Smell – Part Two

Nose of a Bear
See also parts one and three.

There’s more to smell than detecting odors. If it was just a case of identifying odors, it wouldn’t be very interesting for very long.

Our ability to smell has been broken down to seven primary odors. Those are: camphoric – like mothballs, etheral – like cleaning fluid, floral – flowers, musky – some perfumes, pungent – like vinegar, peppermint – mints and putrid – like rotting eggs. Of course, we actually recognize thousands of different smells. And even with the primary odors there are wide variations. Most of us can think of other putrid smells besides rotten eggs, for instance. Continue reading

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Smell

Human nose
See also parts two and three.

Not everyone smells the same. It seems to be true that every human has their own bouquet, other than identical twins. Even dogs can’t tell identical twins apart by smell, and dogs smell far better than humans. Maybe in both senses of the word. How would we know? We don’t smell especially well.

We smell well enough to survive and thrive in our environmental niche, and no more. Our bodies by nature don’t waste their finite resources where they’re not needed. The proteins deployed in the sensory system, and the neurons used to process the subsequent sensory information can be used elsewhere. Still, on average, we are estimated to be able to discriminate about 10,000 different odors.

Smells are chemicals. They are distinct arrangements of molecules; particles with particular shapes and distinct modes of vibration. The particles have to be small enough to float in the air, so we can breathe them into our noses. Then we dissolve them in the mucus lining our olfactory tissue in the region called the nasal mucosa. Humans have about ten million receptor cells, which have a stem tipped by a knob that has hairs. The actual smell receptors are on the tiny hairs.

Each receptor is attended by a neuron, whose job is to send a signal to the brain when a smell particle is identified. Although we have hundreds of different kinds of odor receptors, for identifying hundreds of molecules, only a few kinds are on each hair. The types, numbers and distribution of receptors vary through the population. We don’t all smell the same.

Smell has the shortest path to the brain of all the senses. The information goes directly into the limbic system, a most ancient part of the brain. The limbic system is strongly involved in basic motivation, emotions and memory. This region has a rich network of connections with other parts of the brain, going both ways.

Not all smells are passed on to the brain. Some we simply can’t detect, not having the required receptor. Sometimes the neuron doesn’t fire, if the system is saturated by that smell, for instance. Not all smells are passed to our awareness if the limbic system decides it’s not necessary. So a lot of the smells that we react to, we don’t even notice.

We all have a different smell. Likewise, we all have a different sense of smell. Not everyone smells the same.

rjb

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Grannies

Grannies

About thirty thousand years ago there was a huge increase in grandmothers. At the same time the human population experienced explosive growth.

Scientists studying hominid fossils found that in the Early Upper Paleolithic period, thirty thousand years ago, there were more people living into old age than ever before. They made this observation based on the fossils’ teeth. It’s possible to estimate how long they lived by the amount of wear on their teeth. Old age in the study is defined as twice the age of sexual maturity, or about thirty years. While we don’t see very many thirty year old grandparents these days, it was probably common then.

Throughout the first three million years of the study, from Australopithecines through Homo Erectus to early modern humans, only a small percentage of people lived long enough to help raise their grandchildren. Then there was a population explosion of grannies. And grandpas, too. Five times as many people were living beyond the age of thirty. At the same time there was a marked increase in the population of modern humans in general. And the archeological record shows that their social structures were becoming more complex as well.

This supports the Grandmother Hypothesis. Anthropologists believe that the older members of human societies allowed their cultures to develop. They increased the accumulation of useful knowledge and its transmission down the generations. Their continuing presence helped to build bridges between families and clans. And grandmothers’ experience improved the success of child bearing and child rearing.

When this is put together with continuing improvements in areas like tool-making, language and food preparation, it helps to explain why modern humans did so well populating the planet. Having all those older, wiser people to rely on gave us an advantage.

Something else that contributed to our success is that we are better at cooperating than are other primates. Scientists can infer that from fossil evidence from as long ago as 3-4 million years. The bones indicate a small sexual dimorphism, or size difference, between hominid males and females. In other primates like gorillas and baboons, which have fierce mating competition among males, the sexual dimorphism is much greater. Our ancient hominid ancestors differed in size between the sexes by less than 15% on average, the same as our modern ratio. The toning down of competition and an increase in group cooperation seem to have been successful traits for us hominids.

All we needed then was more grandmothers.

rjb

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