Cardiology
Clinical Updates
How
Statins Work: The Development of Cardiovascular Disease and Its Treatment
With 3-Hydroxy-3-MethylglutarylCoenzyme A Reductase InhibitorsCME
[Cardiology
Clinical Updates - © 2001 Medscape, Inc.]
Michael
H. Davidson, M.D., F.A.C.C; Terry A. Jacobson, MD
Introduction
At the
turn of the 21st century, the primary cause of death and disability in
industrialized nations is cardiovascular disease (CVD). Based on current
estimates, by the year 2020, CVD will be the primary cause of death worldwide,
as the living standards of the developing nations rise and their populations
adopt the "Western lifestyle."
It
is well known what the unhealthy elements of this lifestyle are: too much
food (especially fats and saturated fats) and too little exercise. The
result is that the mass of the food consumed overwhelms the body's normal
metabolic needs and begins to accumulate throughout the cardiovascular
system. Specifically, the system succumbs to a disease process known as
atherosclerosis (from the Greek word "athero" for "gruel" and "sclero"
for "hard"-- literally, a hardening of the normally soluble "gruel" that
flows through the vascular system, delivering nutrients to the body).
Defining
the Disease State
All
of the food mammals ingest is chemically broken down and reorganized as
it passes through the gastrointestinal system and into the cardiovascular
circulation. This serves 2 purposes: some of the nutrient chemicals are
reconfigured to serve as a source of energy for the body's activity, and
some are reconfigured to provide building blocks for the body's structure.
In this review, we want to concentrate on the second process and what happens
when it malfunctions.
A
principal element in the circulation that causes this normally healthy
process to malfunction to the point that it becomes a disease state is
an excess of plasma cholesterol. Cholesterol is a vital biological molecule
that, in excess, accumulates in deposits of atherosclerotic plaque on the
walls of the circulatory tree. This, in turn, leads to the blockages and
interruptions of the circulation that result in angina, heart attacks,
and, ultimately, death.
Even
though this disease process affects so many people, it is not inevitable.
With varying degrees of success, it can be both prevented and treated.
The best interventions, both as prevention and as therapy, are proper diet
and adequate exercise. However, since these principles are not always followed,
nor are they necessarily adequate, it is reassuring that several pharmacologic
agents have proven effective in combatting the progression of CVD -- including
niacin, the fibrates, the bile acid sequestrants, and the "statins" (technical
name, 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors). All
of these drugs have been demonstrated to be effective across a range of
patients and disease severities, but the most successful and most widely
prescribed is the class of drugs known as "statins."
If
we examine the problem of atherosclerosis and its development more closely,
we are immediately faced with 2 issues:
-
What is
cholesterol? Where does it come from? How does it get from our dinner plates
into our arteries?
-
How and
why do statins work
A Brief
Definition of Terms
The role
of cholesterol in the pathogenesis of cardiovascular disease remained controversial
until surprisingly recently. Large surveys of patient records after World
War II first suggested a connection, and the introduction of better chemical
analysis techniques that could measure the amount of cholesterol in the
blood helped confirm the link. But the results of early attempts to lower
cholesterol with medical treatment were confusing, and the theory that
elevated cholesterol levels are unhealthy remained in question.
In
fact, it was really only in the last 20 years -- especially following the
statistically significant mortality results of large clinical trials with
the statins in the 1990s -- that assessment of plasma cholesterol levels
has become an important measurement in the doctor's office.
Originally,
the name for the problem of elevated cholesterol levels was hypercholesterolemia
(or, "too much cholesterol"), and the more general term, to include the
other lipid subfractions (ie, triglycerides) in addition to cholesterol,
was hyperlipidemia. However, the term dyslipoproteinemia is now
considered the most accurate, because it reflects states with multiple
lipid abnormalities, such as those characterized by reduced high-density
lipoprotein (HDL) but average total plasma cholesterol.
Triglycerides:
From Ingestion to Packaging
| The
principal components of the foods we ingest are protein, fat and fatty
acids, carbohydrates, and fiber. All of these elements are digested in
the stomach and then pass into the intestines, where the nutrient components
are absorbed and the remainder is excreted. In this review, we want to
concentrate on what happens to the fat and fatty acids.
Most
dietary fat consists of triglycerides (composed of a glycerol --
a 3-carbon alcohol -- plus 3 long-chain fatty acids of varying length).
For an average-sized and normally active individual, a healthy diet should
contain about 2000 cal/day, of which 30% may be fat; this represents a
daily intake of approximately 66 g of triglycerides and approximately 250
mg of cholesterol.
However,
the body must take into account the fact that food is not always available
and dietary fat content is not always constant. Moreover, the triglycerides
the body needs do not come directly from dietary sources, but rather the
food consumed must be processed to provide them. Therefore the mammalian
gastrointestinal system has evolved mechanisms to ensure a readily available
and reliable supply of triglyceride molecules to meet its metabolic demands.
After
fatty acids are ingested, they pass through the intestines, where they
are absorbed into the intestinal cells. Through a series of enzymatic reactions
involving apolipoprotein B-48, the fatty acids are turned into a stable
emulsion of lymph and triglyceride fat and are packaged into lipoprotein
micelles (ie, droplets or globules of fat plus protein) called chylomicrons.
These consist of 86% triglyceride fat, 9% phospholipids, 3% cholesterol,
and 2% protein. The chylomicrons are then rapidly secreted from the intestinal
wall and enter the blood stream, where they are suspended in the plasma. |
Panel 1. Triglycerides:
From Ingestion to Packaging
|
When
the chylomicrons reach the peripheral circulation, they enter the capillaries
of adipose tissue and muscle cells, where they encounter a chemical enzyme
called lipoprotein lipase (LPL). This enzyme, in turn, hydrolyzes the triglyceride
fat in the chylomicrons and produces a chylomicron remnant, which continues
through the circulation until it is taken up into the liver cells.
