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Trying to understand life
without clearly watching it in action
-
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is like an alien species trying
to understand the rules of a football game
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from just a few snapshots.
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We can learn a lot from these images.
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For example, there's players
on and off the field.
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There's a band.
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There's even cheerleaders
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having a great time watching the game.
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And of course, despite learning
all of this information
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from watching these pictures,
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we still cannot piece together
the rules of the game.
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In order to be able to do that,
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we need to actually
watch the game in action.
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Much of what we know about how life works
-
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comes from watching these snapshots.
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Scientists have been able to figure out
a lot by looking at similar snapshots,
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but ultimately for them
to understand how life works
-
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they need to actually watch it in action.
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And this is essentially where life happens
-
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is trying to understand
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how the fundamental unit of life works,
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and to be able to watch this
-
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we need to be able
to understand how life is.
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Compared to this ant, a human cell
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is about a hundred million
times smaller in volume.
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Do you see the cell
that's right next to this ant?
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It's right there.
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To be able to watch this cell,
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we need to make the invisible visible,
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and we do this by building microscopes.
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Not these microscopes:
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the ones that we build
look something like this.
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It helps that I'm part
of a paparazzi, well, of sorts.
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Instead of taking pictures of people,
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I'm more interested
in taking pictures of famous cells.
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Well, my own career path
up until this moment in time
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has been pretty windy,
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starting with my first childhood obsession
and continued passion in computer science,
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which took a sharp transition
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to looking at engineering,
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and more recently
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a very sharp transition
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to trying to understand cell biology.
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Now, it's these combination of disciplines
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that has led me to where I am today.
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I'm able to carry out
interdisciplinary research
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with one clear goal,
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and the idea is to be able
to advance innovation and discovery
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by bringing together experts
from these different disciplines
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to be able to work together
and solve problems that each of us can't.
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Now, we're interested
in understanding the cell.
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The cell... what is it?
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Well, it's the fundamental unit of life.
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Simply put, it's just a bag.
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It's a bag that has trillions
of inanimate molecules,
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whether it's proteins,
carbohydrates, lipids or fat.
-
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And it turns out,
over the past half a century,
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molecular biologists and biochemists
have figured out ways
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to make these proteins glow.
-
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They light up just like fireflies.
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Now, microscope developers
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have been able to make
better and better instruments
-
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to be able to capture this light
emitted from these molecules,
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and computer scientists and mathematicians
-
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have been able to understand
the signals that are being recorded
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from the cameras.
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And by bringing these tools together,
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we're actually being able to understand
the organization of these molecules
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inside of these cells,
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understand how that changes over time,
-
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and that's essentially
what we're interested in,
-
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trying to understand life at its essence.
-
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So we want to go from imagine life,
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which has traditionally
been confined to two dimensions,
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to being able to image life
in three dimensions.
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So how do you make a two-dimensional image
into a three-dimensional image?
-
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Well, turns out
it's pretty straightforward.
-
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We just collect a series
of two-dimensional images
-
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as we're moving the sample up and down,
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and then we stack the images
on top of each other,
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and then you create
a three-dimensional volume.
-
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The problem with this approach
-
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is that traditional microscopes,
-
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they dump way too much
energy into the system.
-
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That means that this cell
that you see over here,
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it's experiencing a lot of light toxicity,
-
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and that's a problem.
-
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Let me explain that a little bit better.
-
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For example,
-
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let's say that on this planet,
life evolved under just one sun, yes?
-
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Now, let's say I wanted
to watch the shoppers on this street
-
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to understand their shopping habits:
-
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how long they linger in front of stores,
-
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window shopping,
-
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how many stores they go into,
-
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and how long they spend
inside of each of the stores.
-
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And if I was sitting down
at a coffee shop just people-watching,
-
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many wouldn't even notice
that I'm watching them.
-
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Now, what if all of a sudden
-
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I was shining the equivalent
of what is, say,
-
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the light, or the sunlight,
from about five
-
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or, say, 10 different suns?
-
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Would they still behave
as they normally did?
-
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Would they still linger outside
for just as long?
