Stem Cells & Peptides: The Secret to Reversing Chronic Pain and Aging | Dr. Adeel Khan
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November 20, 2024
TLDR: Discusses regenerative medicine approaches such as stem cells, exosomes, and gene therapy in healing chronic pain, reversing aging, and enhancing longevity with Dr. Adeel Khan. Also touches upon managing autoimmune conditions.
In this enlightening episode of The Doctor's Pharmacy, Dr. Mark Hyman engages with Dr. Adeel Khan, a pioneer in regenerative medicine, to explore the transformative potential of stem cells and peptides for reversing chronic pain, aging, and enhancing overall health.
Understanding Regenerative Medicine
Dr. Khan introduces the concept of regenerative medicine, which focuses on activating the body's innate healing systems rather than simply managing symptoms. This approach aims to restore tissue and cellular function through advanced therapies such as stem cells, exosomes, and gene therapy.
Key Concepts:
- Activation of Healing Systems: The body has natural mechanisms for repair that can be harnessed effectively.
- Functional Medicine vs. Traditional Medicine: Functional medicine emphasizes restoring optimal function rather than blocking pathways, setting the stage for regenerative treatments.
The Power of Stem Cells
What Are Stem Cells?
Stem cells possess the unique ability to replicate and differentiate into various cell types, making them critical for tissue repair. Dr. Khan explains the limitations and capabilities of different stem cell types:
- Mesenchymal Stem Cells (MSCs): Commonly used for their anti-inflammatory properties, but may not regenerate new tissue effectively.
- New Cell Types: Innovative cells known as mu-cells demonstrate superior longevity and regenerative abilities, offering promising results for patients with degenerative conditions.
Clinical Applications of Stem Cells:
- Orthopedic Treatments: Used to heal injuries and manage pain.
- Systemic Treatments: Potential benefits for conditions like ALS and heart disease by promoting healing and reducing inflammation throughout the body.
Harnessing Exosomes for Healing
Dr. Khan highlights exosomes—tiny vesicles secreted by cells that play a crucial role in cell communication. These vesicles can be isolated and injected to facilitate healing without the risks associated with whole stem cell therapies.
Benefits of Exosomes:
- Cell Signaling: They release growth factors and anti-inflammatory cytokines, creating a favorable environment for healing.
- Safety Profile: Free from DNA, making them less likely to cause adverse effects compared to traditional stem cell therapies.
Gene Therapy and Longevity
Overview of Gene Therapy
The discussion shifts to gene therapy, particularly Follistatin and Clotho gene therapies:
- Follistatin: This gene regulates muscle growth, potentially reversing age-related muscle loss, and improving overall metabolic health.
- Clotho: Known as the "thread of life," it may enhance longevity and protect against neurodegenerative diseases.
Implications for Health:
- Gene therapies demonstrate how manipulating biological processes can lead to significant improvements in quality of life and longevity.
- Both hormones can help mitigate chronic inflammation and support tissue regeneration.
Practical Applications and Insights
Dr. Hyman and Dr. Khan discuss practical considerations regarding these therapies:
- Skill and Technique: Successful outcomes rely heavily on the skill of medical practitioners performing these therapies.
- Cost and Accessibility: Current costs can be prohibitive, but advancements and economies of scale are expected to increase accessibility.
- Research and Future Directions: Ongoing research into these therapies promises to yield new clinical applications and refine existing methodologies.
Conclusion: A Glimpse into the Future of Medicine
The conversation underscores a revolutionary shift in medicine toward harnessing the body’s own power to heal. As researchers like Dr. Khan push the boundaries of regenerative medicine, the future holds great promise for managing chronic conditions effectively while enhancing quality of life.
Key Takeaways:
- Regenerative medicine represents a paradigm shift in how we approach healing and longevity.
- Stem cells, exosomes, and gene therapies are at the forefront of this movement, offering hope for chronic pain, autoimmune diseases, and age-related decline.
- As technology and understanding progress, these treatments may become widely available, transforming healthcare.
Call to Action:
For those interested in exploring these advanced therapies, staying informed through reputable sources and consulting with qualified practitioners is essential.
This discussion is not just about science fiction—it's about tangible advancements that could redefine medicine as we know it today.
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Hi, I'm Dr. Mark Hyman, a practicing physician and proponent of systems medicine. A framework to help you understand the why or the root cause of your symptoms. Welcome to the doctor's pharmacy. Every week, I bring on interesting guests to discuss the latest topics in the field of functional medicine and do a deep dive on how these topics pertain to your health. In today's episode, I have some interesting discussions with other experts in the field. So let's just jump right in.
A deal of welcome to the Dr. Saranti podcast. It's great to have you here. Last time I saw you was in Cabo, when you were about to inject me with a bunch of interesting compounds that are biological compounds they use in regenerative medicine for my disc issues, which helped tremendously. And I think you've been in the leading edge of this whole field of regenerative medicine. And I think most people don't really understand what is regenerative medicine. So why don't we start
by talking about your own story, how you went through medical training, where your frustrations were, and how you ended up in this place where you're practicing medicine that most people probably have never heard of and don't know what it is, and we're going to describe today in detail. But I think in many ways the future,
of prepare healing, renewal, longevity, managing more of the PD issues, which I've certainly used for my own body. So tell us about your journey, how you got here. And then what the heck is your gender medicine? Yeah. Yeah, no. Actually, it's funny because I watched your TED talk when I was in medical school.
And I remember you talking about depression and how you have to look at micronutrient deficiencies, the gut health, neuro inflammation. And that just, the whole concept just made so much sense to me. So you were definitely a part of the inspiration for me to pursue this. So thank you for that. And in terms of, yeah, I read your books. I read obviously Jason Bland functional
I had a lot of time to read other things, but the reason I got into it was partly because
I saw patients not always getting better and even my own mom had some medical illnesses and it was kind of frustrating when the doctors were just like, well, there's nothing else you can do. And then I started thinking deeper and obviously I came across functional medicine.
all this root cause work. And then I'm like, wait a minute, there is stuff you can do. We're just not learning about it. So then it was kind of like, why aren't we learning about it? And then you realize it's just because doctors don't know what they don't know. And that's just how medical school is. You're being taught by specialists who might be the best cardiologists at their in-depth center and they're amazing what they do amazing work.
But they don't know much beyond what they do and that's just the limitations of the knowledge and so oftentimes we're only being given one perspective which is allopathic medicine. But there it turns out there's a lot more than just allopathic medicine out there. And when you look at the totality of the research, you realize there's a lot of stuff out there that can be quite beneficial with less harm.
And that's really what drew me to this field was just because, hey, if I can do less harm for my patient and have the same benefit, why wouldn't I do that first? And that's kind of what got me into regenerative medicine because regenerative medicine is just a playoff of functional medicine, which is, you know, you're trying to restore tissue or restore
dysfunction of the cell back to normal. And now you can do that using cell therapy, gene therapy, or tissue engineering, or the combination of those three is kind of what we label as regenerative medicine.
