Info Iron &Maganese

[Guest guest]

| Acu-Cell Analysis | Acu-Cell Nutrition | Disorders | Diets & MLM |

Mineral Ratios | Tin & Health | Spiritual Health |

| Links & Downloads | HOME PAGE

|

Iron

Manganese

When assessing Cellular Nutrition with Acu-Cell Analysis, only

essential, biological elements that have

their own cell receptors are measured. They are neurologically

arranged into left-sided and right-sided

groups and are discussed in associated pairs, as they function as an

inseparable, interdependent unit:

_____________________________________________________

CalciumMagnesiumPhosphorusSodium

IronManganeseZincPotassium

SeleniumSulfurTinIodine

GermaniumSiliconBismuthLithium

NickelCobaltChromiumCopper

FluorideChlorideVanadiumMolybdenum

_____________________________________________________

Boron Bromine Strontium B-Complex Bioflavonoids Vit

C, E, B12, B15

Trace mineral symptoms of excess or deficiency are generally one-

sided, depending on their ratios to

other chemical members, and depending which group they are

neurologically assigned to. In the event

of calcification, it is not a high calcium level that results in the

formation of a stone or spur, but calcium

being high in ratio to associated or interactive elements.

For instance, phosphorus and zinc have both left-sided cell

receptors, so if either level is low in ratio to

calcium, calcification would only take place on the left side of the

body, whereas the cell receptors of

manganese or magnesium are right-sided, as a result, any

calcification would develop on the right side

of the body only.

The same rules apply to most nutrition-related inflammatory or

degenerative conditions, so successful,

non-symptomatic treatments require the application of those same

principles. Since intracellular and

serum levels of nutrients represent different physiological and

pathological processes, abnormal levels

seen in one medium are not necessarily reflected in the other, so

they need to be interpreted differently.

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

========

Iron & Manganese: Both elements share left-right-sided cell

receptors and are considered essential

to human health. As is the case with all other associated mineral

pairs, the absorption of iron (Fe) is

dependent on manganese (Mn), however with manganese being frequently

lower than iron, and since

iron can provoke a number of problems when supplemented

(constipation, gastric upset), the addition

of manganese, when low also, is vitally important. This not only

prevents further ratio conflicts between

the two, but also substantially reduces the amount of iron needed

when manganese is supplemented

at the same time.

While some sources claim that manganese lowers iron levels, this is

mostly a theoretical consideration

that would only happen under unusual circumstances. In actual

clinical settings, I have not seen a single

incidence of a patient's iron (ferritin) levels decline as a result

of taking manganese, even when doses

as high as 150mg per day were supplemented on an ongoing basis. In

fact, most minor iron-deficiency

situations can be dealt with by using manganese alone - without any

iron - which reduces any possible

adverse effects that can be part of routine iron supplementation.

In contrast to Acu-Cell Analysis, routine blood tests do not include

manganese measurements, but use

a number of iron determinations alone, none of which are very

reliable to assess true iron requirements

in a patient, with only ferritin levels being more accurate and being

closest to actual intracellular values.

Consequently, patients are given far too many false positive and

false negative recommendations

to supplement iron, to the detriment of the patient. Pregnant women

are a most vulnerable target for

either insufficient, or excessive iron supplementation, with the

latter being able to trigger 'toxemia of

pregnancy' (high iron causes excessive sodium retention), and in

which case higher amounts of folic

acid should have been given instead.

Likewise, blood loss, or malabsorption are considered to be the main

causes for low iron after ruling

out any of a number of blood disorders, however low iron can very

easily result from manganese levels

having been low for a long period of time, or from other elements

such as calcium, zinc, or magnesium

reducing normal iron values. Cellular levels of iron best correspond

to actual symptoms of excess or

deficiency, in contrast to blood levels, which unfortunately

fluctuate considerably under various medical

conditions, particularly with infections. Following are some iron

and manganese interactions with other

trace minerals:

There is a synergism between Cobalt + Vit B12 + Manganese, and

between Nickel + Vit C + iron, and

there are some other minor interactions between iron + manganese, and

for instance copper, iodine,

chromium, and others, but they are less specific since they depend on

the total chemical profile, or they

can go either way, which in the case of copper can either help, or

inhibit iron or manganese absorption.

