The Peter Attia Drive - #35 - Nir Barzilai, M.D.: How to tame aging
Episode Date: January 7, 2019In this episode, Nir Barzilai, director of the Institute for Aging Research and expert in the genetics of longevity, discusses the evidence that metformin and rapamycin have anti-aging properties and ...how his TAME study aims to support this hypothesis in humans. Additionally, he describes the role of genetics in lifespan/healthspan and how it might affect important pathways such as IGF and insulin sensitivity. We discuss: Nir’s background and interest in aging and endocrinology [3:30]; History of metformin, and understanding the mechanism [11:15]; Attempting to define insulin resistance [21:15]; Metformin as a possible anti-aging drug [48:45]; The TAME trial: Targeting Aging with MEtformin [57:45]; Why Nir believes metformin can slow aging [1:16:30]; The genetic gift of centenarians [1:28:00]; IGF/GH and its impact on aging and chronic diseases [1:34:15]; Genetics/epigenetics of centenarians, gene sequencing, CETP-VV, Lp(a) [1:49:15]; Should you be taking HGH? [2:05:30]; NAD and NAD precursors (NR and NMN) [2:30:00]; Parting thoughts on metformin [2:36:15]; Possible blind spots in Nir and Peter’s thinking? [2:43:00]; and More. Learn more at www.PeterAttiaMD.com Connect with Peter on Facebook | Twitter | Instagram.
Transcript
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Hey everyone, welcome to the Peter Atia Drive. I'm your host, Peter Atia.
The drive is a result of my hunger for optimizing performance, health, longevity, critical thinking,
along with a few other obsessions along the way. I've spent the last several years working with
some of the most successful top performing individuals in the world, and this podcast is my attempt
to synthesize
what I've learned along the way to help you
live a higher quality, more fulfilling life.
If you enjoy this podcast, you can find
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at peteratiamd.com.
Hey everybody, welcome to this week's episode of The Drive.
And happy new year to everyone. We took a week off as you probably noticed. So hopefully everybody's welcome to this week's episode of the drive. And happy new year to everyone.
We took a week off as you probably noticed.
So hopefully everybody's ready to jump back into this fun stuff.
My guest this week is near Barzalai.
And if you're at all into the space of longevity, he'll be no stranger to you.
Near is the founding director of the Institute for Aging Research, the Nathan Shock Center
of Excellence in Basic Biology at Albert Einstein. He's completed two fellowships, one
in metabolism at Yale, the other in endocrinology and molecular biology at Cornell. He directs
the longevity genes project, and in my estimate near is probably the most knowledgeable person
ever on the genetics of
longevity.
And we talk a ton about that during this episode.
He also is leading the effort to test metformin in a prospective clinical trial for non-diabetics
with respect to aging.
And this is referred to as the tame trial.
We get into that obviously in detail here and also will use a lot of the data for that in the show notes.
This is in many ways I think Nier is probably one of the most insightful people when it comes to
understanding the clinical benefits of metformin. And we talk about that a ton.
We also talk about insulin resistance. I can't resist the urgent upon intended, I guess,
to get into sort of a detailed discussion on what IR is with sort
of people who are really deep in the space.
We talk a lot about IGF and growth hormone, and I got to tell you this is a topic that
you've probably heard me waffle on a little bit because I'm still really kind of on the
fence about this relationship of IGF GH.
I think the Centenarian data point in one direction.
I think the epidemiology outside of Centenarians point in a different direction.
And of course, none of this really speaks to the question I get asked constantly, which
is, do you think administration of growth hormone is beneficial from a lifespan or health
span perspective, or do you think it's harmful?
And truthfully, I've always leaned towards the harmful side, but we get into this in detail
and near offers some great insights.
Certainly for me, I was really helped by this process.
We do go back and talk about the centenarians,
and because I'm in the midst of some of you
of writing this book, I'm knee deep on all that literature.
And so it was really great to kind of clarify a few things
that I think even if you're not steeped in this stuff,
well, you'll find very interesting.
And of course, we talk about all of my other favorite topics,
like atophagy, color restriction.
We even get into a little bit of this stuff around NAD
and nicotinamide riboside and things like that.
So overall, I think this is a bit of a technical episode,
but not that technical.
We've certainly done more technical stuff.
The show notes will be valuable, as always,
especially for a show of this
nature. So with nothing else to add, please welcome to the show near Barcelona.
In here, how are you? I'm terrific. How are you? I'm good. I can't believe not only did you make
it down here on time, but you made it down here ahead of me at my own place. Nice to stay young.
down here ahead of me at my own place. Nice to stay young.
Yeah, this is, I don't know, these days, this is why there's so one pleasant, but yeah,
you beat me here.
I was a bit of, I was a bit of a bit of a...
It's unpleasant for you because you're in California most of the time.
Yeah, yeah, I think that's part of it, but you're from Israel, so this has to be unpleasant
for you too.
Israel was too warm for me.
I'm okay.
Got it.
Well, speaking of which, so you were born in Israel.
You spent how long there?
Did you serve military time there?
Yes, I served military time.
I was a nurse and a medical student.
I went to the Technion Medical School.
I went then to Hadassah Hospital for residency, which I finished. And only then I came to the United States.
I was at Yale with Ralph DeFronzo doing metabolism.
Actually, I was looking at the mechanism of action
of metformin in 1987 before it was approved
for use in the United States.
There's a serendipitous connection to that later.
And then I went to Cornell for an endocrine fellowship.
And then I was recruited to Einstein.
And so my first part of my life was metabolism.
But then I started doing what I really was interested in.
And this is aging and the biology of aging.
And I remember reading a quote once from you
that said,
maybe paraphrasing, but Metformin is the reason
I came to the United States.
Well, in a way it was, but this is life in retrospect, right?
I wasn't really expecting.
I was done with Metformin in 1988.
I was done with Metformin until it started again
about three, four years ago.
Well, I can't wait to talk about mit forming because they're probably, I'm trying to think,
if I think of four or five exogenous molecules, which is just the terminology I use to describe
anything that you ingest or take that comes from outside the body. So I would include drugs,
supplements, hormones, anything in there. But when you lump all of these things together,
if I were to say, what are the three or four of these
that I am asked about the most frequently from patients,
or frankly anybody, if I'm at a party
and I let it slide what I do for a living,
the first question is, should I be taking that form?
And there's usually a handful of others
that they wanna know about.
Should I be taking nicotinamide riboside,
although they usually don't say that, they usually say,
should I be taking NAD or something to that effect?
So it's wonderful that we will be able to speak today because few people can speak about
metformin the way you kept.
And so I'm really looking forward to that.
But before we go down that path, I do still want to kind of understand a little bit more
about your journey and your interest in endocrinology.
Did you know from day one when
you entered the field of medicine that this was the area that you wanted to study? Yes, I was interested
in aging from the time I was pretty much 13 and spend weekends with my grandfather who was telling me his life story and his life story wasn't easy and he did lots
of physical things and he dried the swamp and he did this and that.
And I'm looking at a man who was then 68 years old that walks slowly his obese white hair
and he just didn't look like somebody who did everything he told me to do.
And you know, they say that children have imagination, but most kids don't see their grandparents
as what they will be, right?
They see them as, I don't know how they got there.
And this really stuck with me.
And I started to be interested in the biology of aging.
When I was, for example, when I did my residency, I always was interested in how not what's
the age of the patient, but does he look older or younger than his age.
I kind of realized intuitively that there's a chronological age and a biological age,
and what is this difference between the biological and chronological age?
And of course, as a physician, it looked like endocrine is a good place to start because
you knew that there is a lot of endocrineology in aging, and you assumed that hormones are
going down or some are going up, but if you could fix that,
maybe you could fix a lot of aging. Now, everything that happened in my life was fascinating from
the biology of aging, replacing the hormones wasn't really a part of it, but we'll get to it.
Going back to the hormone thread, the most obvious example of changes in hormones with aging, of course, occur in women, where they have this very abrupt change in one of their
endocrine systems, this androgen system.
Did you think about it even more broadly than that, for example, like what was happening
in thyroid hormone and what was happening in fuel partitioning hormones and other things
like that?
Oh, absolutely, absolutely.
But I'll tell you to the point, when there was a discussion whether to do the Women Health
Initiative.
You know, many people thought this is a waste of time.
You know, we know that estrogen is good for women.
There's lots of studies like that.
Of course, it's major in aging.
And I didn't look at it this simply for maybe two reasons. One is men are also aging and in several ways similar to women.
That's not an estrogen story.
It wasn't the testosterone decrease,
wasn't really as dramatic as the estrogen decrease.
I thought that there's a lot of aging that's done without estrogen.
Let's start with that.
And also, you're replacing just one hormone with lots of hormones, are changing.
It didn't look like a good study to me.
Well, especially at the time, and I try to be tempered my criticism for that study by
trying to have some empathy for the fact that the investigators were dealing with what
the treatment protocols were at the time, but to use oral estrogen
that's conjugated equine, to use synthetic progestin and not even actual progesterone.
And you could come up with a list of 18 things that in retrospect are so obvious
why that study was a failure.
Absolutely true, but the other part of that is that the way to show effect of estrogen in animal
models was to take their ovaries out and give them estrogen. And then you could show, you could
do lots of provocation, it was good. So estrogen is a good hormone on a young body. But then there
were studies that were hardly published, but I was aware of them, of taking old animals.
So you could take the young animals in just one center in Houston, they did it.
You took the young animal, you took their ovaries out.
You gave the estrogen and you employed a stroke model.
And when you gave estrogen, the stroke was smaller in everything.
When you did the same in older animals, the stroke became worse.
And they couldn't publish it for a while because they said, well, it's all the animals.
So they have other diseases or other things.
But every experiment that had estrogen in old model was the opposite.
Not only that it didn't affect, it was the opposite, not only that it didn't affect it was the opposite, which
would happen, you know, to the WHOI in a certain way.
Yeah, although I still think that it was probably the breast cancer that garnered
the most headline in the WHOI and actually that's an interesting topic, which I'll
be going into in great depth on another episode. There's a great book that just
came out that tackles this that goes through the history of the WHO. At what point? Well, let's go back to the Metformin thing
actually. So it's 1987 and you're thinking like, okay, Metformin is the next line of agent we will
use to treat type 2 diabetes. So Metformin was already in clinical practice in Europe, is that correct?
Oh correct. For many years. How many years, like 20 or 30 years?
So, mid-forming few years ago was 60 years.
So we are talking about 1950 or something, 1950, 1960.
When I was in Israel, I prescribed mid-forming.
That was the first line for type 2 diabetes.
What took so long for it to come to the US?
That's a terrible story that still continues.
You know, the FDA said, we don't know,
we don't know that mid-form is going to be effective
in the population in the United States.
So you have to do the studies.
And it was Bristol Meyer, really, that got to do the studies.
And basically, they had to do a phase three study again
to show that metformin is effective.
As sulfonyluria is an indication for type 2 diabetes.
And even then, the idea was that it will be good only
in obese people, which happened not to matter much because all
the type to the United States were obese, but it was really a matter of regulation.
And part of having regulation was that the FDA asked more studies to understand the mechanism
of aging and metforming. And in a certain way, maybe they are right, because
metformal mechanisms of action is really complicated. And I'm
not sure that today, as a new drug, it would be approved.
Interesting. Why do you, where do you think it would fail in
safety or efficacy?
No, it's not in mechanism.
In the inability to elucidate the mechanism.
Right. When you come to the FDA and you say,
you know, we've done that and we've done this in animal
and we've done this in sales and you're trying to show
what is the major mechanism of action, you would have failed.
So what I showed in humans is that metformin targets a patiglucos production or the insulin sensitivity of the liver.
And that's the major mechanism of action unlike, for example, sulfonyluria that increase insulin secretion, right?
Or TZDs that increase the insulin sensitivity in the muscle more than in the liver. So this was a mechanism that you could pack to the FDA, but it's really not the
interstellar mechanism of metformin. So at the time, was it understood what metformin's activity was
on complex one of the mitochondria? Now, not really. This came later. I don't know what year, but it came later. It came when the
seahorses essays were developed to show really which mitochondria, in which pathway of mitochondria
you have changes. Maybe for the listener, explain what a seahorse
essay is. Seahorse essays and essay to look at mitochondrial action, whether you extract mitochondria or even
tissues.
It really shows some relationship between oxygen, consumption, in relationship to polarity
and it's very sensitive to look at some of the effects of drugs that are interfirmal mitochondria
action or decrease mitochondrial activity.
It's almost like the indirect calorimetry of the mitochondria.
Right, indirect because it's a provocative test, really.
So, yes.
Metformin was discovered from a plant as well, correct?
Right, it's a French lily.
And it was, firstly, obviously, and this was discovered
in the 40s or 50s? Correct. The first thing that happened, there was a drug by the name of
fanforming, a cousin of midforming. Which apparently is much more potent. It's much more potent because
unlike midforming, it doesn't need a transporter to get into the cells. On the other hand, it was
associated with a lot of lactic acidosis, and it was considered unsafe eventually, and
then metformin was a safer part with much less of lactic acidosis side effects.
What is the mechanism by which metformin caused lactic acid doses?
Because in all the use I've seen of metformin clinically, I've never seen a case of it,
which is not to say it doesn't happen, I'm sure it does, and you could stack risks by
taking someone with renal insufficiency, giving them contrast and tons of metformin.
But in medical school, this was like the board question you got asked every single test.
What do you have to worry about with lactic acidosis?
What's the putative mechanism by which that happens?
So first of all, I would tell you that in my study
in the 80s, every patient that we gave met forming
had an increase in lactic acid.
From what to what in millimolar?
Within the normal range.
So if it's two was the yeah the cutoff the cutoff
So it was you know between went from one one point five towards the two and sometimes even went over the two
But it wasn't really anything associated with that C. Dozi and there was no change in pH. No
No, no onion gap not anything like that. Any probably has to do, I, I don't know that I can tell you for sure,
but it has to do with what happens when complex one part of the metabolic effect when complex one
is inhibited. But there's lots of speculation, and I don't really care to comment on that.
But I think what became clear, we call it endocrinologist called it mala.
It's metforming associated lactic acidosis.
In other words, we moved away from metforming causing lacticisose to the association because it's if anywhere it described more in
people
that have kidney failures or have a heart attack or something and had lacticazisose anywhere on red forming too and
That was kind of the association, but it's not clear to me that there are truly people who develop lacticazisose from it forming
clear to me that there are truly people who develop plastic as it does is from it forming that is just because of it forming and not associated with something else.
I'm glad to hear you say that.
That's sort of generally been my bias, but I'm happy to be corrected if that bias is incorrect.
But yeah, I've always thought that frankly, so many of the drugs that we're really interested
in now as we look back from an aging perspective, whether it be metformin or rapamycin, so many of the negative
side effects that people typically associate with those drugs are very difficult to isolate
from the patients in whom those drugs have historically been given.
And so it's nice to hear that mala is now being generally recognized as an alternative viewpoint to that.
