Brain size: Difference between revisions

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{{Image|ComparitiveBrainSize.jpg|left|350px|Comparative anatomy of adult brains from various vertebrate species, highlighting the gradual differences in brain size and [[gyrification]].}}
{{Image|ComparitiveBrainSize.jpg|left|350px|Comparative anatomy of adult brains from various vertebrate species, highlighting the gradual differences in brain size and [[gyrification]].}}


{{Image|Herculano-Houzel 2009 human brain in numbers Fig 004.jpg|right|350px|Comparison of [[rodent]] and [[primate]] brains (from [[CZ:Ref:Herculano-Houzel 2009 The human brain in numbers: a linearly scaled-up primate brain|Herculano-Houzel, 2009]]). [[Brain size]] is not a reliable indicator of number of [[neuron]]s across [[order (biology)|orders]]. Because of the different cellular [[allometry|scaling]] rules that apply to rodent and primate brains, primates always concentrate larger numbers of neurons in the brain than rodents of a similar, or even larger, brain size. Data from Herculano-Houzel et al. (2006, 2007). Illustration by Lorena Kaz. }}
{{Image|Herculano-Houzel 2009 human brain in numbers Fig 004.jpg|right|350px|Comparison of [[rodent]] and [[primate]] brains (from [[CZ:Ref:Herculano-Houzel 2009 The human brain in numbers: a linearly scaled-up primate brain|Herculano-Houzel, 2009]]). Brain size is not a reliable indicator of number of [[neuron]]s across [[order (biology)|orders]]. Because of the different cellular [[allometry|scaling]] rules that apply to rodent and primate brains, primates always concentrate larger numbers of neurons in the brain than rodents of a similar, or even larger, brain size. Data from Herculano-Houzel et al. (2006, 2007). Illustration by Lorena Kaz. }}


Since the [[brain]] has enlarged considerably during [[hominid evolution]], '''brain size''' is a central term in many discussions related to [[cognitive evolution]], [[intelligence (biology)|intelligence]] and a number of [[brain disorder]]s, especially [[microcephaly]]. To compare different brains, several indicators of brain size have been used. These include ''absolute brain size'',  ''relative brain size'' (normalized by body size or weight), and the [[encephalization coefficient]].
Since the [[brain]] has enlarged considerably during [[hominid evolution]], '''brain size''' is a central term in many discussions related to [[cognitive evolution]], [[intelligence (biology)|intelligence]] and a number of [[brain disorder]]s, especially [[microcephaly]]. To compare different brains, several indicators of brain size have been used. These include ''absolute brain size'',  ''relative brain size'' (normalized by body size or weight), and the [[encephalization coefficient]].

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(CC) Photo: University of Wisconsin and Michigan State Comparative Mammalian Brain Collections and National Museum of Health and Medicine (see http://www.brainmuseum.org/)
Comparative anatomy of adult brains from various vertebrate species, highlighting the gradual differences in brain size and gyrification.
Comparison of rodent and primate brains (from Herculano-Houzel, 2009). Brain size is not a reliable indicator of number of neurons across orders. Because of the different cellular scaling rules that apply to rodent and primate brains, primates always concentrate larger numbers of neurons in the brain than rodents of a similar, or even larger, brain size. Data from Herculano-Houzel et al. (2006, 2007). Illustration by Lorena Kaz.

Since the brain has enlarged considerably during hominid evolution, brain size is a central term in many discussions related to cognitive evolution, intelligence and a number of brain disorders, especially microcephaly. To compare different brains, several indicators of brain size have been used. These include absolute brain size, relative brain size (normalized by body size or weight), and the encephalization coefficient.

Determinants of brain size

A number of parameters have been found to be involved in the determination of brain size. These include the genes microcephalin (MCPH1) and ASPM (MCPH5; for overview, see Stern and Woods, 2006 and Tang 2006), habitat density (at least in bats, cf. Safi et al., 2005), and pelvic size in human females (cf. Ridley 1995) as a limiting factor.

Correlates of brain size

Further variables interact with brain size but cause and effect in these relationships have not yet been clearly identified. This is the case with the maximum rate of population increase (Isler & Van Schaik, 2009), the basal metabolic rate (Isler & van Schaik, 2006a), the flight musculature (at least in birds, cf. Isler & van Schaik, 2006b), the wing area (at least in bats, cf. Safi et al., 2005), and some cognitive traits like kleptoparasitism (Morand-Ferron et al., 2007).

Effects of brain size

Brain size, in turn was found to have an effect on gyrification (cf. Hofman 1989 and Casanova et al., 2004) and the glia-neuron ratio (cf. Sherwood et al., 2006).