The Insulin Magnesium Story

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The Insulin Magnesium Story

_http://magnesiumforlife.com/medical-application/the-insulin-magnesium-story

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(http://magnesiumforlife.com/medical-application/the-insulin-magnesium-story/)

Mark Sircus Ac., OMD International Medical Veritas Association

_http://publications.imva.info_ (http://publications.imva.info/)

Email: _director_

(director)

 

 

 

Magnesium is necessary for both the action of insulin and the manufacture

of insulin.

 

 

Magnesium is a basic building block to life and is present in ionic form

throughout the full landscape of human physiology. Without insulin though,

magnesium doesn’t get transported from our blood into our cells where it is

most needed. When Dr. Jerry Nadler of the Gonda Diabetes Center at the City

of Hope Medical Center in Duarte, California, and his colleagues placed 16

healthy people on magnesium-deficient diets, their insulin became less

effective at getting sugar from their blood into their cells, where it’s

burned or stored as fuel. In other words, they became less insulin sensitive or

what is called insulin resistant. And that’s the first step on the road to

both diabetes and heart disease.

 

 

Insulin is a common denominator, a central figure in life as is magnesium.

The task of insulin is to store excess nutritional resources.This system

is an evolutionary development used to save energy and other nutritional

necessities in times (or hours) of abundance in order to survive in times of

hunger. Little do we appreciate that insulin is not just responsible for

regulating sugar entry into the cells but also magnesium, one of the most

important substances for life. It is interesting to note here that the kidneys

are working at the opposite end physiologically dumping from the blood

excess nutrients that the body does not need or cannot process in the moment.

 

 

Controlling the level of blood sugars is only one of the many functions of

insulin.

 

 

Insulin plays a central role in storing magnesium but if our cells become

resistant to insulin, or if we do not produce enough insulin, then we have

a difficult time storing magnesium in the cells where it belongs. When

insulin processing becomes problematic magnesium gets excreted through our

urine instead and this is the basis of what is called magnesium wasting

disease.

 

 

There is a strong relationship between magnesium and insulin action.

Magnesium is important for the effectiveness of insulin. A reduction of

magnesium in the cells strengthens insulin resistance. [1],[2]

 

 

Low serum and intracellular magnesium concentrations are associated with

insulin resistance, impaired glucose tolerance, and decreased insulin

secretion. [3],[4],[5] Magnesium improves insulin sensitivity thus lowering

insulin resistance. Magnesium and insulin need each other. Without magnesium,

our pancreas won’t secrete enough insulin–or the insulin it secretes

won’t

be efficient enough–to control our blood sugar.

 

 

Magnesium in our cells helps the muscles to relax but if we can’t store

magnesium because the cells are resistant then we lose magnesium which makes

the blood vessels constrict, affects our energy levels, and causes an

increase in blood pressure. We begin to understand the intimate connection

between diabetes and heart disease when we look at the closed loop between

declining magnesium levels and declining insulin efficiency.

 

 

Though it would be a long stretch of the longest giraffe’s neck to compare

insulin with chlorophyll we are walking a trail at the very nuclear core

of life. It’s the magnesium trail and we find to our surprise that it takes

us into intimate contact with the very structure and foundation of life.

The dedication of this chapter is to the beauty of magnesium, to its meaning

in life, in health and in medicine.

 

 

We were talking about chlorophyll and now insulin and putting magnesium

in-between. Walking further along is the DHEA magnesium story and the DNA

magnesium story. And then there is the cholesterol magnesium story. Every part

of life is in love with magnesium except allopathic medicine which just

cannot accept it in all its light, flame and beauty. Thousands of years ago

the Chinese named it the beautiful metal and they were seeing something

pharmaceutical medicine does not want to see for there is little money to be

made from something so common.

