StarTalk Radio - Unlocking Gene Therapy with Gaurav Shah
Episode Date: January 23, 2024Are rare diseases themselves rare? Neil deGrasse Tyson and comedian Chuck Nice learn about the science of gene therapy and how it can treat and potentially cure rare diseases with Gaurav Shah, CEO, Ro...cket Pharma.NOTE: StarTalk+ Patrons can listen to this entire episode commercial-free here:Â https://startalkmedia.com/show/unlocking-gene-therapy-with-gaurav-shah/Thanks to our Patrons Ernesto Rodriguez, James Lewandowski, Juan Cornejo, Shane, Hayden Christensen, jacob vine, and Calina Lungu for supporting us this week. Subscribe to SiriusXM Podcasts+ on Apple Podcasts to listen to new episodes ad-free and a whole week early.
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Discussion (0)
Coming up on StarTalk, we feature my interview with the CEO and co-founder of Rocket Pharma.
This is a company in New Jersey that specializes in finding cures for genetic ailments using
gene therapy. More on that coming up. Welcome to StarTalk, Your place in the universe where science and pop culture collide.
StarTalk begins right now.
All right, let's get this party started.
I don't know if we would have done this if the name of your company didn't have the word rocket in it.
I know. I know.
So, if I... yeah, you know,
before this,
we got duped into doing
something for rocket mortgage.
It's RKT,
not RCKT.
Okay, got it.
Well, different,
different ticker.
Different ticker,
yeah, exactly.
So,
I have a hundred questions
for you,
and
I'm just wondering, the fact that you had a telescope as a kid,
and so you have a science geek underbelly within you,
astro science geek underbelly.
So would you have rather been an astrophysicist?
Like, did you just stumble into this field?
Yeah, what are you doing wasting your life on this crap?
Saving lives. into this field? Yeah, what are you doing wasting your life on this crap? That's right.
Saving lives.
Saving lives.
Curing disease.
Yeah, you could have been completely useless
like the rest of us.
What's the...
You know, I grew up
in Fort Worth, Texas.
Fort Worth?
Yeah, there's a lot of
spelling bee nerds
that come out of there
for some reason.
Is that right?
I think most winners
come from Fort Worth.
It's like this really weird thing.
But the son of Indian immigrants who came from India
and wanted the best for us.
You only have three career choices, really.
It's medicine, engineering,
and I'm not sure what the third one is.
Right?
So, but I also, you know, it was a science theme
that pervaded the first several years of my life,
whether it was astronomy or medicine, and I loved both.
Actually, in my first year of college, though, I was an astronomy major under John Huckstra.
Oh, yes.
Years ago, but I changed.
John Hooker.
Hooker, yes.
Yeah, yeah.
That's at Harvard.
Yeah.
That's a way to say he's saying he went to Harvard.
That's how that, you do that, you know?
Okay.
Not to be confused with the John Hookard of Rutgers.
No, I mean.
I was trying to be quiet about it.
Yeah, yeah, John Hookard was your friend and colleague.
Yes.
No, so I'm delighted to learn that the universe was part of what excited you to be a scientist, to go into science fields.
And then there's this thing about a Grammy. So you're also a musician. And what I'd like to know,
just to start off before we get into the nitty gritty here, would you say your career in music,
your side career in music, mattered or contributed to your
inspirations or curiosity in the sciences? I think they're all sort of the same,
is what I would say. I think whether... Talk to your mother when you come home saying you
want to be a musician. Actually, I did, and it didn't work out so well.
Yeah, it didn't work out so well. That conversation didn't go very well.
No, it did not. I ended up marrying a musician, and that's one step removed,
so it worked out.
But I think they're all the same.
I think that whether it's music or astronomy or medicine,
there's a sense of feeling connected to other people,
feeling connected to something greater,
for making sure that we don't feel alone in the universe.
I think that's the connection between these disciplines.
Interesting.
So, not to put words in your mouth,
but you're suggesting, I think, correctly and accurately,
that art is a force of nature unto itself
that serves to bring humans together.
