42-circulation-text-and gas exchange
TRANSCRIPT
Copyright © 2005 Pearson Education, Inc. publishing as Benjamin Cummings
PowerPoint Lectures for Biology, Seventh Edition
Neil Campbell and Jane Reece
Lectures by Chris Romero
Chapter 42
Circulation and Gas Exchange
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• Overview: Trading with the Environment
• Every organism must exchange materials with its environment
– And this exchange ultimately occurs at the cellular level
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• In unicellular organisms
– These exchanges occur directly with the environment
• For most of the cells making up multicellular organisms
– Direct exchange with the environment is not possible
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• The feathery gills projecting from a salmon
– Are an example of a specialized exchange system found in animals
Figure 42.1
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• Concept 42.1: Circulatory systems reflect phylogeny
• Transport systems
– Functionally connect the organs of exchange with the body cells
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• Most complex animals have internal transport systems
– That circulate fluid, providing a lifeline between the aqueous environment of living cells and the exchange organs, such as lungs, that exchange chemicals with the outside environment
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Invertebrate Circulation
• The wide range of invertebrate body size and form
– Is paralleled by a great diversity in circulatory systems
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Gastrovascular Cavities
• Simple animals, such as cnidarians
– Have a body wall only two cells thick that encloses a gastrovascular cavity
• The gastrovascular cavity
– Functions in both digestion and distribution of substances throughout the body
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• Some cnidarians, such as jellies
– Have elaborate gastrovascular cavities
Figure 42.2
Circularcanal
Radial canal
5 cmMouth
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Open and Closed Circulatory Systems
• More complex animals
– Have one of two types of circulatory systems: open or closed
• Both of these types of systems have three basic components
– A circulatory fluid (blood)
– A set of tubes (blood vessels)
– A muscular pump (the heart)
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• In insects, other arthropods, and most molluscs
– Blood bathes the organs directly in an open circulatory system
Heart
Hemolymph in sinusessurrounding ograns
Anterior vessel
Tubular heart
Lateral vessels
Ostia
(a) An open circulatory systemFigure 42.3a
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• In a closed circulatory system
– Blood is confined to vessels and is distinct from the interstitial fluid
Figure 42.3b
Interstitialfluid
Heart
Small branch vessels in each organ
Dorsal vessel(main heart)
Ventral vesselsAuxiliary hearts
(b) A closed circulatory system
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• Closed systems
– Are more efficient at transporting circulatory fluids to tissues and cells
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Survey of Vertebrate Circulation
• Humans and other vertebrates have a closed circulatory system
– Often called the cardiovascular system
• Blood flows in a closed cardiovascular system
– Consisting of blood vessels and a two- to four-chambered heart
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• Arteries carry blood to capillaries
– The sites of chemical exchange between the blood and interstitial fluid
• Veins
– Return blood from capillaries to the heart
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Fishes
• A fish heart has two main chambers
– One ventricle and one atrium
• Blood pumped from the ventricle
– Travels to the gills, where it picks up O2 and disposes of CO2
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Amphibians
• Frogs and other amphibians
– Have a three-chambered heart, with two atria and one ventricle
• The ventricle pumps blood into a forked artery
– That splits the ventricle’s output into the pulmocutaneous circuit and the systemic circuit
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Reptiles (Except Birds)
• Reptiles have double circulation
– With a pulmonary circuit (lungs) and a systemic circuit
• Turtles, snakes, and lizards
– Have a three-chambered heart
