In this episode, Angelica and Bey talk about artificial organs and 3D printing with Brian Shepard, the CEO of the United Network for Organ Sharing, and Director of Innovation at the Jefferson Health Design Lab, Dr. Robert Pugliese.
Show Links
- United Network for Organ Sharing (UNOS)
- Brian Shepard
- Jefferson Health Design Lab
- Robert Pugliese, Pharm.D.
- View episode transcript
Transcript
Hello, world, and welcome to So Curious, presented by the Franklin Institute.
Speaker:In this season, Human 2.0, we will be talking to scientists and non-scientists
Speaker:alike about technology and innovation surrounding the human experience.
Speaker:We're your hosts.
Speaker:I'm Angelica Pasquini.
Speaker:And I'm the Bul Bey.
Speaker:But you can just call me Bey.
Speaker:On today's episode, we're going to be talking about organs with Brian Shepherd,
Speaker:and co-founder of the health design lab, Robert Pukeley.
Speaker:Organs. Yeah.
Speaker:And the design of them and the printing of
Speaker:them and all these weird things of transplanting.
Speaker:Yeah.
Speaker:So typically organs are something that you don't think about until you have to.
Speaker:Right.
Speaker:I remember when I signed up to be an organ donor.
Speaker:Right.
Speaker:And I have to be honest with you, I did it.
Speaker:But there's something about it that doesn't always sit right with me.
Speaker:I'm going to be honest. I'm just like...
Speaker:Well, I saw this one dumb video once.
Speaker:The lady was awake because she wasn't totally dead yet.
Speaker:But that's not something that....
Speaker:I don't know what ....Dark web?
Speaker:No, it wasn't.
Speaker:It was like 2020 Dateline. Yeah.
Speaker:But you know what? That's a rare example.
Speaker:Are you an organ donor?
Speaker:I have it listed on my driver's license. Yes.
Speaker:I ignorantly don't necessarily know what all the responsibilities mean from that.
Speaker:You will be dead, right?
Speaker:And I'm kind of hoping that that's the case.
Speaker:I know it's one of those things where people are in need.
Speaker:Yeah. And I'm always of the person, I'm always
Speaker:of the mind, rather, that people's needs need to be met.
Speaker:Yeah.
Speaker:And I know organ donation is something that is not popular.
Speaker:People kind of shy away from it. Yeah.
Speaker:It's not a classic combo, but I do think
Speaker:that it's like you obviously don't think about it until you need it.
Speaker:Right.
Speaker:But recently I heard about people who have healthy organs who know about the shortage
Speaker:of organs in our country, and they literally will go to a hospital and be
Speaker:like, I know I don't need this organ and I'm willing to donate it.
Speaker:Yes. Wow.
Speaker:I noticed the whole system and even that ....That's not even something I'm aware of
Speaker:the mechanisms of, "I'd like to take this out of me and give it to somebody."
Speaker:Yes.
Speaker:Where do you even start? Where does that even begin? And who's behind it?
Speaker:Okay, let's get an expert in here, shall we?
Speaker:Yeah, I'll introduce him.
Speaker:Our first guest is Brian Shepherd from United Network for Organ Sharing (UNOS).
Speaker:UNOS is the engine that powers the US
Speaker:organ donation and transplantation system and matches organs with recipients.
Speaker:Hi, Brian. Could you introduce yourself in your own words?
Speaker:My name is Brian Shepherd.
Speaker:I'm the CEO of the United Network for Organ Sharing, UNOS.
Speaker:And what UNOS does is match donated organs with patients who need transplants.
Speaker:We really are the engine that powers the organ donation and transplant system, and
Speaker:we bring together the entire donation and transplant community: doctors, patients,
Speaker:and other professionals, together, to make the rules to drive that system.
Speaker:Awesome. And one of the most interesting things to
Speaker:me about UNOS is that it's not a part of the government, and it's a nonprofit.
