Post by jilleryhttp://youtu.be/GosX5-kuWUs
For those who don't know, Gutsick Gibbon is the Youtube handle for a
PhD student in Biological Anthropology. This particular video
<https://www.nature.com/articles/s41586-024-08205-2>
It got my attention for two reasons. First, it describes a
non-destructive method for analyzing the growth patterns of fossil
teeth, using propagation phase-contrast synchrotron microtomography.
Second, the authors used that method to compare the tooth ontogeny of
several fossil hominids and modern apes. Using these patterns as
proxy for overall physical development, the authors concluded that
early hominids' growth patterns were more similar to modern
chimpanzees, and different fossil hominids' growth patterns evolved to
become more similar to modern humans over time.
Finally, the authors raise the question of whether the inferred
life-history characteristics of early Homo reflect an evolutionary
change in reproduction strategies, before substantial brain expansion
and reorganization, and before a general slow-down in life history.
Paraphrasing Gutsick Gibbon, it was early tool use three million years
ago, which altered the selective pressures for large teeth and jaws,
which in turn allowed developmental changes for extended childhood,
which preceded the large increase in brain size.
Discuss or ignore, as you will.
This is the paper that I posted before, and asked what could be
determined from a sample size of one? This paper had enough samples
from chimps and humans to have error bar estimates on their
develompental trajectories, but they only had 4 orangutan measurments
and one of them fell squarely (right on the line) on the human
trajectory. The error bars clearly separated the trajectories of chimp
and human tooth development, but they didn't have enough orangutan
samples and only had the one ancient homo sample. From their own
orangutan sample, what could they infer from a single early Homo sample?
Human babies are born with larger brains to body weight than the apes
and at a less physically developed state. They are pretty helpless, and
cultural changes would have had to occur in order to care for this type
of infant. Both human and ape brains have to grow with the growing
infant, but the ape brains do not grow as much, and are more developed
when the infant is born. Human infant brains may be larger, but they
are less developed, and the physical abilities of the infants body are
also retarded compared to apes. Before the current way that we grow
larger brains evolved there must have been a stage where our brains
evolved to be able to more effectively assimilate (learn) existing
culture of the group, and develop cultural novelties in order to adapt
to the biological changes that would be needed to go to the next level
of brain development.
One way to develop better brains is to allow them to grow longer after
birth. You would just be adding to how developed the brain already is
in apes at birth. This would likely lengthen child development, but
would also allow more time for the infants to learn the culture of the
group as their brains developed. The paper notes that Homo brains 1.7
million years ago were not that much larger than ape brains.
Australopithecines had larger brains by body weight than chimps, and the
Taung child is thought to be a little over 3 years of age when it died
and it already had a brain about the size of adult chimp. The brain
might have needed to grow a bit more to have an Australopithecine adult
brain size.
Ron Okimoto