Sports Nutrition: Fat as an Energy Source During Exercise (PDF)

Summary

This document is a chapter from a textbook on sports nutrition, focusing on the importance of fat as an energy source during exercise. It details the different types of fats, their sources, and how the body utilizes them for energy. The chapter also includes information on fat substitutes and cholesterol.

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Chapter 05
Fat: An Important
Energy Source during
Exercise
Williams’ Nutrition for
Health, Fitness and
Sport
Thirteenth Edition
Eric S. Rawson, J. David
Branch, Tammy J. Stephenson

© McGraw Hill LLC. All rights reserved. No reproduction or distribution without the prior written consent of McGraw Hill LLC.
 Dietary Fats

Dietary fat is the nutrient of greatest concern to
the American Heart Association because of the
association of certain types of fat with coronary
heart disease.
Dietary fat is an important energy source for
endurance-type sport events.

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 What are the different types of dietary fats?

Triglycerides.

Cholesterol.

Phospholipids.

Specific fatty acids:
Omega-3 fatty acids.

Omega-6 fatty acids.

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 What are triglycerides?

An ester of glycerol (alcohol) and 3 fatty acids.

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 Types of Fatty Acids

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 What are some common foods high in fat
content?

Obviously high-fat content:
Butter, oils, shortening, mayonnaise, margarine,
and the visible fat on meat.

Hidden fat:
Whole milk, cheese, nuts, desserts, crackers,
potato chips, and many commercially prepared
foods.

In general, animal foods tend to contain more total
fat and saturated fat than plant foods.

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 Fatty Acids in Common Oils and Fats

Note that fats are also typically rich in monounsaturated fatty acids (40–50% of total fatty acids).
*Rich source of the omega-3 fatty acid alpha-linolenic acid (7% and 12% of total fatty acid
content for soybean oil and canola oil, respectively).
**Natural trans fatty acids in butter are not harmful.

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 How do I calculate the percentage of fat kcal in
a food?

Advertised percentage refers to the weight of the product,
not its caloric content (water has no kcal).
To determine the percentage of calories from fat in a
product like the one below, divide calories from fat by
total calories.

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 What are fat substitutes?

Fat substitutes are designed to provide the taste
and texture of fats, but without the kcal, saturated
fat, or cholesterol.
May be manufactured from carbohydrate, protein, or
fat and may contain 0 to 4 kcal per gram.
Some examples:
Simplesse.
Salatrim.
Olestra.

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 What is cholesterol and what foods contain
cholesterol?

Cholesterol:
Not a fat, but a sterol.
Not an essential nutrient because it is
manufactured in the liver.

Cholesterol is found only in animal products:
Protein foods including beef, pork, poultry, fish,
shellfish, and eggs.
Dairy products including milk, butter, cream
cheese, and ice cream.
Bread/cereal products prepared with animal
products (that is, biscuits, pancakes, etc. made
with milk and/or eggs).
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 What are phospholipids and what foods contain
phospholipids?

Not essential.
The body can make
them from
triglycerides.

Egg yolks provide
substantial amounts of
lecithin.
Other good sources
include liver, wheat
germ, and peanuts.

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 How much fat and cholesterol do we need in
the diet?

We need fat for three reasons:
To meet energy needs.
To provide essential fatty acids.
To provide essential fat-soluble vitamins.

Important during growth and development years.

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 Dietary Fat: Dietary Reference Intakes 1

Total fat:
An A M D R of 20 to 35 percent of daily energy
intake.
No R D A, A I, or U L have been set, but diets
greater than 35 percent total fat are not
recommended.

Saturated fatty acids and trans fatty acids:
No R D A, A I, or U L have been developed.
Health professionals recommend maximum of 7 to
10 percent of daily energy needs.

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 Dietary Fat: Dietary Reference Intakes 2

Cis monounsaturated fatty acids:
No R D A, A I, or U L developed.
Some health professionals suggest these are good
fats.
Cis polyunsaturated fatty acids:
Linoleic acid is an essential omega-6 fatty acid (A I:
17 g for adult males, 12 g for adult females).
Alpha-linolenic acid is an essential omega-3 fatty
acid (A I: 1.6 g for adult males, 1.1 grams for adult
females).
Cholesterol:
By following a diet low in saturated fats, cholesterol
intake will likely be between 100 and 300 mg/day.
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 Consequences of Excessive Consumption of
Dietary Fat and Cholesterol

Chronic diseases:
May be linked to heart disease.
May be linked to obesity.