Not only the artists themselves, but those who might not have such talent,
but they are nonetheless touched by the art.
Absolutely.
Actually, when we're in a band and we're performing,
it doesn't matter where you're from.
It doesn't matter what language you speak.
It doesn't matter how old you are.
Everyone becomes a fellow musician.
A participant in the experience.
And you're seeking something that's bigger than the band.
But it does matter which one of you has a fallback in science.
So that you will not be sleeping on your friend's couch at age 45.
Right, right.
Which is why there are street musicians,
but there aren't street scientists.
Right.
You just think that through.
Exactly.
I'll calculate for a dollar.
Yes, it does it.
So would you say, given this beautiful reference
to humanity and the connectivity within us,
would you say you approach your science with an artistic lens,
or do you approach your art with a science lens?
It's both.
Great.
I love the question.
It's a two-way lens.
I don't think these are that separable, in my view.
And I'll give you specific examples.
are that separable, in my view. And I'll give you specific examples. In gene therapy, the way that gene therapy works is that there's a viral vector and a transgene that carries the corrected DNA
to the patient's cells, right? And in figuring out how to create that vector, you can create a million
types of vector,
and only one will be the best one.
And how do you know?
We can predict, you can use AI,
you can use mathematics, various models to figure out that you need the right promoter,
the right length, cut out the stuff that doesn't matter.
At the end of the day, there's an art to it.
There's a music to it.
And what's actually going to work
is what the intersection of that vector
and the patient and that patient's body,
which is a musical artistic thing, less scientific.
In the same way, when one is learning music,
you have to be rigorous, rational, practice over and over again
and really, really think.
It's a cerebral thing to really learn music
until you get to a point where it's natural
and it's instinctive. So I don't think
there's that much of a difference.
Alright. Now, you mentioned
gene therapy.
Could you, let's do gene therapy
101 for the moment.
It's for me and maybe Chuck.
Well, I already know what gene therapy is.
It's for other people.
Yeah, I mean, you know, maybe the people out there who work for the company might want to know.
You know, I mean, you have some genes.
They lay on the couch.
They talk about their gene mother.
Right.
So, you know, many of us have heard of gene editing.
And so maybe let me start with the question,
can you distinguish for us, for me,
between gene editing and gene therapy?
Absolutely.
And I know you've done a podcast with Jennifer Doudna.
Yes, we did.
Which I saw, which was really fabulous
and much to learn from.
So think of your whole genome like a book.
And what gene editing does is it finds a word that was misspelled,
whites it out, and writes in the correct word.
Right?
Each page is a gene.
So you edit.
That's called gene editing.
You said whites it out?
Yeah, like white out.
Whites it out.
Oh, yeah.
I'm just kidding.
If everyone younger than 30 in this room,
there used to be a typewriter and paper and ink.
I know, right.
Okay.
And then there was this liquid.
Okay.
They still have it in Texas, by the way.
That's for sure.
Okay, so you would blot it out.
Yeah, so you blot it out, and you write or type in the correct word.
And what we do, traditional gene therapy,
is you add the whole page with the corrected word in it.
You just add the whole gene back
instead of trying to edit it individually with individual letters.
So that's the difference.
Isn't that harder to put all the genes back than just
fix one of them? We can create the gene in a lab, basically, with the whole sequence intact.
And you don't have to edit. It's the scissors and editing part that's hard. Just replacing the whole
thing is actually really much easier. That I didn't know. Right. And gene editing is starting to work.
There's a company that just released a product in sickle cell disease just a week ago. So it
is starting to work. But traditional gene therapy is here for so many patients who need it now.
There's ways to replace genes that will work for cardiac and hematology diseases and reach these patients who are otherwise going to probably die pretty soon
without waiting for gene editing.
So if you do this, if you swap that out,
again, I'm still in gene 101 here.
Every one of my cells has my entire genome in it, correct?
Yeah.
Okay, so what does it mean to swap it out here when I have all the rest of my body cells?
Are you going into every one of my body cells to do this?
