Planetary Radio: Space Exploration, Astronomy and Science - 2024 NASA Innovative Advanced Concepts Symposium: Part 1 - Human hibernation and swarming Proxima Centauri
Episode Date: September 18, 2024Join us on a journey to the 2024 NASA Innovative Advanced Concepts (NIAC) Symposium. We'll hear from the teams behind two NIAC projects that could help us study distant planets and potentially reach t...hem ourselves. Marshall Eubanks from Space Initiatives, Inc. and his colleagues will introduce us to their concept for a swarm of laser sailing pico spacecraft that could travel interstellar distances. Then Ryan Sprenger from Fauna Bio Inc. joins us to discuss how hibernation could help humans reach other worlds. Then, our chief scientist, Bruce Betts, joins us for What's Up and a new random space fact. Discover more at: https://www.planetary.org/planetary-radio/2024-niac-part-1See omnystudio.com/listener for privacy information.
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Join me on a journey to the 2024 NASA Innovative Advanced Concepts, or NIAC, Symposium, this week on Planetary Radio.
I'm Sarah Al Ahmed of the Planetary Society, with more of the human adventure across our solar system and beyond.
Space agencies are well known for creativity, but the NASA Innovative Advanced Concept Program takes it to a totally different level. It funds
imaginative and sometimes quirky ideas that could one day change the face of
space exploration. I had the pleasure of returning to the symposium to host the
webcast this year, and over the next two weeks I'll share some of my interviews
with the people I met at the event. We'll kick things off with an introduction
from Pam Melroy, NASA's Deputy Administrator, followed by Thomas Swick, Chief Technologist of NASA's Jet
Propulsion Laboratory, who will discuss some of NASA's most impactful innovations. Then we'll
learn more about two NIAC Phase 1 projects that could help us study distant planets or reach them
ourselves. Marshall Eubanks from Space Initiatives, Incorporated and his colleagues
will introduce us to their concept for a swarm of laser-sailing Pico spacecraft that could travel
interstellar distances. Then Ryan Springer from Fauna Bio, Incorporated joins us to discuss how
hibernation could help humans reach other worlds. We'll close out with our chief scientist Bruce
Betts as he joins me for What's Up and a new random space fact.
If you love planetary radio and want to stay informed about the latest space discoveries,
make sure you hit that subscribe button on your favorite podcasting platform.
By subscribing, you'll never miss an episode filled with new and awe-inspiring ways to
know the cosmos and our place within it.
The NASA Innovative Advanced Concepts program is pretty unique.
It nurtures ideas that could potentially transform the future of space exploration.
While seeming like science fiction today, these concepts are grounded in scientific and engineering principles.
Not all of them succeed, but many have the potential to change how we explore space
and create new technologies with applications here on Earth.
NIAC funds projects across many areas.
Space telescope concepts, lunar bases, new systems for sustainable settlement on Mars,
spacecraft propulsion, and even astrobiology.
The program operates in phases.
Phase 1 focuses on proving the theoretical groundwork for a concept, ensuring that the
idea has the potential to overcome all the significant technical hurdles.
Phase two involves developing more detailed designs, conducting experiments, and proving
key technologies.
And then there's phase three.
For exceptional concepts, this last round of work focuses on bringing these futuristic
visions closer to reality, potentially
transforming them into full-fledged NASA missions. Part of what I love about the program and
about the symposium is that NIAC emphasizes a collaborative approach, bringing together
some of the brilliant minds in academia, industry, and NASA centers to address some of the most
difficult aspects of space exploration. Day one of the conference began with this address
from Pam Melroy,
NASA's Deputy Administrator.
Hello, I'm NASA's Deputy Administrator Pam Melroy.
It's my honor to welcome you to this year's NIAC Symposium.
For years, NASA's Innovative Advanced Concepts Program has encouraged us to push the boundaries of what's possible,
turning science fiction
into science fact.
This program is essential to our agency as it nurtures visionary ideas by supporting
early stage research while also engaging America's innovators and entrepreneurs as valuable collaborators
in the journey. Our next steps and giant leaps rely on the innovation of agency and industry minds.
And the concepts born from NIAC can radically change the future,
as we venture farther than ever before with NASA's Artemis missions,
while also keeping an eye on our home planet for the benefit of all. One example of that is the Microtechure Off-Planet Project,
which received NIAC Phase III Award funding this year
to continue its development.
Led by Lynn Rothschild and the team
at NASA's Ames Research Center,
this project is developing technologies
that could grow habitats on the moon, Mars, and beyond using fungi.
Not only does this technology have the potential to revolutionize the future of deep space habitats,
but it's already being put to good use right here on Earth as potential building material for sustainable and affordable housing in places with scarce resources.
I share your excitement to explore new ideas,
learn from the best and the brightest in the industry
over the next few days.
Thank you for joining our journey to the stars
for this year's NIAC Symposium.
Pam mentioned Lynn Rothschild's work.
Lynn and her teams are the first to have been concurrently awarded funding for a Phase I, II, and III project.
It's really impressive.
She's already agreed to come onto the show on a later date to speak about the intersection between evolutionary biology and space technologies. Shortly after Pam Melroy's introduction, John Nelson, who's
the NIAC program executive, took to the stage to introduce the next guest.
We're going to kick off today with a welcome from Tom Swick from JPL, or of course right
down the street from JPL here in Pasadena. Tom is currently the chief technologist at
NASA's Jet Propulsion Laboratory. In this role he provides strategic leadership for the technology development efforts at
JPL and specifically he's responsible also for the portfolio of projects that fall under
Space Technology Mission Directorate, which of course includes NIAC.
Tom's been at JPL for over 30 years.
He's worked as the associate chief technologist.
He's managed the space technology office.
He's worked in several development areas,
developed several flight hardware systems,
and also led formulation of the NASA Aquarius mission.
