Chelation therapy?.

[Guest guest]

The following is the information i was seeking regarding chelation. Thanks

for all the helpful and useful information.

 

Vester

 

 

The Nanobacteria Link to Heart Disease and Cancer

JoAnn Guest

Mar 03, 2006 19:17 PST

 

The Nanobacteria Link to Heart Disease and Cancer

Nanoparticles are implicated in the harmful calcification that's

common to many illnesses.

A simple treatment is now reversing the symptoms, especially in

heart disease,

so why aren't the health authorities telling patients and doctors

about it?

 

http://www.nexusmagazine.com/articles/Nanobacteria.html

--

 

 

Extracted from Nexus Magazine, Volume 12, Number 5 (August -

September 2005)

PO Box 30, Mapleton Qld 4560 Australia. edi-

Telephone: +61 (0)7 5442 9280; Fax: +61 (0)7 5442 9381

From our web page at: www.nexusmagazine.com

 

by Douglas Mulhall © May–July 2005

Email: in-

Website: http://www.calcify.com

Based on the book The Calcium Bomb

by Douglas Mulhall and Katja Hansen

(The Writers' Collective, 2005)

 

 

-

 

 

Millions of seriously ill patients are unaware that heart disease is

being measurably reversed with an approach pioneered by researchers

at the National Aeronautics and Space Administration (NASA) and in

Finland,

aided by Mayo Clinic and Washington Hospital Center findings. This

approach is now prescribed by hundreds of doctors for thousands of

patients. A similar approach has been developed with prostate

disease at

the renowned Cleveland Clinic in Florida. According to doctors, both

approaches are practical options for those whose other medicines and

surgery have failed. So why aren't other desperately ill patients

whose

treatments don't work being told about it?

 

In July 2004, the medical journal Pathophysiology published a

peer-reviewed research paper with the innocuous title " Calcification

in coronary artery disease can be reversed by EDTA–tetracycline long-

term chemotherapy " .1 In plain terms, it meant that hardening of the

arteries

was being reversed. Not only were rock-hard calcium deposits being

reduced, but chest pains were being resolved in most patients and

bad

cholesterol levels were being cut beyond what other medicines had

achieved. The findings were important for patients whose other drugs

and

surgery weren't working, i.e., the " cardiac cripples " , whose numbers

are

in the millions and whose doctors have told them there is nothing

more

to be done. They were the ones who responded most favourably to the

new

approach.

Then, in February 2005, a paper published in the prestigious Journal

of

Urology by researchers from the Cleveland Clinic, one of the leading

urology hospitals in America, reported " significant improvement " in

chronic prostatitis—a growing problem for millions of men—again,

where

other approaches had failed.2

The studies, although otherwise separate, had a compelling link.

They

used a cocktail of well-known, inexpensive medicines that have been

around for half a century but were never before used in this

combination. Both reports urged more studies to confirm their

conclusions, and emphasised that not every patient experienced a

reversal; only a majority did. Nonetheless, the results were

encouraging. Chronic diseases that had befuddled modern medicine

were

being reversed.

To put a human face on this, take the case reported by Dr Manjit

Bajwa

of McLean, Virginia, who did not participate in the clinical studies

but

whose experience with one patient paralleled study results. Dr Bajwa

reported in a testimonial of 5 May 2005:

" Two years ago I had a patient with severe coronary artery disease

with

a 75–85% blockage in left coronary and two other arteries. Open

heart

surgery was recommended as stents could not be put in. The patient

was

told he would probably die within two weeks if surgery was not

performed.

 

" He declined surgery and instead chose chelation. [Author's note:

chelation in this case is an intravenous form of heavy metal

removal.]

After twenty-five treatments of chelation, his angina worsened

[author's

emphasis]. With [his] heart calcium score of 2600, I started the

nanobacteria protocol. Within two to three weeks his angina abated.

He

was able to return to all his normal activities and exercises in two

months.

 

" Nanobacteria protocol helped this patient measurably, when other

treatments had failed. I am quite impressed with his results. With

heart

calcium scores of 750 or more, nothing else seems to work. "

Bajwa and her patient are far from alone. In Santa Monica,

California,

general practitioner Dr Douglas Hopper said he recorded impressive

results with a diabetic patient when he used the treatment to help

her

recover from congestive heart failure. Hopper then put his patient

on

the same treatment used in the clinical study: a regimen of

tetracycline, EDTA and nutraceuticals,3 administered by the patient

at

home. Note that this was not intravenous chelation, which has been

broadly analysed and critiqued, but, instead, a mix of oral and

suppository treatments.

 

In Toledo, Ohio, cardiologist Dr James C. Roberts, who pioneered

early

patient treatment with this approach, has on his website case

histories

from dozens of patients who have shown remarkable improvement. In

Tampa,

Florida, cardiologist Dr Benedict Maniscalco, who supervised the

clinical study [Pathophysiology study, referenced previous page],

reports that patients who stayed on the treatment after the study

was

completed showed dramatic reductions in their heart disease

symptoms.

