Gas Exchange

1. Gas Exchange Mr. Tamashiro

2. 6.4.1 Distinguish between ventilation, gas exchange and cell respiration. • Ventilation: • The flow of air in and out of the alveoli is called ventilation and has two stages: inspiration (or inhalation) and expiration (or exhalation). • Lungs are not muscular and cannot ventilate themselves, but instead the whole thorax moves and changes size, due to the action of two sets of muscles: the intercostal muscles and the diaphragm.

3. 6.4.1 Distinguish between ventilation, gas exchange and cell respiration. Gas Exchange: This is the diffusion of gases (oxygen and carbon dioxide) There are two sites for gas exchange (a)Alveoli: Oxygen diffuses into the blood from the alveoli and carbon dioxide diffuses from the blood into the alveoli (b)Tissues: Oxygen diffuses from blood into the cells and carbon dioxide diffuses from cells to the blood

4. 6.4.1 Distinguish between ventilation, gas exchange and cell respiration. • Cell Respiration • Aerobic respiration uses oxygen in the mitochondria and produces carbon dioxide • Anaerobic respiration does not use oxygen but still produces carbon dioxide

5. 6.4.2 Explain the need for a ventilation system. • A ventilation system is needed to maintain high concentration gradients in the alveoli. • The steep concentration gradient across the respiratory surface is maintained in two ways: • by blood flow on one side and • by air flow on the other side. • The ventilation system • replaces and diffuses oxygen (keeping the concentration high) and • removes carbon dioxide (keeping the concentration low). • This means oxygen can always diffuse down its concentration gradient from the air to the blood, while at the same time carbon dioxide can diffuse down its concentration gradient from the blood to the air.

6. 6.4.3 Describe the features of alveoli that adapt them to gas exchange. • This should include: • a large total surface area • a wall consisting of a single layer of flattened cells • a film of moisture and • a dense network of capillaries • Large surface area due to the combined spherical shape (600 million alveoli = 80 m2) • Flattened epithelial cells of alveoli and close association with capillaries • Short diffusion distance from alveoli to blood (0.5-1.0 um) • Dense capillary network • Moist surface for the solution of gases

7. Describe the features of alveoli that adapt them to gas exchange.

8. 6.4.4 Draw and label a diagram of the ventilation system, including trachea, lungs, bronchi, bronchioles and alveoli. (a) Trachea (b) Cartilage ring support (c) Bronchi (plural) Bronchus (single) (d) Lung (e) Heart (f) Sternum (g) Rib cage (h) Bronchioles (j) Alveoli (k) Diaphragm

9. 6.4.5 Explain the mechanism of ventilation of the lungs in terms of volume and pressure changes caused by the internal and external intercostal muscles, the diaphragm and abdominal muscles. The diaphragm contracts and flattens downwards. The external intercostal muscles contract, pulling the ribs up and out this increases the volume of the thorax this increases the lung and alveoli volume this decreases the pressure of air in the alveoli below atmospheric (Boyle's law)air flows in to equalize the pressure

10. 6.4.5 Explain the mechanism of ventilation of the lungs in terms of volume and pressure changes caused by the internal and external intercostal muscles, the diaphragm and abdominal muscles. • The diaphragm relaxes and curves upwards • the external intercostal muscles relax, allowing the ribs to fall • this decreases the volume of the thorax • this decreases the lung and alveoli volume • this increases the pressure of air in the alveoli above atmospheric (Boyle's law)air flows out to equalise the pressure. • The abdominal muscles contract, pushing the diaphragm upwards • The internal intercostal muscles contract, pulling the ribs downward • This gives a larger and faster expiration, used in exercise