So it is my pleasure to welcome to the stage, Dr. Tom Swick.
(*applause*)
Tom Swick. Thank you, John.
It's a real pleasure to be here and welcome you to Selling California and JPL Caltech
here in Pasadena.
I'm Tom Swick again.
I'm the chief technologist at JPL and have been working with NIAC and various technologies
for many years, as John mentioned.
And one of the things we do is assess the health.
Well, how healthy is this area for new ideas?
Because these are the ideas that pull us into the future.
And when I look at the NIAC program year after year,
you see it's very healthy.
The ideas are incredible.
When I look at NIAC, also NIAC's about changing the future.
So I thought about that, what are three things
that we at NASA, and specifically here through JPL,
did to change the future?
And I looked back and I said there was Voyager,
Soljourner, and Ingenuity.
And these, I thought, were actually not NIACs.
They were either too early or they didn't fit into it.
But I was talking to Walt and STMD, and we believe Ingenuity actually was an early NIAC
concept.
And if you look back, Voyager, in 1966, some navigators, some scientists said every 175
years, the outer planets align such that if you launch,
you could actually, one vehicle could actually travel to all four of them out there, Jupiter,
Saturn, Uranus, and Neptune.
And from that idea, from that simple little idea of astronomy and navigation and trajectory
design, Voyager was born.
Voyager, of course, still flying,
a one-way light time, 23 years now out of the solar system.
And we still keep, with plutonium that's driving it,
and after this time, the plutonium is down,
I think it's a little less than half the power,
just because of the decay of the plutonium
after 72 years of half-life.
And so we keep it moving along,
finding the faults that come up every once in a while,
if you saw that recently,
and then figuring out how to fix them 23 light hours away.
And Voyager, and of course the golden record on there,
which sort of changed science fiction,
or originated a piece of science fiction
with the golden record of Dr. Sagan and his team.
So, Jörner, in the 90s, it was thought that mobility
at the time, planetary mobility
from a scientific viewpoint thought,
well, it's not really necessary
because if you have a fixed lander,
you're gonna land in one spot,
you're gonna have a lot of power
and scientific instrumentation on your lander.
And so if you're gonna scoop and dig
and do remote sensing
locally it's probably not much of a gain to be able to rove say hundreds of meters with the reduced
resources that you could put onto a rover. And so it wasn't it wasn't a given that rovers were
important scientifically but in fact a group of people had an idea that it is you can put enough
resource onto that rover to drive it around and then put instruments on it that you could make smaller and
and actually prove that out. So Sojourner, July 4th, 1997 landed on Mars.
The actual rover there as you see coming off the landing
IGRIS system there out to Iraq on Mars was literally built on the cheap.
You know it was radio shack parts for those folks that still remember radio
shack. We actually JPL engineers went down the street literally in La
Cañada and had got some parts and screened them and did the right things
to try to make them work but that's how you know the ingenuity the the
inventiveness came along to show now that
roving on planets is important and that of course today we're not going to fly anything
but rovers to the planets. And then of course our little helicopter ingenuity. Again, an idea,
the first idea was simply can you even fly on Mars? One percent atmosphere by pressure compared to Earth.
And so can you even put together the lift, the power, the batteries, some type of control
system to allow you to fly on Mars?
Because we believed, some folks believed that if you could do that, you're going to go to
places that you wouldn't go otherwise. Even the most optimistic rover and you will land and do and you could do some in situ measurements
rather than only remote sensing measurements. And so Ingenuity of course landed at 2021 was going to
fly for maybe five different flights to prove it out and sure enough after 72 it kept flying until finally at the end
it came down and then fell over and broke a blade or two. It's impossible
and change of the future that that is and there are many ideas now for other
other flights on Mars. Probably what actually may even be more important than
all that is the use of COTS parts. So
Ingenuity is all driven by electronics that are COTS rather than the big heavy
Rad750 and compute and so on and you need a lot of compute for flying autonomously
such that you can you could move hundreds of meters and then be able to land in a safe spot to keep your track along The way and so on when you don't have GPS obviously and global
localization along with it.
And so there's a selfie of perseverance and ingenuity and the changes that that bring.
Again, small group of people, idea, passion said, we believe this is really going to change
the future.
And here are three cases that actually did.
I interviewed many of the NIAC fellows during my time at the symposium, but the two projects
that we'll be hearing about today address some of the questions that I've had since
I was a child.
How can we send spacecraft to other star systems?
And how can we make long-term space travel safer and more palatable for those who want
to visit places like Mars?
We'll tackle the first of these questions next with Marshall Eubanks and his team.
Marshall is chief scientist at Space Initiatives Incorporated,
a startup that focuses on developing and deploying
small satellites for low Earth orbit.
Their NIAC project explores using swarms of spacecraft
propelled by laser sails to reach the nearest
potentially habitable star system, Proxima Centauri.
We have Marshall Eubanks from Space Initiatives incorporated, along with several other members of the team.
Could you please introduce yourselves?
Robert Kennedy of the Institute for Interstellar Studies, U.S.
Andreas Heun from the Initiative for Interstellar Studies and University of Luxembourg.
And Paul Blasi with Space Initiatives, Inc.
So your project is called Swarming Proxima Centauri.
Essentially what you're suggesting is that we want to get to the nearest habitable world,
well potentially habitable world to Earth using not just one but a swarm of Pico spacecraft.
How small does the spacecraft have to be in order to qualify as a Pico spacecraft? Well there's the mass and the size so the mass has to
be a few grams, four grams maybe. The size is four meters and so it's not as
particularly small in terms of size but it's small in terms of mass. And that's
all set by the size of the laser beam. The laser beam has to illuminate it for
as long as possible. So from the laser beam parameters we have, we needed four meters. So what they're trying to do
is not just send a bunch of small spacecraft, but they want to put solar sails on them in order to
get these technology out using lasers. Laser sails, this is a whole extra thing. Usually when we're
using the light of stars to do this,
it's not as much radiation pressure essentially.
