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Created by

Enahj Sey

Cards (29)

All living things obtain the energy they need by metabolizing energy-rich compounds, such as carbohydrates and fats
In the majority of organisms, this metabolism takes place by respiration, a process that requires oxygen
In the process, carbon dioxide gas is produced and must be removed from the body
In plant cells, carbon dioxide may appear to be a waste product of respiration, but because it is used in photosynthesis, carbon dioxide may be considered a by-product
Carbon dioxide must be available to plant cells, and oxygen gas must be removed
Gas exchange is an essential process in energy metabolism, and gas exchange is an essential prerequisite to life, because where energy is lacking, life cannot continue
Diffusion 
The movement of molecules from a region of greater concentration to a region of lesser concentration, in the direction following the concentration gradient
In living systems, the molecules move across cell membranes, which are continuously moistened by fluid
Single-celled organisms, such as bacteria and protozoa, are in constant contact with their external environment, and gas exchange occurs by diffusion across their membranes
Even in simple multicellular organisms, such as green algae, their cells may be close to the environment, and gas exchange can occur easily
In larger organisms, adaptations bring the environment closer to the cells
Adaptations in larger organisms
Liverworts have numerous air chambers in the internal environment
Sponges and hydras have water-filled central cavities
Planaria have branches of their gastrovascular cavity that connect with all parts of the body
In aquatic plants, water passes among the tissues and provides the medium for gas exchange
In terrestrial plants, air enters the tissues, and the gases diffuse into the moisture bathing the internal cells
In the leaf of the plant, an abundant supply of carbon dioxide must be present, and oxygen from photosynthesis must be removed
Gases do not pass through the cuticle of the leaf; they pass through pores called stomata in the cuticle and epidermis
Stomata are abundant on the lower surface of the leaf, and they normally open during the day when the rate of photosynthesis is highest
Physiological changes in the surrounding guard cells account for the opening and closing of the stomata
In animals, gas exchange follows the same general pattern as in plants, with oxygen and carbon dioxide moving by diffusion across moist membranes
In simple animals, the exchange occurs directly with the environment, but with complex animals, such as mammals, the exchange occurs between the environment and the blood, which then carries oxygen to deeply embedded cells and transports carbon dioxide out to where it can be removed from the body
Earthworms exchange oxygen and carbon dioxide directly through their skin, with the oxygen diffusing into tiny blood vessels in the skin surface, where it combines with the red pigment hemoglobin
Hemoglobin binds loosely to oxygen and carries it through the animal's bloodstream, while carbon dioxide is transported out to where it can be removed from the body
Stomata 
Abundant on the lower surface of the leaf
They normally open during the day when the rate of photosynthesis is highest
Physiological changes in the surrounding guard cells account for the opening and closing
Gas exchange in animals
1. Oxygen and carbon dioxide move by diffusion across moist membranes
2. In simple animals, the exchange occurs directly with the environment
3. In complex animals like mammals, the exchange occurs between the environment and the blood
4. Blood carries oxygen to deeply embedded cells and transports carbon dioxide out to where it can be removed from the body
Gas exchange in animals
Earthworms exchange oxygen and carbon dioxide directly through their skin
Terrestrial arthropods have spiracles that open into tracheae
Fishes use gills for gas exchange
Terrestrial vertebrates have lungs
Earthworms 
Oxygen diffuses into tiny blood vessels in the skin surface, where it combines with the red pigment hemoglobin
Hemoglobin binds loosely to oxygen and carries it through the animal's bloodstream
Carbon dioxide is transported back to the skin by the hemoglobin
Terrestrial arthropods 
Have a series of openings called spiracles at the body surface
Spiracles open into tiny air tubes called tracheae, which expand into fine branches that extend into all parts of the arthropod body
Fishes 
Use outward extensions of their body surface called gills for gas exchange
Gills are flaps of tissue richly supplied with blood vessels
As a fish swims, it draws water into its mouth and across the gills
Oxygen diffuses out of the water into the blood vessels of the gill, while carbon dioxide leaves the blood vessels and enters the water passing by the gills
Terrestrial vertebrates 
Have well-developed respiratory systems with lungs
Frogs swallow air into their lungs, where oxygen diffuses into the blood to join with hemoglobin in the red blood cells
Amphibians can also exchange gases through their skin
Reptiles have folded lungs to provide increased surface area for gas exchange
Rib muscles assist lung expansion and protect the lungs from injury
Birds have large air spaces called air sacs in their lungs
When a bird inhales, its rib cage spreads apart and a partial vacuum is created in the lungs
Air rushes into the lungs and then into the air sacs, where most of the gas exchange occurs
Mammals have lungs divided into millions of microscopic air sacs called alveoli
Each alveolus is surrounded by a rich network of blood vessels for transporting gases
Mammals have a dome-shaped diaphragm that separates the thorax from the abdomen, providing a separate chest cavity for breathing and pumping blood
During inhalation, the diaphragm contracts and flattens to create a partial vacuum in the lungs, causing the lungs to fill with air