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Surface area to volume ratio

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Organisms exchange substances and heat with their environment all the time, and this possibility is crucial to survival. The specific way in which this is achieved is very tightly related to the shape and structure of the specific organism, as well as its environment. For example, unicellular organisms are so small that molecules such as oxygen and water can readily diffuse in and out via the membrane, due to the short diffusion pathway. Could this be achieved by a human, or even a bee? No – they are simply too big.

 

Two properties are important to consider here: the volume of an organism, and the surface area of an organism. The volume is what determines the amount of substances which need exchanging, while the surface area determines the amount which can be exchanged.

 

Surface area describes the number of cells in direct contact with the environment. Volume describes the space occupied by all metabolically active cells.

 

Key principle: as the size of an organism increases, the surface area to volume ratio decreases.

 

That might seem hard to really understand. Why use a ratio in the first place? Well, the ratio shows the relationship between surface area and volume ratio, i.e. how similar or dissimilar are they?

 

 

 

 

What this basically means is that the larger an organism gets, the less surface area is available to serve its increasing needs due to its increasing volume. So what adaptations do larger organisms have to cope with the large demand for substance and heat exchange?

 

For one, mere diffusion directly into and out of the organism is not possible. Insects, for example, have a system of tubules which distribute air within the body so that it reaches all the different parts. Mammals have lungs and blood vessels. Fish have gills. All these are systems are specifically aimed at making it possible to exchange substances such as oxygen, carbon dioxide, nutrients, as well as heat, between an organism and its environment.

 

In fact, the reason behind insects’ limited size is that their tubule system can only work for those sizes. Otherwise, we might just have gigantic wasps flying around. Be thankful for surface area to volume ratio!

 

Coping with increasing distance between cells and nutrients involves minimising the diffusion pathway by employing thin structures e.g. cells, vessels, membranes, as well as increasing the available surface area for reactions e.g. leaf area, and maintaining concentration gradients to enable passive and active transport in cells.

 

 

This is exemplified by the leaf mesophyll where cells are tightly packed, root hairs that increase surface area of cells in contact with the environment for water and ion absorption, capillaries that are just 1-cell thick to the point where red blood cells must fold to pass through, and alveoli in the lungs. All these diverse structures are adapted to have a small diffusion pathway, large surface area and maintain steep concentration gradients.

 

 

 

 

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