There is also a synergistic and antagonistic interaction between iron

+ manganese and a number of

other nutrients, particularly B-vitamins, however these interactions

will change under various medical

situations. For instances, with kidney disease, a fine balance needs

to be maintained between folate

and iron levels since one will otherwise inhibit the other; the same

applies with adrenal disturbances,

except they will affect the balance between iron and Vitamin B1

(thiamine).

Stomach acid levels heavily interact synergistically with iron and

manganese, whereby the absorption

of both minerals is enhanced by higher HCl acid levels, and likewise,

an increase in iron or manganese

will generally - but not always - result in raised stomach acid

levels. Since calcium and magnesium

have the exact opposite effect on stomach acid levels, their

interaction with iron and manganese have

a major impact on medical conditions that are associated with raised

or lowered stomach acid levels

(see also Acu-Cell " Calcium & Magnesium " ).

Many left-sided cancers develop in the presence of upper stomach acid

levels being low, next to low

iron and/or high calcium, - while many right-sided cancers develop in

the presence of lower stomach

acid levels being low, next to low manganese and/or high magnesium.

Initially though, excessive iron and/or manganese levels may have set

the stage for cancer - perhaps

as much as 10 or 20 years earlier - subsequent to a number of factors

that may have influenced liver

chemistry such as excessive intake of Tylenol, alcohol, estrogen

therapy, antifungal drugs, conditions

such as hepatitis, or inherited liver disease. All these can result

in higher manganese and/or iron liver

storage, regardless of actual manganese or iron consumption.

By the time cancer develops however, most patients don't exhibit

excessive liver storage of iron and/or

manganese any longer. In fact, along with lowered stomach acid

levels, manganese or iron levels have

usually dropped to well below normal, which sometimes coincides with

a decline in perimenopausal or

postmenopausal estrogen levels in females. After following patients

with a similar history over more

than two decades, it appears that if liver functions are normalized

in time (as part of normalizing or

raising stomach acid levels), on average, no cancers develop. (see

also Acu-Cell Disorders " Cancer " ).

The primary function of iron in the body is the formation of

hemoglobin, the essential oxygen-carrying

component of the red blood cell (RBC). In combination with protein,

iron is carried in the blood to the

bone marrow, where with the help of copper, it forms hemoglobin. Red

blood cells pick up oxygen from

the lungs and distribute it to the rest of the tissues, all of which

need oxygen to survive. Iron absorbed

into the blood is usually bound to the protein transferrin and goes

mainly to the bone marrow, where it

can be used to make red blood cells.

Myoglobin is a red, iron-containing protein, which stores oxygen for

muscle contraction. There is about

3 to 5 gm of iron in the body, of which hemoglobin represents 65%,

while about 30% occurs as ferritin,

which is the iron storage complex found in the liver, spleen and bone

marrow. Neutrophils (white blood

cells) depend on iron to help generate superoxide to function as a

bacteria-destroying agent, whereby

inadequate iron levels reduces the effectiveness of the immune

system. With severe iron deficiency,

hemoglobin levels decline and the packed volume of red blood cells,

the hematocrit, declines.

Heme Iron from meat is about 10 times more absorbable than iron from

all plant / vegetable sources.

Many vegans have trouble obtaining sufficient iron from the diet

alone since phytates present in whole

grains and oxalates found in certain vegetables may bind to some of

the iron and reduce absorption.

Iron deficiency is more common during infancy, childhood,

adolescence, pregnancy, menstruation,

chronic infections, low stomach acid (sometimes from low salt

intake), chronic diarrhea, bleeding, or

impaired absorption (celiac disease). The elderly may become iron

deficient due to poorer absorption

and inadequate dietary intake of iron. Vitamin C also helps iron

absorption.

Iron Toxicity (excessive organ storage of iron) and/or high blood

levels of iron are associated with

increased risk of free radical damage and cancer. Ferritin levels

are a good indication of iron storage

levels. While a normal value is 15-200mcg, levels below 15mcg

suggests very depleted iron reserves,

and high ferritin (over 200mcg) can be a risk factor for

cardiovascular disease. Free radicals formed

as a result of high iron can attack low-density lipoproteins (LDL)

and subsequently lead to fatty plaque

buildup, damage to the walls of arteries, as well as heart muscle

tissue.

