Re: Iodine and CFIDS

[Guest guest]

> So the question is: How many of you have tried kelp tablets? What

> effects did you see... did you have cold hands/feet before?

I did try kelp tablets maybe 5 yrs into my illness(ill now 24 yrs). I tried a

lot and I tried a little for quite awhile and I didn't notice any difference in

any symptoms at all. I was later put on

Thyroid med which helps me some, I wouldn't want to be without it, but its not a

cure for my CFS :-(

Marcia

[Guest guest]

Ken,

Im not sure if this helps, but Ive often found myself to crave

eating prawns with this illness, and felt generally really good after

eating them (although guilty because of how expensive they are).

Anyway I believe prawns are high in iodine also.

Sincerely,

.

>

> SPECULATION: that the dysfunctions produced by CFIDS may result in

> reduce absorbtion of Iodine OR reduced efficiency in using iodine...

> There may also be a connection between some forms of coagulation

and

> iodine.... UNFORTUNATELY -- almost all research about iodine has

> been focused on severe iodine deficiency.... goiter and cretinism.

>

> Iodine does affect the thyroid

>

> So the question is: How many of you have tried kelp tablets? What

> effects did you see... did you have cold hands/feet before?

[Guest guest]

Ken,

I have tried kelp in the past, along with everything else. I didn't notice

any circulatory benefits. My sinuses were slightly clearer, though this

was as likely to be immune suppression as anything else. Kelp blocks

guaifenesin and several other herbs, BTW.

Salt here in the UK is not iodised, but I thought it was in the US. If so,

then only those in a low iodine area and on a low sodium diet should be

deficient in iodine.

Rob

Iodine and CFIDS

> One characteristic that some people have reported associated with

> CFIDS is cold hands and feet (Circulation problems). This is

> consistant with the model of coagulation induced circulation

> problems. I remember (pre-recent CFIDS round) that I had the same

> indication of a circulation problem which improved greatly within a

> month of starting kelp tablets (High Iodine). based on " herbal books "

> about how to correct cold hands and feet.

>

> This caused me to do a bit of searching on Iodine...

>

> What I found was:

> * Mild iodine deficiency has been reported to reduce intelligence

> quotients (I.Q.) by 10-15%. http://www.sph.emory.edu/PAMM/iodine.htm

> Interestingly Hyde et al report a 20-30% drop in IQ seen with CFIDS.

>

> SPECULATION: that the dysfunctions produced by CFIDS may result in

> reduce absorbtion of Iodine OR reduced efficiency in using iodine...

> There may also be a connection between some forms of coagulation and

> iodine.... UNFORTUNATELY -- almost all research about iodine has

> been focused on severe iodine deficiency.... goiter and cretinism.

>

> Iodine does affect the thyroid.See

> http://www.meddean.luc.edu/lumen/MedEd/medicine/endo/thyroid/thy9.htm

>

> and " We found important differences in the coagulatory /fibrinolytic

> parameters between the hyperthyroid patients and healthy controls. "

> http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?

> cmd=Retrieve & db=PubMed & list_uids=12030606 & dopt=Abstract

>

> So the question is: How many of you have tried kelp tablets? What

> effects did you see... did you have cold hands/feet before?

>

>

>

>

>

>

>

> This list is intended for patients to share personal experiences with

each other, not to give medical advice. If you are interested in any

treatment discussed here, please consult your doctor.

>

>

[Guest guest]

I tried kelp tablets several years ago, but it did nothing at that time.

However, I had significant improvement in my cold hands and feet when I

started 100 mg. of QMax, the form of CoQ10 that my naturopath recommended.

(I didn't have this same benefit from any of the other brands of CoQ10 that

I tried, including Q-gel.)

I remember reading somewhere about a test to determine if you are

insufficient in iodine. You get a bottle of tincture of iodine from the drug

store, and paint a 1 inch square of it on your body somewhere. If you are

iodine deficient, the square will have been completely absorbed within 24

hours. When I did this test on myself, the square was completely absorbed

within an hour. However, the bottled brand of iodine from stores (which

contains sodium iodide) is not a particularly good way to get iodine.

