Insulin: Part 2
Intracellular magnesium
relaxes muscles. What happens when you can't
store magnesium because the cell is resistant?
You lose magnesium and your blood vessels
constrict.
This causes an increase in
blood pressure and a reduction in energy since
intracellular magnesium is required for all
energy producing reactions that take place in
the cell.
But most importantly,
magnesium is also necessary for the action of
insulin and the manufacture of insulin. When you
raise your insulin, you lose magnesium, and the
cells become even more insulin resistant. Blood
vessels constrict and glucose and insulin can't
get to the tissues, which makes them more
insulin resistant, so the insulin levels go up
and you lose more magnesium. This is the vicious
cycle that begins even before you were born.
Insulin sensitivity starts to
be determined the moment the sperm combines with
the egg. If a pregnant woman eats a
high-carbohydrate diet, which turns into sugar,
animal studies have shown that the fetus will
become more insulin resistant.
Worse yet, researchers have
used sophisticated measurements and found that
if that fetus happens to be a female, the eggs
of that fetus are more insulin resistant. Does
that mean it is genetic? No, you can be born
with something and it doesn't mean that it is
genetic. Diabetes is not a genetic disease as
such. You can have a genetic predisposition, but
it should be an extremely rare disease.
Sodium
Retention: Congestive Heart Failure
We mentioned high blood
pressure; if your magnesium levels go down or
your blood vessels constrict you get high blood
pressure. Insulin also causes the retention of
sodium, which causes the retention of fluid,
which causes high blood pressure and fluid
retention: congestive heart failure.
One of the strongest
stimulants of the sympathetic nervous system is
a high level of insulin. What does all of this
do to the heart? Not very good things.
There was a solid study done a
couple of years ago that showed that heart
attacks are two to three times more likely to
happen after a high-carbohydrate meal and are
specifically NOT likely after a high-fat meal.
Why is that?
Because the immediate effects
of raising your blood sugar from a
high-carbohydrate meal is a raise in insulin.
This immediately triggers the sympathetic
nervous system, which will cause arterial spasm,
or constriction of the arteries. If you anyone
is prone to a heart attack, this is when they
are going to get it.
Blood
Lipids
Insulin mediates blood lipids.
For that patient mentioned earlier who had a
triglyceride level of 2200, one of the easiest
things we can do is lower triglyceride levels.
It is so simple. There was just an article in
the Journal of the American Medical Association
(JAMA) saying that the medical profession
doesn't know how to reduce triglycerides
dietarily, that drugs still need to be used.
This is so ridiculous because
you will find that it is the easiest thing to
do. There is an almost direct correlation
between triglyceride levels and insulin levels,
though in some people more than others.
The gentleman who had a
triglyceride level of 2200 while on all the
drugs only had an insulin level of 14.7. That is
only slightly elevated, but it doesn't take much
in some people. All we had to do was get his
insulin level down to 8 initially and then it
went down to six and that got his triglycerides
down to under 200.
The way you control blood
lipids is by controlling insulin.
LDL cholesterol comes in
several fractions, and it is the small, dense
LDL that plays the largest role in initiating
plaque, as it's the most oxidizable, and it’s
the most able to actually fit through the small
cracks in the endothelium. And this is the
cholesterol that insulin actually raises the
most. When I say insulin, I should say insulin
resistance. It is insulin resistance that is
causing this.
Cells become insulin resistant
because they are trying to protect themselves
from the toxic effects of high insulin. They
down regulate their receptor activity and number
of receptors so that they don't have to listen
to that noxious stimuli all the time. It is like
having this loud, disgusting music played and
you want to turn the volume down.
You might think of insulin
resistance as similar to sitting in a smelly
room and pretty soon you don't smell it anymore
because you get desensitized.
You can think about it, it’s
not that you are not thinking about it anymore.
But if you walk out of the room and then come
back in, the smell is back, which means you get
resensitized.
If your cells are exposed to
insulin at all, they get a little bit more
resistant to it. So the pancreas just puts out
more insulin. I saw a patient today whose blood
sugar was 102 and her insulin was 90! She wasn't
sure if she was fasting or not, but I've seen
other patients where their blood sugar was under
100 and their fasting insulin has been over 90.
That is a fasting insulin. I'm
not sure how many people are familiar with
seeing fasting insulins, but if I drank all the
glucose I could possibly drink my insulin would
never go above probably 40. So she was extremely
insulin resistant.
What was happening was that
she was controlling her blood sugar.
Statistically she was not diabetic or even
impaired glucose tolerant. Her glucose is
supposedly totally normal. But her cells aren't
listening to insulin; she just has an
exceptionally strong pancreas.
Her islet cells that produce
insulin are extremely strong and are able to
compensate for that insulin resistance by
producing thirty times more insulin than what my
fasting insulin is. And just by mass action her
pancreas is yelling so loud that her cells are
able to listen, but they are not going to listen
forever. Her pancreas is not going to be able
keep up that production forever.