There are many more examples.

 

 

Normally results such as these, when reinforced by clinical studies,

however preliminary, would be cause for loud celebration. If the

findings had been reported by a major pharmaceuticals company, they

could have easily made the front pages of medical news services

because,

until then, no one had reported reversing the symptoms of such

diseases

to such an extent. More encouraging still, because the medicines

have

been around for many years and their side effects are minimal and

well

known, the new approach is already available across the USA and used

with thousands of patients. That leaves thousands more doctors with

millions more patients who might benefit right now. On top of that,

a

blood test based on the new approach has been used to identify heart

disease early in patients who show no outward symptoms.

Why, then, has the response from government authorities, medical

associations and health experts been cavernous silence?

To understand this requires looking at a scourge that has been with

us

for millennia, and which science has been at a loss to explain until

now. It is known as calcification.

 

CALCIFICATION

Calcification is a rock-hard mix of the most plentiful minerals in

the

body: calcium and phosphorus. Normally this calcium phosphate mix is

essential for building bones and teeth. But as we age, and sometimes

when we are still young, some of it goes haywire, stiffening

arteries,

roughing up skin, destroying teeth, blocking kidneys and salting

cancers.

The arithmetic is frighteningly easy. Calcification doubles in the

body

about every three or four years. We can have it as teenagers and not

notice, although it mysteriously accelerates in some athletes. Then

as

we age and also live longer, it becomes so endemic that most people

over

seventy have it.

For decades, calcification has been growing imperceptibly in tens of

millions of baby boomers. Politicians and pundits are among the

high-profile victims of this slow-motion explosion that is ripping

apart

healthcare with skyrocketing treatment costs.

 

In December 2004, doctors diagnosed US President George W. Bush with

one of the more commonly known forms: coronary artery calcification.

Former President Clinton required emergency surgery because doctors

missed much of his calcification when they used older tests to track

it.

 

 

Vice President Dick Cheney and many of his Senate colleagues are

calcified. At least three sitting US women governors have had it in

breast cancer as well. And they are not alone. Media types who cover

politics or poke fun at it haven't escaped. Larry King and David

Letterman are both calcified, as are many ageing news anchors. A

much

younger CBS Early Show co-host, Rene Syler, has it too.

As we learn more about it, calcification is competing to be the

leading

medical disorder. Although it is nowhere on the " Leading Causes of

Death " list, it contributes to most diseases that kill us, including

heart disease, diabetes and cancer. The numbers are staggering. For

the

60 million Americans who have heart disease, most have

calcification. Of

the millions of women who develop breast or ovarian cancer or who

have

breast implants, calcification is a warning. Men with prostate

disease

often have it, as do kidney-stone sufferers. Athletes with stress

injuries like bone spurs and tendonitis get it frequently.

Most of us don't know the pervasiveness of calcification because it

has

a different name in many diseases, and here are just a few: dental

pulp

stones, hardening of the arteries, kidney stones, pitcher's elbow,

bone

spurs, microcalcification in breast cancer and " brain sand " .

 

 

Unsuspecting patients aren't the only ones in the dark. Many doctors

are

unaware of new studies that show calcification is toxic, causing

acute

inflammation, rapid cell division and joint destruction. Oddly,

these

nasty effects are well known to specialists who study calcification

in

arthritis, but awareness of them hasn't translated very well to the

cardiovascular community, with the result that calcification is

still

misperceived by many as an innocent bystander instead of an

inflammatory

devil.

The double-think about calcification is illustrated by how it is

treated

in breast cancer. When microcalcification is detected in the breast

with

routine scans, it is a warning sign for cancer and the deposits are

biopsied for malignancies. This was the case, for example, with

Connecticut Governor Jody Rell in early 2005. Doctors found cancer

in

the calcium deposits in her breast before scans detected a tumour.

This

let them surgically remove it before it spread to her lymph nodes.

That typifies one perverse advantage of calcification: it helps

doctors

pre-empt more serious disease. In some ways, it is a canary in the

mine

of the body. And yet, if cancer is not found in calcium deposits,

these

are often declared as " benign " and patients are told there is

nothing to

worry about.

 

 

The same thing goes for heart disease. Coronary artery calcification

is

seen as an excellent predictor of the illness. Tens of billions of

dollars are spent every year on scanning technology to identify the

telltale thin white lines that betray its presence. Yet most doctors

see

calcification in the arteries as something that comes along later

once

the disease takes hold, despite evidence that calcium phosphate

crystals

generate the same type of inflammation that, according to

cardiologists,

plays a big role in heart attacks.

Incredibly, with all the advanced detection techniques, there has

been

no way to find calcium deposits where they get started in the

billions

of capillaries in the human body—so, without being able to see the

starting point, doctors often conclude that what they don't see

isn't

there. But make no mistake: calcification is there, and it is a

medical

disorder. It was registered in 1990 as a disorder under the

International Classification of Diseases list of the World Health

Organization and was adopted by WHO member states as of 1994 (see

http://www.who.int/classifications/icd/en/).