Speaker:Can you illuminate to the listeners how that works.
Speaker:When organ transplant was created, it
Speaker:really grew up regionally, because there are limits on how far you can transport an
Speaker:organ once it's been recovered before you have to use it.
Speaker:And so in the 80s, Congress looked at this regional system that had developed and
Speaker:said, we really need a single unified national system.
Speaker:And they passed an act called the National Organ Transplant Act, or NOTA.
Speaker:But at the time, they said, we want government oversight, we want a single
Speaker:system, and we want government to have a role in making sure that they follow the
Speaker:rules, that it's fair and that it's appropriate.
Speaker:But we really want the experts in the
Speaker:community to be making these kinds of decisions.
Speaker:And so we want a private nonprofit organization that can bring together
Speaker:doctors and patients and let them make the decisions that drive this process.
Speaker:And that's how you guys came to be.
Speaker:We came from one of the previous regional organizations that had sort of grown up
Speaker:organically, and that organization happened to be in Virginia, and they
Speaker:reached out to some of the other organizations and kind of assembled this
Speaker:team to bid for the very first contract under this new law in the 80s.
Speaker:And the government bids that contract out every five years or so, but we've been
Speaker:able to consistently win it and keep doing the work.
Speaker:Wow. What was one of the first things you
Speaker:guys changed when you were given this opportunity?
Speaker:Organ transplant is always a race against time.
Speaker:Once an organ is recovered, you've got to
Speaker:get to the recipient, get that organ implanted, because the longer it sits on
Speaker:ice, the more it's going to deteriorate and the less useful it's going to be.
Speaker:So a constant theme of the history of organ transplant is being able to reach
Speaker:further and further, as technology improves or clinical treatments improve.
Speaker:We can look for the sickest patient over a further and further distance all the time.
Speaker:It used to be they would have to be in the
Speaker:same hospital, or the donor would have to be just down the street.
Speaker:But now we can move an organ for hundreds
Speaker:of miles if that's where the sickest patient is that needs that organ.
Speaker:You know, a lot of people think organ
Speaker:transplant is about replacing people's organs, but to my knowledge, it's about
Speaker:extending that lifespan of the organ. Can you explain that a little bit more?
Speaker:So there's really three phases of organ failure, care and pre-transplant.
Speaker:Because there are not enough organs to go around.
Speaker:If you can treat organ damage without a transplant, that's better.
Speaker:And save that transplant for people who, really, that's their only vehicle.
Speaker:So things like dialysis for kidney
Speaker:failure, things like heart assist devices for hearts, those are important
Speaker:pre-transplant remedies that make it possible, maybe, for people to postpone
Speaker:transplant or even avoid transplant altogether.
Speaker:But then there are devices that can improve the span of time that an organ
Speaker:spends in between the donor and the recipient.
Speaker:So devices that pump fluid and oxygen
Speaker:through organs to make sure that they last longer and are in better condition when
Speaker:they arrive at the recipient for transplant.
Speaker:And then there are constant improvements
Speaker:in the third phase, [which] would be after transplant.
Speaker:Immunosuppression medicines, better matching.
Speaker:Your body wants to reject a foreign object.
Speaker:Your immune system is supposed to repel things that don't come from your own body.
Speaker:For an organ transplant recipient, it's a constant balance of medicines that keep
Speaker:your immune reaction in check, to keep your own body from trying to get rid of
Speaker:the organ that you now have to save your life.
Speaker:Totally. Are you familiar with the show Gray's Anatomy?
Speaker:I'm not the most familiar person on my
Speaker:team with Gray's Anatomy, but it certainly gets talked about a fair amount around.
Speaker:Yeah, so basically in our culture (because this is something that you don't learn
Speaker:about until it happens to you), it seems like our culture has dramatized this, and
Speaker:it is dramatic, of course, but we try to make a grasp using narrative storytelling.