You know, metformin is to me an interesting drug from a diabetic standpoint because,
and I don't know that this was appreciated in the 80s.
In fact, I would suspect it was not because there's really two macro strategies for improving
type 2 diabetes.
You can obviously, the highest goal is to control glucose levels, so to regulate
the degree of glucose in the blood. But you can do that through at the highest level two ways,
you could increase insulin either exogenously or through increase insulin production,
pharmacologically, or you could reduce glucose. And of course, metformin falls into the
latter category of that, or increasing
muscle insulin sensitivity, to enhance glucose disposal. Today, it's generally regarded that
while both strategies will have an equal benefit on the microvascular, the glucose lowering
by insulin lowering, so the less glucose production strategy has a superior effect on the macro
basculature.
And therefore, Metformin would be a better alternative to, for example, a drug that's
going to increase insulin production out of the pancreas.
Was it appreciated at the time, meaning when you were doing this in the late 80s, how
potentially beneficial this drug was?
Well, at that time, in the United States, it was all about insulin resistance.
You know, people like Jerry Riven, Ralph DeFronzo, the people at the NIH, Ron Khan, were all,
you know, discovering the insulin receptor, discovering insulin resistance, discovering
the association of insulin resistance with the metabolic syndrome.
So it was all, we all had the bias, that the major problem we talked to diabetes
is insulin resistance.
And you know, we know now that it's a total collaboration,
yeah, you increase insulin resistance,
and the punkers have to secrete more insulin.
And we humans, at least in the condition
of our environment, obesity, everything, many of us, I would say 40%
cannot deal with that. And we become diabetic. There is this starling curve of the punk-rest,
you know, like for the heart, that you increase insulin secretion at some point, you cannot
increase insulin secretion, you become diabetic and then insulin secretion decrease.
And so insulin resistance was a major way
and that's why mitforming was a good place to come with.
You know, at least it affects mainly
the hepatic glucose production rather than the muscle.
Although I have to tell you in vitro,
on muscle specimen, it's an insulin sensitizer in the muscle, although I have to tell you, in vitro, on muscle specimen, it's
an insulin sensitizer in the muscle, too.
Let's talk about this idea of insulin resistance.
I think there are a few terms that leave me scratching my head more than that one.
So this is an example of something where maybe five years ago, I thought I really knew
what insulin resistance was, and I think today I'm pretty sure I don't know what it is.
In the sense that when you take the typical phenotype of someone who's insulin resistant,
what do they look like? Biochemically and anthropomorphologically, right? So they're hyper-insulinemic.
They have elevated levels of glucose. They probably have some degree of obesity or
out of posity. So what does that mean? Because clearly their fat cell is quite sensitive to insulin.
If the fat cell ever became resistant to insulin, you could not re-establish fatty acids, and
you would have an endless stream of lipolysis exiting fatty acids from the fat cell.
So you'd actually be quite lean.
There's something going on in the muscle that clearly is resistant to the effect of insulin,
but of course, there are both insulin dependent and insulin independent means by which we can
dispose of glucose. And this is where, coming back to what you said, a moment ago, I actually wanted
to ask you that question, which is, but we'll park it, but the question was, does metformin
participate in the AMPK-driven insulin independent modality of glucose disposal, you're nodding.
So I think that's a yes, and we'll come back to it.
And then there's the liver.
And this is the one to me that is the most complicated.
And the one I'd like to begin with.
So before I ask you to elaborate on the specifically,
what is meant by insulin resistance in the liver,
am I a complete moron for not understanding this?
No, but can I make it a little bit more interesting even because I need to bring it to aging.
Yes.
I would love to talk about diabetes, but let me just put up front.
I'm not sure that the diabetes property of metformin are really the aging properties
of metformin.
Okay.
This is my provocation. But let me go back to insulin resistance
because in 1997, a science paper appeared
that made it the best day of my life
and the worst day of my life.
Okay, wow.
What was the paper?
The paper was taking a nematot, okay, so a primitive model
Decreasing the insinin sensitivity. This is known as the Duff-2 model and when you do that
The nematot accumulates fat in their intestinal cells, so they are becoming visceral obese and they leave several times longer.
So why is it my the best day in my life?
Because you could with one genetic manipulation, extends life, spend
significantly.
That meant going from hope, actually, from nothing from this
synthias paper.
We know that's Gary Roofkin.
But at the same time, Cynthia had their Daphsixteen.
Tom Johnson has had the age one model.
There are several papers that came and all of them said, Hey, we can
change a lifespan.
And the example was always in some sense.
And this mutation to be clear because between Daph two, Daphsixteen,
and the dietary manipulations, there are several permutations of that C-Elegance model.
But just to make sure, I know which paper we're talking about,
this was only attenuation of DAF2,
nothing to DAF16 and nothing to dietary change.
Right, right.
Can you just for the listener define,
what is the analog of DAF2, DAF16 in us?
DAF2 is the insulin receptor, and DAF16 is the foxyl transcription factor.
But the point is, at that time, you took a worm that normally lives two weeks and you turned
down its insulin receptor slightly, not off, correct?
Right, right.
But you made it insulin resistant, and it was accumulating fat.
And what was I bringing in to the field?
I was saying the major reason for aging is this insulin resistance syndrome, and the
main part of the insulin resistance is accumulation of visceral fat.
And so the premise was good.
The example was disaster to me.
I had the JCI paper at that time in press,
really showing with MRI pictures
how caloric restriction decreases the visceral fat.
I was talking about the biology of those fat and stuff. And it was a major paradox
for us in the field and how we continue if we're saying insulin resistance is good for longevity
and everybody in diabetes knew that this is a disaster. Why am I telling you that? Because I learned
later, I was thinking later on experiments that I've done. Oh, so first of all, the experiment that I've done that was very conclusive was I took a bunch of rats, 150 actually,
and all of them underwent surgery after puberty.
In some of them, I removed their visceral fat depots by surgery,
and in the other, it was a sham procedure.
Just moved it, but didn't remove it.
And we had three groups in the experiment.
One was Ed Libidum feeding.
The second was caloric restriction.
This is the control.
They would leave 40% better.
And the third group was Ed Libidum feeding
of the rats that their visceral fat was removed. And I said,
you know, without the visceral fat, even with nutrients, they live longer. And they actually
lived significantly longer than the Ed Libbydum by 20 percent, but not as much as the caloric
restriction. So just to make sure I understand, you had a two to one ratio of your animals
because you had no, I had three groups.
Three groups, but one of them was all adlib feeding of the visceral fat removed.
That was right.
And then of the ones that had sham surgery, they were randomized to adlib versus CR.
Correct.
It really showed that visceral fat, the removal of visceral fat, had major effect.
And when the animals who had the visceral fat removed were autopsy,
or whatever the word is for rat autopsies,
had they figured out a way to reaccumulate visceral fat,
or where had they accumulated fat?
No, in fact, when you do this procedure after puberty,
if you do it before puberty, they accumulate visceral fat.
Otherwise, they don't accumulate much visceral fat.
Did they have changes in subcutaneous fat?
That's a good question. My's heavy when you do it and rats do not.
What did they ultimately succumb to? They all die from the same thing only at different times.
Which is what cancer? Yeah.
It was sprague dolly. So kidney disease and cancers were the leading cause of death.
So you basically got half the benefit of CR by doing this.
By eating a Libby Doom, but without visceral fat.
So you understand it's very...
Sorry, one other question, near.
Was there any change in their health span or their sprain as...
Yes, there was a health span.
In fact, what happened to the Libby Doom, the Libidum starts losing weight at the end of their life.
And the adlibidum with visceral fat have still gained weight after the others, you know,
it was a significant change in weight.
And then there's a whole health spender, insulin levels, and other things that we've
done in parlor.
So they were healthy and they were healthier for longer,
which is kind of the experience that we do with animal months.
Is it possible to take one of those rats and either through caloric restriction or other dietary
restriction, get it to puberty to the point where you did the surgery, but without any visceral fat?
And then ask the question, if they've gone through that period of development without developing
visceral fat
Do they have somehow protection from the diseases that come even if you feed them ad libidum thereafter?
So we did this experiment in Zucker fat animal or Zucker diabetes animal and
We took their visceral fat tell tell people what the Zuckerrat looks like. So the Zuckerrats are rats that are really, really, really obese.
Hungry all the time.
So they have hyperphasia, they can't stop eating.
Right, because they don't have the leptin receptor.
So they are hungry all the time.
And they're nasty because you try to come close to them,
they think your finger is food.
So they're eating it all the time. close to them, they think your finger is food.
So they're eating it all the time.
And we did surgery on them before puberty
because they became obese really much before puberty.
And what happened is by six months,
they all become diabetics.
Our animals up to four months did not become diabetic.
And then between four and six, they became diabetic,
although we took their visceral fat.
But what we found out that 80% of the visceral fat grew back.
So we actually had the perfect experiment,
as long as they didn't have visceral fat,
they didn't develop diabetes.
Once they got the visceral fat, they developed diabetes.
But I want to make.
And sorry, one other thing. If you took that group and who already developed diabetes
with visceral fat, and you just removed the visceral fat, can you reverse the diabetes?
No, I, we've never done this experiment. Don't know, because we're interested in aging.
But I'm telling you all that to make one point because so far the
paradox just got worse, right? The Neumatodes with the insulin resistant visceral fat leaves
longer and we showed that mammalians live longer if you take this visceral fat and make them
insulin sensitivity. Whenever we take visceral fat, we make them more insulin sensitive, okay?
Until I realized one thing, it takes me few hours to make red insulin resistant.
I give them glucose, I give them free fatty acid, I give them some other things. I can make
them insulin resistance very rapidly. So at first, I used it as you see, we can do the
chronic insulin resistant in few hours. Okay, you just load them with nutrients,
you become insulin resistant. But then I thought of the aging part. When you get glucose to the
muscle, the glucose goes into the muscle. If you're not moving the muscle, it's not going to
turn more glucose to energy. It will switch from free fatty acid to glucose, but there's no more glucose burning.
So it goes to glycogen, right?
And it goes to glycogen, but you keep on putting glucose in the muscle and there's just so
much glycogen that the muscle can store.
So the muscle has to become insulin resistance.
Okay, it's a protective mechanism.
There's no evidence that the muscle can in any way shape or form undergo to nova lipogenesis
and create any of the fatty acid, is there?
To create any of the fatty acid from the coast.
No, not.
There are any evidence that muscle can carry out the nova lipogenesis.
I don't think so.
I don't think so.
I'll have to think because I have a different...
Yeah, yeah.
I have to think about it. But the. Yeah, yeah. I have to think about it.
But the point is, okay, I understand your point.
I don't think, if anything, there's no much.
The glucose, the muscle tells the glucose, you go somewhere else.
You go to fat.
Okay.
So the only organ that can take in completely excess amount of glucose in the end has to
be the liver because it at least has the capacity to turn excess glucose
into fat, whereas all of the other organs are going to be saturated. That's true, and that's part
of I think where the glucose is going, okay, to fat and to liver. Okay, so what am I telling you?
I'm saying that insulin resistance is a protective mechanism. It's a modulator. it's a stress response, it's something. So now I understand why a stress response mechanism
in one animal caused them to live longer.
And in another animal, it's a pain in the butt.
So I went and I wrote this review with Luigi Ferruji.
I wrote this review where we took all the animals
that had problems with
their insulin sensitivity.
The animals that are insulin resistance and live longer, and the animals with insulin
sensitivity that live shorter.
And there's a huge list of it.
Repamising is an example, right?
Repamising causes insulin resistance.
And the animal is the best intervention in rodents.
There's a PTP-1, a transgenic animal,
it's very insulin sensitivity,
and it has half the lifespan.
The lifespan of a wild type animal.
When you say insulin,
resistance, insulin sensitive,
are you always referring to muscle?
Are you referring to liver?
How are you defining them?
Well, in this sense, it was everything. It was IRS, for example, IRS one, IRS two knockout,
some of them only in the brain. So it was really insulin resistance everywhere.
Is IRS one found in the muscle? It's not the liver. No, IRS one and IRS two are everywhere,
but IRS two is more in liver and brain.
Yeah, they sort of have selective expressions.
They have selective expressions.
Yeah, so I'll just translate.
IRS one insulin receptor substrate.
So let's talk about exactly how the muscle takes in glucose.
So we are walking around, if I bolus you with glucose right now,
and your blood glucose rises from wherever it is right now, 90 to 200, let's say I give you an
enormous bolus of glucose, I double it. So you're up to 180 milligrams per desolate. It's a very
high screaming high level, which by the way only amounts to an extra few grams of glucose, but
nevertheless, what is the chain of events
that leads to insulin being secreted
and the muscle ultimately disposing of that glucose,
both actively or passively?
Well, there'll be obviously a secretion to insulin
that's relative to your glucose level.
And hopefully...
So the beta cell is the sensor and outcomes insulin.
And now what is insulin doing to the muscle?
And insulin through the insulin receptor will get
translocation of the glute for those are the glucose
transporters that are the major glucose transporters in muscle.
It will go from an intracellular pool into the plasma membrane,
integrate that and starts getting glucos like crazy into the cells.
And that happens quite passively, meaning once the glute-4 transporter is translocated
across the cell membrane, glucose can passively rush in, correct?
It doesn't require ATP to bring it in a constegrate into any sort.
Correct.
And in fact, it has its own intrinsic activity that's not the energy dependent, so it can
go faster or slower by
by different ways. Now is there another method by which without insulin we can get glucose into a cell
that somehow relies on AMP kinase? Not on AMP kinase but there's non-insulin mediated glucose
uptake. In other words there's a way for glucose to get up without the insulin.
And we know that from hyperglycemic clamp and from other things that when we can move
the insulin or keep insulin level at basal, and still there's a substantial glucose uptake
that's happening. So yeah, we know that.
What's the mechanism of that? I'm not sure I know.
It also seems to be enhanced by exercise. That's true. That's true.
This ninja is the non-insurmediated glucose uptake is something that he's exercise dependent too.
And it seems to. That's why I now understand your question. He's the MP kinase. Yes.
Part of the day and I don't know that. Yeah. I only have one patient in my practice who has type one diabetes,
but he is such an interesting patient
because of his incredibly strict dietary control
and his unbelievable appetite for exercise.
And he, I've never seen a higher level of adipinectin
in a human, I've never seen a higher level of sexipenectin in a human. I've never seen a higher level of sex, hormone binding,
globulin in a human, which you're basically,
and we know how much insulin he has because he injects it,
and he injects so little insulin to himself,
and yet can seem to, you know, he has a hemoglobin A1C below six,
using six to eight at units of insulin a day.
And so what got me, that's what got me very interested
in this non-insulin dependent glucose uptake.
Yeah, I'm not doing this research anymore.
I used to be in front of that.
I glucose itself can modulate
glucose kinase activity in the liver.
There's a lot of things that happening.
And of course, there's coordination
between the fat and the liver.
And then I started being interested
because we can do things to the
hypothalamus and take over this insulin and muscle and fat and liver. We can do it all from the brain.