 

When well established, calcification stares defiantly at

radiologists

every day from X-rays as it multiplies incessantly. There has been

no

proof of where it comes from, and there is no known way to prevent

it or

sustainably get rid of it without removing it surgically. Due to its

gestation period of years before it triggers real trouble, it has

just

begun sucking the life out of baby boomers and their healthcare

budgets.

 

Among its more exotic effects, it threatens space exploration when

it

disables astronauts with unexpected kidney calcification and it is a

budget-breaker for pro-sport-team owners who lose athletes to its

ravages.

 

At the more mundane level, it complicates root canals and it

disrupts

the lives of otherwise healthy young people when it strikes as

kidney

stones. Worst of all, it infiltrates plaque in heart disease and

stroke

and it plugs bypasses and stents used to fix our internal plumbing.

The US National Library of Medicine holds thousands of research

documents referencing calcification, and various medical journals

cover

it in depth. GE Healthcare, Toshiba, Philips and Siemens sell

thousands

of machines for detecting it.

 

TREATMENT A THREAT TO PHARMCO PROFITS

But with all this money being thrown at calcification, there has

been

virtually no success at finding the cause. So when researchers such

as

those at Mayo Clinic and NASA find something that seems to cause it,

and

clinical studies show that a new approach seems to get rid of it,

you'd

think that most of the medical establishment would be rapt with

attention, right? Wrong.

Only a few small studies have been co-financed by the National

Institutes of Health (NIH) to look into this, and neither has to do

with

the treatment. The only thing the Food and Drug Administration (FDA)

seems to have done is to make rumblings about whether the treatment

is

legitimate, although the active ingredients—tetracycline and EDTA—

have

been FDA approved for other uses for decades. So far, no government

agency has made public note of the peer-reviewed studies that many

physicians say are so promising.

According to doctors familiar with the approach, here are a few

reasons

why the treatment has not been given the attention that it seems to

merit...

• The most perturbing for patients: the treatment is relatively

inexpensive and produces poor profits compared to other drugs. It is

exponentially cheaper than open heart surgery. Because it does not

have

to be taken for life at full dose—as is the case with most other

heart

drugs—it does not provide the steady cash flow that other medicines

do.

 

• Although the treatment is initially used alongside other medicines

as

a precaution to make sure patients don't switch prematurely and

suffer

problems, evidence suggests that the new approach might replace more

profitable blood thinners and anti-inflammatories that are staples

of

the pharmaceuticals industry.

• And if the approach continues to reverse coronary artery disease,

it

will cut down on expensive surgical procedures that are the

financial

mainstay of hospitals.

 

That's not to say surgeons don't want to get rid of calcification.

New

stents that go into arteries are specially coated with time-release

drugs that seem to ward off calcification. But that only happens

where

the stent is located, not in the other 99.999 per cent of the

arteries.

Also, the EDTA–tetracycline–nutraceutical combo that has

demonstrated

such promise is not the only treatment shown to work. A group of

drugs

known as bisphosphonates, used for example to treat osteoporosis,

has

been shown to be effective in the lab against some calcification.

But

bisphosphonates can have nasty side effects, especially with the

type of

regular application that seems to be necessary to reverse heart

disease

in seriously ill patients. Due to these risks, the only present

approach

that seems to be safe and effective in reversing heart disease is

the

one that uses the EDTA–tetracycline–nutraceutical mix.

 

Critics claim the reason why the treatment isn't adopted more

broadly

has nothing to do with money but instead with science. They say

researchers can't show how the treatment works.

 

NANOBACTERIA DISCOVERED IN OUR BLOOD

It all comes down to a sub-microscopic blood particle known as a

nanobacterium, discovered in 1988 by Finnish researcher Dr Olavi

Kajander at Scripps Research Institute in California.

The particle has a special habit no other blood particle has been

known

to possess: it forms a rock-hard calcium phosphate shell that is

chemically identical to the stuff found in hardening of the

arteries,

prostate disease, kidney disease, periodontal disease and breast

cancer.

The problem is, the particle is so small that it apparently can't

accommodate nucleic acid strings that, according to commonly

accepted

wisdom, would let it replicate on its own and be alive. So

scientists

are stumped over how it manages to self-replicate.

For 15 years, microbiologist Dr Neva Ciftcioglu (pronounced

" shift-show-lew " ) has been peering with an electron microscope at

this

blood particle that critics say doesn't live. But according to NASA

colleagues and Mayo Clinic researchers, the question of whether it

lives

is less important than what it does. Despite or perhaps due to its

tiny

size and genetic elusiveness, this speck may be the Rosetta stone

for a

calcified language found in most diseases on the Leading Causes of

Death

list.

