|A Neanderthal model at |
Zagros Paleolithic Museum, Kermanshah
Courtesy Wikimedia Commons
Differences in the temporal lobes and olfactory bulbs also suggest a combined use of brain functions related to cognition and olfaction.
The increase of brain size is intimately linked to the evolution of humanity. Two different human species, Neanderthals and modern humans, have independently evolved brains of roughly the same size but with differing shapes. This could indicate a difference in the underlying brain organization.
In a study published this week by Nature Communications, led by Markus Bastir and Antonio Rosas, of the Spanish Natural Science Museum (CSIC), high-tech medical imaging techniques were used to access internal structures of fossil human skulls. The researchers used sophisticated 3D methods to quantify the shape of the basal brain as reflected in the morphology of the skeletal cranial base. Their findings reveal that the human temporal lobes, involved in language, memory and social functions as well as the olfactory bulbs are relatively larger in Homo sapiens than in Neanderthals. "The structures which receive olfactory input are approximately 12% larger in modern humans than in Neanderthals", the authors explain.
|This image shows the shape differences in the brains of an adult Homo sapiens (blue) and an adult Neanderthal (red).|
Credit: MPI for Evolutionary Anthropology/Phillip Gunz
These findings may have important implications for olfactory capacity and human behaviour. In modern humans the size of the olfactory bulbs is related to the capacity of detection and discrimination of different smells. Olfaction is among the oldest sense in vertebrates. "Also, it is the only one that establishes a direct connection between the brain and its environment", says Markus Bastir, the lead author of the study. While other senses must pass through different cortical filters, olfaction goes from the environment right into the highest centres of the brain. What is more, "olfaction never sleeps", adds Antonio Rosas, "because we always breathe and perceive smells". The neuronal circuitry of olfaction coincides with that of memory and emotion (the limbic system), "which explains the enormous memory retention and vital intensity of olfaction-mediated life events."
Researchers at the Max Planck Institute for Evolutionary Anthropology in Leipzig, who also contributed to the current publication, could recently show differences in the patterns of brain development between modern humans and Neanderthals during a critical phase for cognitive development. "In the first year of life the brains of Neanderthals and modern humans develop differently," says Philipp Gunz from the Max Planck Institute of Evolutionary Anthropology in Leipzig. "Modern humans have smaller faces and smaller noses than their Neanderthal cousins. However, the part of the brain that processes smells, is bigger in modern humans than in Neanderthals". "Evidence is accumulating that Neanderthals and modern humans independently evolved large brains and that their brains might have worked differently. Our new study offers a glimpse into the functional significance of these developmental differences," adds Jean-Jacques Hublin, who heads the Department of Human Evolution at the Max Planck Institute of Evolutionary Anthropology in Leipzig.
Olfactory information projects to brain regions directly responsible for processing of emotion, motivation, fear, memory, pleasure and also attraction. Neuroscientists have coined the term "higher olfactory functions" to describe those brain functions which combine cognition (memory, intuition, perception, judgment) and olfaction. The greater olfactory bulbs and relatively larger temporal lobes in H. sapiens compared to any other human species may point towards improved and different olfactory sense possibly related to the evolution of behavioural aspects and social functions.
Markus Bastir, Antonio Rosas, Philipp Gunz, Angel Peña-Melian, Giorgio Manzi, Katerina Harvati, Robert Kruszynski, Chris Stringer & Jean-Jacques Hublin
Evolution of the base of the brain in highly encephalized human species
Nature Communications, December 13, 2011