Marieb Human Anatomy & Physiology: Nutrition, Metabolism, and Energy Balance PDF

Summary

This chapter from Marieb Human Anatomy & Physiology, Twelfth Edition, focuses on the subjects of Nutrition, Metabolism, and Energy Balance. The chapter explores the important roles of various macronutrients such as carbohydrates, lipids, and proteins, as well as micronutrients like vitamins and minerals. It details their utilization in the body and their significance in maintaining health.

Full Transcript

Marieb Human Anatomy & Physiology
Twelfth Edition

Chapter 24
Nutrition, Metabolism, and
Energy Balance

PowerPoint® Lecture Slides
prepared by Justin A. Moore,
American River College

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Video: Why This Matters (Career
Connection)
Understanding the process of how the body converts
nutrients into energy can help you effectively advise your
patients on dietary choices that will allow their bodies to
operate at peak performance

Click here to view ADA compliant video:
Why This Matters (Career Connection)

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Part 1—Nutrients

Nutrient: substance in food needed for growth, maintenance, repair
– Five categories
▪ Three macronutrients that make up most of our diet
– Carbohydrates, lipids, and proteins
▪ Two micronutrients that are equally important, but requirements are small
– Vitamins and minerals
– Most nutrients used for metabolic fuel, some for building molecules and cells
Water also needed; accounts for ~ 60% by volume of the food we eat
Essential nutrients: ~ 40 molecules must be provided by diet
– We can’t synthesize them in adequate amounts, like the hundreds of other
nonessential nutrients we require
▪ Cells (especially liver cells) have ability to convert one type of molecule to
another; interconversions allow us to adjust to varying food intakes

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Part 1—Nutrients
Energy value of nutrients measured in kilocalories (kcal)
– One kcal is amount of heat needed to raise temperature of 1 kg H2O by 1 C
▪ 1 kcal = one calorie (C)
– Carbohydrates and proteins have 4 kcal/g, but lipids have almost 9 kcal/g
USDA’s MyPlate: guidelines represented as portions on a dinner plate
– Food groups represented:
▪ Fruits
▪ Vegetables
▪ Grains
▪ Protein
▪ Dairy
Basic dietary principles:
– Eat only what you need
– Eat plenty of fruits, vegetables, and whole grains
– Avoid junk food

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USDA’s My Plate Food Guide

Figure 24.1 USDA’s MyPlate food guide

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24.1 Carbohydrates, Lipids, and
Proteins Supply Energy and Are
Used as Building Blocks

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Carbohydrates

Dietary sources
– Mostly plants, except for milk sugar (lactose) and small
amounts of glycogen
– Sugars (mono- and disaccharides): fruits, sugarcane,
sugar beets, honey, milk
– Starch (polysaccharide): grains and vegetables
– Insoluble fiber (the cellulose we can’t digest in
vegetables) provides roughage that increases bulk of
stool and facilitates defecation
– Soluble fiber (like pectin in apples and citrus) reduces
blood cholesterol levels

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Carbohydrates

Uses in the body
– Glucose is the carbohydrate molecule used by cells to
make ATP
▪ Fructose and galactose converted to glucose by liver
before entering circulation
▪ Many cells also use fats for energy, but neurons and
RBCs rely almost entirely on glucose (neurons die
quickly without it)
▪ Excess glucose converted to glycogen or fat (for later
use)
– Other uses: building nucleic acids (with pentose sugars)
and cell’s glycocalyx (with short chain sugars)

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Carbohydrates

Dietary requirements
– Recommended daily intake is 45–65% of total calories
▪ Typical American adult at 46%
– Should consist mostly of complex carbohydrates (whole
grains and vegetables) rather than simple (monosaccharides
and disaccharides)
▪ Eating large amounts of refined, sugary foods (“empty
calories”) can lead to obesity, as well as nutritional
deficiencies
– Starchy foods (rice, pasta, breads) cost less than high-
protein foods (like meat), so carbohydrates often make up
greater percentage of diet in low-income groups

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Lipids

Dietary sources
– Primarily triglycerides (neutral fats) in the form of:
▪ Saturated fats in meat, dairy, some tropical plants (e.g., coconut)
▪ Trans fats in hydrogenated oils (e.g., margarine and shortening)
▪ Unsaturated fats in seeds, nuts, olive oil, and most vegetable oils
– Cholesterol found in egg yolk, meats, organ meats, shellfish, and milk
products
▪ Liver makes 85% of blood cholesterol
– Two essential fatty acids liver can’t synthesize (but found in most
vegetable oils)
▪ Linoleic acid—an omega-6 fatty acid (component of lecithin)
▪ Linolenic acid—an omega-3 fatty acid

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 Lipids
Uses in the body
– Adipose tissue provides protective cushioning, insulation, energy storage
– Phospholipids essential part of myelin sheaths (neurons) and cell membranes
– Cholesterol stabilizes cell membranes; precursor of bile salts and steroid
hormones
– Prostaglandins (regulatory molecules made from linoleic acid)
▪ Role in smooth muscle contraction, regulation of B P, and inflammation
– Triglycerides provide a major energy source for skeletal muscle and liver cells
– Help body absorb fat-soluble vitamins

Dietary requirements
– Fats should represent 20–35% of total caloric intake (> 40% in typical
American diet)
▪ Limit saturated fats to 10% or less of total fat intake
– Cholesterol can be synthesized to meet needs (not required in diet)
▪ Many recommend intake as low as possible, especially for those with high
blood cholesterol levels, which is associated with cardiovascular (CV)
disease
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Proteins

Dietary sources
– Animal products (eggs, milk, fish, most meats) and
soybeans provide complete proteins—meeting all
amino acid requirements
– Legumes, nuts, and cereal grains contain incomplete
proteins—low in one or more essential amino acids
▪ Ingested together, cereal grains and legumes
provide all essential amino acids