Once her production of insulin
starts slowing down, or her resistance goes up
any more, then her blood sugar goes up and she
becomes a diabetic. For many years, decades
before that, her insulin levels have been
elevated but have never been checked.
That insulin resistance is
associated with the hyperinsulinemia that
produces all of the so-called chronic diseases
of aging, or at least contributes to them. As
far as we know in many venues of science, this
is the main cause of aging in virtually all
life.
Insulin is that important.
So controlling insulin
sensitivity is extremely important.
Insulin and
Cardiovascular Disease
Insulin is a so-called
mytogenic hormone. It stimulates cell
proliferation and cell division. If all of the
cells were to become resistant to insulin we
wouldn't have that much of a problem, but all of
the cells don't become resistant.
Some cells are incapable of
becoming very resistant. The liver becomes
resistant first, then the muscle tissue, then
the fat. When the liver becomes resistant it
suppresses the production of sugar.
The sugar floating around in
your body at any one time is the result of two
things, the sugar that you have eaten and how
much sugar your liver has made. When you wake up
in the morning it is more of a reflection of how
much sugar your liver has made. If your liver is
listening to insulin properly it won't make much
sugar in the middle of the night. If your liver
is resistant, those brakes are lifted and your
liver starts making a bunch of sugar, so you
wake up with a bunch of sugar.
The next tissue to become
resistant is the muscle tissue. What is the
action of insulin in muscles? It allows your
muscles to burn sugar for one thing. So if your
muscles become resistant to insulin it can't
burn that sugar that was just manufactured by
the liver. So the liver is producing too much,
the muscles can't burn it, and this raises your
blood sugar.
Well the fat cells become
resistant, but not for a while as it takes them
longer. So for a while your fat cells retain
their sensitivity.
What is the action of insulin
on your fat cells? To store that fat. It takes
sugar and it stores it as fat. So until your fat
cells become resistant you get fat. As people
become more and more insulin resistant, their
weight goes up and up.
But eventually they plateau.
They might plateau at 300 pounds, 220 pounds,
150 pounds, but they will eventually plateau as
the fat cells protect themselves and become
insulin resistant.
As all these major tissues,
your liver, muscles and fat, become resistant
your pancreas is putting out more insulin to
compensate, so you are hyperinsulinemic and
you've got insulin floating around all the time,
90 units or more.
But there are certain tissues
that aren't becoming resistant such as your
endothelium; the lining of the arteries
doesn’t become resistant very readily, so all
that insulin is affecting the lining of your
arteries.
If you drip insulin into the
femoral artery of a dog, there was a Dr. Cruz
who did this in the early 70s by accident, the
artery will become almost totally occluded with
plaque after about three months.
The contra lateral side was
totally clear, just contact of insulin in the
artery caused it to fill up with plaque. That
has been known since the 70s and has been
repeated in chickens and in dogs; it is really a
well-known fact that insulin floating around in
the blood causes a plaque build-up. They didn't
know why, but we know that insulin causes
endothelial proliferation. This is the first
step as it causes a tumor, an endothelial tumor.
Insulin also causes the blood
to clot too readily and causes the conversion of
macrophages into foam cells, which are the cells
that accumulate the fatty deposits. 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.
Insulin is a part of any known
cause of cardiovascular disease. It influences
nitric oxide synthase; you produce less nitric
oxide in the endothelium. We know that helps
mediate vasodilatation and constriction, i.e.
angina.
I mentioned that insulin
increases cellular proliferation, what does that
do to cancer? It increases it. And there are
some pretty strong studies that show that one of
the strongest correlations to breast and colon
cancers are levels of insulin.
Hyperinsulinemia causes the
excretion of magnesium in the urine. What other
big mineral does it cause the excretion of?
Calcium. People walking around with
hyperinsulinemia can take all the calcium they
want by mouth and it's all going to go out in
their urine.
Insulin-like
Growth Factors (IgFs)
Insulin is one of the first
hormones that any organism ever developed, and
as I mentioned in genetics, things are built
upon what was there before. So all the other
hormones we have in our body were actually built
upon insulin. In other words, insulin controls
growth hormone.
The pituitary produces growth
hormone, and then it goes to the liver and the
liver produces what are called IgF 1 thru 4,
there are probably more. What does IgF stand
for? Insulin-like growth factor. They are the
active ingredients. Growth hormone has some
small effects on its own, but the major growth
factors are the IgFs that then circulate
throughout the body.
Why are they called IgF's or
insulin-like growth factors? Because they have
an almost identical molecular structure to
insulin. When I said that insulin promotes
cellular proliferation, it is because it
cross-reacts with IgF receptors. So somewhere in
the evolutionary tree, IgFs diverged from
insulin. Insulin can work very well by itself;
it doesn't need growth hormone, but growth
hormone can't do anything without insulin.
Thyroid
The thyroid produces mostly
T4. T4 goes to mostly to the liver and is
converted to T3. We are getting the idea that
insulin controls a lot of what goes on in the
liver, and the liver is the primary organ that
becomes insulin resistant.