Like her science, Ciftcioglu's life is full of unusual turns. Being

a

woman microbiologist from Turkey speaks volumes. Throw into that her

once-fluent Finnish, a position at NASA and professorships on both

sides

of the Atlantic, and you've got a determined character struggling

with a

stubborn scientific cryptogram.

Ciftcioglu's work with nanobacteria began when her PhD scholarship

took

her to the University of Kuopio in Finland, where alongside her once

mentor, biochemist Olavi Kajander, she developed the antibodies

necessary to find the particle in the human body. A decade later,

her

work caught the eye of NASA chief scientist Dr David McKay and she

ended

up at the Johnson Space Center in Houston, gathering science awards

that

testify to her success.

 

Now Ciftcioglu and long-time collaborator Kajander, who discovered

the

nanoscopic artifact, stand at the eye of a growing storm. They and

their

colleagues are garnering praise and scorn because they claim to have

evidence for why most of us are literally petrified by the time we

die.

More profoundly, their work may influence how new life is found on

Earth

and other planets.

 

SELF-REPLICATING NANOPARTICLES

An intense dispute has raged for years that connects how we look for

infection in the body with how we look for bio-kingdoms on Earth and

throughout the universe. Researchers have long sought terrestrial

extremophiles that tell them what might survive on Mars, while

others

doubt the wisdom of looking for life on Mars at all. The mystery

remains: what is the most effective way to find novel organisms?

 

Until recently, every life-form was found to have a particular RNA

sequence that can be amplified using a technique known as Polymerase

Chain Reaction (PCR). Nucleic acid sub-sequences named 16S rRNA have

been universally found in life-forms. By making primers against

these

sub-sequences, scientists amplify the DNA that codes for the 16S

rRNAs.

Resulting PCR products, when sequenced, can characterise a life-

form.

One high-powered group persuaded NASA with a " Don't fix it if it

ain't

broke " line and lobbied successfully to use the same method employed

for

years: get a piece of RNA and amplify it. The group—led by

scientists

such as Dr Gary Ruvkun at the Department of Genetics in

Massachusetts

General Hospital, Boston, and advised by luminaries such as Dr

Norman

Pace at the University of Colorado—got money from NASA to build

a " PCR

machine " that would automatically seek such clues in harsh

environments

such as those found on Mars.

Other scientists known as astrobiologists say the PCR machine

approach

is a waste of money because such amplification shows only part of

the

picture—not what nature might have done on other planets or, for

that

matter, in extreme Earthly environments.

However, their argument always suffered from lack of evidence—that

is,

until 2003 when scientists associated with the San Diego–based

Diversa

Corporation and advised by Professor Karl Stetter, of the University

of

Regensburg, Germany, published the genome of an extremophile known

as

Nanoarchaeum equitans, which Stetter's team had discovered in

Icelandic

volcanic vents.

N. equitans was special because it had the smallest known genome

found

so far, but it also had another intriguing trait. With Nanoarchaeae,

the

particular 16S rRNA sequence found in other life-forms wasn't in the

place that it was expected to be and did not respond to conventional

PCR

tests. The 16S rRNA sequence was different in areas addressed by the

PCR

primers and did not amplify. Stetter noted that the so-called

universal

probes that work with humans, animals, plants, eukaryotes, bacteria

and

archaeae did not work in this organism.

How, then, was the discovery made if the organism couldn't be

sequenced

in that way? Stetter had found that the organism's sequence where

the

traditional " universal " primers are located was abnormal. This

finding

let him use other means to sequence the gene. In reporting their

discovery in the Proceedings of the National Academy of Sciences,4

the

Stetter team observed that the information-processing systems and

simplicity of Nanoarchaeum's metabolism suggests " an unanticipated

world

of organisms to be discovered " . In other words, it might be the tip

of a

nano-lifeberg.

Stetter's finding gave ammunition to scientists such as Neva

Ciftcioglu

who say they have found other extremophiles, including human

nanobacteria, that cannot have their nucleic acids detected with

standard PCR amplification.

 

One of the differences between Stetter's N. equitans and the

nanobacteria found by Ciftcioglu and Kajander's team is that

Nanoarchaeae need another organism to replicate, whereas at least

some

nanobacteria seem to replicate by themselves. Another difference is

that

Nanoarchaeae are slightly wider: 400 nanometres compared to 100–250

for

nanobacteria. The greater size allows for what conventional wisdom

says

is the smallest allowable space for life-replicating ribosomes.

Which leads to the question: how do nanobacteria copy themselves?

Evidence for self-replicating nanoparticles has been around for

years in

everything from oil wells to heart disease, but failure to sequence

them

using regular PCR led some to dismiss them as contamination or

mistakes.

However, researchers have found characteristics that make the

particles

hard to explain away. They replicate on their own, so are not

viruses.

 

They resist high-level radiation, which suggests they are not

bacteria.

They respond well to light, where non-living crystals don't. So if

they

aren't viruses, regular bacteria or crystals, what are they?