(sodium iodide can exacerbate fibrocystic breast disease, which I have)

I have a concern that kelp may be a source of mercury, as well as other

heavy metals, as many algae types of plants absorb mercury and other heavy

metals, and kelp, as far as I know, is an algae type plant. I did some

digging around on the Internet, and found warnings about kelp contributing

to heavy metal problems, but couldn't find any information about how to

differentiate whether or not any kelp brands had been tested to determine

safe brands. The benefits of kelp that are listed, sound like it could be

very beneficial. But I don't know if those benefits can outweigh the risk of

increasing heavy metals. Would anyone happen to know a SAFE brand of kelp?

As for why I haven't benefited in the past when I took it, I have a lot of

malabsorption problems, which likely contributes to my not absorbing it. Any

suggestions on getting past that problem?

lindaj@...

Iodine and CFIDS

> One characteristic that some people have reported associated with

> CFIDS is cold hands and feet (Circulation problems). This is

> consistant with the model of coagulation induced circulation

> problems. I remember (pre-recent CFIDS round) that I had the same

> indication of a circulation problem which improved greatly within a

> month of starting kelp tablets (High Iodine). based on " herbal books "

> about how to correct cold hands and feet.

>

> This caused me to do a bit of searching on Iodine...

>

> What I found was:

> * Mild iodine deficiency has been reported to reduce intelligence

> quotients (I.Q.) by 10-15%. http://www.sph.emory.edu/PAMM/iodine.htm

> Interestingly Hyde et al report a 20-30% drop in IQ seen with CFIDS.

>

> SPECULATION: that the dysfunctions produced by CFIDS may result in

> reduce absorbtion of Iodine OR reduced efficiency in using iodine...

> There may also be a connection between some forms of coagulation and

> iodine.... UNFORTUNATELY -- almost all research about iodine has

> been focused on severe iodine deficiency.... goiter and cretinism.

>

> Iodine does affect the thyroid.See

> http://www.meddean.luc.edu/lumen/MedEd/medicine/endo/thyroid/thy9.htm

>

> and " We found important differences in the coagulatory /fibrinolytic

> parameters between the hyperthyroid patients and healthy controls. "

> http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?

> cmd=Retrieve & db=PubMed & list_uids=12030606 & dopt=Abstract

>

> So the question is: How many of you have tried kelp tablets? What

> effects did you see... did you have cold hands/feet before?

>

>

>

>

>

>

>

> This list is intended for patients to share personal experiences with each

other, not to give medical advice. If you are interested in any treatment

discussed here, please consult your doctor.

>

>

[Guest guest]

Hi ,

With prawns there is another possibility -- the protien in them is

easier to digest than fowl or meat. After initial onset, I found

myself craving protien in the form of peanut butter - which WITH b-

vitamins gave my body all of the components needed to generate more

red-blood cells (and thus improve oxygen delivery).

Digestion problems (including leaky gut) are common with CFIDS and

mal-absorbtion of tradition protien sources seems to be very common.

Hence the use of non-denatured whey (which is very easy to absorb)

as a way of getting protien often occurs.

Of course, one could go all of the way in this direction and see if

there are any sellers of non-pasturized, non-homog. milk in your

state - thus getting a richer amino acid mix (since pasturization

and homog. reduces/breakdown the original components) . It is

available in some states.

> Ken,

> Im not sure if this helps, but Ive often found myself to crave

> eating prawns with this illness, and felt generally really good

after

> eating them (although guilty because of how expensive they are).

> Anyway I believe prawns are high in iodine also.

>

> Sincerely,

> .

>

[Guest guest]

I have traditionally gone for Icelandic Kelp -- it is a very

isolated location, away from the chemical plants of US and Europe.

