Encephalization quotient

Species Encephalization
quotient (EQ)[1]
Human7.4–7.8
Tucuxi4.56[2]
Bottlenose dolphin4.14[3]
Orca2.57–3.3[3][4]
Chimpanzee2.2–2.5[5]
Rhesus monkey2.1
Elephant1.13–2.36[6]
Chinchilla 1.34[7]
Dog1.2
Squirrel1.1
Cat1.00
Horse0.9
Sheep0.8
Mouse0.5
Rat0.4
Rabbit0.4

Encephalization quotient (EQ), or encephalization level, is a measure of relative brain size defined as the ratio between actual brain mass and predicted brain mass for an animal of a given size, which is hypothesized to be a rough estimate of the intelligence or cognition of the animal.[8]

This is a more refined measurement than the raw brain-to-body mass ratio, as it takes into account allometric effects. The relationship, expressed as a formula, has been developed for mammals, and may not yield relevant results when applied outside this group.[9]

Additionally to volume, mass or cell count, the energy expenditure of the brain could be compared with that of the rest of the body.

Brain-body size relationship

Species Simple brain-to-body
ratio (E/S)[10]
small birds1/12
human1/40
mouse1/40
dolphin1/50
cat1/100
chimpanzee1/113
dog1/125
frog1/172
lion1/550
elephant1/560
horse1/600
shark1/2496
hippopotamus1/2789

Brain size usually increases with body size in animals (is positively correlated), i.e. large animals usually have larger brains than smaller animals.[10] The relationship is not linear, however. Generally, small mammals have relatively larger brains than big ones. Mice have a direct brain/body size ratio similar to humans (1/40), while elephants have a comparatively small brain/body size (1/560), despite being quite intelligent animals.[10][11]

Several reasons for this trend are possible, one of which is that neural cells have a relative constant size.[12] Some brain functions, like the brain pathway responsible for a basic task like drawing breath, are basically similar in a mouse and an elephant. Thus, the same amount of brain matter can govern breathing in a large or a small body. While not all control functions are independent of body size, some are, and hence large animals need comparatively less brain than small animals. This phenomenon has been called the cephalization factor: C = E ÷ S2 , where E and S are brain and body weights respectively, and C is the cephalization factor.[13] To determine the formula for this factor, the brain/body weights of various mammals were plotted against each other, and the curve of E = C × S2 chosen as the best fit to that data.[14]

The cephalization factor and the subsequent encephalization quotient was developed by H.J. Jerison in the late 1960s.[15] The formula for the curve varies, but an empirical fitting of the formula to a sample of mammals gives .[9] As this formula is based on data from mammals, it should be applied to other animals with caution. For some of the other vertebrate classes the power of 3/4 rather than 2/3 is sometimes used, and for many groups of invertebrates the formula may give no meaningful results at all.[9]

Calculation

Snell's equation of simple allometry[16] is:

Here "E" is the weight of the brain, "C" is the cephalization factor and "S" is body weight and "r" is the exponential constant. The exponential constant for primates is 0.28[16] and either 0.56 or 0.66 for mammals in general.[17]

The "Encephalization Quotient" (EQ) is the ratio of "C" over the expected value for "C" of an animal of given weight "S".[17]

Species EQ[17] Species EQ[17]
Human 7.44 Dog 1.17
Dolphin 5.31 Cat 1.00
Chimpanzee 2.49 Horse 0.86
Raven[18] 2.49 Sheep 0.81
Rhesus monkey 2.09 Mouse 0.50
Elephant 1.87 Rat 0.40
Baleen whale 1.76 Rabbit 0.40

This measurement of approximate intelligence is more accurate for mammals than for other phyla of Animalia.

EQ and intelligence in mammals

Intelligence in animals is hard to establish, but the larger the brain is relative to the body, the more brain weight might be available for more complex cognitive tasks. The EQ formula, as opposed to the method of simply measuring raw brain weight or brain weight to body weight, makes for a ranking of animals that coincide better with observed complexity of behaviour.