Some supporters of standardised 16S rRNA tests are quick to discount

nanobacteria. That's not surprising. If a novel nucleic sequence

holds

true with other extremophiles as with N. equitans, then a machine

that

searches for life using standard PCR tests might miss them and be

obsolete. Conscious of this, the PCR machine team has said that as

part

of their work, they plan to " search for the boundaries " of the 16S

sequences, but what exactly that means and how they plan to overcome

the

problem hasn't been set out yet.

Reputations, money and perhaps the foundations of life ride on the

16S

rRNA dispute. Resolving it may determine who gets money to find the

next

great biological kingdom.

 

NANOBACTERIAL INFECTION

How relevant is the outcome for human welfare? In 2004, researchers

reported finding nanobacteria in everything from heart disease to

cancer

and kidney stones. Medical researchers reported to the American

Heart

Association's Scientific Sessions 2004 that a test for nanobacteria

is

an accurate predictor of heart disease risk. But the work that these

researchers say may already have saved lives has been ridiculed by

critics who claim that such nanobes don't exist, which in turn has

made

funding for basic research hard to get.

 

 

Who is right? One well-respected astrobiologist observer qualified

the

struggle this way: " Unless we declare [the nano-organism scientists]

incompetent, then the info they have gathered is rather compelling

that

something interesting is going on. "

That's why a few intrepid investors have plopped US$7 million and

counting into a Tampa biotech start-up devoted exclusively to

Ciftcioglu

and Kajander's discoveries about the calcifying particle. For the

big

pharmaceuticals companies that's pocket change, but for these

entrepreneurs it's a pocketful of faith that's been keeping them on

edge

for years. And it's starting to show some results, as published

research

from NASA, Mayo and various universities indicates. Moreover,

despite

its relative financial insignificance, this venture may end up

wagging

the dog due to a long-overdue paradigm shift in, of all things, the

space program.

 

 

After decades of resistance, NASA—provoked by successful upstart

private

projects such as the X Prize, which led to the first private foray

into

space—is now collaborating with fledgling companies, instead of just

corporate behemoths, on intractable problems: in this case, why

perfectly healthy astronauts come down with kidney and other

calcifying

disorders. The result: in March 2005, NASA's Johnson Space Center

put

the finishing touches on a tightly secured lab aimed at decoding

nanobacteria found at the core of kidney stones. After some serious

growing pains, the lab is finally beginning to look into what

Ciftcioglu

and Kajander began examining so many years ago: the genetic content

of

nanobacteria. Meanwhile, Ciftcioglu and others have published

results

showing that nanobacteria multiply five times faster in

weightlessness

than in Earth gravity,5 which may explain why calcification shows up

so

suddenly in space.

But while researchers argue over what this nanobacterium is and how

it

multiplies, doctors are finding that, when they treat it with a

medical

cocktail, their patients improve.

Nor is it unusual that doctors are succeeding before science figures

out

why. Antibiotics were used successfully against bacteria long before

scientists deciphered DNA. Doctors stopped infecting patients by

washing

their hands long before they were able to identify all the viruses

and

bacteria that they inadvertently transported from patient to

patient.

Most recently, a vaccine that prevents cervical cancer has been put

on

the market. It apparently works by targeting the human papilloma

virus.

Problem is, researchers can't show exactly how the virus causes

cancer;

they can only show that when it is stopped, the cancer doesn't

occur.

But that hasn't prevented the drug from being patented and put on

the

market. The history of medicine is full of such examples where

patients

improve with treatments whose mechanisms aren't fully understood at

the

start.

 

The idea that infection could be at the heart of chronic illness is

intriguing because it has been around for more than a century but

only

now is regaining favour due to discoveries of, for example, a

vaccine

that prevents cervical cancer (as mentioned above). The resulting

debates over infection in chronic disease have a novel twist because

they are driven by new diagnostic technologies that give researchers

the

molecular accuracy required to confirm older theories about

infection.

 

On one hand, clinical results suggest antibiotics alone do not

prevent

the rate of heart attacks among coronary patients. On the other,

discoveries that infection is responsible for most stomach ulcers

and

some cancers support the long-held idea that the same might be true

in

heart disease, if only science could find the right infection and

get

rid of it.

Some say that nanobacteria may be one such infection. Yet

scientists'

inability to fully explain the genetics of nanobacteria is being

used by

high-ranking medical authorities as an excuse to ignore the pathogen

and

its treatment. This is especially perplexing because scientists

involved

in the discoveries work at some of the highest level institutions in

America, including NASA, Mayo Clinic, Cleveland Clinic, Washington

Hospital Center and many others, and are not only respected in their

field but are also award winners. Other centres of excellence

internationally, such as University Hospital in Vienna, have also

isolated the pathogen and observed it in diseases such as ovarian

cancer.

 

For decades, scientists have shown that disease can be caused by

contaminants that are not " alive " and cannot replicate on their own.

Environmental toxins, many viruses and, most recently, particles

known

as prions have all been shown as players in disease processes,

although

they cannot self-replicate.