On a related question. US salt has iodine -- however reviewing the

available literature (so far), it is yet to be demonstrated that

everyone needs the same level of iodine. My ancestory is coastal

area where fish has been a large part of the diet for centuries..

thus it seemed to make sense that my genetics may have normalize to

higher quantities of iodine.

my reading on

http://www.meddean.luc.edu/lumen/MedEd/medicine/endo/thyroid/thy9.htm

has 10% with hyperthyrodism when below the " norm " that decreases to

2% for those above the norm. And for Hypothryoidism it is 5% when

below the norm and 22% above the norm. This implies to me that there

is a great variation in people on the " right amount " of iodine.

The test that you suggested is interesting -- as always, although

there may be common-aspects to CFIDS, everybody has a DIFFERENT road

to walk ..... with some potential 20+ infections involved and some

8+ coagulation defects, we have at least " 160 types of CFIDS " -

depending on the interactions of these. Add in genetics and it gets

more variations still. So do not look for a magic universal cure,

but carefully work your ways thru the possiblities.

> Would anyone happen to know a SAFE brand of kelp?

>

> As for why I haven't benefited in the past when I took it, I have

a lot of

> malabsorption problems, which likely contributes to my not

absorbing it. Any

> suggestions on getting past that problem?

>

>

> lindaj@h...

>

[Guest guest]

I have traditionally gone for Icelandic Kelp -- it is a very

isolated location, away from the chemical plants of US and Europe.

On a related question. US salt has iodine -- however reviewing the

available literature (so far), it is yet to be demonstrated that

everyone needs the same level of iodine. My ancestory is coastal

area where fish has been a large part of the diet for centuries..

thus it seemed to make sense that my genetics may have normalize to

higher quantities of iodine.

my reading on

http://www.meddean.luc.edu/lumen/MedEd/medicine/endo/thyroid/thy9.htm

has 10% with hyperthyrodism when below the " norm " that decreases to

2% for those above the norm. And for Hypothryoidism it is 5% when

below the norm and 22% above the norm. This implies to me that there

is a great variation in people on the " right amount " of iodine.

The test that you suggested is interesting -- as always, although

there may be common-aspects to CFIDS, everybody has a DIFFERENT road

to walk ..... with some potential 20+ infections involved and some

8+ coagulation defects, we have at least " 160 types of CFIDS " -

depending on the interactions of these. Add in genetics and it gets

more variations still. So do not look for a magic universal cure,

but carefully work your ways thru the possiblities.

> Would anyone happen to know a SAFE brand of kelp?

>

> As for why I haven't benefited in the past when I took it, I have

a lot of

> malabsorption problems, which likely contributes to my not

absorbing it. Any

> suggestions on getting past that problem?

>

>

> lindaj@h...

>

[Guest guest]

> Salt here in the UK is not iodised, but I thought it was in the US. If so,

> then only those in a low iodine area and on a low sodium diet should be

> deficient in iodine.

Rob,

most salt in the US is iodized, but you can buy it either way in most grocery

stores with/or without it. I've always bought iodized salt. A few years ago when

I changed to strictly sea salt from

the health food store I found a brand that sells an iodized sea salt, because I

was concerned about that. Thats interesting that salt in the UK is not iodized,

where do people get that nutrient?

Marcia

[Guest guest]

Marcia,

Iodine is present in the soil and hence in vegetables. Historically, a

person's iodine status has depended on the local soil content.

Traditionally, I think Derbyshire in England was infamous for goitre,

though nowadays food travels much further so these deficiencies have been

ironed out to some extent -- at least in a fairly small country like ours

but probably not to the same extent in the US. Anyone taking supplementary

iodine needs to be careful because as always, too much is as bad as too

little.

Rob

Re: Iodine and CFIDS

>

>

> > Salt here in the UK is not iodised, but I thought it was in the US. If

so,

> > then only those in a low iodine area and on a low sodium diet should

be

> > deficient in iodine.

>

> Rob,

>

> most salt in the US is iodized, but you can buy it either way in most

grocery stores with/or without it. I've always bought iodized salt. A few

years ago when I changed to strictly sea salt from

> the health food store I found a brand that sells an iodized sea salt,

because I was concerned about that. Thats interesting that salt in the UK

is not iodized, where do people get that nutrient?

