Minerals

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M I N E R A L S ? ?

- Tim O'Shea

 

 

 

 

Minerals is one confusing topic. Inorganic, organic, chelated, elemental,

ionic, colloidal, essential, trace - all these claims! What do we really need?

Credentials in nutrition apparently mean very little when it comes to minerals.

Much of what is written about minerals is speculative, market-oriented, or dead

wrong.

 

 

A net search on minerals is an overwhelming assault on one's patience,

time and credulity. How could all this stuff be right?

 

Minerals come from mines. Except when you're talking about nutrition. Then

they come from food. At least they used to. When we still had some viable

topsoil.

 

Four elements compose 96% of the body's makeup: carbon, hydrogen, oxygen,

and nitrogen. The remaining 4% of the body's composition is mineral. There are

several opinions about how many minerals are essential. The following table

shows the ones that are not in dispute, in the first column. Macro means more

than 100mg per day. Trace usually means we don't know how much we need.

 

 

Essential Minerals

 

 

.....MACROMINERALS........

 

 

Calcium

Chlorine

Sodium

Potassium

Phosphorus

Magnesium

Sulfur

 

........TRACE MINERALS . . . . . . .

Chromium

Tin

Zinc

Vanadium

Copper

Silicon

Manganese

Nickel

Iron

Molybdenum

Fluorine

Iodine

Cobalt

Selenium

 

 

 

- U.S. Dept. of Agriculture

National Research Council

 

 

The controversy primarily involves the second column - trace minerals.

 

Of the 14 trace minerals listed above, three or four may not have

universal agreement as essential, but a majority of creditable sources admit

that most of them are essential. Deficiency amounts have never been determined

for most trace minerals, although several diseases have been linked with

deficiencies of certain ones. Conclusive evidence has not been found regarding

the exact daily intake amounts necessary, since some of the actual requirements

may be too small to measure; hence the name " trace. "

 

After this, the marketplace takes over and science bows out. People are

out there talking about glacial milk, 88-mineral toddies, minerals from ancient

lakes, longevity of 150 years, calcium from pasteurized milk, " normal " doses of

lead, eye of newt, etc., making unproven claims about this or that combination,

trumpeting anecdotal cures for everything from cancer to hangnails. The purpose

of this chapter will be to try to sift through the debris and leave behind only

the fundamental information which can be verified.

 

In the past few years, even mainstream medicine is beginning to

acknowledge the incontrovertible importance of mineral supplementation. In an

article appearing in JAMA, the top American medical journal, 24 Dec 1996, a

controlled study of selenium use for cancer patients was written up. Selenium as

you remember, effects powerful antioxidant activity, neutralizing free radicals,

which are rampant in the presence of cancer. In this study, 1312 subjects were

divided into groups. Some were given selenium; others the placebo.

 

Soon it was noticed that there was a decrease of 63% with prostate cancer,

and 46% with lung cancer in the selenium group. The results were so blatant that

the designers actually terminated the study early so that everyone could begin

to benefit from selenium. This is just one example of the research that is

currently being done on mineral supplementation. The problem is, if the results

of studies economically threaten a current drug protocol, like chemotherapy, it

is unlikely that an inexpensive natural supplement like selenium would be

promoted by oncologists as a replacement any time soon.

 

There are six nutrient groups:

 

 

- Water

- Vitamins

- Minerals

- Fats

- Protein

- Carbohydrate

 

 

All groups are necessary for complete body function.

 

 

The necessity for minerals is a recent historical discovery, only about

150 years old. In the 1850s, Pasteur's contemporary, Claude Bernard, learned

about iron. Copper came about 10 years later, and zinc about the turn of the

century. With the discovery of Vitamin A in 1912, minerals were downplayed for

about 50 years in favor of vitamin research. By 1950, after about 14 vitamins

had been discovered, attention returned once more to minerals when it was shown

that they were necessary co-factors in order for vitamins to operate. Minerals

are catalysts for most biological reactions. Soon the individual functions of

minerals in the body were demonstrated:

 

 

Ø Structural: bones, teeth, ligaments

Ø Solutes and electrolytes in the blood

Ø Enzyme actions

Ø Energy production from food breakdown

Ø Nerve transmission

Ø Muscle action

 

 

 

The following is a table of minerals linked with the specific functions

most commonly agreed upon today:

 

 

Calcium

 

Muscle contraction

Bone building

 

Sodium

 

Cell life

Waste removal

 

 

Potassium

 

Nerve transmission

Cell life

Normal blood pressure

Muscle contraction

 

 

Phosphorus

 

Bone formation

Cell energy

 

 

Magnesium

 

Muscle contraction

Nerve transmission

Calcium metabolism

Enzyme cofactor

 

Chlorine

 

Digestion

Normal blood pressure

 

Sulfur

 

Protein synthesis

Collagen cross-linking, bone and ligament structure

 

Copper

 

Immune system

Artery strength

Forms hemoglobin from iron

 

 

Chromium

 

Insulin action

Immune function

 

Iron

 

Blood formation

Immune function

 

 

Selenium

 

