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The Mechanics of Breathing
Breathing
•The mechanism by which mammals ventilate their lungs
•Air will flow from a region of higher pressure to a region of lower pressure
•There are two muscular structures that control air pressure inside our lungs
Muscles involved in breathing:
Intercostal Muscles
Diaphragm
Intercostal Muscles
•Muscles associated with the ventral surface of the rib cage•These muscles are found between the ribs•There are two kinds
Intercostal Muscles
•Located in the inside of the ribcase
Internal Intercostal Muscles
•Located in the outside of the ribcase
External Intercostal Muscles
Intercostal Muscles
X-Section of Intercostal Muscles
Diaphragm
•A muscle layer that separates
•the thoracic cavity (region of the lungs) from
•the abdominal cavity (region of the stomach and the liver)
Diaphragm
Found in all mammals
Prime function: to assist in the ventilation of the lungs
Works simultaneously with intercostal muscles
To produce breathing-related movements
How breathing works
Inhalation vs. Exhalation
Lungs
Diaphragm
Diaphragm
HOW BREATHING WORKS- Inhalation
•To inhale, the external intercostal muscles contract
•Intercostal muscles expand the rib cage, lifting it up and out
HOW BREATHING WORKS- Inhalation•the diaphragm contracts and pulls
downward in the thoracic cavity•This increases the volume of the thoracic
cavity, causing the lungs to expand.•How?
How Lungs Expand•The thoracic cavity is relatively airtight•An increase in its volume, produces a
decrease in air pressure within the cavity•This decrease in pressure draws the
flexible walls of the lungs outward into the thoracic cavity
•Therefore, the lungs expand
HOW BREATHING WORKS- Inhalation•As a result of this expansion, the air
pressure within the lungs is lower than the air pressure in the external environment
•Recall: Air will flow from a region of higher pressure to a region of lower pressure
•Therefore, air enters thelungs
HOW BREATHING WORKS- Exhalation•The diaphragm relaxes, returning to a
dome-shaped curve
HOW BREATHING WORKS- Exhalation•To exhale, the external intercostal
muscles relax•But the internal intercostal muscles
contract to help pull the ribcage back to its original shape and position
HOW BREATHING WORKS- Exhalation•These changes create a higher pressure
in the thoracic cavity•This causes the lungs
to shrink, which resultsin a higher pressurein the lungs
•Air then moves outthrough the trachea
Inhalation and Exhalation• Intercostal muscles
contract, lifting rib cage up and out
• Diaphragm contracts and pulls downward
• The lungs expand, air is sucked in
• Intercostal muscles relax• Diaphragm relaxes• The ribs fall downward
and inward • Diaphragm back into
dome shape, squeezing lungs and pushing air out
Exchange of Gases•Review Capillary network and gas
exchange
Composition of inspired and expired air under normal conditions
20.94% Oxygen0.04% Carbon Dioxide79.02% Nitrogen and Trace gases
16.49% Oxygen4.49% Carbon Dioxide79.02% Nitrogen and Trace gases
Lung Capacity
•The different volumes of air drawn in or pushed out by the lungs are distinguished
Tidal Volume
•The volume of air inhaled and exhaled in a normal breathing movement
Inspiratory Reserve Volume
•The additional volume of air that can be taken in, beyond a regular or tidal inhalation
Expiratory Reserve Volume
•The additional volume that can be forced out of the lungs, beyond a regular or tidal exhalation
Vital Capacity
•The total volume of gas that can be moved in or out of the lungs
•VC=Tidal volume+IRV+ERV
Residual Volume
•The amount of gas that remains in the lungs and the passageways of the respiratory system even after a full exhalation
•The residual volume never leaves the respiratory system
• If it did, the lungs and the respiratory passageways would collapse
• It has little value for gas exchange, because it is not exchanged with air from the external environment
Residual Volume
Respiratory Efficiency
•In mammals, the rate at which oxygen can be transferred into the blood stream for transport to the rest of the body
•There are factors that affect the respiratory efficiency
•Other animals have respiratory systems with special adaptations to help increase respiratory efficiency
•One adaptation is facilitated diffusion
The Respiratory System in Fish
•The gills of fish utilize counter-current flow•A very effective mechanism for removing the
maximum amount of oxygen from the water flowing over them
Gills & Gas Exchange: Counter-current Flow
•During counter-current flow, two types of fluids (blood and water) with different concentrations flow in opposite directions past one another
Oxygenated blood
Deoxygenated Blood
Counter-current Flow
•These two fluids (water and blood) are separated by thin membranes
Counter-current Flow•Fish gills consist of a
series of filaments supported by bony gill arches
•Each filament is covered with thin folds of tissue called lamella
•Blood flows across each lamella within a dense network of capillaries
Filament
Gill arch
Gill arch
Filament
Lamellae
High O2
Low O2
Counter-current Flow•Water is deflected over
the lamellae in a direction opposite the flow of blood in the capillaries
•Thus, the most highly oxygenated blood is brought close to the water that is just entering the gills and that has an even higher oxygen content than blood
Low Oxygen
Low Oxygen
High Oxygen
High Oxygen
Water flow
Blood flow
Vein-Oxygen poor blood
Artery-Oxygen rich blood
Counter-current Flow
•As the water flows over the lamellae, gradually losing its oxygen to the blood, it encounters blood that is also increasingly low in oxygen
• In this way, the gradient encouraging oxygen to move from the water into the blood is maintained across all the lamellae.
Low Oxygen
Low Oxygen
High Oxygen
High Oxygen
Water flow
Blood flow
Vein-Oxygen poor blood
Artery-Oxygen rich blood
Counter-current Flow
Low Oxygen
Low Oxygen
High Oxygen
High Oxygen
Water flow
Blood flow
Vein-Oxygen poor blood
Artery-Oxygen rich blood
Current vs. Counter-current Flow
Counter-current Flow
•Within each lamella, Counter-current flow enhances diffusion by maintaining a concentration gradient of oxygen between the water (relatively high in oxygen) and the blood (lower in oxygen)
•Countercurrent flow is so effective that some fish extract 85% of the oxygen from the water that flows over their gills.
Gas Exchange in Mammals
• In the mammalian lung, the oxygen gradient between the respiratory medium in the lungs and the blood in the capillaries is steadily reduced as oxygen passes across the alveoli wall
•The blood may take up about 50% of the oxygen in the respiratory medium entering the lungs
Gas Exchange in Fish
•In a countercurrent exchange system, the oxygen gradient is maintained over the whole of the gill
•The blood may take up as much as 80% of the oxygen carried in the respiratory medium entering the gill
The Respiratory System in Birds•Respiration in
birds is much different than in mammals.
•Birds do not have a diaphragm; instead, air is moved in and out of the respiratory system through pressure changes in the air sacs
Avian Respiratory System•Inhalation:•When the bird breathes in, the air
sacs expand•Most of the inhaled air passes into
the posterior air sacs•Some flow from there into the lungs•At the same time, the air
that was in the lungsmoves into the anteriorair sacs
Posterior air sacs
Anterior air sacs
Anterior air sacs
Lungs
Avian Respiratory System•Exhalation:•When the bird exhales, all the air
sacs contract, forcing the air in theposterior air sacs into the capillary-lined tubes of the lungs
•Gas exchange takes place in the lungs
•Then, the air from the anterior air sacsis forced out throughthe trachea
Posterior air sacs
Anterior air sacs
Anterior air sacs
Lungs