>

> Marcia

>

>

> This list is intended for patients to share personal experiences with

each other, not to give medical advice. If you are interested in any

treatment discussed here, please consult your doctor.

>

>

[Guest guest]

The reason why salt was originally iodized was because soils in the United

States were typically deficient of iodine, especially away from coastal

areas. Goiters were common in the mid-west because of iodine deficient soils

up until they began iodizing salt. However, although table salt is typically

iodized, salt used in processing foods is very often not iodized, because

iodized salt can contribute to discoloring, cloudiness, etc. in processed

foods. So even if a person is not eating a low sodium diet, and even if they

use iodized table salt, they can still become iodine deficient.

Additionally, iodine is not readably absorbed by everyone. Some people are

more prone to become iodine deficient because they don't absorb it as well.

Because food is now commonly transported from coast to coast, and

internationally, having iodine deficient soils may impact people in areas

where there is adequate iodine in the soil, and visa versa not be a problem

for people living in area's with poor iodine content in the soil.

I would imagine that the soil in the UK has a much higher iodine content,

since it is generally closer to island/coastal land, so iodine deficiencies

probably haven't generally been a problem there, and they haven't had to

resort to iodizing salt to replace iodine. But the more food that's imported

is eaten, the more likely a problem might occur. Iodized salt is not the

only source of iodine, however.

lindaj@...

Re: Iodine and CFIDS

>

>

> > Salt here in the UK is not iodised, but I thought it was in the US. If

so,

> > then only those in a low iodine area and on a low sodium diet should be

> > deficient in iodine.

>

> Rob,

[Guest guest]

kelp fluoride ( Google Search)

======================

http://home.thezone.net/~ampi/fucus.html

Iodine 300.00

Fluoride 44.00

-----------------------------

http://www.rvi.net/~fluoride/PFPC/f_in_food.htm

328 mg/kg Super Kelp Tablets

-------------------

http://www.bowtechforhealth.com/news/Thyroid_Kelp.htm

Fluoride and chlorine are two chemicals that are detrimental to the

health of the thyroid. They block receptors in the thyroid that take

up iodine. Radiation is also another substance that can be

detrimental to the thyroid as radiation treatments anywhere in the

body can settle in the thyroid. On the other hand, adequate iodine

consumption as well as a healthy nervous system can do wonders for an

ailing thyroid.

--------------------

http://www.bruha.com/fluoride/html/pfpc__3.html

" FLUORIDES: ANTI-THYROID MEDICATION "

1) EARLY PIONEERS

(the following information has been compiled from the references

listed at the end of the newsletter)

In 1932 Wilhelm May first reported on his findings using sodium

fluoride in the treatment of hyperthyroidism.

May had been largely inspired by the work of Goldemberg who was based

in Buenos Aires and had published extensively between 1919 and 1930

on his findings of applying fluorides as anti-thyroid medication.

Goldemberg firmly believed that the occurrence of goiter and

cretinism was NOT due to iodine deficiency, but to excessive fluoride

intake from air, food and water.

Investigating areas then commonly referred to as " goiterous waters "

('Kropfwaesser') and reviewing the work by Repin, Gautier, Clausmann,

McCarrison, Parhou and Goldstein, Pighini, Cristiani, Cahages,

Houssay, Tappeiner, Schulz, Brandt and Pisotti, Goldemberg became

convinced of the fluorine-iodine antagonism and thus began using

fluorides in the successful treatment of hyperthyroidism.

As a result of Goldemberg's findings, May likewise began with fluoride

therapy in preliminary trials involving 39 patients in Germany,

publishing the results in 1932. By 1935 he had observed the

antagonism successfully in 800 more patients.

May - as did Goldemberg before him - reported that the thyroid after

fluoride administration developed a similar hyperplasia as were seen

in goiter.

Like Goldemberg, von Mundy, and Todd, May found that the fluoride-

iodine antagonism was most easily observable through fluoride's

action on glycolysis in the liver. [Glucose is required to convert

thyroxine (T4) to the biologically active triiodothyronine (T3). This

occurs mainly in the liver, if glucose is adequate].