Mean EQ for mammals is around 1, with carnivorans, cetaceans and primates above 1, and insectivores and herbivores below. This reflects two major trends. One is that brain matter is extremely costly in terms of energy needed to sustain it.[19] Animals which live on relatively nutrient poor diets (plants, insects) have relatively little energy to spare for a large brain, while animals living from energy-rich food (meat, fish, fruit) can grow larger brains. The other factor is the brain power needed to catch food. Carnivores generally need to find and kill their prey, which presumably requires more cognitive power than browsing or grazing.[20][21] The brain size of a wolf is about 30% larger than a similarily sized domestic dog, again reflecting different needs in their respective way of life.[22]

Another factor affecting relative brain size is sociality and flock size.[23] For example, dogs (a social species) have a higher EQ than cats (a mostly solitary species). Animals with very large flock size and/or complex social systems consistently score high EQ, with dolphins and orcas having the highest EQ of all cetaceans,[4] and humans with their extremely large societies and complex social life topping the list by a good margin.[1]

Comparisons with non-mammalian animals

Birds generally have lower EQ than mammals, but parrots and particularly the corvids show remarkable complex behaviour and high learning ability. Their brains are at the high end of the bird spectrum, but low compared to mammals. Bird cell size is on the other hand generally smaller than that of mammals, which may mean more brain cells and hence synapses per volume, allowing for more complex behaviour from a smaller brain.[1] Both bird intelligence and brain anatomy are however very different from those of mammals, making direct comparison difficult.[24]

Manta rays have the highest EQ among fish,[25] and either octopuses[13] or jumping spiders[26] have the highest among invertebrates. Despite the jumping spider having a huge brain for its size, it is minuscule in absolute terms, and humans have a much higher EQ despite having a lower raw brain-to-body weight ratio.[27][28][29] Mean EQs for reptiles are about one tenth of those of mammals. EQ in birds (and estimated EQ in dinosaurs) generally also falls below that of mammals, possibly due to lower thermoregulation and/or motor control demands.[30] Estimation of brain size in the oldest known bird, Archaeopteryx, shows it had an EQ well above the reptilian range, and just below that of living birds.[31]

Biologist Stephen Jay Gould has 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 weight of the spinal cord from the brain.[32] This formula is useless for invertebrates because they do not have spinal cords or, in some cases, central nervous systems.

EQ in paleoneurology

Behavioural complexity in living animals can to some degree be observed directly, making the predictive power of the encephalization quotient less relevant. It is however central in paleoneurology, where the endocast of the brain cavity and estimated body weight of an animal is all one has to work from. The behaviour of extinct mammals and dinosaurs is typically investigated using EQ formulas.[15]

Fossils of archaic humans have EQ e.g. 4.15.[33]

Criticism

Recent research indicates that whole brain size is a better measure of cognitive abilities than EQ for primates at least.[34] The relationship between brain-to-body mass ratio and complexity is not alone in influencing intelligence. Other factors, such as the recent evolution of the cerebral cortex and different degrees of brain folding,[35] which increases the surface area (and volume) of the cortex, are positively correlated to intelligence in humans.[36]

See also

References

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  2. William Perrin. Encyclopedia of Marine Mammals. p. 150.
  3. 1 2 Marino, Lori (2004). "Cetacean Brain Evolution: Multiplication Generates Complexity" (PDF). International Society for Comparative Psychology. The International Society for Comparative Psychology (17): 1–16. Retrieved 2010-08-29.
  4. 1 2 Marino, L. and Sol, D. and Toren, K. and Lefebvre, L. (2006). "Does diving limit brain size in cetaceans?" (PDF). Marine Mammal Science. 22 (2): 413–425. doi:10.1111/j.1748-7692.2006.00042.x.
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  10. 1 2 3 http://serendip.brynmawr.edu/bb/kinser/Int3.html
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