The Dr. Hyman Show - How Stem Cells Can Reprogram Our Biology To Create A Younger You with Dr. Bob Hariri
Episode Date: July 5, 2023This episode is brought to you by Rupa Health, ButcherBox, Pendulum, and Apollo. I don’t just want to live a long life, I want to feel good while I’m doing it. That’s why I’m always interest...ed in the latest therapies to slow the aging process. Stem cells are one of those therapies that have been gaining a lot of traction for reducing nerve and muscle pain, improving the appearance and health of hair and skin, and even increasing sexual vitality. Today on The Doctor’s Farmacy, I’m excited to talk to Dr. Bob Hariri about stem cell therapy and how it’s changing the field of aging science and the future of human health. Dr. Bob Hariri is an accomplished surgeon, biomedical scientist, and serial entrepreneur in two technology sectors, biomedicine, and aerospace. He is the chairperson, founder, and chief executive officer of Celularity, Inc., one of the world’s leading human cellular therapeutics companies. Dr. Hariri pioneered the use of stem cells to treat a range of life-threatening human diseases. He holds over 170 issued and pending patents for discoveries, including placenta-derived stem cells, which Nature recognized as one of the ten most important patent estates in the field. He has authored over 150 published chapters, articles, and abstracts. This episode is brought to you by Rupa Health, ButcherBox, Pendulum, and Apollo. Rupa Health is a place where Functional Medicine practitioners can access more than 3,000 specialty lab tests from over 35 labs. You can check out a free, live demo with a Q&A or create an account at RupaHealth.com. Right now ButcherBox has a special offer: new members can get New York strip steaks for a year PLUS $20 off your first order at Butcherbox.com/farmacy with code FARMACY. Pendulum is offering my listeners 20% off their first month of an Akkermansia subscription with code HYMAN at Pendulumlife.com. Apollo was designed by neuroscientists and physicians to tap into your body's natural rhythms to bring calm and focus and restore equilibrium to your nervous system. You can check out the Apollo wearable and save $40 by visiting apolloneuro.com/drhyman. Here are more details from our interview (audio version / Apple Subscriber version): Three things people commonly do to shorten lifespan (6:07 / 3:40) Why stem cells are so remarkable (10:20 / 7:52) Retrieving and injecting stem cells into the body (15:07 / 12:40) Embryonic and placental stem cells (19:47 / 16:46) Capabilities of injected stem cells (28:14 / 24:12) Reprogramming your biology for a younger you (35:50 / 31:20) Cell therapies beyond stem cells (52:05 / 47:33) Natural killer cells (55:28 / 50:54) Tips for healthy aging (1:15:15 / 1:10) Learn more at celularity.com and check out pilotinghealth.com.
Transcript
Discussion (0)
Coming up on this episode of The Doctor's Pharmacy.
So when you deliver a stem cell to a site like the liver,
it is capable of restoring any of the corrupted software in that organ and tissue.
Hey everyone, it's Dr. Mark.
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pharmacy to receive two pounds of ground beef plus $20 off. And now let's get back to this
week's episode of The Doctor's Pharmacy. Welcome to The Doctor's Pharmacy. I'm Dr. Mark Hyman. That's Pharmacy. I have a place for
conversations that matter. If you care about living a long and healthy life, this is going
to be an important podcast for you because we're talking about stem cells and cell therapy, which
is really the future of medicine. It's something you might have heard about but probably don't
understand too well, including me. So I'm going to be on this ride with you. I'm excited to have as our
guest today, Dr. Bob Ferrari, who's an accomplished surgeon. He's a biomedical scientist. He's a pilot,
flies jets. He's a serial entrepreneur in two different sectors, biomedicine and aerospace.
He's a chairperson and founder and chief executive officer of Cellularity, which is one of the world's leading human cellular therapeutics companies.
He's also pioneered the use of stem cells to treat a whole range of life-threatening diseases.
He's most recognized for his discovery of pluripotent stem cells derived.
And what that means is basically a stem cell that can become anything that are derived from human placenta. And as a member of the team that discovered one of the most important cytokines we've
heard about called tumor necrosis factor alpha, which is a lot of the therapies, for example,
around autoimmune disease are focusing on shutting that down, which is helpful, but
has problems.
Now, he holds over 170 different patents and pending patents for discoveries, including
placental derived stem cells.
Nature recognized that as one of the most prestigious medical journals.
Nature recognized that as one of the 10 most important patent developments in the field.
He's offered over 150 published papers, chapters, articles, abstracts.
And like I said, when he's not working in the lab or in the boardroom, he's flying his jets
and did all kinds of cool stuff.
He's produced documentaries. So, Bob, I'm really excited to have you on this podcast.
Well, Mark, I can't thank you enough for inviting me, and it's great to see you. You look fantastic.
Oh, thank you. Thank you. So, we're going to get into all the nitty-gritty of stem cells,
what they are, what they do, what the options are, how they can be used, and basically kind
of unpack why this is such an
important part of the future of healthcare and medicine. But, you know, first, I kind of want
to just sort of highlight the fact that medicine for the last 100 years has been focused on trying
to shut down or stop or interfere or block some process in the body using medications.
And they've been helpful, but the body has this extraordinary healing power,
this innate intelligence, this capacity for regeneration, renewal, and repair
that we have yet to unlock.
And so we're going to talk about what that power is
through the concept of cell therapy, which is what you pioneered.
And it's something that I think most people don't understand we actually have within us.
So like Dorothy in her ruby red slippers, you've clicked her heels three times and she'd go back
to Kansas if she wanted any time. She just didn't know it. And I feel like that's where we are now
in medicine. We have locked within us these innate longevity pathways, these switches,
these systems that we can
activate. And that's what we're going to get into today through the power of understanding
stem cells and cell therapy. But before I do, Bob, I want to ask you about how we can kind of
learn from what's happened in the last bunch of years around the research around longevity and
healthy aging, because we have so many different therapies, techniques, knowledge, technology,
but we're sicker than ever.
And the question is, what are the three things in your perspective that people are doing every day to shorten their lifespan?
Like, let's start with the end in mind here.
What are the people doing to screw themselves up?
You know, you set this up for me beautifully because we all know that despite all of the tools people have, nutritional tools, tools to improve their
exercise and performance, we still are suffering from many of the same chronic conditions that
erode our quality of life, erode our performance as we age. And I'll take the point of saying that
the things that we do wrong are affecting the fundamental toolkit we have resident in our body
that is grounded in
these remarkable cells, stem cells, that as you kind of alluded to, are there to continually
repair and renew and renovate your body during your lifetime. So if you ask me what the three
things are that I think people are doing wrong, Well, first and foremost, there's no doubt that
the way we fuel ourselves through what we eat, what we consume, that nutritional platform,
if it contains certain things, and obviously there's a lot of attention being paid to
preservatives and other chemicals that are not necessarily natural. And there's no doubt that
those chemicals are a burden. You know, our body is designed to accommodate for foreign chemicals.
