And now researchers know exactly what you're eating. Matching blood or stool samples to a reference database of foods reveals how much of our body chemistry is traceable to what we consume
From: University of California San Diego
July 7, 2022 – Researchers
describe a new method to identify all of the unidentified molecules derived
from food, providing a direct way to link molecules in diet to health outcomes.
An international team
of scientists, led by researchers at University of California San Diego, report
a new method called untargeted metabolomics to identify the vast number of
molecules derived from food that were previously unidentified, but that appear
in our blood and our stool.
The method, described
in the July 7, 2022 issue of Nature Biotechnology, matched all of
the products of metabolism in a specimen to large databases of samples where
chemical inventories were available, providing an unprecedented catalog of the
molecule signatures created by consuming food or by processing it in our gut.
The authors said that,
used broadly, the new approach could dramatically expand understanding of the
sources of chemicals in many kinds of human, animal and environmental samples.
"Untargeted mass
spectrometry is a very sensitive technique that allows for the detection of
hundreds to thousands of molecules that can now be used to create a diet
profile of individuals," said co-corresponding author Pieter Dorrestein,
PhD, director of the Collaborative Mass Spectrometry Innovation Center at
Skaggs School of Pharmacy and Pharmaceutical Sciences at the University of
California San Diego.
"The expanded
ability to understand how what we eat translates into products and byproducts
of metabolism has direct implications for human health. We can now use this
approach to obtain diet information empirically and understand relationships to
clinical outcomes. It is now possible to link molecules in diet to health
outcomes not one at a time but all at once, which has not been possible
before."
Metabolomics involves
the comprehensive measurement of all metabolites in a biological specimen.
Metabolites are the substances, usually small molecules, made or used when an
organism breaks down food, drugs, chemicals or its own tissues. They are the
products of metabolism. The study also used a related technique, metagenomics,
to measure genetic material in biological samples and characterize microbes
present.
Current metabolomics
studies annotate or identify only 10 percent of molecular features in sampled
specimens, leaving 90 percent of the material unknown. The new approach uses
reference-data-driven (RDD) analysis to match metabolomics data derived from
tandem mass spectrometry or MS/MS (an analytical tool that measures molecular
weight using two analyzers instead of one) against metadata-annotated data is a
pseudo-MS/MS reference library.
Essentially, each molecule
is stripped of electrons to make it charged. The charged ion is weighed using a
very sensitive scale, then smashed into pieces and those pieces weighed,
creating a unique fingerprint for each molecule.
These collections of
pieces or "fragmentation spectra" can be matched between the sample
being analyzed and a reference database. However, until now the process has
been very challenging.
In the new work,
researchers investigated thousands of foods contributed by people around the
world in the Global FoodOmics initiative launched at UC San Diego seven years
ago, building on the success of the citizen-science American Gut Project/The
Microsetta Initiative. The scientists increased their data output more than
five-old over conventional techniques. Most importantly, the new method allowed
untargeted metabolomics to be used to determine the diet based on a stool or
blood sample.
The authors said RDD
analysis allowed them to parse dietary patterns (vegan versus omnivore, for
example) and consumption of specific foods and more generally, match the data
against any existing reference databases.
"This advance is
crucial because traditional methods for measuring diet, such as food diaries or
food frequency questionnaires, are a pain to fill out and very hard to do
accurately," said co-corresponding author Rob Knight, PhD, director of the
Center for Microbiome Innovation at UC San Diego.
"The potential to
read out diet from a sample directly has huge implications for research in
populations like people with Alzheimer's Disease, who may not be able to
remember or explain what they ate. And in wildlife conservation applications.
Good luck getting a cheetah or a gorilla, to name just two species out of the
hundreds we're studying, to fill out a food diary."
Of particular interest,
said Dorrestein and Knight, were the large improvements in how many of the
molecules in blood or stool that could be explained when food items were
matched to population, such as matching food from Italy to people from the
Cilento peninsula where UC San Diego scientists are collaborating on a study of
centenarians.
"This really shows
how important it will be to get both food specimens and clinical samples from
people around the world in order to understand how our molecules and microbes
work together to improve or degrade our health based on the diets we eat,"
said Knight.
"This study also
points the way toward using RDD to explain the dark matter in our
metabolome," added Dorrestein, "not only in terms of diet, but in
exposures to chemicals from the clothes we wear, the medications we take, the
beauty products we apply and the environments we are exposed to. It will truly
let us explore the chemical connections between ourselves and the world we
inhabit."
https://www.sciencedaily.com/releases/2022/07/220707133613.htm
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