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Gas Exchange

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Title: Gas Exchange


1
Gas Exchange
  • By Zoe Kopp-Weber

2
Coevolution of circulatory and respiratory systems
  • Allowed for vertebrates to develop larger bodies
    and locomotion.
  • As these abilities grew, the need for efficient
    delivery of nutrients and O2 and removal of
    wastes and CO2 from the growing mass of tissues
    grew too.

3
Coevolution of circulatory and respiratory
systems (cont.)
  • Gills developed in fish and with it the 4-chamber
    heart, one of the major evolutionary innovations
    in vertebrates.
  • Mammals, birds and crocodiles also have a
    4-chamber heart, with 2 separate atria and 2
    separate ventricles.
  • Right atrium receives deoxygenated blood and
    sends it to right ventricle which pumps blood to
    lungs. Left atrium receives oxygenated blood and
    delivers it to the left ventricle to pump the
    blood to the rest of the body.

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  • For most multicellular animals, gas exchange
    requires special respiratory organs which provide
    intimate contact between gases in the external
    environment and the circulatory system.

6
  • Respiration describes the uptake of O2 from the
    environment and disposal of CO2 into the
    environment at a body system level.
  • Cellular respiration internal respiration
  • Gas exchange external respiration
  • Communication between internal and external
    respiration is provided by the circulatory system.

7
  • Respiration involves processes ranging from the
    mechanics of breathing to the exchange of O2 and
    CO2 in respiratory organs.
  • Respiratory organs
  • Invertebrates epithelium, trachae and gills
  • Fish and larval amphibians gills
  • Other amphibians skin or epithelia used as
    supplemental/primary external respiratory organ.
  • Mammals, birds, reptiles, adult amphibians lungs

8
  • Respiration involves the diffusion of gases
    across the plasma membrane
  • Which must be surrounded by water to be stable.
  • Thus the external environment is always aqueous,
    even in terrestrial animals.

9
  • Rate of diffusion between 2 sides of the membrane
    has a relationship called Fricks Law of
    Diffusion
  • RD x A delta p/d
  • R rate
  • D diffusion constant
  • A area diffusion occurs
  • Delta p difference in concentration btw interior
    of organism and external environment
  • d distance across diffusion occurs

10
  • Evolution has optimized R via increased surface
    area, decreased distance and increased
    concentration difference.
  • Levels of O2 required cant be obtained by
    diffusion alone over distances greater than 0.5
    mm.
  • Vertebrates decreased this distance through the
    development of respiratory organs and bringing
    the external environment closer to the internal
    fluid

11
  • Dry air is composed of 78.09 N, 20.95 O2, 0.93
    Ar and other inert gases, and 0.03 CO2.
  • This composition remains constant at altitudes of
    at least 100 km but the amount of air decreases
    as the altitude goes up.
  • Humans dont survive long over 6000 meters,
    though the same composition of O2 is there, the
    atmospheric pressure brings it to only half the
    amount of 02 than whats at sea level.

12
  • Though gills are effective in aquatic
    environments, there are two reasons terrestrial
    animals replaced gills with other respiratory
    organs.
  • 1. Air is less buoyant than water. Gills collapse
    out of water while internal air passages remain
    open because the body provides structural
    support.
  • 2. Water diffuses into air via evaporation.
    Terrestrial animals are constantly surrounded by
    air and therefore lose H2O. Gills would provide a
    large surface area for H2O loss.

13
Terrestrial respiratory organs
  • Trachae used by insects and is a network of
    air-filled tubular passages.
  • Lung moves air through branched tubular
    passages. Air is saturated with H2O before
    reaching a thin, wet membrane that allows gas
    exchange.
  • All but birds use a uniform pool of air
  • Moves in and out of the same airway passages

14
  • Mammals have higher metabolic rates so they
    require a more efficient respiratory system.
  • Lungs are packed with tiny, grape-like sacs
    called alveoli. Air is inhaled through
    mouth/nose, past the pharynx to the larynx where
    it then passes through the glottis and into the
    trachea.

15
  • The trachea splits into right and left bronchi
    which enter into each lung and subdivide into
    bronchioles that deliver air into the alveoli.
  • All gas exchange btw air and blood occurs across
    walls of alveoli.

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  • Visceral pleural membrane a thin membrane that
    covers the outside of each lung.
  • Parietal pleural membrane lines the inner wall
    of the thoracic cavity.
  • Pleural cavity the space between these two
    membranes, very small and filled with fluid.
  • Fluid allows membranes to adhere to each other,
    coupling the lungs to the thoracic cavity.
  • Pleural membranes package each lung separately so
    if one should collapse, the other can function.

18
Mechanics of breathing
  • In all terrestrial vertebrates but amphibians,
    air is drawn into the lungs by subatmospheric
    pressure.
  • Boyles Law when the volume of a given quantity
    of gas increases, its pressure decreases.
  • When inhaling, volume of thorax is increased and
    the lungs expand. Lowered pressure in lungs
    allows air to enter.

19
  • Diaphragm a muscle that increases thoracic
    volume by contracting.
  • When it contracts, it assumes a flattened shape
    and lowers, expanding the volume of the thorax
    and lungs while adding pressure onto the abdomen.
  • External intercostal muscles also contributes
    in increasing thoracic volume.
  • These muscles between the ribs contract, causing
    the ribcage to expand.

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  • The thorax and lungs have a degree of elasticity.
  • They resists distension and recoil when
    distending force subsides.