But when those chemicals have an impact on the genetic material, the programming of our cells,
or if they in some way disrupt the normal metabolic processes, your cells suffer. Your
mature specialized cells that make up your body
suffer, but your stem cell population suffers also. So it's like if I have a component of brand
new, unadulterated, uncorrupted cells laying in wait to fix me, and I'm damaging them every day
with what I put in my body, that's not a good thing. So we all know excessive sugar, processed
sugar, processed carbohydrates are incredibly damaging for more than what people would think.
In addition, in addition, using, eating processed foods, using nutritional supplements that are
coming from really a chemical factory rather than from nature clearly, clearly has a negative effect. Stress,
you know, people don't recognize how important the neuroimmune axis is. And the immune system
can be thought of as a giant stem cell factory and a giant stem cell repository. So things we do to
create a signaling from the nervous system to your immune system, that also has chronic effects
that are cumulative over time. So stress, avoiding stress is essential. And then, you know, the target
that you and I both care a lot about, one of the most actionable areas we have to preserve our health
is to take care of our skeletal muscle tissue. Maintaining healthy skeletal muscle is essential.
And there's lots of reasons for it.
You know, aside from the fact that what we generally think the muscular system is for,
force generation, right, mobility.
Locomotion, yeah.
Locomotion.
The fact is, the fact is your muscle is the largest wet body mass of your body
compared to everything else, which means it's the largest
venous capacitance organ in the body. And what does that mean? It means that the stuff that
circulates around your immune cells and your stem cells take up kind of transient residence there.
And so by having healthy muscle and by working your healthy muscle, you're helping to mobilize
and traffic those cells into
your body. And that's how we effectuate the repair and renewal and renovation process that keeps us
young. So, you know, nutritional issues, stress, and clearly declining muscle mass, I think are
big problems. Cut out processed foods, starch and sugar, deal with stress differently, learn how to
kind of regulate our nervous systems through a whole variety of techniques,
and make sure you build and keep your muscle as you age.
I 100% agree, and those are the things we're not doing as a society.
You know, I think before we sort of get into the nitty-gritty of what all these things do,
what the heck are stem cells?
Why do we have them?
Like, what's the big hullabaloo about this?
Why is everybody talking about it? And why is this the promise of the future of medicine?
So, you know, I'll take you back to when I first heard the term stem cell. This is way back in the
80s when I was training as a surgeon at Cornell in New York, and my area of interest was trauma
and how to take care of severe head and spinal cord injury, stem cells hit the airwaves as
this remarkable discovery that, and we all kind of knew about this.
You remember from our embryology courses in medical school, we all knew that every human
being originates as a single cell.
And that single cell is created by the fertilization of the egg by the
sperm, which means it is a composite of the DNA of your parents, your mother and your father.
That single cell has to give rise to ultimately trillions upon trillions of cells that take on
very specialized form and function. Now, if you think about this, right, every cell in the body of every human
being, regardless of their age, had its origins way back in the placenta. And when I first heard
about stem cells, I said, wow, the fact that these cells retain their versatility, their ability to
mature and specialize into any very, very specific form of a cell, like a brain cell or a heart
cell or a bone cell, the ability to kind of be a utility infielder and decide you're going
to become a brain cell or a heart cell is driven by signaling that occurs at the site
of the tissue or organ that calls upon this repair and renewal process. So, you know,
every human being is about 25, 30 trillion cells. Think about this for a second. From a single cell,
you're producing tens of trillions of cells, and those cells are continually being renewed in your
body during your lifetime. So during a lifetime, you may actually make, you know, 100, 500, 1,000 trillion cells, and that's all originating in a
single cell. So think about the replicative integrity and fidelity of a single cell that
can give rise to cells that keep giving rise to other cells, each one of them capable of
performing the function and having the features of that specialized tissue. So stem cells, each one of them capable of performing the function and having the features of that
specialized tissue. So stem cells, first and foremost, are incredibly important because none
of us would exist without them. They are what builds us, you know, and we often make the joke
that the placenta is nature's 3D printer that prints the baby. And that's kind of a good way
to think about it. But many years ago, when I tried to dissect all of this and figure out what does it mean,
you know Arnie Kaplan, the father of mesenchymal stem cells.
Arnie and I were talking, and I combined some of the things I learned from him
and some of the stuff I learned from Craig Venter, the genomics guru,
who was the first scientist to sequence the human genome.
And I put two and two together and said, you know, what a stem cell really seems to me to be a lot alike is a master boot disk that you're using to renew and restore the functions of the information system in your body.
So if I take a second.
All the young people listening probably don't even know what you're talking about, because in the old days of computers, you'd get a disk you'd have to keep in your drawer.
And if your computer went on the fridge, you'd have to put it in and reboot it from the
original software. That's a good point. I probably have no idea what I'm talking about. But, you know, it is funny, though, right? We know that even the best software running in the best computer, over time, being used and being used, it gets glitch DNA is our biological software. It's a programming language. And Arnie Kaplan
said, you know, your stem cells are basically the delivery system for information. So if you put
those two things together, a stem cell has the full complement of biological information stored
in that DNA in an uncorrupted form. So when you deliver a stem cell
to a site like the liver, it is capable of restoring any of the corrupted software in that
organ and tissue. And so that's how I think about it. I think about it as a master boot disk that
can be used to recover the quality of that information, which is necessary for everything in biology.
So the stem cells are coming from your bone marrow. They're coming from your fat tissue.
You can get them from placental stem cells. You can get them from umbilical cord stem cells.
And then they can be injected into your venous system just directly throughout your whole body
systemically, or they can be directed to a particular organ,
like your heart or your liver or joint.
When you inject them,
are they actually then becoming that new tissue or are they just secreting
compounds by exosomes,
which are these little packets or vesicles of information within the stem
cells that then help the body to repair and renew?
So is it a direct sort of like
becoming of something or is it actually just providing all the kind of medicines that the
body needs to renew itself? So you're asking a really important question. So the way I look at
it is when we are built, when we are going through the process of embryogenesis and fetogenesis to create the newborn baby, that newborn baby has every specialized cell type we need in our mature
functioning system. So the cells that go on to build the liver of a newborn will be the source
of cells to continually renew that liver during our lifetime. That's done not by the cells that you're born with in that
specialized tissue, but by the cells that are resident there in this versatile stem cell form,
which get called upon to repair and renovate the tissue. And so, you know, when you kind of
consider that when we're 100, we want to have a liver and a brain and a heart that have the elements that build that particular organ and tissue that are of the highest quality.
