Gas Exchange Study Notes PDF

Summary

These notes cover various aspects of gas exchange in animals, including multicellular gas exchange, the role of specialized structures like gills and lungs, countercurrent exchange, and characteristics of different respiratory systems across animal taxa. Information is detailed to support understanding the structure and function of different gas exchange systems.

Full Transcript

Gas Exchange: Animals
 Gas Exchange Across Respiratory
Surfaces
For gases to move across a membrane
involves diffusion
surface must be moist to dissolve gases
 Multicellular & Gas Diffusion
Oxygen will only penetrate < 0.5mm into a group of cells,

for most multicellular organisms sufficient O2 cannot be
obtained by diffusion across body surface alone.

God designed multicellular organisms to enhance gas
exchange through
1. Increasing ventilation[moving air/water around]
2. Increased vascularisation
3. Increasing surface area
4. Specialization of cells
5. Specific Oxygen carrying molecules
 1. Increasing ventilation[moving
air/water around]
To keep high gradient difference for O2/CO2,
many organisms create air or water currents that
continuously keep concentration of gases high at the
desired level for diffusion over the respiratory
surfaces e.g counter current systems
Done by, muscular activity causing
inhalation/exhalation, fish operculum beat and fish
swim, cilia beating
Carry gases away internally to keep gradient high.
e.g vascularisation/ moving internal fluids
 Ventilation of water in fish
Fish need water flow past the gills to keep a high
concentration of oxygen compared to their blood.
Mobile fish (such as tuna) swim with their mouth open to
continuously move water passed the gills
Most bony fish use pumping action to ventilate; some
can alternate
 2. Increasing surface area and
decreasing diffusion distance
Some multicellular organisms are flat and thin so
no cells are far from external supply e.g
flatworms, tapeworm, leaves
Specialized respiratory organs that increase the
surface area available for diffusion
– Gills, tracheae, and lungs
– These adaptations bring the external
environment (air or water) close to the internal
fluid such as blood or hemolymph, which is
circulated throughout the body
Maximization of Gas Diffusion
Maximization of Gas Diffusion
Gill diffusion using counter-current flow
 Specialized cells

Specialised tasks include carrying oxygen. E.g.
Red blood cell - only function is to carry oxygen.
 Gas attracting molecules

Molecules such as
haemoglobin [iron based in mammals and others] or
heamocyanin [copper based in arthropods and others]
leghemoglobin [in plants such as legumes]

chemically attract oxygen to increase their solubility. This
means that body fluids such as blood can absorb and
carry more oxygen than without.
 Hemoglobin
Oxygen has a low solubility; blood plasma
can only contain a maximum of 3mL O2
per liter
However, whole blood contains ~200mL
O2 per liter since most of the O2 in the
blood is bound to hemoglobin
O2 is transported by respiratory pigments
 Structural & functional
adaptations for gas exchange
What does this graph tell you?
 Mediums: Air vs Water
Carbon dioxide is more soluble than
Oxygen in water
The warmer the water the less oxygen is
dissolved
Oxygen concentration is 100x more
available in air than water.
e.g. air 20% O2 water 1-2% O2
Need more efficient gas exchange design when living in water
to extract sufficient oxygen. What design features are they?
 Gills
Gills are specialized extensions of tissue
that project into water
– External gills are not enclosed within body
structures; many fish and amphibian larvae
– External gills require constant movement to
ensure contact with fresh (high O2) water

axolotl
Gills
 Gills
In bony fishes, the gills are located
between the oral cavity and the opercular
cavities
These two cavities operate as pumps that
alternately expand
– Water is moved into the mouth, through the
gills and out of the fish through the open
operculum, or gill cover
 Videos
https://www.youtube.com/watch?v=_2kjL9
BV3SA
Bony fish have four gill
arches on each side of
their heads

Each gill arch is composed of
two rows of gill filaments, which
consist of lamellae, thin
membranous plates that project
out into the flow of water

Water flows past the lamellae in one
direction only; blood flows opposite to this
direction (countercurrent gas exchange)
 Maximization of Gas Diffusion

H 20

http://life.bio.sunysb.edu/marinebio/o2countercurrent.jp
g

Large surface area, high blood flow
Countercurrent exchange – deoxygenated blood flows in
one direction, while oxygenated blood flows in the other;
maintains a high concentration gradient
Countercurrent gas exchange
Blood circulation in fish
 Skin surface as a respiratory
organ
O2 and CO2 are able to diffuse across the
skin [mucous membranes] in some
vertebrates
– amphibians
– turtles
Requires skin to be constantly moisture
Supplements lung respiration
Tracheal systems in Arthropods
Tracheal systems are found in arthropods
Respiratory system consists of small, branched trachae, or air
ducts, which branch into tracheoles, a series of tubes which
transfer gases directly to cells.
Air enters into trachea through spiracles
Body fluid circulates around tracheal system, obtaining oxygen and
losing carbon dioxide, by diffusion
 Figure 42.22 Tracheal systems