Isn't that amazing? Well just because I'm so fascinated by this and I think it will help the
listener to understand the complexity of what you just said.
If I took an animal and put a lesion into the ventral part of the hypothalamus, a normal
animal, what could that do?
What would that change about its metabolism?
Well, that would increase basically food intake and change a lot of the peripheral physiology, but we do basically the opposite. We give insulin to
diapotalamus or glucose or IGF or Leptin, okay, and then we see what happens to the peripheral,
though in the periphery, those hormone levels are not increasing at all. And not only that,
the liver is a good target to follow because what you can do with the liver,
you can do selective hepatic vagotomy.
And everything that you did through the brain doesn't work anymore because it needs the
nerves.
Right.
So I'll explain to the listener what that means.
So the vagus nerve connects the body through this parasympathetic system.
And of course, if a patient has a liver transplant or if you do an
operation where you sever the vagus nerve, you sever that connection between the central nervous
system and the periphery. Correct. And so we can do it experimentally and it will help us
see if it really how much of it is vaguely mediated versus not. Or yeah, or more nerve on me,
you know, it's the nerves because we do, it's not only
if I got to me, we do a little bit, uh, adrenergic too, but it's through the, the nerves and
not through a chemical reaction on the liver.
You see, this is the problem with metabolism near the more I go into it, the less I know,
it drives me nuts.
My absolute knowledge increases incrementally and my relative knowledge falls precipitously.
Well, I think I realize that you know what to ask.
So you're undermining your own abilities, but it's really the integrity of metabolism
is really very confusing to explain.
So we will define insulin resistance at the muscle, whether it be from an aged phenotype
or a diabetic phenotype, as a scenario under which a fixed amount of insulin hitting the
insulin receptor produces fewer glute-for-transporters, is that a fair definition?
Well, the definition of insulin resistance is really different and very simple. It's all about the glucose
uptake in the muscle release. It's all about the ability of insulin to clear glucose. Okay.
That's the only way we define clinically insulin resistance, although that totally misses the point because those
insulin levels have different effects on different tissue, but for us, the
insulin sensitivity is totally related to the glucose uptake. So let me give you
an example. So when I use an oral glucose tolerance test with my patients, I'm a
bit of a stickler. So if they take their 75 grams of glucola, I measure their glucose and insulin
at baseline, administer the glucola. 30 minutes later, 60 minutes later, 90 minutes later,
and if I'm feeling aggressive, 120 minutes later, we re-measure the glucose, the insulin,
and the FFA, and maybe even the CPAP type. But for simplifying it, just the glucose and insulin.
So let's assume you
have two patients who start out with a fasting glucose of 90 milligrams per desoleter and six
insulin of the IUs of six. They both get their 75 of glucose, and let's again simplify this by
just looking at one hour what happens. Both of them at one hour have a rise of glucose from 90 to 130 milligrams per deciliter.
One of them did so with a rise of insulin from 6 to 20.
The other did it with a rise of insulin from 6 to 90.
They've both disposed of glucose with equal magnitude.
Would you describe them both as equally insulin sensitive?
It's a little bit complicated, you know, first of all, so let me just say for aging, 120
is not enough, in elderly, the glucosaurants go. So the rising insulin is changing throughout
normal physiology and throughout individuals. And you must have, you might have missed some of the insulin picks earlier on or later on.
Yeah, the third, looking at 30 versus 90 is a big insight.
And, and you're right, I mean, Joseph Kraft, who is a pathologist who has done a lot of work on this,
he samples to five hours.
Now again, clinically that's challenging
in the regular day to day practice,
but in the laboratory that's feasible,
and you're right, you can see so much happening beyond that.
But I tried to pick an example that was
as egregious enough in its difference,
that what I'm trying to get is the difference
in hyperinsulinemia and whether that factors
into how we think about insulin resistance.
Right.
Now, I don't think the clinical world is thinking like that.
So I'm actually an active endocrinologist.
I still see on Thursday, if I'm on time in town, teaching fellows in diabetes clinic,
want if you're a hospital.
So I am involved very much in this field and I'll tell you that we rarely
measure insulin in any of our patients, but that's not really your patients, okay? I'm talking about
what's the use of measuring insulin in type 2 diabetic patients. So it's a different issue, but
yeah, this is sounds like there's a different insulin response
to lower the glucose to the same extent.
Because the hypothesis would be that the patient with hyperinsulinemia is now demonstrating.
I mean, that's basically a harbinger of the first one who's going to struggle with glucose
disposal. That would be my hypothesis is the one who needed 90 units of insulin to dispose of glucose with
the same efficacy as the person who needed 30 is sooner rather than later going to have a harder
time disposing of glucose. Well, you know, there is another possibility that those are the people who
get other diseases for a slayer like heart attacks or stroke. In other words, their insulin resistance will affect a lot the way they do the atherosclerotic
plaque.
And you know, this hyperinsulinemia on organs that might not be insulin resistant even,
right, on cells that not coming into the insulin.
So I would say that they could either the one who become diabetic or the one who are
going to get macrophosphor disease much faster.
Which brings it right back to our observation of glucose versus insulin, micro versus macular
vascular. That's a very good point. So how does insulin signaling work to get glucose into the liver?
The liver has a different glucose transporter. It's a glute too, that is not translocated
and that is the major way by glucose gets into the liver.
So it's a little bit different, but it's not stimulated the same.
So it's constitutively expressed across the membrane?
It's not stimulated really by insulin as much.
So it's more gradient driven to get the glucose from the circulation into the liver.
And that's where the portal blood is.
So there it's very sensitive to the increasing glucose concentrations.
Well, that's very interesting because there's lots of evolutionary reasons why that would
be a fail safe, right?
Given the importance that you would never, ever want the liver to be denied glucose, given
that if you ever shut down the liver's ability to make glucose, by my calculation, you could
live about six minutes.
Yeah, look, I was an intern of Sheila Sherlock.
She's Dame Sheila Sherlock in England in Royal Freos, but very known at Pathologies.
And she asked a group of us, what's the main role of the liver?
And I raised my hand and I said, it's to produce glucose.
That would be my answer, and everybody laughed at me.
And she threw chalks at them and stuff.
And she said, just a minute, why are you saying that?
I said, because if you take the liver out and clamp the vessels,
the guy will die from hyperglacemia, which is absolutely true.
Yeah, yeah, it's, um, I, you know, maybe it's just because I'm in the midst of writing this
chapter for my book about the liver, but I literally yesterday I sat here in my room
and penned out the calculation of 180 pound person with blood glucose of 180 milligrams
per desoliter, clamp the liver, how many minutes
until they die? It's about four under those conditions. Can you imagine that? Think about
like what this beautiful organ has to do.
But you know, another thing to consider in your example, right? So for example elderly Have enough insulin to suppress glucose production glucose production is easier to suppress
then
It's suppressing lower level of insulin than stimulating glucose uptake in the muscle
Deliver is more sensitive than the muscle and so elderly
muscle. And so elderly have the ability to suppress a particular glucose production because they have enough of insulin to do that. But when you start giving them food during the day, they fail.
And they become glucose intolerance and diabetic. They might have diabetes, although their their basal level are well, just because of this, this enough insulin to suppress glucose
production and not enough to increase glucose uptake. So the sensitivity of the tissues is
really, to insulin is really part of what you're describing. If you look at the basal,
it's very different when you look at the challenge. That's such a great point.
And I won't go down that rabbit hole anymore because I would love to, but there's so many other
things I want to talk about near.
Let's go back to Metformin and let's do it now through the context of an anti-aging drug.
So there's going to be some people listening to this who already know everything about you.
If for no other reason, then the efforts you've put into tame.
Obviously, I want to have plenty of time to talk about that.
But let's back up for a moment.
Tell me when you first realized,
hey, this metformin drug that I worked on 30 years ago.
It's not just a great drug for people with diabetes.
This could actually be a drug
that helps someone without diabetes live longer.
What was that epiphany for you?
So first of all, there were studies on the biology of aging in rodents. And the first guy,
which I'll be embarrassed now to forget, he's a guy from Leningrad, that was the first to say,
I've done rodent studies and animals with mitformin anatoly. I'll remember it maybe later.
And he showed that life extension increases in variety of animals to which he gave metformin.
That led to some studies. What was his hypothesis to your remember? Why would he, what would he,
what would he, what drove him to what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would he, what would different effect and then he considered it to aging,
but at that time, this was in the 80s when he started debt and he thought, I don't remember
his name. That's okay, you remember? I should take more of it forming. And he was pushing,
he was showing up in meeting and showing. And so people have tried to do it in the United
States and they
showed that there is a significant effect on insulin. By the way, the effect of insulin
in animals is 10%, not like, weaponizing this 24%. So there is a milder effect, but in every
study, they showed that health spend is improved by 50%.
So the effect on longevity was less than the effect of health.
By the way, that's perfect for what I'm trying to say.
I'm not for longevity, I'm just for health spend, right?
So if we can leave healthy, healthy, healthy, die, that's fine with me.
Yeah, the so-called squaring of the longevity.
Squaring, right, squaring of the longevity.
So he started the Asimov, his name is Asimov. So that's what Asimov showed. People have started
looking at that. They've, they're several studies, three studies that gave it also to Nehmetot,
they also lived longer. And there's several effects on health spend in the biology of aging. Now, the reason there's a lot of needle threading here in my story here, okay, but I want to
tell you the moment that I knew we have to do this study was a publication, not in a very high impact journal, but it was an amazing study
that could be done only in the UK, because in the UK you can go into pharmacies
and look at prescription that they gave, and you could follow the mortality of those patients.
Because the NHS system allows you to centralize everything from prescription to usage to mortality.
Exactly. And they're probably, they don't need to be de-identify after mortality. When you're dead,
you're not private anymore.
So they did this study. So what they've done, they're forearms to this study.
They came and took patients who are on sulfonyluria, 12,000 patients.
And they matched them to 12,000 people without diabetes.
They match them to 12,000 people without diabetes.
Same pharmacies, same doctors controlling for some other things.
And of course, the people in Sulphanileuria had higher mortality than their control.
Because of course, they had a reason
to be taking the self-nuria.
They had diabetes.
So that's okay.
Then they took 78,000 people on metformin. And 78,000 people
who were non-diabetic, again, matching them. And the 78,000 on metformin was metformin
monotherapy. Monotherapy. First line. Right. And they watched their mortality. So just to
and they watched their mortality. So just to
underline again, the people on mitforming had diabetes. The control didn't have. They were more obese than the control.
They also have more diseases than the control.
But they had significant less mortality, 17% less mortality
mortality, 17% less mortality in the metforming group. And, you know, the sulfonylorea group was, okay?
So, if you get less mortality with metforming,
when the set-up is diabetes, that really shows that metforming has a very important effect in humans as far as aging.
What was the median dose of metformin in those populations?
They were over 1000 milligrams.
That's it, just 1000 milligrams.
Well, they intended more, but the average was about 15 milligrams.
You know, I don't know.
I would just 1500?
Yeah, no, 1000 milligrams. I'm sorry.
They, this is a discussion there. I don't think they really could validate the dose.
Because an elegant thing to do if you have 78,000 in your database is now stratified by dose. Absolutely. Who's taking 500, 1,500, 2,000?
They couldn't do that.
And I really cannot answer you if you can get back to the data or not.
I really don't know.
Those would chose came from other studies.
But you know, that's not the only thing we know about mid-form.
What was the time course of that, by the way? Do you know how many years five years more time?
So five years exposure to metformin or five years of
prospective mortality following?
No, it's well, it's all it was all a prospective study.
Okay, it was all a prospective study when they started.
Okay, they went back.
They looked at everybody
on metformin.
Oh, I guess what I'm asking is, do we know how long they needed to be on metformin to
achieve the benefit?
No, no, we don't know.
Okay.
So we followed them for five years of mortality in a prospective cohort, but they could have
been on metformin for five years or 25 years, we don't know.
No, no, it's newly, it's newly prescribed metformin.
There were not more than five years.
So we have normalized by duration.
Absolutely, absolutely.
No, they haven't been on metformin before.
Those are newly diagnosed type 2 diabetes.
So, near that's a pretty to be blunt,
God damn staggering result.
So my metformin moment, nowhere near as the dramatic as yours,
be basically came out of a research project I did with two analysts in 2013, and I
don't even remember what prompted the question, but there was a question we had
internally about what was the benefit of Metformin? Oh, I don't know, now I remember the question.
The question was, was there a relationship between hyperinsulinemia and breast cancer?
This was the question we wanted to ask. And as we dug and dug and dug and dug and dug,
something kept hitting us over the head, over and over and over and over again, which
was with or without diabetes, with or without obesity, with or
without hyperinsulinemia, any way you sliced and diced the data of people with type 2 diabetes
within without metformin, they got much less breast cancer, which then dug us down a rabbit
hole if they seemed to get much less cancer, which was, you know, that was a big aha moment. Right. And there are hundreds of studies that show the association
between metformin and less cancers.
And not only that, less, all cancer, except prostate, by the way,
prostitutes hanging there, maybe a little bit.
And when we went, and I'll tell you later, but when we went to the NCI
to make them partners in this same study
It was really interesting. Can you tell people what tame stands for?
Tame stands for taming or targeting aging with mid-forming and it's a study that's designed to prove the concept that aging can be
targeted but also
mainly for me is for the
FDA to give an approval to an indication that's like aging.
The first time I heard about tame was actually here in this city. I was having dinner with Steve
Osteved. It must have been in 2015, maybe 14, 15. Steve is a gem of a human being. I consider
him certainly one of the most important mentors in my exploration of this field of aging.
We're partners in many ways.
He's a great guy.
He is.
He is one of these guys that has his knowledge is out of control.
You can't ask him a question that he doesn't know where to go for the answer.
I have the highest respect for Steve and can't wait to interview him here as well.
But I remember him telling me about this.
My first thought was, Steve, that's a crazy idea.
The drug is free.
Who the hell is going to pay for this study?
NIH can't pay for it because they don't consider aging a disease.
Farm can't pay for it because there's no way to make money on it.
I mean, I might pay like 10 cents a year for my supply of metformin.
It's a free drug.
I said, you're doing the wrong study, man.
You got to do this with rapamysin.
So, talk to me about the challenges of this.
This is, you're proposing something
that has really never been done before.
Can I just ask you, are we going back to mid-forming?
Because you asked me about diabetes,
but not mid-forming action.
Will you ask me later?
Absolutely.
I cannot wait to dive into mid-forming.
Yeah, we're not going to get off this topic for a while. So yeah, so, so look, if I'm answering now, why I'm
at forming a not a repamizing, you don't need to answer that question.
I was just sort of teasing Steve that day, but well, there are people who are asking.
And of course, metformin, we have preliminary data.
We have the concert.
We have clinical studies, you know, clinical studies of metformin, the diabetes prevention program, it prevents diabetes. The UKPDS, it
prevents cardiovascular disease. The Alzheimer literature, there are two clinical
studies to suggest that in mild cognitive impairment, it improves some domain.
By the way, like name recalling. Assimov. We'll up your dose after dinner.