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Essential Amino Acids

Figure 24.2 Essential amino acids

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Proteins
Uses in the body
– Structural materials: keratin (skin), collagen and elastin (connective
tissue), and muscle proteins
– Functional molecules: enzymes and protein hormones control various
activities
– Multiple factors determine whether amino acids in cell are used to
synthesize new proteins or used for energy (to make ATP):
▪ The all-or-none rule: all amino acids needed to build a particular
protein must be present at the same time
– If one or more are insufficient, protein can’t be made, and its
amino acids are instead used as energy or converted to carbs
or fats
▪ Adequacy of caloric intake: food and body proteins used as energy
when intake of carbohydrate or fat calories are insufficient for ATP
needs
▪ Hormonal controls: anabolic hormones like GH and gonadal
steroids promote protein synthesis; other hormones like
glucocorticoids promote protein breakdown and conversion of amino
acids to glucose
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Proteins

Nitrogen balance
– Homeostatic state where rate of protein synthesis equals rate of
breakdown and loss; amount of nitrogen ingested (via protein) equals
amount excreted
– Positive nitrogen balance: synthesis exceeds breakdown
▪ Normal in growing children, pregnant women, tissue repair
– Negative nitrogen balance: breakdown for energy exceeds synthesis
▪ Occurs during stress, burns, infection, injury, low quality or quantity
of dietary proteins, starvation
Dietary requirements
– Needed to supply essential amino acids (and make nonessential ones)
– Amount needed depends on age, size, metabolic rate, current nitrogen
balance
▪ Rule of thumb: daily intake of 0.8 g per kg body weight

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24.2 Most Vitamins Act as
Coenzymes; Minerals Have Many
Roles in the Body

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Vitamins
Vitamins are organic compounds body requires in minute amounts
– Not an energy source themselves, but needed to use macronutrients that
are—dietary carbohydrates, proteins, fats would be useless without
vitamins
Most are coenzymes (or parts of), which act with an enzyme to carry out a
particular reaction; e.g., B vitamins act as coenzymes when glucose is used to
make ATP
Most must be ingested, except vitamin:
– D (made in skin)
– B and K (synthesized by intestinal bacteria)

Also, body can convert beta-carotene (orange pigment in carrots) to vitamin A

Balanced diet best way to avoid deficiencies
– No one major food group contains all vitamins

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Vitamins

Two types of vitamins based on solubility
– Water-soluble vitamins
▪ B complex and C are absorbed with water
▪ B12 absorption requires intrinsic factor (secreted from stomach glands)
▪ No significant storage in body; absorbed vitamins not used by cells are
excreted in urine (so problems from excessive intake are rare)
– Fat-soluble vitamins A, D, E, and K are absorbed with lipids in gut
▪ Problems with lipid absorption can interfere with uptake of fat-soluble vitamins
▪ Stored in body (except for K); excessive intake can cause health problems
Free radicals (molecules with unpaired electron) generated during normal metabolism
– Vitamins A, C, E, and mineral selenium are antioxidants—participants in
antioxidant reactions that neutralize dangerous free radicals
– Megadoses of vitamins not beneficial, and may cause serious health problems
(especially fat-soluble vitamins)

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 Vitamins
Table 24.2 Vitamins

Water-Soluble Vitamins
Vitamin Major Dietary Sources Major Functions In The Body Symptoms Of Deficiency Or Extreme Excess

Vitamin B sub 1 Pork, legumes, peanuts, Coenzyme used in removing C O2 Beriberi (nerve disorder—tingling, poor coordination,
(thiamine) whole grains from organic compounds reduced heart function)

Vitamin B sub 2 Dairy products, meats, Component of coenzymes FAD and Skin lesions such as cracks at corners of mouth
(riboflavin) enriched grains, vegetables F MN
B1 CO2
Vitamin B sub 3 Nuts, meats, grains Component of coenzymes Skin and gastrointestinal lesions, nervous system
(niacin) disorders Liver damage
N A D super plus and N A D P super plus

B2

Vitamin Most foods: meats, dairy Component of coenzyme A Fatigue, numbness, tingling of hands and feet
(pantothenic B
B sub 5

acid)
3 products, whole grains, etc.
NAD and NADP 
Vitamin B
B sub 6 Meats, vegetables, whole Coenzyme used in amino acid Irritability, convulsions, muscular twitching, anemia
(pyridoxine) 5 grains metabolism Unstable gait, numb feet, poor coordination

Vitamin B sub 7 B6 Legumes, other vegetables, Coenzyme in synthesis of fat, Scaly skin inflammation, neuromuscular disorders
(biotin) meats glycogen, and amino acids

Vitamin B sub 9
B7
(folic Green vegetables, oranges, Coenzyme in nucleic acid and Anemia, birth defects May mask deficiency of vitamin B sub 12

acid) nuts, legumes, whole grains amino acid metabolism
B9
Vitamin B sub 12 Meats, eggs, dairy products Coenzyme in nucleic acid Anemia,B12
nervous system disorders (numbness, loss of
metabolism; maturation of red blood balance)
B12 cells

Vitamin C Fruits and vegetables, Used in collagen synthesis (such as Scurvy (degeneration of skin, teeth, blood vessels),
(ascorbic acid) especially citrus fruits, for bone, cartilage, gums); weakness, delayed wound healing Gastrointestinal
broccoli, tomatoes antioxidant upset

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Vitamins

Table 24.2 [cont.] inued

Fat-Soluble Vitamins
Vitamin Major Dietary Sources Major Functions In The Symptoms Of Deficiency Or
Body Extreme Excess
Vitamin A Provitamin A (beta-carotene) in Component of visual Blindness, skin disorders,
(retinol) deep green and orange pigments; maintenance of impaired immunity Headache,
vegetables and fruits; retinol in epithelial tissues; irritability, vomiting, hair loss,
dairy products antioxidant blurred vision, liver and bone
damage
Vitamin D Dairy products, egg yolk; also Aids in absorption and use Rickets (bone deformities) in
made in human skin in presence of calcium and phosphorus children, bone softening in adults
of sunlight Brain, cardiovascular, and kidney
damage
Vitamin E Vegetable oils, nuts, seeds Antioxidant; helps prevent Degeneration of the nervous
(tocopherol) damage to cell membranes system
Vitamin K Green vegetables, tea; also Important in blood clotting Defective blood clotting Liver
(phylloquinone) made by colon bacteria damage and anemia

Modified from: Urry et al., Campbell Biology, 12th Edition, © 2021. Reprinted by permission of Pearson Education, I nc.,
Upper Saddle River, N.J.