Yeah, it's really interesting because, you know, as I think about functional medicine, it's really about how do you restore optimal function using compounds that support and enhance the body's function as opposed to interrupt block or interfere somehow. And most traditional drugs are anti-drugs, right? They're antibiotics. They're inhibitors, like these inhibitors, they're
You know, blockers, like beta blockers. So they're anti-bait inhibitors or blockers, right? And that's fine for some pathways in some medical therapies. But there's an incredible healing system built into our biology that most people are not even aware of. And when you cut your skin, how does it know what to do to repair your skin? Or when you break a bone, how does your body know what to do? Well, you have a
You have a built in healing regenerative repair renewal system. We just don't know how to activate it. And that's a lot of what functional medicine is. But regenerative medicine, you know, my understanding of it, is that it actually uses the body's own repair and healing systems to actually help facilitate repair by extracting them from biological sources and then repurposing them and putting them back into the body so they can go and do the repair and healing work without a lot of the side effects and consequences. Is that right?
Yeah, exactly. Our slogan is empowering the body's natural healing abilities. So that's what we live by. But to your point, it's not just limited to biological substances. You can even use something like bioelectricity or shockwave electrical signals that can manipulate the bodies at a cellular level to help it to heal. So essentially, it's anything really a signaling-wise that can facilitate healing or regeneration in your own body.
And that's why even peptides, in my opinion, fall into this category of progerative medicine, because a lot of them are just sending signals, especially, obviously, there are some peptides that are more regenerative in nature. They're just sending signals to help your body to heal better. And of course, there's biological substances, which we'll go into, too, but at a very high level, we're just giving your body the right tools and the right signals so it can heal in itself.
Yeah, it's exactly right. And it's really quite amazing. And it's unfortunately not accessible through traditional medicine. I've had back issues for the last 30 years because I ruptured a disc and really damaged the nerve when I was 32. And that left me with chronic limp and then chronic back pain as a result of changed biomechanics. And I sort of managed it with yoga and stretching and massage and sort of managed my way through.
As we got older, it's got more degenerative and there's been more issues. And I was in a place where I just was really a mess. And I looked toward regenerative medicine as a way to solve it. And I'd had steroid injections. I'd had radiofrequency ablation, which I didn't know when at the time would cause secondary consequences.
damage to my back through damaging the muscles in my back. So basically, I really struggle. And the only thing that's helped me take away my back pain are these compounds that are from this toolkit of regenerative medicine. So maybe we can sort of talk about, you know, there's two parts in my mind to regenerative medicine. One is orthopedics, basically healing and repairing trauma injury, stuff that hurts, right? And pain management. And the other is,
sort of renew a divination around various chronic illnesses or longevity that's more systemic. So there's like, you know, injecting a knee with something or they're just putting something in your veins. And then we're going to talk about both of those things. But in the, in the, in the, before we start sort of getting into the details of it, I would love to sort of run through at a high level. What are the
So tools in the toolkit of Virginia medicine, one of the kinds of things that are included in that bucket, you mentioned peptides, which are things that all of us have tens of thousands of these running around our biology that are the communication superhighway, regulating all of our biological processes.
You might have heard about Zampek, that's a peptide, insulin to peptide. You know, they're very powerful, but there are things that the body makes that we can then synthesize or extract. And then we check back into the body to help accelerate the healing. But that's just one component. So maybe you can take us through, you know, what are the kinds of tools in our toolkit that are considered regenerative medicine? Yeah, and I think that's really the key. The tools that we have now are much better than they were even five years ago. So
And regenerative medicine is moving at an accelerated rate. And that's, to your point, a lot of physicians don't understand that there's so much innovation happening in regenerative medicine. And so they still have this concept that they were taught in medical school or maybe they learned, you know, or 10 years ago when, you know, stem cells had all this hype and they don't actually end up doing anything. And so in their mind, that's what they still think. And of course, stem cells is the first one I have to talk about just because I think that's the one people always think about with regenerative medicine.
And so, stem cells is a very broad term, number one. Number one, what that means is that it's not specific to any type of nomenclature. So, if you go to a stem cell clinic, they're not specifying, what does that mean? Does that mean you're getting a stem cell from
like the fat, the bone marrow, and even if you get the stem cell, is it culture-expanded? How is it being engineered? How is it being isolated? Is it yours? This is somebody else's right. And there's so many questions that just don't go answered when you ask these clinics that, and that's a problem still to this date with a lot of the offshore clinics too, is, you know, there's all this excitement around stem cells, but at the end of the day, stem cells have two functions. You want this to self renew,
and the others who differentiate and turn into other types of tissue. So the analogy I like is it's kind of think of it like a master key and that master key can replicate itself and then it can open up different doors or it can divide and clone itself and then open up other doors that way. And so if that's a function of a stem cell in theory, then it should be able to repair tissue and
fix things in your body when we put them there, but it turns out when we take stem cells in the test tube and versus when we put them in your body, we behave differently. It's not as simple as we thought. There's a lot of different types of stem cells. Those stem cells are one of the big categories of regenerative medicine.
And so keep going around that. I'm just sort of contextually because there's a lot of other compounds that are used. There's so many. And even, but even in stem cells, I mean, you can just do a whole podcast just literally about that because stem cells are such a depth concept. But at a very high level, what people need to understand is just when you take, when you take something from your own body, like for example, if you go to the US right now, there's a lot of stem cell clinics, but they're not actually true stem cells because if you're just taking your bone marrow or your fat,
And then you're just isolating that and injecting it. It doesn't actually have the ability to turn into a new tissue, but it does have an ability to reduce inflammation. And so a better term for it that Arnold Kaplan, who's a guy who coined the term mesenchymal stem cells in 1992, he's a guy who coined it. He wrote a paper about this, but basically he said that using should be called committed progenitor cells, which is
a fancy word for just saying that they can't turn into new tissue that they can reduce inflammation. Which can still be useful in some conditions, but it's just misleading because a lot of patients are like, oh yeah, I got stem cell injections. It's like, well, it wasn't really a stem cell per se. It was more just something to reduce inflammation because it's not.
Because remember, the definition of a stem cell is something that can actually regenerate your tissue. And if you're just taking your fat or your bone marrow and injecting it, that's not regenerating your tissue through the mechanism of that stem cell. It may send signals to your own body stem cells to help with some regeneration, but for the most part, it's an anti-inflammatory product.
And so that's the number one thing to understand about these. And this is, we're talking about the broader category of mesenchymal stem cells, which is just an embryological term. But essentially what it means is this is from the reason we use mesenchymal stem cells is because of the easiest to source.
because they're in the fat, they're in the bone marrow, they're from a milk accord tissue, or dental pulp, there's so many different sources now. But that's the reason why MSCs, or Rezeccumostem cells, are so popular. And the other reason is because Rezeccumostem cells, when we have a finite ability to differentiate
which means they won't cause tumors or cancer. Of course, that's always been a concern with embryonic stem cells, if you're taking them from aborted fetuses, which some clinics still do. And obviously, during the Bush era, there was a lot of controversy around that. And that's why stem cells kind of got categorized into this unethical thing. But that's not how we're sourcing our stem cells. We're sourcing them, obviously, we're not harming any babies. And they're being sourced from C-section birds instead of being thrown away. They're donated.
So it's a very simple collection process, but the problem with the mesenchymal stem cells, as we said, is first of all, there's a lot of clinics saying that they're taking your fat and bone marrow and cleaning their stem cells, which are not. But let's say you go offshore somewhere and they can isolate them and then they can do what's called culture expansion, which means they can grow them and they can replicate them. So then they can actually have some sort of dose that can be a therapeutic and potentially regenerate tissue in theory, but then
What happened, it turns out when you take these stem cells, whether from any of these sources, when you put them in the body, most of them don't survive. And when you do them intravenously, most of them get trapped in the lungs or die. And that's why the results have been very inconsistent. And that's why stem cells haven't taken off the way we thought they would, you know, 10, 15 years ago. And that's why the clinical trials have been so mixed.