When the liver can no longer
listen to insulin, you can't convert T4 to T3
very well. In people who are hyperinsulinemic
with a thyroid hormone that comes back totally
normal, it is important to measure their T3.
Just as often as not, their free T3 will be low,
but get their insulin down and it comes back up.
Insulin helps control sex
hormones estrogen, progesterone, and
testosterone as well. Insulin helps control the
manufacture of cholesterol and where do all the
sex hormones come from? All the stearic hormones
are originally derived from cholesterol, so
that's one way. Dr Nestler from the University
of Virginia who has spent the last eight years
doing multiple studies to show that DHEA levels
are directly correlated with insulin levels, or
I should say insulin resistance.
The more insulin resistant you
are, the lower your DHEA levels. He firmly
believes, and has a lot of studies to back it
up, that the decline in DHEA is strictly due to
the increase in insulin resistance with age. If
you reduce the insulin resistance, the DHEA
rises.
And how are these sex hormones
carried around the body? Something called sex
hormone binding globulins. The more that is
bound, the less free, active hormone you have.
Sex hormone binding globulin is controlled by
what? Insulin. There is not a hormone in the
body that insulin doesn't affect, if not
directly control.
Osteoporosis
You take a bunch of calcium.
The medical profession just assumes that it has
a homing device and it knows to go into your
bone. What happens if you have high levels of
insulin and you take a bunch of calcium? Number
one, most of it is just going to go out in your
urine. You would be lucky if that were the case
because that part that doesn't does not have the
instructions to go to your bone because the
anabolic hormones aren't working.
This is first of all because
of insulin, then because of the IGFs from growth
hormone, also testosterone and progesterone.
They are all controlled by insulin and when they
are insulin resistant they can't listen to any
of the anabolic hormones. Your body doesn't know
how to build tissue anymore so while some of the
calcium may end up in your bone, a good deal of
it will end up everywhere else--leading to
metastatic calcifications, including in your
arteries.
Diseases are a result of a
lack of communication. There are certain things
that your cells need to be healthy. If you learn
nothing else today, you should know that
everything is at the cellular and molecular
level and we are nothing but a community of
cells. We are a commune of cells; a metropolis
of cells that have been given instructions to
cooperate.
When you have a large number
of cells, like we have ten trillion or so, there
must be proper communication so that there will
be proper division of labor. You can take most
any cell in your body, put it in a petrie dish
and under the right conditions it can live all
on its own. They each have a life of their own.
You can manipulate the
genetics of a cell, and we've now made a blood
cell into a nerve cell. Pretty soon we are going
to be able to take any cell we want and make it
into any other cell, because every cell in your
body has the identical genetics, all derived
from that egg and that sperm that came together.
Why is one cell different from another? Because
they are reading different parts of the same
library.
You can influence which part
of that genetic library that every cell reads by
the environment of that cell. The environment of
that cell is going to be very much dictated by
hormones and what you eat. Eating is just
internalizing the external environment. That is
what you have circulation for, to bring that
external environment to each and every one of
those cells that is inside of you.
I hope that by now you have
gotten the idea that high insulin resistance is
not very good for you. So now let's talk about
what causes insulin resistance.
What Causes
Insulin Resistance?
Any time your cell is exposed
to insulin it is going to become more insulin
resistant. That is inevitable; we cannot stop
that, but the rate we can control. An inevitable
sign of aging is an increase in insulin
resistance.
That rate is the variable. If
you can slow down that rate, you can become a
centenarian, a healthy one. You can slow the
rate of aging. Not even just the rate of
disease, but the actual rate of aging itself can
be modulated by insulin. We talked about some of
the lower animals and there is some pretty good
evidence that even in humans we still retain the
capacity to control lifespan at least partially.
We should be living to be 130 to 140 years old
routinely.
Let's talk about
carbohydrates. We talk about simple and complex
carbohydrates, this is totally irrelevant, it
means absolutely nothing. Carbohydrates are
fiber or non-fiber. Few things in life are as
clear-cut as this. Fiber is good for you, and a
non-fiber carb is bad for you. You can bank on
that.
There is not a whole lot of
middle ground. If you have a carbohydrate that
is not a fiber it is going to be turned into a
sugar, whether it be glucose or not. It may be
fructose and won't necessarily raise your blood
glucose. Fructose is worse for you then glucose
so if you just go by blood sugar, which is just
glucose, it doesn't mean that you are not
raising your blood fructose, or your blood
galactose which is the other half of lactose.
All of those sugars are as bad
or worse for you than glucose. You can't just go
by so-called blood sugar because we just don't
measure blood fructose or blood galactose, but
they are all bad for you.
Why are they bad? Well number
one we know that it provokes insulin and every
time you provoke insulin it exposes your body to
more insulin and just like walking in a smelly
room your body is going to become more resistant
to insulin.
So every time you have a surge
of sugar and you have a surge of insulin, you
get more and more insulin resistant and risk all
of the problems we've talked about.
Part
3