This
process, whereby the ingested fats -- especially the triglycerides -- are
"packaged" as lipoproteins for circulation through the cardiovascular system,
is entirely healthy and vital for the metabolic processes of the body.
A problem occurs when some of the lipoprotein subfractions become elevated,
resulting in dyslipoproteinemia.
Classification
of Lipoproteins
| There
are 3 major types of lipids that circulate in the plasma: cholesterol and
cholesterol esters, phospholipids, and triglycerides. Because lipids are
not soluble in water, the principal constituent of blood, they must be
packaged in some way in order to be suspended in the plasma. During the
initial pass through the gastrointestinal system, they are packaged as
chylomicrons, secreted into the circulation, transformed into chylomicron
remnants, and then finally delivered to the liver. There they are repackaged
as a series of smaller, denser lipoprotein "particles" and are resecreted
back into the circulation.
Although
there is an entire spectrum of these lipoprotein particles, they share
most of the same components, the principal difference being their size
and density. The figure depicts the major divisions in this spectrum and
their principal components: cholesterol (red stars), apolipoprotein B (keys),
apolipoprotein A (y shapes), and membrane proteins (blue dots).
Each
of these lipoprotein particles serves an important step in the body's metabolic
process. As they pass through the intestines and |
Panel 2. Classification
of Lipoproteins
|
into the
circulation with their contents of fatty acids, they act as little "food
trucks," delivering the nutrients in their core to the adipose and muscle
tissues. However, some of these particles, when they occur in the wrong
amount in the wrong place, can begin to cause problems -- problems so severe
that they ultimately lead to CVD, the primary cause of death in the industrialized
world.
The
difficulty for the physician and for the patient is that most dyslipoproteinemias
have few, if any, symptoms and only rarely cause clinical signs evident
on physical exam. It is thus important to have a working knowledge of the
elements of lipid metabolism in order to ensure proper recognition and
management of dyslipoproteinemia.
In
the panels that follow, we will discuss how each of these lipoproteins
is created and what role it plays. Note that these particle subtypes can
be further subdivided. For example, the low-density lipoprotein (LDL) particles
can be further subdivided into a range of sizes, from "light, fluffy" LDL
particles down to "small, dense" LDL particles, with the smaller particles
being more atherogenic (ie, causing atherosclerosis). However, measuring
these subfractions of the LDL particles requires sophisticated analytical
systems that are generally too expensive and complicated to be used in
ordinary medical practice. Therefore, tests that distinguish only the general
class of "LDL" particles are considered adequate for the purpose of diagnosis.
In
addition, analysis of recent clinical trial data (eg, from the Scandinavian
Simvastatin Survival Study, 4S) has shown that assessment of an aggregate
of the lipoprotein subfractions other than HDL (ie, very low-density
lipoprotein [VLDL] + intermediate-density lipoprotein [IDL] + LDL) is at
least as effective, and perhaps more linear, than assessment of LDL alone
as a predictor of future CVD events. Thus, in the new US National Cholesterol
Education Program (NCEP) guidelines, the "non-HDL" subfraction of cholesterol
has become the new target of measurement and treatment. To calculate this
parameter, the clinician measures total cholesterol (TC) and then determines
the non-HDL level according to the formula:
non-HDL
= TC - HDL
Structure
of a Lipoprotein
As
discussed above, the lipoprotein molecules that we ingest are repackaged
into particles so that they can be incorporated into a food delivery and
fat removal system. As shown in the figure, all of these particles are
assembled as lipid "globules," or particles, with a monolayer phospholipid
membrane. The important points to remember are that:
-
All cells
require cholesterol to maintain the structure of their membranes;
-
All cellular
membranes contain phospholipids, which are necessary for cell-to-cell communication
throughout the body; and
-
All cellular
membranes contain glycerol, a component of triglycerides.
|
Panel
3. Structure of a Lipoprotein
|
The enlargement
of the cell membrane on the right side of the figure shows the components
of the monolayer phospholipid membrane:
-
Millions
of 2-tailed phospholipid molecules, with their "heads" arranged so that
they form the outer surface of the membrane of the chylomicron;
-
A few
cholesterol molecules interspersed among the phospholipid molecules that
form the particle's membrane;
-
Membrane-spanning
protein "pores"; and
-
Membrane-spanning
apolipoproteins
-
several
apolipoprotein B molecules (Apo B) in the LDL or VLDL particles
-
1 apolipoprotein
A molecule (Apo A) in each HDL particle
The lower
left of the figure affords a look "inside" the lipoprotein particle, where
we see the "fatty core," consisting of cholesterol, cholesterol esters,
triglycerides (the dark brown "jelly fish"), and free fatty acids (the
"legs" of the jelly fish).
All
lipoprotein particles are constructed in this manner; the particles differ
in their size and density or, in the case of the HDL vs non-HDL, in the
apolipoprotein molecule embedded in the surface membrane (Apo A vs Apo
B).
Metabolism
of Fatty Acids
| The
human lipid transport system ferries hydrophobic lipid molecules from sites
of synthesis to sites of utilization. For example, it transports triglycerides
through the digestive system and the liver to peripheral sites of utilization
or storage (eg, muscle or adipose tissue), and it transports cholesterol
to the liver for bile acid synthesis and for excretion from the body.
Not
surprisingly, the proteins (or apolipoproteins) that mediate this process
are remarkably well conserved through evolution, and the same basic process
is observed in most mammals.
As
outlined briefly in Panel 1, once the fatty acids are packaged into the
chylomicrons and pass out of the intestines and into the circulation, they
encounter the enzyme LPL. This enzyme hydrolyzes ("dissolves") some of
the fat in the core of the chylomicron, and the depleted globule becomes
a chylomicron remnant, which ultimately passes into the liver. The
remnant is then taken up into the liver cells and undergoes a series of
reactions that repackage the constituent lipids into other lipoprotein
particles (as shown in Panel 2) and deliver them back into the circulation. |
Panel 4. Metabolism
of Fatty Acids
|
This
process involves 2 important steps: (1) removal of the chylomicron remnants
from the circulation, and (2) repackaging of the large chylomicron fragments
into smaller, ever more atherogenic particles.