 

 

In a study from Taiwan, the risk of dying from diabetes was inversely

proportional to the level of magnesium in the drinking water.[6]

Dr. Jerry L. Nadler

 

 

Dr. Jerry Nadler of the Gonda Diabetes Center at the City of Hope Medical

Center in Duarte, California, and his colleagues placed 16 healthy people

on magnesium-deficient diets, their insulin became less effective at getting

sugar from their blood into their cells, where it’s burned or stored as

fuel. In other words, they became less insulin sensitive.

 

 

Insulin regulates cholesterol levels. There is a direct connection between

the level of cholesterol and the level of insulin.

 

 

Magnesium is necessary for both the action of insulin and the manufacture

of insulin. Magnesium is a basic building block to life and is present in

ionic form throughout the full landscape of human physiology. Without

insulin though, magnesium doesn’t get transported from our blood into our

cells

where it is most needed.

 

 

Diabetes mellitus is associated with magnesium depletion, which in turn

contributes to metabolic complications of diabetes including vascular disease

and osteoporosis. Intracellular depletion is directly connected to the

impaired ability of insulin to increase intracellular magnesium during insulin

deficiency or insulin resistance. Magnesium deficiency per se has been

reported to result in insulin resistance.

 

 

Insulin resistance and magnesium depletion result in a vicious cycle of

worsening insulin resistance and decrease in intracellular Mg(2+) which

limits the role of magnesium in vital cellular processes.[7] Magnesium is an

important cofactor for enzymes involved in carbohydrate metabolism so anything

threatening magnesium levels threatens overall metabolism. Large

epidemiologic studies in adults indicate that lower dietary magnesium and lower

serum magnesium are associated with increased risk for type 2 diabetes.[8],[9]

 

 

Redistribution of magnesium into cells may cause lower magnesium levels in

the serum. Insulin causes this effect.

 

 

Researchers at the Institute of Internal Medicine, University of Palermo

wrote, “Intracellular magnesium concentration has also been shown to be

effective in modulating insulin action (mainly oxidative glucose metabolism),

offset calcium-related excitation-contraction coupling, and decrease smooth

cell responsiveness to depolarizing stimuli. A poor intracellular Mg

concentration, as found in noninsulin-dependent diabetes mellitus (NIDDM) and

in

hypertensive patients, may result in a defective tyrosine-kinase activity at

the insulin receptor level and exaggerated intracellular calcium

concentration.†[10]

 

 

The link between diabetes mellitus and magnesium deficiency is well known.

A growing body of evidence suggests that magnesium plays a pivotal role in

reducing cardiovascular risks and may be involved in the pathogenesis of

diabetes itself.

Dr. Jerry L. Nadler

 

 

Magnesium improves and helps correct insulin sensitivity, which is the

fundamental defect that characterizes pre-diabetes, metabolic syndrome and

even full blown diabetes and heart disease. An intracellular enzyme called

tyrosine kinase requires magnesium to allow insulin to exert its

blood-sugar-lowering effects. In several studies, daily oral magnesium

supplementation

substantially improved insulin sensitivity by 10% and reduced blood sugar by

37%.[11],[12] Magnesium also helps correct abnormal lipoprotein patterns.

We would expect to find larger improvements in this increased insulin

sensitivity if magnesium is supplemented in a correct way meaning through

transdermal and oral methods combined using liquid magnesium chloride

(magnesium

oil) as compared to the very inefficient oral solid forms commonly used.

 

 

Improved insulin sensitivity from magnesium replacement can markedly

reduce triglyceride levels.[13] Reduced triglyceride availability, in turn,

reduces triglyceride-rich particles, such as very low-density lipoprotein

(VLDL) and small low-density lipoprotein (small LDL), both of which are

powerful

contributors to heart disease. Magnesium supplementation can also raise

levels of beneficial high-density lipoprotein (HDL).[14]

 

 

Insulin regulates intracellular magnesium levels via activation of

Na+/Mg2+ exchange. Insulin’s effect on Na/Mg exchange may explain the low

cellular

magnesium levels observed in vivo under hyperinsulinemic conditions.[15]

 

 

Magnesium is a necessary element for all living organisms both animal and

plant. Chlorophyll is structured around a magnesium atom, while in animals,

magnesium is a key component of cells, bones, tissues and just about every

physiological process you can think of. Magnesium is primarily an

intracellular cation; roughly 1% of whole-body magnesium is found

extracellularly,

and the free intracellular fraction is the portion regulating enzyme

pathways inside the cells. Life packs the magnesium jealously into the cells,

every drop of it is precious.