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Minerals
Seven minerals required in moderate amounts (plus trace amounts of others):
– Calcium, phosphorus, potassium, sulfur, sodium, chlorine, and magnesium

Like vitamins, work with nutrients for proper body functioning
– Incorporating minerals into structures makes them stronger
▪ Calcium, phosphorus, and magnesium salts harden teeth and strengthen
bone
– Most ionized in body fluids or bound to organic compounds to form phospholipids,
hormones, and various proteins
▪ Iron is essential part of oxygen-binding heme of hemoglobin
▪ Sodium and chloride are major electrolytes in blood
▪ Iodine is necessary for thyroid hormone synthesis

Uptake and excretion balanced to prevent toxic overload
– Natural sodium in foods poses little-to-no health risk; the large amounts added to
processed foods and sprinkled on food may cause fluid retention and high BP
– Mineral-rich foods: legumes and other vegetables, milk, some meats
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Table 24.3 Minerals in the Body
Greater than 200 mg per Day Required

Mineral Major Dietary Sources Major Functions In The Body Symptoms Of Deficiency*
Calcium (Ca) Dairy products, dark green Bone and tooth formation, blood clotting, Impaired growth, possibly loss of bone
vegetables, legumes nerve and muscle function mass

Phosphorus (P) Dairy products, meats, Bone and tooth formation, acid-base Weakness, loss of minerals from bone,
grains balance, nucleotide synthesis calcium loss

Sulfur (S) Proteins from many Component of certain amino acids Symptoms of protein deficiency
sources
Potassium (K) Meats, dairy products, Nerve function, acid-base balance Muscular weakness, paralysis, nausea,
many fruits and vegetables, heart failure
grains
Chlorine (Cl) Table salt Acid-base balance, formation of gastric Muscle cramps, reduced appetite
juice, nerve function, osmotic balance

Sodium (Na) Table salt Water balance, blood pressure, nerve Muscle cramps, reduced appetite
function
Magnesium (Mg) Whole grains, green leafy Cofactor; ATP bioenergetics Nervous system disturbances
vegetables

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Table 24.3 Minerals in the Body
Table 24.3 [cont.] inued

Trace Amounts Required
Mineral Major Dietary Sources Major Functions In The Body Symptoms Of Deficiency*
Iron (Fe) Meats, eggs, legumes, whole Component of hemoglobin and of electron Iron-deficiency anemia,
grains, green leafy vegetables carriers in energy metabolism; enzyme weakness, impaired immunity
cofactor
Fluorine (F) Drinking water, tea, seafood Maintenance of tooth (and probably bone) Higher frequency of tooth decay
structure
Zinc (Zn) Meats, seafood, grains Component of certain digestive enzymes Growth failure, skin abnormalities,
and other proteins reproductive failure, impaired
immunity
Copper (Cu) Seafood, nuts, legumes, organ Enzyme cofactor in iron metabolism, Anemia, cardiovascular
meats melanin synthesis, electron transport abnormalities
Manganese (Mn) Nuts, grains, vegetables, fruits, tea Enzyme cofactor Abnormal bone and cartilage
Iodine (I) Seafood, iodized salt Component of thyroid hormones Goiter (enlarged thyroid)
Cobalt (Co) Meats and dairy products Component of vitamin B sub 12 None, except as deficiency
B sub 12

Selenium (Se) Seafood, meats, whole grains Enzyme cofactor for antioxidant
B
enzymes Muscle pain, possibly
B12
heart
12
muscle deterioration
Chromium (Cr) Brewers’ yeast, liver, seafood, Involved in glucose and energy Impaired glucose metabolism
meats, some vegetables metabolism
Molybdenum (Mo) Legumes, grains, some vegetables Enzyme cofactor Disorder in excretion of nitrogen-
containing compounds

*All of these minerals are also harmful when consumed in excess.
Modified from: Urry et al., Campbell Biology, 12th Edition, © 2021. Reprinted by permission of Pearson Education, I nc.,
Upper Saddle River, N.J.
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Part 2—Metabolism
Metabolism: sum of all biochemical reactions in the body,
which involve nutrients
– Substances are constantly built up (anabolism) and
broken down (catabolism)
– Even at rest, body uses lots of energy for essential
activities (like breathing and absorbing nutrients from
food)

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24.3 Metabolism is the Sum of All
Biochemical Reactions in the
Body

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Anabolism and Catabolism
Anabolism: reactions that build larger molecules or structures from smaller
ones;
– E.g., synthesis of proteins from amino acids

Catabolism: reactions that break down more complex structures to simpler
ones
– E.g., hydrolysis of proteins into amino acids

Three major stages involved in processing energy-containing nutrients:
– Stage 1: digestion and absorption in gastrointestinal tract
– Stage 2: in cytoplasm, newly delivered nutrients either:
▪ Built into lipids, proteins, and glycogen by anabolic pathways
▪ Broken down by catabolic pathways to smaller fragments (like
pyruvate)
– Stage 3: in mitochondria, complete breakdown of stage 2 products (most
will first be converted into acetyl C o A)
▪ Uses oxygen
▪ Produces carbon dioxide, water, and large amounts of ATP

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Anabolism and Catabolism

Cellular respiration: group of catabolic reactions
(glycolysis, the citric acid cycle, and oxidative
phosphorylation) that convert some of the chemical energy
of nutrients (like glucose) into a form of chemical energy
(ATP) cells can use to do work
Phosphorylation: transfer of high-energy phosphate
group from ATP to another molecule
– Primes molecule; changing it in a way that increases
its activity, produces motion, or does work
Body stores energy as glycogen and triglycerides, then
breaks them down later to produce ATP for cellular use

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Three Stages
of Metabolism
of Energy-
Containing
Nutrients