Thus,
one of the first points at which the lipid transport system can malfunction
is when removal of the chylomicron remnants from the circulation is overwhelmed.
In the normocholesterolemic person, triglyceride levels following a meal
(ie, postprandial levels) return to baseline within 8-10 hours. In patients
with atherosclerosis, by contrast, the postprandial triglyceride levels
are higher and take longer to return to baseline, due to a delayed removal
of the chylomicron remnant particles. This illustrates why it is important
for a patient with atherosclerosis to maintain a diet low in total and
saturated fats, in order to decrease the excess of chylomicron remnants
that must be removed from the circulation.
Once
the chylomicron remnant is taken up by receptors in the liver, its components
are repackaged into a VLDL particle, a process that requires apolipoprotein
B100. The VLDL particle is then secreted from the liver back into the circulation.
The same LPL that changed chylomicrons into chylomicron remnants now hydrolyzes
the triglyceride fats in the core of the VLDL to produce IDL cholesterol.
Recall
that the triglyceride molecule consists of glycerol plus 3 fatty acid "tails."
To hydrolyze the triglycerides in the core of the VLDL particles, LPL cleaves
the fatty acyl residues attached to the glycerol, generating 3 molecules
of free fatty acid for each molecule of glycerol. The fatty acids are rapidly
taken up by muscle cells for energy utilization (a process requiring insulin)
or by adipose cells for storage, and the depleted particle is left as the
smaller and denser IDL.
Next,
via the interaction of apo E and the LDL receptor in the liver, some of
the IDL particles are reabsorbed in the liver, while others are further
hydrolyzed by hepatic lipase to produce the still more-compact LDL cholesterol.
These LDL particles are then secreted into the circulation to transport
their fatty energy molecules throughout the body.
LDL
particles contain mostly cholesterol and apo B100, and normally contain
only 4% to 8% of their mass as triglycerides. However, under certain circumstances,
especially when triglyceride levels are elevated, LDL particles can be
enriched in core cholesterol esters and depleted in triglycerides, making
them even smaller and more dense, and hence more atherogenic (as will be
discussed below).
Build-up
of Plaque in the Arterial Walls
| After
all of the steps outlined above, the vital cholesterol molecules are now
packaged as relatively small, dense LDL particles, ready to be circulated
throughout the body's vascular system. Again, this is a normal and healthy
process. However, at some crucial concentration of LDL particles and viscosity
of blood flow, some of the LDL particles begin to "stick" at certain vulnerable
points in the arterial wall. At this point, a whole cascade of events follows,
with the formerly healthy, smoothly functioning artery now becoming clogged
and only sluggishly responsive.
One
of the first ultrastructural alterations to occur in the atherosclerotic
artery is an accumulation of small LDL lipoprotein particles in the intima
(or walls) of the blood vessels. The principal reason for this change is
that there is simply too much LDL cholesterol in the circulation -- thus
providing another argument for patients, particularly those with atherosclerosis,
to consume less fat and saturated fat.
When
the LDL particles begin to adhere to the vessel wall, they bind via their
apolipoprotein "receptors" to the proteoglycans (large |
Panel 5. Build-up
of Plaque in Arterial Walls
|
proteins
combined with sugars) in the intima. When examined under high magnification,
these lipoprotein particles appear to coalesce into aggregates that "decorate"
the walls of the arterial intima. At this point, the problem is compounded,
because once the LDL particles bind to the proteoglycans, they begin to
exhibit increased susceptibility to oxidative or other chemical modifications,
and oxidized LDL particles are particularly chemoattractive to the
area of a lesion in the artery wall. Finally, the permeability of the endothelial
monolayer increases at sites where these particles have accumulated, causing
a predilection for even more accumulation of LDL.
Thus,
once the LDL particles, especially oxidized LDL particles, begin to bind
to points in the vessel wall, they lose their ability to flow freely, create
a "lesion" on the vessel wall, the problem begins to grow.
Enter
the Macrophages
| As
we saw in Panel 5, the first step toward an atherosclerotic artery has
occurred: LDL particles, especially the smallest and the oxidized LDL particles,
have begun binding to the wall of the artery, creating a "lesion" in the
normally smooth arterial wall.
The
second morphologically definable event in the initiation of atherosclerosis
is the recruitment and accumulation of leukocytes, especially macrophages
("macro" = large; "phage" = to eat), at the site of the lesion.
Normal
endothelial cells generally resist adhesive interactions with leukocytes;
however, soon after an atherosclerotic lesion forms in the wall of the
vessel, leukocytes begin to adhere to the vessel wall and accumulate lipids,
becoming lipid-laden macrophages known as "foam cells." In the healthy
state, when the system is not overloaded with cholesterol, an elegant control
mechanism quenches expression of the LDL receptor as soon as a cell collects
enough LDL cholesterol for its metabolic needs. In the pathologic state,
however, the LDL receptor is supplanted by molecules known as "scavenger"
receptors. |
Panel 6. HDL and
the
Reverse Cholesterol Transport
System
|
In
contrast to its actions at the LDL receptor, cellular cholesterol sufficiency
does not suppress the activity of scavenger receptors. These scavenger
receptors preferentially bind to modified (especially oxidized) lipoproteins
and mediate increased uptake of oxidized LDL into the macrophages, causing
them to rapidly become lipid-laden foam cells under conditions of cholesterol
excess.
The
result is the precursor lesion, known as the "fatty streak," which consists
mainly of accumulations of lipid-engorged leukocytes (principally macrophages)
and which appears on the interior wall of the blood vessel almost like
a "pimple." As these lesions, or fatty streaks, evolve into atherosclerotic
plaque, it is the extracellular matrix that makes up much of the volume,
although plaques often also develop areas of calcification as they evolve.