 

 

Add the story of red blood cells and hemoglobin, which replace the

chlorophyll molecule’s magnesium center with ion to function for O2 and CO2

transport, but retains magnesium in other crucial roles, and we are on the

essential axis of life that allopathic medicine can address with intensive

magnesium therapies.

 

 

Magnesium improves insulin sensitivity thus lowering insulin resistance.

Magnesium and insulin need each other. Without magnesium, our pancreas won’t

secrete enough insulin–or the insulin it secretes won’t be efficient

enough–to control our blood sugar. Insulin is a hormone. And like many

hormones, insulin is a protein. Insulin is secreted by groups of cells within

the

pancreas called islet cells. Insulin is much more important and has many

more functions then we realize. It regulates:

 

lifespan - Lower insulin levels equate to a longer life.

 

blood sugar

 

blood lipids

 

excess nutrients (from glucose, carbs and calories) and converts them to

fat

 

builds muscle

 

stores protein

 

magnesium levels in our body

 

calcium levels in the body

 

retains sodium levels

 

cell division

 

growth hormone

 

liver functions

 

sex hormones, estrogen, progesterone, testosterone

 

cholesterol in the body

 

fat in our body

 

 

Magnesium is a cofactor for multiple enzymes involved in carbohydrate

metabolism.[16] Adipocyte cells placed in low-magnesium media show reduction in

insulin-stimulated glucose uptake.[17] Magnesium deficiency is associated

with increased intracellular calcium levels, which may lead to insulin

resistance. Low erythrocyte magnesium content increases membrane

microviscosity, which may impair insulin interaction with its receptor.[18]

Tyrosine

kinase activity is decreased in muscle insulin receptors of rats fed a

low-magnesium diet.[19] These findings indicate that magnesium deficiency

directly

affects insulin signaling.

 

 

When magnesium levels fall hypersecretion of adrenalin and insulin

compensate. Their increased secretion help maintain the constancy of the levels

in

intracellular magnesium in the soft tissues. Plasma and intracellular

magnesium concentrations are tightly regulated by insulin. In vitro and in vivo

studies have demonstrated that insulin modulates the shift of magnesium

from extracellular to intracellular space.

 

 

Dr. Ron Rosedale says that, “Insulin floating around in the blood causes

plaque build-up. They didn’t know why, but we know that insulin causes

endothelial proliferation. Every step of the way, insulin is causing

cardiovascular disease. It fills the body with plaque, it constricts the

arteries, it

stimulates the sympathetic nervous system, it increases platelet

adhesiveness and coaguability of the blood.â€

 

 

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[1] Paolisso G, Scheen A, D’Onofrio F, Lefebvre P: Magnesium and glucose

homeostasis. Diabetologia 33:511–514, 1990[Medline]

 

[2] Nadler JL, Buchanan T, Natarajan R, Antonipillai I, Bergman R, Rude R:

Magnesium deficiency produces insulin resistance and increased thromboxane

synthesis. Hypertension 21:1024–1029, 1993

 

[3]Ma J, Folsom AR, Melnick SL, Eckfeldt JH, Sharrett AR, Nabulsi AA,

Hutchinson RG, Metcalf PA: Associations of serum and dietary magnesium with

cardiovascular disease, hypertension, diabetes, insulin, and carotid wall

thickness: the ARIC study. J Clin Epidemiol 48:927–940, 1985

 

[4] Rosolova H, Mayer O Jr, Reaven GM: Insulin-mediated glucose disposal

is decreased in normal subjects with relatively low plasma magnesium

concentrations. Metabolism 49:418–420, 2000[Medline]

