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Cancer affects all of us --
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especially the ones that come
back over and over again,
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the highly invasive
and drug-resistant ones,
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the ones that defy medical treatment,
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even when we throw our best drugs at them.
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Engineering at the molecular level,
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working at the smallest of scales,
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can provide exciting new ways
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to fight the most aggressive
forms of cancer.
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Cancer is a very clever disease.
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There are some forms of cancer,
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which, fortunately, we've learned
how to address relatively well
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with known and established
drugs and surgery.
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But there are some forms of cancer
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that don't respond to these approaches,
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and the tumor survives or comes back,
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even after an onslaught of drugs.
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We can think of these
very aggressive forms of cancer
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as kind of supervillains in a comic book.
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They're clever, they're adaptable,
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and they're very good at staying alive.
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And, like most supervillains these days,
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their superpowers come
from a genetic mutation.
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The genes that are modified
inside these tumor cells
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can enable and encode for new
and unimagined modes of survival,
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allowing the cancer cell to live through
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even our best chemotherapy treatments.
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One example is a trick
in which a gene allows a cell,
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even as the drug approaches the cell,
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to push the drug out,
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before the drug can have any effect.
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Imagine -- the cell effectively
spits out the drug.
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This is just one example
of the many genetic tricks
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in the bag of our supervillain, cancer.
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All due to mutant genes.
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So.
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We have a supervillain
with incredible superpowers.
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And we need a new and powerful
mode of attack.
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Actually, we can turn off a gene.
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The key is a set of molecules
known as siRNA.
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siRNA are short sequences of genetic code
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that guide a cell to block a certain gene.
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Each siRNA molecule
can turn off a specific gene
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inside the cell.
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For many years since its discovery,
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scientists have been very excited
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about how we can apply
these gene blockers in medicine.
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But, there is a problem.
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siRNA works well inside the cell.
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But if it gets exposed to the enzymes
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that reside in our bloodstream
or our tissues,
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it degrades within seconds.
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It has to be packaged, protected
through its journey through the body
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on its way to the final target
inside the cancer cell.
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So, here's our strategy:
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First, we'll dose the cancer cell
with siRNA, the gene blocker,
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and silence those survival genes,
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and then we'll whop it with a chemo drug.
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But how do we carry that out?
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Using molecular engineering,
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we can actually design a superweapon
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that can travel through the bloodstream.
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It has to be tiny enough
to get through the bloodstream,
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it's got to be small enough
to penetrate the tumor tissue
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and it's got to be tiny enough
to be taken up inside the cancer cell.
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To do this job well,
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it has to be about one one-hundredth
the size of a human hair.
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Let's take a closer look
at how we can build this nanoparticle.
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First, let's start
with the nanoparticle core.
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It's a tiny capsule that contains
the chemotherapy drug.
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This is the poison that will
actually end the tumor cell's life.
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Around this core, we'll wrap a very thin,
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nanometers-thin blanket of siRNA.
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This is our gene blocker.
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Because siRNA is strongly
negatively charged,
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we can protect it
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with a nice, protective layer
of positively charged polymer.
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The two oppositely charged
molecules stick together
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through charge attraction,
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and that provides us
with a protective layer
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that prevents the siRNA
from degrading in the bloodstream.
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We're almost done.
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(Laughter)
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But there is one more big obstacle
we have to think about.
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In fact, it may be the biggest
obstacle of all.
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How do we deploy this superweapon?
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I mean, every good weapon
needs to be targeted,
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we have to target this superweapon
to the supervillain cells
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that reside in the tumor.
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But our bodies have a natural
immune-defense system:
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cells that reside in the bloodstream
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and pick out things that don't belong,
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so that it can destroy or eliminate them.
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And guess what? Our nanoparticle
is considered a foreign object.
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We have to sneak our nanoparticle
past the tumor defense system.
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We have to get it past this mechanism
of getting rid of the foreign object,
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by disguising it.
