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Demo: A needle-free vaccine patch that's safer and way cheaper

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    It's a pleasure to be here
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    in Edinburgh, Scotland,
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    the birthplace of the needle and syringe.
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    Less than a mile from here in this direction,
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    in 1853 a Scotsman
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    filed his very first patent on the needle and syringe.
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    His name was Alexander Wood,
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    and it was at the Royal College of Physicians.
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    This is the patent.
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    What blows my mind when I look at it even today
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    is that it looks almost identical
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    to the needle in use today.
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    Yet, it's 160 years old.
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    So we turn to the field of vaccines.
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    Most vaccines are delivered with
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    the needle and syringe,
    this 160-year-old technology.
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    And credit where it's due -- on many levels,
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    vaccines are a successful technology.
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    After clean water and sanitation,
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    vaccines are the one technology that has increased
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    our life span the most.
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    That's a pretty hard act to beat.
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    But just like any other technology,
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    vaccines have their shortcomings,
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    and the needle and syringe
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    is a key part within that narrative --
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    this old technology.
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    So let's start with the obvious:
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    Many of us don't like the needle and syringe.
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    I share that view.
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    However, 20 percent of the population
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    have a thing called needle phobia.
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    That's more than disliking the needle;
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    that is actively avoiding being vaccinated
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    because of needle phobia.
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    And that's problematic in terms
    of the rollout of vaccines.
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    Now, related to this is another key issue,
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    which is needlestick injuries.
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    And the WHO has figures
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    that suggest about 1.3 million deaths per year
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    take place due to cross-contamination
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    with needlestick injuries.
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    These are early deaths that take place.
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    Now, these are two things that
    you probably may have heard of,
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    but there are two other shortcomings
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    of the needle and syringe you
    may not have heard about.
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    One is it could be holding back
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    the next generation of vaccines
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    in terms of their immune responses.
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    And the second is that it could be responsible
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    for the problem of the cold chain
    that I'll tell you about as well.
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    I'm going to tell you about some work
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    that my team and I are doing in Australia
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    at the University of Queensland
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    on a technology designed to
    tackle those four problems.
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    And that technology is called the Nanopatch.
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    Now, this is a specimen of the Nanopatch.
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    To the naked eye
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    it just looks like a square
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    smaller than a postage stamp,
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    but under a microscope
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    what you see are thousands of tiny projections
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    that are invisible to the human eye.
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    And there's about 4,000 projections
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    on this particular square compared to the needle.
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    And I've designed those projections
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    to serve a key role, which is to
    work with the skin's immune system.
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    So that's a very important function
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    tied in with the Nanopatch.
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    Now we make the Nanopatch
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    with a technique
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    called deep reactive ion etching.
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    And this particular technique
    is one that's been borrowed
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    from the semiconductor industry,
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    and therefore is low cost
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    and can be rolled out in large numbers.
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    Now we dry-coat vaccines to
    the projections of the Nanopatch
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    and apply it to the skin.
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    Now, the simplest form of application
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    is using our finger,
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    but our finger has some limitations,
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    so we've devised an applicator.
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    And it's a very simple device --
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    you could call it a sophisticated finger.
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    It's a spring-operated device.
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    What we do is when we apply
    the Nanopatch to the skin as so --
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    (Click) --
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    immediately a few things happen.
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    So firstly, the projections on the Nanopatch
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    breach through the tough outer layer
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    and the vaccine is very quickly released --
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    within less than a minute, in fact.
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    Then we can take the Nanopatch off
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    and discard it.
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    And indeed we can make
    a reuse of the applicator itself.
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    So that gives you an idea of the Nanopatch,
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    and immediately you can see some key advantages.
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    We've talked about it being needle-free --
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    these are projections that you can't even see --
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    and, of course, we get around
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    the needle phobia issue as well.
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    Now, if we take a step back and think about
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    these other two really important advantages:
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    One is improved immune
    responses through delivery,
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    and the second is getting rid of the cold chain.
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    So let's start with the first one,
    this immunogenicity idea.
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    It takes a little while to get our heads around,
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    but I'll try to explain it in simple terms.
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    So I'll take a step back and explain to you
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    how vaccines work in a simple way.