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Mammals and Birds
• In all mammals and birds
– The ventricle is completely divided into separate right and left chambers
• The left side of the heart pumps and receives only oxygen-rich blood
– While the right side receives and pumps only oxygen-poor blood
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• A powerful four-chambered heart
– Was an essential adaptation of the endothermic way of life characteristic of mammals and birds
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FISHES AMPHIBIANS REPTILES (EXCEPT BIRDS) MAMMALS AND BIRDS
Systemic capillaries Systemic capillaries Systemic capillaries Systemic capillaries
Lung capillaries Lung capillariesLung and skin capillariesGill capillaries
Right Left Right Left Right Left Systemic
circuitSystemic
circuit
Pulmocutaneouscircuit
Pulmonarycircuit
Pulmonarycircuit
SystemiccirculationVein
Atrium (A)
Heart:ventricle (V)
Artery Gillcirculation
AV VV VV
A A A AALeft Systemicaorta
Right systemicaorta
Figure 42.4
• Vertebrate circulatory systems
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• Concept 42.2: Double circulation in mammals depends on the anatomy and pumping cycle of the heart
• The structure and function of the human circulatory system
– Can serve as a model for exploring mammalian circulation in general
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Mammalian Circulation: The Pathway
• Heart valves
– Dictate a one-way flow of blood through the heart
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• Blood begins its flow
– With the right ventricle pumping blood to the lungs
• In the lungs
– The blood loads O2 and unloads CO2
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• Oxygen-rich blood from the lungs
– Enters the heart at the left atrium and is pumped to the body tissues by the left ventricle
• Blood returns to the heart
– Through the right atrium
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• The mammalian cardiovascular system
Pulmonary vein
Right atrium
Right ventricle
Posteriorvena cava Capillaries of
abdominal organsand hind limbs
Aorta
Left ventricle
Left atriumPulmonary vein
Pulmonaryartery
Capillariesof left lung
Capillaries ofhead and forelimbs
Anteriorvena cava
Pulmonaryartery
Capillariesof right lung
Aorta
Figure 42.5
110
11
5
4
6
2
9
3 3
7
8
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The Mammalian Heart: A Closer Look
• A closer look at the mammalian heart
– Provides a better understanding of how double circulation works
Figure 42.6
Aorta
Pulmonaryveins
Semilunarvalve
Atrioventricularvalve
Left ventricleRight ventricle
Anterior vena cava
Pulmonary artery
Semilunarvalve
Atrioventricularvalve
Posterior vena cava
Pulmonaryveins
Right atrium
Pulmonaryartery
Leftatrium
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• The heart contracts and relaxes
– In a rhythmic cycle called the cardiac cycle
• The contraction, or pumping, phase of the cycle
– Is called systole
• The relaxation, or filling, phase of the cycle
– Is called diastole
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• The cardiac cycle
Figure 42.7
Semilunarvalvesclosed
AV valvesopen
AV valvesclosed
Semilunarvalvesopen
Atrial and ventricular diastole
1
Atrial systole; ventricular diastole
2
Ventricular systole; atrial diastole
3
0.1 sec
0.3 sec0.4 sec
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• The heart rate, also called the pulse
– Is the number of beats per minute
• The cardiac output
– Is the volume of blood pumped into the systemic circulation per minute
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Maintaining the Heart’s Rhythmic Beat
• Some cardiac muscle cells are self-excitable
– Meaning they contract without any signal from the nervous system
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• A region of the heart called the sinoatrial (SA) node, or pacemaker
– Sets the rate and timing at which all cardiac muscle cells contract
• Impulses from the SA node
– Travel to the atrioventricular (AV) node
• At the AV node, the impulses are delayed
– And then travel to the Purkinje fibers that make the ventricles contract
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• The impulses that travel during the cardiac cycle
– Can be recorded as an electrocardiogram (ECG or EKG)
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• The control of heart rhythm
Figure 42.8
SA node(pacemaker)