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So we add one more
negatively charged layer
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around this nanoparticle,
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which serves two purposes:
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First, this outer layer is one
of the naturally charged,
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highly hydrated polysaccharides
that resides in our body.
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It creates a cloud of water molecules
around the nanoparticle
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that gives us an invisibility
cloaking effect.
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This invisibility cloak allows
the nanoparticle
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to travel through the bloodstream
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long and far enough to reach the tumor,
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without getting eliminated by the body.
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Second, this layer contains molecules
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which bind specifically to our tumor cell.
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Once bound, the cancer cell
takes up the nanoparticle,
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and now we have our nanoparticle
inside the cancer cell
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and ready to deploy.
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Alright! I feel the same way. Let's go!
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(Applause)
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The siRNA is deployed first.
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It acts for hours,
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giving enough time to silence
and block those survival genes.
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We have now disabled
those genetic superpowers.
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What remains is a cancer cell
with no special defenses.
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Then, the chemotherapy drug
comes out of the core
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and destroys the tumor cell
cleanly and efficiently.
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With sufficient gene blockers,
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we can address many
different kinds of mutations,
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allowing the chance to sweep out tumors,
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without leaving behind any bad guys.
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So, how does our strategy work?
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We've tested these nanostructure
particles in animals
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using a highly aggressive form
of triple-negative breast cancer.
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This triple-negative breast cancer
exhibits the gene
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that spits out cancer drug
as soon as it is delivered.
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Usually, doxorubicin -- let's call
it "dox" -- is the cancer drug
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that is the first line of treatment
for breast cancer.
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So, we first treated our animals
with a dox core, dox only.
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The tumor slowed their rate of growth,
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but they still grew rapidly,
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doubling in size
over a period of two weeks.
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Then, we tried
our combination superweapon.
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And now layer a particle
with siRNA against the chemo pump,
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plus, we have the dox in the core.
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And look -- we found that not only
did the tumors stop growing,
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they actually decreased in size
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and were eliminated in some cases.
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The tumors were actually regressing.
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(Applause)
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What's great about this approach
is that it can be personalized.
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We can add many different layers of siRNA
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to address different mutations
and tumor defense mechanisms.
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And we can put different drugs
into the nanoparticle core.
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As doctors learn how to test patients
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and understand certain
tumor genetic types,
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they can help us determine which patients
can benefit from this strategy
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and which gene blockers we can use.
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Ovarian cancer strikes
a special chord with me.
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It is a very aggressive cancer,
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in part because it's discovered
at very late stages,
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when it's highly advanced
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and there are a number
of genetic mutations.
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After the first round of chemotherapy,
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this cancer comes back
for 75 percent of patients.
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And it usually comes back
in a drug-resistant form.
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High-grade ovarian cancer
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is one of the biggest
supervillains out there.
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And we're now directing our superweapon
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toward its defeat.
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As a researcher,
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I usually don't get to work with patients.
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But I recently met a mother
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who is an ovarian cancer survivor,
Mimi, and her daughter, Paige.
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I was deeply inspired
by the optimism and strength
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that both mother and daughter displayed,
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and by their story of courage and support.
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At this event, we spoke
about the different technologies
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directed at cancer.
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And Mimi was in tears
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as she explained how learning
about these efforts
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gives her hope for future generations,
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including her own daughter.
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This really touched me.
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It's not just about building
really elegant science.
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It's about changing people's lives.
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It's about understanding
the power of engineering
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on the scale of molecules.
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I know that as students like Paige
move forward in their careers,
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they'll open new possibilities
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in addressing some of the big
health problems in the world --
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including ovarian cancer, neurological
disorders, infectious disease --
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just as chemical engineering has
found a way to open doors for me,
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and has provided a way of engineering
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on the tiniest scale -- that
of molecules --
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to heal on the human scale.
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Thank you.
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(Applause)
closed TED