According to Dresel and Goldner glycolysis in the liver was to be seen

as the FIRST sign of thyroid hormone activity. Abelin had shown that

priority in the treatment of hyperthyroidism had to be given to

improving the disturbed liver function. Later Stuber and Land

reported their findings that glycolysis was inhibited directly

correlating with increasing fluoride levels in the blood.

First experiments with sodium fluoride, showing inhibitory effects on

glycolysis in isolated muscle tissue had been published as early as

1869 [Nasse O - " Beitraege zur Physiologie der contractilen

Substanz " ; Pfluegers Archiv fuer Physiologie 2: 97-121 (1869)].

is further reported that fluoride were to be seen as catalyst

in the process of calcium binding. Goldemberg had already pointed to

increased calcium levels in the blood due to fluoride .

According to Saegesser hypercalcemia occurred in hypothyroidism. He

showed that this was due to increased calcium levels in the blood,

resulting from a reduction in calcium excretion. In hyperthyroidism,

therefore, a reverse condition of INCREASED calcium elimination had

to be observable, and this was indeed confirmed by May in 1935.

In 1937 Dr. Georg Litzka reported on the use of 3-fluorotyrosine in

the treatment of hyperthyroidism which was now being used by him and

May. IG Farben had brought this product (developed by Schiemann and

co-workers) onto the market under the tradename " Pardinon " . (IG

Farben, of course, was also the notorious and most powerful industry

cartel which developed Sarin.)

Schoeller and Gehrke had earlier brought evidence that the specific

traits of the fluorine atom were sustained when bound in organic

compounds.[schoeller a. Gehrke - Klin. Wochenschr. 1129 (1929)]

When tyrosine was bound to fluorine, the action of fluorine were not

only sustained, but greatly magnified and a mere 0.1mg/day F- had

therapeutic effects on humans.

[We have since found much evidence of this in ALL our fluoride-

compound investigations, be it tolylfluanid (pesticide), PMSF,

Prozac, Paxil, phenothiazine or many other fluorinated medications.

The thousands of studies on fluoride-aluminum compounds or beryllium

fluoride clearly show this as well by their documented G protein

activation, an activity normally reserved for TSH, the thyroid

stimulating hormone. TSH controls iodine,selenium and zinc]

For May, 3-fluorotyrosine became the treatment of choice in

hyperthyroidism. Within 6 to 8 weeks patients became symptom-free,

and employment-ready. (1937) Litzka and May were able to document and

supply evidence for all claims. Between Jan.1, 1935 and October 1936,

May further cured 501 patients successfully with fluorotyrosine.

Around the same time (1932) Gorlitzer von Mundy, being aware that

fluorides also get absorbed through the skin, began fluoride

treatments of hyperthyroid patients in Austria by prescribing 20

minute baths containing 30ccm (0.03l) HF per 200 liters of water. He

reported on his successful treatment spanning over 30 years and

involving over 600 patients at a 1962 symposium on fluoride toxicity

organized by Gordonoff in Bern, which was also attended by other

world-leading experts including the great Waldbott, Steyn, and

others.

--------------------------------------------------------------

#2) GALETTI

We have received several comments from doctors and dentists who we

have sent some of our documents to. They claim that fluoride

suppresses the thyroid only at high doses, citing the Galetti paper

from 1958. This is NOT correct. We wish these folks had a better

understanding of thyroid disease and function. It shows how much

ignorance relating to thyroid disorders must be overcome first in

order to have this issue addressed properly. There is a reason why

the thyroid has often been called the most neglected and

misunderstood organ in the body... We are concentrating our efforts

to bring this information to endocrinologists. It is this field which

should be addressing the fluoride issue.

The fact is that in ALL cases but 1 fluoride showed reduced plasma

bound iodine, even at 0.9 mg/day - a fact of great importance when

one considers the current knowledge on sub-clinical hypothyroidism.