Iron supplements frequently cause constipation or stomach complaints,

which may result from the use

of ferrous sulfate, or similar hard-to-digest forms of iron. Other

types of iron such as ferrous gluconate,

ferrous fumarate, or ideally chelated iron supplements are generally

better tolerated, and there are also

water-soluble iron products that are probably the easiest on the

system and cause less of these effects.

Manganese is a much neglected, but extremely important mineral when

trying to stabilize blood sugar,

particularly with hypoglycemic individuals, and for lowering total

cholesterol (cholesterol-lowering drugs

actually raise manganese). It has strong estrogenic properties, and

as a result is the most important

element when nutritionally treating menopausal symptoms,

osteoporosis, and postpartum depression,

for which manganese, along with Vitamin B1, is most effective.

Just like iron, manganese can be helpful with some types of asthma,

where lung capacity measurably

increases proportional to manganese intake. Extra supplementation of

manganese may be helpful in

some cases of carpal tunnel syndrome, deafness, epilepsy,

infertility, and lack of libido in both sexes.

In addition, individuals who regularly dislocate joints (particularly

knee joints), frequently present with

insufficient cellular manganese levels, so normalizing manganese in

those cases will permanently

resolve that problem.

Manganese is important to many enzyme systems such as protein

metabolism, bone formation, and

the synthesis of L-dopamine and cholesterol, as well as carbohydrate

metabolism, where it is required

for the synthesis of glucose from non-carbohydrate substances

(gluconeogenesis). As a cofactor in

glycolysis, manganese aids glucose metabolism.

It is also needed for normal brain and muscle function, blood

clotting, and DNA and RNA synthesis,

and it activates the enzyme responsible for the formation of urea.

Manganese may help with some

symptoms of Parkinson's disease such as muscle rigidity and

twitching, although an excessive level

of manganese can in itself produce Parkinsonian syndrome from a loss

of dopamine in the brain cells.

L-dopa, which converts to dopamine in the brain, is used in the

treatment of manganese toxicity to

reduce the symptoms. High levels of manganese can produce violence

and other mental changes,

including a psychiatric disorder resembling schizophrenia.

When people supplement certain herbs to " cleanse " their liver, they

will always affect manganese and

iron status. For instance, by taking Devil's Claw on an ongoing

basis, they will eventually raise iron and

manganese levels. On the other hand, taking Milk Thistle will in

time decrease iron and manganese

stores, which can be an advantage with hemochromatosis (excess iron

storage disease), where regular

consumption of milk thistle, RNA / DNA, magnesium and Vitamin B2 -

whichever ones are individually

indicated - will keep iron levels closer to normal, and frequently

eliminate the need for phlebotomies.

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

========

Dietary Reference Intake (DRI) is the latest term replacing daily

dietary reference values such as

Adequate Intake (AI), Tolerable Upper Intake Level (UL), Estimated

Average Requirements (EAR),

Nutrient Reference Value (NRV), and Recommended Dietary Allowance /

Intake (RDA / RDI).

Iron:Manganese:

DRI (RDA):DRI (RDA):

0-6 months10mg0-6 months0.5-0.7mg

6-12 months15mg6-12 months0.7-1.0mg

1-10 years10-15mg1-10 years1-3mg+

11-18 years10-18mg+11-18 years3-5mg+

18 years +males10mg+18 years +4-10mg+

18 years +females18mg+

50 years +females10mg+

pregnant / lactating+ 30-60mgpregnant / lactating+ 3mg

Therapeutic Range:10mg - 900mg+Therapeutic Range:15mg - 200mg

______________________________________________________________________

________

Cellular / Intracellular Effects and Interactions:

Iron Synergists:Manganese Synergists:

Phosphorus, bismuth, germanium,nickel,Sodium, lithium, silicon /

silica, cobalt,

manganese, Vitamin A, Vitamin B1, Vitamin C,PABA, niacin /

niacinamide, Vitamin E,

folate, niacin, niacinamide, lecithin, protein,biotin, choline,

sugar,* alcohol,*

Iron Antagonists:Manganese Antagonists:

Zinc, calcium, magnesium, tin, cobalt, Vitamin B2,Potassium,

magnesium, calcium, iodine,

Vitamin B5, Vitamin B12, Vitamin E, caffeine,nickel, boron, Vitamin

B1, Vitamin B6,

insoluble fiber, rice (phytates), tea (tannic acid),Vitamin B15,

Vitamin C, [iron],

soy protein, dairy (casein), oxalic acid, [folate],sugar,* alcohol,*

* These can have synergistic or antagonistic action, depending on

hypoglycemic or hyperglycemic

tendencies.