And so, unfortunately, there's still a lot of clinics claiming that we can regenerate tissue. It's just misleading. And even I thought this, which is that I thought IV stem cells were great, but it turns out a lot of them just get trapped in the lungs and most of them die. And that, even with that, you still get some people who get benefits. And that's the old generation technology.
we can isolate the best stem cell population and use that one. So it turns out that when you take a stem cell, a mesenchymal stem cell, there's actually 17 subtypes, which is kind of crazy if you think about it. So it's like they're something called single cell RNA sequencing, which is basically to look at gene expression of individual cell profiles. So that way you can see how different cells behave
And then you can see that, hey, there's actually these 17 different cliques that they hang out together and they behave differently. And some of them are more useless and some of them are more useful. So we don't necessarily want all 17 subtypes, which is what most stem cell clinics do. And that's what we were doing up until a year ago. But as you know, I spent the summer in Japan. And in Japan, they won the Nobel Prize for regenerative medicine, Professor Yamunaka.
for cellular reprogramming, in which we can talk about those stem cells. But there's another professor, Professor Mary Dazawa, who discovers something called mu cells, and which stands for multi lineage, differentiating stress enduring cells. So it's a mouthful. All you need to remember for people is that these are cells that are mu's, exactly, the mu's. The mu's is the cool stuff. And they're able to, they're pluripotent, which means they can
differentiate into all 220 cell types in our body or over 200 cell types. And then they are stress enduring, which means they can survive harsh environments. So that's really the key. So they don't die when they go in the body. So we can isolate these using cell sorting technology and filter them out so that we're injecting primarily new stem cells
Instead of just injecting all the different type of stem cells and so that's now what we've moved on to and of course if you talk earlier about your back and that's what we use for you and that's what we're using exclusively just because the results are so much more consistent and the science makes a lot of sense and you know I'm in the process of doing some clinical work with professor desire wise well and we want to investigate these new cells were a lot of different conditions but
In Japan, they've already published files for ALS, for heart attacks, for stroke. And these are not easy to treat conditions. And with intravenous new cells, you do see benefits. And of course, we're seeing that in the real world, treating patients with all sorts of degenerative conditions and actually seeing a real meaningful difference. And that's just because these cells are actually surviving and doing what they are meant to do, which is reduce inflammation, repair cellular function,
reduce oxidase stress. We know one of the biggest mechanisms by which they work is through mitochondrial DNA transfer and mitophagy, which is preparing damaged mitochondria. And I think everyone now knows the mitochondria are so important, not just for energy, but for regulating cellular metabolism and aging. So that's why there's so much interest in this space for longevity and not just for repeated conditions.
And so those are mesenchymal stem cells. And then there's also induced pluripotent stem cells, IPSDs. And that's the Yamanaka stem cells where you can take any old cell and you can make it young again.
So, of course, when you think about that, you're like, holy, well, that's great. Shouldn't everyone be doing this? But it turns out, when you make that old cell young again, it makes it almost embryonic in nature, which means it can cause cancer or tumors. So, IPSCs, as are called, or Yamanaka stem cells to honor Professor Yamanaka, they're great, but the problem is they have the risk of tumor-genicity, and so we don't actually use them clinically yet.
There's a lot of work being done on it, but it's still I think a few years away from clinical translation So that's why the new cells because we know they don't cause cancer and we know they're naturally occurring on the body So they have a lot more clinical translation than the Yamanaka
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So these are basically these different kinds of stem cells. And the most of the kind in the first generation seems like they were getting an inflammatory effect, but they might not be doing the full effect we had fought. They might, and why there was variable results. And they get trapped in the lungs. The mu cells seem to be stress resistant. So they hang out more. They have time to do their job more. And they have the ability to actually work in a different way because they're not sort of
chute up so fast. And these don't get also trapped in the lungs. They are resistant to that. Yeah. So about 10 to 15 times more are able to go into circulation. So there is still some that get trapped in the lungs, but Professor Dazawa showing work showing that it's not like two times more. We're talking an order of magnitude, like 10 times more are able to go into circulation. So it is still a big difference compared to standard MSC.
And, you know, there's two kind of uses, as you mentioned. One is injecting it into a joint or a back or some damaged traumatic tissue or injecting them intravenously for systemic effects around, really, things like ALS or stroke. Those are really, like you said, almost impossible to treat problems. And what kinds of results are they seeing when they do these systemic treatments? And what are the kinds of conditions where it might be applicable for?
Yeah, look, I just had an ALS patient I treated a couple of weeks ago and I was blown away because it was my first ALS patient I treated with new cells and she couldn't swallow because of the bulbous symptoms, you know, and now she can swallow, she can speak rarely, she couldn't, she was barely able to speak before and that was just one IV and I mean it was pretty incredible to see. Obviously that's anecdotal but the clinical trial that was done also showed, you know, some slowing of progression and we all know how devastating ALS is.
And if you can, if there's something that can flow down even, I think we just don't know the exact dosing for ALS yet, but I think for now, I think we could certainly say it can be helpful and it's not harmful. And then for stroke, we can be much more, much more kind of.
certain that they are going to have positive results. Because in stroke, for example, she showed that 30% of patients in the clinical trial were able to go back to full time work when they were disabled. Like we're talking patients who were disabled. And so imagine you're. So are you saying that someone's in a wheelchair and came with the side of their arm? Exactly. Exactly. Yeah, exactly. And they go back to full time work. So now 30% of people and the other 70% still had significant clinical benefits and we're able to get off, you know, we're
they weren't necessarily able to return to work. A lot of them were able to get back to normal functioning of ADLs and IADLs and stuff like that, which is very big deal. And you know what the most interesting part was? 25% of the patients in the clinical trial had reversal of gray hair. And that was just like an accidental finding.
That's wild. So, what other kinds of conditions might this be up for autoimmune diseases, lung jazz? Yeah, it sounds, you almost sound like a, you know, like a used car salesman or something when you're like, this can treat everything, you know, but once you understand the physiology of chronic disease, as you do, you understand that there's certain hallmarks of aging.
And there's hallmarks of chronic disease that overlap. So I'm not going to list all form with them because I'll bore people, but there's basically 12 hallmarks of aging. We've listed a few of them, mitochondria dysfunction, stencil exhaustion, yeah, chronic inflammation, which is related to amino senescence.
And, you know, there's lots of protein, like, there's so many protein misfolding. There's so many other ones. And so basically, these 12, let's call them the 12 homeworks, they actually underlie, not just aging, which is, you know, arguably the most complex chronic disease. They underlie all chronic diseases from heart disease to asthma to dementia to cancer even.
and just components of that that are overlying. And a lot of them are metabolic in nature. And so that's why these stem cells have this ability to restore metabolic health because of that mitochondrial DNA transfer and helping to repair the mitochondria through metophagy. And then of course the mitochondria are the ones that help to regulate metabolism, right? That's where you eat food.