Immune stimulant

Fight free radicals

Activates Vit E

 

 

Nickel

 

Immune regulation

Brain development

DNA synthesis

 

 

Iodine

 

Thyroid function

 

 

Vanadium

 

Circulation

Sugar metabolism

 

Molybdenum

 

Enzyme action

 

 

Silicon

 

Enzyme action

Connective tissue

 

Tin

 

Enzyme action

 

Manganese

 

Enzyme action

 

 

Fluorine

 

Teeth enamel

 

 

- Larry Berger, PhD and Parris Kidd, PhD

 

 

Zinc is necessary for antioxidant production, which prevents aging and

cancer. It is also a cofactor for some 80 metabolic enzymes. (Erasmus, p 172)

Zinc is necessary for wound healing, fat metabolism, insulin function, semen

production, tissue repair, especially skin, and HCl production. (Erasmus)

 

Mineral deficiency means that some of these jobs will not get done. The

body is capable of prodigious amounts of adapting, and can operate for long

periods of time with deficiencies of many of the above. But someday those checks

will have to be cashed. The result: premature aging. Cell breakdown. Without

minerals, vitamins may have little or no effect. Minerals are catalysts –

triggers for thousands of essential enzyme reactions in the body. No trigger –

no reaction. Without enzyme reactions, caloric intake is meaningless, and the

same for protein, fat, and carbohydrate intake. Minerals trigger the vitamins

and enzymes to act; that means digestion.

 

DEFICIENCY

 

With the exception of those egregiously uninformed doctors who quack " you

should be able to get all the nutrition you need from your food, " a virtually

undisputed fact is deficiency. Mineral deficiency is the reason for the titanic

output of websites, articles, and supplements visible today. The majority of

mineral websites quote a 1936 source - Senate Document #264, as scientific proof

that dietary minerals were generally inadequate for optimum health.

 

" ...most of us are suffering from certain diet deficiencies which cannot

be remedied until deplete soils from which our food comes are brought into

proper mineral balance. "

 

" The alarming fact is that food...now being raised on millions of acres of

land that no longer contain enough...minerals are starving us, no matter how

much of them we eat. "

 

" Lacking vitamins, the system can make use of minerals, but lacking

minerals, vitamins are useless. "

 

Senate Document 264

74th Congress, 1936

 

 

The same document went on to quantify the extent of mineral deficiency:

 

 

" 99% of the American people are deficient in minerals, and a marked

deficiency in any one of the more important minerals actually results in

disease. "

 

 

Congressional documents are not generally highly regarded as scientific

sources, and other reference texts cite other percentages. The figures quoted by

Albion Laboratories, the world leader in patents on supplemental minerals, are

somewhat lower, but the idea begins to come across:

 

 

DEFICIENCIES - % of U.S. Population

 

 

 

Magnesium - 75%

Iron - 58%

Copper - 81%

Manganese - 50%

Chromium - 90%

Zinc - 67%

Selenium - 60%

 

 

sources: Albion Labs, Fats That Heal

 

 

FIVE REASONS FOR MINERAL DEFICIENCY:

 

1. SOIL DEPLETION

 

Different studies will show different figures, of course, but there is

certainly no lack of explanation for mass deficiencies of mineral intake. The

most obvious of these is soil depletion and demineralization. In 1900, forests

covered 40% of the earth. Today, the figure is about 27%. (Relating Land Use and

Global Land Cover, Turner, 1992). Aside from hacking down rainforests in order

to raise beef cattle or to build condos, one of the main reasons for the dying

forests is mineral depletion. According to a paper read at the 1994 meeting of

the International Society for Systems Sciences, this century is the first time

ever that " mineral content available to forest and agricultural root systems is

down 25%-40%. " Less forests means less topsoil. In the past 200 years, the U.S.

has lost as much as 75% of its topsoil, according to John Robbins in his

Pulitzer-nominated work Diet for a New America. To replace one inch of topsoil

may take anywhere from 200-1000 years, depending on climate. (Utah Teachers

Resource Books)

 

Demineralization of topsoil translates to loss of productive capacity.

Contributing further to this trend is the growing of produce that is harvested

and shipped far away.

 

The standard NPK (nitrogen-phosphorus-potassium) fertilizer farmers

commonly use is able to restore the soil enough to grow fruits and vegetables

which are healthy looking, but may be entirely lacking in trace minerals. The

inventor of the entire NPK philosophy, Baron von Leibig, recanted his theories

before he died when he saw the deficiencies his methods were fostering as they

became the agricultural standard in both Europe and America.

 

Mineral depletion in topsoil is hardly a controversial issue. The question

is not if, but how much. Plants are the primary agents of mineral incorporation

into the biosphere. The implication for our position on the food chain is

simply: lowered mineral content in produce grown in U.S. topsoil. Not much

argument here.

 

I have not found any source that insists that the mineral content of

American topsoil is as good today as it was 50 years ago. Generally, studies

talk in terms of how much, if any, minerals are still present.