If we really wanna get out there and start going at speeds
that are close to the speed of light,
we're gonna have to use laser technology in order to do this.
How many spacecraft are you going to need
in this kind of group in order to achieve this?
And why is the swarm technology
the one that you wanna be using
instead of just sending one really robust solar sail for example or laser
sail? Well the current plans are a thousand sales and that's a lot yes but
we think that with the laser system we have and there'll be a duty cycle where
it sends one and has to wait a little bit sends one and we think we should
send them all within about a month. And the month comes from having them having to, getting them to cohere as a swarm after you send
them. You'll only have somewhat, that uses interstellar medium drag. You think of the
interstellar medium as a fantastically good vacuum. It's way better than any vacuum you could make here
on Earth. But at point 2C, at 20% of the speed of light, you actually have significant drag,
and we can use that drag, but only so much.
Why would you want to send more than one spacecraft instead of just one?
To avoid single-point failure, right?
So that's why you don't send one big thing and the other reason to send many little ones is economic.
The human race is unlikely to build this century a laser big enough that'll push anything more than a few grams.
We just... it's unlikely to build a laser that big.
So you're limited, each bullet, four grams. That's it.
We started out really trying to solve one problem, which is how to get enough data back to Earth.
But in solving that, the way this happens sometimes,
we realize that
actually there's a lot of other things we can do with swarms. And resilience is one
of them. But there's a lot more than you can do. For example, we can take pictures of the
planet from all sorts of directions so we can get a map of the whole planet and not
just like wherever the spacecraft has us to look, because we have lots of spacecraft.
Which brings me to my next question.
You were already talking about the fact
that our laser technology is not yet at the level
that we're going to need in order to do this.
There are several other components,
including the light bucket for collection
of the actual data back,
that we still don't have in place in order to do this.
So what is the current state of this technology,
and what advancements are we going to need
in order to make this viable?
Actually the technology exists. It's mostly an economic problem.
The launch lasers are variations of like an industrial cutting laser
and some of the military lasers used in beginning to be used in no beam weaponry so the
the laser technology is available it's mostly a matter of scaling it up we're
talking for a fleet like this about a hundred gigawatts so it's not just the
lasers how do you power the silly thing thing while it's sending these guys out?
We have a pretty good handle on the technology for building the probes, but they'll probably
have to be built in space.
They're essentially four meter diameter integrated circuits, built using very thin film technology
so they'll be very fragile in most directions.
They'll do like 10,000 G's while they're accelerating, but that's a known force from one direction.
And then, like I said, the light buckets on the receiving end, again, that's, you know,
known technology.
We, it's just, they're just big telescopes.
But again, you've got to have several thousand of them spread out over a kilometer.
Frankly, we anticipate doing this on the far side of the moon.
We have to build up that infrastructure.
Thankfully, we're sending humans back to the moon fairly shortly.
Fingers crossed for the Artemis program.
And we've seen other nations.
China has already gone to the far side of the moon and done a sample
retrieval, so we're beginning to have this capability. So that's totally
viable given enough time. The thing is that if we're going to be going all the
way out to the nearest potentially habitable world, that's a little over four
light-years away, which means if we did get there, you're gonna have a time delay
of about eight years between Earth sending a signal there and then beaming it all back.
So you're going to get a fair degree of autonomy in these craft in order to make this work.
What kind of decision-making power would you have to be giving each of these spacecraft in order for this to work?
Yeah, so the decision-making power in each of the spacecraft has to be fairly significant,
but we anticipate that on the time scales where we expect those other technologies to mature and economic conditions to be
available to develop such an infrastructure that the computational
power available on each spacecraft has vastly increased compared to current, to
the current status. So that's the reason why we don't really worry that much
about the computational capabilities
and the algorithms which are going to be on those spacecraft because both are making tremendous
advances at the moment.
It sounds like you need a very specific kind of formation of these spacecraft in order
to optimize this.
I was reading about how you want to organize them in kind of like a lens shape essentially.
What is the benefit of doing that?
Well for all of this to work they have to be synchronized. They have to communicate
with each other. They have to know the range to each other, the distance to
each other so they can determine with their positions. And a hexagonal pattern
is very good for that. Now if you only had one layer you would have a very
hard time determining like is the thing does the thing have bins in it.
It's like carpet that sticks up or something
that's that could be hard to determine in the carpet.
So you want several layers because we really need to know a 3D position for the whole swarm
and that's crucial both to get there properly and then usual navigation problem
but also to send the data back to earth in a synchronized fashion.
And we think we can get about a kilobit per second back with the current plan.
And that would mean that's comparable to New Horizons.
So that would mean three or four gigabytes in a year.
And that's more or less what New Horizons sent back.
So all the pictures of Pluto, we think we could do that at Proxima Centauri.
And by the way, we're assuming that effectively there's no communication from Earth to the probes because of that.
Because any data from the Earth, of Proxima itself, will be eight years old, right, from the probe standpoint.
They're on their own.
They're really on their own. They have to decide all of this stuff and do all of this stuff and, you know,
and even like pick out which will take way more pictures than we can send back.
So they have to decide which pictures we can take.
And in fact, I call this the Paris selfie problem.
You have a thousand tourists, you get them all a camera, and you say, go to Paris and
take a picture, and you get back a thousand pictures of the Eiffel Tower.
That's not what you want.
You want distribution.
So that's actually a fairly tough computational problem, but we do have a lot of probes. So not only has each probe's intelligence improved or
computational ability improved, but we can also use them as a swarm together.
So you can have a distributed intelligence and that we'll be doing a
lot of that of necessity because we can't even send all the data we collect
between all the probes. And so you have to say, here's my best data, what's your
best data like? We got to have, you know, and then come up with a coherent picture
of what's the best data for the whole mission to send back to Earth.