Indeed, the presence of calcifications is one of the ways that plaque can
be visualized with current imaging techniques.
The
Atherosclerotic Vessel
| Once
plaque is established, this section of this vessel has become atherosclerotic.
For a long time, it was thought that CVD occurred when one of these plaques
formed and grew until it obstructed flow through the blood vessels, interrupting
flow of blood to the heart (or the brain) and resulting in ischemia (ie,
"no flow"), which the patient experienced as angina, then a heart attack
(or stroke), and ultimately, if not treated in time, ischemic death. This
picture is wrong for 3 reasons:
First,
advanced imaging techniques have shown that the vessel "remodels" and the
wall of the vessel bulges outward, so that the lumen size remains relatively
unchanged (often making the presence of plaque difficult to visualize on
simple angiography). Only after the plaque burden exceeds the capacity
of the artery to remodel outward does encroachment on the arterial lumen
begin.
As
these plaques encroach on the luminal space, they are called "stenoses."
Eventually, the stenoses may grow to a size at which they impede blood
flow through the artery; lesions that produce stenoses > 60% of the lumen
size can cause flow limitations under conditions of increased demand. |
Panel 7. The
Atherosclerotic Vessel
|
Second,
however, the problem is not that the plaque grows until it completely obstructs
the vessel. Rather, the problem is that the plaque becomes unstable, bursts,
and empties a cocktail of thrombogenic substances that grow into the blockage
that leads to ischemia.
Finally,
atherosclerosis is not a discrete area of plaque at a single area of the
arterial tree, but a diffuse disease process that creates the "fatty streaks,"
or atherosclerotic lesions, over wide areas throughout the vasculature.
The
initiation and evolution of the atherosclerotic plaque generally takes
place over many years, during which the affected person often has no symptoms.
This is why, once the patient becomes symptomatic (generally experiencing
angina), the disease is already established, and strong and effective therapeutic
measures are required.
The
Maturation of HDL
| As
we saw in Panel 2, evolution of the non-HDL family of lipoprotein particles
that culminates in oxidized LDL and atherosclerotic plaque does not account
for all of the elements in the metabolism of cholesterol.
All
of the non-HDL particles discussed thus far (ie, VLDL, IDL, and LDL) share
the same components, including the apolipoprotein that mediates their principal
binding activity, Apo B. However, the same basic chemical components can
also be assembled into a very dense arrangement with a different membrane-spanning
apolipoprotein molecule, Apo A. These smallest particles, known as HDL
cholesterol,
are created by a process that is conceptually the reverse of the VLDL ->
IDL -> LDL sequence.
Like
the non-HDL particles, nascent HDL particles are assembled in the liver
and intestine and are then secreted into the circulation as particles consisting
almost entirely of phospholipids and Apo A1. Because these nascent HDL
particles contain little or no cholesterol (ie, they have no central lipophilic
core), they appear flat, or discoid. The nascent HDL particle is thus primed
to remove cholesterol that it encounters in peripheral cells as it travels
through the circulation. |
Panel 8. The Maturation
of HDL
|
As
these nascent HDL particles move through the circulation, Apo A1 in the
HDL membrane binds with phospholipids from non-HDL particle membranes and
with phospholipids that are shed from those membranes when the core triglyceride-rich
lipoproteins are spilled out during hydrolyzation by LPL. Next, a free
fatty acid from lecithin is transferred to the unesterified cholesterol
that has been absorbed into the nascent HDL particle by the action of lecithin-cholesterol
acyl transferase (LCAT) and its activating cofactor, Apo A1. This free
cholesterol is then esterified (ie, combined with an alcohol and depleted
of water) by plasma LCAT and, because cholesterol esters are hydrophobic,
they move to the core of the lipoprotein, causing the HDL particle to assume
its mature spherical configuration.
HDL
and the Reverse Cholesterol Transport System
| As
discussed above, as the nascent HDL moves through the body, it removes
unesterified (free) cholesterol from peripheral cells, such as macrophages,
through the transfer of cholesterol across the cell membrane by the ABC1
transporter protein. The mature, spherical HDL particle, which contains
these cholesterol esters in its core, then returns to the liver and is
selectively taken up by the liver through the interaction of HDL with the
hepatic HDL receptor. This process is known as "reverse cholesterol
transport."
About
50% of the cholesterol esters in mature HDL particles will be delivered
to the liver through the HDL receptor. The other 50% are transferred by
cholesterol ester transfer protein from HDL to the Apo B-containing lipoproteins
VLDL, IDL, and LDL, and the "forward" transport of cholesterol recommences.
|
Panel 9. HDL and
the
Reverse Cholesterol Transport
System
|
The
Big Picture
| Thus,
if we now look at the entire sequence, we can see what happens to the food
on our plate, especially to the food rich in fats or saturated fats. Once
it is ingested, the chemical components are packaged and distributed throughout
the body for our metabolic needs; if taken in excess of these needs, they
are stored as body fat and atherosclerotic plaque in our arteries.
Now
we need to look more closely at the "black box" where most of these transformations
take place -- the liver. How do the fatty foods that we consume and that
enter the body as fatty globules known as chylomicrons become the various
forms of cholesterol that ultimately, in excess, can become the underlying
cause of death?
In
short, how are the fatty acids in our food transformed in the liver into
the cholesterol in our circulation?
|
Panel 10. The
Big Picture
|
Understanding
the Synthesis of Cholesterol
| What
is cholesterol? Chemically, cholesterol is a "pearly, fat-like steroid
alcohol," meaning that the cholesterol molecule contains only carbon, hydrogen,
and oxygen atoms. This would mean it is similar to a sugar -- but it is
assembled as an alcohol -- except that it is hydrophobic, and thus acts
more like an oil.