And your body has to process it. It has to go through your mitochondria to produce energy. And if your mitochondria aren't working properly, which is what happens to everyone with aging and chronic disease, then guess what? Your metabolism is messed up. And that's why metabolic disease is really the root cause of so many different problems. And that's why they call dementia type 3 diabetes.
all these other stuff, right? Because a lot of them are metabolic in nature. And if you can restore metabolic health, which stem cells can do, then that's why you can treat so many chronic diseases. And that's number one. And number two, the other beauty of these stem cells is their ability to regulate your immune system. So this is called immunomodulation. That's the medical term, but that just basically means we're shifting your body from a pro-inflammatory state to an anti-inflammatory state. So this is called immunomodulation, which is reprogramming your immune cells
Specifically your macrophages and if there's one cell that you need to understand, it's your macrophages. They're probably, they're my favorite cell in the body. You're like a little Pac-Man and like going chew up all the stuff that shouldn't be there, right? Exactly. So they're like your little Pac-Man controlling and surveilling and making sure the bad guys don't get in and they eat the bad guys when they're around. They take them away.
and they'll dispose of them, but what happens to a lot of Pac-Man or police officers, other like columnists, they get fat and tired, and then they start eating too many donuts and they can't do their job anymore. And this is actually called lipid-associated macrophages or lands.
And so they accumulate fat and lipid peri-oxidation inside of the macrophage, and then they can't do their job anymore, and the job is so important. And then they start releasing the wrong signals. They start saying, so the macrophages start releasing pro-inflammatory signals.
And then that causes the cycle of chronic inflammation. And that's really the root, as we know, of so many disease processes. And that's why if you can treat chronic inflammation, you can treat so many different chronic diseases. And that's why these IV new cells have so much potential. And even with IV, let's call it the first generation. Even with the first generation stem cells, there are clinical trials that are published showing that inflammatory bowel disease can get into remission, that rheumatoid arthritis can get into remission.
It's just the dosing is quite high and people need a lot of frequency of those but with the new cells you can get obviously you can get a lot better results, but it's the same principle which is you're just regulating the immune system.
That's incredible, yeah. So for autoimmune disease and for chronic inflammatory age related diseases, for just rejuvenation and longevity itself, these can seem to be helpful. One of the things I love you to explain is how does themselves work? Because you kind of alluded to the fact that they don't actually work as we thought they did, which is you inject them and then they go, if you have a liver problem, they become a liver cell. Or if you have a kidney problem, become a kidney cell. They just have certain compounds inside of them that go out and
Yeah exactly, so stem cells. So, mesenchymal stem cells primarily work through. Let me just before you kind of go into that. Mesenchym, for everybody listening, that's a big word. It means just your body's tissue. What the other kind of stem cells come from umbilical cords or from embryo. So, we're not doing embryos at all. We're talking mostly about umbilical cord blood that actually has
basically baby stem cells, as opposed to mine, which are like almost 65, right? And they're not as antigenic, in other words, they don't tend to cause this foreign reaction. Like if you were to take, I was taking your stem cells, I'd have a rejection of those stem cells as part of my biology, because we go like foreign stuff. But with these,
kind of umbilical cord cells, it's not like that. So you can use these umbilical cord, use stem cells to actually kind of bypass that of thing, but actually have the benefit of these younger stem cells, right?
Yeah, exactly. Unfortunately, using your own stem cells, there's many reasons not to, but the biggest one is definitely they've gone through a lot of replicative stress because they've gone through their own aging process. And so they can, they can actually have markers of senescence and other even cancer markers as you get older. So you don't want to take your own stem cell to put them in your body, especially if you're over age 40. But, but anyway, yeah, back to, yeah, back to the point about
what these stem cells are doing inside of your body, the mesenchymal stem cells are primarily reducing inflammation via what's called the sacrotome. So the sacrotome is kind of the soup that the stem cells grow in or release and there's signals. So there's micro RNAs, there's what are called cytokines, which are these proteins that help to reduce inflammation, there's growth factors. So this is all what's called the sacrotome, and depending on what type of sacrotome,
the stem cells are releasing, dictates their ability to change the microenvironment and help with these different cellular processes. So, for example,
The sacrotome of a stem cell from your own body isn't going to be as good as a sacrotome from a umbilical cord tissue. And you can probably understand that intuitively because it's like, oh, yeah, it makes sense. My cells are old. They've gone through X amount of cell damage versus a umbilical cord tissue, which doesn't. And that's why exosomes are such a hot topic because
If the most of the benefits of mesenchymal stem cells are due to the signaling process, then why not just isolate those signals and inject those? And that's what the exosomes are. Okay, so hold there, hold there for a sec. There's stuff that the stem cells secrete, right? That's why it's called this secrete-tone or secretome, which is, I hate to pronounce it, right? So there's stuff that it squirts out basically in its environment that goes out and does all these good things.
And what you're saying is that inside of the stem cells, there are these little vesicles, these little packets of healing factors called exosomes. And there may be where most of the benefit comes from the stem cells. So you can actually take the exosomes out of the stem cells, you grow the stem cells in a lab, you remove the exosomes, you can concentrate them. They don't have any DNA material, they're much safer, they're less expensive.
and then you can use them also. So now explain to us what are exosomes because that's another part of this whole field of beginner medicine. We kind of basically scurted the surface of stem cells. I hope you got a good sense of that. But I want to get into a few other things. So exosomes are the next topic. And let's explore what are exosomes, how do we use them, and why do they work?
Yeah, I mean, you kind of just said the definition, which is they're a type of extracellular vesicle, which are just packages by which your cell communicates with other cells. So they help with cell to cell communication. And there's different type of extracellular vesicles. So there's something called apoptotic bodies. There's something called MBVs, which are mycobesicle bundles. And then there's exosomes, which are the smallest type of extracellular vesicle. So extracellular vesicle or EVs is kind of the class.
and then there's different types of EVs, and exosomes are the smallest type of EVs.
And they're basically to help facilitate cell-to-cell communication, which interestingly changes as you age. So exosomes are also becoming a hot topic in diagnostics because it turns out the exosome profile of your cells as it become cancerous or as it become chronic diseases. You can detect certain exosome products because we didn't have this technology, right, like five years ago. And now we do. And now we can figure out, hey, the signals your cells are sending are changing. This means that you might be developing this problem.
So that's why exosomes are becoming a hot topic in diagnostics too. And then of course in intervention or therapeutics, then it makes sense because like you said, it's all about the signals that are being sent by the stem cells that dictate their ability to modulate or change the cells in a favorable way.
The exosomes can be isolated in a lot of different ways. Previously, it can only be done through ultra centrifugation of cells that are replicating. So you have to have cells that are replicating. But now that technology is improving so that you can actually get exosomes from terminally differentiated cells.
Meaning, even if they're not replicating, you can basically homogenization, which is basically like you're blending fruit to get the pulp out and the juice, it's like taking the juice basically of tissue and that's the exosome. So you can do that now with any tissue. So for example, there's people working on natural killer exosomes, dendritic cell exosomes, exosomes from liver, from muscle,
So there's so many interesting exosome products being worked at. There's 290 or 281 patents or something like that on exosomes in the last couple of years. So that can tell you the scale. The different kinds of exosomes. Oh, yeah. So that tells you the scale, though, over 200 patents on just exosomes alone in the last couple of years. So that tells you the scale and the magnitude of research that's happening right now.