Arthropod Gas exchange [Nelson txtbok]
 Lungs in terrestrial vertebrates
Air is less (structurally) supportive than water
Unlike gills, internal air passages such as trachea
and lungs can remain open because the body
provides the necessary structural support
Water evaporates
Terrestrial organisms constantly lose water to the
atmosphere; gills would provide an enormous
surface area for water loss
Most terrestrial exchange surfaces are internalised
are thin and highly vascular
protected and physically supported
prevent moisture loss. lung minimizes evaporation by
moving air through an internal tubular passage
 Lungs
Air drawn into the respiratory passages
becomes saturated with water vapor prior
to reaching the inner region of the lungs
A thin, wet membrane permits gas
exchange
A two-way flow system (gases move into
and out of lungs through same airway
passages)
 Air characteristics

Air contains a constant proportion of gases
– 78.09% nitrogen
– 20.95% oxygen
– 0.93% argon and other inert gases
– 0.03% carbon dioxide
Lungs work by changing air pressure.
Because of gravity, air exerts a downward
pressure (atmospheric pressure; 760mm Hg)
it enters the lungs which are at a lower
pressure
 Lungs of Amphibians
The lungs of amphibians are saclike
outpouchings of the gut
Surface area increased by folds
Amphibians breathe by forcing air into
their lungs: positive pressure breathing
Also use their body surface as a
respiratory organ. Thus it must be moist
and is convoluted
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Nostrils
Air
open
External
nostril
Buccal
cavity
Esophagu
s

Lung
s

a.

Nostrils
closed

Air

b.
 Lungs of Reptiles
Terrestrial reptiles have dry, scaly skins
which prevent surface respiration
Expand their rib cages by muscular
contraction; this creates a lower pressure
inside the lungs compared to the
atmosphere, which moves air into the
lungs: negative pressure breathing
Same in mammals
 Lungs of Mammals
Endothermic (“warm-blooded”) animals, such
as birds and mammals, require more efficient
respiratory systems than ectothermic
(“cold-blooded”) animals due to their increased
metabolic oxygen demands

The lungs of mammals are packed with millions
of alveoli, sites of gas exchange
– Provides lung with enormous surface area for
gas exchange
Lungs of Mammals
Maximization of Gas Diffusion

Large surface area/highly vascularised/moist
The alveolus (singular) is
composed of epithelium only 1
cell thick, and is surrounded by
capillaries with walls that are
also only 1 cell layer thick.

The distance across which gas
must diffuse is very small, only
0.5-1.5μm
 In summary: lung design
Alveoli are surrounded by an extensive
capillary network
Gas exchange between the air and blood
occurs across the thin walls of the alveoli
Red blood cells pass through capillaries in
single file; O2 from alveoli enters the red
blood cells and binds to hemoglobin
Surface area of respiratory system is
greatly enhanced; much more than
amphibians and reptiles
 Lungs of Birds
Most efficient respiration of all terrestrial
vertebrates
Gas exchange occurs in parabronchi
Air flows through the parabronchi in one
direction only
In other terrestrial vertebrates, inhaled
(fresh) air is mixed with O2-depleted air
from the previous breath
In birds, the unidirectional flow allows only
fresh air to enter the site of gas exchange
 Lungs of Birds
Respiration in birds
occurs in 2 cycles:
– 1. Inhaled air is drawn
in from the trachea into
posterior air sacs, and
exhaled into lungs
– 2. Air is drawn in from
the lungs into anterior
air sacs, and exhaled
through the trachea
http://people.eku.edu/ritchisong/birdrespiration.html
 Features of Gas exchange
surfaces are
1. Large SA
2. Moist
3. Vascularised
4. Thin
5. Ventilated
 Hemoglobin
Oxygen has a low solubility; blood plasma
can only contain a maximum of 3mL O2
per liter
However, whole blood contains ~200mL
O2 per liter since most of the O2 in the
blood is bound to hemoglobin
O2 is transported by respiratory pigments
– Bound to hemoglobin inside red blood cells
(all vertebrates, most inverts), or hemocyanin
in the plasma (arthropods and some molluscs)
Hemoglobin
 Heamoglobin
Hemoglobin acquires O2 in the alveolar
capillaries
– O2-bound haemoglobin (oxyhaemoglobin)
appears bright red
– Haemoglobin without O2 (deoxyhaemoglobin)
appears dark red, but has a bluish hue in
tissues
– Hemoglobin provides an oxygen reserve
Only 1/5 of oxygen is released to muscles by
oxyhemoglobin; the reminder serves as a reserve
during physical exertion, and ensures enough O2
to maintain life for 4-5 minutes if breathing is
interrupted or the heart stops
In Summary: Types of gas exchange structures/designs