What's that smell?
James Urton, UW News
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Even brief exposure
to nature can help. One well-known study found that hospital patients recovered
faster if their room included a window view of a natural
setting.
Knowing more about nature’s effects on our bodies could not only help our well-being, but could also improve how we care for land, preserve ecosystems and design cities, homes and parks.
Yet studies on the
benefits of contact with nature have typically focused primarily on how seeing
nature affects us. There has been less focus on what the nose knows. That is
something a group of researchers wants to change.
“We are immersed in a world of odorants, and we have a sophisticated olfactory system that processes them, with resulting impacts on our emotions and behavior,” said Gregory Bratman, a University of Washington assistant professor of environmental and forest sciences. “But compared to research on the benefits of seeing nature, we don’t know nearly as much about how the impacts of nature’s scents and olfactory cues affect us.”
In a paper published May 15 in Science
Advances, Bratman and colleagues from around the world outline ways to expand
research into how odors and scents from natural settings impact our health and
well-being. The interdisciplinary group of experts in olfaction, psychology,
ecology, public health, atmospheric science and other fields are based at
institutions in the U.S., the U.K., Taiwan, Germany, Poland and Cyprus.
At its core, the human sense of smell, or olfaction, is
a complex chemical detection system in
constant operation. The nose is packed with hundreds of olfactory receptors,
which are sophisticated chemical sensors. Together, they can detect more than one trillion scents, and
that information gets delivered directly to the nervous system for our minds to
interpret — consciously or otherwise.
The natural world releases a steady stream of chemical
compounds to keep our olfactory system busy. Plants in particular exude volatile organic compounds, or VOCs, that
can persist in the air for hours or days. VOCs perform many functions for
plants, such as repelling herbivores or attracting pollinators. Some
researchers have studied the impact of exposures to plant VOCs on people.
“We know bits and pieces of the overall picture,” said
Bratman. “But there is so much more to learn. We are proposing a framework,
informed by important research from many others, on how to investigate the
intimate links between olfaction, nature and human well-being.”
Nature’s smell-mediated impacts likely come through different routes, according to the authors. Some chemical compounds, including a subset of those from the invisible realm of plant VOCs, may be acting on us without our conscious knowledge. In these cases, olfactory receptors in the nose could be initiating a “subthreshold” response to molecules that people are largely unaware of.
Bratman and his co-authors are calling for vastly expanded
research on when, where and how these undetected biochemical processes related
to natural VOCs may affect us.
Other olfactory cues are picked up consciously, but scientists still don’t fully understand all their impacts on our health and well-being. Some scents, for example, may have “universal” interpretations to humans — something that nearly always smells pleasant, like a sweet-smelling flower.
Other scents are closely tied to specific memories, or have
associations and interpretations that vary by culture and personal experience,
as research by co-author Asifa
Majid of the University of Oxford has shown.
“Understanding how olfaction mediates our relationships
with the natural world and the benefits we receive from it are
multi-disciplinary undertakings,” said Bratman. “It involves insights from
olfactory function research, Indigenous knowledge, Western psychology,
anthropology, atmospheric chemistry, forest ecology, Shinrin-yoku — or ‘forest bathing’ —
neuroscience, and more.”
Investigation into the potential links between our sense
of smell and positive experiences with nature includes research by
co-author Cecilia Bembibre at University College
London, which shows that the cultural significance of smells, including those
from nature, can be passed down in communities to each new generation.
Co-author Jieling Xiao at Birmingham City
University has delved into the associations people have with scents in built
environments and urban gardens.
Other co-authors have shown that nature leaves its
signature in the very air we breathe. Forests, for example, release a complex
chemical milieux into the air. Research by co-author Jonathan
Williams at the Max Planck Institute for Chemistry and the
Cyprus Institute shows how natural VOCs can react and mix in the atmosphere,
with repercussions for olfactory environments.
The authors are also calling for more studies to
investigate how human activity alters nature’s olfactory footprint — both by
pollution, which can modify or destroy odorants in the air, and by reducing
habitats that release beneficial scents.
“Human activity is modifying the environment so quickly in some cases that we’re learning about these benefits while we’re simultaneously making them more difficult for people to access,” said Bratman.
“As research illuminates more of these links, our hope is that we can make more
informed decisions about our impacts on the natural world and the volatile
organic compounds that come from it. As we say in the paper, we live within the
chemical contexts that nature creates. Understanding this more can contribute
to human well-being and advance efforts to protect the natural world.”
Other UW co-authors on the paper are Peter
Kahn, profess of psychology; Connor Lashus, a graduate student in the
School of Environmental and Forest Sciences; and Anne Riederer, a clinical associate
professor of environmental and occupational health sciences. Additional
co-authors are Gretchen Daily of Stanford
University; Richard Doty at the University of
Pennsylvania; Thomas Hummel of the Dresden University of Technology; Lucia Jacobs of the University of
California, Berkeley; John Miller of Wildwood|Mahonia; Anna Oleszkiewicz of the
University of Wrocław; Hector Olvera-Alvarez of Oregon Health
and Sciences University; Valentina Parma of the Monell Chemical
Senses Center; Nancy Long Sieber and John Spengler of Harvard University;
and Chia-Pin Yu of National Taiwan University.
For more information, contact Bratman at bratman@uw.edu.