 

2. DIET

 

The second contributor to mineral deficiency within the population is

obviously, diet. Even if our produce did contain abundant minerals, less than 4%

of the population eats sufficient fruits and vegetables to account for minimal

RDAs. To compound matters further, mass amounts of processed food, excess

protein, and refined sugars require most of our mineral stores in order to

digest it and remove it. The removal process involves enzymes, which break

things down. Enzyme activity, remember, is completely dependent on minerals like

zinc and copper and chromium. No minerals – no enzyme action.

 

In addition, milk and dairy products, alcohol, and drugs inhibit the

absorption of these minerals, further depleting reserves. So it is cyclical:

refined foods inhibit mineral absorption, which then are not themselves

efficiently digested because of diminished enzyme activity. And then we go

looking for bugs as the cause of disease?

 

3. MUCOID PLAQUE

 

In the chapter on the COLON we saw how the standard indigestible American

diet packs layer upon layer of plaque onto the inner lining of the colon. One of

the prime functions of the colon is to reabsorb water, in order to prevent

dehydration. Plaque prevents such a reclamation, and the result is that we lose

both water and minerals that normally should be reabsorbed.

 

4. COMPETITION

 

The fourth reason for inadequate minerals in the body is a phenomenon

known as secondary deficiency. It has been proven that an excess of one mineral

may directly cause a deficiency of another, because minerals compete for

absorption, compete for the same binding sites, like a molecular Musical Chairs.

Secondary deficiency means that an excess of one mineral causes a deficiency of

another. (Kidd)

 

For example, iron, copper, and zinc are competitive in this way. Copper is

necessary for the conversion of iron to hemoglobin, but if there is excess zinc,

less iron will be available for conversion. This may cause a secondary

deficiency of iron, which can manifest itself as iron deficiency anemia. All due

simply to excess zinc. Researchers have found that these secondary deficiencies

caused by excess of one mineral are almost always due to mineral supplements,

since the quantities contained in food are so small.

 

5. DRUGS

 

A fourth reason for mineral deficiency in humans is overuse of

prescription drugs. It has been known since the 1950s that antibiotics interfere

with uptake of minerals, specifically zinc, chromium, and calcium. (The Plague

Makers) Tylenol, Advil, Motrin, and aspirin have the same inhibitive effect on

mineral absorption. Moreover, when the body has to try and metabolize these

drugs to clear the system, its own mineral stores are heavily drawn upon. Such a

waste of energy is used to metabolize laxatives, diuretics, chemotherapy drugs,

and NSAIDs, such as Tylenol, Advil, and aspirin out of the body. This is one of

the most basic mechanisms in drug-induced immunosuppression: minerals are

essential for normal immune function.

 

Ultimately, the only issue that really counts with minerals is

bioavailability. Really doesn't matter what we eat; it only matters what makes

it to the body's cells. Let's say someone is iron deficient, for example. Can't

he just take a bar of iron and file off some iron filings into a teaspoon, and

swallow them? Just took in more iron, didn't he? Will this remedy the iron

deficiency? Of course not. Here is a major distinction: the difference between

elemental minerals and nutrient minerals. Iron filings are in the elemental

form; absorption will be 8% or less.

 

Same with most iron pills and most calcium supplements. Food-bound iron,

on the other hand, like that contained in raisins or molasses, will have a much

higher rate of absorption, since it is complexed with other living, organic

forms, and as such is classed as a nutrient mineral. Minerals are not living,

though they are necessary for life. Minerals are necessary for cell life and

enzyme reactions and hundreds of other reasons. But they must be in a form that

can make it as far as the cells. What is not bioavailable passes right through

the body, a waste of time and sometimes money.

 

Bioavailability has a precursor, an opening act. It is called absorption.

Take a mineral supplement pill. Put it in a glass of water and wait half an

hour. If it is unchanged, chances are that the tablet itself would never even

dissolve in the stomach or intestine, but pass right out of the body. You would

be astounded how many mineral supplements there are in this category.

 

OK, let's say the tablet or capsule actually does dissolve in the

digestive tract. Then what? In order to do us any good, the mineral must be

absorbed into the bloodstream, through the intestinal walls. Elemental minerals

are absorbed about 1-8% in this manner. The rest is excreted. Elemental minerals

are those found in the majority of supplements, because they're very cheap to

produce. For the small percentage that actually makes it to the bloodstream, the

mineral is available for use by the cells, or as catalysts in thousands of

essential enzyme reactions that keep every cell alive every second. Use at the

cellular level is what bioavailability is all about.

 

With this background in mind we can begin to understand that varying

amounts of the seven macrominerals and approximately 14 trace minerals, in a

bioavailable form are necessary for optimum cell activity, optimum health and

would seem to contribute to long lifespan. So besides epidemic mineral

deficiency, what's the problem?

 

In a word, supplementation. Mineral deficiency has become such an obvious

health concern, causing specific diseases because of a lack of a single mineral,

and general immune suppression with a lack of several, that the obvious need for

supplementation has spawned an entire industry to the rescue. But in any

market-driven industry involving pills, again we find that often the cures are

worse than the original problems. Why?

