Journal article
Proceedings of the Royal Society B, 2019
APA
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Seymour, R., Bosiocic, V., Snelling, E., Chikezie, P. C., Hu, Q., Nelson, T. J., … Miller, C. (2019). Cerebral blood flow rates in recent great apes are greater than in Australopithecus species that had equal or larger brains. Proceedings of the Royal Society B.
Chicago/Turabian
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Seymour, R., V. Bosiocic, E. Snelling, P. C. Chikezie, Q. Hu, T. J. Nelson, B. Zipfel, and C. Miller. “Cerebral Blood Flow Rates in Recent Great Apes Are Greater than in Australopithecus Species That Had Equal or Larger Brains.” Proceedings of the Royal Society B (2019).
MLA
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Seymour, R., et al. “Cerebral Blood Flow Rates in Recent Great Apes Are Greater than in Australopithecus Species That Had Equal or Larger Brains.” Proceedings of the Royal Society B, 2019.
BibTeX Click to copy
@article{r2019a,
title = {Cerebral blood flow rates in recent great apes are greater than in Australopithecus species that had equal or larger brains},
year = {2019},
journal = {Proceedings of the Royal Society B},
author = {Seymour, R. and Bosiocic, V. and Snelling, E. and Chikezie, P. C. and Hu, Q. and Nelson, T. J. and Zipfel, B. and Miller, C.}
}
Brain metabolic rate (MR) is linked mainly to the cost of synaptic activity, so may be a better correlate of cognitive ability than brain size alone. Among primates, the sizes of arterial foramina in recent and fossil skulls can be used to evaluate brain blood flow rate, which is proportional to brain MR. We use this approach to calculate flow rate in the internal carotid arteries (Q˙ICA), which supply most of the primate cerebrum. Q˙ICA is up to two times higher in recent gorillas, chimpanzees and orangutans compared with 3-million-year-old australopithecine human relatives, which had equal or larger brains. The scaling relationships between Q˙ICA and brain volume (Vbr) show exponents of 1.03 across 44 species of living haplorhine primates and 1.41 across 12 species of fossil hominins. Thus, the evolutionary trajectory for brain perfusion is much steeper among ancestral hominins than would be predicted from living primates. Between 4.4-million-year-old Ardipithecus and Homo sapiens, Vbr increased 4.7-fold, but Q˙ICA increased 9.3-fold, indicating an approximate doubling of metabolic intensity of brain tissue. By contrast, Q˙ICA is proportional to Vbr among haplorhine primates, suggesting a constant volume-specific brain MR.