Speaker:So on Gray's Anatomy, Meredith Gray would
Speaker:always have to contact UNOS in deciding who gets an organ.
Speaker:But it's very dramatized and extremely drawn out.
Speaker:We're just curious a little bit about what UNOS is and also what it isn't.
Speaker:Like, what are the misconceptions?
Speaker:So, it is dramatic.
Speaker:Whether it's as dramatic in the moment as
Speaker:it is on Gray's Anatomy, it's probably harder to say.
Speaker:So what happens when a potential donor dies in a hospital?
Speaker:The hospital will contact an organ procurement organization, an OPO.
Speaker:And the OPO has staff that comes out and
Speaker:evaluates the donor, decides whether or not they're able to be a good organ donor.
Speaker:For example, someone who dies of cancer is
Speaker:not likely to donate an organ because we don't want to transmit that cancer.
Speaker:But the OPO staffer then puts all that
Speaker:clinical information into a computer that we operate.
Speaker:That's what UNOS does.
Speaker:So we take that information, and we've got a database full of all the candidates for
Speaker:transplant, all the patients in the United States who need an organ transplant.
Speaker:And when the OPO says, "here's a donor,"
Speaker:our computer system is the same one that all the hospitals and OPOs are using.
Speaker:And it says, "okay, here's where the heart goes, here's where the right kidney goes,
Speaker:here's where the left kidney goes, here's where the liver goes." And they use that
Speaker:system to match that donor with the patients who are waiting.
Speaker:So in the moment, it's impossible to sort of choose between people, right?
Speaker:So we have committees that are made up of doctors and patients and other
Speaker:professionals that write rules that help sort the patients into priority.
Speaker:And primarily for hearts, livers and
Speaker:lungs, the rules are the closer you are to death, the higher priority you are.
Speaker:For kidneys, it's more the longer you've been waiting, the higher priority you are.
Speaker:So because of dialysis, you can wait longer.
Speaker:And so that tends to be more like just getting in line and waiting your turn.
Speaker:Whereas hearts, livers and lungs, you could go quickly up the list by being so
Speaker:sick that you're about to die in the immediate future.
Speaker:So we have sort of set that IT system up
Speaker:to implement all those rules in the moment.
Speaker:So in the moment, there's no committee that says, let me think about this person,
Speaker:but let me think about that person over there and try to compare them.
Speaker:It's based on their clinical condition.
Speaker:It's based on all the information their doctor has put in there.
Speaker:And that computer generates a list of candidates in order
Speaker:based on either how long they've been waiting or how sick they are.
Speaker:That's fascinating. You mentioned IT.
Speaker:Are there moments where just human judgment and the IT clashes?
Speaker:When the OPO puts the donor's information into the computer, it's not necessarily
Speaker:everything there is to know about that donor.
Speaker:And so what our system provides is an
Speaker:offer to a transplant doctor on behalf of his candidate.
Speaker:And sometimes that doctor can say, "you
Speaker:know what, this organ is not for us, not today." And then we'll go to the next
Speaker:person on the list, and the next person on the list, the next person on the list.
Speaker:So the computer isn't completely insisting
Speaker:that this organ goes to this patient, but the computer does put them in order of
Speaker:priority to receive and consider those offers.
Speaker:So there is a doctor making that human
Speaker:judgment, but only if their patient is up next on the list.
Speaker:Around how many times a day is this happening?
Speaker:We're going to get probably for the first
Speaker:time this year, 40,000 organ transplants in the United States.
Speaker:That'll be the first time ever we've hit
Speaker:that number and the highest number in any country, in any year, in the world, which
Speaker:means that we're doing a few more than 100 every single day.
Speaker:The advent of new technology, like growing skin from stem cells and cloning organ
Speaker:cells and all that stuff, how far are we from the reality of just growing organs in
Speaker:a lab and what does science still need to do, or not do, to make this a possibility?