Figure 24.3 Three stages of metabolism of energy-containing nutrients

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Oxidation-Reduction Reactions and the
Role of Coenzymes
Many reactions in cells are oxidation reactions
– Oxidation is the gain of oxygen or the loss of hydrogen
atoms (with their electrons)
▪ Oxidized substance always loses (or nearly loses)
electrons as they move to (or toward) a substance
that more strongly attracts them
▪ E.g., oxidation of glucose involves removal of pairs
of hydrogen atoms (with their electrons) until only
CO2 remains
– O2 is final electron acceptor, joining with
removed H atoms to form H2O
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Oxidation-Reduction Reactions and the
Role of Coenzymes
Oxidation-reduction (redox) reactions
– Whenever one substance loses electrons (oxidized), another gains them
(reduced)
▪ Oxidized substances lose and reduced ones gain energy (as energy-
rich electrons transferred from one substance to next)
– Redox reaction enzymes:
▪ Dehydrogenases catalyze removal of hydrogen atoms
▪ Oxidases catalyze transfer of oxygen
– Most redox enzymes require a B vitamin coenzyme, which can accept the
hydrogen and its electron, becoming reduced when a substrate is oxidized
▪ Two important coenzymes of the oxidative pathway:
– Nicotinamide adenine dinucleotide (NAD )
– Flavin adenine dinucleotide (FAD)
▪ E.g., FAD reduced to FADH2 as succinate is oxidized to fumarate
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Succinate to Fumarate

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ATP Synthesis

Two mechanisms capture (as ATP) some of the energy released via cellular respiration

Substrate-level phosphorylation
– Direct transfer of high-energy phosphate group from substrate to ADP
– Occurs twice in glycolysis (enzymes in cytosol) and once in Krebs cycle (enzymes
in mitochondria)
Oxidative phosphorylation more complex, but produces most of the ATP
– Carried out by inner mitochondrial membrane proteins in two steps:
▪ Electron transport chain: ~ 50% of energy released via nutrient oxidation
used to pump H across inner membrane, creating steep [H ] gradient
▪ Chemiosmosis: coupling movement of H (diffusion down gradient) across
selectively permeable membrane to a chemical reaction—the synthesis of ATP
– Diffusion of H across inner membrane through protein ATP synthase
provides energy to attach phosphate groups to ADP, making ATP

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Mechanisms of Phosphorylation

Figure 24.4 Mechanisms of phosphorylation
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24.4 Carbohydrate Metabolism Is the
Central Player in ATP Production
Food carbohydrates are converted to glucose, which enters cells via
glucose transporters
– Process enhanced by insulin
Glucose enters cell and is immediately phosphorylated to glucose-6-
phosphate
– Most cells lack enzymes to reverse reaction, so glucose trapped
in cell
▪ Only cells in intestine, kidney, liver can reverse reaction and
release glucose
– Keeps intracellular glucose (a different molecule from glucose-6-
phosphate) concentration low, ensuring continued glucose entry
(via facilitated diffusion)

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Oxidation of Glucose

Glucose is catabolized via following reaction:
C6H12O6  6O2 6H2O  6CO2  32 ATP  heat
glucose oxygen water carbon
dioxide

Complete glucose catabolism requires three pathways, in
sequence:
1. Glycolysis
2. Citric acid cycle
3. Oxidative phosphorylation

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During Cellular Respiration, ATP Is Formed
in the Cytosol and in the Mitochondria

Figure 24.5 During cellular respiration, A TP is formed in the cytosol and in the mitochondria
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Oxidation of Glucose

Glycolysis (glycolytic pathway)
– Occurs in cytosol, involves ten chemical steps that
convert each glucose to two pyruvate molecules
– Anaerobic process
▪ Glycolysis itself does not use oxygen and occurs
whether or not oxygen is present
– Three major phases
Phase 1: Sugar activation
Phase 2: Sugar cleavage
Phase 3: Sugar oxidation and ATP formation

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The Three Major Phases
of Glycolysis

Figure 24.6 The three major phases of glycolysis
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Oxidation of Glucose
Glycolysis (cont.)
inued

– Final products of glycolysis (each molecule of glucose is C6H12O6 ) :
▪ 2 molecules of pyruvate (C3H4O3 )
▪ 2 reduced NAD (NADH  H )
▪ Net gain of 2 ATP
– To continue glycolysis, NAD must remain available to accept more H
atoms
▪ When oxygen readily available, this is no problem, and NADH  H
delivers its H atoms to the electron transport chain
▪ When oxygen insufficient (e.g., during strenuous exercise), NADH  H
unloads its H atoms back onto pyruvate, reducing it to form lactate

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 Oxidation of Glucose
Glycolysis (cont.)
inued

– Some of this lactate enters blood and is picked up by liver,
which can convert it back to glucose-6-phosphate
▪ Then converted to glucose and released into blood or
stored as glycogen
– With more oxygen available, more lactate can be oxidized
back to pyruvate to enter aerobic pathways (citric acid cycle
and oxidative phosphorylation)
– Glycolysis generates ATP rapidly, but yields only 2 ATP
compared to 30–32 ATP when glucose is completely
oxidized (via pyruvate entering mitochondria)

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Oxidation of Glucose

Citric acid cycle (Krebs cycle)
– Next stage of glucose oxidation; named for its first substrate (citrate)
– Occurs in mitochondrial matrix, fueled mostly by pyruvate (via glycolysis) and fatty
acids from fat breakdown
– Transitional phase converts pyruvate to acetyl CoA via three-step process:

1. Decarboxylation: 1 carbon from pyruvate is removed, producing CO2
gas, which diffuses into blood to be expelled by lungs
2. Oxidation: remaining 2-C fragment oxidized to acetate by removal of H
atoms, which are picked up by NAD
3. Formation of acetyl CoA: acetate combines with coenzyme A to form
acetyl coenzyme A (acetyl CoA)
– Acetyl CoA is now ready to enter the citric acid cycle and be broken down by
mitochondrial enzymes

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Simplified
Version of
the Citric
Acid (Krebs)
Cycle

