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Gas exchange is the physical process by which gases move passively by diffusion across a surface. Oxygen is required in all organisms to release energy in the form of ATP during respiration.
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Jetzt kostenlos anmeldenGas exchange is the physical process by which gases move passively by diffusion across a surface. Oxygen is required in all organisms to release energy in the form of ATP during respiration.
The gases are transferred between the organism’s internal and external environments. The transfer occurs passively (no energy required), down the concentration gradient. The transfer of gases includes the exchange of oxygen and carbon dioxide during the respiration and photosynthesis processes.
The diffusion rate of gasses depends on the surface area, concentration gradient, permeability and thickness of the membrane. Diffusion of gases will happen between two close surfaces. For example, this occurs between the alveoli and capillaries in the lung.
Membrane permeability: ability of substances to move passively through the membrane.
Concentration gradient: difference in the concentration of a substance between two media.
Partial pressure refers to the pressure exerted by a particular gas in the mixture of gases and is used to predict the movement of gases. The gas will move from a high partial pressure area to a lower partial pressure area because the higher the difference between the two environments’ partial pressures, the faster the movement of gases.
So why do gases move down their partial pressure gradient?
Gas will move in random directions due to heat energy and depending on what it crashes into. Gas has equal probability to move in any direction. In case of gas trapped in an enclosed space, such as a container, the spreading out is referred to as diffusion. Imagine that the molecules are on one side of the container, they will move towards the side where there are no gas molecules. This is like in normal diffusion: movement of substance from higher to lower concentration (down the gradient).
Because molecules are in a gas phase, the concentration gradient is exactly the same as partial pressure gradient (assuming that the temperature is not at a gradient). So, gas will move down the gradient i.e. down the partial pressure gradient.
The trachea is a flexible airway supported by the cartilage rings, which prevents the trachea from collapsing when the air pressure inside falls while breathing in. The trachea is divided into two divisions called bronchi. Bronchi then split into a series of bronchioles ending in alveoli - minute air-sacs. The alveolar membrane is the gas exchange surface.
When you inhale oxygen, it enters the lungs and travels to the alveoli. Cells lining alveoli and capillaries carrying blood are in close contact with each other. The barrier thickness averages to 1 micron - that’s 1/10 000 of a centimetre! Oxygen passes through the barrier into the blood in capillaries. In turn, carbon dioxide passes into the alveoli from the bloodstream and is exhaled.
Oxygen travels from the lungs to the pulmonary veins, which take oxygen to the left side of the heart, where it is pumped to the rest of the body. Deoxygenated blood returns to the right side of the heart and is pumped through the pulmonary artery back to the lungs.
Alveoli have adaptations to facilitate efficient gas exchange. You will learn about four central adaptations.
Single-celled organisms have a large surface-to-volume ratio allowing efficient diffusion of gasses. Oxygen diffuses into the cell, and carbon dioxide leaves the cell, followed by respiration. The membrane is entirely permeable to facilitate this exchange. The distance between the internal and the external environments is small enough, and the surface area is large enough for the cell’s needs. No specialised structures are required for the gas exchange.
Insects have an internal network of tubes called tracheae which divide into smaller tracheoles (the end tubes). There is only a short diffusion pathway from tracheoles - the oxygen is brought directly into the respiring tissues.
Gasses move in three ways:
Fish have gills to facilitate gas exchange due to their small surface area to volume ratio (similar to mammals’ lungs). Gills are made up of gill filaments. Gill filaments are stacked (imagine stacking your notebooks, just like that). They contain gill lamellae which are at a right angle to the filaments. They increase the surface area for gas exchange.
Did you notice that the movement of water over gills and blood flow is in opposite directions in Figure 6? This is the countercurrent exchange system.
The countercurrent exchange system allows the blood to be well-loaded with oxygen when it meets water. Diffusion will occur, and oxygen will move into the blood. Blood with little oxygen will meet water which has the most oxygen. Take a look at Figure 7; what if the flow was parallel instead of countercurrent? The blood would absorb a much lower percentage of 50% of available oxygen, which is why fish prefer to stick to the countercurrent flow, wouldn’t you?
Gas exchange in the leaf occurs in the gas phase quicker than in water. Living cells are in close contact with the source of oxygen and carbon dioxide (air).
Leaves, as the main gas exchange surfaces, have adaptations for rapid diffusion:
Gas exchange is the physical process by which gases move passively by diffusion across a surface.
Living organisms have developed different adaptations to facilitate efficient gas exchange to survive.
For example, mammals have a lung system, fish have gills with the countercurrent flow system, and single-celled organisms rely on the diffusion of gasses in and out of the cell.
Factors affecting the rate of gas exchange are membrane thickness over which gases have to diffuse, the surface area of the membrane, the pressure difference across the membrane and the steepness of the diffusion gradient.
Gas exchange is the physical process by which gases move passively by diffusion across a surface.
Gas exchange will take place across a surface. Depending on the organism, this surface will differ. Let’s use lungs in mammals as an example. Alveoli (the end air-sacs in the lungs) are the gas exchange surface.
Alveoli have certain adaptations to facilitate efficient gas exchange.
- Large surface area
- Alveoli walls are only one cell thick which allows them to be in close contact with surrounding capillaries.
- The layer of moisture in the alveoli allows gases to diffuse more quickly.
- Alveoli have a good blood supply due to close contact with capillaries making the gas exchange quicker and more efficient.
The trachea, a flexible airway supported by the cartilage rings which prevents the trachea from collapsing when air pressure inside falls when breathing in. The trachea is divided into two divisions called bronchi. Bronchi then divides into a series of bronchioles, ending in alveoli - minute air-sacs. Alveoli have a large surface area and are in close contact with capillaries. This allows rapid gas exchange between the bloodstream and the lungs.
Gas exchange allows the organisms to replenish the oxygen and eliminate the carbon dioxide. In the case of plants during photosynthesis, it allows release of oxygen and replenishment of carbon dioxide (plants also need oxygen, just like animals, for respiration). Oxygen is used to release energy as ATP during respiration.
Why will fish use a countercurrent flow system for gas exchange, rather than a parallel one?
The countercurrent exchange system means blood is already well-loaded with oxygen when it meets water. This is because diffusion will occur, and oxygen will move into the blood. Blood with little oxygen will meet water which has the most oxygen. If fish used a parallel exchange system, only 50% of oxygen would diffuse into the blood (lower diffusion gradient). The system would be less efficient.
What is the gas exchange surface in the mammalian lungs?
Alveoli is the exchange surface of the lungs. They are in close contact with capillaries - this is where the gas exchange takes place.
Insects use active transport for gas exchange. True or false?
False.
What is the main adaptation of single-celled organisms for gas exchange?
Large surface area.
What are the small pores on the surface of the leaf called and how are they important?
Stomata. They allow close air contact with the cells. Gas exchange can take place at a more rapid rate.
Gas exchange is more rapid in water. True or false?
False.
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