 

First off, toxicity. Remember, even macrominerals are only necessary in

tiny amounts. Most trace minerals are necessary in amounts too small to be

measured, and can only be estimated. Toxicity is a word that simply means extra

stuff. When extra stuff gets put into the body, it's a big deal. All forces are

mobilized for removal of the extra stuff, which are called antigens, toxins,

poisons, reactants, etc, but you get the idea – it doesn't belong there.

Toxicity means taking a nonessential non-nutrient mineral into the body.

 

Take lead poisoning, for example. If lead gets into the blood, the body

will try to remove it. Since the metal atoms are so heavy compared with the

body's immune forces, removal may be impossible. Lead can initiate a chronic

inflammatory response and can remain in the body permanently, which is why we

don't have lead in paint or gasoline any more.

 

Most minerals can be toxic if taken to excess. And this excess would not

happen from food; only from supplements.

 

 

SO, WHAT SUPPLEMENTS WOULD BE BAD?

 

Well, for starters, any supplement containing more than about 21 minerals,

because that's all that have been proven to be necessary for humans. New

toxicities are always being discovered. Aluminum linked to Alzheimer's is a

recent discovery. Beyond these 21 or so it's simply anybody's guess, no matter

what they tell you about the 5 civilizations where people live to be 140 years

old. People who show dramatic improvements from taking these 60 and 80 mineral

drinks generally were so depleted that they rapidly absorbed the essential

minerals in which they were deficient. But the toxicities from the nonessential,

unknown minerals may take a long time to show up. Why take in anything extra?

 

Here's an example of an ingredient list from one of these mega-mineral

drinks. I pulled it off the Net: Calcium, Magnesium, Zinc, Vanadium, Manganese,

Potassium, Selenium, Chromium, Phosphate, Iron, Sulfur, Carbon, Sodium, Barium,

Strontium, Cesium, Thorium, Molybdenum, Nickel, Cerium, Germanium, Copper,

Rubidium, Antimony, Gallium, Neodymium, Lanthanum, Bismuth, Zirconium, Thallium,

Tungsten, Ruthenium, Boron, Iodine, Chloride, Bromine, Titanium, Cobalt,

Dysprosium, Scandium, Samarium, Fluoride, Niobium, Praseodymium, Erbium,

Hafnium, Lithium, Ytterbium, Yttrium, Cadmium, Holmium, Rhenium, Palladium,

Gold, Thulium, Terbium, Iridium, Tantalum, Europium, Lutetium, Rhodium, Tin,

Indium, Silver, Beryllium, Tellurium, and Platinum.

 

Any questions?

 

Amidst all the confusion about minerals, one thing should be made clear:

we only need a little. So the mineral supplements we take should be as

absorbable and as bioavailable as possible – that way we won't have to take

much. Less chance of toxicity.

 

So the question then becomes: which mineral supplements are the most

absorbable and the most usable, and therefore effective in the smallest amounts

possible? Four candidates present themselves, all contending for the title:

 

 

Ø Elemental

Ø Ionic

Ø Colloidal

Ø Chelated

 

 

Unraveling this puzzle is one area where the internet actually impedes

progress. Try it and you'll see why.

 

There's only one answer, but it's buried deep. To find it, we have to

review a little

 

BASIC PLUMBING

 

The digestive tract goes like this: mouth, esophagus, stomach, small

intestine, large intestine, and out. Mineral absorption means transferring the

mineral from the digestive tract through the wall of the intestine, into the

bloodstream. You really have to picture this: the digestive tract is just a long

tube, from one end to the other. As long as food and nutrients are inside this

tube, they are actually considered to be still outside the body, because they

haven't been absorbed into the bloodstream yet. This is an essential concept to

understanding mineral absorption. Minerals can't do any good unless they make it

into the bloodstream. This is exactly why most minerals bought at the grocery

store are almost worthless: they pass right through the body - in one end and

out the other. It's also why many nutritionists' and dieticians' advice is

valueless; they commonly pretend everything that is eaten is absorbed.

 

Two main reasons for lack of absorption:

 

- the pill never dissolved

- the mineral was in its elemental form (non-nutrient, e.g., iron filings)

 

 

Let's say these problems are overcome; neither is true. Or let's say the

mineral is contained within some food, such as iron in molasses, or potassium in

bananas. Food-bound minerals are attached or complexed to organic molecules.

Absorption into the blood is vastly increased, made easy. The mineral is not

just a foreign metal that has been ingested; it is part of food.

 

Fruits and vegetables with high mineral content are the best way to

provide the body with adequate nutrition. Food-bound minerals are the original

mode. As already cited above, however, sufficient mineral content is an

increasingly rare occurrence. Foods simply don't have it. How little, what

portion of normal depends on what studies one finds. Soon the necessity for

supplementation becomes obvious: if the food no longer has it, and we need it,

pass the supplements, please. At that point, the marketplace assaults one's

awareness and we're almost back to the days of the tonics, brews, toddies, and

snake potions of yesteryear.

