The universal anesthesia machine

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I'm going to talk to you today
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about the design of medical technology
for low-resource settings.
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I study health systems in these countries.
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And one of the major gaps in care,
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almost across the board,
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is access to safe surgery.
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Now one of the major
bottlenecks that we've found
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that's sort of preventing
both the access in the first place,
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and the safety of those surgeries
that do happen, is anesthesia.
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And actually, it's the model
that we expect to work
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for delivering anesthesia
in these environments.
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Here, we have a scene that you would find
in any operating room across the US,
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or any other developed country.
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In the background there
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is a very sophisticated
anesthesia machine.
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And this machine is able
to enable surgery and save lives
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because it was designed
with this environment in mind.
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In order to operate,
this machine needs a number of things
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that this hospital has to offer.
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It needs an extremely
well-trained anesthesiologist
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with years of training
with complex machines
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to help her monitor the flows of the gas
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and keep her patients
safe and anesthetized
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throughout the surgery.
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It's a delicate machine
running on computer algorithms,
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and it needs special care, TLC,
to keep it up and running,
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and it's going to break pretty easily.
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And when it does, it needs
a team of biomedical engineers
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who understand its complexities,
can fix it, can source the parts
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and keep it saving lives.
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It's a pretty expensive machine.
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It needs a hospital
whose budget can allow it
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to support one machine
costing upwards of 50 or $100,000.
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And perhaps most obviously,
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but also most importantly --
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and the path to concepts
that we've heard about
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kind of illustrates this --
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it needs infrastructure that can supply
an uninterrupted source of electricity,
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of compressed oxygen,
and other medical supplies
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that are so critical
to the functioning of this machine.
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In other words, this machine
requires a lot of stuff
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that this hospital cannot offer.
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This is the electrical supply
for a hospital in rural Malawi.
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In this hospital,
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there is one person qualified
to deliver anesthesia,
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and she's qualified
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because she has 12, maybe 18 months
of training in anesthesia.
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In the hospital and in the entire region
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there's not a single biomedical engineer.
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So when this machine breaks,
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the machines that they have
to work with break,
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they've got to try and figure it out,
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but most of the time,
that's the end of the road.
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Those machines go the proverbial junkyard.
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And the price tag
of the machine that I mentioned
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could represent maybe a quarter or a third
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of the annual operating budget
for this hospital.
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And finally, I think you can see
that infrastructure is not very strong.
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This hospital is connected
to a very weak power grid,
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one that goes down frequently.
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So it runs frequently,
the entire hospital,
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just on a generator.
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And you can imagine,
the generator breaks down
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or runs out of fuel.
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And the World Bank sees this
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and estimates that a hospital
in this setting in a low-income country
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can expect up to
18 power outages per month.
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Similarly, compressed oxygen
and other medical supplies
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are really a luxury,
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and can often be out of stock
for months or even a year.
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So it seems crazy, but the model
that we have right now
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is taking those machines
that were designed
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for that first environment
that I showed you
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and donating or selling them
to hospitals in this environment.
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It's not just inappropriate,
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it becomes really unsafe.
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One of our partners at Johns Hopkins
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was observing surgeries in Sierra Leone
about a year ago.
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And the first surgery of the day
happened to be an obstetrical case.
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A woman came in,
she needed an emergency C-section
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to save her life and the life of her baby.
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And everything began pretty auspiciously.
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The surgeon was on call and scrubbed in.
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The nurse was there.
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She was able to anesthetize her quickly,
and it was important
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because of the emergency
nature of the situation.
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And everything began well
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until the power went out.
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And now in the middle of this surgery,
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the surgeon is racing
against the clock to finish his case,
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which he can do -- he's got a headlamp.
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But the nurse is literally running
around a darkened operating theater
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trying to find anything
she can use to anesthetize her patient,
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to keep her patient asleep.
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Because her machine doesn't work
when there's no power.
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This routine surgery that many of you
have probably experienced,
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and others are probably the product of,
has now become a tragedy.
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And what's so frustrating
is this is not a singular event;
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this happens across the developing world.
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35 million surgeries
are attempted every year
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without safe anesthesia.
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My colleague, Dr. Paul Fenton,
was living this reality.
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He was the chief of anesthesiology
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in a hospital in Malawi,
a teaching hospital.
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He went to work every day
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in an operating theater like this one,
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trying to deliver anesthesia
and teach others how to do so
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using that same equipment
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that became so unreliable,
and frankly unsafe, in his hospital.
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And after umpteen surgeries
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and, you can imagine,
really unspeakable tragedy,
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he just said, "That's it.
I'm done. That's enough.
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There has to be something better."
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He took a walk down the hall
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to where they threw all those machines
that had just crapped out on them,
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I think that's the scientific term,
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and he started tinkering.
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He took one part from here
and another from there,
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and he tried to come up
with a machine that would work
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in the reality that he was facing.
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And what he came up with:
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was this guy.
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The prototype for the Universal
Anesthesia Machine --
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a machine that would work
and anesthetize his patients
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no matter the circumstances
that his hospital had to offer.
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Here it is, back at home
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at that same hospital, developed
a little further, 12 years later,