So there's something called tropism.
The attraction for the viral vector.
Tropism?
Tropism.
What did he say?
He said.
I'm a gene.
I'm just a gene.
Very good gene.
Very good.
The best.
The best gene. Very good. The best. The best, Gene. All right.
So the tropism...
Tropism.
Tropism is the attraction of a vector, and I'll come back to a vector.
You're loving yourself for vectors here.
Yeah, I love vectors, yeah.
Okay.
For a particular cell type.
For example, there's a vector called AAV,
AAV9 specifically, that loves the heart.
I got heart socks on today.
Yeah.
It loves the heart, and it's tropic for the heart.
So it primarily will take the corrected gene to the heart,
not to all the cells in the body.
That's essentially how it works.
So when you do this, does there have to be a problem,
or can you identify the potential of a problem,
change the page, and then once you do that,
will I then pass that corrected gene on to my offspring?
That was my next question.
Yeah, so right now...
Wow, we've been working together too long, man.
No, so gene therapy right now,
gene therapy and gene editing
is directed towards somatic cells.
So only cells that are already fully developed,
not germline cells.
There may be a day when we want to correct our disease
and also make sure that our offspring don't have it.
But the first step is to correct the individual's disease.
That's what we're focused on right now
and probably for the foreseeable future.
It seems to me if you're really good at that,
then you don't have to correct it at the germ level
because you just do it any time it comes up.
You just do it.
You go to the hospital and you go home,
and then you're done.
That's right. And Chuck, you also asked the question, do you do it. You go to the hospital and you go home, and then you're done. That's right.
And Chuck, you also asked the question, do you do it after there's disease or before?
Right.
So with our trials, we have to start in a setting where the disease is already present.
For example, we have a drug in a certain form of devastating heart failure called Danone disease.
We want to wait right now until patients actually manifest Danone disease
because you don't want to treat somebody unnecessarily while still being tested.
Is there somebody named Dannon?
There is a Dr. Dannon who also came to a seminar just like this a couple of years ago.
And it's his disease?
That's what I'm saying.
He discovered it.
Let me tell you some advice here, okay?
I once got a phone call and said, we'd like to name an asteroid after you.
My next question was, is it headed towards Earth?
You don't want Asteroid Tyson to take out civilization.
So they said, oh no, it's safe in the asteroid belt.
So I said, thank you.
So to have a disease that is especially lethal
with your name on it doesn't sound like an honor.
Unless Dr. Tyson was going to also help steer the asteroid away from Earth.
Right.
Which is what Dr. Dannon did.
Oh.
That sounds like the volunteer firefighter who started the fire.
Oh!
That's right.
Yeah, no, so Dr. Dannon's a wonderful person.
He discovered the disease, but he also helped us uncover the solution for it.
Okay, so now you have, you're using viruses for this
because they're kind of badass at what they do, right?
And so you're recognizing this fact.
So how do you know which virus to use of the countless ones that we share this planet?
Yeah, that's been a journey of probably three decades of earlier discovery before we got to this place.
We use two types of viruses.
One is a lentivirus, which is a modified HIV virus.
We know how infectious HIV can be, but we're inactivating it and making sure that it doesn't self-replicate,
but still infect cells. That's a good thing, yeah.
Right? So still infect cells. And that's good for bone marrow diseases, hematology conditions.
Sickle cell is actually one of them, a hematology disease where something like lentivirus would be
good. And another virus we use is called AAV, adeno-associated virus. And AAV is non-infectious, but also can infect cells
pretty robustly. And we use that for our cardiac diseases, as well as other companies have worked
on CNS and liver and other diseases using AAV. So you select the virus based on the target organ,
again, where it would be most tropic for. So you're turning, reminds me of a quote from Abraham Lincoln.
And he said,
can we not defeat our enemies by making them our friends?
For enemies?
Well, no, that's different.
That was real housewives.
No, the point is you have viruses
and none of us thinks nice things about viruses.
You turn them into something that can help us, and then viruses become our friends.