So there's lots of money and safety.
Look, if we're going to have a new indication,
we don't want to kill anybody on the road.
With rapamycin, we won't be sure.
And it causes diabetes and it causes
a testicular atrophy and cataracts in animals.
Okay, so we have to play it
safe. So I would only add one caveat in defense of rapamycin, which is with constitutive dosing.
Right. And you're you're aware of the studies from John Manic, right? Yes, of course.
The last ones. Yes. Okay. So my view on rapamycin is it should not be doseed every day.
Exactly. It should be selectively dose to target target M4 Complex 1, leave Complex 2 alone.
Exactly.
And I will get back to that because I'll tell you what we've done with Metformin for
the biology of aging part.
So that's why the fact you look, we are a bunch of professors, including Steve Austin.
We go to the FDA.
By the way, beautiful movie by Ron Howard.
He went with us to the FDA to the Senate.
Wait, has it been released yet?
It's documentary.
No, you're in a half ago.
It's I'm sorry that I'm anxious.
It's called the age of aging, it's national geographic, it's the best movie that was done ever
on aging. It's really quite incredible. Ron Howard is narrating it.
I remember, I'll tell you what, I was having dinner with Steve at some point during, he was
here in New York for that being filmed.
So we're a bunch of professors that are coming to the FDA and kind of telling them, you know,
you know that aging has biology, but this biology also can be targeted.
And they said, so what?
We said, well, if you slow aging, then you prevent a bunch of age related diseases altogether.
And I said, well, we're interested to hear. And we went through this discussion with the FDA. I would say that the most interesting part and you'll appreciate it because you're diabetes centric. I see your I'm actually not. I'm purely I'm purely
aged centric. I am your metabolic. But I'm diabetes. I think of diabetes as a great example of what
happens when you don't fix things earlier. So we told them basically we came and we said we'll
do a study and what we're going to see is cardiovascular disease and cancer and Alzheimer's mortality and diabetes.
And I said, not diabetes. You said, what do you mean not diabetes? I said, no, diabetes, look.
You diagnosed diabetes. First of all, you diagnosed it on a chemical test. You know, you decide.
Yeah. And only 40% of them, 10 years later, will get complication. We're really not interested in diabetes.
Wait, wait. Did the FDA actually say this?
Absolutely, absolutely said it.
And by the way, I should add that there's another bunch of people who came to tell the FDA
that they should allow me to form in for pre-diabetes because the DPP said forming prevents diabetes
by 30%.
And the FDA said, well, if you think that's important, why don't you make
the diagnosis of diabetes in 5.8 andoglobin in one C? You know, it's not up to us
to do that. And they wouldn't give them an indication for prediabetes.
That's a very counterintuitive point of view when you consider the long term, not short term.
The short term cost burden of diabetes is relatively trivial, but it's that long term cost burden
that becomes quite elaborate. You know, it's very boring with you because we have the same views.
You're right. So yeah, so okay, but so we had to adjust our study. We had to take diabetes as one of the outcomes.
Yeah. And put in and you know just increase the number and take diabetes out. It's not that we're
not going to follow the risk, but FDA is not interesting. Yeah. So the really the challenge was how
do we define aging in a clinical study? Because one view, well, let's because you can't use survival
overall mortality. Well, there's no, there's no biomarkers to aging. All the diseases are, are
their major risk factor is aging, you know, so how do you define it? And we basically did a lot
of work and published a lot of work and showed that, okay, let's take somebody
who has survived cancer and he's 65 to 80 years old.
What's his chances of getting cardiovascular disease, cognitive decline, mortality, right?
The other things.
And let's say it was 10, okay.
And okay, now let's switch it around.
Let's take somebody who had cardiovascular disease.
What's his chance of getting cancer and all the other?
10.
Okay, let's take somebody with Alzheimer.
What's his chance of?
It really with aging, it doesn't matter.
The disease you get first depends on, you know, your genetics and environment.
If you have a mother who's diabetic and your obese,
you'll get diabetes first, okay?
But really, because we age biologically,
in different way, whatever it is, the next disease,
you're going to get the next disease,
and we don't know what's the next disease,
but that's what we're going to prevent.
That's sort of like, it's a really interesting idea you proposed because it's in lending,
you would call that asset value correlation. So you'd say, well, let's say near comes to my bank
and he has a credit card and he has a car loan and he has a student loan and he has a mortgage
and he has a personal business loan. Which one is going to default first?
I don't know. I mean, I could sort of tell you. Which one is going to default first? Yeah. I don't know.
I mean, I could sort of tell you, typically people are going to stop paying their credit card
before they stop paying their car and their mortgage.
But boy, once you default on one, those dominoes start to fall very quickly.
And so that would have what we would call a very high asset value correlation of default.
Yeah.
And sort of like, this is the same for disease.
Yeah, I think you're
right. I'm I'm saying it a little bit different. I'm saying I'm agnostic to the disease. To which the
first one is, yeah, it's just I'm agnostic. It doesn't matter what you come and what what you're
going to have. I'm going to prevent whatever it is. That's why we have a composite, okay, a
composite. And people get very prickly about composite outcomes. Very.
And I got it, I'm going to get on my soapbox for a minute here because this pisses me off
to no end when people get all bent out of shape about how you can't have a composite outcome.
And this is the bias against aging, really.
Because in the end, what matters is how long are you alive and how long is your health
span optimized?
So I'm sorry for I made that rant as short as I normally could.
Normally that would be a 10 minute rant.
Well, that would be a 10 minute rant for me too.
Okay.
Yeah, absolutely.
And this is where we get into trouble.
I'll tell you what the other pieces, but we had our grant review that the NIH and unfortunately.
And is this inside any of the groups except NIA? Like is NCI weighing in on this?
Yes, yes. I'll tell you what we've done. I'll tell you what we've done in a second. Let me just
make sure that I say that. So our reviewers were not gyrosanpt because we everybody is involved and we have 14 centers.
Okay, so everybody is involved.
So the reviewers are from other place and they just, they just, just a minute.
You're saying that aging can be targeted and one drug can do it.
You're crazy.
Okay, there's no such thing.
Why don't you do three studies?
One study is metformin cardiovascular. One don't you do three studies? One studies met forming cardiovascular one studies met forming cancer
one study and we're saying no
Because what are we doing? We're trying to give aging and indication
Suppose we do it's just such an anthem up to the way they think and I'm not saying that to be critical of them, right?
But they're in a silo. I, which is if you come to NCI,
how can you care about anything but cancer?
Right. I know.
The silos are really, are really killers.
But for us, so you could say, well, let's do all those studies.
But for us, we're calculating the power.
I was just about to say the power analysis on that study
is going to quadruple your budget.
Well, for what they decide for the silo state. the power analysis on that study is going to quadruple your budget.
No, well, for what they this, for the side for the side of the side, for us, it's not only it's not only the budget, we don't want to stop
this study. Let's say that we show in two years that we delay cardiovascular
disease, it's significant, they'll stop the study and they said, no, everybody
now has to be on med forming, but we wouldn't be able to show the FDA
that we are aging. For us, aging is the stop telling us diseases. We are going to have a cluster
and we're just going to delay the aging. So we'll get the health spend extended by two,
three years. That's what we're trying to show you. And the significance is for the cluster,
not for the individual disease. And if you tell me to do individual disease And the significance is the for the cluster, not for the individual disease.
And if you tell me to do individual disease, I need triple the budget and I'm not going to get
to the FDA with the indication for aging. So it seems to me that the biggest challenge here
is not the funding, it's not the study design, it's the conceptual leap, it's a completely
different paradigm of how we think about the
laying death. Correct. Correct. Where do you stand today? So I'll tell you a few
things. First of all, we conceived it. I got my friends to what I call a
prison, a French prison in Spain somewhere. We were in a parador in the middle of
nowhere in Spain for several days, saying, whatador, in the middle of nowhere in Spain, for several
days saying, what do we have to do in order to open the field for aging to allow us to
get to treatments? And we decided several things, but one of them is to go ahead with time.
By the way, I'm saying French prison because the food was good, but it wasn't Spain. And
we started, and I started getting those people, those
clinical people together, and we started really thinking through for what it takes, for what
it takes. And we had this whole academic and wrote papers in order to say how we're thinking,
how we're thinking of cluster of diseases, how we're doing power calculations for targets
aging and stuff like that.
We really spend a lot of time with the best people.
Now our friends came to us and said, just a minute, your study is $70 million.
If the national issue of aging is going to spend $70 million, that means the national
issue of aging is very small.
It's just 3% of the budget, although we are 80% of the diseases, right?
Then we won't have money for the grants.
And I said, well, what I'm going to do is two things.
First of all, half of the money is going to come
from somewhere else.
That's my association with AFR,
where Steve and I are the scientific directors.
And for AFR, I got the other half.
So the 40, 35 million is already waged,
and that's mostly philanthropic.
Right.
And then we went among the institutes.
And so NCI should chip in.
NCI, NHLBI, and IDDK.
They didn't commit because first they have to see the review.
OK?
Or they have to have the decision that then I want. I would tell
you though that the NCI director is a good friend of mine is waiting for tame to come, you
know. He is like, where is tame? So the NCI has committed. It's basically a bunch of contingent
commitments. Yeah, I just want to say committed is the wrong word because they didn't have a budget
yet and the grant didn't come to them. But I know that they will give them money because their head will do it.
Yeah. So that's good to hear. So realistically, when is the soonest you would begin enrolling for
time? You know, I'm waiting for something to know next week. And if next week goes well,
so I just want to let you know that we have an alternative.
The alternative is not for profits.
That the reason they haven't joined us
is that their charter is not to fund anything
that the NIH funds, they want something riskier, of course.
So if the NIH is not funding
because they feel it's risky, those will
fund. So we can start anywhere and it's the answer is early 2019. Okay, we're basically
all our centers are ready to go. How many centers? 14. How many subjects? 3000. Age. 65
to 80. Any limitation on comorbidities? No, in fact, well, there are a lot of limitations,
but we're very inclusive, but no, no existing diagnosis of cancer. No, unless they're cured.
Okay, so you could be in remission, but you can't have active cancer. Yes. You could have
secondary prevention or primary. You could have cardiovascular disease, you know, in the past, if you're, if you're
okay now, you could have mild cognitive impairment. And low speed walk will be a criteria. So, in
other words, we don't want the people like in my study who will become centenarians because we're
wasting, we're wasting time on them. We want people who we know are kind of in the midst of aging and we know that it's never too late to target aging and that's who we're so 65 years and up five years
studied and
You're gonna randomize one to one or two to one one to one and the placebo versus what dose of metformin two grams?
1500 so you know. So first of all, I should tell you that
Merck company from Germany is giving us
the placebo in metformin.
Right.
So the drug is free.
So when you say nobody's interested,
it's true.
It's generic, but actually Merck has the worldwide
license for metformin.
And they're actually giving supply to lots of studies
because they kind of realize that this is good.
And man, do you think there's a difference
between generic metformin and branded in terms of efficacy?
Is there any reason?
No.
So they're really, this isn't necessarily
a creative to them because one can buy
metformin, generic, anywhere.
They're not going to make more money from giving us this.
Well, I should say, even now, a lot of them at forming suppliers have higher
sales and a lot of them are non-therbetic.
Yeah.
So this thing, which is, which is bad for me because I don't want too many people to know
that, right?
I want to do this study.
I don't want, and I don't want to be.
Well, you'll have, you know, I don't want, and I don't want to be. Well, you'll have, you know,
I don't think, hopefully it won't impair your recruiting.
And the power analysis, I mean, it's funny.
Honestly, near, I would have guessed,
but this is, this speaks to the non-linearity
and complexity of estimating power.
You can't do it without the tables.
I would have guessed you needed a bigger end
than 1,500 in each group.
You are using 80 or 90% power.
90% power, but I should tell you, look, for every disease,
we have almost a 30% effect, and we chose 22% effect.
Okay, for every disease, we have preliminary data
for the same.
Got it, so you lowered your threshold to call it 20%
from 30% and at 90% power, you've hopefully powered this.
You've got buffer both on your power and effect. And again, we don't want to stop the study early
either for one effect. So we carefully thought about it. We ask for a grant for six years because we don't want to overdo it
Okay, so it might finish in four or in six, but we have the flexibility to
Look at that any non-US centers are they all US? No, we decided to do only in the US because of
communication and because look
because of communication. And because, look, outside of the US,
people came and said, you know, we'll fountain.
But how, you know, if they say after two years
we won't fount them, you know, it's very different.
Because if it's a center,
they need to be part of the power
and we cannot afford to lose them.
So we, you know, those and other consideration we decided to stick
with the United States. So let's go back to what we really glossed over, but now I want to dive into.
Why do you believe at the cellular mechanistic level metformin is an anti-aging drug? So let me
take you through that in a, I don't want to say schematic way because we don't have
the scheme here, but in a way that maybe I think will be easy to think. So I want to start by saying
that studies have shown that some of the effects of metformin are through AMP kindness and some
of them are independent of AMP kindness. Yes. Okay. Is it important not for metformin, but I don't know which are the ones who are relevant more for aging?
Okay, and it's hard to know, and it'll get complicated in a second more.
So metformin gets into the cell through a transporter that's called OCT1.
This transporter is not equally in every cell.
So, unlike performing that goes without other transporters and affect everything,
metforming is peculiar in this way, but we have the preliminary data.
And it binds to complex one in the mitochondria.
Does it do so preferentially? Does it gain entry preferentially into the liver in humans?
Only in the sense that there's a nice concentration of OCT one in the liver, but it's not, I don't
think it's the top other organs have.
So basically, it's more about OCT distribution and expression.
Maybe it's more.
It's more that I want, I want met forming everywhere.
Okay.
I want met forming everywhere.
And I'll tell you how I kind of proved it.
So now met forming binds to complex one in mitochondria.
I'll tell you that met forming has some action, epigenetic action that are independent of the mitochondria. You can do it
with what's called row zero cells. You can you can you can deplete mitochondria and see and
measure things and you can measure things even without mitochondria. Okay, again, do I need the
mitochondria? What type of epigenetic changes do you see in the row cell?
In histondia situation. Okay, so I cannot argue that this can be important.
It's not important if we use metformin, but it's important if you want to ask me,
are the mechanism that forming AMP dependent, mitochondria dependent?
So there's an HDAQ property that we may not dependent, mitochondria dependent.
So there's an HDAQ property that we may not have even thought of before.
Right. Okay. So it gets to the mitochondria.
And in the mitochondria, it basically changes ADP, ATP ratio.
And that's a lot of it is important in the liver, but not only to the extent that there is an activation of AMP
kinase.
And near, is there a demonstrable reduction in NAD to NADH in that cell when complex one
is inhibited?
Yes.
Yeah, absolutely.
Those studies have been done.
So there is a lot that's going through AMP kinase. And I would tell you
that downstream of AMP kinase, there is mTOR. And it depletes, it decrees mTOR activity
and increase autophagy. And there's a whole pathway that will go to the pillars of aging.