Impaired physical performance:
May displace carbohydrates in the diet.
May lead to excess caloric intake and body weight.
May cause gastrointestinal distress as part of a
pregame meal.

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 Metabolism and Function How does dietary fat
get into the body?

About 98 percent of dietary fat consists of
triglycerides.
About 2 percent consists of sterols and
phospholipids.
Bile salts and lipases digest dietary lipids into
free fatty acids (F F As), glycerol, cholesterol, and
phospholipids.
Absorbed into intestinal cell; form a
chylomicron, which enters the lymphatic
system.
Some fatty acids (from M C Ts) go directly to the
liver.
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 Summary of Fat Digestion and Absorption

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 Schematic of a Lipoprotein

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 Absorption of Lipids

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 What happens to the lipid once it gets into the
body?

Circulate in the body as chylomicrons.
Lipids deposited in body cells for storage as
triglycerides.
Fat or adipose cells.
Muscle cells (IMTG—intramyocellular
triacylglycerol).

Liver continues to modify the composition of the
lipoproteins.

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 What are the different types of lipoproteins?

Very low-density lipoproteins (V L D L):
Mainly triglycerides; provide fatty acids and glycerol to
cells.
Low-density lipoproteins (L D L):
High proportion of cholesterol and phospholipids, but
little triglycerides.
Delivers cholesterol to cells.
Small dense LDL of health concern.
High-density lipoproteins (H D L):
40 to 50 percent protein.
Transport cholesterol from cells to liver.
Lipoprotein (a):
Similar to L D L, in the upper L D L density range.
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 Content of Lipoproteins

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 Fat Metabolism

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 Can the body make fat from protein and
carbohydrate?

Fatty acids are polymers of acetyl C o A.
Amino acids may be converted into acetyl C o A,
which can then be converted into fat.
Carbohydrates may be converted into fat via acetyl
C o A.

It is not what you eat, but how much, that determines
if you will gain body fat.

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 What are the major functions of the body
lipids?

Structure:
Component of cell membranes.
Form myelin, an important component in the sheath
covering nerve fibers.
Function as insulators to conserve body heat and shock
absorbers to protect organs.
Metabolic regulation:
Essential F F A involved in intracellular metabolic
pathways.
Cholesterol is part of some hormones.
Adipose cells produce adipokines (adipocytokines),
such as leptin, that influence metabolic processes.
Eicosanoids possess local hormone-like properties.
Energy source.
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 Fats as an Energy Source

Fat produces energy only by aerobic processes.
Fat provides about 60 percent or energy at rest.
Triglycerides yield.
Glycerol, which goes to the liver.
FFA, which may be oxidized for energy.

Ketones
By-products of excess fatty acid metabolism.
May be used for energy in cells.

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 How much total energy is stored in the body as
fat?

Fat is an efficient form of energy storage.
9 k cal per gram.
Very little water content.

Total amount of stored fat energy varies, but
approximately 80,000 to 100,000 k cal in the average
adult male with normal body fat.
Most fat is stored in the adipose cells; about 2,500 to
2,800 k cal are stored in triglycerides within and
between muscle cells.

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 Fats and Exercise Are fats used as an energy
source during exercise?

Fat energy sources.
Plasma chylomicrons and triglycerides: minor
source.
Adipose cell triglycerides.
Hormone-sensitive lipase released F F A.
Increases serum F F A for delivery to muscle.
Muscle cell triglycerides.
Enzyme similar to H S L releases F F A.
Use during exercise.
Plasma F F A into muscles is increased during
exercise.
Epinephrine stimulates F F A release from adipose
cell triglycerides to the muscle cell.
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 Fat as an Energy Source During Exercise

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 Fat Use During Exercise

Mild exercise @ 25 percent V O2 max:
About 80 percent or energy may come from fat.
Most plasma FFA come from the adipose tissue.
More intense exercise up to 65 percent V O2 max:
Fats and carbohydrates appear to contribute equally to the
energy expenditure.
Plasma FFA and muscle triglycerides contribute equally to the
energy derived from fats.
High-intensity exercise ≥85 percent V O2 max:
Carbohydrate is more important and fat use drops to ≤25
percent as muscle glycogen becomes the main source.
In general, FFA oxidation decreases as carbohydrate oxidation
increases with an increase in exercise intensity.