 

1. ELEMENTAL

 

Let's look at the four types one by one. Least beneficial are the

supplements containing minerals in the elemental form. That means the mineral is

just mentioned on the label. It's not ionized, it's not chelated, it's not

complexed with an oxide or a carbonate or a sulfate, or with a food, and it's

not colloidal. Like under " ingredients " it just says " iron " or " copper, " or

" calcium, " etc.

 

Elemental minerals are obviously the cheapest to make. A liquid would only

have to be poured over some nails to be said to contain iron. Elemental minerals

are the most common in grocery store supplements. They may not be toxic, as long

as only the minerals mentioned on the label are included in the supplement. The

problem is absorption: it's between 1 and 8 percent. The rest passes right

through. Not only a waste of money; also a waste of energy: it has to be

processed out of the body. This can actually use up available mineral stores.

 

2. IONIC

 

Next comes ionic minerals. Usually a step up. Ionic means in the form of

ions. Ions are unstable molecules that want to bind with other molecules. An ion

is an incomplete molecule. There is a definite pathway for the absorption of

ionic minerals through the gut (intestine) into the blood. In fact, any percent

of the elemental minerals that actually got absorbed became ions first, by being

dissolved in stomach acids.

Ionic minerals are not absorbed through the intestine intact.

 

The model for mineral ion absorption through the intestine is as follows.

Ions are absorbed through the gut by a complicated process involving becoming

attached or chelated to some special carrier proteins in the intestinal wall.

Active transport is involved; meaning, energy is required to bring the ionic

mineral from inside the intestine through the lining, to be deposited in the

bloodstream on the other side.

 

Ionic minerals may be a good source of nutrients for the body, depending

upon the type of ions, and on how difficult it is for the ion to get free at the

appropriate moment and location. Minerals require an acidic environment for

absorption. Remember low pH (less than 7) is acidic; high pH (above 7) is

alkaline. As the stomach contents at pH 2 empty into the small intestine, the

first few centimeters of the small intestine is the optimum location for mineral

absorption. The acidic state is necessary for ionization of the dissolved

minerals. If the pH is too alkaline, the ions won't disassociate from whatever

they're complexed with, and will simply pass on through to the colon without

being absorbed.

 

As the mineral ions are presented to the lining of the intestine, if all

conditions are right, and there are not too much of competing minerals present,

the ions will begin to be taken across the intestinal barrier, making their way

into the bloodstream. This is a complicated, multi-step process, beyond the

scope of this chapter. Simply, it involves the attachment of the free mineral

ion to some carrier proteins within the intestinal membrane, which drag the ion

across and free it into the bloodstream. A lot happens during the transfer, and

much energy is required for all the steps. Just the right conditions and timing

are necessary – proper pH, presence of vitamins for some, and the right section

of the small intestine.

 

Iron, manganese, zinc, copper – these ions are bound to the carrier

proteins which are embedded in the intestinal lining. The binding is

accomplished by a sort of chelation process, which simply describes the type of

binding which holds the ion. The carrier protein or ligand hands off the mineral

to another larger carrier protein located deeper within the intestinal wall.

After several other steps, if all conditions are favorable, the ion is finally

deposited on the other side of the intestinal wall: the bloodstream, now usable

by the cells.

 

Ionic mineral supplements do not guarantee absorption by their very

nature, although they are certainly more likely to be absorbed than are minerals

in the raw, elemental state. However, ionic minerals are in the form required

for uptake by the carrier proteins that reside in the intestinal wall.

 

The uncertainties with ionic minerals include how many, how much, and what

else are the unstable ions likely to become bound to before the carrier proteins

pick them up. All ionic supplements are not created equal. Just because it's an

ion doesn't mean a supplemental mineral will be absorbed. Too many minerals in a

supplement will compete for absorption. Too much of one mineral will crowd out

the others. The idea is to offer the body an opportunity for balance; rather

than to overload it with the hope that some will make it through somehow.

Minerals are biologically active in tiny amounts.

 

3. COLLOIDAL

 

Speaking of overloading, the third type of supplemental minerals is the

one we hear the most about: colloidal. What does colloidal really mean?

Colloidal refers to a solution, a dispersion medium in which mineral particles

are so well suspended that they never settle out: you never have to shake the

bottle. The other part of the dictionary definition has to do with diffusion

through a membrane: " will not diffuse easily through vegetable or animal

membrane. " Yet this is supposed to be the whole rationale for taking colloidal

minerals – their absorbability. Colloidal guru Joel Wallach himself continuously

claims that it is precisely the colloidal form of the minerals that allows for

easy diffusion and absorption across the intestinal membrane, because the

particles are so small. Wallach claims 98% absorption, but cites no studies,

experiments, journal articles or research of any kind to back up this figure.

Why not? Because there aren't any. The research on colloidal minerals has never

been done. It's not out there. Senate Document 264 doesn't really cover it.

 

In reality, colloidal minerals are actually larger than ionic minerals, as

discussed by researcher Max Motyka, MS. Because of the molecular size and

suspension in the colloid medium, which Dorland's Medical dictionary describes

as " like glue, " absorption is inhibited, not enhanced. No less an authority than

Dr. Royal Lee the man responsible for pointing out the distinction between whole

food vitamins and synthetic vitamins, stated:

 

<

" A colloidal mineral is one that has been so altered that it will no

longer pass through cell walls or other organic membranes. "

 

 

Does that sound like easy absorption?