Speaker:So we are close enough to that to sort of see it over the horizon.
Speaker:Not close enough that if you need an organ now that you can count on that to be your
Speaker:solution, but close enough that we can kind of see it coming.
Speaker:There's a group in Wake Forest. But for
Speaker:right now, it really is about the generosity of organ donors.
Speaker:It's about people being willing to sign up to give their organs when they die and to
Speaker:make that available to other people because that is the current source.
Speaker:And that's the way that organ transplant happens right now.
Speaker:What does the history of transplantation as a medical practice look like and what
Speaker:were some of the first organ transplants? Do you know that history of it?
Speaker:Kidney transplantation has taken place at very low levels since really the 50s.
Speaker:Some of the first ones were done in Boston and in Virginia.
Speaker:The very earliest ones were living donor
Speaker:transplants, and the first one was done from a twin to his brother.
Speaker:And that's how they were confident that it would match.
Speaker:As time went on, we learned more about deceased donation.
Speaker:We learned more about...
Speaker:Liver donation was mostly developed in Pittsburgh.
Speaker:Heart donation was really, started to become more established, in the 80s.
Speaker:It's astonishing to look at the age of
Speaker:this field and think this is really brand-new.
Speaker:This is not something that my grandparents would have had access to at all.
Speaker:This field is really still in the very
Speaker:early stages of learning how this is done and making this happen.
Speaker:So organ tracking service operates with the same fluency as an Uber service.
Speaker:[Laughs] Right? So can you speak a little bit more to this, and why the journey of
Speaker:organs from donor to recipient is handled with so much care?
Speaker:Again, it really is because it's always a race against time, to make sure that organ
Speaker:is still as high quality as it can be, and to get it to the right place.
Speaker:So we operate a GPS tracking system for organs, and we only recently developed it.
Speaker:And in the pilot phase, one of the very
Speaker:first instances we had was a courier who picked up a package and didn't really
Speaker:understand, kind of, what they were carrying.
Speaker:And our team was watching them on a screen
Speaker:and saw that they were going away from the airport and actually were able to call and
Speaker:say, "that's a kidney, and it has to make this flight.
Speaker:" And the Courier turned around and drove to the airport and got there on time.
Speaker:That doesn't happen a lot.
Speaker:It was a break to get something that dramatic right at the beginning.
Speaker:But even allowing hospitals to know exactly when the organ is going to get
Speaker:there helps them get the transplant process started for their patients.
Speaker:A lot of times, at least, the surgical
Speaker:prep, and sometimes even some of the steps of the surgery, have begun as the organ is
Speaker:arriving because they know exactly when it's coming.
Speaker:And they can make that process work a lot
Speaker:smoother for the patient and get that transplant done quicker.
Speaker:Wow. Cool! Well, we learned so much.
Speaker:Thank you so much for your time.
Speaker:Yeah! Thank you.
Speaker:Let's get a reflection.
Speaker:Well, that was really interesting because
Speaker:it seems like this organization, the priority, is decided by a committee.
Speaker:And I thought that was really interesting because you're essentially
Speaker:removing.... I like the way he said, " because it's anonymous, we're not giving
Speaker:these to celebrities first." That was good to hear.
Speaker:Yeah. I had no clue about that system.
Speaker:The IT behind it.
Speaker:And I appreciated the clarification of when IT might clash with the human
Speaker:judgment side of deciding what goes where and how it gets there.
Speaker:But I really appreciated the level of care in transporting organs.
Speaker:Yeah.
Speaker:It's something that you don't think about when your body is working well, but when
Speaker:something goes wrong, you want to have an efficient system, and this seems
Speaker:efficient. Do you think this could be more efficient in the future?
Speaker:Oh, my God.
Speaker:Imagine being a person driving the "Organ Ãœber."
Speaker:The "Organ Uber" is five minutes away.
Speaker:Yeah.
Speaker:I think I could actually really lock into that and drive like, NASCAR.
