Brain to body mass ratio

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Brain to body mass ratio (also known as the Encephalization Quotient or EQ) is a rough estimate of the possible intelligence of an organism.

Roughly speaking, the larger an organism is, the more brain mass is required for housekeeping tasks, such as breathing, thermoregulation, senses, motor skill, etc.^{[citation needed]} The larger the brain is relative to the body, the more brain mass might thus be available for more complex cognitive tasks. This method, as opposed to the method of simply measuring brain mass alone, puts humans closer to the top of the list.

Rather than simply dividing brain mass by body mass, some divide brain mass by the ⅔ power of body mass (in other words, divide brain mass by body surface area) or the ¾ power of body mass.

Dolphins have the highest brain to body mass ratio of all cetaceans. Sharks have the highest for a fish, and octopuses have the highest for an invertebrate. Humans have a higher brain to body mass ratio than any of these animals.

It is a trend that the larger the animal gets, the smaller the relative brain size gets. Large whales have very small brains compared to their weight, and small rodents have huge brains. One of the reasons to this could be that even if the animals gets larger, the size of the neural cels remains the same, and more nerve cell will cause the brain to increase in size to a lesser degree than the rest of the body. This phenomena has been called the cephalization factor; E = CS², where E and S are body and brain weights, while C is the cephalization factor. Just focusing on the relationship between the body and the brain is not enough, one also has to consider the total size of the animal.

However, there seems to be some controversy over whether humans have the highest brain to body mass ratio (followed by dolphins) ^{[1] [2] [3]}, or whether treeshrews are on the top of the list ^[4] Treeshrews hold nearly 10% of their mass in their brain, making it one of the most encephalized animals.^[5]

Since shrews are less intelligent than humans, many^{[citation needed]} believe that intelligence correlates with the absolute brain-mass left over from when one subtracts the brain-mass for running the body. In the essay "Bligh's Bounty"^[6], Stephen Jay Gould noted that if one looks at vertebrates with very low encephalization quotients, their brains are slightly less massive than their spinal cords. Theoretically, intelligence might correlate with the absolute amount of brain an animal has after subtracting the mass of the spinal cord from the brain^{[citation needed]}. This formula is useless for invertebrates because they do not have spinal cords, or in some cases, central nervous systems.

[edit] See also

• Cranial capacity
• Encephalization
• Neuroscience and intelligence

[edit] References

1. ^ http://www.tufts.edu/as/wright_center/cosmic_evolution/docs/text/text_cult_3.html
2. ^ http://21stcentury.chinadaily.com.cn/article.php?sid=16240
3. ^ http://www.wsu.edu:8080/~taflinge/mindwork/mawint1.html
4. ^ http://www.hindustantimes.com/news/181_935198,00300006.htm
5. ^ http://www.kk.org/thetechnium/archives/2004/11/brains_of_white.php
6. ^ web archive of monash.edu.au

[edit] External links

• http://www.tufts.edu/as/wright_center/cosmic_evolution/docs/text/text_cult_3.html
• http://www.wsu.edu:8080/~taflinge/mindwork/mawint1.html
• a graph of body mass vs. brain mass
• "Bligh's Bounty" — Stephen Jay Gould