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 Fat Use During Exercise: Limiting factors

Inadequate F F A mobilization from adipose tissue
may limit delivery to the muscle.
Suboptimal metabolism of intramuscular processes
may limit fat oxidation.
Increased carbohydrate oxidation may inhibit fatty
acid oxidation.

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 Fat Use During Exercise: Dietary effects

Carbohydrate intake decreases fat oxidation.
Increased insulin may decrease lipolysis and fatty
acid oxidation in muscle.

Carbohydrate intake will help optimize endurance
exercise performance.
As carbohydrate levels diminish and F F A use
increases, exercise intensity decreases.

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 Does sex influence the use of fats as an energy
source during exercise?

Some studies report females may oxidize more fat
than males during submaximal exercise.
Other research notes no difference in carbohydrate
or fat metabolism during exercise in equally trained
subjects.

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 What effect does exercise training have on fat
metabolism during exercise?

Exercise induces adaptations that enhance fat
utilization and aerobic exercise performance.
Increased expression of genes in the skeletal
muscle that increase capacity for fat oxidation.
With training, more energy used in exercise is
derived from fat, sparing glycogen in muscle.
Increased content and use of muscle triglycerides.

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 Fats: Ergogenic Aspects

Strategies or supplements proposed to be ergogenic:
High-fat diets.
Fasting.
Infusion of lipids into the bloodstream.
Medium-chain triglycerides (MCTs).
Lecithin.
Glycerol.
Omega-3 fatty acids or fish oil.
Hydroxycitrate.
Conjugated linoleic acid.
Phosphatidylserine.
Ketones.
Caffeine.

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 High-Fat Diets

Theoretical mechanism to help delay onset of fatigue.
Elevated serum F F A levels and muscle triglyceride
levels.
Increase the percentage use of fat as an energy
source during exercise.
Spare the use of muscle glycogen.

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 Acute High-Fat Diets

Acute high-fat diets (fat loading):
Infuse a lipid solution, with heparin.
Ingest a high-fat meal prior to exercise.
Ingest a high-fat diet for 1 to 2 days prior to
exercise.

Research findings:
Acute high-fat diets do not enhance aerobic
endurance performance and may impair
performance if they contribute to GI distress.
Some research indicates consuming a high-fat diet
for 1 to 2 days may impair performance in high-
intensity exercise tasks.
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 Chronic High-Fat Diets

Chronic high-fat diets:
50 percent or more energy from fat.

Research findings:
Athletes will increase their muscle triglyceride
levels and may increase the use of fat and
decrease use of carbohydrate during exercise.
When an individual is placed on a chronic high-fat
diet (1 week or more), the body adjusts its
metabolism to use fats more efficiently.
Metabolic improvements do not necessarily
correlate with or guarantee performance
improvements.
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 Chronic High-Fat Diets—Ergogenic Effect

Few studies support an ergogenic effect of chronic fat
loading.
Increased exercise time to exhaustion at moderate
intensity.
Faster time in cycling time trial.
Greater fat utilization and sparing of muscle
glycogen.

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 Chronic High-Fat Diets—No Ergogenic Effect

Well-controlled research suggests that chronic high-
fat diets do not benefit endurance performance.
No effect on cycling endurance or performance.
Some evidence for enhanced ultra endurance
cycling with a high-fat diet compared to a high-
carbohydrate diet, though the main effects were
not significant.
In several studies, there was greater fat utilization
and sparing of muscle glycogen.
Studies of ketogenic diets have shown performance
impairment.
May impair cognitive function, speed, and mood.
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 High-Fat Diets and Weight Loss

The long-term impact of a low-carbohydrate and
high-fat (ketogenic) diet on weight loss in those
with overweight or obesity unknown.
When it comes to weight loss, kcal matters more
than macronutrient distribution.
Long-term effects on health outcomes (cancer and
other diseases).

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 Does exercising on an empty stomach or
fasting improve performance?

Fasting may increase serum F F A availability and
theoretically, increase fat oxidation, spare
glycogen, and improve performance.
If fasting reduces muscle glycogen or causes
hypoglycemia, it may impair performance.
Fasting may encourage greater weight loss, either
through metabolic adaptations or reductions in
appetite.