Speaker:Right. And then hopefully not get pulled over,
Speaker:but I would be really, really...I'd t ake that seriously.
Speaker:Well, I would hope that there's, like,
Speaker:some lane, some passing lane that you could just go into.
Speaker:"I am transporting an organ.
Speaker:I need to get to this place!" Because the
Speaker:lifespan of an organ is something that we opened up, too.
Speaker:I had no clue it was so, like, time-sensitive.
Speaker:Yeah, of course. And then also there's, what he was
Speaker:introducing to us a bit, was the synthetic organ concept.
Speaker:Yeah. Do you want a plastic or some kind of rubbery?
Speaker:I'm down. Whatever.
Speaker:If I need it, I'm open.
Speaker:Right! I think the idea of it is like, no,
Speaker:I don't want anything that's made out of rubber or plastic.
Speaker:But if you're in need, and something shuts down, I want that.
Speaker:Just give it to me. Exactly.
Speaker:Okay. Let's get an expert in here, shall we?
Speaker:Our next guest is Robert S.
Speaker:Pugliese.
Speaker:Prior to taking on a fulltime role in healthcare innovation, Robert spent ten
Speaker:years practicing and teaching in the specialty of emergency medicine.
Speaker:As a person with insulin-dependent diabetes, Robert takes a personal interest
Speaker:in ensuring that everyone has a voice in improving our health care system.
Speaker:Okay.
Speaker:Robert, thank you so much for coming on to the show.
Speaker:Can you tell us a little bit first about who you are and what you do?
Speaker:On paper, I am the director of Innovation Design at Thomas Jefferson University in
Speaker:Jefferson Health, and I'm the cofounder and managing director of a place called
Speaker:the Health Design Lab. It's a think tank, it's a creative lab.
Speaker:It's a place where people can come together to think differently and try to
Speaker:solve problems in healthcare using concepts of design and creative arts, and
Speaker:kind of bridging those two worlds together.
Speaker:So it's design-specific. Our mission is twofold.
Speaker:We want more people in healthcare to start
Speaker:thinking about design as an important aspect to what we do.
Speaker:Right. An important aspect from providing care,
Speaker:to building environments for care, to doing surgery.
Speaker:Everything that we experience in health care is designed.
Speaker:How has design existed in the past?
Speaker:It's basically like, I need a hammer.
Speaker:So here's a hammer, right?
Speaker:It's not a question of, wait, why are you
Speaker:trying to smash things with something and what do you really need?
Speaker:Right. Yeah.
Speaker:And we frequently don't ask those
Speaker:questions, which is why so much of the healthcare system is designed so poorly.
Speaker:I know that you guys are taking steps to encourage innovation and inclusivity in
Speaker:your space and you want to change the way we look at the future of healthcare.
Speaker:But I think first it would be cool to just
Speaker:better understand for people who might not know how it happened.
Speaker:Yeah, I wish I could really explain that in a very clear and well thought out way.
Speaker:Yeah. But honestly, healthcare is a combination
Speaker:of systems layered upon systems, processes layered upon processes.
Speaker:Right? At some point, a long time ago, somebody
Speaker:did come up with a really great way of teaching medicine, practicing medicine.
Speaker:And then as things have changed, as the
Speaker:technologies have improved, as the way we do things have improved, people just start
Speaker:layering on systems, layering on systems. Add payment into the mix.
Speaker:Payment becomes really complicated.
Speaker:Add technology.
Speaker:It would be a discredit to the people who have done it well to say that it was all
Speaker:just bandaids and hacks, but it's a lot of bandaids and hacks.
Speaker:Smashing two computer systems together and
Speaker:hoping that they'll communicate. Or really well-meaning providers and health care
Speaker:professionals just doing what they can to serve their patients the best way they can
Speaker:with the tools at their disposal, which may not be the best.