You know, I asked David Sabatini this question a month ago and where he doesn't know the
answer, but
I'm hopeful that maybe one of the post-docs in his lab will start to figure this out.
I'm very curious about what the dose equivalent is between, in terms of purely looking at
the readout of MTOR inhibition, what is the dose to dose equivalence of metformin via AMPK versus RAPA directly?
And I haven't, I mean, David didn't know the answer, which tells me nobody probably knows the answer.
Right. Look, it's really difficult. First of all, for example, lots of the non-AMP
kindness activities are on much higher doses of metformin.
Well, that's my point is, can you clinically match them? No, because you really don't know at the end how much metformin is in the cell. What we're doing
now, we're doing isolated cells. In other words, we treated animals with metformin and we're taking
isolated cells to just see the variability of metformin in individual sales.
Even amongst homogeneous tissues. Yeah.
Like we take a pathosites and look at the.
A variability of expression. Yeah. Right.
So it's all kind of important question, but the story is still I'll tell you the story
because at the end I'm going to answer you what is
doing for aging, okay? And I don't want to rush this story because this is a great story.
You take your sweet time. So think about it in a scheme. You have the
metformin in the middle, getting through the plasma membrane, getting to the mitochondria.
And on the left side, let's say, there is the AMP kinase. Now, in the right side.
Oh, sorry, just for the listener, explain what AMP kinase
does at the high level.
It's a hormone of what?
It's a hormone of nutrient deprivation,
and therefore, it tells the body to do what.
Like, when you don't eat for a day, AMP K goes up.
Why?
Well, but it's also an exercise mimetic pathway. Yes, that's what happens with
the exercise really. That's what the hope of what AMPKine is doing, but it's a nutrient sensing
that is in part upstream of MTOR. Okay, but the other side of metforming is what happens to the mitochondria because in a way, and I hope
I want to regret saying it here, but metforming is a weak cyanide.
Okay. Look what cyanide acted at complex for right, but right.
Oh, you just mean more broadly speaking and inhibiting the ETC.
Right. It inhibits right. It inhibits. So there is less ROS production, okay?
And then there is less inflammation.
And there is other things that's going just because the mitochondria is less oxidative
pathway going down.
So this is a great example of why binary thinking doesn't do very well in biology, right?
It can't be all or none.
Well, so now I can go on and on and connect all those to eventually the pillar of aging.
But I want to insert another thing because other things are happening, for example,
insulin levels goes down, right? Why? Is it just due to the reduction of a paddock glucose output?
I'll tell you why I think. And then also inflammatory factors are going down.
And there is a whole NFKAPA-B action of metformin that might be part of the ROS and part
could be independent, even without mitochondria.
Okay, it's that confusing.
But this is the point I want to make.
I don't know which one of those is important for aging, but parts of what you are measuring
is the following.
You fix the aging on a cellular level.
Okay, so the younger, the cells are younger, a lot of things are correcting themselves.
So I think at the end, the lower insulin levels, the low inflammatory are not necessarily
a direct effect, and that's why we're fighting all the time about modement for me is doing,
because you can measure lots of things, but the things you're measuring are because aging was fixed.
And once aging is fixed, then there's whole,
hemodynamic, readjustent, or whatever you want to call it.
And then you're measuring that everything,
and this is not only typical to metformin, this is with rapamycin, with resveratol.
You also can see that there's a lot of things that are improving themselves.
And I think we have to get used to the fact that when you have a drug, that we argue what it's doing because everybody is measuring something,
some of it is true, but it's like secondary. It's you fixed it. How did you fix it?
Yeah, it's true and unrelated. And it's one of you, you mentioned those three,
which again, I think speaks to an advantage you have with tame.
So when you look at Rapa Mison, Rysvera Troll,
and Metformin, the big advantage of Metformin
is you already know the dose and the frequency.
With Rapa Mison over dinner tonight, I'm going to give you my philosophy on the dose and the frequency, and RAPA Mycin over dinner tonight,
I'm going to give you my philosophy on the dose and the frequency,
and we can discuss it, but I can't demonstrate it to you
with anywhere near the validity that you could do the same with Metformin.
Had a wonderful discussion with David Sinclair,
and Bioavailability came up on Resvera Troll, right?
So maybe all the trials that say Resvera Troll is meaningless
are simply not looking at what happens if you get enough Resvera Ttrol, right? So maybe all the trials that say Rostravera-trol is meaningless are simply not looking at what
happens if you get enough Rostravera-trol in the right place.
And again, it's amazing to me how many times in biology we can
make mistakes of the first order because of a third or fourth
order omission. And this, I guess I don't think I realized it until you just gave that explanation,
the value of effectively millions of patient years worth of data on metformin, not just from a
safety standpoint. By the way, it's billions. It's billions years. Yeah. So billions of patient
year data on metformin, I know that from an FDA standpoint, the highest
priority is safety.
That's a low bar to cross.
The more interesting one from the standpoint of this study is actual efficacy.
And it seems like if I'm hearing you correctly, metformin is an amazing B student.
Let's not be insulted by that.
What do I mean?
Are there better ways to inhibit Ross if you want to hammer the Ross chain? Probably. There's clearly better ways to inhibit M-Tor if that's all you
want to do. Are there better ways to modulate H-DAC? Yes, I'm sure there are. But it might
be that maybe part of Metformin's beauty is it does so many things at a B-plus level.
Never it's an A student, but it's not a D student.
And it's never, you know, I mean, I'm sort of thinking about this
sort of in a tongue-in-cheek way, but it seems to do so many things reasonably well.
Well, I call it form in a tool, from my perspective.
It's just a tool to show that we can target aging,
because I think that there'll be much better drugs and combination drugs
than other in the future. Human lifespan is 115 years. We argue. Maximal life. Yeah,
yeah. Maximal life. We argue because there's somebody 122. But there's a statistic thing. So,
okay, we die before the age of 80s. So there are 35 years that as a species without,
not that we cannot change more, but just now, without thinking
too much futuristic, long-hanging fruit that we can do. And Mettformin is the perfect tool
to start showing the proof of principle here. But the future is much better. It's just
you have to to pave the road here. This is a beautiful pivot to something else I want to discuss with you because unfortunately
I could talk about metformin for three hours, but there's so many other things I want to
discuss with you near based on your work and you just alluded to one, which is the work
that you and your colleagues have done on centenarians has been very influential in my
thinking. So, as I think about aging clinically,
I ask the question, start with the existence principle.
What does it mean to live a long life?
Is there proof of this having existed?
And there is.
We have centenarians. They exist.
My hypothesis, when I first started reading your literature, which was only about
five years ago, my hope, I should say not my hypothesis, my hope was that whatever genetic
benefit they had, which it became very clear to me very quickly, that this wasn't about
what they did. In fact, they seem to have almost near immunity to the worst behaviors imaginable.
My fear when I read your first paper, which was a review paper, I can still see it, and
I still remember where I was sitting in a Sheridan hotel reading it.
My fear was, whatever blessing they had, it had nothing to do with chronic disease, and
it had to do with something nebulous
and they had complete immunity from chronic disease and they just died in car accidents.
Like they eventually just died because something else tripped them up and what I took away
from your work was no.
Their genetic gift was a phase shift and when they got chronic diseases, they still died
of heart disease, they still died of cancer, they still died of Alzheimer's disease, they
simply got a 20 year bonus, if not more, maybe 29 on average, you could calculate,
call it a close to 30 year bonus. Well, of health spend. Yes, yes.
Because completely functional life. Because they had compression of morbidity. So it's not only
that they lived longer and they lived healthier, but they died quicker.
They died quicker at the end of that.
And you know, it's interesting, the CDC, the Center for Disease Control have looked at
the last two years cost of life of people, you know, with different stuff.
So they looked at people who died at 70 and after 100.
And the cost of dying after 100 was third of that of dying in 70. So it's not
only in our study, there's actually evidence. Wow, I didn't know that. To suggest that the medical
and by the way, those when they were 70, they didn't go to the doctor, okay. So the and this is the
base of this concept that's called the longevity dividend. Okay.
What what will happen to society if will actually be healthier for two and a half years and
and the benefits are immense. You think only of you know, so we pay social security more and stuff,
but there are seven trillion dollars just in saving of medical cost if you could just leave
health here. So I know you don't spend an enormous amount of time anymore thinking about the centenarians,
your literature, follow it very closely.
You definitely are spending much more time talking about it, writing about the things that
we just discussed.
But if you could go back in time a little bit for me.
By the way, that's not true.
Maybe it's just selectively where I'm reading.
Well, no, I think that's what's interesting to people now,
and I'm very happy about that.
But I just got the longevity, the Ipsan longevity price,
and my talk was actually about centenarians,
with a little bit of my hypotelamos stuff
that was related to something.
But the centenarians are, and we have lots of grants
on the centenarians because, you know, there...
Is that talk, by the way, is it something that people can watch no no it wasn't
record it's a shame it's a real I thought about it but this talk it was fun for
me to give because it was reflective a little bit you know one of the things
that's always funny for me is people say oh you know I have I can measure
this thing I'm sure that centenarians, they have, they have high level
because high levels are good.
And I had to put in to rest the fact that the genetics
of centenarians is really great for me.
But the phenotype is not because you have a hundred years old
and you can measure something that can reflect
what brought you here
or the fact that 30% of them are going to die in the next year. So it could be a marker of
of death and not of longevity. The phenotype makes doesn't interest to me. That's why I have
their offspring because their offspring will have the phenotype or half of their offspring will
have the phenotype. But those things were something that was nice because so many people are saying,
we should measure in centenarians. No, we are, we're doing a longitudinal study on their offspring
and their offspring are equal everywhere to our control group. They just have half of the diseases.
Although, you, by the way, that's a really interesting point near. I never once thought of that.
I never, what you just said, that if I have a hundred-year-old centenarian in my study and he or she
has a C-TEP mutation or an APOC3 mutation and I look at the predictable phenotype because
I know what you should have if you have that mutation.
Hypofunctioning APOC3 should have low triglyceride.
But technically without a little more
longitude and a legwork, I don't actually know if what I'm measuring as a result of that.
But that said, there must still be some benefit in, you know what now that I'm saying
it, I realize you can't do it.
The dream state would be to have health records and phenotypes for centenarians that go 30 years back.
In other words, it would be beautiful to follow a centenarian from 70 to 100 with phenotypic data.
So that's why we have the Longevity study. It's a longitudinal study of offspring of centenarians
and people without longevity. And we're going forward. We're already 10 years into the study.
And we're starting to see the differences between those guys
It's different population. They are aging slower. Okay, the children of centenarians. So we have some of these things in mind
What are the most important genetic differences between those either
Centenarians or offspring of centenarians and the rest of us?
those either centenarians or offspring of centenarians and the rest of us. So it's very interesting and so this is a part that you haven't heard so
from but it's actually the growth hormone IGF axis. We have probably 60% of our
centenarians have genomic reasons. So let's explain the normal path of that.
So the pituitary gland makes GH,
it tells the liver primarily to make IGF.
Right, it binds to a receptor, right, in the liver and IGF.
And so some of the effects of the growth hormone system
are through growth hormone itself.
And some of it is through IGF1 level.
Both of them are decreasing with aging.
So in this system, we, you know, more than 60%
and I think I'm underestimating, okay?
It's more, it's probably more,
but I didn't really calculate who has several mutations.
You know, I can calculate how many mutations there are,
but not the overlap of the mutation.
So I'm saying 60 percent, but it's the most common
genomic alteration in our centenarians. And I have to tell you. And where is it specifically?
I'll tell you in a second, and I want to just tell you, I never
I wrote grants on that
because I thought because there's preliminary data in nature, right?
The small dogs live longer and the ponies live longer and when you mutate, growth
hormone or they're born dwarf, they live longer and when you give more growth hormone,
they live shorter. So there is a lot in nature, but the human data was really confusing.
Some diseases, you know, when you have a high IGF, you have more cancers, but you have less
Alzheimer's disease, less cancer. I mean, sorry, less heart disease and less diabetes, but more cancer.
Right. And mortality in mortality, it's like in the middle, you know, a little bit tending to more from
you know, from cancer.
By our analysis, which I think pulls all of your data, we found that there is a U-shaped mortality curve
with the nadir being between 60th and 80th percentile of all-cause mortality.
So I want to tell you the problem with this association.
On one hand, an individual that age quickly, okay, their growth from an IGF goes down quickly.
Okay.
So, you would measure falsely low IGF1 level.
If you catch them on the wrong side of their aging group.
Right, that wouldn't fit our theory that low IGF is good because that's their accelerated aging. So this is a problem with an association study like that.
We discovered first of all that when we take our centenaires, so they're in our study because
they've been healthy at age 95, living independently. We take them at any age, but that's what they have to do.
living independently. We take them at any age, but that's what they have to do.
And we just look at those with the highest IGF and the lowest IGF one level,
those with the lowest IGF one level leave twice as long. Those are already to centenarians. But only women, men do not. And every example that I gave you, there's a sex difference.
The growth on IGF is very
sensitive for women or for females. So right, near let me ask you another question.
It's very difficult clinically to measure GH because it's pulsatile. Right. So whenever you're
saying growth hormone, are you really saying IGF, which is easier to measure? No, because I'm
going to talk soon, but not I'm measuring what I'm measuring, but where the mutations are.
Okay, but repeat what you just said. The difference between men
and women was that based on IGF level or GH level, IGF levels. Okay.
But we discovered in aging, we did a huge football, okay, that
we are now correcting. We we studied in in our labs
Males only we had excuses like females are
menstruating we don't know their effects and we're all discovering look
Even repamizing that really works everywhere is better in females than males
But our controls is in males, right?
their their examples where we totally miss the sex effect. And growth on IGF is a perfect example, except those mice
that are the snail mice or the Ames miles,
they have a pituitary problem which makes them, I think,
sex confuse.
So they have so many other alterations,
but sex difference is important.
We also showed that those women with the lowest IGF one level
has much less cognitive problems,
you know, third of the cognitive deficiencies of those
with the highest IGF.
All right, okay, so we had to grab our second round
of Topo Chico there, which by the way,
I didn't even ask you up front.
This is your first time having Topo Chico, right?
Yeah, I mean, love.
I mean, this is, there are a few things
that bring me as much joy as introducing people
to this bottled water.
The perier has is much milder.
I like to feel the bubbles.
Well, I think one thing we should consider for tame is if we can have an arm that also
includes Topo Chico.
So there's a placebo, there's a metformin, and then there's a metformin plus Topo Chico,
and the question hypothesis will be, does that somehow enhance lifespan?
Because even if it does not, I predict it will enhance happiness.
Well, I have to tell you, I'm an advisor to the Prime Minister of Singapore.
Singapore is a place that can, you know, plan the future.
And before going, I said, why don't you ask me questions?
And one of the questions, shall we put metforming in the water or in sodas?
Now, good to ask, you know, the answer is no, obviously, but it's good that you're thinking
that way.
So, metaphorically, and should you change your mind?
I think you now know which soda it should go into.
