeking to find and destroy the parasite,
while the parasite is attempting to stay hidden and
alive. One way that the cysts are able to “hide” from
the immune system is by degrading the antibodies
that attach to them. There is some evidence that
the antibodies are used as a food source, and that
the cysts are able to coax the immune system to make
more antibodies. The cysts can even disguise themselves
as part of the host’s body by displaying proteins
on their surfaces that identify them as part of the
host—much as Wile E. Coyote hides from Sam
Sheepdog in a herd of sheep by wearing a sheepskin.
Finally, the location of the cysts is itself conducive
to escaping detection by the immune system. The brain
is not easily accessible to the cells of the immune
system due to the presence of the blood-brain barrier,
and so the parasites are partially protected from
random encounters with the body’s defenders.
Only when the immune response is in full swing can
the immune cells enter the brain in large numbers.
Besides hiding from the immune system, the tapeworm
parasites are able to prevent the immune cells from
killing them by using several strategies. For instance,
the parasites are able to prevent the complement
proteins from attaching to their surfaces. The tapeworms
can even release molecules that act as decoys, tricking
the killer proteins into leaving them alone. The
cysts also release other proteins that are able to
protect them from being eaten, although how exactly
this is accomplished is still unknown. THE PULSER
GETS IN DEEPLY
There is some
evidence that these proteins are able to prevent
phagocytes from accurately targeting the cysts. One
of the ways that phagocytes are able to go to the
right place in the body during an infection is by
following a chemical trail. This trail is produced
by other immune cells at the site of infection. Some
of the proteins released by the cysts are able to
obscure this chemical trail so that the phagocytes
become lost on their way to the infection. Cysts
are also thought to release a second set of proteins
that decreases the activity of new phagocytes. These
proteins affect another group of immune cells that
control the activity of new phagocytes; these regulatory
immune cells then decrease the number of active phagocytes.
Finally, a third set of proteins released by the
cysts is thought to be able to prevent phagocytes
from producing the proteins necessary to kill the
cysts.
This treatment disables microbes as they float
through the bloodstream. This is an important part
of the protocol.
Dr Bob Beck electrification devices are attached
directly to the bloodstream via the wrists, not
the palms of the hands, as with Dr Clark's zapper.
The Beck electrification device output is much
stronger and has been measured in the bloodstream,
using hypodermic probes. The slower pulsation of
Beck's device is said to "permit the current
to penetrate deeply". Once the microbes are disabled, they are harmless
and the body
should eventually excrete them.
More info here
|
Victory? The cysts are very successful in evading the immune
system, but they gradually become more and more vulnerable
to attack. As the immune system response gains strength,
the most common symptoms of infection become more
and more obvious. At first, the parasites are simply
unable to hide from the immune cells, and cannot
pretend to be part of the host’s body anymore.
Then the full immune system response kicks in, and
because the immune cells are able to detect the parasites,
the parasites are doomed. More antibodies and complement
proteins are released, more phagocytes are born,
and more blood and immune cells rush to the parasitic
sites. The areas where the parasites are located
become swollen, which often leads to seizures and
compression of the surrounding brain tissue. As the
response progresses, the cysts are replaced by scar
tissue, and finally by calcium deposits. (Calcium
deposition often occurs in the body due to the activity
of bacteria living in the blood, rather than as a
direct effect of the immune system’s response.)
The scar tissue and calcium deposits are also known
to cause seizures. In addition, the immune response
causes irreparable brain damage to the areas of the
brain around the cyst as the phagocytes ingest the
cells surrounding the cysts, which also contributes
to the seizures.
 |
Naegleria fowleri in the amoeboid form, near
right, and in the cyst form, far right. The scale
bar is 10 micrometers. Images courtesy of Bret
Robinson, Australian Water Quality Centre and
CRC for Water Quality Research. |
In fact, more harm than good often comes out of the
immune response to infection of the brain by tapeworms.
Against most pathogens, however, the immune response
is actually beneficial to the body. Foreign organisms
often cause lots of damage, and it is important that
they be destroyed as quickly and efficiently as possible.
Furthermore, the immune system response is generally
the same regardless of the identity of the foreign
invader; and in most circumstances, the immune response
does not have negative effects. Overall, the immune
system is actually highly effective at defending
the body from foreign organisms.
Of course, the effectiveness of the immune system is
largely dependent on the ability of the body to mobilize
its defenses. Some parasites act so quickly that
the immune system is unable to react before the infection
becomes fatal. One such brain parasite is Naegleria
fowleri, a water-borne amoeba.
Danger in the Waters
If you’ve never heard of Naegleria fowleri, don’t
be surprised. Unlike the pork tapeworm, N. fowleri
has only infected about 175 people in the world, causing
a disease called primary amoebic meningo-cephalitis.
But out of those 175 people, only six have survived,
giving a mortality rate of 97 percent. For this reason,
it is quite an important parasite to study, as there
are no current treatments that have proven effective
against it.