AV node Bundlebranches
Heartapex
Purkinjefibers
2 Signals are delayedat AV node.
1 Pacemaker generates wave of signals to contract.
3 Signals passto heart apex.
4 Signals spreadThroughoutventricles.
ECG
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• The pacemaker is influenced by
– Nerves, hormones, body temperature, and exercise
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• Concept 42.3: Physical principles govern blood circulation
• The same physical principles that govern the movement of water in plumbing systems
– Also influence the functioning of animal circulatory systems
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Blood Vessel Structure and Function
• The “infrastructure” of the circulatory system
– Is its network of blood vessels
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• All blood vessels
– Are built of similar tissues
– Have three similar layers
Figure 42.9
Artery Vein
100 µm
Artery Vein
ArterioleVenule
Connectivetissue
Smoothmuscle
Endothelium
Connectivetissue
Smoothmuscle
EndotheliumValve
Endothelium
Basementmembrane
Capillary
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• Structural differences in arteries, veins, and capillaries
– Correlate with their different functions
• Arteries have thicker walls
– To accommodate the high pressure of blood pumped from the heart
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• In the thinner-walled veins
– Blood flows back to the heart mainly as a result of muscle action
Figure 42.10
Direction of blood flowin vein (toward heart)
Valve (open)
Skeletal muscle
Valve (closed)
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Blood Flow Velocity
• Physical laws governing the movement of fluids through pipes
– Influence blood flow and blood pressure
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• The velocity of blood flow varies in the circulatory system
– And is slowest in the capillary beds as a result of the high resistance and large total cross-sectional area
Figure 42.11
5,0004,0003,0002,0001,000
0
Aor
ta
Arte
ries
Arte
riole
s
Cap
illar
ies
Ven
ules
Vei
ns
Ven
ae c
avae
Pre
ssur
e (m
m H
g)V
eloc
ity (c
m/s
ec)
Are
a (c
m2 )
Systolicpressure
Diastolicpressure
50403020100
120100
806040200
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Blood Pressure
• Blood pressure
– Is the hydrostatic pressure that blood exerts against the wall of a vessel
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• Systolic pressure
– Is the pressure in the arteries during ventricular systole
– Is the highest pressure in the arteries
• Diastolic pressure
– Is the pressure in the arteries during diastole
– Is lower than systolic pressure
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• Blood pressure
– Can be easily measured in humans
Figure 42.12
Artery
Rubber cuffinflatedwith air
Arteryclosed
120 120
Pressurein cuff above 120
Pressurein cuff below 120
Pressurein cuff below 70
Sounds audible instethoscope
Sounds stop
Blood pressurereading: 120/70
A typical blood pressure reading for a 20-year-oldis 120/70. The units for these numbers are mm of mercury (Hg); a blood pressure of 120 is a force that can support a column of mercury 120 mm high.
1
A sphygmomanometer, an inflatable cuff attached to apressure gauge, measures blood pressure in an artery.The cuff is wrapped around the upper arm and inflated until the pressure closes the artery, so that no blood flows past the cuff. When this occurs, the pressure exerted by the cuff exceeds the pressure in the artery.
2 A stethoscope is used to listen for sounds of blood flow below the cuff. If the artery is closed, there is no pulse below the cuff. The cuff is gradually deflated until blood begins to flow into the forearm, and sounds from blood pulsing into the artery below the cuff can be heard with the stethoscope. This occurs when the blood pressure is greater than the pressure exerted by the cuff. The pressure at this point is the systolic pressure.
3
The cuff is loosened further until the blood flows freely through the artery and the sounds below the cuff disappear. The pressure at this point is the diastolic pressure remaining in the artery when the heart is relaxed.
4
70
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• Blood pressure is determined partly by cardiac output
– And partly by peripheral resistance due to variable constriction of the arterioles
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Capillary Function
• Capillaries in major organs are usually filled to capacity
– But in many other sites, the blood supply varies
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• Two mechanisms
– Regulate the distribution of blood in capillary beds
• In one mechanism
– Contraction of the smooth muscle layer in the wall of an arteriole constricts the vessel
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• In a second mechanism
– Precapillary sphincters control the flow of blood between arterioles and venules
Figure 42.13 a–c
Precapillary sphincters Thoroughfarechannel
ArterioleCapillaries
Venule(a) Sphincters relaxed
(b) Sphincters contractedVenuleArteriole
(c) Capillaries and larger vessels (SEM)
20 m
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• The critical exchange of substances between the blood and interstitial fluid
– Takes place across the thin endothelial walls of the capillaries
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• The difference between blood pressure and osmotic pressure
– Drives fluids out of capillaries at the arteriole end and into capillaries at the venule end
At the arterial end of acapillary, blood pressure is
greater than osmotic pressure,and fluid flows out of the
capillary into the interstitial fluid.
Capillary Redbloodcell
15 m
Tissue cell INTERSTITIAL FLUID
CapillaryNet fluidmovement out
Net fluidmovement in
Direction of blood flow
Blood pressureOsmotic pressure
Inward flow
Outward flow
Pre
ssur
e
Arterial end of capillary Venule end
At the venule end of a capillary, blood pressure is less than osmotic pressure, and fluid flows from the interstitial fluid into the capillary.