 

[5] Resnick LM, Gupta RK, Gruenspan H, Alderman MH, Laragh JH:

Hypertension and peripheral insulin resistance: possible mediating role of

intracellular free magnesium. Am J Hypertens 3:373–379, 1990[Medline]

 

[6] _http://www.mgwater.com/diabetes.shtml_

(http://www.mgwater.com/diabetes.shtml)

 

[7] Magnesium transport induced ex vivo by a pharmacological dose of

insulin is impaired in non-insulin-dependent diabetes mellitus. Hua, H :

Gonzales, J : Rude, R K Magnes-Res. 1995 Dec; 8(4): 359-66

 

[8] Lopez-Ridaura R, Willett WC, Rimm EB, Liu S, Stampfer MJ, Manson JE,

Hu FB: Magnesium intake and risk of type 2 diabetes in men and women.

Diabetes Care 27:134–140, 2004

 

[9] Kao WH, Folsom AR, Nieto FJ, Mo JP, Watson RL, Brancati FL: Serum and

dietary magnesium and the risk for type 2 diabetes mellitus: the

Atherosclerosis Risk in Communities Study. Arch Intern Med 159:2151, 1999

 

[10] Mol Aspects Med. 2003 Feb-Jun;24(1-3):39-52. Role of magnesium in

insulin action, diabetes and cardio-metabolic syndrome X.Barbagallo M,

Dominguez LJ, Galioto A, Ferlisi A, Cani C, Malfa L, Pineo A, Busardo’ A,

Paolisso

G. Institute of Internal Medicine and Geriatrics, University of Palermo,

Via F Scaduto 6/C, Palermo, Italy. _mabar_ (mabar)

 

[11] Guerrero-Romero F, Tamez-Perez HE, Gonzalez-Gonzalez G et al. Oral

magnesium supplementation improves insulin sensitivity in non-diabetic

subjects with insulin resistance. A double-blind placebo-controlled randomized

trial. Diabetes Metab. 2004 Jun;30(3):253-8.

 

[12] Rodriguez-Moran M and Guerrero-Romero F. Oral magnesium

supplementation improves insulin sensitivity and metabolic control in type 2

diabetic

subjects: a randomized double-blind controlled trial. Diabetes Care. 2003

Apr;26(4):1147-52.

 

[13] Yokota K, Kato M, Lister F, et al. Clinical efficacy of magnesium

supplementation in patients with type 2 diabetes. J Am Coll Nutr. 2004

Oct;23(5):506S-9S.

 

[14] Rasmussen HS, Aurup P, Goldstein K, et al. Influence of magnesium

substitution therapy on blood lipid composition in patients with ischemic

heart disease. A double-blind, placebo controlled study. Arch Intern Med. 1989

May;149(5):1050-3.

 

[15] Am J Hypertens (2002) 15, 104A–104A; doi:S0895-7061(02)02558-X P-207:

Insulin regulates human erythrocyte Na+/Mg2+ exchange. Ana Ferreira1, Jose

R. Romero1 and Alicia Rivera. Pathology, Harvard Medical School; Medicine,

Harvard Medical School, Boston, MA, United States

 

[16] Paolisso G, Scheen A, D’Onofrio F, Lefebvre P: Magnesium and glucose

homeostasis. Diabetologia 33:511–514, 1990[Medline]

 

[17] Kandeel FR, Balon E, Scott S, Nadler JL: Magnesium deficiency and

glucose metabolism in rat adipocytes. Metabolism 45:838–843, 1996[Medline]

 

[18] Tongyai S, Rayssiguier Y, Motta C, Gueux E, Maurois P, Heaton FW:

Mechanism of increased erythrocyte membrane fluidity during magnesium

deficiency in weanling rats. Am J Physiol 257:C270–C276, 1989

 

[19] Suarez A, Pulido N, Casla A, Casanova B, Arrieta FJ, Rovira A:

Impaired tyrosine-kinase activity of C