Actually, for folks who are right now potentially cured of their hematologic diseases like Fanconi anemia and LED, which we're working on, those viruses are their friends.
Hello, I'm Vicki Brooke Allen, and I support StarTalk on Patreon.
This is StarTalk with Nield Graz Tyson.
So you've said vector at least 30 times in this conversation.
So you have a virus that, and I have a cartoon understanding of viruses.
There's a cell, there's a virus, and they'll only interact if there's a way for them to physically connect.
And so can a virus otherwise just bust in to do its work?
Or does it need some kind of backdoor or some kind of trapdoor that it knows about?
A docking station.
Docking station? How does that work?
I'm glad you say that.
So yes, there are protein-protein interactions on the surface of the virus and the surface of the cell,
and that's exactly what tropism is.
But taking maybe the cartoon... Oh, so you're saying in tropism,
it's not even biochemical, it's physical.
Yes, yes.
That's what you mean by tropism.
Oh, okay.
The shapes match up, and then there you go.
Exactly, exactly.
But so it's like a dog, right?
So think of a vector like a rocket.
There comes a rocket uh you knew that was
cut you knew that was coming listen i would have i wouldn't have it any other way okay you're not
surprised the rocket the vector is like a rocket the gene that you're correcting is basically the
cargo or the payload or even the people right and you're basically uh you can use that analogy to
think about gene therapy, right?
Taking corrected gene into cells just like a rocket takes people to wherever they want to go.
Where do you want to go, by the way?
I like Earth.
You're fine.
Okay, so rocket is vectored, right?
It has a direction and it has a purpose and a mission and the velocity.
Right.
Okay.
I was debating with some of my team about velocity as a value
because we want to move fast, but they're like,
well, Rocket already has velocity, so it's sort of redundant.
I said, fine.
Velocity can equal zero, just to be clear.
Good point.
V equals zero.
V equals zero, right.
That's fine.
Velocity can even be negative as a vector. I equals zero. Yeah. V equals zero, right. Okay. That's fine. And velocity can even be negative as a vector.
Yeah.
I stand down.
Okay.
Yeah.
All right.
So here's a big economic question.
If there's a rare disease out there,
what is your, other than the goodwill you might have,
what is your financial incentive to invest
people time energy resources venture capital money to cure that where you can run the math on it
and it could never pay your bills no critical math unless you charge like a hundred million
dollars per dose, which is just
absurd. And then you got to hope that Jeff Bezos is the one who has the disease.
Just write that check. So tell me, what is your relationship to this world of rare diseases?
And how does that make economic sense? Yeah. So I think someone who pursues rare disease is a rare individual.
It takes a certain mission, passion-driven focus, science focus, and entrepreneurship to really go
into rare disease. Bigger companies tend to shy away from rare disease because, to your point,
it doesn't make business sense. But for a small company that's starting out, it makes total
business sense. You were publicly traded, but you'd still. But for a small company that's starting out, it makes total business sense. You were publicly traded,
but you'd still be counted as a small company.
In my mind, we're a startup
because the mindset of a startup is that everyone cares
and we're all founders, we're all owners,
and the patients and we are connected very personally.
So even if we blossom into a much bigger company,
we'll always be a startup in our mindset.
Now- Keep telling yourself that. 283 people here. if we blossom into a much bigger company, we'll always be a startup in our mindset. Now...
Keep telling yourself that.
283 people here.
I think we all feel that way.
28,000 people.
Exactly.
That is...
Okay, so a startup mentality, by the way,
is one of the healthiest things
that can exist in a growing economy
because then ideas can germinate.
They're not squashed by legacy
of whatever people
think should be true.
Latitude to be creative.
Yeah, all of that.
We're loving that.
So, all right.
I looked at some numbers
before I got here.
I did a little bit
of homework.
Uh-oh.
And there's a website
that is all about
rare diseases.
What is it?
The National
N-O-R-D
Nord. Nord. See, everybody here knows Nord. Right. And What is it? The National N-O-R-D.
NORD. NORD.
See, everybody here knows NORD.