Speaker:As far as I understand, you're using 3D
Speaker:printing technology to produce tissue similar to our natural body parts. Can you
Speaker:elaborate on that more? Could you explain more detail how this technology works?
Speaker:We're trying to introduce people in health care to design.
Speaker:Well, on the other side of that, we're
Speaker:also trying to bring designers and creatives into the world of healthcare.
Speaker:When you're talking about technologies
Speaker:like 3D printing, this is not just something that a scientist can operate.
Speaker:You have experts.
Speaker:When we're talking about bioprinting, you have experts in cell biology.
Speaker:How do you grow cells?
Speaker:How do you train cells to do certain things?
Speaker:How do you put cells together in ways that they begin to mimic an organ?
Speaker:You can train a cell? You can.
Speaker:Yes, you can. That's the basis of how a lot of basic
Speaker:science, biological science, is done, by taking these cell lines that have been,
Speaker:quote, unquote, trained to do very specific things, and using them as our
Speaker:experimental framework for how we test drugs and different chemicals and how they
Speaker:would react in a human but in a petri dish.
Speaker:That's an entire field of expertise that
Speaker:doesn't even begin to touch the 3D printing part.
Speaker:It's a world of engineers and people who are technically experienced in things like
Speaker:software coding devices and non-biological materials.
Speaker:And bioprinting is the combination of those two things.
Speaker:People with these skill sets, they grow
Speaker:up, they learn in completely different environments.
Speaker:Usually they rarely talk to each other.
Speaker:And it's only through very intentional
Speaker:kind of environments, or places like what we're trying to create in the health
Speaker:design lab, where people can come together from disparate backgrounds and do
Speaker:something together to jump into the bioprinting space.
Speaker:It's a growing field.
Speaker:It's moving at an increasingly rapid pace.
Speaker:You're going to see a lot of innovation in
Speaker:that space over the next 10, 20, and forever years.
Speaker:Right. But we're at early days, and there's
Speaker:definitely experts around the world, not many who could really talk about the
Speaker:details of it. But I think what's really cool to talk about is how did we get here?
Speaker:How did we get here to a place where suddenly we're able to print life?
Speaker:Love that. How did we?
Speaker:It's mind blowing just to hear.
Speaker:Now imagine you're struggling with your
Speaker:traditional on-paper printer that we've been working on and perfecting for decades
Speaker:now, and now increase the complexity of that by 10 to 100 fold.
Speaker:And that's where we are with bioprinting.
Speaker:So bioprinting is part of the rapidly
Speaker:-growing field of regenerative medicine. Could you explain for our listeners what
Speaker:regenerative medicine is, and what the role bioprinting plays in the field?
Speaker:Regenerative medicine is what it sounds like, right?
Speaker:It's the practice of trying to regain
Speaker:function or regain something that was lost.
Speaker:So if you're talking about ...Regain a function of an organ.
Speaker:So as a great example, I have type one diabetes.
Speaker:My pancreas no longer makes insulin.
Speaker:In order for my body to get insulin, I have to inject it into myself.
Speaker:In regenerative medicine, one of the biggest goals in science right now, and
Speaker:actually some great news about it last week, is that we want to figure out how to
Speaker:fix our pancreas so that it starts making insulin again.
Speaker:That's regenerative medicine.
Speaker:And it can also span....
Speaker:It's not necessarily just like high -tech, reawakening broken organs.
Speaker:It's also like, "I hurt myself and I need therapy in order to regain that function
Speaker:again." Even that is a form of regenerative medicine, in a way.
Speaker:And on your website, you describe how these 3D printing and scanning
Speaker:capabilities have the potential to decrease costs, improve outcomes, and
Speaker:improve patient experience. How important is the case of bioprinting in the field of
Speaker:regenerative medicine and human life as a whole?
Speaker:3D printing is already having a tremendous impact on all of our lives.
Speaker:Yes.