Yeah, interesting. I actually, you know, there's, I'm going to talk about some of them in the music exosomes, but I, I had COVID and like many of us out there in the world.
And after one course of COVID, I got seriously depressed. And I don't have that as a thing I deal with. And I felt like it was a physiological depression of inflammation in the brain, because we know the depression is inflammation in the brain. And I felt my cognition was off. I had severe brain fog. I kind of can understand why people would kill themselves. It was a really strange experience. And I had, you know, my higher self was there knowing, hey, this is just your COVID talking.
I was able to get some exosomes and inject them intravenously and almost instantaneously it went away. It was quite striking. I was like, wow, this is quite an interesting tool. I also had back surgery four years ago that went badly and I had bleeding into my spine.
and had severe just pain afterwards for months. And I saw Virginia medicine doctor before, before he and I had Matt Cook and I had exosomes injected right up into the spinal canal through the bottom of my spine, it's called a coddle, epideral, essentially of exosomes.
And within really almost minutes, I was feeling dramatically better. And so I began to kind of understand by using some of my own body with my own degenerative arthritis, with all the messed up things that are going on my back, with the discs, with the inflammation, that these products actually really help relieve this chronic pain that I've had for so long.
And it was really striking to me because I didn't know that this was possible, just with these simple therapies. And yes, it's anecdotal. And the problem with stem cells is that they've been in the elected area of research in America. There are people doing it in academic centers, but it's kind of on the margins. Traditional medicine hasn't recognized it. You have to go to other countries like Mexico or Costa Rica or Panama or Dubai or Japan,
And so we're often sort of trying to find solutions for people and I have to send them other places if they want to try these things. And in physics, it's still sort of, I would say, in the experimental phase, there's concerns about certain risks of it.
there's more data needed. But I would say, you know, when you're pain, you don't really care about what the randomized controlled trial says, you just want to be out of pain. And it's something healthy. Try it. And a lot of athletes use it. A lot of people in professional sports use it. I know you work with a lot of professional athletes. And these regenerative compounds, whether it's stem cells or exosomes or peptides or other even compounds like placental matrix, which is kind of mashed up placenta, which I found incredibly helpful for pain relief.
All are available, and there's other kinds of things that are also being used systemically in a part of regenerative medicine, including cord blood plasma, which is the fluid that cells run in. There's gene therapies that are available to help
improve muscle, for example, like full stat, and there'll be cloth ogean therapy, which is another sort of longevity gene that's there that some people have some but don't, but you can actually provide it into people through different vectors that actually then can activate it and turn on.
these longevity factors. So it's a really extraordinary field of medicine that is, I think, going to be the future. And I think it's not really available that widely because it's hard to get to, it's expensive. What other tools besides sort of the exosome, which you can use by the way systemically, or you can use them directly into an injured area, what are the other kinds of things you're seeing are being effective in?
and talk a little bit about the muse exosomes, because I think these are special forces, I think of these special forces and the Navy SEALs and the Army Rangers, the Greek Rays of stem cells, right? Exactly, yeah. So, yeah, a few things. First thing I would say, just because you touched on a little bit, was there's a lot of politics, limited regenerative medicines, ability to really get mainstream in US.
Interestingly, Japan has the opposite politics, which is that because of Professor Yamunaka, they spent $8 billion of taxpayer money on regenerative medicine, and they have lobbyists for regenerative medicine. So it's very different environment that's actually favorable for regenerative medicine. And unfortunately, the US has taken a really archaic stance to the point where they regulate exosomes, which is an acellular product, meaning it doesn't have any cells, like you said, no DNA material.
And therefore, we know it's very safe. They're just signals that stay in the body for minutes to hours. And then, you know, they're more or less, they're gone. And then, but they help to change the microenvironment and help to change the functioning of cells. And so the safety is so high of exosomes, but FDA has decided to regulate it like a drug. And so therefore, an FDA has still not approved any drug
or any X's own product. So technically, you know, I mean, obviously there's so many clinics offering it, which is very interesting, but technically none of them are FDA approved. So it's just something to understand the regulatory environment. I don't agree with it, but that's the world we live in. And that's why people have to travel offshore, unfortunately. And that's, I think that's going to be a way it is for the next few years. It'll take a while before, you know, even if someone like us gets FDA approval for the new X's, it takes seven years, you know, five to seven years. You just got to, you have to go through
the phase one, the phase two, the phase three, the post-market, like you have to go through all that. And even that, you may not get FDA approval. And so they really made it difficult for regenerative medicine, which doesn't make sense by things.
But other countries are, other countries are moving forward, right? Oh, yeah, exactly. U.S. is being left behind, basically. And so... And the data is in, how strong is the data around these things? So there are... So it's about safety. Safety is always number one. Exisms are so safe. And even, you know, the zencomals themselves have so much safety data around them too. It's always about first do no harm. And this stuff does not have harm. And so why not try it as an alternative to opioid or to surgery?
for chronic pain, especially, right? Like it doesn't, to me, it baffles my mind, but it's very clear. Unfortunately, do you know what the most profitable drug now is? No, it's actually methotrexate. It made
It made something like $26 billion last year. So it's surpassed, it surpassed spattens. So methotrexate, which is a chemo drug, but it's used for autoimmune disease. So you're saying it's the autoimmune rise of autoimmune. It's an epidemic of autoimmune conditions, probably related to toxins in an environment, probably COVID, maybe, you know, everything else that's going on in the modern world.
And so it's just an epidemic. And you and I both know you can treat many of these to see nutrition and lifestyle, but most doctors don't know anything about that. So of course, they're just prescribing medications. And we know these things
wouldn't you rather be on something that's going to regulate your immune system and fix it than just suppress it, which may cause cancer, right? Like it doesn't, the risk benefit, it just makes no sense, you know, and, and I think you always have to look at what's called number needed to treat versus number needed to harm. And that's essentially just a fancy, fancy way of just saying benefit versus harm. And if you look at that for a lot of the pharmaceuticals, it's not that great.
You know, it's like for static medications, the number needed to treat is not one to one, meaning not every person who gets it, their life is going to be safe from a heart attack. It's something like one in 200.
Yeah, you have to treat if for people for preventing a heart attack, you have to treat at 89 people to just prevent one heart attack and death. But, you know, it's quite, it's quite amazing. It's not really a good data on how effective these are. It's like, so talk more about why you brought that up.
Yeah, because to me, then you have these interventions that we're seeing that are reducing inflammation, oxidative stress, that are helping with so many different chronic diseases, and they don't have harm. So why not have them as a first line as opposed to going straight to a lot of these pharmaceuticals that have risk? And that to me is kind of the logic. And on your note of new exosomes, the reason they're superior to standard exosomes is simply because they're from that new cell lineage.
So when you cells are replicating and when they're growing, the soup that they're growing in, that's what we're isolating, which has the signaling profile, meaning that sacrotome, which we talked about earlier, is superior than just a standard in the zencomil stem cells. So it has a better profile, number one, and number two, because it is from a stress enduring lineage too, meaning the exosomes can stick around longer than standard exosomes, which it cleared up pretty quickly.