-
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Can I really believe that their behavior
hasn't been altered as a consequence
-
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of being exposed to this much sunlight?
-
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No.
-
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Most microscopes these days,
-
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and conventional microscopes,
-
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have been able to dump
-
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between 10 to 10,000 times the sunlight
that we're exposed to on this planet
-
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where life actually evolved.
-
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And because of this,
-
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well, turns out I'm part
of the cell paparazzi,
-
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so we need to be very careful
in terms of how much light
-
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we actually put into the cell.
-
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Otherwise, we might end up
with a deep-fried cell.
-
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And turns out, there's really
nothing natural
-
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about trying to watch a damaged cell
-
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whose behavior has been
significantly altered.
-
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Well, let's take this cell for example.
-
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It's sitting on a piece of glass.
-
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You see the spots everywhere?
-
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Those spots represent molecular machines
-
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that are assembling
on the surface of the cell
-
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in order to be able to shuttle food
from outside the cell into the cell.
-
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Our lab uses something called
the lattice light sheet microscopy,
-
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which generates a very,
very thin sheet of light,
-
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paying attention not to damage the cells
-
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or not to put too much light
into the system.
-
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And when we do this,
-
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we're able to watch the dynamics
of that process for much longer
-
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without really stressing out these cells.
-
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We've used this microscopy technique
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and tools to be able to understand
how viruses infect cells.
-
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In this example, we've exposed
the cell to rotavirus.
-
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It's an extremely contagious pathogen
that kills over 200,000 people every year.
-
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And by watching these molecules,
these virus particles,
-
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how they diffuse
on the surface of the cells,
-
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we can actually understand
the rules that they're playing by,
-
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and when we understand these rules,
-
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we can start to outsmart them,
-
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whether through
intelligent drug therapies,
-
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to be able to mitigate, manage,
or even prevent the virus
-
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from binding into the cell
in the first place.
-
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Now, we've made the invisible visible,
-
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but the question remains,
-
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when can we believe what we actually see?
-
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Everything I've shown you
up until this point
-
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has been a cell that's been held prisoner
on a piece of glass or in a petri dish.
-
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Well, it turns out that cells
didn't really evolve on a piece of glass.
-
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Right?
-
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They didn't evolve in isolation,
and they didn't evolve
-
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outside their physiological context.
-
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To truly understand
cells' natural behavior,
-
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we need to able to watch them in action
where actually is their home turf.
-
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So, let's take a look
at this complex system.
-
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This is a developing zebrafish embryo,
-
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where you're looking at cells
that are organizing themselves
-
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in order to form tissues,
in order to form organ systems.
-
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And when we watch the movie again,
you'll see that at about 20 hours,
-
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you start to form the eye
and the tail of the zebrafish.
-
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Now, we can watch this,
not in this low resolution,
-
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we can watch this in exquisite detail,
-
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and we want to be able
to watch this in three dimensions
-
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over the course of minutes, seconds,
hours, or even days.
-
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So the problem with these
complex systems is that we scramble,
-
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or they scramble the light
that we actually shine on to them,
-
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which causes us to record
very blurry images.
-
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And it turns out that astronomers
have had a similar problem,
-
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but for them the problem comes
when they're trying to record the light
-
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from distant stars on telescopes
that are ground-based.
-
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The problem is, when the light
travels thousands of light years
-
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and it hits our turbulent
atmosphere all of a sudden,
-
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the light gets scrambled.
-
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They've always luckily figured out
-
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a solution to this
for over half a century.
-
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What they do is they generate
an artificial star
-
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about 90 kilometers
above the Earth's surface,
-
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and they use that light,
which passes through
-
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the same turbulent atmosphere
as the distant star's light,
-
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and they're able to understand
how the light is getting scrambled,
-
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and they take a mirror
that can change its shape
-
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in order to compensate
or undo that scrambling.
-
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So what we've done is we
have taken those ideas
-
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and we've implemented that
with our microscope system,
-
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and when you do that
you can more or less unscramble
-
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the complexity of the scrambling
and the fuzziness that's happening
-
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as a consequence of complex systems.
-
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And we do this in zebrafish.
-
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We like zebrafish because,
like us, they're vertebrates.