Figure 24.7 Simplified version
of the citric acid (Krebs) cycle
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Oxidation of Glucose
Citric Acid Cycle Makes
2 molecules of CO2
4 molecules of reduced coenzymes 3 NADH
and 1 FADH2
1 molecule of ATP (GTP)

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Oxidation of Glucose

Oxidative phosphorylation
– Electron transport chain (ETC) only pathway to directly use oxygen
▪ Citric acid cycle provides substrates (reduced coenzymes) for ETC, so the
coupled pathways are aerobic (require the presence of oxygen to continue)
– Overview
▪ NADH  H and FADH (from glycolysis and Krebs cycle) shuttle H atoms to
2

ETC proteins, which combine with O2 to form H2O
▪ Chemiosmosis uses energy released to attach Pi to ADP, forming ATP
– ETC involves chain of carrier proteins (with bound metal atoms called cofactors)
embedded in inner mitochondrial membrane
▪ Flavins: proteins derived from riboflavin (ETC complexes I and II)
▪ Cytochromes: proteins with iron-containing pigment (III and IV)
▪ Respiratory enzyme complexes: clusters of neighboring carriers that are
alternately reduced and oxidized as they pass electrons down the line

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Focus Figure
24.1 Oxidative
Phosphorylation

Focus Figure 24.1 Oxidative
Phosphorylation
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Oxidation of Glucose

Oxidative phosphorylation has two phases:
– Phase 1: ETC creates proton (H ) gradient across inner mitochondrial membrane
using high-energy electrons (e ) removed from food fuels
▪ Complexes I and II accept H from NADH and FADH2
– NAD and FAD can now return to glycolysis and Krebs cycle
▪ H atoms split into protons (H )  electrons (e  )
– Electrons passed down chain, releasing energy with each transfer
– Each complex is reduced (picking up e ) and then oxidized (transferring
e  to next complex)
▪ At complex IV, electron pairs combine with two H and half a molecule of
oxygen to form water
2 H  2 e   ½ O2 H2O

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Energy Is Harvested
at Each Step in the
Electron Transport
Chain

Figure 24.8 Energy is harvested at each
step in the electron transport chain
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Oxidation of Glucose

Oxidative phosphorylation has two phases: (cont.) inued

– Phase 2: Chemiosmosis uses energy of proton gradient to synthesize ATP
▪ Proton gradient is both a pH gradient (H higher in intermembrane
space than matrix) and a voltage gradient (negative on matrix side of
membrane)
▪ As a result, H strongly attracted to matrix side of membrane, but can
only cross through membrane protein ATP synthase (complex V)
– These synthases act as small rotary motors that drive a
molecular mill that joins ADP and Pi into ATP (like an ion pump
working in reverse)

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Structure and
Function of ATP
Synthase

Figure 24.10 Structure and function of A TP synthase

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Structure and
Function of ATP
Synthase

Figure 24.10 Structure and function of A TP synthase

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Structure and
Function of ATP
Synthase

Figure 24.10 Structure and function of A TP synthase

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Structure and
Function of ATP
Synthase

Figure 24.10 Structure and function of A TP synthase

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Energy-Converting ATP Synthase Rotor
Rings as Seen by Atomic Force Microscopy

Figure 24.9 Energy-converting ATP synthase rotor rings as seen by atomic force
microscopy
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Clinical—Homeostatic Imbalance 24.1
Metabolic poisons interfere with oxidative phosphorylation
– E.g., hydrogen cyanide binds to cytochrome oxidase
and blocks electron flow from complex IV to oxygen
Poisons called “uncouplers” destroy proton gradient by
making inner mitochondrial membrane permeable to H
– Electrons continue down ETC to oxygen at rapid pace
and oxygen consumption rises, but no ATP made

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Energy Yield During Cellular Respiration

Figure 24.11 Energy yield during cellular respiration
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Bioflix “Cellular Respiration”

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Glycogenesis, Glycogenolysis, and
Gluconeogensis
Cells cannot store large amounts of ATP
If more glucose available than can be oxidized, intracellular ATP levels rise,
eventually inhibiting glucose catabolism and promoting its storage as glycogen
or fat
– Fats account for 80–85% of stored energy
Glycogenesis
– Is synthesis of glycogen, a large polysaccharide made of long glucose
chains
▪ Form of carbohydrate storage in animal cells
▪ Most active in liver and skeletal muscle
– Process:
▪ Glucose converted to glucose-6-phosphate, then to its isomer glucose-
1-phosphate
▪ Terminal phosphate removed as enzyme (glycogen synthase)
catalyzes attachment of glucose to growing chain
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Glycogenesis, Glycogenolysis, and
Gluconeogensis
Glycogenolysis
– Is glycogen breakdown to release stored glucose; triggered by low glucose levels
– Process:
▪ Splitting and phosphorylating of glycogen by enzyme glycogen phosphorylase
produces molecules of glucose-1-phosphate
▪ Converted to glucose-6-phosphate, which can enter glycolysis
▪ Liver (and some kidney and intestinal) cells contain enzyme glucose-6-
phosphatase that removes terminal phosphate
– Producing glucose that can enter bloodstream for use by other cells

Gluconeogenesis
– Low glucose availability also promotes gluconeogenesis (formation of new
glucose molecules from noncarbohydrate sources) via liver
▪ Glucose can be made from glycerol and amino acids
▪ Protects body (especially CNS) from damaging effects of low blood glucose
(hypoglycemia)

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Glycogenesis and
Glycogenolysis

Figure 24.13 Glycogenesis and glycogenolysis
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24.5 Lipid Metabolism Is Key for Long-
Term Energy Storage and Release
Fats are the most concentrated source of energy
– Contain very little water, and their catabolism yields
twice the energy (9 kcal/g) compared to glucose or
protein catabolism (4 kcal/g)
Most products of fat digestion are transported in lymph (to
blood) via chylomicrons
– Lipids hydrolyzed by capillary (endothelial) enzymes
into fatty acids and glycerol that can be taken up by
cells for various uses

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Oxidation of Glycerol and Fatty Acids

