Anthony Atala: Growing new organs

339,706 views ・ 2010-01-21

TED


Please double-click on the English subtitles below to play the video.

00:15
This is actually a painting
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that hangs at the Countway Library at Harvard Medical School.
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And it shows the first time an organ was ever transplanted.
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In the front, you see, actually, Joe Murray
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getting the patient ready for the transplant,
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while in the back room you see Hartwell Harrison,
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the Chief of Urology at Harvard,
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actually harvesting the kidney.
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The kidney was indeed the first organ
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ever to be transplanted to the human.
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That was back in 1954,
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55 years ago.
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Yet we're still dealing with a lot of the same challenges
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as many decades ago.
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Certainly many advances, many lives saved.
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But we have a major shortage of organs.
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In the last decade the number of patients
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waiting for a transplant has doubled.
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While, at the same time, the actual number of transplants
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has remained almost entirely flat.
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That really has to do with our aging population.
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We're just getting older.
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Medicine is doing a better job
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of keeping us alive.
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But as we age, our organs tend to fail more.
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So, that's a challenge,
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not just for organs but also for tissues.
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Trying to replace pancreas,
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trying to replace nerves that can help us with Parkinson's.
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These are major issues.
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This is actually a very stunning statistic.
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Every 30 seconds
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a patient dies from diseases
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that could be treated with tissue regeneration or replacement.
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So, what can we do about it?
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We've talked about stem cells tonight.
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That's a way to do it.
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But still ways to go to get stem cells into patients,
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in terms of actual therapies for organs.
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Wouldn't it be great if our bodies could regenerate?
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Wouldn't it be great if we could actually harness the power
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of our bodies, to actually heal ourselves?
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It's not really that foreign of a concept, actually;
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it happens on the Earth every day.
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This is actually a picture of a salamander.
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Salamanders have this amazing capacity to regenerate.
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You see here a little video.
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This is actually a limb injury in this salamander.
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And this is actually real photography,
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timed photography, showing how that limb regenerates
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in a period of days.
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You see the scar form.
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And that scar actually grows out
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a new limb.
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So, salamanders can do it.
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Why can't we? Why can't humans regenerate?
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Actually, we can regenerate.
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Your body has many organs
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and every single organ in your body
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has a cell population
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that's ready to take over at the time of injury. It happens every day.
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As you age, as you get older.
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Your bones regenerate every 10 years.
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Your skin regenerates every two weeks.
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So, your body is constantly regenerating.
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The challenge occurs when there is an injury.
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At the time of injury or disease,
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the body's first reaction
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is to seal itself off from the rest of the body.
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It basically wants to fight off infection,
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and seal itself, whether it's organs inside your body,
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or your skin, the first reaction
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is for scar tissue to move in,
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to seal itself off from the outside.
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So, how can we harness that power?
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One of the ways that we do that
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is actually by using smart biomaterials.
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How does this work? Well, on the left side here
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you see a urethra which was injured.
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This is the channel that connects the bladder to the outside of the body.
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And you see that it is injured.
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We basically found out that you can use these smart biomaterials
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that you can actually use as a bridge.
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If you build that bridge, and you close off
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from the outside environment,
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then you can create that bridge, and cells
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that regenerate in your body,
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can then cross that bridge, and take that path.
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That's exactly what you see here.
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It's actually a smart biomaterial
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that we used, to actually treat this patient.
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This was an injured urethra on the left side.
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We used that biomaterial in the middle.
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And then, six months later on the right-hand side
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you see this reengineered urethra.
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Turns out your body can regenerate,
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but only for small distances.
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The maximum efficient distance for regeneration
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is only about one centimeter.
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So, we can use these smart biomaterials
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but only for about one centimeter
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to bridge those gaps.
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So, we do regenerate, but for limited distances.
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What do we do now,
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if you have injury for larger organs?
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What do we do when we have injuries
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for structures which are much larger
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than one centimeter?
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Then we can start to use cells.
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The strategy here, is if a patient comes in to us
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with a diseased or injured organ,
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you can take a very small piece of tissue from that organ,
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less than half the size of a postage stamp,
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you can then tease that tissue apart,
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and look at its basic components,
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the patient's own cells,
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you take those cells out,
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grow and expand those cells outside the body in large quantities,
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and then we then use scaffold materials.
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To the naked eye they look like a piece of your blouse,
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or your shirt, but actually
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these materials are fairly complex
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and they are designed to degrade once inside the body.
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It disintegrates a few months later.
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It's acting only as a cell delivery vehicle.
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It's bringing the cells into the body. It's allowing
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the cells to regenerate new tissue,
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and once the tissue is regenerated the scaffold goes away.
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And that's what we did for this piece of muscle.
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This is actually showing a piece of muscle and how we go through
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the structures to actually engineer the muscle.
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We take the cells, we expand them,
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we place the cells on the scaffold,
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and we then place the scaffold back into the patient.