Speaker:And I do want to kind of segue from this concept of traditional printing to 3D
Speaker:printing to get us to bioprinting, because it is all the same chain.
Speaker:It is a progression through the same technology.
Speaker:This is all the same technology we're talking about.
Speaker:The only thing that's really changed is the ink.
Speaker:I like the ink analogy. What is the ink?
Speaker:We're talking cells, we're talking cells. Got it.
Speaker:So if traditional printers use ink, then
Speaker:3D printers were invented and they use plastics.
Speaker:Through the magic of kind of trans
Speaker:-disciplinary collaboration, somebody was like, hey, we can take these 3D printers
Speaker:that squirt out hot plastic, and just put cells in there instead.
Speaker:And inject, in a very precise three
Speaker:-dimensional pattern, different combinations of living human cells.
Speaker:One of the most advanced utilizations of
Speaker:bioprinting right now is actually in two things: 3d printing functional human
Speaker:bladders, that is then implanted into a person.
Speaker:That's the capability that we have today as we speak.
Speaker:Yeah. So that is currently happening.
Speaker:That's one of the only examples of a human
Speaker:organ that is being bioprinted for human implantation.
Speaker:What does it mean for human beings, and what comes after that point?
Speaker:Other things that are being printed for implantation are like, stents.
Speaker:So kids who are born with an inability to keep their windpipe open, and they need a
Speaker:very specific-shaped thing to keep it open.
Speaker:Right now, certain centers are actually bioprinting.
Speaker:Sometimes it's a plastic.
Speaker:Other times I've heard it being made out of collagen or different biological
Speaker:substances so that the body can absorb it, to keep that open.
Speaker:So that's another really interesting kind
Speaker:of human use, and you start imagining the possibilities.
Speaker:Right. Researchers right now are printing these
Speaker:little miniature versions of organs to test substances that, before, we would
Speaker:have had to test on an animal or on a human.
Speaker:But they are able to replicate that kind of little system and put drugs in it and
Speaker:see how it responds, to accelerate the development of so many things.
Speaker:We're not really constrained by the shapes
Speaker:and the complexity of structures and how we put them together.
Speaker:The wall that we have to get over is in the biological side.
Speaker:To make it fully functioning?
Speaker:To make it functioning, to make cell lines
Speaker:that do what we want them to do, to make them communicate, to replicate the
Speaker:complexity of the human body, is something we're at very early days.
Speaker:Rob, I want to ask about you.
Speaker:You're a person who is open about being
Speaker:insulin-dependent and how this experience gives you a personal interest in making
Speaker:sure that everyone has a voice in improving our healthcare system.
Speaker:Could you speak more about your personal experience, how it informs your work, and
Speaker:how important it is to make sure that everyone has a voice in health care?
Speaker:How does the health design lab work to give everyone a voice?
Speaker:The crazy thing about working in health care, and kind of devoting your career to
Speaker:trying to make healthcare better, is that you realize that everybody has an
Speaker:experience with healthcare. Whether it's good experiences, bad experiences...
Speaker:It's hard to find somebody who hasn't had
Speaker:a bad experience of some kind with our American health care system.
Speaker:I take that as kind of inspiration, to use myself as an example to get others to
Speaker:share and be open about their own personal experiences.
Speaker:Because health is a very personal thing.
Speaker:It's not something that everybody wants
Speaker:to, nor should they have to, feel like they have to share.
Speaker:But hearing the experiences of others is the best way to try to improve.
Speaker:And one of the core tenets of what I do,
Speaker:and our work in the health design lab, is to encourage those voices to be heard.
Speaker:How essential is access to these types of technologies?
Speaker:So the technologies are becoming more and
Speaker:more accessible, and it's one of those areas that is, again, accelerating almost
Speaker:as rapidly as computers and cell phones and video games.
Speaker:Pretty much anybody can buy a traditional 3D printer, build it themselves.
Speaker:And, yeah, think the cheapest one I've ever saw was like $60, maybe less now.