As long as you have a healthy, uncorrupted population of stem cells in your organs and tissues, and you point it out, you can get them pretty much anywhere, right?
You can find them in fat.
You can find them in bone marrow.
Clearly, you can find them in other sources. As long as you have a good complement of those cells
in an uncorrupted form, they will repair you and renew you to perfection each time.
The problem is our stem cells in our organs and tissues are subjected to the same things
you and I were just talking about. Bad nutritional factors, too much glucose,
chemicals we're getting in our foods, et cetera. That stuff creates a cumulative damage to the underworkings of those stem cells. And when they do the repair job that they're supposed to do,
it's not as good. It's like I sometimes say that you're renovating a house if you have if you have kept all the starting materials all the tile and all the woodwork and all the materials that you
built that house with originally and they're in perfect form when you renovate your house it's
going to look perfect but if that material is not perfect and you're kind of renovating with
imperfect materials it shows same thing happens in the body. So in a sense, if you then are damaging your stem cells as we age, we don't have that same
reparative capacity. And one of the hallmarks of aging, there was nine, and I put 10 in my book,
because I had the microbiome, and then there's another few that got added.
The stem cell exhaustion is one part of
the hallmarks of aging and so what you're talking about is all the trials and tribulations we go
through throughout our life the crappy food we eat the lack of exercise the stresses the lack of
sleep environmental toxins nutritional deficiencies all of this does a job on our stem cells and so we
get pooped out stem cells and this is really where where then
your work is going which is because i mean and i've had this done you suck out your fat tissue
with liposuction you get a bone marrow biopsy you suck out the bone marrow it's a painful
expensive procedure you then have to try to culture the stem cells you can't do that in
america so you have to send them to panama or you have to send them to Costa Rica. They have to kind of go back there to do it. And it costs a ton of money.
But you're saying essentially, if I do that, I'm getting my old stem cell. I'm getting my
Dr. Mark Hyman's 63-year-old stem cells. But you created a model where you can get
foreign stem cells, but without the problem of rejection, which is what happens when you get
some foreign tissue from the placenta or potentially umbilical cord, and you pioneered this model of placental stem cells, the question I have
for you is when you inject those, let's say I inject them into my body, let's say tomorrow I
get a big load of 200 million stem cells and I just shoot them in my vein, what's happening when
I do that? Versus, for example, what's happening when I inject into my liver or my knee if it's
problematic, fibroarthritis, for example? So if you understand the concept that our ability to
repair ourselves and rebuild ourselves is dependent upon these stem cells, and these stem
cells are fragile and are potentially perishable, then the concept that we had many, many years ago
was where could we possibly find high-quality stem cells that could be delivered one size fits all without the need to match the donor to the recipient?
And could those stem cells do the job of the of the patient's own stem cell population that might be corrupted? corrupted. And so it turns out that if you go back and I, we go back 30 some odd years ago,
35 years ago, when I first got interested in the field, if you remember, most of the work being
done on stem cells was being done on cells derived from the leftover embryos from a in vitro
fertilization event, or from the byproducts of an abortion, fetal material that was being discarded.
Now, you know, as a guy who's focused on trying to create tools for medicine, the concept of using those sources had problems. And aside from the ethical and moral dilemma around using embryos or fetal material, which I didn't really, that wasn't my primary concern.
My concern was, could you guarantee the quality of stem cells from those sources
was good enough to be turned into a living medicine? And so my thought at the time was,
well, sure, why not? Probably. But what we learned was that, particularly with abandoned embryos,
that at the stage of development that you isolate stem cells from an embryo,
which is at the blastocyst stage, it's very early in development,
that particular stem cell may or may not be of the quality necessary to be healthy years and years later.
What I mean by that is this. Only one out of every four or five
conception events where you create an embryo actually is qualitatively good enough to go
all the way to a full-term pregnancy. That's why we have early miscarriages, the late period,
et cetera. That's because the genetic material that makes up that first fertilized egg that becomes an embryo doesn't necessarily have everything perfect.
And so nature clears that out.
So the term I often use, if you get stem cells that have made it all the way through pregnancy and produced a healthy newborn, it's gone through nature's quality control process. And so what you have is you have a cell that's capable of creating a
healthy newborn human, and it hasn't been affected by any of the outside effects, radiation,
chemicals, et cetera. So it's about in the best possible biological state it'll ever be.
And so that was the driving force for me saying, well, we need to find a resource
that's renewable, reliable, scalable in order to turn living cells into medicines.
And I give my oldest daughter credit for this. My oldest daughter, who is, I'm incredibly lucky,
she works for me in my business development team and she's
absolutely brilliant. When she was in utero, she taught me lessons even back then. So I was a young
surgeon. I went down to the L&D suite to look at the ultrasound of my developing newborn.
And for the first time, Mark, you know what? It dawned on me when I looked at the ultrasound that
although she was a peanut-sized embryo,
the placenta was already a big organ.
And as an engineer by training, I said, well, wait a second.
In medical school, remember, we were taught the placenta is kind of a vascular interface
between the mom and the developing baby, right?
If that was true, they would grow at the same rate.
So the placenta would be this little tiny organ next to the little peanut-sized embryo. The fact that it's already developed into a significant organ means, or meant to me at least,
that it's the governor or it's controlling the development of the embryo and the fetus. And if
that's the case, why? And so at the same time, I'm hearing about stem cells, and I know that
they come in embryos, and you can find them in fetal material. I said, well, maybe the placenta is this big organ because it is a stem cell factory. And so,
you know, back in the 80s, I started collecting placentas and taking them apart. And lo and behold,
lo and behold, found out, Mark, that the placenta is designed as a giant bioreactor.
It's designed to propagate, differentiate, which means to
specialize, and then trap itself, probably in the participation of the development of the newborn.
But clearly, at the end of that pregnancy, all those cells are left over in the organ.
And so what happens after the baby's born? The placenta is expelled, usually when no one's
looking, right? You know, the doctor's off kind of, you know, with the baby. And all of a sudden,
after a few minutes after birth, the placenta detaches and is expelled, and it's discarded
as a waste material. So, you know, back in the 80s, I started questioning, well, what if I could
collect these placentas after birth and isolate the cells. And so that's how this all
originated. And the cells from placenta, yeah, and the cells from the placenta, number one,
are incredibly abundant. From one placenta, we can recover billions of cells. And think about it,
right? It's the most incredibly controllable environment for collecting a raw material.
You know when the pregnancy is occurring.