 

Stedman's Medical Dictionary talks about colloids " resisting

sedimentation, diffusion, and filtration " Again, resisting diffusion seems to

indicate inhibition of absorption, not increased absorption, wouldn't you think?

 

As Alexander Schauss and Parris Kidd both explain, colloids are

suspensions of minerals in clay and water. Clay often has levels of aluminum as

high as 3000 parts per million, with safety levels set at 10 ppm or lower

(Kidd). Aluminum has been proven to kill nerve cells, which we now see in the

pathophysiology of Alzheimer's.

 

Dr. Schauss characterizes the aluminum content as the big problem with

colloidal minerals. He cites a standard geology reference text - Dana's Manual

of Mineralogy - describing clay as primarily aluminum:

 

 

" Clay minerals are essentially hydrous aluminum silicates. "

- Dana's Manual, p436

 

And another geology text:

 

 

" [clays] are essentially hydrous aluminum silicates and are usually formed

from the

alteration of aluminum silicates. "

 

- Mineral Recognition p 273

 

 

Schauss finds references as high as 4400 PPM of aluminum in colloidal

clay. Schauss states that he has done an exhaustive search for any human studies

using colloidal minerals and after searching 2000 journals, like everyone else,

has come up with zero.

 

For a mineral to be absorbed, it must be either in the ionic state, or

else chelated, as explained above. The percentage of colloidal minerals which

actually does get absorbed has to have been ionized somehow, due to the acidic

conditions in the small intestine. Only then is the mineral capable of being

taken up by the carrier proteins in the intestinal membrane, as mentioned above.

By why create the extra step? Ionic minerals would be superior to colloidal,

because they don't have to be dissociated from a suspension medium, which is by

definition non-diffusable. All this extra work costs the body in energy and

reserves.

 

In an editorial in Am J of Nat Med, Jan 97, Alexander Schauss further

points out the error of Wallach's claims. Wallach states that colloidals are

negatively charged, and this enhances intestinal absorption. The problem is his

science is 180* backward: Wallach claims the charge of the intestinal mucosa is

positive, but all other sources have known for decades that the mucosal charge

is negative. (Guyton, p13) This is why ionic minerals are presented to the

intestinal surface as cations (positively charged ions). Opposites attract, like

repels – remember? Another big minus for colloidals.

 

QUALITY CONTROL

 

Consistency of percentages of each mineral from batch to batch. Very

simply, there isn't any with the mega mineral supplements, as the manufacturers

will themselves admit. The ancient lakes and glaciers apparently have not been

very accommodating when it comes to percent composition. Such a range of

variation might be acceptable in, say, grenade tossing or blood dilution in

seawater necessary to attract a shark, or IQ threshold of terrorists, or other

areas where high standards of precision are not crucial. But a nutritional

supplement that is supposed to enhance health by drinking it – this is an area

in which the details of composition should be fairly visible, verifiable, the

same every time. In these 80-trace-mineral toddies, there is no way of testing

the presence or absence of many of the individual minerals. Many established

essential trace minerals do not even have an agreed-upon recommended daily

allowance, for two reasons:

 

 

- the research has never been done

 

- the amounts are too small to be measured.

 

 

How much less is known about the amounts and toxicities of those unknown

minerals which have never been studied, but are claimed to be present in these

" miraculous " toddies?

 

TOXICITY AND COMPETITION

 

Some essential minerals are toxic in excess, but essential in small

amounts. Iron, chlorine, sodium, zinc, and copper are in this category. Toxic

levels have been established, and resulting pathologies have been identified: we

know what diseases are caused by their excesses. How risky is it to take in 40

or 50 minerals for which no toxicity levels have ever been set?

 

The problem is selective utilization, as explained by Dr. Parris Kidd.

toxic trace minerals may closely resemble the essential minerals in atomic

configuration. The result is competition for enzyme sites by two similar

minerals only one of which is beneficial:

 

" aluminum competes with silicon

cadmium competes with zinc

tellurium competes with selenium

lanthanum competes with calcium "

 

- Kidd, p42

 

We also know that zinc competes with iron. (Erasmus)

 

 

A separate hoax is being played out with

 

 

COLLOIDAL SILVER,

 

 

used by many as a " natural antibiotic. " Extremely uninformed physicians

recommend daily doses of colloidal silver, in order to " prevent " colds, in the

absence of any studies or trials whatsoever. As Dr. Kidd points out:

 

 

" the body is not well-equipped to handle silver. This element can poison

the kidneys, become deposited in the brain, and even give to the skin a gunmetal

type of gloss. "

 

 

Doug Grant, a nutritionist, cites several minerals which frequently appear

on the ingredient labels of certain mega-mineral products – they actually admit

their supplements contain or " may contain " some of the following: (the phrase

" may contain " has always been scary for me. If they're not sure, then what else

is there that this product " may contain " that they don't know about?)