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Unlike us, they're mostly transparent.
-
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That means that when
we shine light on them,
-
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we can watch the cellular
and the sub-cellular dynamics
-
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with exquisite detail.
-
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Let me show you an example.
-
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In this video, you're watching the spine
and the muscle of the zebrafish.
-
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We can look at the organization
of the cells, hundreds of cells
-
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in this particular volume,
-
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in the presence and absence
of adaptive optics.
-
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Now, with these tools,
-
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we can watch more clearly
than we've ever been able to before.
-
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And in a very specific example,
-
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looking at how the eye develops
in the zebrafish,
-
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you can really see the commotion inside
of this developing zebrafish embryo.
-
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So you can see the cells
that are dancing around.
-
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In one example, you see
how the cell is dividing.
-
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In another example,
-
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you see cells trying to get places
and squeezing past another cell.
-
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And in the last example, you see a cell
being completely rowdy to its neighbors
-
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by just punching its neighbors. Right?
-
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This technology really enables us
to watch deeper and more clearly,
-
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almost as if we are watching
single cells on a piece of glass
-
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where they have been held prisoner.
-
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And to demonstrate the promise
that this technology holds,
-
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we've partnered with
some of the best scientists
-
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from around the world.
-
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And we've started to ask
a range of fundamental questions
-
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that we're starting to work on
right now together.
-
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For example, how does cancer
spread through the body?
-
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In this example, you're looking
at human breast cancer cells
-
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that are basically kind of migrating,
-
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where they're using the blood vessels
that are shown in magenta,
-
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they're basically using
these blood vessels
-
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as highways to move about the cabin.
-
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You can basically see them
squeezing through the blood vessels.
-
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You can see them rolling
where there's enough space.
-
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And in one example, well, you see
what looks like Ridley Scott's trailer
-
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for the next Alien movie.
-
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This cancer cell is literally trying
to claw its way out of the blood vessel
-
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in order to invade
another part of the body.
-
Not Synced
In the last example I'm going to show you,
-
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we're trying to understand
how the ear develops.
-
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In this case, we were completely
upstaged by crawling immune cells.
-
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These immune cells are basically
on patrol all the time.
-
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Basically, they don't get any time off.
-
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They're working constantly to understand
whether there's stranger danger,
-
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trying to understand
whether there's an infection.
-
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They're sensing the environment,
constantly moving around.
-
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Now, we can watch these images
and these movies in greater detail
-
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than has ever been possible before
in our time up til now.
-
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Now, as with all new technologies,
new capabilities come with new challenges,
-
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and for us the big one
is how we handle the data.
-
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These microscopes generate a ton of data.
-
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We generate anywhere from one
to three terabytes of data per hour.
-
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To put that into context, we're filling up
two million floppy disks every hour,
-
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for our more experienced audience members.
-
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(Laughter)
-
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Roughly equal, then, to about 500 DVDs,
-
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or to put things into
better context for the Gen Z,
-
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that's about a dozen iPhone 11s
that I'm filling up every hour.
-
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We've had a ton of data.
-
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We need to find new ways
to be able to visualize this.
-
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We need to be able to find
new ways to be able to extract
-
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biologically meaningful information
from these data sets.
-
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And more importantly,
-
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we want to make sure that we can put
these advanced microscopes
-
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into the hands of scientists
from all around the world.
-
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And we're giving the designs
of these microscopes for free,
-
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but the key important part
is we need to collaborate
-
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even more to make an impact.
-
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We're bringing together scientists who can
develop new biological and chemical tools.
-
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We're working together
with data scientists
-
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and instrumentation scientists
-
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to be able to build and manage the data.
-
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And because we're giving
these instruments out for free
-
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for all academic and nonprofits,
-
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we're also building advanced
imaging centers to house them,
-
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to be able to bring together the group
of people that are microscopists,
-
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that are the biologists
and the computational people,
-
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and to build a team that's able
to solve the types of problems
-
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that each of us individually cannot.
-
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And thanks to these microscopes,
-
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the frontier of science is open again,
so let's take a look together.
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Thank you.
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(Applause)
closed TED