Triglycerides only lipids routinely oxidized for energy; their building blocks
(glycerol + fatty acids) oxidized separately:
– Glycerol converted into glyceraldehyde-3-phosphate (glycolysis
intermediate, equal to half a glucose), and eventually to acetyl C oA, which
enters citric acid cycle
▪ So, yield per glycerol ~ 15 ATP
– Fatty acids undergo beta oxidation in mitochondria
▪ Fatty acid chains broken down into two-carbon fragments, and
coenzymes (FAD and NAD ) are reduced
– Each fragment binds with CoA to form acetyl CoA

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Lipid Oxidation

Figure 24.15 Lipid oxidation
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Lipogenesis
Lipogenesis: triglyceride synthesis; stimulated by high glucose levels
and cellular ATP
– Dietary glycerol and fatty acids not needed for ATP are stored as
triglycerides
▪ When made faster than they can enter citric acid cycle, these
excess intermediates are channeled into triglyceride synthesis
pathways
▪ Acetyl CoA molecules are joined, forming fatty acid chains
that grow two carbons at a time (so almost all fatty acids in
body contain an even number)
Glucose easily converted to fat because acetyl CoA (glucose
catabolism intermediate) is also the starting point for fatty acid
synthesis

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Lipolysis
Lipolysis: breakdown of stored fats into glycerol and fatty acids (lipogenesis
in reverse)
– Fatty acids preferred fuel of liver, cardiac muscle, resting skeletal muscle
– Lipolysis accelerated when carbohydrate intake inadequate to fill fuel
gap
Beta oxidation of released fatty acids increases production of acetyl CoA,
which can enter citric acid cycle only if enough carbohydrate intermediates
are available
– If not, excess acetyl CoA converted by ketogenesis in liver to ketone
bodies (ketones), including:
▪ Acetoacetic acid

▪ -hydroxybutyric acid
▪ Acetone

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Lipid Metabolism

Figure 24.16 Lipid metabolism
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Synthesis of Structural Materials
All body cells use phospholipids and cholesterol to build
their membranes
– Phospholipids also form myelin sheaths of neurons
Ovaries, testes, and adrenal cortex use cholesterol to
synthesize their steroid hormones
The liver:
– Synthesizes lipoproteins to transport cholesterol, fats,
other substances in blood
– Synthesizes cholesterol from acetyl CoA
– Uses cholesterol to form bile salts

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24.6 Amino Acids Are Used to Build
Proteins or for Energy
Proteins have limited life span, must be broken down and
replaced before deteriorating
– Amino acids are recycled into new proteins or different
N-containing compounds
– Cells take up dietary amino acids from blood and use
them to replace tissue proteins at rate of ~ 100 g/day
Proteins are not stored in body
– When dietary amino acids (proteins) in excess, they are
oxidized for energy or converted to fat or glycogen for
storage

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Degradation of Amino Acids
Goal: produce molecules that can be used for energy in citric acid
cycle or converted to glucose
First, they are deaminated—their amine group (–NH2 ) is removed
Resulting molecule then converted to pyruvate or one of the keto acid
intermediates of citric acid cycle
– Key molecule in these conversions is amino acid glutamate
Three events of amino acid degradation

1. Transamination
2. Oxidative deamination
3. Keto acid modification

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Processes That Occur When Amino
Acids Are Utilized for Energy (1 of 3)

Figure 24.17 Processes that occur when amino acids are utilized for energy
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Processes That Occur When Amino
Acids Are Utilized for Energy (2 of 3)

Figure 24.17 Processes that occur when amino acids are utilized for energy
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Processes That Occur When Amino
Acids Are Utilized for Energy (3 of 3)

Figure 24.17 Processes that occur when amino acids are utilized for energy
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24.7 Energy Is Stored in the Fed State
and Released in the Fasting State

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Interconversion of Carbohydrates, Fats,
and Proteins

Figure 24.19 Interconversion of carbohydrates, fats, and proteins
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Fed State

Fed state, also called absorptive state, lasts for ~ 4 hours after eating begins, as
nutrients are being absorbed (entering bloodstream)
– Anabolism exceeds catabolism and nutrients are stored
▪ Glucose major fuel for ATP synthesis
– Dietary amino acids and fats used to remake degraded body protein or fat
▪ Small amounts oxidized to provide A TP
– Excess nutrients (regardless of source) transformed to fat

Carbohydrates
– Absorbed monosaccharides delivered directly to liver; fructose and galactose
converted to glucose
▪ Glucose can enter blood or be converted to glycogen or fat in liver
▪ Glycogen remains in liver; fat packaged with proteins as very low-density
lipoproteins (VLDLs) and released to blood for storage by adipose tissue
– Bloodborne glucose enters body cells; excess stored as glycogen in muscles or fat
in adipose tissues

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Fed State
Triglycerides
– Hydrolyzed to fatty acids and glycerol by enzyme lipoprotein lipase
before passing through capillary wall
▪ Enzyme particularly active in capillaries of muscle and fat tissues
– Primary energy source for adipose, liver, and skeletal and cardiac muscle
cells
– Most glycerol and fatty acids enter adipose tissues to be reconverted to
triglycerides for storage
Amino acids
– Some deaminated in liver to keto acids that can be used in citric acid
cycle or stored as fat
– Others used by liver to synthesize plasma proteins (albumin, clotting
proteins, and transport proteins)
– Most taken up by other body cells for protein synthesis

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Major Events and Principal Metabolic
Pathways of the Fed State

Figure 24.20a Major events and principal metabolic pathways of the fed state
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Major Events and Principal Metabolic
Pathways of the Fed State

Figure 24.20b Major events and principal metabolic pathways of the fed state
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Fed State

Hormonal control of the fed state
– Insulin directs essentially all events of the fed state; its secretion is stimulated by:
▪ Elevated blood glucose and amino acid levels
▪ GI tract hormone glucose-dependent insulinotropic peptide (GIP)
▪ Parasympathetic stimulation
– When insulin binds to target cell receptors, it facilitates insertion of glucose
transporters into the target cell membrane for carrier-mediated facilitated diffusion
▪ Glucose entry (particularly in muscle and adipose cells) increases ~ 20-fold
▪ Brain and liver take up glucose without insulin
– Insulin is a blood glucose lowering (hypoglycemic) hormone that enhances:
▪ Glucose oxidation for energy
▪ Conversion of glucose into glycogen and (in adipose) triglycerides
▪ Active transport of amino acids into cells and protein synthesis