And I guess that's the benefits of a mesh network. You can interconnect all of them
and really do this kind of science. But given the really limited nature of how much mass
you can put on these, what kind of instrumentation can we actually hope to send to Proxima B with this technology? Oh we're planning a
lot. We think we can do 60 meter resolution. So I mean that would
mean for example in terms of like looking for technosignatures and
biosignatures we could look for airports. We could look for forests. We could look
for you know coral reefs maybe that kind of stuff. There's a
lot you can do with imaging. I mean we've
heard from people, oh you anything you
can do up there with these small probes
you could do on the earth. Well no, there's
just no way. I mean we could look for
lightning on the dark side.
We will go by both sides until we can
look at the dark side and the light side.
And from a biosignature point of view
the most important
thing I think, we can do transmission spectroscopy. So we can look at Alpha Centauri AB set behind
the planet. For example, we can look at the sun set behind the planet. We can look at
the drive laser. We can get the drive laser turned on at the right time set behind the
planet. And from that, you can find out a lot about the planetary atmosphere and what
molecules are in it. So you could look for methane or carbon or water or you know, ozone, all kinds of different
molecules.
Some with photography and others with transmission spectroscopy.
So if you combine those two things together I think you have a really powerful quick look.
I mean if you saw the video we have it's your 30 seconds and it's over.
A long time to be gone and a short time to be there,
but because it's a 20-year voyage. But we think we actually have a good chance if there's a
significant biology or technology even on Proxima b we should find it. That is the dream right there.
We do have the technology with many of our spacecrafts to look at the atmospheres of other
worlds and analyze their components. That can give us a good idea of whether or not they're
habitable, but the ability to actually send our instruments to another star system and analyze
that world up close, that is so far beyond anything we're capable of right now. And that could
change everything, not just for Proxima B, but what other applications could we use this
for? What other worlds could we explore using this technology?
Well, clearly we're going to have precursor missions, as one of the other speakers was
talking about. We could send, I mean, my visioning is we'd first send missions to nearby asteroids,
potentially hazardous asteroids maybe, to look at them. I mean, this would be a very
good capability for the planetaryary Defense Office to have.
If you find a new potentially hazardous asteroid, send a few probes out there. What does it look like?
How big is it? What's it spinning like? You know, all that kind of stuff.
But then you can just go, and so I think it's a step program, you'll do that.
You'll go to like things like, oh the Martian Trojans.
We could go there, it's as easy as getting to Mars, but nobody goes to the Trojans,
because well you're going to Mars instead of the Trojans.
But we could, you know, because they're cheaper.
So that's another advantage, it's cheap.
But then as you develop capabilities you can go out, I mean, with a fraction of the power
the laser would take to go to Proxima Centauri, targets like Sedna, 100 AU away, Eris, would
become quite possible.
You know, it would not be, oh, it's way out there.
You don't have to wait 40 years.
You could do it, well, a year at least.
I mean, at worst.
You know, it's like all these things you think about, you could get there within a year mission.
So that actually makes it more like a grad, you know, if you want to think about the academic
aspect, it's like a grad student could like, oh, I want to send the mission to Sedna.
Send the mission to Sedna, get the data back
and get their PhD all without growing a long gray beard.
And I liked that in your original article on this,
you pointed out that you could not only do things like that,
but potentially even use it to go to places
like interstellar asteroids, like Oumuamua,
and things like that.
We've seen a few of these things, I think two interstellar asteroids go through our systemu and things like that. That, you know, we've seen a few of these things.
I think two interstellar asteroids go through our system.
That one and Borisov came through and we had no way
of getting to them in time to investigate them.
With this technology, we just go right out there
and check it out.
Well, actually there is a way to get to them
with a funny, you know, solar flyby
and later Jupiter flyby,
which most of this team was in on. It's called Project Lyra
You're looking at three of the authors
You know people think we missed the boat on Oumuamua
We didn't we could catch it and with lasers and laser sails you could absolutely
fly by Oumuamua
One of the things I like to say is for millennia, for thousands of years to come, getting to
Muamua will be easier than getting to Proxima Centauri.
I think we will go there eventually.
The question is will it be in 10 years or 100 years, but eventually somebody's going
to say, yeah, we should go out and look at it.
And as this technology improves, doing that's going to get from, I mean, we could do it
right now if you wanted to develop like a whole SLS launch, descending a fairly small 100 kilogram or so probe to
it and do a lot of gravity assists and so on. It would be expensive, but if you wanted
to, you could do it. Is this technology improves? That'll get cheaper and cheaper and quicker
and quicker. At some point, somebody's going to say, well, let's just do that. It's a five-year
mission or a one-year mission or whatever, but you know, we're doing all this other stuff,
we might as well do that too.
So I'm convinced of this,
we will get the Humuamua one of these days.
And that is even true if we find a whole bunch
of other ones, just because it'll be the first
and it's a little strange and it's not
from an interstellar standpoint that far away.
range and it's not from an interstellar standpoint that far away. To actually touch an interstellar object, you know, touch or sample it on the way past,
that's worth a flagship mission.
Ten to the tenth of dollars.
The value to science, that's absolutely worth that kind of money, like we paid for great
observatories or flagship missions.
It's genuine, bona fide, extra solar origin.
That's worth knowing, paying a lot to know.
I absolutely agree.
I mean, can you imagine just the amount
that we're learning about our place in space
through samples like OSIRIS-REx,
through the Hayabusa missions from JAXA,
the far side of the moon sample,
I cannot wait to see more about that.
It is absolutely bonkers what we could learn.
And if we could get a sample of literally material from another star system, who knows
what that could teach us about ourselves and our place in the universe.
I think this is really cool technology.
I'm really glad that organizations are doing this.
You're not the only ones that have proposed trying to go to nearby star systems like Proxima using this, but I mean as someone from an
organization who once had a solar sail, we get emails every week about people
who are passionate about this. So I really hope that your team manages to
pull this off and move on to the next phases because this is revolutionary.