 

So it seems unusual that nanobacteria would be discounted just

because

no one has yet shown how they multiply. Which takes us to the

question

of where nanobacteria might come from.

 

NANOBACTERIA-CONTAMINATED VACCINES

 

When Dr Olavi Kajander discovered nanobacteria in 1988, he was not

looking for disease at all. He was looking for what was killing the

cells that are used to develop vaccines. Labs everywhere have a

vexing

and expensive problem with these widely used cell cultures: they

stop

reproducing or die after a few generations and have to be thrown

out.

 

Kajander surmised that something invisible was killing them; and

when he

incubated supposedly sterile samples for more than a month under

special

conditions, he got a milky biofilm. That biofilm contained particles

that he later named nanobacteria, unaware at the time that some of

their

characteristics made them quite distinct from bacteria.

 

The serum that Kajander used to grow the nanobacteria came from the

blood of cow foetuses. Serum from the UK especially was full of

nanobacteria, but a much later study also concluded they were

present in

some cow herds in the eastern US. In other words, nanobacteria are

in

cows, and cow blood is used to develop many vaccines.

 

Kajander emphasises that this should not stop people from using

vaccines, because the immediate risk from diseases that the vaccines

are

intended to prevent is relatively higher than the calcification risk

in

the short term. Nonetheless, the potentially explosive implications

of

contaminated vaccines and cow by-products would be clear to everyone

at

government agencies who has examined the issue.

In that context, a series of hotly disputed discussions went back

and

forth between Kajander and Ciftcioglu and disease prevention

agencies.

And it certainly wasn't a secret because the Medical Letter on the

CDC &

FDA (10 June 2001) published an article entitled " Nanobacteria Are

Present In Vaccines; But Any Health Risks Remain Unknown " ,

explaining

 

that nanobacteria had been discovered in some polio vaccines.

 

The minutes of a subsequent meeting of the FDA Center for Biologics

Evaluation and Research (CBER) advisory committee in November 2002

reveal an extraordinary decision by the committee members: they

elected

not to investigate the potential contamination. According to the

minutes

they based their decision on a lone experiment, suggesting that what

Kajander had found was a contaminant often found in lab experiments

and

nothing new. In other words, they maintained that Kajander had made

a

mistake.

 

But one of the glaring problems with the NIH-funded experiment

performed

around late 1999 or early 2000, as shown in the published paper

about

the results,6 is that it did not use a control sample that could

have

been provided by Kajander. In other words, the experiment never

examined

the particle that Kajander had discovered, but instead relied on

growing

the particle independently without knowing if it was the same one

Kajander was referring to. Moreover, the experiment was never

repeated

after the preliminary finding. On that very slim basis, according to

the

CBER committee minutes, the whole issue of nanobacteria was

dismissed as

a potential contamination issue for the time being.

 

Since then, papers have been published showing that nanobacteria

have

been grown in labs around the world and that patients began to

improve

when the pathogen was targeted in disease. Nonetheless, neither the

FDA

nor NIH has indicated much readiness to re-investigate the vaccine

contamination issue or the nanobacteria treatment.

 

What might be the price for this delay in researching nanobacteria?

Annually, millions of heart disease patients go through agony or die

because drugs and surgery prescribed for them haven't worked. For

this

last-ditch group, the choices are simple: try something new or die.

The question that the NIH and FDA may one day face is: when such

promising early evidence was being reported and so many patients had

exhausted their other options, why were doctors not advised of this

new

possibility so that they could at least tell patients and make some

informed decisions?

Researchers like Ciftcioglu and Kajander, along with cardiologists

like

Benedict Maniscalco plus experienced general practitioners such as

Douglas Hopper, profess frustration that so many patients and their

doctors are not being given the information that could help them,

especially in last-ditch situations. Meanwhile, calcification

continues

its relentless march in millions, and the human and financial costs

are

mounting.

 

POSTSCRIPT

In May 2005, Dr Olavi Kajander delivered a sobering message to a

joint

meeting of the US FDA and the European Medicines Agency on viral

safety

when he presented new evidence to support something first published

in

1997: that vaccines are contaminated with nanobacteria.

Since 1999, government agencies have done virtually nothing to

investigate the claim, due largely to that NIH experiment which

failed

to use particles discovered by Kajander as control samples; so now

that

the vaccine contamination has been officially reported to

authorities,

the question is: what will be done?

Then on 24 June 2005, a " smoking gun " was announced about calcium

deposits in heart disease. British researchers published proof in

the

leading medical journal Circulation Research7 that calcium phosphate

crystals cause inflammation in the arteries. Inflammation is a

leading

cause of heart attacks, but until now most cardiologists have

believed

calcification to be an innocent bystander in the inflammatory

process.

Because of that, calcium deposits were never targeted with

treatment. If

true, the British discovery would force a re-evaluation of the whole

medical approach, not only to inflammation but also to the

foundations

of heart disease, looking at calcification as a prime culprit.