The critics critics don't bother to analyze the actual data, but tend

to concentrate on the author's conclusion which state his doubts

about fluoride as an effective anti-thyroid. There is much wrong with

that, for if one does not understand thyroid disorders and evaluate

the test methods properly, one surely cannot evaluate results

correctly. Galetti's conclusions are very much based on knowledge as

it was in the year 1958, and he displays severe ignorance about

thyroid function and anti-thyroid agents when compared to today's

standards. However, it's his DATA that's important. In ALL cases but

1 the Basic Metabolic Rate (BMI) decreased. This was achieved

sometimes within 20 days. To evaluate this properly, one needs to

understand how anti-thyroid agents work. It is well known in the

field of endocrinology that PTU and Methimazole, the two drugs

currently used in the treatment of hyperthyroidism, sometimes can

take a few months to kick in, due to the

thyroid storing large amounts of iodine. Galetti seems to complain

about the fact that it took so long, concluding that it

was " effective only occasionally among people subjected to massive

doses of this substance " (This besides the fact that 6 of 15 patients

were completely healed!...average " massive " dose meaning 6mg NaF (2.9

F-) daily, less than half the intake as estimated in 1991 by the US

PHS in fluoridated areas =>6.5mg F-)

One patient was clinically cured by 2.72 mg F-/day over a period of

four month period...

---------------------------------------------------------------

#3)IODINE DEFICIENCY OR FLUORIDE EXCESS?

EXCERPTS from WORLD HEALTH ORGANIZATION PRESS RELEASE, May 25, 1999

World Health Organization Sets Out To Elimate Iodine Deficiency

Disorders

" It affects 740 million people a year. It causes brain disorders,

cretinism, miscarriages and goiter. It is the world's single most

important and preventable cause of mental retardation. And it is

almost unknown...Calling it one 'one of the best kept secrets' the

WHO has rededicated itself to eliminating Iodine Deficiency Disorder,

or IDD, through an intense programme of salt iodisation and iodine

delivery within the next decade. "

IDD: The Impact

IDD is a significant public health problem in 130 countries,

affecting a total of 740 million people. While remarkable measurable

progress is being made through universal salt iodization, there are

nearly 50 million people estimated to still be affected by some

degrees of IDD-related brain damage.

One third of the world's population is estimated to be at risk of

IDD. Since the passage of a special resolution at the World Health

Assembly in 1990 and subsequent resolutions in 1992 and 1996, the

Department of Nutrition for Health and Development (NHD) of WHO has

worked tirelessly to establish iodisation programmes around the world.

The director of the NHD Department, Dr. Graeme Clugston, points out

that 'The tragedy is that such a huge global burden of brain damage

is still occurring, much of it irreversible, yet less than a single

teaspoon of iodine is all a person requires during an entire

lifetime.' "

-------

Is this really iodine deficiency? Or is Goldemberg right, and it's

really caused by excessive fluoride intake through water, food and

air and which dose-dependently reduces biologically active iodine in

the system and causes biochemical iodine deficiency? We agree with

Goldemberg.

Let's look at one example - Hong Kong. Water fluoridation was

introduced in 1961.

Hong Kong is declared an area of Iodine Deficiency. This is

completely absurd, as it is in most areas in Asia where sea products

are commonly consumed. Both hypo- and hyperthyroidism exist in Hong

Kong.

A paper was published in 1996 in the European Journal of Clinical

Nutrition [Kung AWC, Chan LWL, Low LCK, JD - " Existence of

iodine deficiency in Hong Kong - A coastal city in southern China "

Eur J Clin Nutr 50; 8 (1996)] which shows that " as far as IDD is

concerned, Hong Kong is just another big city in China. " (CCPR) The

study shows that although Hong Kong is a non-goitrous area, iodine

deficiency exists. Iodine intakes, as reflected in urinary iodine

excretion, were found to be marginally deficient. The study was done

out of concern because a high percentage of newborns were found to

have TSH cord blood values greater than 5mIU/l and a high incidence

of transient neonatal hypothyroidism.

There is NO " iodine deficiency " in Hong Kong.