Can you get it in Singapore?
Oh, I'm sure we can, yeah.
So back to sort of what you were saying, this IGF male female disconnect, let's keep
going down that rabbit hole. So I was saying that one of the worries about low growth hormone and IGF is the effect on the
muscle because people think that growth hormone affects muscle function, muscle size. And we found
that in females and males, the IGF one level is not associated with better or worse,
the IGF-1 level is not associated with better or worse,
lots of muscle functioning, including grip and getting out of chair and other things.
So maybe the effect of low IGF and aging
are just as good as having a higher effect of IGF on muscle,
it just weighs itself out.
Okay, but then our study is genetics, Okay, that's what we try to do. And several
years ago, almost I guess a decade ago, we found clusters of mutations in the IGF receptor.
Those were new mutations that haven't been found before, but we found them in nine of our sentinans, which was 2% of our sentinarians.
And that was kind of a proof of concept for us.
That clusters of mutations that are functional is what we really need to look for, rather
than like everybody's doing, doing Jew-was and find, you know, something infraginomic
somewhere. And this was also the first proof of concept that the growth hormone IGF could
be relevant to human aging. People that those two percent of our, those nine people had
higher IGF-1 level because they were resistant, right? It's the IGF receptors. They were resistant to IGF.
So their level was a little bit higher,
but they were significantly shorter than others.
Which is a great explanation of how that phenotype would play out.
You would say, well, how can they be short-statured
with high IGF?
And the answer is, if the IGF isn't as effective at the receptor.
Right.
But remember that most of our people with low IGF are doing better.
By the way, we take the people with the IGF-
Sorry, men also or just women.
Two men in those nine people.
And by the way, then there are dwarfs, human dwarfs that call lorond dwarfs, the clevenin
in Ecuador. And Haseko and Volta Longo and some of the people in Ecuador
were looking, basically, were trying to find if they live longer,
to fume them to really know.
But they have less cancer and less diabetes, you know, significantly less.
So there's other evidence from humans came after hours that
that there is at least less age-related diseases in those people. significantly less. So there's other evidence from humans came after hours that
that there is at least less age-related diseases in those people.
It certainly didn't live a better life in any way that we could assess correct.
Right. I mean, we we always joked that
they weren't happy with the fact that they're short, so they drank a lot and that's the alcoholism. And then when they crossed the road, nobody saw them.
So then they died of more trauma.
But I think it's really not true.
So I met some of them.
We were in a Vatican conference.
Everybody has to bring to bring his patients and longer brought somebody from
Ecuador and I brought a centenary from Rome.
And and the guy that he brought told a different story.
He wasn't unhappy.
He was also happily married with a big woman and had children and was, so I, I don't know.
And is the defect in them at the growth hormone receptor in the liver?
So they make normal amount of growth hormone.
Their liver doesn't acknowledge it. I am out of growth hormone receptor in the liver. So they make a normal amount of growth hormone. Their liver doesn't acknowledge it.
A high amount of growth hormone,
because it doesn't work.
Yeah, so they have lots of growth hormone,
but it's not being expressed through the liver
into IGF.
And so they have no IGF.
So we published last year a paper that took us 10 years
to write.
And basically, we were looking at a relatively common mutation. I'm saying
common because it's like 3, 4% in the population where they have a complete deletion of exome 3
in the growth hormone receptor. Okay, so one of the exomes, you know, one of the things that are important for the integrity of this hormone is deleted.
And of course you would think that that means that the growth
hormone is less effective.
And Gillette's money was fellow with me, brought me this data to
suggest that while it's 3, 4% in our control population, it's 12% in our centenarians.
So, I asked, so what's the IGF1 level? And he showed it's lower. And I said, and what's
the height of the people? He said, well, that's the problem. They're much taller. So, I said,
I cannot do anything with this study. It just makes no sense. I don't know how to write.
So the people with lower IGF, but the mutation was in the exon of of the growth hormone receptor.
Okay. So they had lower IGF. So it was a dysfunction of the receptor in theory. So less
IGF. And we know that it was fully penetrant all their life. In other words, we there's
no chance that it didn't start showing up until they were in adult.
Well, we'll come back to that,
but the mutation didn't change.
They didn't change.
And by the way, just give me some numbers here.
How low are there IGFs?
I don't remember.
Directionally.
Like, are we talking about like less than 100?
We're talking.
No, less than 200.
Okay.
Yeah, 100 is about the median level of IGF for somebody over 65.
Yeah, I think in the studies that I told you, the average or the mean or whatever was 94,
something like that.
I don't remember to answer about those people, okay, now.
Okay, so you said what to do.
I said, well, first of all, what you do with genetics,
you do replication study, you know, you go to other populations and you see what's going
on there. And second, you do a functional study. Let's see if it's really a functional mutation.
So it took almost 10 years, right? And in 10 years, we replicated the data in three other populations in Amish, French, centenarians in the CHS here in the United States.
And in all studies, that people that lived the longest had much more of those homozygocities
in the growth hormone receptor.
So that was a great validation.
Second, the functional. So, Haseko and my partner in USC, we send him the lymphoblasts
of our patients, they're affected and not affected. And he is a growth hormone IGF expert.
So he incubated them serum-free, so without stimulation, and with growth hormone, and
looked both at activation and proliferation by growth hormone.
So in serum free without stimulation, they had less activation and less proliferation, half of normal.
Suggesting, yeah, that's the mutation, that's the function.
When he incubated them with growth hormone, it totally switched. I'm sorry, but going back, you talked about proliferation,
but was there a functional difference in the lymphocyte?
In addition to its increasing number.
No, there's, yeah, the first was activation by phosphorurk
and some of the, okay, some of the...
Non-specific activation.
No, no, specific to what growth hormone is doing, but
okay, proliferation, it's, you know, it's a cell that's an easy one.
Yeah.
When he incubated it with growth hormone, it was the opposite.
Rather than this low proliferation, low activation, it was high activation, high proliferation.
So what's going on?
Well, what's going on? When do we have high growth
hormones for puberty? Yes. So with high growth hormone, something has changed in the activation
from low activation, you jump to high activation for reason with the molecular, the real mechanism
we don't know really, but that's what happened when you have high growth
hormones. So they all were taller. And then when growth hormone got down for the rest of their life,
they shut off. Okay, so, so, okay, so this is 12% of our people. Then, Yushin Suh, who's a geneticist
that's working on this, she was interesting, microRNA. That's another,
you know, epigenetic thing that comes, we haven't been thinking about it, but those are RNA that comes from certain region of the gene, and they bind specifically to active region of the
gene, and they modulate it. Well, 30% of our centenarians have clusters of microRNA that are overexpressed by a lot, by 40 times,
you know, just immensely activated. One of them, for example, microRNA, microRNA 142,
that's increased by 35-fold. When you incubate it with cells, it prevents the phosphorylation of the IGF receptor,
decreases some other signaling, foxos signaling, and some other stuff dramatically.
So, there's a microRNA targeting of the growth hormone IGF receptor in about 30% of our centenarians. Then 22% of our centenarians have mutation in Fox
3a. That's a common mutation in centenarians. So you start 2% and 12%. Yeah, tell people what Fox
3a does. Fox, Fox 3a is another, how would I say, just house, housekeeper,
that lets in good stuff and change things
and put things in stop.
It's too complicated to go more,
but it is part of the insulin-
It's a very important transition factor
at regulating homeostasis, cellular homeostasis.
And that's not a great explanation,
but it isn'tXO the most prevalent genetic difference?
If you were to just isolate them by genotype, if you look at CTEP and C3 and FOXO and GH
and IGF, I mean, my recollection is that FOXO might be the single most prevalent of
this. So it might be the single most prevalent of it. Well, Fox, so I'm not sure that it's true,
but Fox 3a is common in all centenarians population
around the world.
Not every population has the same mutations.
In fact, what we're doing now
when we have the exome sequencing of all our subject,
almost 3,000 exome sequencing, all our subjects, you know, almost 3000 exome sequencing.
The important thing to do is to assign them to pathways because, you know, we're doing
something really silly with genetics.
When we had this GWAS, we said we have millions of SNPs around the genome, we'll find the
diseases, every disease in the world.
And one of the stupidest thing we did, we took one SNP a time. Okay, let's see if this sleep is significant, but we're not
build of one sleep of a time. And in certain population, there is
down this pathway, there'll be another sleep that will change the
function. So you need, you need to our analysis now is totally different
than how we started. But this, you know, I mean, I agree with you completely, but I don't think most of the world is listening
near.
I mean, if I had a dollar for every time one of my patients came with their complete
sequence and they want me to interpret them, I have the same discussion so many times.
Okay, you have 20,000 genes. To my last counting, maybe
78 of them have a deterministic relationship with a disease. You have none of them, and we know
you have none of them, because if you had any of them, we would know by now. There's no chance
you got here with Huntington's disease, and we sort of missed it, or there's no chance you have
some inborn air of metabolism that somehow got missed.
And then we get into this whole GWAS morass, and you know, it's hard to explain to people how
multifactorial these issues are. And I find myself, maybe you do as well,
somewhat frustrated by these discussions, and the over and the over emphasis on this genetic, you know,
it's a little bit of the drunken, the street light problem, right?
When the guy is standing with all the street light and you say, what are you doing here?
And he says, I'm looking for my keys and you say, did you drop them here?
And he says, no, but this is where the light is.
So let me not increase the complexity, but give you another ammunition, okay?
So we did, you know, now several years ago,
because of funding, we did our 44 best, you know,
first centenarians, their whole genome sequencing.
So think about it, we have a study without control.
We just have 44 centenarians,
and we do the whole genome sequencing.
And our question was, do centenarians have the perfect genome?
I mean, maybe one out of 10,000,
they just don't have all this crap from the GWAS,
those snips for heart and Alzheimer's are there, just great.
And we went to this data set that's called CleanVar.
CleanVar then had the 15,000
butogenic mutation that most probably will cause a disease.
Okay?
Now they have about 30,000.
And our hypothesis is that our centenarians
don't have any of those.
Okay?
We'll support the perfect genome.
44 centenarians had more than 230 mutations between them. In other, five to six mutations
that should have caused them diseases. And none of them had this disease in 100 years of life.
And some of those mutations, I'll give you the best example there for Parkinson and cancer and everything. But Apple, apoi, apoi, apoi,
apoi. Yeah, what's the if we have two apoi for 100 years old people that the textbook would
say they're a demanded at 70 and dead at 80 and they're not, demanded and not dead at
100. Do you think this at all explains the LPA up tick we see because, you know, one of
my favorite topics is lipidology and of course
L.P. little A is a very virulent, lipoprotein and yet centenarian seem to have more of it
than the general population.
Exactly.
So we actually showed in a paper because we found a way. So basically, we can obviously, we can have mutations that are protected because
they have slow aging or longevity genes that protect them, right? So how do you prove that?
So we noticed that when you look cross-sectionally, I hope I can make it very simply.
When we put any genotype cross-sectionally, in other words, we have all the ages from 50
to 112 is our oldest.
We see patterns.
If we see pattern that the genotype is declining with age, we know it's killing people.
If we see that it's kind of monotonically increased with age, like with the...
That's concentrating.
...then means that people are surviving, are surviving with this mutation.
That's why we have it more in 100.
Like the example of the Rotomon receptor going for three to 12 in a monotonic way.
So we looked at LPLLA, exactly.
And this is the most confusing of them all, because I don't see any compelling evidence that LPLLA
is anything other than Athrogenic. And so it begs the question, why would it concentrate
in centenarians as opposed to just rise, commensurate with the population?
Exactly. So this is the answer, okay? First of all, we show cross-sectionally that LPA drops
until the age of 80. By half. In other words, it kills half of the people.
It kills half of the people. It kills you like crazy. People drive.
Until it's not.
Right. And then, and then you look at that and you kind of tried to understand
just a minute now, this thing that killed now, all of a sudden,
centenarians have even more, right? It should stay flat after maybe,
right? It should be flat. Why is it increasing?
Well, because it's a protected aging gene, in other words, it was obviously during
evolutionary times. Are you saying that the thing that LP Little A did for us 500,000 years
ago that is no longer beneficial in this lousy environment, the centenarians have managed
to tap into its properties of? No, no.
So what we did, what we did, and it's all published in computational biology journals,
we took every one of the longevity gene that we have, and we did gene-to-jean interaction.
In other words, we tried to see if there is interaction between the bed genotype and the
good genotype, the good longevity genotype.
And we did it to variety of those U-shape, right?
I'm telling you, there is a U-shape.
It goes down with aging and then it's good in centenarians.
And we really found statistically significant that L-pil-A is protected by people who are homozygous to
a CTP mutation that is a longevity mutation that we found before.
That's the VV mutation.
The VV mutation.
In other words, most of the people with LPLA that are centenarians were also CTP, CTP mutation.
So can we tell people what that phenotype is?
So I've talked on this podcast a lot about CTEP and its role in reverse cholesterol, transport,
et cetera.
Talk to me about what does the lipid panel look like for someone who is CTEP-VV plus or
minus LP little A?
So those with CTP-VV, they have higher HDL levels, they have larger
lipoprotin particle size, and they have lower CTP levels. That's their phenotype. And this
CTP has been protective against several age related disease, the most dramatic is cognitive decline. And by the way, the two
apoi-4 are also CTP-VV carriers.
So really, the question is, it sounds to me like, if you are a CTEP-VV, that's a very
protective phenotype. And the difference, if I remember the data going from 70 to 80
was basically flat. If you're CTTEP VV, it really goes
up when you turn 80, meaning the concentration of C-TEP VV...
The genotype.
Yes, the genotype goes up significantly once you hit 80.
It goes in 55, it's 8% of the population and at 120% of the population. So it's also important to know that not,
first of all, the 8% that have VV,
I don't know how many of them will be centenarians, right?
And also not all centenarians are VV,
but it's still very impressive
because the problem with HDL cholesterol
is it's just such a dumb ass metric.
It's so useless.
It's so far downstream that it doesn't tell us much.
But the hypothesis here would have to be that these people have far more functional HDL
particles because I mean, we don't have to rehash this, but anytime you pharmacologically
increase HDL cholesterol by inhibiting C-TEP. Nothing good seems to happen. Right.
Because you're actually impairing
the reverse cholesterol transfer.
Right.
So it has to be with effect.
Right.
That's why it's a functional thing of the HDL probably
or the lipoprotein particle side or something.
So I understand all of that.
Here's the part I still don't understand, near.
Why wouldn't the LP little A phenotype or the LPA gene flat line after 80?
In other words, I understand why CTEP-VV is protective.
I don't understand why LP little A should concentrate.
I think because the CTP is common and is very protective and that's why you do it. Look, it's a cross-sectional.
By the way, it's a good question.
That's what we ask.
Why it's not flat.
But for a person who's born and is going to be a centenarian,
for them, it's really not so they don't die.
I mean, I guess I need to, I need to do the math.
We, and we could do this over dinner.
We'll sketch this out on a napkin.