 

 

Aluminum: Documented since the article in Lancet 14 Jan 1989 to be

associated with Alzheimer's Disease, as well as blocking absorption of essential

minerals like calcium, iron, and fluoride.

 

Silver: questionable as a single-dose antibiotic, consistent intake of

silver accumulates in the blood-forming organs – spleen, liver, and bone

marrow-, as well as the skin, lungs, and muscles. Serious pathologies have

resulted: blood disorders, cirrhosis, pulmonary edema, chronic bronchitis, and a

permanent skin condition known as argyria, to name just a few. Silver is better

left in the ancient lakes, and in tableware.

 

Gold: Manufacturers of mega-minerals hawk that " there's more gold in a ton

of seawater than there is in a ton of ore. " So what? Our blood is not seawater;

it evolved from seawater. Gold used to be used to treat rheumatoid arthritis,

but has largely been abandoned when they proved that it caused kidney cell

destruction, bone marrow suppression, and immune abnormalities.

 

Lithium Rarely used as an antipsychotic medication, lithium definitely can

cause blackouts, coma, psychosis, kidney damage, and seizures. Outside of that,

it should be fine.

 

The list goes on and on. These are just a few examples of mineral

toxicities about which we have some idea. But for at least half the minerals in

the mega toddies, we know nothing at all.

 

4. CHELATED

 

The fourth form of supplemental minerals is the chelated variety. Some

clarification of this term is immediately necessary. Chelated is a general term

that describes a certain chemical configuration, or shape of a compound in which

some molecule gets hooked up with some other chemical structures. When a mineral

is bound or stuck to certain carrier molecules, which are known as chelating

agents, or ligands, and a ring-like molecule is the result, we say that a

chelate is formed. Chelate is from the Greek word for claw, suggested by the

open v-shape of the two ligands on each side, with the mineral ion in the

center.

 

Chelation occurs in many situations. Many things can be chelated,

including minerals, vitamins, and enzymes. Minerals in food may be bound with

organic molecules in a chelated state. Many molecules in the body are chelated

in normal metabolic processes. The carrier proteins in the intestinal wall

discussed above, whose job it is to transport ionic minerals – these chelate the

ions. Another sense of the word chelation as exemplified in a mainstream therapy

for removing heavy metals from the blood is called chelation therapy. The toxic

metals are bound to a therapeutic amino acid ligand called EDTA. With a Pac-Man

action, the metals are thus removed from the blood.

 

Molecular weight is measured in units called daltons. The ligands or

binding agents may very small (800 daltons) or very large (500,000 daltons)

resulting in a many sizes of chelates. Mineral + ligand = chelate. Generally the

largest chelates are the most stable, and also the most difficult to absorb.

Ionic minerals absorbed through the intestine are chelated to the carrier

proteins, at least two separate times.

 

Using the word chelated with respect to mineral supplements refers a very

specific type of chelation. The idea is to bind the mineral ion to ligands that

will facilitate absorption of the mineral through the intestine into the

bloodstream, bypassing the pathway used for ionic mineral absorption. Sometimes

minerals prepared in this way are described as " pre-chelated " since any ionic

mineral will be chelated anyway once it is taken up by the intestinal membrane.

 

After decades of research at Albion Laboratories in Utah, it was learned

that small amino acids, especially glycine, are the best ligands for chelating

minerals, for three reasons:

 

 

- bypasses the entire process of chelation by the intestine's own

carrier proteins

 

- facilitates absorption by an entirely different pathway of intestinal

absorption, skipping the intermediate steps which ionic minerals go through

 

- the chelate will be the at the most absorbable molecular weight for

intestinal transfer: less than 1500 daltons

 

 

It has also been established beyond controversy that certain pairs of

amino acids (dipeptides) are the easiest of all chelates to be absorbed, often

easier than individual amino acids. Proteins are made of amino acids. Normal

digestion presumably breaks down the proteins to its amino acid building blocks

so they can be absorbed. But total breakdown is not always necessary. It has

long been known that many nutrient chains of two or three or even more amino

acids may be absorbed just as easily as single amino acids. Food-bound copper,

vitamin C with hemoglobin molecule, animal protein zinc, are some examples of

amino acids chelates that are easily absorbed intact. (Intestinal Absorption of

Metal Ions, Chapter 7).

 

To take another example, in abnormal digestion it is well known that

chains of amino acids - dipeptides, tripeptides, even polypeptide proteins -

sometimes become absorbed intact in a pathology known to gastroenterologists as

Leaky Gut Syndrome. Obviously it is not healthy and has many adverse

consequences, but the point is that amino acids chains are frequently absorbed,

for many different reasons. It's not always like it says in the boldface section

headings in Guyton's Physiology.

