Terrestrial vertebrates (amphibians, reptiles, birds, and mammals) use a pair of lungs to exchange oxygen and carbon dioxide between their tissues and the air.
Figure 18.104.22.168 Frog lungs
The frog's lungs are a pair of thin-walled sacs connected to the mouth through an opening, the glottis. The surface area of the lungs is increased by inner partitions which are richly supplied with blood vessels. The frog inflates its lungs by
- filling its mouth with air
- then closing its mouth
- closing the internal openings to its nostrils
- opening its glottis
- raising the floor of its mouth thus forcing air into the lungs.
The frog's skin serves as a supplementary organ of gas exchange. However, it must remain moist to do this, which is one reason that frogs, like other amphibians, live in moist places. The frog's circulatory system, which brings oxygen-depleted blood to its lungs (and skin) and takes oxygen-enriched blood away is described in a separate page.
Figure 22.214.171.124 Reptile lungs
The skin of reptiles is dry and scaly, so they can live in arid locations (although many do not). However, they cannot use their skin as an organ of gas exchange. Reptiles depend entirely on their lungs for this. Their lungs are considerably more efficient than those of amphibians.
- They have a much greater surface area for the exchange of gases.
- They are inflated and deflated by the bellowslike expansion and contraction of the rib cage.
While fresh air flows in and stale air out of the lizard's lungs, another reptile, the American alligator, uses a more efficient mechanism similar to that described below in birds.)
The lizard's circulatory system, which brings oxygen-depleted blood to its lungs and takes oxygen-enriched blood away is described in a separate page.
Figure 126.96.36.199 Bird lungs
Unlike reptiles, birds are homeothermic ("warm blooded"), maintaining a constant body temperature (usually around 40°C) despite wide fluctuations in the temperature of their surroundings. They maintain their body temperature with the heat produced by muscular activity. This depends, in turn, on a high rate of cellular respiration. So the demands on the gas-exchange efficiency of the lungs of a small, active bird are great.
Although the ventilation of bird lungs is similar to that of reptiles, their effectiveness is increased by the presence of air sacs. Although no gas exchange occurs in the air sacs, their arrangement increases the efficiency of lung ventilation by enabling fresh air to pass in one direction through the lungs during both inhalation and exhalation. The air sacs also aid in reducing the density of the body by substituting air for tissue or fluid in many places. Even some of the bird's bones are penetrated by air sacs.
Ventilation of mammalian lungs is assisted by the diaphragm - a muscular partition that divides the thoracic cavity from the abdominal cavity.