This is game-changing stuff. Well thank you you so much for joining me, all of you.
I really appreciate it.
And seriously, all the luck in the world
from the bottom of my heart,
this is the dream technology I've wanted to see since I was a small child.
And I'm sure that's true for all of you as well.
That's a nerdy thing to say, but it's true.
Well, I think you made my day.
We'll be right back with more from the NIAC Symposium
after this short break.
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Later that day, I spoke with Ryan Springer, senior research physiologist at FaunaBio Incorporated. Their company focuses on AI-driven drug discovery.
It uses data from the last 100 million years of evolved disease resistance in mammals to
find new ways to improve human health.
Their team's NIAC proposal looks at animals that naturally hibernate to learn more about
how we can induce a state of torpor in humans for long-term spaceflight.
Thank you so much for joining us.
So, this is Ryan Sprenger, correct?
He's from Fana Bio Incorporated with a project called STASH.
Now this is studying torpor in animals for human space health or
space health and humans. Yeah. Essentially if you're a fan of science
fiction you've probably heard of this idea of putting people into a hyper
native state or cryogenic freeze as an example in order to send them to other
worlds right. Cryogenic freezes were not all the way there yet completely freezing
humans is not the thing but what is it that you're trying to do here in order
to enable humans to travel to other worlds? Yeah, essentially what you're
talking about, we're interested in studying hibernation as a potential way
of traveling humans in space for longer and in a healthier way. And so based on
precedential information that we have from the ground, we know that
hibernators are protected against a lot of things that you run into in space.
And so that's where the health benefits come from.
And these are things like radiation.
For example, hibernators are well protected against radiation.
They don't have disuse atrophies, so they don't lose muscle on the ground when they're
not active.
And these are two major health risks for astronauts in space.
So that's the health aspects of it.
And then in addition to that, like you had mentioned with the science fiction and the
cryopreservation,
long duration space flight might be a lot easier
if you're in a semi-quiescent state like hibernation,
where you're not perceiving that you're in space
for years and years and years.
And on top of all of this, hibernators don't eat, drink,
they don't go to the bathroom.
These are all things that you have to think about
when you're traveling very far in space for a long time.
And so if you can move humans, for example, into a state like that, you have a lot less issue with
logistics with regard to that long duration space travel. So there's a lot
of benefits that hibernation may provide to astronauts in space. I'm thinking too
about the psychological impact of being stuck inside of a spacecraft for that
kind of extended travel through space. There's a lot of studies we've done on
trying to lock people into these tiny little biocontainment units and see how they'll
interact over time, but it might be a lot healthier and a lot easier if we can
just kind of put people into hibernation. The question is, how are you planning to
achieve that? Because we want to do it safely and make sure that we can do
these studies in a way that's ethical. Yes, yeah, and that's what Stash is
starting with. So the question is, how do you safely translate hibernation in humans?
And that's something that you can work on on the ground, for example, but translating
hibernation in humans in space is a whole different question.
And so Stash, for the first time, would allow for the actual study of hibernation in space,
which has not been done ever.
So we don't even know if hibernation will work in space.
We don't know if the protective mechanisms will still be happening in space.
And so STASH is providing an environment
that you can study hibernation in space for the first time.
And as a consequence of that,
we can also study other organisms in space as well
with regard to real-time physiology,
which again is not currently available
in the space environment.
So that's the first step to doing it safely
is first understanding what it looks like
and how it
applies in the space environment.
And then from there, applying it into humans, again, is a very precarious road to take,
but it is a road I think that we do need to take, but doing that safely, that's a large
discussion, maybe for a different time.
And we're not just talking about launching one of these random units into space, right?
We're specifically talking about putting one of these on the ISS and on the International
Space Station.
And specifically, you want to integrate it into the SABL unit, correct?
I'm forgetting what the acronym stands for.
Space Automated Biological Laboratory.
That's developed by BioServe and they're in Colorado Boulder.
But yes, so this is aboard the ISS.
It's already there.
We've actually, as part of our program, we've shown integration efficacy with the Sable already.
So the unit that we're developing
as part of this TASH program is called the respires unit.
We've just named that recently.
And so this would be launched and integrated to the Sable
onto the space station to allow for this study.
So how do you actually induce this hibernative state?
Yeah.
It depends what you're trying to induce it in.
In a natural hibernator,
you just, you really don't have to do anything to be honest. They'll just do it by themselves
when the season or the time of season comes around. In an animal that doesn't normally
hibernate, there's a couple different methods that you can induce it with. Typically involves
sort of messing with the preoptic area of the hypothalamus. The field is now sort of
at the point in which we can induce a hibernation like state in, for example, a rat, which normally wouldn't hibernate. So that's a different induction method, but for
our purposes, we just have to put them in in the right time of season, and they'll go into hibernation,
we think. At least on the ground they will. We don't know in space yet because we don't know how
well hibernation will work in space. But the most robust way of inducing, though, is making the
environment cold. And so that's also what the sable provides is environmental control. So the sable can move the temperature of the unit
down to about four degrees, actually down to minus five,
but we won't go that low.
So you make them cold, they won't eat at that time of year.
They refuse to eat despite giving them food and water
and everything like that, they won't eat.
And so it's quite an easy induction
with the species that we're looking to study first.
Forgive me talking about hibernation,
I'm immediately just imagining bears in space,
but we can't fit those on the ISS, unfortunately.
And I'm glad you mentioned that because the best species to study for human hibernation
is bears.
We think that human hibernation will look a lot more like bears than it would, for example,
hibernating ground squirrel or a small rodent.
So that would be the dream is bears hibernating in space, which would be cool.
Since we can't accomplish that though, what are some model organisms that we can
use that have enough of similarity with humans that it's meaningful science?