You can screen the donors through the mom and dad,
and you can create the system for procuring the organ at the moment of birth
under full informed consent with all the medical history of the parents
and being able to discriminate whether or not the underlying donor quality will be good
enough.
And so that's what led to us creating a system to collect placentas, isolate the cells from
the placentas, and isolate all the other biologically meaningful materials to turn them into therapeutic
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dr hyman and now let's get back to this episode of the doctor's pharmacy so so when when you when
you've gotten these stem cells and you inject them like i said do they do they go and become
a part of your new cartilage in your knee or do they help repair your liver if your liver is
damaged or is it because of what it's secreting in the body? Is the actual stem cells redeveloping
into a new part that you have or that you need? So that's really the perfect question to explain
the complexity of what these cells can do.
So first and foremost, we know from bone marrow transplantation, right, that stem cells can
actually go in and totally replace and remodel an organ like the bone marrow.
What that means is that they go in and they either fill a gap because the cells there
are missing or they're dying or they're diseased,
or you can assist that process in bone marrow transplantation by wiping out the bone marrow
using chemotherapy or radiation. And now you have fresh, fertile environment for these cells to take
up residence. And what they do is they traffic, once you inject them into the peripheral vein, they're in your body's
circulatory system. They traffic to a whole range of different places and they know where they are.
It's funny. Stem cells have the ability when they take up residence in a discrete location,
like the liver or the lung, they know from the underlying, what we call the
basement membrane of the particular tissue, they know where they are. And what that means is that
I can inject the stem cell into my vein in my arm, the stem cells that get to my liver will become,
they will differentiate and mature in an appropriate way and they'll become liver cells.
They're not going to become bone cells. And that is what is the precision of cellular medicine. We don't have to necessarily put them
in a discrete location. They'll find their way. And when they get there, they do what they're
supposed to do as nature designed. And that means that, you know, if I get, if I have a patient
who's got, for example, liver damage as a consequence of their treatment for cancer, their chemotherapy or whatnot,
if I give an intravenous infusion of stem cells meant to and renew our tissues in an appropriate way is fundamental to stem cells.
But if I, for example, I have a bad knee and I just inject into my vein, I can't imagine it's going to work as well as if I inject it right into my knee or my shoulder if I have a shoulder injury. So that's the issue more about sort of dose and what's an effective dose that you need for a specific therapeutic effect. So for example,
if you want to, there's no doubt that intravenously administered stem cells will, some of them will
find their way to your damaged knee. They'll follow the signaling, the signaling that comes
from the damaged knee and they'll say, hey, wait a second, we got to go there because there's inflammation or there's injury and there's a need to repair. But in order
to get enough cells concentrated where you want, we find that you can deliver them not just
systemically, but also you can deliver them locally. And you're absolutely right. If you
know that the problem you want to deal with is your bad knee, not only is local delivery into the joint space going to be useful, but if you couple that with systemic administration, you can augment the overall benefit.
And that's what we're learning in cell therapy now.
It's like both and.
And you know what?
And you know, it's funny.
In cellular medicine, a lot of people think that it's a one-shot deal, right? I've never, never embraced that concept. I believe that cellular
medicine has to be delivered with a relative dose and frequency necessary to sustain the benefit,
the medical benefit. So for example, if you were having your knee fixed,
we'd want to get enough cells into your joint to help, number one,
control the inflammatory process and turn back on the repair process,
participate in the repair, and then lastly,
you want them to stick around long enough to create a stable,
homeostatically normal tissue in your joint.
And that may mean, because the reason your knee's
bothering you is you're probably working out too hard and you're damaging it, right? And by
monitoring the effect, and then when the negative effect comes back, will allow you to create a
rationale for retreating patients. And that's where I think cell therapy is ultimately going
to find its place in the field of sort of performance and longevity medicine.
Yeah. And so in terms of longevity and aging, I mean, right now, you have a company that
calls Cellularity that produces placental stem cells, but are they allowed to be provided in
the United States? Can people get them? Is this something you only can do out of the country?
Can you grow them?
How does the legal situation work now with people who are interested?
So Cellularity is the company that sort of pioneered the use of the placenta as a source of cells for this emerging field.
If you remember, if you go back 20, 25 years, cell therapy was considered to be the cornerstone of regenerative medicine.
And most of the thought of applications were to use these cells to treat degenerative diseases.
What we learned over the last 10, 15 years is that if you can produce mature cells of a specific type, like of the immune system, you can focus the activity and the use of those cells in a discrete condition.
So the biggest breakthroughs
that have occurred in stem cells that have gotten into patients is in immunotherapy. So, what
cellularity basically has focused on is taking this source material that can produce any cell
type and coming up with a range of clinical candidates that can be taken in to treat everything from serious cancers and
immunologic diseases to also treating some of the degenerative diseases. Now, in the United States,
all of this work, for the most part, is in development. It's in the clinical trial process.
The United States has a very, as you know, a very complicated and sophisticated regulatory system.
And what we are very much focused on is doing things that meet the standards of the regulatory community.
However, there's tremendous demand for self-therapies for things like you just mentioned, treating a damaged knee, shoulder, et cetera. So what's happened is
other jurisdictions, other countries, other regulatory systems, in some cases, have taken
the sort of progressive position of saying, you know what, we're satisfied, we know enough about
the fundamental safety of these products, we'll allow them to be used in either a provisional way,
like in places like Japan, where they have provisional way, like in places like Japan where they have provisional
approvals, or in Panama where actual approval to use cells from newborns from umbilical cord
are allowed for the treatment of patients. And so, you know, listen, not every country
follows the same fundamental architecture of a regular system. So let's face it, there's people who recognize they can go elsewhere
to get treated, and that's what they do. So let's talk about now how those can be used for
longevity. What is the effect and what does the science tell us about how we can literally
reprogram our biology to a younger you? We've talked about in the podcast how we can reverse
our biological age, how it's not static, that we can now use different interventions to reprogram our biology through epigenetic reprogramming and through cell therapy, stem cells and exosomes. improving our overall health, improving our function, preventing chronic diseases like
heart disease and diabetes and Alzheimer's and cancer. Can you talk about how they play a role
in all that and where this is all going? So I think a fundamental objective in the
longevity world is to replace anything that's damaged or defective that has occurred as a consequence of the aging
process with as healthy and as young and as vital a replacement cell as possible. Now, when your
stem cell population is in good quality, it does its job pretty effectively. But let's face it,
there's nothing better than a cell that's recovered from a newborn and is delivered
in that kind of newborn form. Now, there's some characteristics of stem cells that are important.
We've learned that this characteristic of stemness, which means the cell is incredibly
capable of versatile specialization, which means simply enough that that particular cell can transcribe, can read
and follow the recipe that exists in your DNA perfectly. So if you think about it, we got 25,000
genes, roughly something like that. What happens in the process of stem cell differentiation to a mature cell is a series of gene silencing events.