You take a hundred people who are going to be centenarians,
a hundred people who are not, eight percent of each of them,
call it 10 percent of each of them have LPA.
We should do the math on if it's,
are we being fooled by the age?
Because I do have one alternative hypothesis, by the way.
Oh, I'll show you, I'll show you dinner. I'll show you the actual calculation.
Computation. Okay. So, so this will be good. This will answer my question because the other
hypothesis I've often wondered is depending on, so I'll start with my question and then
I'll go to my hypothesis. How much phenotyping have you done on the LPA? Do you know how much
heterogeneity is with their cringol repeats, for example? No, and I don't have their LPA level. I
have just their LPA general type. So the things that we've done are, though we can do, actually, we've
done a little bit on the CTP levels or we've done, but those
calculations are on gene-to-gene interaction.
Taking out the people without genotype and without genotype and seeing who are the people,
who are the centenarians that stayed with the bed LPA genotype, they're only the ones
who are CTP also.
I see it.
Do you have serum stored on these subjects?
Yeah, but and I have a proteomics done and maybe we can have some measurement. I'm not sure.
I wonder if there's a clue to a very vexing question, which is, why is it that some people with
high LP little A do not go on to get premature heart disease?
Many do, most do.
A significant number do not.
And it appears completely uncoupled
from the level of their LP little A,
which makes me wonder, are there virulent
and non-virulent phenotypes that at the level of expression
by number or molecular weight aren't captured,
and my question then becomes, is the non-virulent one, the one that is concentrating in the
centenarians, and are they the population in which we should understand that phenotype,
so we can better risk stratify the rest of us, schleps, walking around today, 10% of whom
have elevated LPLLA,
but we don't know how aggressively to treat them.
Yeah, I didn't know that there's virulent
or non virulent LPLLA.
My explanation is totally gene to gene interaction.
In other words, you do another phenotype.
I guess the answer is different.
Is the people with the, what's the LPLLA,
what's their CTPL level, what's their HGL, what's
their HGL particle size, and maybe you can see that generalized that if you inhibit CTP,
the LPL A is less interactive.
I mean, I think the problem, I agree with what you're saying, the challenges we do not
have an HDL functional assay.
So right now we can measure HDL cholesterol, we can measure HDL particle number
and we can measure HDL size, but none of those come close to telling us how functional the particle is.
Well, I have a collaboration with Dan Raider, who's doing HDL e-flux and stuff like that.
Yeah, I mean, Dan is a god in this field. Yeah. So maybe, but I'm, you know, that's not my,
this is a past life for me. Yeah, yeah. I moved on.
So I don't, I don't really know to answer you.
I didn't really let go back to the IGFGH thing because this one still creates
tremendous.
Let's bring it back to clinical stuff.
So I'm often asked by patients, Hey, should I be on growth hormone?
And my answer is I don't think so.
But if I'm going to be brutally honest, I really don't know. I really have no insight into whether growth hormone. And my answer is, I don't think so. But if I'm going to be brutally honest,
I really don't know. I really have no insight into whether growth hormone is exogenous administered,
growth hormone is harmful, helpful, neutral, or what, because the clinical data certainly
don't give us the answer, right? So the epidemiology, if you're in sort of, you know,
Valtors camp is, that would be the worst thing you could ever do. Growth hormone is bad because IGF is bad. But again, the epidemiology tell a different story,
tell a much more nuanced story that has to do with how high is too high at what age and for what
gender and with respect to what disease. So of course, how can you manipulate IGF? Well, you can
manipulate it, the two easiest ways to manipulate IGF, the three easiest ways to manipulate IGF, well, you can manipulate it the two easiest ways to manipulate IGF, the three easiest ways to manipulate IGF or to manipulate growth hormone exogenously, manipulate
IGF dietarily, predominantly through amino acids, and manipulate insulin to indirectly
impair or enhance IGF binding proteins.
Well, let me tell you, we just published a paper in nature a month ago, a study that we're going also for a while.
And what we did is we got from M. Gen.
M. Gen. is as much as other pharmaceuticals try to develop antibodies against IGF receptor
because IGF receptor is expressed in many cancers.
Yeah, this was the disaster drug that they tested against metastatic pancreatic cancer.
Right. disaster drug that they tested against metastatic pancreatic cancer, it failed.
But if I recall, there was a very special little gift, which is no CNS penetration.
Am I thinking of the right one?
Yeah, right.
So it failed, but we're interested for aging, right?
And not only we're interested for aging, our hypothesis was that IGF, you know, that you need
to decrease IGF action in the periphery, but increase it in the brain because of the
data.
So we asked them to modernize their antibodies.
Modernize means to make it available for a mouse.
And we got it and we did a longevity study that we started at 22 months.
By the way, remind me in the human study, how much did it lower IGF and the periphery?
It increased. I know. I'm sorry. I know it. I'm sorry. How much did it lower IGF activity
in the periphery? Was it a reduction by what fold? Like was it a twofold reduction?
It's very hard to measure. You don't measure it like that. You measure it in, you know, in vitro.
It's very hard to measure how much.
Got it.
And they rebounded a little bit with IGF,
which is not the case with aging,
because with aging you don't have the growth hormone secretion.
So we gave it to 22 months old,
and a moles that are 70, 75 years of age equivalent.
We increased their health spend dramatically and we increase
their lifespan by 10% at an older age.
Okay, so this is a drug that's already was.
And you were able to demonstrate, I'm sorry, I missed this paper, it came out a month
ago.
So I'll be inhaling it this time tomorrow.
You basically showed that you didn't change IGF levels in the brain or you actually increased IGF levels to the brain.
We really don't know. There is a little increase in IGF1 level in the periphery and we're assuming that we didn't make it a big,
I'm telling you what we thought, we didn't make it such a big deal but obviously the antibodies do not cross the blood brain barrier.
Obviously, the antibodies do not cross the blood brain barrier, but the IGF wasn't lower if anything was high.
Right.
So if anything, IGF went up in the periphery because it was being blocked.
And therefore, it could have got more into it.
So you could have had more CNS activity, less peripheral activity of IGF.
Now, again, those were aging, by the way, it was in females.
In males, we started to do the studies in males. And since we
didn't see any major effects, and we had relatively little, you know, those are months of studies in
many mice. So we eventually did the longevity only in females. We don't have data on males. But
the extent of health span, and you'll see the paper, it's really, it's a great paper with lots of studies.
And it's impressive how much they did better the females with that.
So there you have an example, we have all the parts where you ask, what do we do?
Here is, it's been in humans.
Okay, the IGF receptor antibody is there.
The only problem for us is aging could be an indication of what's before aging.
Like, we need another indication in order to start selling it before.
But what's your hypothesis in the female mice? You said they lived 10% longer.
Much healthier.
Much healthier. So they had compressed morbidity as well.
They had cardiovascular protection. They have cognitive advantage, functional adventures. There's a whole thing. The interesting thing
between male and female, the difference is the mice, the female mice that were treated
with IGF receptor antibody had a lot of of inflammatory markers, right, when we started.
There were 22 months.
And those inflammatory markers were really decreased with aging.
In males, we had a little bit more inflammatory markers, but they increased
with the IGF treatment.
So maybe the fact, and both the males and the females had an increase in peripheral
IGF, presumably the antibody was working in both of them.
But somehow the inflammatory response in males was different. So it's all dreaming. So I'm
answering you two things. First of all, what do you do? Here's a good example of a drug
that was in females and we have preclinical proof of concept that it's good. But the second is in males,
all those have not been shown. And in fact, the functional that I told you it functional in women,
it looks like the function was better for men with a higher IGF and not with lore, not statistically significant, but you could
see that it might happen.
So I'm telling you from human studies, from genetic studies, I'm telling you, growth
or maltreatment is not beneficial.
It should be dangerous for elderly people, for elderly women.
With men, I'm ready to say that I'm not sure. You know, I'm not sure. It's not
that I've shown that low IGF or growth hormone is better in males. Not in my rodent studies
and not in my human studies, but it's hard to say that giving growth hormone is bad when,
you know, by the way, the growth hormone receptor story is a lot of
them are males.
That's really, that this is so interesting.
I mean, this is such a layer of sophistication to this question, which I've largely sort
of decided that there, I can't come up with a compelling reason for exogenous growth hormone,
but I also can't see much evidence clinically that it's killing people, but of course,
I think disproportionately the data are in men.
What do you think explains this sex difference between men and women?
I think, I'm really, if you look at this inflammatory panel, lots of cytokines and lots of animals,
I'm not sure we don't have the intellectual link to say what happens, but this is something we
want to actually go on and examine. Because if for some paradoxical way that is sex dependent,
low IGF increase inflammation, we want to know why and we want to know how we can affect it.
why and we want to know how we can affect it. It would be great if you could repeat the study with younger mice, both male and female
again, because I mean, the most obvious example is the biggest difference between the men
and the women or the sex hormones and the older they get, that difference is still there.
I mean, women will, you know, the female mice would go from having some testosterone to zero
testosterone, but gosh, the men would probably still have more estrogen than the males have
more estrogen than the females postmenopause, which makes me wonder if the estrogen that
progesterone in the testosterone are somehow protective of the inflammatory effects.
So there's a, you know, we're working on a grant because the sex issue is so interesting.
We started working on their lots of models where you can change X and Y chromosomes and
stuff like that.
And, you know, we're looking at the way to look at it because I don't think it's usually as simple
as the sex hormones.
You know, I think we're missing a whole biology,
a whole biology.
And whatever is the sex hormones,
I don't understand the inflammation in that either.
But by the way, your idea of doing it in young
is good.
Emgene sold this IGF receptor and we cannot get, we cannot get more samples, but we're
interested to maybe do our own.
Anyway, Emgen sold the rights to the human antibody.
Their whole section actually, their whole section to who, which company owns it now, to like
a private company that we're unable to get people to,
though I have to say it's not our major priority now,
and we have some consultants that are trying to get
it together with those people.
So, you know, it's still an issue, but I'll tell you,
if I had to develop a treatment, I would rather use
the microRNA 142, because the IJF receptor antibody didn't work in cancer, but maybe the microRNA 142 because the IGF receptor antibody didn't work in cancer, but maybe the microRNA penetrates
better in another way and maybe that's the way to decrease IGF receptor in, you know, in cancers.
So anyhow, but I really answered you is that yeah, there are things that we could do to affect the
pathway. I mean, what do you think about sort of all the, to me, the most obvious way to manipulate
IGF is through fasting.
So about once a quarter, I fast for a week with just water only, and it has a profound
impact on my IGF level.
So for my age, I think I should know these numbers off by heart, but plus or minus two standard deviations of IGF at my age is about 90 to 250.
And if I measure my IGF level before a fast, right before a fast, it might be 180 to 200.
And right after the fast, it's 80 or 90. And six weeks later, it's maybe 141.50.
So it sort of falls precipitously during the fast and then slowly rises and then falls
precipitantly and slowly rises. And there's part of me that just wonders if a cyclic
approach to IGF is a healthier approach than, say,
constitutively being calorically restricted and just, you know, because you can starve
yourself of methionine and eat no protein and live at a lower IGF level of maybe 110 forever.
But I wonder if the real game is sort of figuring out this sort of cycle and periods of just
just as we think of atoph topogy, if you're always
in a state of a topogy, that's a bad thing. If you never have a topogy, that's a bad thing.
So you know about the calorie or the caloric restriction that the NIA funded in three
centers. Yeah, Eric Ravison, and Penningson was one of the main PIs.
One of the things is that IGF level wasn't decreased in those people, right?
And we think IGF decrease is really an important part of longevity.
But we've learned something else and maybe I'm digressing because I'm sure you talked
about it more, that what we're doing in rats wasn't really caloric restriction.
We're doing intermittent fasting because in our rodents, we would bring the food in the morning. They were hungry.
Right.
They would eat all the food, you know, the 60% whatever we gave to it, Libidon.
And they were fasting for 23 hours.
And they had low, you know, low IGF1 level.
But in Eric Ravousin studies, they didn't have low IGF because it wasn't
color restriction like that.
They gave them just less foot throughout the day.
And I think that was a big mistake that we realized we were doing.
And it doesn't answer the circulating.
I think what we're trying to do at Einstein is we're doing a study.
We know that autophagy is improved quite fast
in fasting rodents.
We don't know the timeline for humans, okay?
So we're trying to figure it out.
And by the way, we can do with anamaria quervo,
we can take tilin for sites and look at the autophagy
on a time course in humans.
And they actually reflect also autophagy in a time course in humans. And they actually reflect
also autophagy in the brain. There's a lot of advantage in doing that.
What are you looking at specifically in the assay? Well, there are several things because there are
several autophagies, right? So macrotophagy or shaperone mediated autophagy, so there are several
things that... Can you measure my topogy also? Yeah, we can do, we do that.
How sensitive is it to meal timing?
You know, like, for example, if a rodent is fasting for 24 hours, especially a mouse.
I mean, that's, gosh, that's probably a human fasting for a week.
Presumably, a topology is highly, highly, highly upregulated. If you give them else a little bit of chow and then measure that assay.
Does it obfuscate? Does it erase the fact that they've been, does it create the illusion,
I guess I should say, that it's erased, that they've had this high period of topology.
Did you transiently truncate it? You know, Annamarie Cuervo did and I don't know the answer.
Did you transiently truncated? You know, animal requirements did, and I don't know the answer.
I don't know the time course.
But the important thing is to find the time course in humans
so that we can really say, for example,
what I'm doing basically is I'm trying not to eat after dinner
until lunchtime the next day.
But do you really, I mean, so first of all,
how hard is it to get an IRB at Einstein to study
this in?
No, no, we have IRB.
We just wrote a grant.
We need money for that.
Okay.
Yeah, I guess, you know, I have a whole framework around nutrition, which I'm happy to
kind of walk through as we inhale our dinner tonight.
Have you decided, by the way, if you want Indian, Turkish, Persian Persian Greek, all of the above.
Sounds good.
You know, because it's raining out, so I guess one of the things we could do to the closest.
Well, for now.
Yeah.
So my concern with time-restricted feeding, which I practice quite liberally, is I'm worried it is not a significant enough deprivation of nutrients in humans.
In other words, I think Satchin's data is so impressive in mice, you know, but I think
that for a mouse to go 16 hours without eating is an enormous task.
It might be the equivalent of us not eating for three days.
And now that said, I'm struggling to see a downside of time restricted feeding.
And I know that, you know, a vulture and others have said time restricted feeding is somehow bad.
I don't accept those arguments.
I'm not convinced by those data.
This is a very interesting question you're asking.
I would argue it's the most interesting question of all because if we understand the time
course of that, all of a sudden, we can program exposure. And have you looked at that assay
in the presence of rapamycin or metformin?
I didn't, but metformin, I don't know where the quervor is using metformin as the control
for autophagy. Okay, it activates autophagy really well. Okay, so that's it. I'm talking about inviteroises. Okay, but we haven't measured it in patients.
The one thing I should say,
I just don't really forget anything.
Can I?
Absolutely.
And it's back to the metforming.