So the species we use is the 13-line ground squirrel.
And the reason we use it is it's the only hibernating species that's bred in captivity.
It's the only hibernating species that has a complete genome.
So it actually has the tools necessary, the readiness,
to translate into humans.
And Fauna Bio actually uses this species quite frequently
to translate other drugs and targets into humans.
And we've been quite successful in that so far.
And so this actually turns out to be a really nice species
to have meaningful impact in humans
because we have that complete genome.
And we've had some success in developing targets
based off of this species.
So it has enough of a shared genome with humans that it's translatable. There's other species
that would be great, like bears. And obviously the 13-9 ground squirrel is a rodent, having a
primate would be the best. And it turns out there is a primate that does use hibernation or torpor
called the ring-tailed lemur, but it's wildly endangered and not a species that you can use
to study something like this. Yeah. It makes me really glad to hear that you're starting out with animals that already have
hibernative states. I think that solves a lot of the ethical considerations around whether or not
we'd be doing harm to animals that don't naturally hibernate, right? But that brings up the whole
next question, which is, you know, how do you deal with the potential ethics of freezing
humans for that long and what
that technology could mean?
Right.
And this is where that precarious nature of translating into humans is going to come because
there will be challenges associated with this translation into humans.
Now, our first step, we think the best thing to do is to first look for targets, drugable
mimetics, for example.
So pathways in the ground squirrel that are upregulated
during the hibernation in space and saying, OK, is this what they're using to protect
themselves? And can we translate that into a drug that you would then give humans, might
afford them those protections? That's step one, we think. Step two is, and we think it's
important, step two is actually moving humans into a torpid-like state because of all the
other benefits. That is going to be a long, arduous process. There's a lot of things that you have to avoid with moving into a lower metabolic rate, a lower body
temperature. There's issues with that. For example, in extreme hypothermia, obviously, humans run into
cardiac arrest, respiratory arrest, and total organ failure. And so, being able to avoid that is going
to be key. And that's why we think bears are going to be a better model because they don't go as low
in body temperature, they don't go as low in metabolic rate, but they still have substantial
savings and they still are in this quiescent state and their organ systems still function.
And so there's going to be different ways to approach it safely, but eventually we'll
have to move into some sort of human testing in the future.
Yeah.
Assuming this goes all the way to phase three and then beyond, right?
It's a really interesting concept because we all want to be able to send humans beyond
our planet to other worlds, but there's so much going on there.
I do wonder though, why is it that a hibernative state on Earth can allow for us to not worry
about like bone density loss or muscle density loss as an example?
And do you think it's going to be functionally different in space? And I guess we won't really know until we get there.
But yeah, that's a very important question for this kind of study. And that's actually
one of the main reasons why we want to study hibernation in space is, is it different in
space? Do the protections change? Do the sort of benefits that we see in hibernation change?
A lot of the things that we're learning from hibernation have applications we think on
the ground as well. So it's sort of a dual use system. We can potentially derive a lot of the things that we're learning from hibernation have applications we think on the ground as well. So it's sort of a dual use system.
We can potentially derive a lot of benefits from hibernation in space, but
also on the ground. And so, you know, avoiding disuse atrophy, avoiding
osteoporosis, these are things that would be great on the ground. There's a lot of
applications for that as well. We hope it's not different between the ground and
space, but we don't know. I mean, imagine if, you know, I just want to sleep until
my birthday and then I can just rest
and come back refreshed.
Imagine what that can do for our longevity
or say you have a terrible terminal illness
and you want to go into some kind of hibernative state
in order to allow us more time to grapple
with the medicine of that.
That's a mind blowing concept.
It is, and there's actually a really neat anecdote
and I'm forgetting the name of the author,
but he wrote a book about his uncle who was in what seemed to be a torpid-like
state, and when they pulled him out of the torpid-like state, and this was because he
had some issues in his hypothalamus in the area that we think is contributing to the
state, when they pulled him out of that hibernation-like state, it actually turned out that he had a
cancerous tumor in his lung, and that then multiplied, and he succumbed to the cancerous
tumor.
So, exactly to that story, it might prolong life
in more than one ways, making a disease quiescent,
for example, like that, or waiting
until new medicines come along.
And there's tons of other applications
that hibernation seems to have on the ground.
So for example, FaunaBio just started a partnership
with the lily.
This is an obesity type question.
Hibernators are really good at saying,
we want to use just adipose tissue.
We want to use just fat as our fuel source.
And so in a very targeted way, they can reduce their adipose mass, which is something that
we wish we could do.
So there's a lot of other benefits that hibernation seems to have just on the ground.
What are some of the metabolic processes or things you're going to be measuring in your
test subjects in order to see whether or not this is actually working?
Yeah.
So the unit that we're designing, the spires unit,
is more or less something we would call a plethysmograph.
So this is allowing us to measure real-time ventilation
in a free-moving animal.
So we can measure how frequently they breathe,
how deep they breathe.
With that, you can measure metabolic rate, too,
because it's a sealed chamber.
So this is indirect calorimetry.
You're measuring oxygen consumption and CO2 production.
The animals, we're thinking right now,
the best option for the first couple experiments
is to add telemeters to the animals.
Then we can get things like heart rate,
body temperature, activity.
With all of these, you can assess hibernation quite precisely.
We know exactly when they are entering into hibernation.
We know exactly how long they're in hibernation
with these measurements.
And then we know when they're coming out as well.
And these measurements are critical
to measuring things like cardiovascular health, pulmonary health,
and things like that in vivo in a free moving animal.
You'll be getting data back from the ISS here on the ground.
But are these experiments something
that the astronauts aboard the ISS are going to be doing?
Or do you anticipate bringing the subjects back to Earth
for further study?
Yes, we will be getting data.
A lot of it will be real time.