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Insulin Directs
Nearly All Events
of the Fed State

Figure 24.21 Insulin directs nearly all
events of the fed state
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Clinical—Homeostatic Imbalance 24.3
Diabetes mellitus: disorder of inadequate insulin production
or abnormal insulin receptors, leaving blood glucose
unavailable to most cells
– Glucose levels remain high as most cells need insulin
for glucose entry
– Large amounts of glucose excreted in urine (carrying
out large amounts of water with it)
Results in metabolic acidosis, protein wasting, and weight
loss as large amounts of fats and tissue proteins used for
energy (in place of glucose)

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Fasting State

Fasting state, or postabsorptive state, is when GI tract
is empty and energy stores are broken down to meet
body’s metabolic demands
– Goal: maintain blood glucose within normal range
(70–110 mg glucose per 100 ml)
▪ By making glucose available to blood and
promoting use of fats for fuel (by organs like
skeletal muscle) to spare glucose for organs that
can’t (brain)

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Fasting State

Sources of blood glucose
1. Glycogenolysis in the liver: first reserve (~ 100g) used; can be mobilized
quickly and maintain blood glucose levels for about 4 hours
2. Glycogenolysis in skeletal muscle: begins before liver glycogen depleted

3. Lipolysis in adipose tissues and the liver: produces glycerol used for
gluconeogenesis in liver
4. Catabolism of cellular protein: major source during prolonged fasting
(starting with muscle proteins); liver converts amino acids to glucose
(gluconeogenesis)

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Fasting State

Glucose sparing
– During prolonged fasting, body uses more noncarbohydrate fuels to conserve
glucose
– Brain uses bulk of glucose while other body cells switch to fatty acids as main fuel
▪ After fasting 4–5 days, brain starts relying on ketone bodies (as well as
glucose)
Hormonal and neural controls of the fasting state
– Hormones and sympathetic nervous system interact to control events of fasting
state
▪ More complex than fed state, which utilizes one hormone (insulin)
▪ Reduced insulin release (as blood glucose falls) important trigger to initiate
events of fasting state

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Major Events and Principal Metabolic
Pathways of the Fasting State

Figure 24.22b Major events and principal metabolic pathways of the fasting state
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Fasting State

Hormonal and neural controls of the fasting state (cont.) inued

– Glucagon
▪ Raises blood glucose levels, making it a hyperglycemic hormone (like
the other fasting state hormones) and insulin antagonist
▪ Released from pancreas (alpha cells) in response to low blood
glucose
▪ Targets liver and adipose tissues to promote:
– Glycogenolysis and gluconeogenesis (liver), releasing glucose
into blood
– Lipolysis (adipose), releasing fatty acids and glycerol into blood
▪ Rising blood amino acid levels stimulates release of both insulin and
glucagon

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Glucagon Is a
Hyperglycemic
Hormone That
Stimulates a Rise in
Blood Glucose Levels

Figure 24.23 Glucagon is a
hyperglycemic hormone that stimulates a
rise in blood glucose levels
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Fasting State

Hormonal and neural controls of the fasting state (cont.) inued

– Sympathetic nervous system
▪ Sympathetic fibers innervate adipose tissue, releasing
norepinephrine to stimulate lipolysis
▪ Release of epinephrine from adrenal medulla targets liver,
skeletal muscle, and adipose to mobilize fat and promote
glycogenolysis
▪ Any stressor that triggers fight-or-flight response, including
exercise, activates this pathway (making lots of fuels available
for muscles)
– Other hormones
▪ Growth hormone, thyroxine, sex hormones, and
corticosteroids also influence metabolism and nutrient flow

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24.8 The Liver Metabolizes, Stores, and
Detoxifies
Liver is one of the most biochemically complex organs,
carrying out ~ 500 metabolic functions
Hepatocytes process nearly every class of nutrient and
play major role in regulating blood cholesterol levels

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Cholesterol Metabolism and Regulation of
Blood Cholesterol Levels
Cholesterol provides structural basis of bile salts, steroid
hormones, and vitamin D
– Also major component of plasma membranes (adds
stability)
~ 15% of blood cholesterol is dietary; rest synthesized
from acetyl CoA (mostly in liver)
Lost from body when catabolized or secreted in bile salts

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Composition and Function of Lipoproteins

Figure 24.24 Composition and function of lipoproteins
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Cholesterol Metabolism and Regulation of
Blood Cholesterol Levels
Blood Levels of Total Cholesterol, L DL, and HDL
– Generally, total cholesterol < 200 mg/dl of blood is desirable for adults
▪ Levels > 200 mg/dl linked to atherosclerosis (and thus CV disease)
– More important to look at ratio of lipoproteins transporting cholesterol in
blood
▪ High LDL levels (160 mg/dl) are generally considered bad
▪ High HDL levels were traditionally considered good because the
transported cholesterol is destined for degradation
– Recent studies have not confirmed that high HDL levels protect
against CV disease

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Clinical—Homeostatic Imbalance 24.4

Previously, high cholesterol and LDL:HDL ratios were
considered most valid predictors of risk for atherosclerosis, CV
disease, and heart attack
– However, many who get heart disease have normal
cholesterol levels, and many with poor lipid profiles remain
free of heart disease
Treatment for people at risk for cardiovascular disease
– Statins: a group of (LDL) cholesterol-lowering drugs;
estimated that > 40 million Americans take statins

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Part 3—Energy Balance

Energy released from chemical bonds when foods catabolized must equal energy output
– Energy intake: energy liberated during food oxidation
– Energy output includes energy:
▪ Immediately lost as heat (~ 60%)
▪ Used to do work (driven by ATP)
▪ Stored as fat or glycogen

Nearly all energy derived from foodstuffs is eventually converted to heat, which is lost
during every cellular activity:
– When ATP bonds are formed and when they are broken to do work
– As muscles contract
– Through friction as blood flows through blood vessels