So like, what is the difference between stem cell use and exosome use? Like some people say, oh, you can use exosomes. You don't need the stem cells because it's actually the exosomes that are doing all the work. So why bother with the stem cells? It's more of a hassle, more expensive. Yeah, that was, that was my take until I had the new cells. That was my take more or less. I would only use the stem cells in very specific situations. But now that's changed because the new stem cells
are actually pluripotent, which means they, and they, new stem cells are very interesting because they act kind of like macrophages. They actually eat, they gobble up damaged cells, and then they turn into the new tissue. So they'll, for example, in the heart, they'll go to the heart, they'll eat the damaged cardiomyocytes, so like damaged heart cells, and then they'll actually regenerate new cardiomyocytes. So they're actually pluripotent.
Right? And that's the key difference because they're not just reducing inflammation. And that's why new stem cells are, of course, more powerful than these exosomes because they're actually going to regenerate new tissue versus just reducing inflammation, which is what the old generation stem cells used to do. And that's why when I was using the old generation stem cells, I was kind of just using exosome for the most part because I didn't see the point because I'm like, you're just really reducing inflammation.
But now that we have something that's pluripotent, if I'm injecting it for something degenerative and I actually want to regenerate something new, then I'm going to use a stem cell. So, for example, with advanced osteoarthritis, if you want to actually stimulate cartilage regeneration, using the new stem cells makes a lot more sense. But if you just want to reduce inflammation, then you can just use the exosome.
So you kind of have to use both of them and practice and there's different uses for different people depending on what the issues are they're struggling with.
Yeah, and there's studies out there showing that the exosomes can create a favorable microenvironment for stem cell differentiation and for stem cells to do their job, basically. So that's why I tend to just combine them because the exosomes are only there for like minutes to hours, you know, like we said, like they're filled up pretty quickly. But then what they do is they go in there, they reduce inflammation, they make it a better microenvironment so that the stem cells can do their job more effectively.
And there's other kinds of tools out there with regenerative medicine that I think are really emerging and interesting. And in terms of the orthopedic part, you can inject peptides, you can inject stem cells, you can inject exosomes, you can inject placental tissue, we call placinometrics. What are all the kind of things that you tend to use and inject to help with these kind of orthopedic chronic injuries? And what kind of results are you seeing?
So the results since the new stuff has been honestly incredible and as a physician.
you always want your patients to get better, and now we have much more consistent results. With the older stuff, the results are a bit more inconsistent, meaning some people would get better, you know, some people wouldn't, and whereas this stuff just tends to be reproducible, and the way we do it is still very specialized, right? And this is the problem too. There's so many stem cell clinics that they don't know how to inject properly. You have to have a very high skill level,
You can't just, yes, there is a certain homo mechanism, but at the end of the day, the treatments are gonna work better if you get them to where they need to go. So for example, if you have a rotator cuff in your shoulder and you don't get the right spot, your results aren't gonna be as good as getting it right in the right spot. So, and that takes a skilled, that takes a very skilled, you know how it's skilled, it can be very skilled at ultrasound and you have to have a high level of proficiency to be able to do that image guided injection. And so that takes years of training
And then on top of that, you have to know which products to use. So I think people don't realize this is a very specialized field. It's not like anyone can just do it, despite a lot of people just offering stencils. You know what I mean? A lot of people are like, yeah, I do stencils. It's like, well, you can't, it's not, it's not just like, you can't just like do that. It's like doing, to me, it's like almost doing surgery. It's like,
I don't just do surgery, just because for the sake of it, you know. I mean, you might intravenously anybody can do that, but when you're trying to direct it to specific tissues or injuries or spots to hit that spot. Yeah. And so the image guidance is very key to it. And the results for musculoskeletal conditions, chronic pain, even neuropathic pain has been, it's very consistent, meaning the only patients that I find that don't get better usually just need a second treatment or sometimes a third in very rare cases.
So it's just a dosing thing. We don't know the perfect dosing for everyone, but we're starting to learn that more and more now. The dosing of the stem cells or the exosomes? Yes, because some people respond great to one treatment and some people need two treatments and we don't really know why. Now, can you talk a little bit about gene therapy? Because this is an emerging area of treatment. Most people probably never heard of it, but I mentioned them a little bit before, like fullest end gene therapy or clotho gene therapy.
What are these therapies? How do they work? What is the science behind them? And what are the risks? And what are we seeing in terms of the benefits? Yeah. So I work with a company called Mini Circle and Mini Circle has the world's first reversible plasma gene therapy. So what that means is it's basically a way for us to transmit any gene of interest up to a certain size to your body. So
For example, if there's a gene like Falostatin, which is a bioidentical peptide hormone in your body, and we want your body to produce more of that, we can put it onto this mini-circle vector. We call it mini-circle because literally it's like a circular strand of DNA, and you insert that Falostatin gene onto there, and then you can inject it, and then that will transmit it to your cell and tell your cell, hey, your cell will now read that instructions.
And then it'll say, hey, I need to produce more folicetin. And then folicetin goes into the blood and you raise your folicetin levels. And that has all these downstream benefits, which we can talk about in a second. But the vector is what people need to, obviously, is probably being like, what is he talking about, right? The vector. You're kind of scary. What are you doing? Yeah, exactly. Are you modifying my DNA? Are you a GMO human? Yeah, exactly. So it's not as advanced as CRISPR.
You know, which is kind of the gene editing technology where you're actually like cutting out different strands of DNA and kind of putting them back together. This isn't as complicated as that. It's not as powerful as that either. But it is still a form of genetic modification because we are inserting a foreign DNA into your body. Where does that foreign DNA come from? It comes from E. coli.
So we're not injecting bacteria into your body, but we're injecting something called plasmid. The plasmid is kind of think of it like exchanging cards with people. It's how bacteria exchange information. So we're isolating that plasmid from the E. coli, and then we're using that as a vector. So plasmids have been around in microbiology for, you know, two, three decades. They're not new, but the new breakthrough was just getting the plasmid to not shut off, because normally when you put a plasmid in the human body,
It does something called transgene silencing, which just says, hey, this doesn't belong here. I'm going to shut you off. And then it just shuts it off. But we figured out a way for it to keep, remain on, specifically to express whatever gene of interest we want, which obviously are longevity genes. We're not going to put something in your body that's not useful. We're going to put something in your body that's going to have some real longevity benefits. And Paul Stanton has been studied again for two decades. Paul Stanton is something your body makes.
It's basically a way for your body to put on more muscle because the higher your follostatin, the lower your myostatin, which is basically imagine the breaks on your muscle. And so if you take the breaks off a little bit, it's not like you're going to get jacked like the end of all steroids, but it will make it a little bit easier to put on muscle, but much more importantly, and this is why I like follostatin, it's very anti-catabolic.
right? And because as you get older, especially after age 60, your catabolism increases like exponentially. What is catabolism? So basically, yeah, so there's animalism and catabolism. So animalism is building more tissue and catabolism is what happened with aging, which is loss of tissue.
We actually lose, I forgot the exact percentage, but we lose some very large percentage of our total tissue mass as we age. That's loss of mitochondria, that's loss of muscle, that's loss of bone density. We lose a lot of tissue as we age. If you can maintain as much tissue as possible, that's going to be
a net positive thing, especially muscle tissue. This muscle tissue is the most metabolically active. It has all these protective cytokines that are released called myokines that, you know, turn off tumor suppressors that help prevent cancer, help with diabetes. I'm sure most people know about the benefits of muscle and anything we can do to help preserve that. I think it's going to have a net positive effect on your health. There's obviously a lot of people get concerned. They're like, how do you know? This is 100% safe because it's new. It is new, obviously.