So these are the things that are non-telemetry, although we want to develop the unit so that we
can get real-time telemetries too. So that gives us heart rate, body temperature activity, things
like that. But the metabolic rate, the ventilation, these are real-time measurements. So we will get
that data back immediately and we can see to the second when these animals are moving in.
So that will be happening. So live animal return is very difficult with the ISS right now. It is
possible. And it's something that we've discussed with the chief flight veterinarians of NASA as
well as the IACUC committee. It's something that we want to shoot for but the initial
mission is probably not. So this would be a tissue return rather than a live animal
return. Again, very valuable tissues because we can learn a lot from what pathways and
what metabolic things, molecular things changed that we can start to determine, you know,
did they lose muscle?
Was there radiation damage?
Although in LOE, we wouldn't expect to see
a lot of radiation damage.
And other paths, so see what was upregulated
in those instances.
So for the first initial missions,
it will likely be a tissue return,
but beyond that, we would,
live animal return would be even better.
So that's something we're targeting in the future.
We are trying to develop the system as autonomous as we can
because we want this to be applicable outside of LOE so that we
can start to ask the radiation questions as well. And so we are in the in the
process of developing it to be more autonomous for like gateway or Artemis
type missions. So we try to do that as much as we could for this phase one
making it as autonomous as possible. So for example it's a self-regulating air
circulation system.
So we don't have to adjust the airflow for the animals,
depending on what metabolic rate they're at.
So all the astronauts, we think, would
have to do is the integration process,
so putting it into the SABLE.
Per IACUC rules and animal ethics rules,
we have to check on the animal every day.
So we will have infrared cameras to see the animals.
But we've also got viewing windows.
So sometimes the astronauts will have
to go and view the animal via the viewing window.
And then after that, the only other so sometimes the astronauts will have to go and view the animal via the viewing window.
And then after that, the only other process that the astronauts would have to do is take
the animal out of the chamber for the termination of the study, essentially.
Yeah.
I know this is really far future looking, right?
We're only talking about beginning these studies that we can potentially send people to Mars
someday.
But the dream is being able to put people in hibernative states so we can potentially send people to Mars someday. But the dream is being able to put people
in hibernative states so we can someday maybe send ships out
to other worlds that aren't generation ships.
I know that's far flung, but this is NIAC.
This is what this is all about,
thinking about those ridiculous scenarios
and then finding a potentially ridiculous
but also viable solution to them.
Is that part of the dream and why you became a
part of this or what inspired you to get into this?
Specifically, myself and my team, we are very much interested in interplanetary
space travel and we think that this is going to be a very usable and critical
way of doing it without generation ships. And so that's part of the inspiration
is that we want to be part of the group of people that helps
send people into space further.
And so that's where our interest comes from,
our basal interest I would say.
That's what inspires us to kind of try to push it further.
And where we're at on that field, it's really hard to say.
You know, how close are we to putting humans in hibernation?
I know that Trish has funded two studies this year looking at actual human hibernation. So in a
rudimentary sense looking at cellular hibernation in humans as well as
reducing metabolism using sedatives for example. But starting to... we're at the
point where we're starting to... I think we're just crossing the start line of
trying to apply this to humans. Now how long is it gonna take? Who knows? But we'd
like to be part of that process, particularly in the space field, is understanding hibernation
in space and then applying it to humans. That's where it's all coming from.
Well, I mean, first we got to get to the moon, then we got to get on to Mars. You got some
time to work on this, but a little bit of time. But I am surprised we've never begun
to do these studies yet, considering how prevalent it is
in science fiction. And I'm so glad to hear that you're beginning to do this work and that NIAC is
supporting this program. Oh, yeah, we are too. And I'm actually glad that you brought that up as well.
You know, this question has been asked of the hibernation field, I think dating back to the
60s, really. There's been working groups that have been put together by several NASA groups in the
DOD, for example, you know, asking, you know, are we there yet? How close are we to being able
to test this in humans? And the answer always has been, we just don't know enough.
But I do think in the last 10 years, we've really moved into starting to say, we might
have an idea of how to move forward on this. And our advancements in translating a hibernation-like
state into animals that don't normally do that, that has gotten really sophisticated
actually over the last five years, I would say even.
So there's been a lot of really amazing progress in the last 10 years in that way.
And obviously that's building off of the foundational work of all the hibernation physiologists
coming before.
But the field has moved in a really good direction, we think.
And being at NASA and NIAC showing a continued interest in this is really encouraging.
There's still so much to come in next week's episode about the NIAC showing a continued interest in this is really encouraging.
There's still so much to come in next week's episode about the NIAC Symposium.
One of my personal highlights was astronaut May Jemison giving a tribute to our co-founder
Lou Friedman.
He's been on the NIAC external council for quite a while, but this was his last year.
In the meantime, here's our chief scientist, Dr. Bruce Betts in What's Up.
Hey, Bruce, I have returned from NIAC.
Hey, welcome back.
You made it.
That ain't no party like a NIAC party.
I'm kidding.
Everyone was very professional.
They do have wonderful after hours meetups.
I have not personally been invited to any NIAC ragers, but maybe it happens somewhere
in history.
Maybe.
But yeah, there are some really good projects this year, but I was really impressed with
Lynn Rothschild because she's the first person to ever have a phase one, phase two, and phase
three project all in the same year.
No pressure.
That seems counterintuitive.
Yeah, that's a lot.
That's a lot of projects going on all at once, but they're all really cool.
Oh, they're different projects.
Oh, yeah.
All different projects.
That makes so much more sense.
Yeah.
I mean, the phase three project was about microtexture and creating habitats on the
moon and Mars using basically mushrooms, like mycelia, to help seal things together.
But personally, my favorite project of hers is the mobile astro
pharmacy, where you can kind of keep little samples of things that allow you to create medicines
while you're in space on the fly. That way we can treat our astronauts if they're all the way at
Mars without the medicine that they need. I think that's really powerful, not just for space, but
also for Earth. Like how many people need medications they don't have access to?