 

The reason these dipeptide chelates are absorbed faster than ionic

minerals is that the chelated mineral was bonded tightly enough so that it did

not dissociate in the acidic small intestine and offer itself for capture by the

intestinal membrane's carrier proteins. That whole process was thus avoided. The

chelate is absorbed intact. An easier form. This is a vast oversimplification,

and the most concise summary, of why chelated minerals may be superior to ionic,

provided it's the right chelate. Only a specific chelate can resist digestion

and maintain its integrity as it is absorbed through the gut. Again, all

chelates are not created equal. Inferior chelates, used because they are cheaper

to produce, include the following:

 

- carbonates

- citrates

- oxides

- sulfates

- chlorides

- phosphates

 

If the label gives one of these chelates, it means the mineral is bound

either too strongly or not tightly enough, and will be released at the wrong

time and the wrong place. Chelation of minerals in nutrient supplements is a

very precise science, yielding chelates superior to those occurring naturally in

foods.

 

Intact absorption is faster, easier, and requires less metabolic energy,

provided the chelate is about 1500 daltons.

 

To compare chelated and ionic minerals, once the research is presented,

there is really not much of a dispute about which is absorbed faster, ionic

minerals or dipeptide-like amino acid chelates. Meticulous isotope testing has

shown the following increases in percent absorption of chelates, as compared

with ionic:

 

Iron 490% greater

Copper 580% greater

Magnesium 410% greater

Calcium 421% greater

Manganese 340% greater

 

- Source: Journal of Applied Nutrition 22:42 1970

 

 

Again, this is just the briefest glance at the prodigious amount of

research comparing ionic with chelated minerals, but the results are uniform.

The winner of the bioavailability contest is: chelated minerals, provided the

chelate was maintained as small as possible, generally using glycine as the

amino acid ligands, at a total weight of about 1500 daltons.

 

FOOD-BOUND CHELATED MINERALS

 

Often you will hear this or that company claiming that " organic " minerals

contained in food are the best, cannot be improved upon, and are superior to all

possible types of mineral supplements. This is almost true. The only exception

is glycine-chelated minerals, for two reasons:

 

- the exact amount of minerals in any food is extremely variable and

difficult to measure, even if there is high mineral content of the soil.

Pesticides destroy root organisms in the soil. These bugs play a major role in

selective mineral absorption.

 

(Jensen p 55)

 

 

- the ligands that bind the mineral in the food chelate may be too strong

or too weak to dissociate

at exactly the right time for maximum absorption in the human digestive

tract. Glycine chelates are uniform and easily measurable. No question about

dosage.

 

Marketing is a wonderful thing – two different companies are now

attributing the longevity of the Hunza tribe in Pakistan to two entirely

different properties of their water: one, the minerals; the other, molecular

configuration. A classic error in logic is described as " post hoc, ergo propter

hoc " - after this, therefore because of this. Maybe it was the weather that made

the Hunzas live longer, or their grains, or the absence of toothpaste or

webservers or Marketing is the art of persuasion by suspending logic.

 

The average lifespan of an American is about 75 years. No one has ever

proven that taking mineral supplements will extend life. Many old people never

took a mineral or a vitamin in their life. It really comes down to quality of

life. Incidence of disease during the lifespan. For how many days or months of

the total lifespan was the person ill? We are the walking petri dishes of Alexis

Carrel – remember? Carrel was the French biochemist, a Nobel prize winner, who

did the famous experiment in which he kept chicken heart cells alive in a petri

dish for 28 years just by changing the solutes every day. Could've gone longer,

but figured he'd proven his point. Mineral content factors largely in the

quality of our solutes: the blood - the milieu interior, the biological terrain.

 

The U.S. has the highest incidence of degenerative diseases of any

developed country on earth. In addition, the infectious diseases are coming

back; antibiotics are getting less effective every year. Americans' confidence

in prescription drugs is weakening. Allow me to disabuse you of unfounded hopes:

cancer and AIDS will never be cured by the discovery of some new drug. It's not

going to happen. There probably will never be another Alexander Fleming – turns

out penicillin was just a brief detour anyway. Bacteria have had 50 billion

years to figure out ways to adapt. The only way that anyone recovers from any

illness is when the immune system overcomes the problem. Allergy shots never

cured an allergy – people who take allergy shots always have allergies.

 

Our only hope of better health is to do everything possible to build up

our natural immune system. One of these preventative measures is nutritional

supplementation. It may not be dramatic, but daily deposits to the immune system

bank account will pay off down the road. Healthy people don't get sick.

 

With respect to minerals, then, what are our goals? My opinion is that

having once realized the necessity for mineral supplementation, our objectives

should be simple:

 

- Take only the minerals we absolutely need

- Take the smallest amounts possible

- Nothing left over ( no metabolic residue)

 

Some of the above ideas may seem strange and difficult to understand, on

first reading. But it is truly a very simplified version of what actually takes

place. Most of the technical details were omitted for the sake of clarity and

brevity. However, the correctness of the above basic framework is verifiable.

The reader is encouraged to flesh things out a little by consulting the attached

reference list.

 

We are living in the age of the Junk Science Hustle. Everybody's an

expert, often quoting shaky sources, shaky facts, and shaky claims which may

have no foundation in physical reality. Seems there's a formula:

 

 

 

 

 

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*§ - PULSE ON WORLD HEALTH CONSPIRACIES! §*

 

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