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But actually, before placing the scaffold into the patient,
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we actually exercise it.
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We want to make sure that we condition
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this muscle, so that it knows what to do
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once we put it into the patient.
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That's what you're seeing here. You're seeing
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this muscle bio-reactor
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actually exercising the muscle back and forth.
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Okay. These are flat structures that we see here,
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the muscle.
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What about other structures?
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This is actually an engineered blood vessel.
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Very similar to what we just did, but a little bit more complex.
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Here we take a scaffold,
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and we basically -- scaffold can be like a piece of paper here.
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And we can then tubularize this scaffold.
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And what we do is we, to make a blood vessel, same strategy.
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A blood vessel is made up of two different cell types.
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We take muscle cells, we paste,
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or coat the outside with these muscle cells,
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very much like baking a layer cake, if you will.
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You place the muscle cells on the outside.
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You place the vascular blood vessel lining cells on the inside.
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You now have your fully seeded scaffold.
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You're going to place this in an oven-like device.
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It has the same conditions as a human body,
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37 degrees centigrade,
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95 percent oxygen.
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You then exercise it, as what you saw on that tape.
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And on the right you actually see a carotid artery that was engineered.
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This is actually the artery that goes from your neck to your brain.
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And this is an X-ray showing you
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the patent, functional blood vessel.
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More complex structures
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such as blood vessels, urethras, which I showed you,
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they're definitely more complex
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because you're introducing two different cell types.
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But they are really acting mostly as conduits.
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You're allowing fluid or air to go through
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at steady states.
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They are not nearly as complex as hollow organs.
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Hollow organs have a much higher degree of complexity,
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because you're asking these organs to act on demand.
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So, the bladder is one such organ.
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Same strategy, we take a very small piece of the bladder,
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less than half the size of a postage stamp.
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We then tease the tissue apart
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into its two individual cell components,
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muscle, and these bladder specialized cells.
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We grow the cells outside the body in large quantities.
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It takes about four weeks to grow these cells from the organ.
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We then take a scaffold that we shape like a bladder.
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We coat the inside with these bladder lining cells.
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We coat the outside with these muscle cells.
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We place it back into this oven-like device.
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From the time you take that piece of tissue, six to eight weeks later
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you can put the organ right back into the patient.
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This actually shows the scaffold.
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The material is actually being coated with the cells.
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When we did the first clinical trial for these patients
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we actually created the scaffold specifically for each patient.
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We brought patients in,
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six to eight weeks prior to their scheduled surgery, did X-rays,
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and we then composed a scaffold specifically for that patient's size
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pelvic cavity.
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For the second phase of the trials
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we just had different sizes, small, medium, large and extra-large.
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(Laughter)
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It's true.
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And I'm sure everyone here wanted an extra-large. Right?
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(Laughter)
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So, bladders are definitely a little bit more complex
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than the other structures.
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But there are other hollow organs that have added complexity to it.
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This is actually a heart valve, which we engineered.
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And the way you engineer this heart valve is the same strategy.
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We take the scaffold, we seed it with cells,
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and you can now see here, the valve leaflets opening and closing.
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We exercise these prior to implantation.
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Same strategy.
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And then the most complex are the solid organs.
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For solid organs, they're more complex
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because you're using a lot more cells per centimeter.
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This is actually a simple solid organ like the ear.
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It's now being seeded with cartilage.
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That's the oven-like device;
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once it's coated it gets placed there.
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And then a few weeks later we can take out the cartilage scaffold.
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This is actually digits that we're engineering.
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These are being layered, one layer at a time,
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first the bone, we fill in the gaps with cartilage.
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We then start adding the muscle on top.
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And you start layering these solid structures.
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Again, fairly more complex organs,
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but by far, the most complex solid organs
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are actually the vascularized, highly vascularized,
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a lot of blood vessel supply,
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organs such as the heart,
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the liver, the kidneys.
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This is actually an example -- several strategies
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to engineer solid organs.
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This is actually one of the strategies. We use a printer.
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And instead of using ink, we use -- you just saw an inkjet cartridge --
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we just use cells.
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This is actually your typical desktop printer.
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It's actually printing this two chamber heart,
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one layer at a time.
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You see the heart coming out there. It takes about 40 minutes to print,
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and about four to six hours later
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you see the muscle cells contract.
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(Applause)
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This technology was developed by Tao Ju, who worked at our institute.
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And this is actually still, of course, experimental,
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not for use in patients.
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Another strategy that we have followed
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is actually to use decellularized organs.
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We actually take donor organs,
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organs that are discarded,
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and we then can use very mild detergents
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to take all the cell elements out of these organs.
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So, for example on the left panel,
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top panel, you see a liver.
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We actually take the donor liver,
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we use very mild detergents,
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and we, by using these mild detergents, we take all the cells
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out of the liver.