What that means is that to go from a stem cell to a mature cholinergic neuron, a specialized neuron
that makes a specialized chemical, to go there, it's a series of cell divisions where part of
the genetic material is isolated from being transcribed or read.
What that yields is it yields a cell that is highly efficient in reading just the genes necessary for that mature, specialized form.
Now, that's great, but what it means is it shuts the stem cell's versatility down.
So you can shut down the versatility of the cell by the differentiation process.
But as you mentioned before, as we age, we're corrupting the stem cell population in our body.
So what that calls for is, hey, if my stem cells at 70 or 80 aren't as good as newborn stem cells, but I could get replacement stem cells that are newborn, that are compatible with me,
that can actually replace what's missing. Now, that's spectacular. That means I have a brand
new replacement part. The analogy I mentioned before, if I need to replace a hydraulic pump
on my airplane, it's a lot better for me to replace it with a brand new hydraulic pump
than to
get a remanufactured one or a refurbished one. Same thing exists in biology. If we can
replace the cells in our body with pristine, uncorrupted stem cells that take on the specialized
role, they will perform better than my original cells. So that's number one.
Number two, here's the other really cool thing.
You know what chimerism is. Chimerism is when a single individual, single organism carries more than one set of instructions, more than one genome. It turns out that chimerism,
where you put more than one specific genome into one organism, natural selection takes over and the traits that are
selectively advantageous to the individual in that stem cell will get upregulated.
And so chimerism has the potential to give you the same benefits of something called
hybrid vigor.
Hybrid vigor is mom and dad are genetically distinct.
They come together to form
the offspring. That offspring has a set of genes that are better than the individual sets of genes
from the parents. That's hybrid vigor. Hybrid vigor occurs between generations. But chimeric
vigor would be that if I give you a cell that has got a different set of instructions,
and some of those instructions protect you from something you're vulnerable to,
that will get upregulated and expressed.
Darwinian natural selection takes place within the body as well as between bodies,
between different individuals.
And so the way I look at it is stem cell therapy is incredibly powerful as a way to replace the defective, deficient cells in your body, but also to augment the capabilities of those cells by giving you a range of different genetic instructions. And so it'll basically help turn back your biological clock if you get an injection of
a certain number of placental stem cells.
Is it once a year or twice a year?
What should people be thinking?
If they, let's say one day on the road, it becomes affordable for most people.
What would be a regimen that you would recommend that would help people to help rejuvenate
their biology, to reverse chronic disease, to increase their health span and their
lifespan. Now, how are you thinking about this as you're sort of looking down the road towards
the future? So some of the things that are necessary for us to do now is to understand
the dose and the frequency that you will need to get these newborn stem cells in order to
effectuate the benefits we've been talking about.
So if you think about it, and this is something to consider, when we first thought stem cells
may be at the corner, at the heart of why we age, damage to our stem cells or defective
stem cells might be at the heart of that.
We did an experiment. We did a little skunk works experiment. We collected stem cells from rats at
birth from their placentas. We processed them and froze them away, cryopreserved them. And then we
gave the animals back doses of their own stem cells every month after they reached sexual maturity.
And what we saw, what we saw was really pretty cool. The animals
who got back their own stem cell, because they were collected and stored at birth, actually lived
40% longer than their litter mates. Yeah. And it was just simple replacement or augmenting their
system with these newborn stem cells. Now, what's the dose and what's the frequency for humans?
That's the stuff we got to work out. And so that's going to be understood better through the
clinical programs, clinical trials that we do. But I would suspect that if you think about the
lifespan of a stem cell in your body, we'll figure out the interval based upon how long that stem cell remains in its
perfect form. And then when that starts to degrade, you just give you another dose of those newborn
cells. Now, this is also... So this would be if you took your own cells at birth. So if anybody
born today should have their umbilical cord cells frozen, right? They're placental cells. That is the heart of which has created them.
That's the easiest, most actionable way to store away that starting material for later
use in life.
Short of that, like I was born in 1959.
I don't think anybody rehearsed themselves back then.
Do I have to rely on placental stem cells?
And is that safe?
And could that be as effective, you think?
So here's the cool thing about the placenta.
Aside from all the great features we've been talking about, the placenta is nature's professional universal donor tissue.
And let me explain that, okay?
A placenta, as we talked about, is made up of cells that are created from the original fertilized egg, which is the combination of mom and dad's DNA.
All that tissue makes up the placenta and the developing fetus.
So it's only a 50% match to mom.
Mom carries it for nine months without an immunologic conflict.
Okay?
So you know that if you want to transplant an
organ, you want to match the organ between the donor and the recipient. But think about this.
But think about this. In surrogate pregnancy, a mother's not even related to the fetus and
placenta she carries. She doesn't reject it. So the placenta has this incredible ability
to induce a state of immune tolerance, okay? Which means that any cell from any placenta has this incredible ability to induce a state of immune tolerance, okay,
which means that any cell from any placenta can be given to any recipient unmatched without
the fear of an aggressive immune rejection phenomenon.
So those cells have suppressed expression of certain things which identify them as foreign. And they also
release factors that tell the host immune system, hey, I'm okay, you can allow me in.
The beauty of that means that what we do at Cellularity, which is to produce high quality
stem cells from placentas, is that we have a one-size-fits-all medicine, biological living medicine.
And that's where the future holds promise for you and me.
And by the way, we're the same vintage, right?
We're in the last of the 50s, guys.
The fact is that we can receive stem cells from an unrelated placental donor, and they will provide benefits to us even though they're not our own cells.
So this unique…
It works as well, you think, as my own cells.
If I took those placental cells and I injected 100 million or 200 million on a regular basis, that I could have the same effect as they did in the mice?
Is that what you're thinking? I think that not only is the promise that they'll be as effective, they may in fact be more effective
than your own cells. And the reason being, if the donor happens to have a set of genes that you
don't have, and those genes confer a benefit, like resistance to Alzheimer's disease, or resistance
to heart disease, or resistance to metabolic syndrome. Oh, I'll give you a perfect example. I'll give you a perfect example.
We now know that in our population, roughly 4% of the population is resistant to developing HIV.
Okay. They can't develop HIV because they don't express, they don't have a gene to express a molecule called CCR5. CCR5 is a molecule on the
surface of white blood cells that the HIV virus has to dock onto in order to infect the cell.