22
Breathing measurements
  • At rest, each breath moves a tidal volume of 500
    mL of air in and out of the lungs.
  • 150 mL in trachea, bronchi and bronchioles where
    no gas exchange occurs.
  • Anatomical dead space, air here mixes with fresh
    air during inhalation.
  • Maximum amount of air expired after a maximum
    inhalation is called the vital capacity.
  • Averages 4.6 liters in young men and 3.1 liters
    in young women.

23
  • Hypoventilating - when breathing is insufficient
    to maintain normal blood gas measurements.
  • Hyperventilating when breathing is excessive
    for a particular metabolic rate.
  • Increased breathing after exercise isnt
    necessarily hyperventilating because faster
    breathing is matched to faster metabolic rate and
    blood gas measurements remain normal.

24
Mechanism regulating breathing
  • Each breath initiated by a respiratory
    controntrol center in the medulla oblongata.
  • Neurons send impulses that stimulate muscles to
    contract and expand the chest cavity.
  • Though controlled automatically, these controls
    can be overridden by, for example, holding ones
    breath.

25
  • A fall in blood pH stimulates neurons in aortic
    and carotid bodies
  • These are sensory structures known as peripheral
    chemoreceptors in the aorta and carotid artery.
  • Send impulses to the respiratory control center
    in the medulla oblongata, which stimulates
    increased breathing.
  • responsible for immediate stimulation when the
    blood partial CO2 pressure rises.

26
  • Central chemoreceptors responsible for
    sustained increase in ventilation if partial CO2
    pressure remains elevated. Increased respiratory
    rate acts to eliminate extra CO2, bringing blood
    pH to normal.

27
Hemoglobin and gas transport
  • When O2 diffuses from alveoli into blood, the
    circulatory system then delivers the O2 to
    tissues for respiration and carries away the CO2.
  • Amount of O2 dissolved in blood plasma depends
    directly on the partial O2 pressure or the air in
    the alveoli.
  • When lungs function normally, the blood plasma
    leaving the lungs have almost as much DO as
    possible.
  • Whole body carries almost 200 mL/L of O2, most is
    bound to molecules of hemoglobin inside red blood
    cells.

28
  • Hemoglobin - protein composed of four polypeptide
    chains and four organic compounds (heme groups).
  • Each heme group has an iron atom at the center,
    able to bind to a molecule of O2.
  • Allows hemoglobin to carry four molecules of O2.

29
  • Hemoglobin loaded with O2 forms oxyhemoglobin.
  • Bright red, tomato juice color
  • As blood passes capillaries, some oxyhemoglobin
    releases oxygen, becoming deoxyhemoglobin
  • Dark red but gives tissues a bluish tinge.

30
  • Red color,
  • oxygenated
  • Blue color,
  • oxygen-depleted

31
  • Hemoglobin is used by all vertebrates, and also
    by many invertebrates
  • Other invertebrates use hemocyanin as an
    oxygen-carrier
  • O2 binds to copper rather than iron.
  • Not found in blood cells but rather dissolved in
    circulating fluid of invertebrates

32
Oxygen transport
  • As blood travels through the systemic blood
    capillaries, O2 leaves the blood and diffuses
    into tissues.
  • 1/5 of O2 is unloaded in tissues, 4/5 in blood as
    a reserve.
  • The reserve allows the blood to supply the body
    O2 during exercise.
  • Also ensures enough O2 to maintain life 4-5
    minutes if breathing is interrupted or the heart
    stops.

33
  • O2 transport affected by
  • CO2 produced by metabolizing tissues, it
    combines with H2O forming carbonic acid. This
    dissociates into bicarbonate and H, lowering
    blood pH.
  • Also reduces hemoglobins affinity for O2 and
    causes it to release O2 more readily.
  • This is all called the Bohr effect.
  • Increase in temperature has a similar effect.
  • Skeletal muscles produce CO2 quicker during
    exercise, producing heat.

34
Carbon Dioxide Transport
  • Systemic capillaries deliver O2 and remove CO2
    from tissues
  • Majority diffuses into red blood cells where its
    catalyzed with water to form carbonic acid
    (H2CO3)
  • Disassociates into bicarbonate and H and moves
    into the plasma, exchanging a chloride ion for a
    bicarbonate (chloride shift).
  • Removes large amounts of CO2 from plasma,
    facilitating diffusion of additional CO2 into
    plasma from surrounding tissues.

35
  • Blood carries CO2 to the lungs in this form.
  • CO2 diffuses out of red blood cells, into the
    alveoli and then leaves the body with exhalation.

36
Nitric Oxide Transport
  • Nitric oxide acts on many cells to change their
    shape/functions.
  • Causes blood vessels to expand by relaxing
    surrounding muscle cells.
  • Blood flow/pressure regulated by nitric oxide in
    bloodstream.

37
  • One hypothesis proposes hemoglobin carries super
    nitric oxide which is able to bind to cysteine in
    hemoglobin
  • Dumps CO2 and picks up O2 and NO in the lungs
  • To increase blood flow, hemoglobin can release
    super NO into blood, making blood vessels expand
  • Can also trap excess NO on vacant iron atoms,
    making blood vessels constrict.
  • Red blood cells return to lungs, hemoglobin dumps
    CO2 and regular NO. Then ready to picl up O2 and
    super NO.

38
Disease
  • Emphysema - usually caused by cigarette smoking,
    the vital capacity of the lungs is reduced and
    alveoli are destroyed.
  • Bronchitis - a respiratory infection affecting
    nose, sinus and throat, then moves on into the
    lungs. Cough produces an excess of mucus.
  • Pneumonia - inflammation of the lungs that can be
    caused by bacteria, viruses or fungi. Causes
    coughing, fever and it will likely make it harder
    to breathe.

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