Here is the more than obvious proof:

Responding to another study which had found that Chinese children in

Hong Kong have a higher incidence of hyperthyroidism, the Consumer

Council took steps to inform the public on the adequacy of iodine

intake, and in association with the Chinese University of Hong Kong,

examined the iodine content of 146 food products including seafood,

salt, seaweed products, meat, vegetables, eggs, soy sauce, milk and

butter.

The amount of iodine customarily consumed in a meal of some dried

seafood, e.g. kelp, mussels, seadragon and seahair was shown to be

much higher than the WHO recommended daily intake for children or

adults. The average iodine concentration of roasted seaweeds is some

400 times higher than that of vegetables.

6 brands of roasted seaweed were found to contain comparatively high

iodine concentration. Consuming 2g (about 7 to 8 small slices or 2

small packages) would have exceeded the WHO recommended daily iodine

intake for children under 12 years old. 3 milk products were found to

contain a particularly high iodine content.

Iodine Deficiency?

In the WHO South-east Asia region alone maternal and hence

fetal " iodine deficiency " is responsible for 101,800 stillbirths and

93,500 neonatal deaths, each year, in the region's eight member

countries, NOT EVEN INCLUDING CHINA!

FLUORIDE KILLS!

REFERENCES:

************************

iodine fluoride intelligence (search)

===============

Iodine Deficiency Disorder Newsletter 1991 August Vol. 7 No. 3

The Relationship of a Low-Iodine and High-Fluoride Environment to

Subclinical Cretinism in Xinjiang

Discussion

One hundred and four children with mental retardation were detected

in all. Area A had 25%, area B 16%, and area C 8%. The significant

differences in IQ among these regions suggests that fluoride can

exacerbate central nervous lesions and somatic developmental

disturbance caused by iodine deficiency. This may be in keeping with

fluoride's known ability to cause degenerative changes in central

nervous system cells and to inhibit the activities of many enzymes,

including choline enzymes, causing disturbance of the nerve impulse

(5). We found significant differences among the three areas,

indicating that lack of iodine in children results in disturbance of

the process of growth and ossification and that high fluoride intake

can further disturb bone development (6,7). Also, the auditory

threshold was significantly different among the three areas, with

severe loss of hearing in high fluoride and low iodine areas. Severe

iodine deficiency in early fetal life has adverse effects on the

development and differentiation of the acoustic organ, and we suggest

that high fluoride intake may also promote hearing loss.

In this study, we found that 69% of the children with mental

retardation had elevated TSH levels. IQ and TSH were negatively

correlated. Many investigators regard an elevated TSH in the presence

of normal T4 and T3 levels as evidence for hypothyroidism that is

subclinical but that can still affect the development of brain and

cerebral function to some degree (6). Reverse T3 (rT3) is formed from

T4 by 3-deiodination in peripheral tissue. The balance of active T3

and inactive rT3 in the serum reflects thyroid hormone economy. In

high fluoride and low iodine areas, the rT3 value was 58 ng/dl (the

normal value, 21 ng/dl), and the ratio of rT3/T3 was 2.91,

significantly low. In areas of low iodine the rT3 value was 32 ng/dl,

and the ratio of rT3/T3 was 5.8. It is possible that excess fluoride

ion affects normal deiodination.

We detected 104 cases with mental retardation among 769

schoolchildren, aged 7-14, in different affected areas. Some 69% of

our cases with mental retardation had one or more items of the

accessory conditions recommended for the diagnosis of subclinical

cretinism by the National Conference on Subclinical Cretinism held in

Xinzhou (4). According to the cautious suggestion of Qian Qi-Dong

that the diagnosis should require two or more of the accessory

conditions, 56% of our cases could still be diagnosed as having

subclinical cretinism.

Currently, in the vast remote areas of South Xinjiang the control of

IDD with iodized salt has not yet been generally implemented and the

prevalence of subclinical cretinism is still high. This situation is

a great obstacle to the child health, agricultural development, and

economic prosperity of minority nationalities in South Xinjiang and

necessitates prompt implementation of iodine supplementation to

control subclinical cretinism.