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 Can the use of medium-chain triglycerides (M C
Ts) improve endurance performance or body
composition?
Theory as an ergogenic aid:
Rapid absorption into portal circulation.
Rapid uptake by mitochondria in muscle cells.
Do not inhibit gastric emptying.
May be absorbed rapidly in small intestine.
May be oxidized at a rate similar to exogenous
glucose.

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 Ergogenic Effects of M C Ts: Research Findings

One study found that carbohydrate-M C T
supplement improved performance by decreasing
oxidation of muscle glycogen.
Most studies have shown no benefits of
supplementation with M C T or M C T combined
with carbohydrate.
Some report impaired performance with M C T
supplementation.
May also cause gastric distress in some individuals.

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 Is the glycerol portion of triglycerides an
effective ergogenic aid?

Theory as an ergogenic aid:
Exogenous glycerol may be converted to glucose
and be an efficient energy source during exercise.

Research findings:
Glycerol does not affect endurance performance.
The rate of conversion by the liver may be too
slow.

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 Omega-3 fatty acid and fish oil supplements

Populations who eat a diet high in these fatty acids
have decreased risk of cardiovascular disease.
Potential anti-inflammatory effect of E P A and D H
A.
May enhance blood flow.
May improve cognitive processing and reduce the
damage and cognitive decline associated with
concussion.
May increase protein synthesis, decrease muscle
soreness.
No effect on glucose or lipid energy metabolism.
No effect on aerobic endurance.
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 Can carnitine improve performance or weight
loss?

L-carnitine may help increase a specific enzyme
that facilitates transport of long-chain fatty acids
into mitochondria, which could increase fat
oxidation.
Research does not support an ergogenic effect of
supplementation.

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 Carnitine Effects on Performance

May increase plasma levels, but not muscle
concentration of carnitine.
No effect on fat oxidation.
May reduce markers of metabolic stress and
perceived muscle soreness, suggesting they
promote recovery from resistance exercise.
No effect on weight loss.

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 Can hydroxycitrate (H C A) enhance endurance
performance?

Theory as an ergogenic aid:
Modify citric acid cycle metabolism to promote
fatty acid oxidation.

Research findings:
Does not enhance endurance performance in
humans.
No effect on fat metabolism during exercise in
either sedentary or endurance-trained cyclists.
No benefit of H C A on weight loss, fat oxidation, or
appetite.

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 Can conjugated linoleic acid (C L A) enhance
exercise performance or weight loss?

Theory as an ergogenic aid:
Marketed as a means to decrease body fat and
increase lean muscle mass in resistance-trained
athletes.
Research findings:
Research with trained athletes is limited, but
indicates C L A supplementation has no effect total
body mass, fat mass, fat-free mass, or strength
tests in resistance-trained athletes.
Effects on health are discussed later in this
chapter.

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 Can ketone supplements improve endurance
performance?

Some research with cyclists
shows improved
performance, while other
research shows impaired
performance.
Poor gastrointestinal
tolerance.

@Fuse/Getty Images

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 What’s the bottom line regarding the ergogenic
effects of fat-burning diets or strategies?

Endurance exercise capacity is not improved with
increased serum F F A availability and fat
oxidation.
High-fat diets may impair exercise performance.
Difficult to adhere to a high-fat diet.

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 Dietary Fats and Cholesterol: Health
Implications

Dietary fat as a risk factor for chronic diseases may
be associated with the amount and type of fat.
A diet moderate in total fat reduces risk of chronic
disease.
The key is moderation.

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 How does cardiovascular disease develop?

A number of cardiovascular diseases.
Coronary heart disease (#1 cause of death):
obstruction of the blood flow in the coronary
arteries leading to heart attack.
Stroke.
Hypertensive disease.
Rheumatic heart disease.
Congenital heart disease.

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 The Heart and Coronary Arteries

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 Coronary Heart Disease

Arteriosclerosis:
Arterial walls thicken
and lose their
elasticity.

Atherosclerosis:
Associated with
formation of
plaque.

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 The Developmental Process of Atherosclerosis
and Thrombosis

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 How do the different forms of serum lipids
affect the development of atherosclerosis?

Total cholesterol (lower is better).
L D L-cholesterol (lower is better).
H D L-cholesterol (higher is better).
Triglycerides (lower is better).
Cholesterol ratios:
T C/H D L: 4.5 is average risk; lower is better.
L D L/H D L: 3.5 is average risk; lower is better.