And I'm not saying there's not enough long-term data to know, is it gonna do something to you 20 years from now? We can't say that for sure, but what I can say, and the reason I'm a believer in it, and the reason I've been it for myself, and obviously patients, and many, I've injected hundreds of people with it, and the reason is because, and the reason patients like it too, is because the net positive of having more muscle
and having reduced systemic inflammation, which is what Paul Saturn does, to me, is going to outweigh any theoretical risk that maybe we don't know about. But I think it's unlikely anyway, because we understand how Paul Saturn
Let me just break this down because that was a lot. So first of all, just to make sure I understand, you can insert into your cells through something called a plasma, which essentially is a communication vesicle that can then take a gene that produces a certain protein. And it's something that you normally would make, but you don't make as much of as you get older. And so you don't have the benefit of this
molecule at the same level you had when you were younger to build muscle. So you can insert this gene that produces this thing called follostatin, which then inhibits the thing called mastatin, which then mastatin is the thing that prevents you from building muscle. So that's why as you see people get older, they lose muscle, they look more frail, they don't have as much
Bulk, and that's because they're having lower levels of this full of stat. By actually putting it in your cells and having a little factory to make extra full of stat, you actually can stop this process which prevents you from building muscle as you get older. Is that right? That's exactly right. It's one of the drivers, but that's a great summary.
So is there a risk of inserting this gene from who knows where into your body that, you know, because it sounds scary, right? If you, oh my God, I'm going to get some. Yeah, I mean, what if the gene, what if the part like some of the risks, for example, in theory could be what if, what if the vector that we're using migrates, what if it goes somewhere we don't want it to go. But plasmid vectors are very well studied and very well
kind of documented how they work and they have a very high, you know, they have a high safety profile because they're very inert, meaning they don't stimulate your immune system. They don't have any, you know, known serious risk, but there are vectors, for example, so people can understand like what with the vector, for example, when they use the COVID vaccine, they use something called a lipid nanoparticle vector, LTV.
But the LTV, if you read about LTV, the vector that they use, unfortunately, can migrate. And that's why some people get myocarditis or pericarditis. And the vector can also be immunogenic. So that's why it stimulates some people's immune system. And that's why they get autoimmune conditions. And that's why we know now. And neurologic conditions. Exactly. We know that the vaccine actually has some harm than more than we probably thought when it first came out. And so
So basically, the plasmid vector, though, as compared to like a lip and nanoparticle vector, is a lot safer, just for comparison.
It's incredible. So, so there's really two that I've made gene therapies that I've heard about. One is full of statin, which is around and available now. When you go offshore, you can get it, not cheap. And then there's this new emerging technology around the Clotho gene. Now, can you tell us about the Clotho gene and Clotho gene therapy, where we are in the research and what it does and actually how we're maybe going to be able to use this clinically soon? Yeah.
Clotho is a really, really interesting peptide because the word itself comes from the Greek of
saying the one who controls the threads of life, which is a bit dramatic, but basically, it's like, whoa, holy, what does this clotho do? Does it control my life? Well, yeah, what they thought, what they realized, they found this accidentally in some animal research, and they found out that animals that had high levels of clotho lived 30% longer, and then they've seen similar data in humans of people who have high levels of clotho naturally,
not only live longer, but they're protected against dementia, even if they have the April E4 gene, which is super interesting, and then it can actually help with chronic kidney disease, too. So the two levels where most of your clotho is produced is your brain and your kidneys. And so those are the two main medical indications, which clotho is being very
very like looked at like there's a lot of research going on right now and there's a lot of biotech companies looking at POCO. But our platform I believe has the most applicability just because of the ease of use and obviously being able to just give it same technology through a plasma detector which is just an injection in your arm or your stomach.
and then optimizing your colto levels. But colto is more definitely more high risk than fallestadin because if you don't want your colto levels to go too high either. If fallestadin levels go too high, it doesn't really have any harm, it just saturates and there's not really much that happens. But colto, if your colto levels go too high, it can cause your PTH to go down and it can kind of mess up your hormonal system and it could actually be other detrimental side effects. So colto is definitely
exciting, but I think we're still, you know, at least a year, a year and a half away before, you know, after the clinical trial that we're starting now, before we can start offering it to people, I'm going to be doing it on myself actually next month. So I'll keep you posted. Oh, wow. Okay. Well, okay. It's, it caused some level of something to go down. What was that? PTH parathyroid hormone. Yeah. Parathyroid hormone, right? So you have to monitor it. So to do blood work for that.
So, so this, what do these do because it's, you know, the, the, both of that seems really clear. It just prevents the breakdown of muscle. What does Clotho do biologically? So it activates wind genes, which are these regenerative pathways, the wind gene pathways kind of well known for being one of the more important ones that a lot of different regenerative molecules work on and Clotho helps with that too. So it can facilitate regeneration and repair as well. And it can also
in terms of helping with neuronal death. So there's something called the integrated stress response, which is what your neurons, when they are under stress, they have this stress response called ISR. And Clotho can help to mitigate that, so there's less neuronal death. And that's why it can help with various, that's why there's so much interest for so many different neurodegenerative conditions.
And so this really fascinating kind of field of different things that we're discovering that the body has built into it innately, whether it's certain proteins, it produces, or stem cells, or whether it's peptides. And there seem to be kind of this explosion of research in this area. I mean, ozempic is a peptide. I'm probably one of the biggest...
So both profitable drug and history, I think. But it's just something that the body naturally makes. The GLP1 agonist is something the body naturally uses to regulate its function. And so a lot of these compounds are talking about are being explored, which are actually helping activate the bodies.
healing repair system by using these different compounds that come from different sources. And we're still sort of sorting through what works, what doesn't work, what the research is. You know, when do you feel like this is ready for prime time? I mean, this is going to be covered by insurance that health care, because right now it's not accessible. Those people, the price are so high. I mean, I remember I bought my first computer in 1988. It was a Mac SE 30 and it was $3,500 for four megabytes of hard drive and one megabyte of RAM on a floppy disk.
You know, it was like this tiny little black and white screen. And now, you know, I get my iPhone, which is, you know, you can probably have more computing power than what took men to the moon for the first time, right? So how are we looking at this field in terms of, you know, the research advances, when it's going to be clinically kind of more widespread, and when the costs are going to come down?
Yeah, so the costs will come down and then I believe and then that really like not we're not talking like 10 years. We're talking within the next five years because we're very close to this kind of automation and manufacturing. There's a company in
Silicon Valley that actually just started, that's, and they're doing well. They basically figured out how to automate cell manufacturing using robotics. And so using using that plus bio reactors, which allow you to grow a lot more cells a lot quicker, will significantly reduce the cost of manufacturing these cells. And obviously if the cost of manufacturing goes down, then the cost of the consumer goes down.
But then there's almost like that, you know, to get rare diamonds. It's hard, but now they make these artificial diamonds. Exactly. Exactly. Yeah. And so that's, so that's the first thing. And then the second thing is.