Right.
And what I noticed is there are so many rare diseases that the rare disease category
is almost as big as any other diseases that are not rare.
In other words, rare diseases are not rare.
As an aggregate.
In the aggregate, is that?
It's funny you say that.
Yeah, so each rare disease is rare, but rare disease is not rare.
Yeah.
And yeah, there's...
As a category.
As a category, that's exactly right.
If you bust in and you're good at rare diseases, that is...
And it's the tactics that you invoke,
which could have specificity depending on the disease,
but the methods and tools are similar.
Oh my gosh, you can corner the market on rare diseases.
Yeah, so actually in...
I shouldn't have said it that way.
That's so crass.
Oh no, it's great.
This is America.
Corner the market.
We are totally fine with what you just said.
We know exactly what she said.
No, corner the market is so crass.
The reality is that developing these therapies does take a lot of money
and requires investment,
and it requires dedicated investors who are here long-term.
Also, the government has a program called Pediatric Review Voucher Program
that will reward companies who just get an approval for a rare disease.
So it sort of helps offset some of those costs so that there's a nice partnership there between
industry and regulators. You would expect at some level the government to step in if something's
not otherwise financial, if it cares about its own citizens. And are there residual or tertiary kind of benefits that come out of the specificity?
When you solve, it's very specific, can you then say, oh, all these other areas are now helped?
Absolutely.
So we here at Rocket…
What you're trying to say is, can one thing help other things?
Is that what you just said?
Basically, yes. Can one thing help other things?
Another way to say it is we have a platform approach.
So once you figure out one solution for a cardiac disease,
it's easier to apply other therapies to other cardiac diseases.
We recognize that. So does the FDA, by the way.
They're trying to make things easier for us
through both clinical and manufacturing sort of streamlining.
And when you discover that help in the other areas,
do you get a cut of that as well?
Well, if it's patented, right?
Yeah, I mean, we have some folks here
who know quite a bit about FTO,
freedom to operate, and patents.
But I think that the profitability here
takes a long time as a startup.
Some of the most successful companies are only profitable about eight years after their biggest launch.
So that's going to take time, but we're really here for the passion, the mission, and ultimately the money will follow the science.
So right now, are you tracking certain specialty do you have certain specialty diseases you're targeting?
What are they?
So we have six diseases that we target.
Three of them are bone marrow derived, which are Fanconi anemia, a disease of DNA repair.
The DNA actually can't repair itself.
Carl Sagan and you had an episode with this DNA repair mechanism, right?
So this is faulty in Fanconi anemia.
with this DNA repair mechanism, right?
So this is faulty in Fanconi anemia.
I remember that from when I was eight,
and then again when I was a little bit older and watching your Cosmos.
You made a pretty good graphic on that.
You did, yeah.
Yeah, yeah, that's right.
Better than, should I say, better than the original?
But that was a long time ago.
Yeah, yeah, yeah.
The original was 1980.
Let's hope, let's hope.
Yeah, about 44 years ago.
Just a quick point.
I just have to slip this in there.
Please.
What I did know about,
I took biology as a senior in high school,
which is inverted from what was typical at the time,
I think even today.
I took physics first, then chemistry, then biology.
So biology for me was more,
I'll do it because I have to, right?
But there's some things I remembered
that the DNA molecule is actually handed.
So if you put a DNA molecule in a mirror, those are not the same molecules.
So because it turns the other way.
And so one of the early versions, because the artists were the computer graphic folks were creating the DNA molecule.
And it was spinning the wrong way.
I said, no, that's not on this planet.
Oh, wow.
Okay.
Yeah, yeah.
So the DNA molecule spins sort of helically clockwise,
if you're looking up from below,
and it'll do that no matter how you orient it.
So I'm just proud of myself.
Interesting.
A little applause for that, I think.
But thank you.
Okay.
That's great.
That's my little thing.
I like chirality and handedness and things like that.
But back to the point.
So you were listing your disease.
Yeah, so Fanconi anemia is exactly one of those molecules doesn't work in Fanconi anemia.