This
sounds exotic, but cholesterol is nevertheless a very important molecule,
because it is found in animal fats and oils, in bile, blood, brain tissue,
milk, the yolk of egg, and the myelin sheaths of nerve fibers, as well
as in the liver, kidneys, and adrenal glands. In fact, cholesterol is a
constituent of all living animal cells.
As
might be expected for such an important molecule, cellular cholesterol
content is closely controlled by several mechanisms. Recall from Panel
4 that circulating plasma cholesterol levels correlate more with saturated
fat intake than with dietary cholesterol -- meaning that the cholesterol
that causes the atherosclerotic complications in the vasculature does not
enter the body as cholesterol; rather, it is actually synthesized by the
body -- in the liver -- from other chemicals. |
Panel 11. Understanding
the Synthesis of Cholesterol
|
So
what is the recipe for the synthesis of cholesterol? We need to know this
if we are going to understand how statins work to correct the problem of
too much cholesterol.
We
have seen that dietary fat is packaged by the intestines as chylomicrons--containing
the triglycerides, lipoproteins, and other components--which are, in turn,
secreted into the circulation to eventually enter the liver as chylomicron
remnants. These are the primary elements of food that are delivered to
the liver. However, the fats in these chylomicron remnants are only a small
part of the range of blood-borne bioactive chemicals that ultimately pass
through the liver. Most of the molecules that the body processes as food
are composed of complicated arrangements of a few basic atoms, usually
hydrogen (H), carbon (C), and oxygen (O). The increasingly intricate arrangements
of these atoms form distinct classes of molecules as they are metabolized
through a series of chemical reactions. The general order of these reactions
is to begin with a carbohydrate, progress to an alcohol, and finally to
an aldehyde.
Starting
from these few atoms and this cholesterol pathway, the liver cells eventually
produce mevalonic acid, or mevalonate. Mevalonate is a precursor
of 3 types of molecules: coenzyme Q (which is a group of related
quinones occurring in the lipid fraction of mitochondria and serving, along
with the cytochromes, as an intermediate in electron transport, similar
in structure and function to vitamin K1); squalene (an intermediate
in cholesterol synthesis in all animals examined); and cholesterol.
Between
the simpler molecules and mevalonate is a chemical known as 3-hydroxy-3-methylglutaryl
coenzyme A (HMG CoA). For HMG CoA to become mevalonate, it needs a catalyst,
called HMG CoA reductase. It follows that if the activity of this catalyst
can be inhibited, then the amount of mevalonate will be controlled, and
ultimately the amount of cholesterol that is produced will be controlled.
(In fact, HMG CoA reductase is the "rate-limiting enzyme" in the HMG CoA-to-mevalonate
reaction, because it is impossible to construct more mevalonate molecules
than there are HMG CoA reductase molecules to catalyze the reaction.)
Putting
HMG CoA Reductase Inhibitors Into Action
| As
discussed above, most of the cholesterol that courses through the circulation
does not enter the system directly from dietary sources. Rather, it is
synthesized in the smooth endoplasmic reticulum by means of a series of
chemical reactions that at one point are catalyzed by HMG CoA reductase.
As
we saw in Panel 11, the first way to block cholesterol synthesis is by
interrupting the conversion of HMG CoA to mevalonate (so that mevalonate
cannot generate cholesterol). In order for HMG CoA to become mevalonate,
the reaction must be catalyzed by the enzyme HMG CoA reductase. If this
enzyme is blocked, mevalonate cannot be generated and cholesterol cannot
be synthesized.
This
is the principal mechanism of action of the most popular and most effective
of the "cholesterol-blocking" medicines, the HMG CoA reductase inhibitors,
which are collectively known as "statins." There is a whole family of statins
(see Panel 14) that, because of variations in their molecular structures,
produce their therapeutic effects in slightly different ways. |
Panel 12. Putting
HMG CoA Reductase Inhibitors Into Action
|
However,
there are 3 other ways, besides blocking the HMG CoA reductase enzyme,
that cholesterol can be removed from the circulation:
-
Receptor-mediated
endocytosis of LDL, whereby the liver cells, or hepatocytes, attach cholesterol
via LDL receptors on their membranes and remove it from circulation;
-
Selective
uptake of free cholesterol from inside the LDL particles; and
-
Cholesterol
efflux from plasma membrane to cholesterol acceptor particles (predominantly
HDL)
Logically,
if the number of cholesterol receptors in the liver is increased, then
the uptake of cholesterol in the liver will be increased. This occurs as
part of the body's regulatory mechanisms, because the number of LDL receptors
is carefully regulated in response to level of circulating cholesterol.
If the liver senses that circulating cholesterol levels are high, it increases
the number of LDL receptors on the liver cell surfaces, resulting in enhanced
receptor-mediated uptake and catabolism of circulating LDL and its clearance
from circulation.
Finally,
in addition to induction of the LDL receptors, another control mechanism
is to inhibit the synthesis of VLDL (a precursor of LDL, as seen in Panel
2) and apolipoprotein B (a constituent of all non-HDL particles, as seen
in Panel 2).
Improving
the Plasma Lipid Profile
| In
Panels 1-12, we saw how the food on our plates becomes the cholesterol
that is so important for the body's cellular structures, as well as how,
in excess, cholesterol can become an underlying cause of cardiovascular
disease. We also saw that it is not the cholesterol molecule per se that
concerns us, but rather the way that it is "packaged" into lipoprotein
particles for transport throughout the cardiovascular system.