Heat energy cannot be used by cells to do work, but is necessary to maintain
homeostatic body temperature, allowing metabolic reactions to occur efficiently

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Obesity

Body mass index (BMI) is a formula (based on height relative to weight) used to
determine obesity

– Clinically, overweight is defined by a BMI of 25–30 (carries some health risk)
▪ Obesity is a BMI > 30 (with markedly increased health risk)
– Obesity-related diseases:
▪ Chronic low-grade systemic inflammation
▪ Insulin resistance and type 2 diabetes mellitus
▪ Higher incidence of osteoarthritis, atherosclerosis, hypertension, heart disease,
and cancer
– Current U.S. statistics:

▪ Adults: ~ 32% are overweight; an additional 42% are obese; 10% have diabetes
▪ Kids: 19% of children are obese (40 years ago it was only 5%)

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Model for Hypothalamic Command of
Appetite and Food Intake

Figure 24.25 Model for hypothalamic command of appetite and food intake
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Basal Metabolic Rate (BMR)
Reflects energy body needs to perform its most essential activities

Measured in fasting state (12-hour fast), reclining position, relaxed mentally and
physically, at room temperature 20–25 C
– Not lowest metabolic state, that’s during sleep (skeletal muscles fully relaxed)

BMR influenced by:
– Age and sex: BMR decreases with age; males tend to have higher BMR since
males typically have more muscle (which is very metabolically activity)
▪ Females tend to have relatively more fat (low metabolic activity)
– Body temperature: BMR increases and decreases with temperature
– Stress: BMR increases with stress (via activation of sympathetic system)

– Thyroxine: increases O2 consumption and heat production, increasing BMR

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24.11 The Hypothalamus Acts as the
Body’s Thermostat
Body temperature reflects balance between heat production and loss
At rest, liver, heart, brain, kidneys, and endocrine organs generate most heat
– Inactive skeletal muscles account for only ~ 20–30%
During intense exercise, muscles can produce 30–40  more heat than the rest of body
– Change in muscle activity important way to change body temperature
Average body temperature in North America 36.7 6 C (98.1 1.1 F)
– Optimal for enzyme activity
– Body temperatures above range denature proteins and depress neurons
– Rate of chemical reactions increases ~ 10% for each 1 C rise in temperature
In children under 5, temperature of 41 C (106 F) can lead to convulsions
– ~ 43 C (109 F) is upper limit for life
Individual body tissues can tolerate low temperatures (e.g., cooling heart when it must be
stopped for surgery to lower its oxygen and nutrient requirements)

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Body Temperature Remains Constant as Long as
Heat Production and Heat Loss Are Balanced

Figure 24.26 Body temperature remains constant as long as heat production and heat
loss are balanced
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Core and Shell Temperatures
Body’s core has highest temperature
– Includes: organs within skull and thoracic and abdominal cavities

Body’s shell (skin) has lowest temperature (in most circumstances)
Rectum typically has temperature about 0.4 C (0.7 F) higher than the mouth
– Rectal temperature is better indicator of core temperature

Core temperature is regulated and stays relatively constant, but shell
temperature can vary between 20 C (68 F) and 40 C (104 F)
– Blood is major agent of heat exchange between core and shell

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Mechanisms of Heat Exchange
Body uses four mechanisms of heat transfer:
1. Radiation: loss of heat in form of infrared waves; radiant energy flows
from warmer to cooler

2. Conduction: transfer of heat by direct contact (from warmer to cooler
object)

3. Convection: transfer of heat to surrounding air; warm air expands and
rises (away from skin) and denser cool air falls (replacing warm air)

4. Evaporation occurs when water absorbs enough heat to vaporize (i.e.,
converted to water vapor)

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Role of the Hypothalamus

Hypothalamus (anterior region in particular) is main integrating center for
thermoregulation
– Thermoregulatory centers:
▪ Heat-loss center
▪ Heat-promoting center
– Receives afferent input from:
▪ Peripheral thermoreceptors in shell (skin)
▪ Central thermoreceptors in core (including anterior hypothalamus);
sensitive to blood temperature
– Then initiates appropriate heat-loss or heat-promoting activities

Central thermoreceptors have more influence, but varying inputs from
peripheral probably alert hypothalamus to the need to prevent temperature
changes in the core

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Mechanisms of
Body Temperature
Regulation

Figure 24.28 Mechanisms of body
temperature regulation
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Clinical—Homeostatic Imbalance 24.7

Hyperthermia (high body temp)
– Overexposure to hot and humid environment overwhelms heat-loss processes
▪ At ~ 41 C (105  F), hypothalamus is depressed (heat-loss mechanisms cease),
creating positive feedback cycle that leads to heat stroke if not corrected
– Increasing temperatures continue to increase metabolic rate, and thus
heat production
– Skin is hot and dry, multiple organ damage can occur (including brain)
▪ Fatal if not corrected quickly with cold water immersion and hydration

Heat exhaustion (exertion-induced heat exhaustion)
– Heat-associated extreme sweating and collapse during or following vigorous
physical exertion due to dehydration and low blood pressure
▪ Causes elevated body temperature and mental confusion and/or fainting
– As heat-loss mechanisms struggle to function, may progress to heat stroke

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Clinical—Homeostatic Imbalance 24.7

Hypothermia (low body temp)
– Caused by prolonged cold exposure
– Vital signs (respiratory and heart rate, blood pressure)
decrease as cellular (enzymatic) activities slow
▪ Person begins to feel drowsy, even (oddly) comfortable
(no longer feels cold)
▪ Shivering stops at core temperature of 30–32 C (87–90 F)
– Can progress to coma and finally death (by cardiac arrest) at
~ 21 C 70 F 

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Clinical—Homeostatic Imbalance 24.9
Metabolic syndrome: cluster of five risk factors that double the chance of
getting heart disease and stroke, and increase the chance of developing type 2
diabetes by five times
– ~ 32% of U.S. population has three of five factors

Figure 24.29 Metabolic syndrome
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