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Two weeks later, we basically can lift this organ up,
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it feels like a liver,
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we can hold it like a liver,
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it looks like a liver, but it has no cells.
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All we are left with
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is the skeleton, if you will, of the liver,
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all made up of collagen,
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a material that's in our bodies, that will not reject.
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We can use it from one patient to the next.
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We then take this vascular structure
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and we can prove that we retain the blood vessel supply.
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You can see, actually that's a fluoroscopy.
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We're actually injecting contrast into the organ.
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Now you can see it start. We're injecting the contrast into the organ
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into this decellularized liver.
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And you can see the vascular tree that remains intact.
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We then take the cells, the vascular cells,
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blood vessel cells, we perfuse the vascular tree
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with the patient's own cells.
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We perfuse the outside of the liver
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with the patient's own liver cells.
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And we can then create functional livers.
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And that's actually what you're seeing.
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This is still experimental. But we are able to actually reproduce the functionality
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of the liver structure, experimentally.
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For the kidney,
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as I talked to you about the first painting that you saw,
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the first slide I showed you,
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90 percent of the patients on the transplant wait list
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are waiting for a kidney, 90 percent.
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So, another strategy we're following
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is actually to create wafers
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that we stack together, like an accordion, if you will.
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So, we stack these wafers together, using the kidney cells.
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And then you can see these miniature kidneys that we've engineered.
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They are actually making urine.
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Again, small structures, our challenge is how to make them larger,
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and that is something we're working on
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right now at the institute.
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One of the things that I wanted to summarize for you then
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is what is a strategy that we're going for in regenerative medicine.
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If at all possible,
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we really would like to use smart biomaterials
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that we can just take off the shelf
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and regenerate your organs.
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We are limited with distances right now,
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but our goal is actually to increase those distances over time.
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If we cannot use smart biomaterials,
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then we'd rather use your very own cells.
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Why? Because they will not reject.
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We can take cells from you,
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create the structure, put it right back into you, they will not reject.
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And if possible, we'd rather use the cells from your very specific organ.
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If you present with a diseased wind pipe
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we'd like to take cells from your windpipe.
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If you present with a diseased pancreas
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we'd like to take cells from that organ.
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Why? Because we'd rather take those cells
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which already know that those are the cell types you want.
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A windpipe cell already knows it's a windpipe cell.
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We don't need to teach it to become another cell type.
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So, we prefer organ-specific cells.
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And today we can obtain cells from most every organ in your body,
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except for several which we still need stem cells for,
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like heart, liver, nerve and pancreas.
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And for those we still need stem cells.
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If we cannot use stem cells from your body
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then we'd like to use donor stem cells.
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And we prefer cells that will not reject
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and will not form tumors.
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And we're working a lot with the stem cells that we
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published on two years ago,
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stem cells from the amniotic fluid,
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and the placenta, which have those properties.
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So, at this point, I do want to tell you that
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some of the major challenges we have.
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You know, I just showed you this presentation, everything looks so good,
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everything works. Actually no,
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these technologies really are not that easy.
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Some of the work you saw today
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was performed by over 700 researchers
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at our institute across a 20-year time span.
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So, these are very tough technologies.
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Once you get the formula right you can replicate it.
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But it takes a lot to get there.
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So, I always like to show this cartoon.
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This is how to stop a runaway stage.
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And there you see the stagecoach driver,
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and he goes, on the top panel,
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He goes A, B, C, D, E, F.
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He finally stops the runaway stage.
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And those are usually the basic scientists,
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The bottom is usually the surgeons.
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(Laughter)
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I'm a surgeon so that's not that funny.
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(Laughter)
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But actually method A is the correct approach.
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And what I mean by that is that anytime we've launched one of these technologies
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to the clinic,
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we've made absolutely sure that we do everything we can
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in the laboratory before we ever
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launch these technologies to patients.
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And when we launch these technologies to patients
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we want to make sure that we ask ourselves a very tough question.
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Are you ready to place this in your own loved one, your own child,
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your own family member, and then we proceed.
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Because our main goal, of course,
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is first, to do no harm.
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I'm going to show you now, a very short clip,
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It's a five second clip of a patient
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who received one of the engineered organs.
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We started implanting some of these structures
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over 14 years ago.
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So, we have patients now walking around with organs,
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engineered organs, for over 10 years, as well.
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I'm going to show a clip of one young lady.
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She had a spina bifida defect, a spinal cord abnormality.
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She did not have a normal bladder. This is a segment from CNN.
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We are just taking five seconds.
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This is a segment that Sanjay Gupta actually took care of.
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Video: Kaitlyn M: I'm happy. I was always afraid
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that I was going to have like, an accident or something.
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And now I can just go and
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go out with my friends,
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go do whatever I want.
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Anthony Atala: See, at the end of the day, the promise of regenerative medicine
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is a single promise.
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And that is really very simple,
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to make our patients better.
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Thank you for your attention.
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(Applause)
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Original video on YouTube.com
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