As
we have seen, cholesterol does not enter the body directly from the food
we consume, nor is there a one-to-one relationship between dietary cholesterol
intake and plasma cholesterol levels. Rather, most of the cholesterol in
circulation is the result of hepatic activity that packages and repackages
dietary fat into lipoprotein particles for transport to the muscles and
fat storage depots of the body. This process involves a complex chemical
reaction that at one point requires a catalyst, HMG CoA reductase, to complete
the synthesis of cholesterol. If the activity of this enzyme is inhibited,
then the metabolism of lipids, and hence the plasma levels of cholesterol,
are reduced. |
Panel
13. Improving the Plasma Lipid Profile
|
As
discussed, there is a whole spectrum of these lipoprotein particles that
share basically identical components and structures but that differ crucially
in their size and density. Because the most readily available biological
analyses sort these subfractions according to these 2 parameters, plasma
cholesterol is categorized on a scale from "low density lipoprotein" (LDL)
to "high density lipoprotein" (HDL), and out of the spectrum of lipoprotein
particles, these are the 2 most important medically.
We
should also recall that not all lipoprotein particles have deleterious
effects: the smallest, densest particles, HDL, actually serve to remove
cholesterol from deposits in the circulatory system and return it to the
liver for further processing, a process termed "reverse cholesterol transport."
The
other important difference among the lipoprotein particles concerns which
apolipoprotein is embedded in the particle's membrane: the HDL particle's
membrane contains Apo A, whereas non-HDL particle membranes contain several
Apo B molecules. These membrane apolipoproteins mediate where and when
the particles bind and exchange their contents with the tissues of the
body as they carry out their roles in the fat and cholesterol transport
system.
All
of these lipoprotein subfractions are important in the maintenance of cardiovascular
health. However, when they occur in the wrong concentration in the wrong
part of the system, the particles are no longer processed through healthy
metabolic pathways, and the vasculature succumbs to the disease state of
atherosclerosis.
Targeting
Plasma Cholesterol Levels. In 1985, the National Heart, Lung, and Blood
Institute (NHLBI), a division of the US National Institutes of Health (NIH),
created the National Cholesterol Education Program (NCEP).
The purpose of the NCEP is to educate healthcare professionals and the
public about the benefits of lowering high blood cholesterol. Over the
years, the NCEP has published a series of protocols discussing and detailing
the plasma cholesterol levels that should be the targets for healthy individuals.
The most recent protocol, known as the third Adult Treatment Panel (ATP
III), was released earlier this year.
Ultimately,
it is the extremes of the lipoprotein spectrum -- LDL particles with Apo
B and HDL particles with Apo A -- that travel through our circulation and
can be measured in the doctor's office, and so it is these lipoprotein
subfractions that the patient must monitor. The target plasma cholesterol
levels defined by the ATP III are shown in Table 1.
Table
1. ATP III Classification of LDL, Total, and HDL Cholesterol
| LDL
Cholesterol (mg/dL) |
|
|
|
Optimal |
|
|
Near
optimal/above optimal |
|
|
Borderline
high |
|
|
High |
|
|
Very
high |
| HDL
Cholesterol (mg/dL) |
|
|
|
Low |
|
|
High |
| Total
Cholesterol (mg/dL) |
|
|
|
Desirable |
|
|
Borderline
high |
|
|
High |
Improving
Body Mass Index. As noted in the Introduction, the principal cause
of the dyslipoproteinemias is the intake of too much food, especially dietary
fats and saturated fats. Therefore, one of the major risk factors for CVD
is excess body weight.
Body
weight is a function of body size: a large person will logically have a
greater body weight than a small person. However, the mathematical ratio
of body size to body weight, or body mass index (BMI), is relatively constant.
To determine BMI, a person's weight in kilograms is divided by height in
meters, squared, or
BMI
= body weight (kg)/height (m)2
For
example, for a person 6 feet tall who weighs 210 pounds, the BMI can be
calculated as:
BMI
= 95.3 kg/ (1.83 m)2 = 28.5
The
spectrum of BMI values are then categorized in Table 2.
Table
2. Categorization of Body Mass Index (BMI)
| |
BMI |
| Healthy
body weight |
20
- 25 |
| Overweight |
>
25 |
| Mild
obesity |
27
- 30 |
| Moderate
obesity |
>
30 </= 35 |
| Morbid
obesity |
>
35 </= 50 |
Being
overweight is a risk factor for almost every disease state known, and calculation
of a person's BMI is a relatively easy way to take body size into consideration
when assessing whether that person is overweight. Given a person's height
and looking at the desirable BMI, it becomes easy to determine which range
of body weight will maintain that patient within the desirable BMI range.
As soon as a patient's BMI is outside of the healthy range, the patient
should seriously address his or her dietary habits.
Making
Lifestyle Changes. Controlling food intake is only one of the parameters
in controlling body weight, however. It is true that mass consumed tends
to end as mass in the body -- unless that mass is converted to energy.
If we recall Einstein's famous physical formula:
E =
mc2
then
this should remind us that if the chemical components of food are "burned"
to fuel the activity of the muscles, they cannot be accumulated as fat.
Therefore, the other way to avoid the unhealthy status of overweight is
by consuming the food calories in the muscles as fuel, instead of sending
those calories to the body's fat depots for storage.
Even
in the absence of overconsumption, a sedentary lifestyle will store food
calories in fat depots instead of burning them, and a "healthy" level of
activity does not require a rigorous exercise regimen. Twenty minutes of
activity as mild as walking fairly briskly will be sufficient to appropriately
apportion the food contents of a proper diet to fuel vs storage.
Finally,
smoking is a known risk factor for CVD. It is beyond the scope of this
review to discuss the ways that inhalation of carcinogens damages the endothelium,
and the harmful effects of smoking are independent of the effects of excess
cholesterol. Nevertheless, along with proper diet and adequate exercise,
smoking cessation is an imperative to avoid CVD.
Pharmacologic
Intervention. These are the fundamental principles for avoiding CVD:
diet, exercise, and smoking cessation. However, as acknowledged in the
Introduction, these principles are not always followed, nor are they necessarily
adequate. Therefore, if the target cholesterol levels and BMI ratios listed
in the tables above cannot be attained, the individual should obtain medical
counseling, which will probably suggest the addition of medical therapy
to a regimen of better diet and exercise.
