Exchange surfaces
Cards (18)
- Multicellular organisms require specialised gas exchange surfaces because their smaller surface area to volume ratio means the distance that needs to be crossed is larger and substances cannot easily enter the cells as in a single-celled organism
- Surface area to volume ratio is calculated by dividing the surface area by the volume
- Three features of an efficient gas exchange surface are:
- Large surface area, e.g. root hair cells
- Thin/short distance, e.g. alveoli
- Steep concentration gradient, maintained by blood supply or ventilation, e.g. gills
- The trachea in the mammalian gaseous exchange system is:
- A wide tube supported by C-shaped cartilage to keep the air passage open during pressure changes
- Lined by ciliated epithelium cells which move mucus, produced by goblet cells, towards the throat to be swallowed, preventing lung infections
- Carries air to the bronchi
- The bronchi in the mammalian gaseous exchange system:
- Are supported by rings of cartilage and lined by ciliated epithelium cells and goblet cells
- Are narrower than the trachea and there are two of them, one for each lung
- Allow passage of air into the bronchioles
- The bronchioles in the mammalian gaseous exchange system:
- Are narrower than the bronchi
- Do not need to be kept open by cartilage, therefore mostly have only smooth muscle and elastic fibres so that they can contract and relax easily during ventilation
- Allow passage of air into the alveoli
- The alveoli in the mammalian gaseous exchange system:
- Are mini air sacs, lined with epithelium cells, the site of gas exchange
- Have walls only one cell thick, covered with a network of capillaries, 300 million in each lung, all of which facilitates gas diffusion
- The process of inspiration and the changes that occur throughout the thorax:
- External intercostal muscles contract (while internal relax), pulling the ribs up and out
- Diaphragm contracts and flattens
- Volume of the thorax increases
- Air pressure outside the lungs is higher than inside, so air moves in to rebalance
- The process of expiration and the changes that occur throughout the thorax:
- External intercostal muscles relax (while internal contract), bringing the ribs down and in
- Diaphragm relaxes and domes upwards
- Volume of the thorax decreases
- Air pressure inside the lungs is higher than outside, so air moves out to rebalance
- A spirometer is used to measure lung volume by having a person breathe into an airtight chamber which leaves a trace on a graph showing the volume of the breaths
- Vital capacity is the maximum volume of air that can be taken in or expelled from the lungs in one breath, calculated from the spirometer graph by finding the maximum amplitude
- Tidal volume is the volume of air we breathe in and out during each breath at rest, calculated from the spirometer graph by finding the amplitude at rest
- Breathing rate is the number of breaths we take per minute, calculated from the spirometer graph by counting the number of peaks in one minute
- Two main features of a fish’s gas transport system are:
- Gills: located within the body, supported by arches, along which are multiple projections of gill filaments, which are stacked up in piles
- Lamellae: at right angles to the gill filaments, give an increased surface area. Blood and water flow across them in opposite directions (countercurrent exchange system)
- The process of gas exchange in fish:
- Buccal cavity volume increased to enable water to flow in, reduced to increase pressure
- Water is pumped over the lamellae by the operculum, oxygen diffuses into the bloodstream
- Waste carbon dioxide diffuses into the water and flows back out of the gills
- The countercurrent exchange system maximises oxygen absorbed by the fish by maintaining a steep concentration gradient, as water is always next to blood of a lower oxygen concentration, keeping the rate of diffusion constant and enabling 80% of available oxygen to be absorbed
- Three main features of an insect’s gas transport system are:
- Spiracles: holes on the body’s surface which may be opened or closed by a valve for gas or water exchange
- Tracheae: large tubes extending through all body tissues, supported by rings to prevent collapse
- Tracheoles: smaller branches dividing off the tracheae
- The process of gas exchange in insects:
- Gases move in and out of the tracheae through the spiracles
- A diffusion gradient allows oxygen to diffuse into the body tissue while waste CO2 diffuses out
- Contraction of muscles in the tracheae allows mass movement of air in and out