So if you don't express CCR5, if you're a CCR5 knockout, which occurs naturally in the population,
you will not get disease from HIV. Now, if you take a donor who's CCR5 negative,
and you take their stem cells and put them into an HIV positive patient, it's now been shown you
can convert that HIV positive patient to HIV negative. That's chimeric therapy. What you've
done is you've basically taken a small percentage of that individual's cells and given them a
genetic superiority advantage. And that gets expressed and provides a disease resistance
that you weren't born with. So I actually think that getting stem cells from a placenta that ain't
your own is probably packed full of advantages that you don't get from your own cells.
And what would people notice?
Like let's say I decided I want to spend the money and get my placental stem cells.
What would I expect them to say?
Would I feel better?
Would I have less pain?
Would I have more energy?
Would I feel younger?
Would I have better sex drive?
Would my hair turn black?
Would my wrinkles go away?
Like what kind of stuff can we expect?
I'm asking that because I want to talk a little bit about the Yamanaka factors and epigenetic programming. So we'll get to that, but I kind of want to push you on this.
What would I see? So what we know from the various clinic environments around the world,
you mentioned places like Panama, Costa Rica, Eastern Europe, Asia. What we have found is that
patients who receive stem cells derived
from newborn material, umbilical cord blood, umbilical cord tissue, the placenta, et cetera,
usually express that they see some very common phenomena after being treated.
Among those things, stem cells, particularly newborn stem cells, are really good at controlling
inflammation. And so the anti-inflammatory properties are associated with reduction in pain,
improvement in certain functions of tissues like your joints. They also find that there's kind of
generalized improvement over time in the way your body is renewing itself. So one of
the most common things that was seen, even in the bone marrow transplant community, is that patients
who got stem cells from a younger donor would often say, you know what? Yeah, my cancer was
controlled by that stem cell transplant, but you know, my hair is thicker, my nails are better,
my skin is younger. Oh, you know, I used to have GERD. I used to have reflux.
That went away. So people will often, often express that they see generalized improvements in things that started to go wrong as they age. And by the way, one of the most exciting and lucrative places to use all of this is in the aesthetics world,
where we already know that our skin starts to change as we age because it accumulates kind of the consequences of bad structural protein synthesis.
I mean, wrinkles are in large part due to the collagen content of our skin and the other structural protein content
changing. You know, the plastic surgeons showed us that if you inject stem cells, even from adipose
tissue, those stem cells can kind of restore the youthful function of the skin. If you're able to
deliver cells from a brand new, young, newborn donor, we we expect and we've seen experimentally that you actually
can restore some of the functionality of those tissues back to almost a newborn state.
And it's a calculus.
It's the sigma, the sum total of the average age of every cell in our body, right?
So, you know that now we're measuring age of cells by looking at the epigenetic changes,
the methylation that's occurring to our DNA.
Methylation means that certain chemicals get attached to our genetic material. And if you measure that, you can get a sense of how old the cell, the biology of the cell
is. Now, if you think about it, newborn cells, aside from the fact that they don't have any of
those accumulated changes, they don't have the methylation of the genetic material. They don't have shortening of the telomeres on the cells, which is associated with stable cell division.
And most importantly, they have young mitochondria.
So newborn stem cells have youthful mitochondria.
So the age of a stem cell may maybe the age of the newborn, if you do the calculus, how many cells in the
recipient, if you give a billion cells, a billion newborn cells to someone who has 10 or 15 trillion
cells in their body, just do the calculus. You've changed the average age of the individual by a
certain amount. So that's one way to look at it. Interesting. Now, in terms of other cell therapies besides stem cells, people are using exosomes and natural killer cell therapy.
Can you explain what those are, how they're different, and where they would be used when you decide to use, for example, stem cells or exosomes or natural killer cells?
And I personally have had the benefit of using exosomes to deal with a lot of back issues and various injuries and trauma. So love to hear
your perspective on that. So in the quest to get access to these remarkable stem cells,
scientists, clinicians, and the general public have looked for alternatives to actual whole cell therapy. And so they have said, well,
how do stem cells effectuate the benefits we see clinically? And you mentioned it before,
the little microscopic nanovesicle nanoparticles that are broken off of stem cells that carry inside the payload, they carry information, information
in the form of genetic material like RNA.
They also carry growth factors and other small molecules and other biologic materials that
can be transferred to your cells and in cases, signal processes that are beneficial. So exosomes are kind of a
poor man's way of getting the benefits of cell therapy, but in a micro-dosable way that will
have effects, but those effects will be somewhat transient. So it's a way to deliver the power of
stem cells in a dosable manner. Are you saying that exosomes give you a short-term benefit, whereas the stem cells give you a
longer-term benefit?
That's right.
So the exosome, if the objective in using an exosome is to treat your back pain, okay,
the exosomes that are delivered that have anti-inflammatory payloads will actually lower
inflammation and give you benefits, clinical benefits, that will have an effect for a period of time.
And depending upon what the origin of your back pain is, is it a chronic injury
or was it an acute injury that you simply want to get under control?
The duration of effective exosomes will vary.
And so let's say you overdid it, you strained your back,
you have inflammation in the paraspinal muscles and maybe in the disc spaces of your vertebral column.
Exosomes will deliver the materials to control inflammation and stimulate repair.
But it'll stimulate repair by calling upon your own stem cells, okay? Exosomes also are exciting because they are a relatively scalable and
ultimately economical tool that can give you the benefits of cellular therapy without having to
deliver the living cells. So that's why there's a lot of popularity and a lot of work going on.
And by the way, you know, arguably, every cell is making exosomes
all day long. So if you have a cultivation system and you're producing cells, those cells will dump
exosomes into the soup and it can be collected and delivered as a therapeutic.
Not just stem cells, but all cells.
All cells. Stem cells are particularly good at producing exosomes for obvious reasons, right?
They're highly synthetic and so on. But you touched upon something which is near and dear
to my heart, which is what's going on in the natural killer cell world. So, you know,
we hear it all day long. All the different approaches to longevity have evolved into what are the mechanisms or the processes of dysfunctional
aging you want to correct? And one of the processes that's been well recognized is that as we age,
some of our cells become senescent. They wind up becoming defective. they accumulate problems, and they are, you know, some people, you refer to them
as zombie cells, right? And these zombie cells are kind of walking around your body, they're doing
their job, but they're doing it less and less effectively and efficiently. And eventually,
they start to do things abnormally, and that contributes to the accumulated problems we see as the signs of aging. Now, we know that the body under normal circumstances has a system to clear away those zombie cells,
those senescent cells.
And so there's an entire field called senolytic therapy where what you're trying to do,
you're trying to hasten the removal of those cells, either by stimulating a normal biologic
mechanism or by specifically killing those cells and getting them to be cleared away.
Well, nature figured out how to do this better than we do it. And the way nature does it is to
use a cell called a natural killer cell. And natural killer cells are part of what we call the innate immune system.