One of those repair pathways doesn't work.
So these patients develop bone marrow failure and leukemia
in their single-digit years in their teens.
So we have a therapy in Phenconanemia
that is going to be submitted to the FDA for approval
first half of 2024.
Just quickly, LAD-1 is a disease,
an infectious disease that really kills little boys and girls by the age of two
in two-thirds of cases. So it redefines the word devastating. They're in and out
of hospitals with fungal pneumonias and we've now treated nine patients. All of
them are out about two years or more and instead of living till the age of two
they may turn 92. In fact our treating treating doctor who works with us, and we didn't
say this because we can't, said this is a cure, right? At the DNA level, correcting the DNA is
the most fundamental way that we can cure disease as human beings as we see it, right? Right.
Third one is called pyruvate kinase deficiency. It's like a hemolytic anemia, like a sickle cell
or like a beta thalassemia. Then we have three cardiac programs
that our company is the first one to get into that space. Dannon disease, which I mentioned,
a disease of the heart where these boys, more than girls, but boys pass away in their teenage
years as well of cardiomyopathy. Sometimes you hear about these athletes who suddenly fall over.
Now we know why some of them fall over.
They have something like Danon disease or PKP2 is another arrhythmia or BAC3.
So we're really uncovering the fact that a lot of what we call traditional disease like heart disease or even stroke or Alzheimer's is actually many diseases.
And we're trying to go after them one by one genetically.
And you're targeting childhood diseases.
That's the greatest loss of life is the death of a child in the statistics of population.
Right.
I mean, you died at 80 because, okay, you lost 10 years tops.
And can any of these applications have relevance
in chronic lifestyle diseases,
which is what we see most of in America?
Yes, there are some folks working on
preventing coronary artery disease
through a similar gene pathway.
People are working on Alzheimer's.
Huntington and Parkinson are already targets.
So the way we see it is that
we want to crack open the door
based on single gene defects, right?
Like the ones I mentioned, or like sickle cell.
And that'll ultimately...
They're at least tractable, right?
They're tractable, yes.
Because if there's something that has 32 genes going on,
you're in a... you can't.
Right.
So we start with one, we'll get to two.
Eventually, we'll be able to tackle many genes.
But that's a ways away.
And I think we're just trying to get the process.
Well, how ways away is it if we have AI plus quantum computing?
That could be next.
It won't make a difference because it will kill us all.
Ha, ha, ha.
2001.
Exactly.
Or you say the AI will use the quantum computing to be especially effective. There you go. Exactly. Or you say the AI will use the quantum computing
to be especially effective.
There you go.
Okay, I take it back.
I take back the question then.
Chuck is right.
I hope in our lifetime,
but certainly in some of our children's lifetime,
I think we'll see a lot of progress. All right, so if you are in the same field,
even though it's specifically different,
swapping out whole pages of DNA,
nonetheless, you are changing, or you would say restoring,
but it's still changing the DNA profile you had before you walked into the room.
Now, in your cases, the morality of it is trivial.
The kids are going to die, okay?
But there are many genetic disorders, we call them,
where you can still live a full life.
It's just you don't match up with the model human
who you compare all your senses and all your limbs.
And are they all to match the model human?
Well, then you're normal.
All right?
And if you don't match it, then you're not normal.
Like baldness.
So where does...
Who says what's normal and what's not?
I mean, I think that...
Before 1987, I read that the American Psychiatric Association
had, until then, had classified homosexuality as a brain disorder.
And so if it's a disorder judged by some committee of people,
then who is deciding who gets gene therapy and who doesn't?
Yeah. Well, I think what's normal is probably defined by the times and by the culture.
Should it be?
Maybe, maybe not. But I can tell you what's not normal is...
Because I know 170 years ago,
what was considered normal in the United States
in the South, okay?
And 170 years from now,
it might be that much different.
Yeah.
But I know what's not normal, right?
Which is having these devastating diseases.
Right.
I don't think that's normal.
Death.
Death, I guess, is normal.
Well, no.