Summary

We studied a total of 769 schoolchildren of 7-14 years in three

areas, characterized by intakes of (A) low iodine, high fluoride; (

low iodine, normal fluoride; and © iodine supplemented, normal

fluoride. Results for the following parameters for areas A, B, and C,

respectively were: (a) average IQ: 71, 77, 96; ( average auditory

threshold (in dB): 24, 20, 16; © bone age retardation (%): 28, 13,

4; (d) thyroid 131I uptake (%): 60, 50, 24; and (e) serum TSH

(mU/ml): 21, 11, 6. Statistically significant differences existed

between these areas, suggesting that a low iodine intake coupled with

high fluoride intake exacerbates the central nervous lesions and the

somatic developmental disturbance of iodine deficiency. The detection

rate of subclinical endemic cretinism in children with mental

retardation was 69%, and the total attack rate of subclinical endemic

cretinism 9%.

References

-----------------------------

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==============================

blood coagulation fluoride

<http://lassesen.com/cfids/coagulation_triggers.htm>

<http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?>

cmd=Retrieve & db=PubMed & list_uids=1568504 & dopt=Abstract

Pub Med

Fiziol Zh 1992 Mar-Apr;38(2):85-90

[The mechanisms of the action of fluorine on periodontal tissues]

[Article in Russian]

Silenko IuI, Tsebrzhinskii OI, Mishchenko VP.

It is stated that fluoride intoxication promotes a sharp

intensification of the peroxidation processes in the parodontium

tissues. It is caused by a respirator explosion of neutrophils, a

decrease in activity of antioxidant system enzymes, thus leading to

disturbances of microcirculation and blood coagulation, ischemia

development. The last factor can retard the enzymatic oxidation in a

cell due to hypoxia, injures lysosomal membranes promoting partial

autolysis of parodontium tissues, cell structures, intercellular

substance. The interaction of blood with destructive elements of

cells and collagen favours the development of trombohemorrhagic

reactions in the parodontium tissues. A generalized damage of

parodontium arises which intensifies under the effect of any other

pathogenetic factors.

PMID: 1568504 [PubMed - indexed for MEDLINE]

+++++++++++++++++++++++++++++++++++

<http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?>

cmd=Retrieve & db=PubMed & list_uids=483736 & dopt=Abstract

Vrach Delo 1979 Aug;(8):106-7

[blood coagulation and fibrinolysis during exposure to fluorides]

[Article in Russian]

Shkliar AS.

PMID: 483736 [PubMed - indexed for MEDLINE]

++++++++++++++++++++++++++++++++++++++

goiter fluoride

http://www.fluoridealert.org/f-iodine.htm

In 1854 Maumene feeds 10g sodium fluoride (4.5g F-) to a dog and

causes a goiter to appear. He was the first to consider fluorides as

a cause of goiter.

Pighini (1923) is also able to cause goiters in rats, dogs and

chicken.

Wespi finds mottled teeth (dental fluorosis) together with goiters in

Italy. (1954)

In 1969 Siddiqui show small visible goiters in persons 14 to 17 years

of age in India to be connected directly to high fluoride

concentrations in drinking water

1972 Day and - studied 648 people in 13 mountaineous

regions in Nepal where the iodine content in the water was low and

found a close relationship between fluoride intake and the incidence

of goiter

Zhao et al (1998) does an extensive study on mice receiving several

fluoride-iodine combinations in addition to basal diet. He finds that

iodine and fluorine do have mutually interacting effects on both

goiter and fluorosis in the experimental mice.

Jooste et al (1999) show that goiter occurrence in two iodine-

sufficient areas in Africa seem to be once again due to high fluoride

water levels.

[Guest guest]

FYI: We avoid fluoride, mercury (and fluorscent lights) as they are

know coagulation triggers.

> kelp fluoride ( Google Search)

> ======================

> http://home.thezone.net/~ampi/fucus.html

> Iodine 300.00

> Fluoride 44.00