 

About the Author:

Douglas Mulhall is a leading nanotechnology journalist who appears

often

on nationally syndicated talk shows in the US. As managing director

of

the Hamburg Environmental Institute, he co-developed methods now

used by

government agencies to measure environmental impacts. His book Our

Molecular Future (Prometheus Books, 2002) describes how to use

nanotechnology as a defence against tsunamis and other natural

disaster

risks. His disease prevention experience comes from pioneering water

purification technologies in China and South America.

Mr Mulhall's communications background began with a Bachelor of

Journalism (Hons.), progressed to (award-winning) documentary film

making, then diversified into management when he co-founded the

first

commercial TV network in the Republic of Ukraine. He has written

articles for US media such as News Day, The Futurist and The

National

Post as well as for publications in Germany and Brazil. He

contributed

to the first Financial Times (UK) book on green business

opportunities

and has also written and edited a range of technology training

books.

Douglas Mulhall sits on the advisory boards of the Center for

Responsible Nanotechnology and the Acceleration Studies Foundation.

He

has given invited lectures to organisations such as the National

Research Council, the US EPA and the Institute of Medicine.

 

Editor's Note:

This article is based on material in the book The Calcium Bomb: The

Nanobacteria Link to Heart Disease & Cancer, by Douglas Mulhall and

Katja Hansen (The Writers' Collective, 2005; see review this issue),

which was selected as a Finalist for the 2004 Book of the Year Award

for

Health by Foreword Magazine. For more information, visit

http://www.calcify.com.

 

Endnotes:

1. Maniscalco et al., " Calcification in Coronary Artery Disease can

be

Reversed by EDTA–Tetracycline Long-term Chemotherapy " ,

Pathophysiology,

July 28, 2004.

2. Shoskes, Daniel A., Kim D. Thomas and Eyda Gomez, " Anti-

nanobacterial

therapy for men with chronic prostatitis/chronic pelvic pain

syndrome

and prostatic stones: Preliminary Experience " , J. Urology, February

2005.

3. The ingredients are described in The Calcium Bomb, p. 94; they

are:

(1) nutraceutical powder (vitamins C and B6, niacin, folic acid,

selenium, EDTA, L-arginine, L-lysine, L-ornithine, bromelain,

trypsin,

CoQ10, grapeseed extract, hawthorn berry, papain), 5 cm3 taken

orally

every evening; (2) tetracycline HCl, 500 mg taken orally every

evening;

(3) EDTA, 1500 mg taken in a rectal suppository base every evening.

According to the representatives of the company that sells the

nutraceutical/EDTA combo, the treatment works this way: the

nutraceuticals boost the immune system, accelerate EDTA action and

reduce inflammation; the EDTA strips off the calcium phosphate

shell;

and the tetracycline eradicates the nanobacteria. The tetracycline

is

also a chelator on its own and helps remove the calcium phosphate.

4. Waters, Elizabeth et al., " The Genome of Nanoarchaeum equitans:

Insights into early archaeal evolution and derived parasitism " , PNAS

100(22):12984-12988, October 28, 2003.

5. Ciftcioglu et al., " A potential cause for kidney stone formation

during space flights: Enhanced growth of nanobacteria in

microgravity " ,

Kidney International 67:1-9, 2005.

6. Cisar, John O. et al., " An alternative interpretation of

nanobacteria-induced biomineralization " , PNAS 97(21):11511-11515,

October 10, 2000.

7. Nadra, Imad et al., " Proinflammatory Activation of Macrophages by

Basic Calcium Phosphate Crystals via Protein Kinase C and MAP Kinase

Pathways – A Vicious Cycle of Inflammation and Arterial

Calcification? " ,

Circulation Research 96(12):1248-1256, June 24, 2005.

_________________

Post subject: Claim made for new form of life

-

Claim made for new form of life

By Paul Rincon

BBC News Online science staff

 

http://news.bbc.co.uk/1/hi/sci/tech/3729487.stm

 

 

 

JoAnn Guest

mrsjo-

www.geocities.com/mrsjoguest/Diets

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

[Guest guest]

If you will demonstrate to my satisfaction, with clear evidence, that any form

of chelation works, oral or IV; in other words, that it can alleviate angina or

arteriosclerosis (the diseases for which it is most often prescribed), I'll

immediately give you $100,000.

jp

-

belltownfog

Monday, March 27, 2006 11:09 AM

Re: Chelation therapy?.

 

 

The following is the information i was seeking regarding chelation. Thanks

for all the helpful and useful information.

 

Vester

 

 

The Nanobacteria Link to Heart Disease and Cancer

JoAnn Guest

Mar 03, 2006 19:17 PST

 

The Nanobacteria Link to Heart Disease and Cancer

Nanoparticles are implicated in the harmful calcification that's

common to many illnesses.

A simple treatment is now reversing the symptoms, especially in

heart disease,

so why aren't the health authorities telling patients and doctors

about it?