There's economies of scale, which just means as more people do it and there's more demand, then obviously you can lower the pricing as there's going to be more people who are willing to do this type of treatment at a lower price point. And that's one of the things I'm very adamant about making this stuff accessible to the average person. And the only way that's going to happen, as you just said, there has to be early adopters, right? You bought a Mac in 1988 and probably not many people had a Mac back then. So it's like,
But there's going to be early adopters for every technology just like you know I was an early adopter of Tesla personally I bought an electric vehicle before anyone else really did and I was and but now it's becoming much more common and so I think it's going to be the same thing with this where it's like okay there's going to be the early adopters there's going to be people who are more into this stuff and and also I think the way to think about it is if you have the means to do this stuff and
You are paving a better way for a future of people, because we're, at least our company, we're investing all of our profits back into R&D and trying to push this field forward, and trying to really make a difference in vagina medicine, as opposed to just using a fork, just for profit for yourself type of thing.
But the only way to push this field forward is you have to, at the day, do controlled clinical trials. Because that's the only way you're going to get insurance companies and regulators to buy into this. And that's the long game. But by being able to offer these offshore treatments that people are willing to pay for, and people actually get real results for, they're funding our ability to do the research, which ultimately will be used as justification for regulators to approve it, which I think will take
Probably seven to 10 years, you know, in terms of getting approvals for specific medical conditions like I think officer arthritis, for example, is not very far away. Where are you getting incredible results with the new cells and hydrogel scaffold, which is kind of, you know, like a jello that protects the stem cells allows them to stay there so they don't migrate.
And there was also already incredible. And just before I came on this call with you, we're working with a company that's making custom scaffolds using 3D bioprinting. And that can actually resurface an entire joint. And they've already done that in large animal studies. So the human trials are next. And that's what we're going to do. And so this stuff is not that far away.
So this whole field of regenerative medicine, it's definitely super exciting to me because it's always what I thought of in functional medicine, which is how do we use the body's own healing power to get better? How do we just get rid of the things that are causing harm and adding in the things that are supporting the body's own repair and healing? And so now we have all these exploration of these biological products that
we're not, we have been discovered really over the last decades that now we're being used clinically. And, and there are these sort of longevity enthusiasts or, you know, athletes or kind of early adopters who are starting to use, including myself and, and seeing, you know, quite significant benefit. Um, you, you see this becoming part of like mainstream healthcare at some point.
Yeah, I mean, look, in Japan, I keep bringing up Japan because they're just so far ahead of us. But in Japan, they actually cover intra-articular stem cell injections for knee osteoarthritis and cartilage defects. And so, and those are culturally-expanded stem cells. And so, you know, the fact that the reason I bring Japan up too, because it's not like Colombia or Mexico or Panama, you know, some random country that doesn't really have a
Any sort of develop economy and rigorous like Japan Japan has like rigorous standards like they're very meticulous with everything And so there so to me the fact that they're able to approve not only approve it But actually I'm insurance companies reimburse people already Just shows you like what's possible, but I think
America, there's just so many politics, right? And the politics unfortunately affect the ability for us to offer these to patients. And what I believe is a solution is personally, you know, if our company becomes big enough, I'm going to get some regenerative medicine lobbyists. And you bet, you bet you I'm going to get them to start lobbying for us. Because I think that's the only way to really get this stuff moving the US.
Yeah, I mean, so either there seem to have probably a lot of companies involved in producing from products and compounds. And there's a lot of money going into this. But is there a lot of funding of research on regenerative medicine? And who is this something coming from governments? Is it coming from? Well, no, it's that's a problem, right? Like that company I was just talking about, for example, a 3D bio printing company, they got, they got a mass national NIH grant.
you know, for 18 million dollars, they're able to do some animal studies and some preliminary phase one stuff. But now they're hitting a roadblock because obviously they need more money to do more trials and it's so expensive to do clinical trials in the U.S. and they can't get any more money from NIH. So basically they have to go to D.C.'s venture capital or private equity and try to raise money and they can't get it. It's too hard because they're biotech and it's high risk.
yada yada. And so it's really hard for these regenerative medicine companies to find, then find money and to, and honestly, that's, that's actually been my strength is I'm good at finding technology. And I have, I have a good networks and I'm able to help like the new cells, for example, Professor Gizawa, unfortunately hasn't had the, you know, she, she, she had funding, but then lost her funding. There's a, again, politics and
But I'm able to help her with that stuff, and then obviously I have marketing and other resources. And so we can, and that's kind of my, I guess, vision with this stuff is being able to actually drive this stuff forward by doing the control clinical trials of very promising technologies that I believe that, you know, based off the science, I think are going to be a huge part of the future of medicine.
Yeah, it's a pretty exciting moment. I mean, we're seeing the advances in healthcare and medicine happening so fast, but it's just the sad thing is it often takes decades between the discovery of something that works and actually having it end up in the doctor's office or your clinic. And you created an incredible... I think that's gonna change, thanks to social media, funny enough, because alternative media is becoming more popular. And I think people will demand
that their doctors or people know that, hey, I deserve to have this as an option. And I think that's when it comes down to patients have the right to have all their options explored and especially options that are safe and can be just as effective as surgery. So I think it's unfair to patients to not be able to, for the doctors to not even know anything about this stuff and not be able to have a conversation with their patient about it just because they don't know, unfortunately they don't know anything about regenerative medicine.
And just because, I mean, you and me, they were like, I think that was generous in that school, right? So there was no education.
That's amazing. So tell us more about how people can find you about your clinics, where they are, because maybe people listening want to go try it out. So how do they get to learn more about what you're doing? Yeah, well, I'm in Dubai now. But we do have clinics in Los Cabos, Mexico, which is probably closest for most of our US patients. And then we have a clinic in Europe. And then we have a partnership in Tokyo as well. And then maybe more time in the night. Maybe we'll have something in Abu Dhabi soon.
But yeah, our company is called Eterna, like Eterna without a L and Eterna without health. But my Instagram, I have a, you know, I'm very responsive on there and it's at dr.akon, K-H-A-N and I try to be as helpful as possible. We've helped many patients with chronic diseases and, you know, sometimes we know affordability can be an issue and we do try our best to help those patients with hardship pricing and stuff like that.
So it's not, you know, it is expensive, but we are also, we are trying our best to work on that and also starting a foundation to help cover those costs for like, you know, for bedrooms and for people with disabilities and stuff like that.
That's amazing. So we'll put the link in the show notes to your website, which is interna.health. And in social media, so people can find more about you. We'll link to some of the research that we've talked about. And it's an incredible field. I just can't wait to see where it's going. And for me, as a guy who's coming up on 65, I'm like,
Thank God. So I think getting all the old injuries kind of fixed up and keep moving up so I can keep skiing and playing tennis and climbing mountains and having fun. So I really appreciate the work you've done, your enthusiasm, your dedication to thinking about this, to learning about what's on the leading edge, trying to sort of navigate a very difficult and complex world. And I know we'll be hearing more about this from you in the future. So thank you so much, Adil for being on the Dr. Sharmuzu podcast. Yeah, thanks for having me.
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This podcast is separate from my clinical practice at the ultra long center and my work at Cleveland Clinic and function health where I'm the chief medical officer. This podcast represents my opinions and my guess opinions and neither myself nor the podcast endorsed the views or statements of my guests. This podcast is for educational purposes only. This podcast is not a substitute for professional care by a doctor or other qualified medical professional. This podcast is provided on the understanding that it does not constitute medical or other professional advice or services.
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