They are pre-programmed, they're pre-programmed to identify and destroy threats that occur
generally in biology. So when we were first studying the placenta and we were so intrigued
by this incredible organ. One of the observations
that was made was, you know, it's interesting, but one in every 1,000 women who's pregnant
has some form of cancer during pregnancy. It's a pretty high frequency. But the incidence of
a mother transmitting her cancer to a developing fetus essentially is zero, right?
I mean, there have been some ice case reports, but they're not linking the mom's cancer necessarily
to the newborn's cancer.
So we were intrigued and we asked ourselves, you know, why is it that the fetus is protected?
And obviously our attention was directed to the placenta.
So about 12, 13 years ago, I set my research team on the mission to find out what is it about the placental immune system that is defensive against the transmission of cancer. And we identified
this unique natural killer cell from the placenta.
So it's a white blood cell that is specialized to be pre-programmed to identify things that are common threats.
So what are some of those common threats?
Well, viral infections, right, fungal infections. it turns out that we learned that these newborn placental stem cells are pre-programmed to attack
and destroy cells that express things called stress antigens. So one of the things our cells do
when they're in trouble, when they're sick, is they express on the surface of the cell
molecules that signal stress. Those stress antigens actually recruit and allow natural
killer cells to target and destroy very specifically those old senescent cells.
And the mechanism is common to the way we react to viral infection, cancer, and senescent cells.
So upon that observation and discovery, we decided we were going to take placental natural killer cells
and use them as a tool in all of those clinical areas, treating viral infections, treating cancer,
treating age-related senescent cells.
And here's the beauty of it.
The NK cells are very, very well tolerated.
They can be administered by systemic infusion.
And they are really, really good at hunting down and clearing you of your senescent cell
population.
And there's a lot of work ongoing.
You've probably seen publications now. NK cells may in fact be the cornerstone of therapy to treat movement disorders
like Parkinson's disease, because it appears that they actually identified the defective cells
in the part of the brain that's damaged during, in Parkinson's disease and clean those out.
So I'm very hopeful. Yeah. So I'm really hopeful that natural killer cells
from placentas will be a tool we use to enhance the senolytic processes that cull the herd and
clean up our biology as we age. And I do, and I think we know, senolytic, effective senolytic
activity benefits us biologically. Now, are the actual natural killer cells from your body that have been cultured and grown and then given back to you, or are these coming from the placenta as well?
So if you isolate the cells from the individual, you can deliver them back and they'll have a benefit. But like we were talking about, if they're old,
if they're old cells, they may not be as effective as cells from a newborn.
The beauty about the placental natural killer cells is that we can manufacture them
to very high quality standards. We can subject them to very rigorous controls and we can deliver
them as a one size fits all product. So we've taken these natural killer cells into clinical trials in cancer,
and ultimately we want to take them into degenerative diseases
as well as age-related, senescent-related phenomena like, you know,
our hair loss, skin changes, potentially even things that occur in the brain.
But the beauty of it is that it's nature's tool, right?
This is what these cells do naturally.
This is what they're pre-programmed to do.
So we're just basically using them in their normal function.
This is exactly what I sort of said at the beginning,
is the body has its own innate healing system.
It's way smarter than our medications
and a lot of the cancer immunotherapies are actually taking advantage of the body's own
military self-defense system to help go and find and kill cancers and it's working better than any
therapies we've had for a number of different things it's not universally effective across
all cancers but it's it's very promising and you're talking about, whether it's stem cells, whether it's natural killer cells,
exosomes, these various kinds of cell therapies, they play a role in basically kind of being this
sort of globally effective therapy for all sorts of different problems, because it treats these
common underlying problems of degeneration and aging that happen in the body
that have universal causes. And so you're attacking these universal causes at the root,
whether it's inflammation, whether it's the breakdown of tissues. So you're seeing these
can be a key part of medicine in the future. Right now, it feels like these are inaccessible.
They're still part of large research trials. You can't really go and get them easily. There's clinics here and there where you can try to get them or you can go out of the country to get them. But how far are we away from having this root cause of the problem. And in many cases, nature has already developed a system to address the root cause, right?
Yeah.
I love it, man.
Nature is a lot smarter than we are, right?
Yeah, totally.
And the beauty, you know, if you have a teleological approach to things,
the beauty is evolution and the natural selection process leads to the use of those tools that are most effective, the ones
that are effective, the ones that stick around, and the next generation and the next generation
will have them. So the truth is what we're doing in cellularity and in the cellular medicine
industry is trying to produce a product that can be delivered in the
conventional healthcare system reliably, logistically, conveniently, and economically
so that we can enhance all of the systems that nature built to keep us healthy.
So at Cellularity, you know, we have spent decades, two decades on figuring out what
the placenta is all about, what we can get out of it, and what the clinical value of those cells
could be to treat some of the things we've been discussing today. Serious diseases like cancer,
all the way to improving the thickness and the quality of our hair. And I can tell you that this is now kind of the hottest game in town in many areas.
You know, there are parts of the world, the Gulf States, the Middle East, parts of Asia,
you know, clearly some areas of Eastern Europe, where a progressive receptive approach to cellular medicine
has created an explosion of applications of this technology to treat diseases.
Cellularity recognizes that the global opportunity is vast, maybe the biggest,
maybe the most lucrative opportunity in all of healthcare. But what's great about it is it's going to drive us to sort of proactive treatment rather than reactive treatment. If we know the
reason that we develop joint problems is that as we age, chronic inflammation damages our joints,
maybe what you do is you treat it before it becomes symptomatic, and you deliver a cell therapy product that helps to build your cartilage back better, control inflammation in the joint, and you never get to the point that degenerative disease actually affects your life. because it can be very proactive. And companies like ours are working to deliver these products
at scale, conveniently, and with the economics that fit the healthcare system. I'd much rather
prevent somebody from getting joint disease than have to replace them three times in their
lifetime with prosthetics. So that's the promise of cellular medicine. And I think, obviously, cellularityenta can produce tens of thousands of doses of cells.
And so the incredible scalability, the logistic ease of getting that raw material,
and the economics of it ultimately, I think, are going to help drive this to being the tool that we use proactively,
as well as reactively, you know,
in response to disease. And so, you know, the promise is enormous. That's huge. And so clearly,
proactively, it makes a lot of sense. Well, let's say your joints are already kind of beaten up and
they're telling you need a germ replacement, or you're having memory loss and you have early
dementia, or you have plaque in your arteries. Are these kinds of therapies helpful in those situations?
And how helpful?
Like, could you avoid a knee replacement?
Could you reverse plaque in your arteries?
Could you reverse the challenges and dementia that happen in the brain with inflammation?