Figure 42.14
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Fluid Return by the Lymphatic System
• The lymphatic system
– Returns fluid to the body from the capillary beds
– Aids in body defense
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• Fluid reenters the circulation
– Directly at the venous end of the capillary bed and indirectly through the lymphatic system
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• Concept 42.4: Blood is a connective tissue with cells suspended in plasma
• Blood in the circulatory systems of vertebrates
– Is a specialized connective tissue
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Blood Composition and Function
• Blood consists of several kinds of cells
– Suspended in a liquid matrix called plasma
• The cellular elements
– Occupy about 45% of the volume of blood
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Plasma
• Blood plasma is about 90% water
• Among its many solutes are
– Inorganic salts in the form of dissolved ions, sometimes referred to as electrolytes
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• The composition of mammalian plasmaPlasma 55%
Constituent Major functions
Water Solvent forcarrying othersubstances
SodiumPotassiumCalciumMagnesiumChlorideBicarbonate
Osmotic balancepH buffering, andregulation of membranepermeability
Albumin
Fibringen
Immunoglobulins(antibodies)
Plasma proteins
Icons (blood electrolytes
Osmotic balance,pH buffering
Substances transported by bloodNutrients (such as glucose, fatty acids, vitamins)Waste products of metabolismRespiratory gases (O2 and CO2)Hormones
Defense
Figure 42.15
Separatedbloodelements
Clotting
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• Another important class of solutes is the plasma proteins
– Which influence blood pH, osmotic pressure, and viscosity
• Various types of plasma proteins
– Function in lipid transport, immunity, and blood clotting
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Cellular Elements
• Suspended in blood plasma are two classes of cells
– Red blood cells, which transport oxygen
– White blood cells, which function in defense
• A third cellular element, platelets
– Are fragments of cells that are involved in clotting
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Figure 42.15
Cellular elements 45%
Cell type Numberper L (mm3) of blood
Functions
Erythrocytes(red blood cells) 5–6 million Transport oxygen
and help transportcarbon dioxide
Leukocytes(white blood cells)
5,000–10,000 Defense andimmunity
Eosinophil
Basophil
Platelets
NeutrophilMonocyte
Lymphocyte
250,000400,000
Blood clotting
• The cellular elements of mammalian blood
Separatedbloodelements
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Erythrocytes
• Red blood cells, or erythrocytes
– Are by far the most numerous blood cells
– Transport oxygen throughout the body
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Leukocytes
• The blood contains five major types of white blood cells, or leukocytes
– Monocytes, neutrophils, basophils, eosinophils, and lymphocytes, which function in defense by phagocytizing bacteria and debris or by producing antibodies
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Platelets
• Platelets function in blood clotting
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Stem Cells and the Replacement of Cellular Elements
• The cellular elements of blood wear out
– And are replaced constantly throughout a person’s life
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• Erythrocytes, leukocytes, and platelets all develop from a common source
– A single population of cells called pluripotent stem cells in the red marrow of bones
B cells T cells
Lymphoidstem cells
Pluripotent stem cells(in bone marrow)
Myeloidstem cells
Erythrocytes
Platelets Monocytes
Neutrophils
Eosinophils
Basophils
Lymphocytes
Figure 42.16
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Blood Clotting
• When the endothelium of a blood vessel is damaged
– The clotting mechanism begins
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• A cascade of complex reactions
– Converts fibrinogen to fibrin, forming a clot
Plateletplug
Collagen fibers
Platelet releases chemicalsthat make nearby platelets sticky
Clotting factors from:PlateletsDamaged cellsPlasma (factors include calcium, vitamin K)
Prothrombin Thrombin
Fibrinogen Fibrin5 µm
Fibrin clot Red blood cell
The clotting process begins when the endothelium of a vessel is damaged, exposing connective tissue in the vessel wall to blood. Plateletsadhere to collagen fibers in the connective tissue and release a substance thatmakes nearby platelets sticky.
1 The platelets form a plug that providesemergency protectionagainst blood loss.
2 This seal is reinforced by a clot of fibrin when vessel damage is severe. Fibrin is formed via amultistep process: Clotting factors released fromthe clumped platelets or damaged cells mix withclotting factors in the plasma, forming an activation cascade that converts a plasma proteincalled prothrombin to its active form, thrombin.Thrombin itself is an enzyme that catalyzes the final step of the clotting process, the conversion of fibrinogen to fibrin. The threads of fibrin become interwoven into a patch (see colorized SEM).
