Team:Exeter/Polysaccharides
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+ | <font color="#57B947" size="+3"><b>Polysaccharides</b></font> | ||
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Polysaccharides are chains of monosaccharides (or sugars) linked by glycosidic bonds, ranging in length | Polysaccharides are chains of monosaccharides (or sugars) linked by glycosidic bonds, ranging in length | ||
from just two joined sugars (a disaccharide) to many thousands. Variations in structure can also lead | from just two joined sugars (a disaccharide) to many thousands. Variations in structure can also lead | ||
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polysaccharide. | polysaccharide. | ||
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- | Storage polysaccharides | + | <font color="#57B947" size="+1"><b>Storage polysaccharides</b></font> |
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- | Storage polysaccharides are used for, well, energy storage! Starches are a type of storage polysaccharide we are familiar with (in | + | </br> |
- | potatoes, rice...), and store energy until they are broken down by our digestive systems. Polysaccharides are ideal energy storage | + | Storage polysaccharides are used for, well, energy storage! Starches are a type of storage polysaccharide we are familiar with (in potatoes, rice...), and store energy until they are broken down by our digestive systems. Polysaccharides are ideal energy storage molecules as they are very long carbohydrates and therefore insoluble in water; they are also highly flexible so perfect for transportation and can be broken down very easily to release the stored energy. Being insoluble in water maintains a cell's equilibrium as no chemical or osmotic reaction is required by the cell. |
- | molecules as they are very long carbohydrates and therefore insoluble in water; they are also highly flexible so perfect for | + | |
- | transportation and can be broken down very easily to release the stored energy. Being insoluble in water maintains a cell's | + | |
- | equilibrium as no chemical or osmotic reaction is required by the cell. | + | |
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- | + | Glycogen is another, and is found in almost all animal cells, principally the liver and muscles. When the body has recieved no food, the energy stored in Glycogen is released in the form of glucose. | |
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- | Structural polysaccharides are polysaccharides found to form the structure of organisms. For example, cellulose forms the basis of cell walls in plants and chitin forms the structural component of exoskeletons. These polysaccharides have huge uses and applications in industry, Cellulose for example forming the basis of wood-and by proxy paper and cotton are nearly pure samples. | + | <font color="#57B947" size="+1"><b>Structural polysaccharides</b></font> |
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+ | Structural polysaccharides are polysaccharides found to form the structure of organisms. For example, cellulose forms the basis of cell walls in plants and chitin forms the structural component of exoskeletons. These polysaccharides have huge uses and applications in industry, Cellulose for example forming the basis of wood-and by proxy paper and cotton are nearly pure samples. | ||
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Latest revision as of 14:02, 14 August 2012
Polysaccharides Polysaccharides are chains of monosaccharides (or sugars) linked by glycosidic bonds, ranging in length from just two joined sugars (a disaccharide) to many thousands. Variations in structure can also lead to linear or branched chains, or determine whether it is a storage polysaccharide or a structural polysaccharide. | |
Storage polysaccharides Storage polysaccharides are used for, well, energy storage! Starches are a type of storage polysaccharide we are familiar with (in potatoes, rice...), and store energy until they are broken down by our digestive systems. Polysaccharides are ideal energy storage molecules as they are very long carbohydrates and therefore insoluble in water; they are also highly flexible so perfect for transportation and can be broken down very easily to release the stored energy. Being insoluble in water maintains a cell's equilibrium as no chemical or osmotic reaction is required by the cell. Glycogen is another, and is found in almost all animal cells, principally the liver and muscles. When the body has recieved no food, the energy stored in Glycogen is released in the form of glucose. |
Structural polysaccharides Structural polysaccharides are polysaccharides found to form the structure of organisms. For example, cellulose forms the basis of cell walls in plants and chitin forms the structural component of exoskeletons. These polysaccharides have huge uses and applications in industry, Cellulose for example forming the basis of wood-and by proxy paper and cotton are nearly pure samples. |