Yes.
But not at a young age. Not at two years old.
We can all agree that's not normal.
But yeah, I think that you're talking about
designer gene therapy,
and that's obviously somewhat of a controversial topic
that's going to evolve over time.
But I think we start where we start
and then see where it goes.
No, because I say that, and I didn't come up with this.
I mean, I see it rising up around me.
What's the film?
Gattaca.
No, no, I know Gattaca.
No, no, it's the film that had, it was a rock musician who went deaf.
The Sound of Metal.
Sound of Metal.
Sound of Metal. In that, it's a rock performer, went deaf. The Sound of Metal. Sound of Metal.
In that, it's a rock performer, and he plays loud rock music,
and then he goes deaf pretty catastrophically.
And then he learns that there's a whole community of deaf people.
I'm summarizing here.
But then they find a way that they could put devices in and restore some of the hearing.
And then, but he had gotten so accustomed to the silence and the community of others
who embraced that state of existence that, no, he ultimately rejected it.
Again, that's a case where he's otherwise healthy.
Just one of his senses is gone.
He's otherwise healthy.
Just one of his senses is gone.
And so I wonder where the future of this goes.
And what kind of future, you know, is there a sort of morality committee?
Is there a, in your field?
Surely there's something going on in the genetics. But that would be such a great thing
because in order to get where you just said, Neil,
we would have to be so advanced.
Oh, right.
We would have cured all diseases.
All the disease.
Nobody would care about the disease anymore
because we would be to a place
where we're now worried about
why is everybody having white babies?
And just one other example.
Oliver Sacks was a guest on one of our earliest episodes of StarTalk.
I got to befriend him briefly.
We weren't beer-drinking buddies, but he's a neuroscientist, best-selling author.
The movie Awakenings was based on his research.
Had Robin Williams in it, but brilliantly acted in that role. I attended a lecture he gave on,
I think it was hallucinogenics or something. He's a brain guy. But he reminded us of his
neurological condition. So he has, I forgot the full word,
but the for regular people word,
he has face blindness, okay?
Where you don't recognize people's faces,
even if you know them well.
And so I would then realize
that he would only recognize me
after I started speaking.
He'd be polite as a new shake hands,
and then I'd speak, oh yes, Neil, how are you?
Okay. So I asked him, if we developed a pill, a magic pill, and you could take it back in time,
you could take it when you were a kid, to cure you of this, would you? And he said, no, he wouldn't.
Because that very affliction in his mind is what got him interested in neuroscience to begin with.
Wow. And so I think to myself, again, if we're going to compare ourselves to some affliction in his mind is what got him interested in neuroscience to begin with.
And so I think to myself, again, if we're going to compare ourselves to some like model homes,
you have a model human, if you want everything to be quote normal, that might eviscerate civilization of the most interesting people our genome can produce.
And to bring it back to music, I would say some of the most creative geniuses
of our time and previous times
weren't completely normal.
You know, and they were challenged,
they were troubled.
Vincent van Gogh among them.
Van Gogh, Mozart.
Not that it's a prerequisite,
but it's not, it doesn't preclude
that you can be highly creative and productive.
Correct.
I think that that is an outworking of being challenged in a way.
Yes.
Yes.
Because if you're normal and you're not challenged,
then what do you have to overcome?
Exactly.
Right.
I mean, you can say the same thing about poverty,
but does that mean that you don't want to end poverty?
I mean, there are many people who
will tell you that if it were not for the humble beginnings from which I came, I would not be the
person that I am today. And I say to them, that's not necessarily the case. There could have been
some other stimulus that would have sparked in you whatever motivated you to become what you are.
would have sparked in you whatever motivated you to become what you are so it's not it's it's it's what we know that made us it's what we know so we say it because that's what we know but we don't
know what could also happen right sure so is the fda your friend or your enemy oh wow uh turn off
the camera i was gonna say turn off the camera was like, I thought this was a friendly discussion.