The
figure lists the various interventions and the effects that they have on
the 2 most important cholesterol subfractions, LDL and HDL. There are several
classes of pharmacologic agents that have proven effective as therapy.
All of these drugs modify plasma cholesterol and triglyceride concentrations
in the healthy direction, with the exception of bile acid sequestrants,
which appear to have no effect on plasma triglyceride levels or may even
have a negative effect by elevating them. The differences among these agents
are primarily in the degree to which they change the plasma lipid levels,
their contraindications, and their side-effect profiles.
Bile
acid sequestrants lower LDL moderately (15% to 30%) and raise HDL very
little (3% to 5%). They are absolutely contraindicated in cases of dysbetalipoproteinemia
(high levels of Apo B, usually an inherited disorder) or for extremely
high triglyceride levels (> 400 mg/dL; should be used with caution when
triglycerides > 200 mg/dL). The side effects include gastrointestinal problems
such as constipation; they may also decrease the absorption of other drugs.
Nicotinic
acid lowers LDL slightly (5% to 25%), raises HDL nicely (15% to 35%),
and lowers triglycerides significantly (20% to 50%). It cannot be used
in cases of chronic liver disease or severe gout. Side effects include
an unpleasant degree of facial flushing, induction of hyperglycemia or
hyperuricemia (gout), some degree of hepatotoxicity, and upper gastrointestinal
distress.
Fibric
acids slightly lower LDL (5% to 20%), slightly raise HDL (10% to 20%),
and significantly lower triglycerides (20% to 50%). They cannot be used
in cases of severe renal or hepatic disease. Side effects include dyspepsia,
gallstones, and myopathy.
Finally,
there is the most successful class of lipid-lowering agents, the 3-hydroxy-3-methylglutaryl
coenzyme A reductase inhibitors, or "statins."
HMG
CoA Reductase Inhibitors
| Numerous
large clinical trials have established that an excess of plasma cholesterol,
when uncontrolled, will lead to a series of insults to the circulatory
system that results in cardiovascular disease and ultimately, if untreated,
death. Conversely, control of plasma cholesterol levels to within the ranges
established by several published guidelines has been shown to significantly
decrease the morbidity and mortality of CVD.
All
of the current guidelines are based on a series of large, well-controlled
clinical trials testing lipid control agents, for the most part statins,
against the absence of trial drug. The first of the lipid-lowering trials
were the Scandinavian Simvastatin Survival Study (4S), with simvastatin,
and the Cholesterol and Recurrent Events (CARE) trial, with pravastatin.
The primary finding of both these trials was that lowering LDL cholesterol
in patients at risk for CVD to within the range advocated by subsequent
guidelines (see Table 1 in Panel 13) will significantly decrease the number
of deaths from coronary artery disease. Subsequently, both the West of
Scotland Coronary Prevention Study (WOSCOPS) and the Air Force/Texas Coronary
Atherosclerosis Prevention Study |
Panel 14. HMG
CoA Reductase Inhibitors
|
(AFCAPS/TexCAPS)
found that using a statin to lower plasma cholesterol levels produced a
significant reduction in coronary events, even in subjects without clinically
evident CVD.
Further
clinical trials have refined the definition of a "healthy" lipid profile.
Post hoc analysis of the 4S results found that patients with the "lipid
triad" (high LDL, low HDL, high triglycerides) had a worse prognosis than
patients with isolated elevated LDL. The Post Coronary Artery Bypass Graft
(Post-CABG) trial found that lowering LDL to an aggressive target (<
100 mg/dL) resulted in significantly fewer clinical events than lowering
to a more modest target (to 132-136 mg/dL). (On the other hand, subsequent
analysis of the CARE and the WOSCOPS results has suggested that there is
diminishing benefit in lowering LDL to levels below 100 mg/dL.) And the
AFCAPS/TexCAPS study found that of all the lipid parameters assessed, low
levels of the HDL apolipoprotein, Apo A-1, was the most consistent predictor
of risk of future events.
Therefore,
good medical practice dictates that all people should maintain plasma levels
of the various lipoprotein subfractions (LDL, HDL, Apo B, Apo A-1, triglycerides)
within the limits set by the NCEP guidelines, as referred to above. When
a lifestyle that includes a properly balanced and apportioned diet, plus
adequate physical activity, does not succeed in achieving these target
levels, then therapeutic intervention with a lipid-modifying pharmacologic
agent should be considered. As discussed, the ideal anti-atherosclerotic
agent would do 3 things:
-
lower
LDL
-
lower
triglycerides
-
raise
HDL
As we
have seen, the primary action of the statins is to inhibit the HMG CoA
reductase enzyme, thus preventing the synthesis of cholesterol in the liver.
This, in turn, leads to an increase in the number LDL membrane receptors,
thereby increasing clearance of LDL from the circulation. Statins are the
most effective agents for lowering LDL cholesterol, are moderately effective
for lowering triglyceride levels, and have been shown to be mildly effective
in raising HDL levels. They thus achieve all 3 results desired of the "ideal"
agent.
Statins
have 2 principal deleterious side effects: increased liver enzymes (statins
are absolutely contraindicated in patients with active or chronic liver
disease) and myopathy. The true incidence of the latter side effect is
still unknown at this time, but the occurrence of rhabdomyolysis (characterized
by muscle weakness or pain and elevation of muscle creatine kinase enzyme
levels) has been identified as a cause of death in a small number of patients
taking one of the statins, cerivastatin, which has resulted in the withdrawal
of this drug from the market worldwide (as indicated in the figure).
Nevertheless,
the efficacy of HMG CoA reductase inhibition has been so clearly established
that the current guidelines unambiguously recommend the addition of an
agent in the statin "class" for control of hypercholesterolemia in all
cases except where clearly contraindicated. As long as physicians are aware
of the signs and symptoms of untoward reactions, statins should continue
to be viewed as extremely effective and well tolerated in the majority
of patients.