Speaker:So then what is the barrier now?
Speaker:What's the barrier to you having a 3D
Speaker:printer, a bioprinter in your home, and making your own insulin?
Speaker:It's the science part, right?
Speaker:It's the getting to the point where you
Speaker:don't have to be an expert to use the technology.
Speaker:Bioprinting.
Speaker:We're still at the point where you have to
Speaker:be an expert to understand how to use the technology.
Speaker:In 10 or 20 years, that's not going to be the case.
Speaker:I can't even imagine what that would look like.
Speaker:But I could totally see that same
Speaker:trajectory where you can buy a printer, and you open up the instructions.
Speaker:It's like, "pour bottle of pancreas into printer.
Speaker:Press go.
Speaker:Make sure the temperature is right before [so] you don't burn it." And then it just
Speaker:starts pumping out chemicals that you need to live.
Speaker:Do you have any examples of people who you've assisted in their research?
Speaker:That's why we exist, right?
Speaker:That's why the lab exists, is because we want to introduce these technologies to
Speaker:people who may not have taken that extra step to bring it into their work or bring
Speaker:it into their research because they thought it was too hard.
Speaker:They thought they didn't have the skills.
Speaker:We started with one research project.
Speaker:We have four active research projects going on right now.
Speaker:And as the technology becomes more
Speaker:ubiquitous in the body of research and in different places, and people are seeing
Speaker:how impactful it can become, they're looking for it.
Speaker:And instead of having to start from zero,
Speaker:they can just come to us and we can accelerate their discovery process.
Speaker:Awesome. Amazing.
Speaker:Amazing. Amazing! Thank you for coming in
Speaker:and sharing all of your knowledge and experiences.
Speaker:This is like, really, really good stuff.
Speaker:Let's get a reflection.
Speaker:That was a really fun interview. Yeah.
Speaker:The overlapping of so many disciplines'
Speaker:focus, because it's not just printing and it's not just biology.
Speaker:There's so many different things, and no one knows it all at once.
Speaker:They have to communicate with each other.
Speaker:That was really cool.
Speaker:This whole introduction of the 3D printer is going to be...
Speaker:I think this is going to be like the next light bulb.
Speaker:Yeah, it's going to be in the kitchen.
Speaker:It's going to change everything. Yeah, it'll be in the kitchen.
Speaker:It'll be in every household.
Speaker:I think that what he's saying is we'll be
Speaker:able to 3D print everything and we'll have to see what that's going to end up looking
Speaker:like, and then the rules and regulations around it.
Speaker:"I'm baking some cookies.
Speaker:I'm also printing a foot, wait a second."
Speaker:[Laughter] Literally!
Speaker:Okay. This wraps up episode ten of So Curious!
Speaker:Thank you so much to Robert and Brian and
Speaker:thanks so much to you for tuning into this episode.
Speaker:This podcast is part of the Franklin Institute.
Speaker:The Franklin Institute is a science Museum located in Philadelphia.
Speaker:The Franklin Institute's mission is to
Speaker:inspire a passion for learning about science and technology.
Speaker:For more information on everything about
Speaker:the Franklin Institute, visit fi.edu. This podcast is produced by Radio Kismet.
Speaker:Radio Kismet is Philadelphia's premiere
Speaker:podcast network for businesses looking to develop their own branded podcast content.
Speaker:Check them out at radiokismet.com. There's
Speaker:a lot of people who make this podcast happen.
Speaker:Thanks to the producers Joy Montefusco and
Speaker:Jayatri Das, our managing producer Emily Charish, our operations head, Christopher
Speaker:Plant, our associate producer, Liliana Green, our audio team Christian Cedarlund,
Speaker:Goldie Dangley, Lauren DeLuca and Brad Florent, our development producer Opeola
Speaker:Bukola, our science writer Kira Villette and our graphic designer, Emma Sager.