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    So vaccines work by introducing into our body
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    a thing called an antigen
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    which is a safe form of a germ.
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    Now that safe germ, that antigen,
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    tricks our body into mounting an immune response,
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    learning and remembering
    how to deal with intruders.
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    When the real intruder comes along
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    the body quickly mounts an immune response
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    to deal with that vaccine
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    and neutralizes the infection.
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    So it does that well.
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    Now, the way it's done today
    with the needle and syringe,
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    most vaccines are delivered that way --
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    with this old technology and the needle.
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    But it could be argued that the needle
    is holding back our immune responses;
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    it's missing our immune sweet spot in the skin.
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    To describe this idea,
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    we need to take a journey through the skin,
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    starting with one of those projections
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    and applying the Nanopatch to the skin.
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    And we see this kind of data.
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    Now, this is real data --
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    that thing that we can see there is one projection
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    from the Nanopatch that's been applied to the skin
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    and those colors are different layers.
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    Now, to give you an idea of scale,
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    if the needle was shown here, it would be too big.
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    It would be 10 times bigger
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    than the size of that screen,
    going 10 times deeper as well.
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    It's off the grid entirely.
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    You can see immediately that we
    have those projections in the skin.
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    That red layer is a tough outer layer of dead skin,
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    but the brown layer and the magenta layer
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    are jammed full of immune cells.
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    As one example, in the brown layer
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    there's a certain type of cell
    called a Langerhans cell --
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    every square millimeter of our body
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    is jammed full of those Langerhans cells,
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    those immune cells, and
    there's others shown as well
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    that we haven't stained in this image.
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    But you can immediately see that the Nanopatch
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    achieves that penetration indeed.
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    We target thousands upon thousands
    of these particular cells
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    just residing within a hair's width
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    of the surface of the skin.
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    Now, as the guy that's invented
    this thing and designed it to do that,
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    I found that exciting. But so what?
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    So what if you've targeted cells?
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    In the world of vaccines, what does that mean?
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    The world of vaccines is getting better.
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    It's getting more systematic.
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    However, you still don't really know
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    if a vaccine is going to work
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    until you roll your sleeves up
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    and vaccinate and wait.
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    It's a gambler's game even today.
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    So, we had to do that gamble.
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    We obtained an influenza vaccine,
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    we applied it to our Nanopatches
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    and we applied the Nanopatches to the skin,
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    and we waited --
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    and this is in the live animal.
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    We waited a month,
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    and this is what we found out.
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    This is a data slide showing the immune responses
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    that we've generated with a Nanopatch
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    compared to the needle and syringe into muscle.
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    So on the horizontal axis we have
    the dose shown in nanograms.
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    On the vertical axis we have
    the immune response generated,
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    and that dashed line indicates
    the protection threshold.
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    If we're above that line it's considered protective;
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    if we're below that line it's not.
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    So the red line is mostly below that curve
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    and indeed there's only one point that
    is achieved with the needle that's protective,
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    and that's with a high dose of 6,000 nanograms.
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    But notice immediately the distinctly different curve
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    that we achieve with the blue line.
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    That's what's achieved with the Nanopatch;
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    the delivered dose of the Nanopatch is
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    a completely different immunogenicity curve.
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    That's a real fresh opportunity.
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    Suddenly we have a brand new lever
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    in the world of vaccines.
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    We can push it one way,
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    where we can take a vaccine
    that works but is too expensive
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    and can get protection
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    with a hundredth of the dose
    compared to the needle.
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    That can take a vaccine that's suddenly
    10 dollars down to 10 cents,
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    and that's particularly important
    within the developing world.
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    But there's another angle to this as well --
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    you can take vaccines that currently don't work
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    and get them over that line
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    and get them protective.
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    And certainly in the world of vaccines
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    that can be important.
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    Let's consider the big three:
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    HIV, malaria, tuberculosis.
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    They're responsible for about
    7 million deaths per year,
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    and there is no adequate vaccination
    method for any of those.
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    So potentially, with this new lever
    that we have with the Nanopatch,
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    we can help make that happen.
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    We can push that lever to help get those
    candidate vaccines over the line.
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    Now, of course, we've worked within my lab
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    with many other vaccines that have attained
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    similar responses and similar curves to this,
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    what we've achieved with influenza.
