Topic 3: Gas Exchange in Fish

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Presentation transcript:

Topic 3: Gas Exchange in Fish By the end of the lesson you should be able to: Label a diagram to show the gill lamellae and gill filaments of a fish Understand what counter-current flow is, and why it is useful

Fish Anatomy Mouth (Buccal Cavity) Operculum Buccal Floor

…lie the gills – the fish’s equivalent of our lungs Behind the Operculum… …lie the gills – the fish’s equivalent of our lungs

Gill Structure Gill arches Gill filaments Lamellae Large surface area

Adaptations of the gills for efficient gas exchange Large surface area : volume - allows more diffusion Permeable membranes - allows gases to diffuse Thin (flattened cells) - short diffusion distance Good vascular (blood) supply - maintains concentration gradients

Counter Current Principle Oxygen content of water is much lower than air, so fish have to be especially well adapted to take oxygen into their blood Fish use a system called counter current flow where by the water and the blood flow in opposite directions over the gills

Concurrent flow = blood and water in same direction When the blood first comes close to the water, the water is fully saturated with oxygen and the blood has very little. There is therefore a very large concentration gradient and oxygen diffuses out of the water and into the blood. As you move along the lamella, the water is slightly less saturated and blood slightly more but the water still has more oxygen in it so it diffuses from water to blood. This continues until the water and the blood have reached equal saturation. After this the blood can pick up no more oxygen from the water because there is no more concentration gradient. The maximum saturation of the water is 100% so the maximum saturation of the blood is 50%.

Counter current flow = blood and water flow in opposite directions As the blood flows in the opposite direction to the water, it always flows next to water that has given up less of its oxygen. This way, the blood is absorbing more and more oxygen as it moves along. Even as the blood reaches the end of the lamella and is 80% or so saturated with oxygen, it is flowing past water which is at the beginning of the lamella and is 90 or 100% saturated. Therefore, even when the blood is highly saturated, having flowed past most of the length of the lamellae, there is still a concentration gradient and it can continue to absorb oxygen from the water.

Counter Current Principle

Check your understanding Fish questions