3
Figure 42.17
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Cardiovascular Disease
• Cardiovascular diseases
– Are disorders of the heart and the blood vessels
– Account for more than half the deaths in the United States
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• One type of cardiovascular disease, atherosclerosis
– Is caused by the buildup of cholesterol within arteries
Figure 42.18a, b
(a) Normal artery (b) Partly clogged artery50 µm 250 µm
Smooth muscleConnective tissue Endothelium Plaque
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• Hypertension, or high blood pressure
– Promotes atherosclerosis and increases the risk of heart attack and stroke
• A heart attack
– Is the death of cardiac muscle tissue resulting from blockage of one or more coronary arteries
• A stroke
– Is the death of nervous tissue in the brain, usually resulting from rupture or blockage of arteries in the head
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• Concept 42.5: Gas exchange occurs across specialized respiratory surfaces
• Gas exchange
– Supplies oxygen for cellular respiration and disposes of carbon dioxide
Figure 42.19
Organismal level
Cellular level
Circulatory system
Cellular respiration ATPEnergy-richmoleculesfrom food
Respiratorysurface
Respiratorymedium(air of water)
O2 CO2
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• Animals require large, moist respiratory surfaces for the adequate diffusion of respiratory gases
– Between their cells and the respiratory medium, either air or water
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Gills in Aquatic Animals
• Gills are outfoldings of the body surface
– Specialized for gas exchange
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• In some invertebrates
– The gills have a simple shape and are distributed over much of the body
(a) Sea star. The gills of a sea star are simple tubular projections of the skin. The hollow core of each gillis an extension of the coelom(body cavity). Gas exchangeoccurs by diffusion across thegill surfaces, and fluid in thecoelom circulates in and out ofthe gills, aiding gas transport. The surfaces of a sea star’s tube feet also function in gas exchange.
Gills
Tube foot
Coelom
Figure 42.20a
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• Many segmented worms have flaplike gills
– That extend from each segment of their body
Figure 42.20b
(b) Marine worm. Many polychaetes (marine worms of the phylum Annelida) have a pair of flattened appendages called parapodia on each body segment. The parapodia serve as gillsand also function incrawling and swimming.
Gill
Parapodia
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• The gills of clams, crayfish, and many other animals
– Are restricted to a local body region
Figure 42.20c, d
(d) Crayfish. Crayfish and other crustaceanshave long, feathery gills covered by the exoskeleton. Specialized body appendagesdrive water over the gill surfaces.
(c) Scallop. The gills of a scallop are long, flattened plates that project from themain body mass inside the hard shell.Cilia on the gills circulate water around the gill surfaces.
Gills
Gills
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• The effectiveness of gas exchange in some gills, including those of fishes
– Is increased by ventilation and countercurrent flow of blood and water
Countercurrent exchange
Figure 42.21
Gill arch
Water flow Operculum
Gill arch
Blood vessel
Gillfilaments
Oxygen-poorblood
Oxygen-richblood
Water flowover lamellaeshowing % O2
Blood flowthrough capillariesin lamellaeshowing % O2
Lamella
100%
40%
70%
15%
90%
60%
30% 5%
O2
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Figure 42.22a
Tracheae
Air sacs
Spiracle
(a) The respiratory system of an insect consists of branched internaltubes that deliver air directly to body cells. Rings of chitin reinforcethe largest tubes, called tracheae, keeping them from collapsing. Enlarged portions of tracheae form air sacs near organs that require a large supply of oxygen. Air enters the tracheae through openings called spiracles on the insect’s body surface and passes into smaller tubes called tracheoles. The tracheoles are closed and contain fluid(blue-gray). When the animal is active and is using more O2, most ofthe fluid is withdrawn into the body. This increases the surface area of air in contact with cells.
Tracheal Systems in Insects
• The tracheal system of insects
– Consists of tiny branching tubes that penetrate the body
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• The tracheal tubes
– Supply O2 directly to body cellsAirsac
Body cell
Trachea
Tracheole
Tracheoles MitochondriaMyofibrils
Body wall
(b) This micrograph shows crosssections of tracheoles in a tinypiece of insect flight muscle (TEM).Each of the numerous mitochondriain the muscle cells lies within about5 µm of a tracheole.