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    I'd like to now switch to talk about
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    another key shortcoming of today's vaccines,
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    and that is the need to maintain the cold chain.
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    As the name suggests -- the cold chain --
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    it's the requirements of keeping
    a vaccine right from production
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    all the way through to when the vaccine is applied,
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    to keep it refrigerated.
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    Now, that presents some logistical challenges
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    but we have ways to do it.
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    This is a slightly extreme case in point
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    but it helps illustrate the logistical challenges,
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    in particular in resource-poor settings,
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    of what's required to get vaccines
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    refrigerated and maintain the cold chain.
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    If the vaccine is too warm the vaccine breaks down,
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    but interestingly it can be too cold
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    and the vaccine can break down as well.
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    Now, the stakes are very high.
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    The WHO estimates that within Africa,
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    up to half the vaccines used there
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    are considered to not be working properly
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    because at some point the
    cold chain has fallen over.
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    So it's a big problem, and it's tied
    in with the needle and syringe
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    because it's a liquid form vaccine, and
    when it's liquid it needs the refrigeration.
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    A key attribute of our Nanopatch
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    is that the vaccine is dry,
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    and when it's dry it doesn't need refrigeration.
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    Within my lab we've shown that we can keep
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    the vaccine stored at 23 degrees Celsius
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    for more than a year without
    any loss in activity at all.
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    That's an important improvement.
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    (Applause)
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    We're delighted about it as well.
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    And the thing about it is that
    we have well and truly proven
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    the Nanopatch within the laboratory setting.
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    And as a scientist, I love that and I love science.
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    However, as an engineer,
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    as a biomedical engineer
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    and also as a human being,
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    I'm not going to be satisfied
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    until we've rolled this thing
    out, taken it out of the lab
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    and got it to people in large numbers
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    and particularly the people that need it the most.
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    So we've commenced this particular journey,
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    and we've commenced this
    journey in an unusual way.
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    We've started with Papua New Guinea.
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    Now, Papua New Guinea is an example
    of a developing world country.
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    It's about the same size as France,
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    but it suffers from many of the key barriers
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    existing within the world of today's vaccines.
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    There's the logistics:
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    Within this country there are only 800
    refrigerators to keep vaccines chilled.
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    Many of them are old, like this one in Port Moresby,
    many of them are breaking down
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    and many are not in the Highlands
    where they are required.
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    That's a challenge.
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    But also, Papua New Guinea has the
    world's highest incidence of HPV,
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    human papillomavirus, the
    cervical cancer [risk factor].
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    Yet, that vaccine is not available in large numbers
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    because it's too expensive.
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    So for those two reasons, with
    the attributes of the Nanopatch,
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    we've got into the field and
    worked with the Nanopatch,
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    and taken it to Papua New Guinea
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    and we'll be following that up shortly.
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    Now, doing this kind of work is not easy.
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    It's challenging,
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    but there's nothing else in
    the world I'd rather be doing.
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    And as we look ahead
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    I'd like to share with you a thought:
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    It's the thought of a future where
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    the 17 million deaths per year
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    that we currently have due to infectious disease
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    is a historical footnote.
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    And it's a historical footnote that has been achieved
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    by improved, radically improved vaccines.
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    Now standing here today in front of you
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    at the birthplace of the needle and syringe,
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    a device that's 160 years old,
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    I'm presenting to you an alternative approach
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    that could really help make that happen --
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    and it's the Nanopatch with its attributes
    of being needle-free, pain-free,
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    the ability for removing the cold chain
    and improving the immunogenicity.
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    Thank you.
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    (Applause)
Title:
Demo: A needle-free vaccine patch that's safer and way cheaper
Speaker:
Mark Kendall
Description:

One hundred sixty years after the invention of the needle and syringe, we’re still using them to deliver vaccines; it’s time to evolve. Biomedical engineer Mark Kendall demos the Nanopatch, a one-centimeter-by-one-centimeter square vaccine that can be applied painlessly to the skin. He shows how this tiny piece of silicon can overcome four major shortcomings of the modern needle and syringe, at a fraction of the cost.
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Video Language:
English
Team:
closed TED
Project:
TEDTalks
Duration:
13:50

English subtitles

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