A lot. A lot. That's the kind of technology, that's
the kind of forward thinking that just really underscores why technology advancement in
space really helps people on Earth. I mean, there's a lot of those overlapping technologies.
I mean, can you imagine life without GPS or the internet?
Yes. Yes. I remember the dark times. I lived
a little of that. Another one of my favorite projects that I spoke to Edward Balaban last
year, but again this year because the Fluidic Telescope concept moved on to its second phase.
And not that I want to get into the intricacies
of the Fluidic Telescope, but what I think is really cool about it is that we're finding new
innovative ways to be able to launch bigger and bigger telescopes into space, or to find ways to
have telescopes that are self-healing, as an example. Because, I mean, let's face it, I don't
know how we're going to get anything bigger than JWST into a rocket and launch it into space unless we're going to find a way to build rockets that
are just unachievably large.
Yeah.
Well, you got origami and apparently you got Fluidic and you got people with tin cans.
But really though, what kind of mysteries are there in planetary and exoplanetary science that would really
be helped by a huge, huge telescope or even multiple JWST-sized telescopes in space that
we just can't achieve right now?
Sorry, the concept of multiple JWSTs just kind of fried my brain for a second.
Do you think interferometry with...
Wow, that's okay. Anyway, exoplanets
is the first big answer because just like JWST is allowing us to do more and hopefully
the habitable world's observatory often 10 or 20 years will allow us to really study
exoplanets and including ones that are Earth-like and that's something you just
need some monster telescopes with serious resolution to learn more.
But there's also the old, we don't know everything that that will do for us
because there are discoveries waiting to happen once we can see them.
And so that's why every telescope advancement,
every spacecraft that goes somewhere with better instruments or somewhere new, we learn stuff.
And often we learn stuff that we didn't even know to ask the question. And that's what's cool about
it as well as a lot of other things. Yeah, science.
I mean just getting telescope time on something like JWST is really difficult and I'm sure
there are so many people that would love to get time but can't. And I think what CubeSats
did for space missions for smaller organizations and universities and people like us that wanted
to send things like
light sail into space, right? If you could find a way to allow people to have a cheap kind of
foldable modular smaller thing that can go into space and then extend, give that technology to a
bunch of universities, wow, the discoveries we could make. Yeah, although it's hard to foresee doing really giant telescopes with that analogy,
but they would do more. Maybe, maybe if your fluids and your, I don't know, what else you
got?
I mean, I just think that's cool. You make it kind of like an extendo foldable origami
style that you just put liquid on it and suddenly you got a big old telescope.
I don't know.
Wait, wait, wait.
I want to focus on you just put liquid on it.
No, just put liquid on it.
I feel like that's an oversimplification.
It definitely is.
I haven't read their research, so maybe I'm wrong.
No, you have to have very specific fluids.
They can't freeze.
They got to remain fluid in certain temperatures.
There's a lot of complexity to what they're doing there.
But I guess that's the whole point of these NIAC projects is that you take these concepts
that seem really sci-fi and out there and if you can actually make them real, you're
not always going to succeed.
But those moments where you really innovate and change things, that is powerful.
Yeah, powerful.
Well, before we move on to the random space fact, I wanted to share a comment that our longtime listener Mel Powell sent in. Because a few weeks ago, you and I were joking about
food and space and salads and how we should start a planetary society salad dressing company.
It was a total joke, but he wrote in and said that he's got the perfect name, Ensaladus.
I get it. Ensaladus, Ensaladus.
Sorry, I'm a child. I literally snort laughed. And I said that in our member community. I
was like, I'm really glad no one was here to hear me snort laugh during that. And he
said he would almost kill for a recording of that. And I would love to tell everyone that I have a bunch of ridiculous
recordings of me laughing like the child I am.
Well, you should start a separate podcast that has no words. That's just you snort
laughing.
Oh man. That would be a weird ASMR, but you know, snort laughs to fall asleep to.
There you go.
Maybe, actually, maybe there's a NIAC proposal in there for that.
We can probably use the frequencies of the snort laughs to, I don't know.
You'll figure it out.
All right.
So before I embarrass myself any further, what is our random space fact this week?
Let me embarrass myself. Thank you.
Uh, space fact.
So, uh, Europa Clipper, our friend coming up on launching, doing this awesome mission,
the launch mass, that's the dry mass and the wet mass as they call it. So the fuel and the spacecraft,
not the rocket and stuff, the spacecraft and what it's carrying on board of the Europa Clipper spacecraft is about
the same as the mass of a large African bush elephant, the largest land mammal on earth.
Yep, I do not think I could lift that.
No, no, I don't think, I mean, no.
Okay, well, thanks.
Anyway, it's big, it's massive, it's Europa Clipper, and it's going to Europa.
And that includes the ginormous solar panels they put on there?
Yes, it does.
Okay, that makes sense because I feel like that's most of the...
Spacecraft launch mass.
That's cool.
Yes, those...
It was quite startling actually seeing those things on the spacecraft after seeing it as
this tiny thing for a while and just like as artistry, little artistic renditions online.
But most of those images have a hard time actually showing the entire span of the solar
panels on it just span of the solar panels
on it just because of the angles they're taking it at.
They're literally that big.
About the length of a basketball court.
Yikes.
There you go.
Oh, if this thing works.
All right.
All right, everybody, go out there, look in the night sky, and you think about names for
space salad dressings. Thank you and good night.
We've reached the end of this week's episode of Planetary Radio, but we'll be back next
week with more of the 2024 NIAC Symposium. I'm excited to share one of the amazing projects
that hopes to screen water on Mars for evidence of extant and introduced life.
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Thank you so much to everyone in our member community that asked for a second episode of NIAC.
I'm gonna be doing some more in-depth interviews with other NIAC fellows in
the future so keep an eye out. Planetary Radio is produced by the Planetary
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