Fortunately, natural infection by the parasite is very
rare, although N. fowleri is ubiquitous in the wild.
It lives mostly in warm freshwater lakes and ponds,
but can even thrive in heated swimming pools. Furthermore,
N. fowleri is actually a free-living organism, which
means that it can survive without a host. This explains
why N. fowleri attacks are so rapidly fatal—since
hosts are not necessary to its survival, the parasite
does not have to take pains to avoid killing them.
Part of the reason that N. fowleri can survive in such
numbers and in so many different places is because
it is an amoeba. Amoebas are single-celled creatures
that resemble sacks of fluid gelatin surrounded by
a greasy membrane. Because of their small size and
few requisites for survival, these organisms are
found everywhere. In addition, the amoebas can form
cysts in harsh conditions like extreme cold; in this
form, they are protected against the environment.
Attack of the Amoebas
When an amoeba invades a person, it is normally in
its active, reproductive phase. Invasion occurs when
the amoeba attaches to the inside of its host’s
nose and then travels up the nose to the brain. The
amoeba follows the path laid out by the olfactory
nerve, although sometimes it can also use the bloodstream.
Several enzymes released by the amoeba are able to
dissolve the host’s tissues, giving access
to the brain. Once in the brain, the amoeba causes
damage by actually eating the nerve cells. As you
can imagine, this is very harmful to the host, and
is the main reason why infection by N. fowleri causes
such rapid death. The amoeba is able to eat neurons
because it has surface proteins that allow it to
cut a hole in the covering of the cell. The contents
of the neuron leak out, and the amoeba can feed on
the nutrients it contains. The amoeba even has proteins
on its surface that tell it where the best food sources
are. These proteins are able to sense the presence
of certain nutrients, and then send signals to the
rest of the cell indicating in which direction the
amoeba should move to eat those nutrients. Finally,
there are other proteins on the amoeba’s surface
that direct it to the most vulnerable areas of a
neuron.
In addition to causing direct brain damage by ingesting
neurons, the presence of N. fowleri amoebas can cause
inflammation of the brain-fluid cavity linings. Similarly
to infection by tapeworm, blocking the brain fluid
can cause increased pressure on the brain. However,
this effect is usually only secondary to the much more
destructive digesting action of the amoebas.
 |
Brain tissue infected by Naegleria fowleri.
The dark dots are the amoebas. Notice the empty
space around the dots; this space used to be
tissue before the amoebas digested it. Image
provided by the Division of Parasitic Diseases,
Centers for Disease Control and Prevention. |
Fighting the Invader
The immune system, however, is not completely idle
while this invasion and destruction is occurring,
although for the most part its efforts are in vain.
The amoebas use several strategies to stave off the
immune cells. Many of these strategies are similar
to those used by tapeworm cysts. For example, the
amoebas are able to internalize antibodies on their
surfaces, although they don’t need these antibodies
as a food source. Other proteins on the amoeba’s
surface prevent the attachment of complement proteins.
If the complement proteins are able to bypass these
surface proteins, the amoeba is able to collect them
in one area of its membrane. Afterwards, the amoeba
can shed that piece of the membrane. The shed membrane
acts as a decoy, attracting more complement proteins
that would otherwise attack the amoeba.
The concept has been revealed in many revolutionary
patents and research papers over the past 100 years
(going back to 1890), but these breakthroughs were
typically lost, suppressed, ridiculed by mainstream
medicine, etc. Blood electrification takes 2 hours
daily for about four weeks to get significant results.
More info Here |
Why are these strategies
effective in shielding the amoebas, but not tapeworms,
from the immune system?
The reason is that an amoebal infection is rapidly
fatal. The immune system does not have time to fully
mobilize its immune cell armies before the brain
damage is so extreme that the organism dies. Since
these amoebas don’t need the host to survive,
it’s not a big deal if they kill him or her
off. Tapeworms, however, die when the host does,
and so they try very hard to keep from being detected
by the immune system. And in fact, they do a fairly
good job at that, since most tapeworm infections
aren’t noticeable until many years after the
tapeworms get into the brain. The immune system is
only able to have a big effect on the infection when
the tapeworms start to die, often from old age.
Parasite Evolution
These two parasites offer only an inkling of the many
organisms that can infect the human brain. While
the two seem to differ greatly, the molecular weapons
they use for defense and invasion are really very
similar. For instance, there is evidence that both
parasites use enzymes to penetrate the blood-brain
barrier, and both use a decoy strategy to deflect
the attention of the immune system. This similarity
results from evolution, which has slowly altered
these parasites so that they are as effective as
possible at survival. As new treatments and cures
of brain-parasite-related diseases become available,
it will be interesting (as well as medically useful)
to see how the strategies of these parasites change.
BOB BECK PROTOCOL
By Andrea Manzo
Andrea Manzo is a senior majoring in biology. She decided
to find out more about brain parasites after attending
the 2002 Biology Forum, “Gray Matters:
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