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April 28, 1998, Tuesday
NATIONAL
DESK
Ancestral Humans Could Speak, Anthropologists' Finding Suggests
By JOHN NOBLE WILFORD (NYT) 1145 words
While scientists agree that speech is probably the most
important behavioral attribute that distinguishes human beings from other
animals, they have been at a loss to determine when and how that transforming
evolutionary step occurred.
They have probed the human brain and compared it with casts of the
braincase from ancient fossil skulls. They have compared bones and muscle
attachment points in the throats of humans, apes and ancestral human
skeletons. Archeologists have examined patterns in early stone tools for
clues to when humans might have developed the creativity and the
self-awareness usually associated with communication skills like speech.
All they had been able to agree on is that the earliest unambiguous
evidence for human speech is found in the cave art and other artifacts,
particularly in Europe and Africa, that began
appearing some 40,000 years ago.
Now scientists at Duke University
have explored a new avenue of fossil anatomy and found surprising evidence
suggesting that vocal capabilities like those of modern humans may have
evolved among species of the Homo line more than 400,000 years ago.
By then, their research shows, human ancestors may have had a full modern
complement of the nerves leading to the muscles of the tongue and so could
have been capable of forming speech sounds.
The new findings, moreover, indicate that the Neanderthals, relatives of
modern humans, could have had the same gift for speech. Their extinction
about 30,000 years ago has often been attributed in part to speech
deficiencies, restricting their ability for cultural innovation.
In a report being published today in The Proceedings of the National
Academy of Sciences, the Duke anthropologists say that if their
interpretation involving the tongue nerves is correct, ''then humanlike
speech capabilities may have evolved much earlier than has been inferred from
the archeological evidence for the antiquity of symbolic thought.''
The research was conducted by Dr. Richard F. Kay and Dr. Matt Cartmill at the Duke
Medical Center
in Durham, N.C.,
with the assistance of a former student, Michelle Balow.
The results were also described earlier this month in Salt
Lake City at a meeting of the American Association
of Physical Anthropology.
''This is evidence for the proposition that Neanderthals could talk,'' Dr.
Cartmill said in a telephone interview on Sunday.
''Did they sound like modern humans? I don't know.''
Anthropologists familiar with the research said the findings were
interesting and exciting. Some were reserving judgment, but not Dr. Erik Trinkaus, an anthropologist at Washington
University in St.
Louis, who specializes in Neanderthal studies.
''I think it's not only a reasonable conclusion,'' he said, ''but one long
overdue.''
Dr. Trinkaus said previous research had been
based on deficient anatomical reconstructions, none of which adequately took
into account the neurological aspects for controlling the vocal track to
allow for speech. As for the possibility of speech by archaic Homo sapiens
400,000 years ago, even before Neanderthals, he said this was consistent with
a significant enlargement of brain size in that period, the appearance of a
more complex tool technology and migrations into colder climates, where life
probably depended on greater planning that could be related to advances in
communications skills.
On the other side, Dr. Philip Lieberman of Brown University, an authority
on early language, has argued that the Neanderthal throat would not have been
well suited for the production of the vowels a, i
and u. But Dr. Trinkaus contended that a species
would not have needed to produce all those sounds in order to have speech and
language.
Even the discovery in Israel
a decade ago of a Neanderthal skeleton with a large hyoid bone, which is in
the throat and associated with speech, had not settled the issue of
Neanderthal speech. Scientists had said there was still insufficient fossil
evidence to enable an understanding of how the large hyoid bone might have
influenced the production of vocalizations.
Dr. Cartmill himself cautioned that the new
evidence for earlier human speech ''is suggestive, but, in the present state
of our knowledge, it is not proof.''
Other scientists noted that other, independent evolutionary developments,
including a lengthened larynx, enlarged prefrontal brain lobes and some
reconfigurations of the brain, would have been critical to the emergence of
speech. The size of the brain of Neanderthals was well within the range of
that of modern humans.
The Duke scientists directed their research at the hypoglossal canal, a
hole at the bottom of the skull in the back, where the spinal cord connects
to the brain. Through the canal run nerve fibers from the brain to the
muscles of the tongue.
It occurred to the scientists that the size of the hypoglossal canal might
serve as an index of the vocal abilities of modern and early humans. The
wider the canal, they assumed, the more nerve fibers there could be to
control the tongue muscles. And the more nerves, they suggested, the finer
control the species could have over its tongue for the purpose of making
speech sounds.
The researchers compared measurements of hypoglossal canals of modern
humans, apes and several human ancestor fossils, and concluded that the
canals of modern humans are almost twice as large as those of modern apes --
the chimpanzee and the gorilla -- which are incapable of speech. They also found
that the canal size of australopithecines, earlier human relatives that died
out about one million years ago, did not differ much from that of
chimpanzees.
The results, the scientists reported, ''suggest minimum and maximum dates
for the appearance of the modern human pattern of tongue motor innervation and speech abilities.''
To narrow the range, the scientists examined skeletons of Neanderthals and
also of species of the Homo genus that lived as much as 400,000 years ago.
These included Kabwe specimens from Africa
and Swanscombe fossils from Europe.
Their hypoglossal canals fell within the range of those of modern Homo
sapiens.
''By the time we get to the Kabwe, about 400,000 years ago, you get a canal that's a
modern size,'' Dr. Cartmill said. ''And that's true
of all later Homo species, including Neanderthal.''
CAPTIONS: Diagram: ''Can We Talk?''
Scientists are reasoning that the size of the canal that houses nerves
controlling the tougue directly correlates the
vocal capabilities of early humans.
HUMAN
The wider the hole, called the hypoglossal, the more nerve fibers can go
through it and give greater control of the tougue.
CHIMPANZEE
A canal of a chimpanzee, shown here for comparison, is about half the size of
that of a human being.
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