There
remains the question whether any statin is functionally the same as any
other -- in other words, whether the beneficial effects shown in the large
clinical trials by some of the early statins can be generalized to the
other statins as a "class" effect. The class effect of statins is associated
with their primary mode of action, enzyme inhibition, as assessed by their
measured effects on LDL (or non-HDL) and HDL cholesterol as well as on
triglyceride levels and (in more sophisticated analyses) on Apo B levels.
The differences among the statins at this time therefore are principally
in the degree to which they affect enzyme levels. The complete safety profile
and other effects -- for example, the amount of atherosclerosis regression
(as opposed to just LDL lowering) -- have yet to be reported across the
class of statins.
In
light of the new NHLBI treatment goals, the principal treatment goal for
patients with elevated cholesterol levels should be to reduce LDL levels
to within the ranges specified in the ATP III guidelines as quickly as
possible, with as few dose adjustments as necessary. The desirability of
avoiding dose titrations is especially important, since there is often
a reluctance on the part of clinicians to up-titrate statin doses for fear
of increased side effects. However, since currently available information
does not suggest significant differences among the statins in terms of
safety and side-effect parameters, the need to effectively lower LDL at
the starting dose is emphasized.
Panel
14 details the relative efficacies of the statins currently marketed in
the United States for lowering the principal unhealthy subfraction, LDL
cholesterol. The newer statin formulations (atorvastatin, currently marketed;
rosuvastatin, expecting approval in mid 2002) appear to be the most effective
on a per dosage basis in lowering LDL cholesterol. However, recall that
the goal is to reduce the total non-HDL cholesterol burden in the circulatory
system. This can be achieved both by lowering plasma LDL cholesterol levels
directly, and also indirectly, by raising HDL levels in order to maximize
the "reverse cholesterol transport." The newest of these statins, rosuvastatin,
appears to be mildly effective for raising HDL across the full range of
doses (10 to 80 mg), whereas the currently most effective statin, atorvastatin,
appears to raise HDL levels less at increasing doses.
Conclusion
At the
beginning of the 21st century, the worldwide health of humanity is undergoing
a fundamental shift. With the economic progress, however defined, of the
previous 50 years, the incidence of infectious diseases and malnutrition,
although still the primary causes of death outside of the developed world,
is declining. Although human immunodeficiency virus (HIV) remains a serious
and increasing subset of infectious disease, on a percentage basis HIV
is a problem that affects only a very small proportion of humankind. Set
against these 2 worldwide health problems is the problem of tobacco use
and its principal manifestation, cardiovascular disease. Within 20 years,
1 out of every 3 humans will die of CVD. This represents a "pandemic" of
epic proportions that, if not addressed, much less controlled, will strain
all public healthcare expenditures and fundamentally challenge the ability
of the world's governments to provide or promote what the developed world
considers to be an acceptable standard of living.
Thus,
it is clear that humanity faces a potential healthcare catastrophe. Avoiding
this bleak future will require alterations in individual behavior (to include
proper diet and weight control, adequate activity and exercise levels,
and avoidance of all forms of the tobacco habit), a dedication of public
policy toward aiding and promoting these individual goals, and continued
education of the medical profession and development of lipid-lowering drugs
to ameliorate the problem when behavior and public policy fall short of
their imperatives. Clearly the "statins," as a class, are a successful
contribution to this task, but there is still much to be done.
Stopping Statins Can Be Deadly
For Certain Patients, Discontinuing Drugs Can Mean Increased Risk of
Heart Attack, Death
By: Jennifer
Warner
WebMD Medical News
March 4, 2002 -- Stopping cholesterol-lowering statin drug therapy in
people with heart disease can dramatically increase their risk of death.
A new study found patients who discontinued using the drugs when they were
hospitalized for chest pain were three times as likely to have a heart
attack or die than those who kept taking their medication.
Researchers say the study adds evidence that statins may do more than
just lower cholesterol, and that the drugs may protect the heart in other
important ways. For example, recent research has shown that statins can
reduce harmful inflammation in the arteries that can lead to blood clots.
But this study, published today in Circulation: Journal of the American
Heart Association, also supports the idea that statins increase the release
of protective nitric oxide in the inner walls of the heart. Animal
research has shown that when the statins are suddenly withdrawn, a rebound
effect occurs, and the nitric oxide levels drop below normal -- increasing
the risk of heart attack or other cardiac events.
A human study to test this rebound effect would be unethical, but
researchers were able to show a similar withdrawal effect in humans by
looking at medical records of patients who'd been enrolled in an international
heart disease trial.
Of the 465 patients who had been taking a statin drug for six months when
admitted to the hospital for chest pains, 379 continued taking the drug,
and
86 stopped. After 30 days, researchers looked at the number of patients
who died or suffered a heart attack.
People who were kept on their statin medication had half the risk of death
or
a nonfatal heart attack than those who had never taken a statin drug. Those
who stopped using statins after hospitalization had nearly three times
the
risk compared with those who continued using their medication.
"The increase in deaths and acute heart attacks was only explained by the
statin withdrawal," says study author Christian W. Hamm, MD, of the
Kerckhoff Heart Center in Bad Nauheim, Germany in a news release.
In addition, significantly more patients who had stopped statin therapy
required additional procedures to restore blood flow within one week after
hospitalization.
Hamm says there is no particular medical rule suggesting that hospitalized
patients should discontinue statin drugs, so the physicians must have either
assumed the statins were no longer beneficial or just forgot to continue
the
patients on the therapy.
"The message to physicians is: Don't stop statins," says Hamm.
Three statin drugs accounted for about 95% of those prescribed in the study
and included Zocor, Mevacor, and Pravachol.
Medically Reviewed
By Charlotte Grayson
http://my.webmd.com/content/article/1756.50193