Figure 42.22b 2.5 µm
Air
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Lungs
• Spiders, land snails, and most terrestrial vertebrates
– Have internal lungs
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Mammalian Respiratory Systems: A Closer Look
• A system of branching ducts
– Conveys air to the lungsBranch from the pulmonary vein (oxygen-rich blood) Terminal bronchiole
Branch from thepulmonaryartery(oxygen-poor blood)
Alveoli
Colorized SEMSEM
50 µ
m
50 µ
m
Heart
Left lung
Nasalcavity
Pharynx
Larynx
Diaphragm
Bronchiole
Bronchus
Right lung
TracheaEsophagus
Figure 42.23
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• In mammals, air inhaled through the nostrils
– Passes through the pharynx into the trachea, bronchi, bronchioles, and dead-end alveoli, where gas exchange occurs
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• Concept 42.6: Breathing ventilates the lungs
• The process that ventilates the lungs is breathing
– The alternate inhalation and exhalation of air
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How an Amphibian Breathes
• An amphibian such as a frog
– Ventilates its lungs by positive pressure breathing, which forces air down the trachea
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How a Mammal Breathes
• Mammals ventilate their lungs
– By negative pressure breathing, which pulls air into the lungs
Air inhaled Air exhaled
INHALATIONDiaphragm contracts
(moves down)
EXHALATIONDiaphragm relaxes
(moves up)
Diaphragm
Lung
Rib cage expands asrib muscles contract
Rib cage gets smaller asrib muscles relax
Figure 42.24
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• Lung volume increases
– As the rib muscles and diaphragm contract
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How a Bird Breathes
• Besides lungs, bird have eight or nine air sacs
– That function as bellows that keep air flowing through the lungs
INHALATIONAir sacs fill
EXHALATIONAir sacs empty; lungs fill
Anteriorair sacs
Trachea
Lungs LungsPosteriorair sacs
Air Air
1 mm
Air tubes(parabronchi)in lung
Figure 42.25
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• Air passes through the lungs
– In one direction only
• Every exhalation
– Completely renews the air in the lungs
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Control of Breathing in Humans
• The main breathing control centers
– Are located in two regions of the brain, the medulla oblongata and the pons
Figure 42.26
PonsBreathing control centers Medulla
oblongata
Diaphragm
Carotidarteries
Aorta
Cerebrospinalfluid
Rib muscles
In a person at rest, these nerve impulses result in
about 10 to 14 inhalationsper minute. Between
inhalations, the musclesrelax and the person exhales.
The medulla’s control center also helps regulate blood CO2 level. Sensors in the medulla detect changes in the pH (reflecting CO2
concentration) of the blood and cerebrospinal fluid bathing the surface of the brain.
Nerve impulses relay changes in
CO2 and O2 concentrations. Other sensors in the walls of the aortaand carotid arteries in the neck detect changes in blood pH andsend nerve impulses to the medulla. In response, the medulla’s breathingcontrol center alters the rate anddepth of breathing, increasing bothto dispose of excess CO2 or decreasingboth if CO2 levels are depressed.
The control center in themedulla sets the basic
rhythm, and a control centerin the pons moderates it,
smoothing out thetransitions between
inhalations and exhalations.
1
Nerve impulses trigger muscle contraction. Nerves
from a breathing control centerin the medulla oblongata of the
brain send impulses to thediaphragm and rib muscles, stimulating them to contract
and causing inhalation.
2
The sensors in the aorta andcarotid arteries also detect changesin O2 levels in the blood and signal the medulla to increase the breathing rate when levels become very low.
6
5
3
4
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• The centers in the medulla
– Regulate the rate and depth of breathing in response to pH changes in the cerebrospinal fluid
• The medulla adjusts breathing rate and depth
– To match metabolic demands
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• Sensors in the aorta and carotid arteries
– Monitor O2 and CO2 concentrations in the blood
– Exert secondary control over breathing
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• Concept 42.7: Respiratory pigments bind and transport gases
• The metabolic demands of many organisms
– Require that the blood transport large quantities of O2 and CO2
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The Role of Partial Pressure Gradients
• Gases diffuse down pressure gradients
– In the lungs and other organs
• Diffusion of a gas
– Depends on differences in a quantity called partial pressure
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• A gas always diffuses from a region of higher partial pressure
– To a region of lower partial pressure