Absolutely. Let me ask it a different way. Is the FDA more stringent about their tests
than most, if not all other countries? And is that a good thing? I think they are. And I think
that's a good thing. Yeah. Okay. Speaking as a scientist.
As a scientist, yeah.
The results have to work.
They've got to be statistically right.
Especially given how susceptible we are to thinking something that's true that isn't.
Yeah.
Or thinking that something isn't true that is.
Yeah.
That is rampant.
Optimism bias, yeah.
Yeah, yeah, yeah.
What's it called?
Confirmation bias.
Confirmation bias.
Thank you. But there is an optimism bias as well. Yeah, yeah. In testing, yes, yeah. The, what's it called? Confirmation bias. Confirmation bias. But there is an optimism bias as well.
Yeah, yeah.
In testing, yes.
Okay, so given that,
how does one get access?
I mean, there's a price.
You're a publicly traded company,
so all your stuff is going to cost money.
And I can't afford it,
and I have a kid who's dying,
so what do I do?
Don't take this personally.
No, so... Rough. So the question, another way to think about the question is, what is the cost of not giving
a life-saving therapy? And what is the cost to that individual, that family, and to society?
And regulators and payers can come up with a price that makes sense, that's based on the
magnitude of clinical benefit.
Those are discussions that insurance companies, payers, exactly, right? So insurance companies
would ultimately agree to be payers for that therapy because of the data they see. And that's
discussions that we're starting to have now. And to answer the FDA question, they're absolutely
friends. When we go to FDA meetings, sometimes you can't figure out who's from the
company and who's from the FDA. They're helping us. We're helping them. That's a good fact.
They're not on the other side of some wall. Yes. They're participants in finding the solution.
And they're people also, they have children. And I think once you understand that this is,
we're learning together, it opens up the doors.
And, you know, again, going back to curiosity and wonder, I think we go into the room with a sense of wanting to learn.
And the outcome has always been great.
So, this is only a question I can ask of a CEO.
How do you measure your risk factors?
you measure your risk factors?
Yeah.
Because in space launches, you know, Elon Musk has been very public about his launches where they blow up on the launch pad, right?
And I spent a fair amount of time working with NASA.
I was on their board for a while.
And there was always someone in the room who was afraid that if the public saw a rocket blow up or some major mistake that somehow they'll withdraw the funding.
And my reply to that was, as an educator, you need to teach people that the day you stop making mistakes is the evidence you're not on the frontier.
And so the public needs to be sensitized to what risk means here. Risk doesn't
mean never anything going wrong. Risk means sometimes stuff goes wrong, and then provided
you learn from that, that's all a good thing. So how do you, in terms of R&D, because you don't
even have product yet, you said, right? Okay, so there's R&D versus profit versus all of this.
And how risk averse are you?
Yeah, we need, I think the secret sauce here
is the right people, world-class people
who are going to believe and stay and persevere
with grit and tenacity over time.
Way to suck up to your employees.
They inspire me more than I inspire them.
Chuck, we are their guests here, okay?
I'll behave, I'll behave.
We need patient investors
who believe in the story.
And yes, mistakes
are a part of this.
And since we're talking
about these fields
all mixing together,
in the world of music,
I've had the chance
to sit and learn
from real, really great masters
as a musician.
And the best masters... I sing Indian classical music and I play this instrument called the
harmonium. Oh, interesting. Okay.
But the greatest masters are the least judgmental. That's what I've learned. And even when you play
a wrong note, they'll consider it musical because they hear what no one else hears. And I think that's the same with making mistakes in science.
There's no right or wrong.
You have to make mistakes.
And I actually applaud SpaceX's being open about it
and not fearful about it.
Yes, I do too, because I am not buying a ticket.
I told Elon, I said, Elon, I'll ride one of your rockets
after you fly your mother on one of them.
There you go.
Safely.
Then I'll go.
I hope you enjoyed my conversation with Gaurav Shah,
the co-founder and CEO of Rocket Pharma,
giving us a glimpse into the future of gene therapy.
This has been StarTalk,
and I've been your host, Neil deGrasse Tyson.
As always, keep looking up.