Low Levels / Deficiency - Symptoms and/or Risk Factors:

Iron:Manganese:

Fatigue, anemia, depression, dizziness, asthma,Fatigue, depression,

hypoglycemia / low blood

gastrointestinal disorders, pale skin, miscarriage,sugar, joint

dislocations (particularly knees),

amenorrhea (failure to menstruate), dysmenorrheahigh cholesterol,

asthma, migraine-headaches,

(painful periods), migraine-headaches, Ménière'sosteoporosis,

gastrointestinal disorders, PMS,

disease, learning difficulties, weak immune system,infrequent

menstrual cycles, ovarian cysts,

ovarian cysts,

High levels / Overdose / Toxicity / Negative Side Effects - Symptoms

and/or Risk Factors:

Iron:Manganese:

Hemochromatosis, migraine-headaches, arthritis,Migraine-headaches,

PMS, frequent menstrual

high blood pressure, heart disease, liver disease,cycles, muscle

tremors, dizziness, depression,

dizziness, gastrointestinal disorders, nausea,mental illness, liver

disease, higher risk for

higher risk for several cancers, fibroid tumors,several cancers,

fibroid tumors, endometriosis,

benign prostatic hypertrophy (BPH), edema,insomnia, osteoporosis,

edema, hypothyroid,

constipation (high supplementation), nausea, colitis,

______________________________________________________________________

________

Iron Sources:Manganese Sources:

Meat, fish, shellfish, nuts, seeds, eggs, molasses,Nuts, seeds, whole-

grain products, wheat

wheat germ, whole-grain products, raisins, beans,germ, seaweed,

beans, peas, ginger, coffee. ¤

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

========

General recommendations for nutritional supplementation: To avoid

stomach problems and promote

better tolerance, supplements should always be taken earlier, or in

the middle of a larger meal. When

taken on an empty stomach or after a meal, there is a greater risk of

some tablets causing irritation, or

eventually erosion of the esophageal sphincter, resulting in

Gastroesophageal Reflux Disease (GERD).

It is also advisable not to lie down immediately after taking any

pills.

When taking a very large daily amount of a single nutrient, it is

better to split it up into smaller doses to

not interfere with the absorption of other nutrients in food, or

nutrients supplemented at lower amounts.

______________________________________________________________________

________

Copyright © 2000-2003 Roth

| Vitamin C Supplements | B-Complex Vitamins | Bioflavonoids,

Flavonoids & Polyphenols | Cocoa & Chocolate | Sugar & Glycemic Index

|

| Multi-Level-Marketing / MLM Products | Sterols & Sitosterol | Blood

Type Diet | Vegetarian / Vegetarianism | Hi / Low Carb-Fat-Protein

Diets |

| Acu-Cell Disorders - Conditions & Diseases A - Z | ADD / ADHD &

Behavioral Problems | ALS / Lou Gehrig's Disease | Alzheimer's

Disease |

| Bone Loss / Osteoporosis | Cancer | Helicobacter Pylori & low

Stomach Acid | Hypoglycemia / Low Blood Sugar | Muscle Spasms &

Cramps |

| Migraine Headaches | Prostatitis | Bismuth | Boron | Bromine |

Calcium | Chloride | Chromium | Cobalt | Copper | Fluoride |

Germanium | Iron |

| Iodine | Lithium | Magnesium | Manganese | Molybdenum | Nickel |

Phosphorus | Potassium | Selenium | Silicon | Sodium | Strontium |

Sulfur |

| Tin | Vanadium | Zinc | Trace Element & Mineral Ratios | Tin -

Health Effects & Toxicity | Vitamin C / Vit E / Vit B12 / Vit B15

Interactions |

| Mineral / Cellular Test - Acu-Cell Analysis | Spiritual Health

Benefits | Cellular Nutrition / Acu-Cell Home Page | Links &

Downloads |