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• In the lungs and in the tissues
– O2 and CO2 diffuse from where their partial pressures are higher to where they are lower
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Inhaled air Exhaled air
160 0.2O2 CO2
O2 CO2
O2 CO2
O2 CO2 O2 CO2
O2 CO2 O2 CO2
O2 CO2
40 45
40 45
100 40
104 40
104 40
120 27
CO2O2
Alveolarepithelialcells
Pulmonaryarteries
Blood enteringalveolar
capillaries
Blood leavingtissue
capillaries
Blood enteringtissue
capillaries
Blood leaving
alveolar capillaries
CO2O2
Tissue capillaries
Heart
Alveolar capillaries
of lung
<40 >45
Tissue cells
Pulmonaryveins
Systemic arteriesSystemic
veinsO2CO2
O2
CO2
Alveolar spaces
12
43
Figure 42.27
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Respiratory Pigments
• Respiratory pigments
– Are proteins that transport oxygen
– Greatly increase the amount of oxygen that blood can carry
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Oxygen Transport
• The respiratory pigment of almost all vertebrates
– Is the protein hemoglobin, contained in the erythrocytes
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• Like all respiratory pigments
– Hemoglobin must reversibly bind O2, loading O2 in the lungs and unloading it in other parts of the body
Heme group Iron atom
O2 loadedin lungs
O2 unloadedIn tissues
Polypeptide chain
O2
O2
Figure 42.28
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• Loading and unloading of O2
– Depend on cooperation between the subunits of the hemoglobin molecule
• The binding of O2 to one subunit induces the other subunits to bind O2 with more affinity
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• Cooperative O2 binding and release
– Is evident in the dissociation curve for hemoglobin
• A drop in pH
– Lowers the affinity of hemoglobin for O2
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O2 unloaded fromhemoglobinduring normalmetabolism
O2 reserve that canbe unloaded fromhemoglobin totissues with highmetabolism
Tissues duringexercise
Tissuesat rest
100
80
60
40
20
0
100
80
60
40
20
0
100806040200
100806040200
Lungs
PO2 (mm Hg)
PO2 (mm Hg)
O2 s
atur
atio
n of
hem
oglo
bin
(%)
O2 s
atur
atio
n of
hem
oglo
bin
(%)
Bohr shift:Additional O2
released from hemoglobin at lower pH(higher CO2
concentration)
pH 7.4
pH 7.2
(a) PO2 and Hemoglobin Dissociation at 37°C and pH 7.4
(b) pH and Hemoglobin Dissociation
Figure 42.29a, b
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Carbon Dioxide Transport
• Hemoglobin also helps transport CO2
– And assists in buffering
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• Carbon from respiring cells
– Diffuses into the blood plasma and then into erythrocytes and is ultimately released in the lungs
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Figure 42.30
Tissue cell
CO2Interstitialfluid
CO2 producedCO2 transportfrom tissues
CO2
CO2
Blood plasmawithin capillary Capillary
wall
H2O
Redbloodcell
HbCarbonic acidH2CO3
HCO3– H++
Bicarbonate
HCO3–
Hemoglobinpicks up
CO2 and H+
HCO3–
HCO3– H++
H2CO3Hb
Hemoglobinreleases
CO2 and H+
CO2 transportto lungs
H2OCO2
CO2
CO2
CO2
Alveolar space in lung
2
1
34
5 6
7
8
9
10
11
To lungs
Carbon dioxide produced bybody tissues diffuses into the interstitial fluid and the plasma.
Over 90% of the CO2 diffuses into red blood cells, leaving only 7%in the plasma as dissolved CO2.
Some CO2 is picked up and transported by hemoglobin.
However, most CO2 reacts with water in red blood cells, forming carbonic acid (H2CO3), a reaction catalyzed bycarbonic anhydrase contained. Withinred blood cells.
Carbonic acid dissociates into a biocarbonate ion (HCO3
–) and a hydrogen ion (H+).
Hemoglobin binds most of the H+ from H2CO3 preventing the H+ from acidifying the blood and thuspreventing the Bohr shift.
CO2 diffuses into the alveolarspace, from which it is expelledduring exhalation. The reductionof CO2 concentration in the plasmadrives the breakdown of H2CO3 Into CO2 and water in the red bloodcells (see step 9), a reversal of the reaction that occurs in the tissues (see step 4).
Most of the HCO3– diffuse
into the plasma where it is carried in the bloodstream to the lungs.
In the HCO3– diffuse
from the plasma red blood cells, combining with H+ released from hemoglobin and forming H2CO3.
Carbonic acid is converted back into CO2 and water.
CO2 formed from H2CO3 is unloadedfrom hemoglobin and diffuses into the interstitial fluid.
1
2
3
4
5
6
7
8
9
10
11
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Elite Animal Athletes
• Migratory and diving mammals
– Have evolutionary adaptations that allow them to perform extraordinary feats
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The Ultimate Endurance Runner
• The extreme O2 consumption of the antelope-like pronghorn
– Underlies its ability to run at high speed over long distances
Figure 42.31
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Diving Mammals
• Deep-diving air breathers
– Stockpile O2 and deplete it slowly