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working on patients
from pediatrics to geriatrics.
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Let me show you a little bit
about how this machine works.
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Voila!
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Here she is.
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When you have electricity,
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everything in this machine
begins in the base.
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There's a built-in
oxygen concentrator down there.
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Now you've heard me mention
oxygen a few times at this point.
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Essentially, to deliver anesthesia,
you want as pure oxygen as possible,
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because eventually you're going
to dilute it, essentially, with the gas.
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And the mixture that the patient inhales
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needs to be at least
a certain percentage oxygen
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or else it can become dangerous.
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But so in here when there's electricity,
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the oxygen concentrator takes in room air.
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Now we know room air is gloriously free,
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it is abundant,
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and it's already 21 percent oxygen.
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So all this concentrator does
is take that room air in, filter it
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and send 95 percent pure oxygen
up and across here,
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where it mixes with the anesthetic agent.
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Now before that mixture
hits the patient's lungs,
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it's going to pass by here --
you can't see it,
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but there's an oxygen sensor here --
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that's going to read out on this screen
the percentage of oxygen being delivered.
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Now if you don't have power,
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or, God forbid, the power cuts out
in the middle of a surgery,
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this machine transitions automatically,
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without even having to touch it,
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to drawing in room air from this inlet.
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Everything else is the same.
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The only difference is that now
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you're only working
with 21 percent oxygen.
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Now that used to be
a dangerous guessing game,
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because you only knew
if you gave too little oxygen
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once something bad happened.
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But we've put a long-life
battery backup on here.
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This is the only part
that's battery backed up.
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But this gives control to the provider,
whether there's power or not,
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because they can adjust the flows
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based on the percentage of oxygen
they see that they're giving the patient.
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In both cases,
whether you have power or not,
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sometimes the patient
needs help breathing.
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It's just a reality of anesthesia,
the lungs can be paralyzed.
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And so we've just added
this manual bellows.
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We've seen surgeries
for three or four hours
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to ventilate the patient on this.
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So it's a straightforward machine.
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I shudder to say simple;
it's straightforward.
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And it's by design.
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You do not need to be a highly trained,
specialized anesthesiologist
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to use this machine,
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which is good because,
in these rural district hospitals,
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you're not going to get
that level of training.
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It's also designed for the environment
that it will be used in.
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This is an incredibly rugged machine.
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It has to stand up to the heat
and the wear and tear
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that happens in hospitals
in these rural districts.
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And so it's not going
to break very easily,
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but if it does, virtually
every piece in this machine
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can be swapped out and replaced
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with a hex wrench and a screwdriver.
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And finally, it's affordable.
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This machine comes in
at an eighth of the cost
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of the conventional machine
that I showed you earlier.
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So in other words, what we have here
is a machine that can enable surgery
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and save lives,
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because it was designed
for its environment,
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just like the first machine I showed you.
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But we're not content to stop there.
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Is it working?
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Is this the design
that's going to work in place?
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Well, we've seen good results so far.
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This is in 13 hospitals in four countries,
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and since 2010, we've done
well over 2,000 surgeries
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with no clinically adverse events.
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So we're thrilled.
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This really seems like
a cost-effective, scalable solution
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to a problem that's really pervasive.
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But we still want to be sure
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that this is the most effective
and safe device
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that we can be putting into hospitals.
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So to do that, we've launched
a number of partnerships
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with NGOs and universities,
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to gather data on the user interface,
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on the types of surgeries
it's appropriate for,
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and ways we can enhance the device itself.
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One of those partnerships
is with Johns Hopkins
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just here in Baltimore.
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They have a really cool anesthesia
simulation lab out in Baltimore.
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So we're taking this machine
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and recreating some
of the operating theater crises
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that this machine might face
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in one of the hospitals
that it's intended for,
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and in a contained, safe environment,
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evaluating its effectiveness.
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We're then able to compare
the results from that study
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with real-world experience,
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because we're putting
two of these in hospitals
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that Johns Hopkins
works with in Sierra Leone,
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including the hospital
where that emergency C-section happened.
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So I've talked a lot about anesthesia,
and I tend to do that.
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I think it is incredibly fascinating
and an important component of health.
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And it really seems peripheral,
we never think about it,
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until we don't have access to it,
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and then it becomes a gatekeeper.
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Who gets surgery and who doesn't?
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Who gets safe surgery and who doesn't?
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But you know,
it's just one of so many ways
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that design, appropriate design,
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can have an impact on health outcomes.
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If more people
in the health-delivery space
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really working on some of these
challenges in low-income countries
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could start their design process,
their solution search,
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from outside of that proverbial box
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and inside of the hospital --
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In other words, if we could design
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for the environment that exists
in so many parts of the world,
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rather than the one
that we wished existed --
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we might just save a lot of lives.
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Thank you very much.
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(Applause)

Title:: The universal anesthesia machine
Speaker:: Erica Frenkel
Description:: What if you're in surgery and the power goes out? No lights, no oxygen -- and your anesthesia stops flowing. It happens constantly in hospitals throughout the world, turning routine procedures into tragedies. Erica Frenkel demos one solution: the universal anesthesia machine.

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Video Language:: English
Team:: closed TED
Project:: TEDTalks
Duration:: 11:03

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Krystian Aparta

The English transcript was updated on 11/9/2016.

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The universal anesthesia machine

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