 

http://www.nexusmagazine.com/articles/Nanobacteria.html

--

 

 

 

 

 

[Guest guest]

There are multiple studies that shows the efficacy of Chelation

Therapy. Here is one such study from the Journal of Integrative

Medicine...

 

Journal of Integrative Medicine 1997;1:7-12

 

Improved Myocardial Perfusion in Patients with Advanced Ischemic

Heart Disease with An Integrative Management Program Including

EDTA Chelation Therapy

 

Majid Ali, M.D., Omar Ali, M.D., Alfred Fayemi, M.D., Judy Juco,

M.D.,

Carol Grieder-Brandenburger, R.N.

 

From the Departments of Medicine of Capital University of Integrative

Medicine, Washington, D.C., and Institute of Preventive Medicine, New

York (MA,OA,AF,JJ, CG), the Department of Pathology, College of

Physicians and Surgeons, Columbia University, New York (MA), and

Department of Pathology, Mount Sinai School of Medicine (AF). Send

requests for reprints to MA at Suite 1-H, 140 West End Avenue, New

York, N.Y. 10083. This outcome study was presented in part at the

1995 annual meeting of the American Academy of Preventive Medicine in

New York.

 

Objective

To assess the clinical efficacy of an integrated management

program including nutritional and herbal therapies, nongoal-oriented

exercise, self- regulation, and EDTA chelation therapy for patients

with advanced ischemic heart disease (IHD).

 

Patients

Twenty-six consecutive patients who presented with advanced

ischemic heart disease and who had fared poorly after one or more

coronary bypass operations (5), one or more angioplasty procedures

(6), or who failed to respond adequately to multiple drug therapies

(15), and who had received a minimum number of 20 EDTA infusions.

Duration of follow-up ranged from 15 months to 9 years.

 

Methods

1. Clinical evaluation of patients before, during and after the

integrated program used in this study. 2. Assessment of myocardial

perfusion by comparative study of thallium perfusion scans performed

before and after the IHD reversal program.

 

Clinical Outcome Measures

The following clinical outcome criteria were semiquantitatively

defined: Excellent outcome, absence of significant symptoms and

discontinuance of previously prescribed drug therapies; good, 75%+

relief of symptoms and reduction of drug dose; moderate, 50%+ relief

of symptoms and reduction of drug dose; and poor, 25% or less relief

of symptoms and reduction of drug dosage. Elements for follow-up

included in the clinical outcome sheet were as follows: angina, chest

tightness and related discomfort, arrhythmia, other chest symptoms,

dyspnea, severity of stress, mood changes, anger, energy level,

quality of sleep, appetite, digestion and frequency of bowel

movements (all clinical parameters that determine the degree of AA

oxidopathy—a state of chronic and insidious accelerated oxidative

molecular injury to all elements of the circulating blood which we

consider to be the core pathogenetic mechanism of IHD.1)

 

Results

Clinical outcome data are as follows: excellent 61%, good 17%,

moderate 13%, and poor 9%. Comparative study of pre- and post-

chelation myocardial perfusion scans showed clear, objective evidence

of significant improvement in myocardial perfusion in five of six

patients in whom such studies were performed. No patients during the

study period suffered an acute myocardial infarction or underwent

angioplasty or coronary bypass operation.

 

Conclusion

Preliminary and limited outcome data in this study indicate

significant potential for reversing IHD in patients with advanced

ischemic heart disease by an integrated management plan with global

emphasis on reducing oxidative stress on the circulating blood,

cardiac myocytes and the conducting system of the heart. The program

included nutritional and herbal therapies, self-regulation, nongoal-

oriented exercise and EDTA chelation therapy. Additional and larger

studies are warranted to fully explore the clinical potential of such

an integrated management plan.

 

www.majidali.com/edta.htm (full bibliography in link)

 

 

 

, " John Polifronio "

<counterpnt wrote:

>

> If you will demonstrate to my satisfaction, with clear evidence,

that any form of chelation works, oral or IV; in other words, that it

can alleviate angina or arteriosclerosis (the diseases for which it

is most often prescribed), I'll immediately give you $100,000.

> jp

> -

> belltownfog

>

> Monday, March 27, 2006 11:09 AM

> Re: Chelation therapy?.

>

>

> The following is the information i was seeking regarding

chelation. Thanks

> for all the helpful and useful information.

>

> Vester

>

>

> The Nanobacteria Link to Heart Disease and Cancer

> JoAnn Guest

> Mar 03, 2006 19:17 PST

>

> The Nanobacteria Link to Heart Disease and Cancer

> Nanoparticles are implicated in the harmful calcification that's

> common to many illnesses.

> A simple treatment is now reversing the symptoms, especially in

> heart disease,

> so why aren't the health authorities telling patients and

doctors

> about it?

>

> http://www.nexusmagazine.com/articles/Nanobacteria.html

>

--

>

>

>

>

>