So what I can tell you is that the mounting data is beginning to point to, yes,
cell therapy, especially cell therapy derived from newborns,
has very profound effects at controlling inflammation and stimulating normal repair.
You and I can use our personal examples. I have two horribly destroyed shoulders,
two completely destroyed rotator cuffs. And, you know, aside from the obvious, the terrible pain
and the loss of function, I was faced, you know, at a relatively young age. And, you know, this
problem started when I was 60, 61 years of age. I'm 60, like you, I'm 64 now. I think you're a
little bit younger than me. Biologically, I'm 43, but I don't know. Well, that's the important thing, man. That means your stem cells in your body are 43 or younger.
But what I realized was I was faced with a choice.
Either get a prosthetic shoulder replacement, which has significant functional limitations,
or try to control the inflammation and stabilize the joint with the use of regenerative therapy.
And so I went offshore and I got placental stem cells as well as placental derived exosomes
injected into my shoulders.
And let me tell you what my result is.
So I'm now four years after these injuries.
And I have restored a pretty profound amount of function.
But most importantly, I've done two things that are meaningful to me.
One is I've controlled the pain.
I've controlled the pain.
And you know, shoulders are terrible, right?
Can't sleep.
I mean, it's miserable.
Yeah, yeah, yeah.
So number one, I controlled the pain.
But number two, I actually showed that I can actually address the arthritis that was developing in my shoulders.
So in the shoulder that got placental cells, I actually reduced the arthritic bone spurs that
I had that were developed while my shoulder was damaged. On the exosome treated side,
I had great pain relief and I had some degree of control of arthritis,
but not as good as the cells, which gets back to the thing about dose and interval, right?
And frequency. So my intent is to go back and do this, you know, until I figure out
that there's a surgical solution that's going to work for me.
Yeah, that's great. Yeah, no, I've also had back pain for 30 years and using exosomes, it's really revolutionized
my life because I don't have this chronic low-grade back pain all the time anymore.
And it's just gone.
And I was marveling.
I've had this for so long.
And on the x-ray, my back looks pretty bad, but it's actually, I feel pretty good.
So it's kind of amazing.
Yeah, this is just such an exciting field.
And it sounds like, you know, we're in other countries are far ahead of us in the application of these therapies.
But we're getting there.
I actually was in the UEA a couple of weeks ago and I went to their stem cell research center in Abu Dhabi.
And it was just stunning the amount of work they were doing, the technology they had, the scientists they had from all over the world doing this work. And we're ahead in many areas in medicine, but this area, for some reason, there's such
fear and concern about it.
And I'm not sure why.
You know, I think hopefully the regulatory situation will improve.
You know, it's interesting.
You mentioned what happens in places where you've got progressive, youthful, risk-tolerant leadership, you know, so the, you know, Saudi Arabia, the Emirates, you know, you've got countries with really brilliant leaders who are open to advancing the state of knowledge, understanding that we're not necessarily at the point where we've perfected all this,
but it's worth the investment to explore and develop these things into tools for healthcare.
You know, so clearly the Middle East and the Gulf States are going to be important leaders here.
But similar leadership exists in Asia. I just got back from Korea. I was fortunate enough to be at a conference, the IPMC conference in Seoul with Scott Gottlieb,
the former head of the FDA, and our good friend Josh Hare from Miami.
And we talked about the breakthroughs in longevity and specifically how countries like Korea, Indonesia, Malaysia,
Japan, even China, as long as they're receptive to the use of these tools and they encourage
the scientific exploration of the activity of these products, we're going to be able to put
these in the hands of clinicians much faster than in places that are much more risk averse and basically create roadblocks to advancing the state of knowledge.
I mean, look, here's the bottom line.
Lamarck, cell therapy has been around for a long time, right?
I would argue that compared to most therapeutic tools, cell therapy is intrinsically safe.
Remember, the first bone marrow transplants using hematopoietic
stem cells from an unrelated donor into a recipient was done, you know, 40, 50 years ago.
Rudimentary technology, right? I mean, we didn't have all of the ways to assess the quality of the
cells. And to be honest with you, even the preparation of the cells for those treatments
was, you know, was done in tiny laboratories without a lot of sophisticated equipment. Today,
cell therapy products are made like pharmaceuticals. And so, I would argue that on the
basis of decades of safety, there's a rationale to be somewhat more permissive to try these in
different indications. I don't have a problem at all in the United States doing these under controlled clinical trials and so on. But if you have an
opportunity in certain jurisdictions to be a little bit more liberal with their use, why not
collect the data? Yeah, I think it's great. Well, this is amazing work, Bob. I think we're just at
the beginning of the application of these technologies. And I think as I began to sort
of really dig into the field of longevity, you know, these are the things that sort of activate the body's own repair systems,
that activate the body's own innate intelligence. It uses its own technology that's far greater than
anything doctors have ever invented and work far better. And I think we're going to see this field
continue to explode and hopefully the regulatory environment will change. But right now, people can go to other countries like Panama
or places in Asia or Costa Rica or Cayman Islands
to actually get these therapies.
And if they're struggling, they can find significant benefit.
I'm an athlete who's used them.
I've used them.
You've used them.
It's often a barrier of cost and access, and that's unfortunate.
But I think all of that's going to get sorted, and I think it'll come down in cost.
It'll be more scalable.
It'll maybe be covered by insurance.
And I think it's just an exciting moment in medicine.
Thank you so much for what you do.
I look forward to staying in touch and working with you on bringing this to more and more people.
So this is quite amazing.
Any last thoughts, Bob, on what people should
think about and know about this whole field? Well, you know, Mark, I'm a huge, huge one of
your fans. And what you've done in bringing to the presence of mind that, you know, aging isn't
an inevitability per se. Dysfunctional aging isn't an inevitability. We can address it. Like you said, guys like you and me said, why not look to what nature does and use those tools?
And why not create a very proactive approach to maintaining the quality of our lives, our performance?
And I always say healthy aging is basically four things.
It's maintaining high-performance mobility, high-performance cognition cognition, high performance immunity, and
youthful aesthetics.
Those four things are all addressable with the tools you and I know are available.
So why not pursue it aggressively?
And I'm looking forward to being in the UAE with you and other places where we can help
drive the field.
Amazing, Bob.
Well, thank you so much, everybody listening.
If you love this podcast, share it with friends and family.
I'm sure they'll love to learn about this whole new field of stem cells and cell therapy.
Leave a comment.
Maybe have you use these therapies for your own benefit and healthy love to learn.
And subscribe to every of your podcasts.
And we'll see you next week on The Doctor's Pharmacy.
Hey, everybody.
It's Dr. Hyman.
Thanks for tuning into The Doctor's Pharmacy.
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