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In 2003,
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when we sequenced the human genome,
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we thought we would have the answer
to treat many diseases.
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But the reality is far from that,
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because in addition to our genes,
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our environment and lifestyle
could have a significant role
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in developing many major diseases.
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One example is fatty liver disease,
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which is affecting over 20 percent
of the population globally,
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and it has no treatment
and leads to liver cancer
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or liver failure.
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So sequencing DNA alone
doesn't give us enough information
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to find effective therapeutics.
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On the bright side, there are
many other molecules in our body.
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In fact, there are
over 100,000 metabolites.
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Metabolites are any molecule
that is supersmall in their size.
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Known examples are glucose,
fructose, fats, cholesterol --
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things we hear all the time.
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Metabolites are involved
in our metabolism.
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They are also downstream of DNA,
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so they carry information
from both our genes as well as lifestyle.
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Understanding metabolites is essential
to find treatments for many diseases.
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I've always wanted to treat patients.
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Despite that, 15 years ago,
I left medical school,
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as I missed mathematics.
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Soon after, I found the coolest thing:
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I can use mathematics to study medicine.
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Since then, I've been developing
algorithms to analyze biological data.
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So, it sounded easy:
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let's collect data from all
the metabolites in our body,
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develop mathematical models to describe
how they are changed in a disease
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and intervene in those
changes to treat them.
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Then I realized why no one
has done this before:
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it's extremely difficult.
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(Laughter)
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There are many metabolites in our body.
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Each one is different from the other one.
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For some metabolites,
we can measure their molecular mass
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using mass spectrometry instruments.
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But because there could be, like,
10 molecules with the exact same mass,
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we don't know exactly what they are,
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and if you want to clearly
identify all of them,
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you have to do more experiments,
which could take decades
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and billions of dollars.
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So we developed an artificial
intelligence, or AI, platform, to do that.
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We leveraged the growth of biological data
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and built a database of any existing
information about metabolites
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and their interactions
with other molecules.
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We combined all this data
as a meganetwork.
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Then, from tissues or blood of patients,
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we measure masses of metabolites
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and find the masses
that are changed in a disease.
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But, as I mentioned earlier,
we don't know exactly what they are.
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A molecular mass of 180 could be
either the glucose, galactose or fructose.
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They all have the exact same mass
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but different functions in our body.
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Our AI algorithm considered
all these ambiguities.
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It then mined that meganetwork
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to find how those metabolic masses
are connected to each other
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that result in disease.
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And because of the way they are connected,
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then we are able to infer
what each metabolite mass is,
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like that 180 could be glucose here,
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and, more importantly, to discover
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how changes in glucose
and other metabolites
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lead to a disease.
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This novel understanding
of disease mechanisms
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then enable us to discover
effective therapeutics to target that.
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So we formed a start-up company
to bring this technology to the market
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and impact people's lives.
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Now my team and I at ReviveMed
are working to discover
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therapeutics for major diseases
that metabolites are key drivers for,
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like fatty liver disease,
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because it is caused
by accumulation of fats,
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which are types
of metabolites in the liver.
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As I mentioned earlier,
it's a huge epidemic with no treatment.
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And fatty liver disease
is just one example.
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Moving forward, we are going to tackle
hundreds of other diseases
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with no treatment.
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And by collecting more and more
data about metabolites
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and understanding
how changes in metabolites
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leads to developing diseases,
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our algorithms will get
smarter and smarter
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to discover the right therapeutics
for the right patients.
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And we will get closer to reach our vision
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of saving lives with every line of code.
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Thank you.
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(Applause)
closed TED