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 Serum Lipid Factors Associated with Increased
Risk of Atherosclerosis

High levels of total cholesterol.
High levels of L D L-cholesterol.
High levels of dense form of L D L-cholesterol.
High levels of I D L-cholesterol.
High levels of abnormal lipoprotein, lipoprotein (a).
High levels of apolipoprotein B.
High levels of triglycerides.
Low levels of H D L-cholesterol.
Low levels HDL
of 2-cholesterol.
Low levels of apolipoprotein A-I.

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 National Cholesterol Education Guidelines:
Lipoprotein profile 1

Total cholesterol:
Less than 200: Desirable.
200 to 239: Borderline high.
240 or above: High.

H D L-cholesterol:
Less than 40: Low.
60 or above: Protective.

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 National Cholesterol Education Guidelines:
Lipoprotein profile 2

L D L-cholesterol:
Less than 100: Optimal.
100 to 129: Near optimal.
130 to 159: Borderline high.
160 to 189: High.
190 and above: Very high.

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 National Cholesterol Education Guidelines:
Lipoprotein profile 3

Triglycerides:
Less than 150: Normal.

151 to 199: Borderline high.

200 to 499: High.

500 and above: Very high.

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 Can I reduce my serum lipid levels and possibly
reverse atherosclerosis?

Research suggests for each 1 percent reduction in
serum LDL-cholesterol, there is a 1 percent reduction
in risk of coronary heart disease.
Healthier lifestyle.
Diet.
Exercise.

Drugs.
Statins inhibit an enzyme that regulates
cholesterol.

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 D A S H Eating Plan Recommended changes
using the D A S H eating plan to help lower
blood pressure and L D L

Source: NIH.

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 Guidelines on the Management of Blood
Cholesterol
1. In all individuals, emphasize a heart-healthy lifestyle across the life course.
2. In patients with clinical A S C V D, reduce low-density lipoprotein cholesterol (L D L-C)
with high-intensity statin therapy or maximally tolerated statin therapy.
3. In very high-risk A S C V D, use a L D L-C threshold of 70 mg/dl to consider addition of
non-statins to statin therapy. Very high-risk includes a history of multiple major A S C V D
events or 1 major A S C V D event and multiple high-risk conditions.
4. In patients with severe primary hypercholesterolemia (L D L-C level ≥190 mg/dl), without
calculating 10-year A S C V D risk, begin high-intensity statin therapy.
5. In patients 40 to 75 years of age with diabetes mellitus and L D L-C ≥70 mg/dl, start
moderate-intensity statin therapy without calculating 10-year A S C V D risk.
6. In adults 40 to 75 years of age evaluated for primary A S C V D prevention, have a
clinician–patient risk discussion before starting statin therapy.
7. In adults 40 to 75 years of age without diabetes mellitus and with L D L-C levels ≥70
mg/dl, at a 10-year A S C V D risk of ≥7.5%, start a moderate-intensity statin if a
discussion of treatment options favors statin therapy.
8. In adults 40 to 75 years of age without diabetes mellitus and 10-year risk of 7.5% to
19.9% (intermediate risk), risk-enhancing factors favor initiation of statin therapy (see
No. 7).
9. In adults 40 to 75 years of age without diabetes mellitus and with L D L-C levels ≥70
mg/dL to 189 mg/dl, at a 10-year A S C V D risk of ≥7.5% to 19.9%, if a decision about
statin therapy is uncertain, consider measuring C A C.
10.Assess adherence and percentage response to L D L-C–lowering medications and
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 Sensible Plan to Monitor the Effects of a
Cholesterol-Lowering Diet

Source: U.S Department of Health and Human
Services.
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 Results of Switching to the Step 1 Diet

Olga Nayashkova/Shutterstock
Source: U.S. Department of Health and Human
Services.
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 Essential Fatty Acids

Polyunsaturated fatty acids should constitute about
10 percent of daily caloric intake.
This should provide adequate amounts of omega-6
and omega-3 fatty acids.

Omega-3 fatty acids (more important for the
prevention of C H D than omega-6).
Eicosapentaenoic acid (E P A).
Docosahexaenoic acid (D H A).

Found mainly in fish oils.

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 Grams of E P A and D H A in Fish (per 3 oz
portion) and Fish Oils (per gram)

>1 gram 0.5 to 1.0 gram