It's just reminded me,
it's back to the metforming studies.
So our reviewers were saying, you know,
okay, all the data on the biology that you showed was from rodents.
And we don't know that the biology is relevant to humans, okay?
Although, of course, the preliminary data in humans are much better than in rodents, right?
The association with diseases.
So we had a clinical study, a small clinical study, which we took 15 people that are 75 years old,
and we gave some of them at forming for six weeks,
and other placebo, and then we crossed over, and it was blinded.
And we took it at the end of each period,
we took biopsy from their muscle,
and biopsy from their edipostitia.
Okay?
So not liver.
And we looked at the transcript and the metabolomics,
but mainly the transcripts in the tissues
to see effects on mid-forming.
And there are three interesting things.
First of all, when they brought me their clinical results,
you know, insulin, homoglucos and all.
There were significant effects in many of them, statistically significant
effects, but I was expecting more.
I started to try and break it down.
And then we found out that the people who were last on met forming,
although it was half of the people had much more significant results than the whole
15 people.
Wait, explain that again. The people in the crossover who started, who went placebo to metformin
had better effects on metabolic parameters relative to themselves or to their peers,
relatively to themselves. Because this was a person to person. This was
a person to person. This is a paired tea test. And the reason is that probably the two weeks
washover is not enough when you fix the assaging. It lasts for a while. Okay. So if you got
metformin and then placebo, you didn't really, you, you went halfway back.
Also, by the way, because metformin is associated with weight loss, then they lost a little weight,
that on itself really made them with the second time.
Yeah, yeah, yeah, no, it's funny. You bring that up. I'm glad you were mention that.
What do you think explains the weight loss phenotype of metformin? So when I started taking metformin,
loss phenotype of metformin. So when I started taking metformin, which was 2010, I didn't mess around. I just went straight to 2.5 grams a day. I didn't even mix it up. I don't think
I took it BID. I mean, I took 2,500 milligrams first thing every morning. And after a month,
I lost quite a bit of weight, but I was also nauseous 24-7. I mean, the thought of eating was repulsive to me. I
still ate, you know, I was exercising a lot and doing all my usual shenanigans, but I clearly ate
less just because of the low grade feeling of nausea. Today, when I prescribe metform into patients,
I have them start at 500 QHS, then 500 BID, then 500 in the morning, 1500 before bed, then one gram BID is sort of standard dose.
And I see far less of that nausea,
and I see far less weight loss.
What other mechanisms do you think it could explain the weight loss?
So, could it be lactic acid going up?
You know, just like ketones, you get to...
As a substrate, an additional substrate.
Yeah, I don't know, but look, I started
midforming several years ago because I was
prediabetic. My doctor did it.
So it's before I'm glad that he did,
but it was before I thought much about it.
And I was just surprised after three months
to realize that I lost seven or eight pounds.
I was surprised because I couldn't,
I was not shaded, I wasn't anything.
I must have eaten less.
I was less hungry.
I reacted better.
I reacted better to my body, right to my leptin.
Maybe I reacted better.
And I probably didn't eat as much,
not totally not noticing it.
It was a surprise to me.
Yeah, it's funny.
I tell patients not to expect that because I don't like the idea of patients thinking
of this as like a weight loss drug.
To me, that sort of is not the right way to think about it.
But I've never had a great explanation.
And by the same token, I have had, I should be clear, I've had also some patients who have,
they've come back and they've lost 10 pounds.
These are patients who are not overweight.
This is not, you know, this is someone that by everybody's standard would be completely
normal weight.
You know, BMI is 24 body composition is reasonable and comes back in, you know, in three months
and they've lost 10 pounds.
But I guess for, in my, at least in my practice, that seems to be the exception and not the rule.
But very, very interesting to you, you know, I guess, of course at least in my practice, that seems to be the exception and not the rule. But very, very interesting to hear.
You know, I guess, of course, you wish that was more than a two by two, two week.
You wish that was a 12 week by 12 week.
We are doing the same thing with AcreBuzz now,
and we're doing longer study with longer washing period
because we want to get away from it.
But back to mid-form, I said, that's one thing is this metforming last issue.
The second thing that we showed that most of the transcripts changes were relative to the tissue.
In fact, it was more free fatty acid metabolism.
The muscle was more pyruvate metabolism, so it was appropriate.
There wasn't the metforming part.
But in both tissues, there were genes
that are not metabolic genes, you know, like BRCA1
or myofibral genes and other things
that are related to aging, but they are not metabolic.
They change by metformin.
In other words, the concept that metformin
is not only metabolic, it's aging, okay?
BRCA1 changed.
Yeah, you know, some other genes that are associated with DNA repair changed significantly.
The second...
Did you see in the muscle, by the way, if you still have biopsies, I'd be very curious
to know if the lactate transporter out of the muscle, I'm blanking on it, it's MCT2.
In other words, as people make more and more lactate
in the muscle, do they get more and more efficient
at shuttling it back to the liver?
And if so, you would expect MCT2 transport.
And is the gene expression changes by that?
Yeah.
We have the road data.
It didn't come up.
I'll tell you, it didn't come up as a winner, but that doesn't mean it's not, it's not change. And you looked at Genome,
or you looked at, you looked at Messenger as well. You looked at mRNA. It's all, it's all, it's
all, it's all mRNA. Okay. So you should have seen it if it happened. Well, if it was highly,
I mean, there are hundreds of changes. Okay. So, uh, yeah so maybe this was underpowered to see that difference.
It's a significant change. So I can still answer you, I can see you specifically. And it's RNA
6. So it's really good. It will be good. You know, if I take that and see that it can be without
taking into account that there are 400 other changes, it can be significant. The other thing though, what you do with Transcript,
you look at upper regulators of the system,
and there's a way to do that.
That's what everybody does now.
So if you look at the upper regulators,
you get back to the same things that are affecting aging,
M.P. kindness, M.Tore, all those pathways
were affected by metformin, except that what you measured below is the tissue
specific effects, but it was all related back straight to aging.
You know, break my heart.
So we really connected not only the clinical data, but the
biological data in humans to the tame study.
not only the clinical data but the biological data in humans to the tame study. It's wonderful.
A few years ago, and my father was diagnosed with cancer, I immediately put him on metformin.
And in his infinite wisdom, his primary care doctor took him off it because, you know,
why would you put him on metformin?
And in the end, my father decided his primary care doctor knows much more than I do,
and so remains off metformin.
But certainly this discussion, because I probably know more about metformin than the average person,
but this discussion has been completely illuminating.
There's one other thing I want to ask you about, which is all of the discussion around NAD.
I mean, you know quite a bit about this.
What is your take right now based on the state of the science
that we have, which admittedly,
I think we're just scratching the surface of,
as far as first and foremost,
just at the mechanistic level.
What is your belief that Oroly administered
nicotinamide riboside can actually make it into a cell?
I don't know if you've seen it,
but Josh Rebeno, what's's paper over the summer would suggest,
no, most of this is going to deliver.
So wouldn't this sort of call into question the companies, there's two of them right now,
Chromodex and Liceum, that sell basically the tinnamide riboside plus or minus terrestrial
bean.
What do you think explains the reported efficacy
of those agents in light of Rebenerwitz's NAD tracer study?
First of all, the Rabinovitz study was also criticized, okay?
Time course and other things, which, okay, I'm just saying that.
But I think really the biggest issue here,
I want just to use this opportunity to say
that a lot of what we're doing
is not based on clinical studies, okay?
And it really just underlines the fact
that unless you do a clinical study,
you can remain guessing.
Now, I'll tell you, I'm taking a good preparation of NMN, okay?
Tell the listener the difference between NR and NMN
because they're both precursors to NAD,
but there's a subtle difference.
Yeah, and I don't know.
I don't know to explain that really well.
I don't care that much.
Okay, but in theory, one is slightly more stable than the other.
Right, it's a stability issue, availability issue, but they'll fight.
And we don't know which is the better, and we don't know which gets to the tissue, right?
Yeah.
But what I wanted to say is the following.
So, so the answer is, it could also, it could all be water, okay? It could all be
This you say that as you hold up a bottle of to pochico, right? Sorry, you didn't see that in the microphone
Okay, but what I'm doing now is I'm opening my feed bit, okay? And one of the things that the feed bit has is
Sleep, okay? And one of the things that the feedback has is sleep. Okay.
Do you use feedback?
No, I use something called aura, which works much better.
Okay.
Yeah, this really measures sleep well.
Do you get also the deep sleep and the REM and all that?
Okay.
Since I started taking N and men and it might be a coincidence.
So I have to stop it and start again. But my sleep has been much better.
That means I have, in the beginning of the night, I have much more deep sleep
and in the end of the night, I have much more REN.
And I thought, if there's anything I can say about it, is that just because of this association?
Okay. But I don't believe it, right? Because it's not a, it's a, it's my, it's me and I.
It's empirical and it's, and it's over.
Many think I could have looked, I was in vacation.
I don't know.
Many things could have happened.
Do you take the NMN by itself?
Or do you also pair it with terrestrial being
or another, or two in activator?
Just an NMN.
But it's a good, it's a good suggestion, maybe.
Okay, but then I run into Imae, do you know who's Shinimai?
He is from St. Louis and he has his own patterns
and studies in Japan on NMN.
And he tells me, unprovoked.
He says, you know, I have 200 subjects.
And one of the interesting thing is their sleep patterns improve.
They get more deep sleep in the beginning of the night and more REM at the end of the
night.
In other words, he tells me what I've noticed.
And it makes me just think and maybe believe and maybe hope that something is getting into
the cells. And that there's a real effect, at least on
sleep, it didn't tell me any other things. But really, my answer is, we don't really know
enough. It's very hard to measure effect because this NAD goes and goes away. And you know what system can you do. It's very hard to measure that.
And without clinical studies that are really well controlled,
I think it's going to be hard to just support that.
And that's me as a conservative scientist
and one who says that even informing that everybody, you have enough data, no, we
have to do the clinical study to prove that. And that's
where I really stand. And it seems to me that
intravenous administration of NAD is also not
particularly helpful, though it seems quite popular in the
sense that I'm not I haven't seen compelling evidence that giving
NAD intravenously makes its way into the cell either. So I think the development
and the interesting development will be to develop a drug and the drug will be
a precursor that will get into the blood outside of the liver. Outside of the
liver. Yeah, exactly. So if you could give NR
or NMN sublingually or intravenously, that strikes me as very interesting. Saying that there's a lot
of data in rodents where also you look, you give it in different ways, you give it some in water,
but some are gavage and maybe that's different because one of the problems,
maybe if you go deep enough,
you can bypass the total circulation.
Right, you can bypass something.
So, you know, but the In vivo studies are good studies, okay?
You just don't know what it means to humans.
Yeah, well, near I'll do a time check here.
We've been going at this for a little while.
There's a lot more I wanna sort of pick your brain on, but we could also just sit down and do this
again sometime. I want to make sure you've said at least as much as you want to
say about Metformin, because I think that to me is, you know, you're at this
point arguably one of the world's experts on a drug that just to put this in
perspective, I think Lou Cantley, who is obviously a close mutual friend of ours, and James Watson, who I don't know personally, have both said quite publicly
that metformin may have already saved more patients' lives from cancer than all other cancer
drugs combined, or something to that effect.
This is a drug that I think with each passing day, more and more people are beginning to learn
about, beginning to ask questions about.
And my hope is that if nothing else, this podcast is a place that people can listen to this
episode, if they can't go and read 16 of your papers and they don't necessarily want to
get that far down the rabbit hole, but to hear it from you and not from me or some other
schmuck who doesn't know much, I want to make sure that if there's anything else you want to say
about metformin that you say so.
Is there anything else that you want to add?
Well, let me do one practical thing and one a little bit more philosophical.
The practical thing that really surprised me, I was giving a talk somewhere for lay people. So it was organized
by a university and they invited people and to their surprise there were 300 people in the audience.
And by the way, my talk wasn't about metforming. My talk, the titles of my talk is usually
how to how to die young in a very old age. That's what I my title is usually if I can
get away with it. That's a good title. So people people are coming and as they're entering some of
them come to me and say so how much platform should I take? Okay, so I started talking and all of
a sudden I said let me ask you something who here in the audience is non-diabetic and is on metforming.
And please, you don't have to, just if you choose to. So how many? Half of the people.
Where was this talk? What university? I don't want to.
Okay. What city can you say, what city? Was it in the United States?
No.
Okay. Fair enough. So, you know, the, in other words,
the prophecies out, which makes me a little bit worried about the study, when we first,
World Street Journal is the first that picked on tape, wrote an article, the next week,
we had 3,000 phone calls and emails of people volunteering to the study,
which is what we need to do the study. And I thought, you trim that budget from 70 million
down to 65, you cut all the recruiting stuff. Exactly. Except that then you realize.
Yeah, it's a bias sample. Then you realize just a minute, those people, first of all, we didn't
advertise. They had to find my phone number
and email. And second, they'll do, they're doing other things, you know, it's like with the estrogen
bias, they're probably exercising and stuff like that. And then when I started getting emails like,
I'm volunteering to the study, as long as I'm not on the placebo, I thought, you know,
if people care so much, if they'll figure
out they're not on mid-forming, they'll just get mid-forming. So from recruiting the 3000,
we we outlawed those, those are not in my study, right? So I want to say that still, we haven't done
the study, okay? We haven't done this study. So you're
between 65 and 80. Okay, just know we haven't done the study. We don't know if it's safe as it is in
young people. And so we don't have really a clinical study with evidence that this is good. And I'm
just worried now that part of the reason to do this study is because if it's not good,
people should know also, right?
And not take another drug, okay?
Not that I believe that, but it is possible.
The second thing that is more philosophical.
So I said before that I was invited to the Vatican.
I actually was invited twice the second time.
And I'm very close to Cardinal
Ravasi, who's number four in the Pontiffs. He's in charge of science and on arts that is including
science. And it's interesting because the Vatican basically says, we don't want to be in a Galileo
Galilei situation again. We don't want to be in a situationilee, Galilee situation again. We don't want to be in a situation where
the science is so right and we're so wrong that we don't know what to do with it. Okay. And so they
call me and they said, you know, we have a meeting in the Vatican. We'd like you to talk about aging.
Could you come and say them? I said, sure, sure, I'll come. And then I'm going on and saying, I'm I'm I the keynote speaker. And he said, the keynote speakers are the Pope and Joe Biden, who was vice president.
I say, okay, sorry, sorry, I'm still coming.
So that's how it goes.
Joe Biden goes up and explains his concern initiative and how difficult it is
because when you have concert, you have
in the concert, maybe five other genomes, and they're also different than every other
concert like that in the world.
It's really a mess.
Then comes the Pope and says, you know, I still hope that there'll be one little peel,
cheap for everyone in the world that will cure whatever cancer
they wear.
Appropriate?
Yeah, I hope so too.
But then I go up and I say, well, there is actually a cheap peel like that.
And I don't know if it cures any cancer in the world, but it can prevent a lot of the
cancers in the world, but it can prevent a lot of the cancers in the world.
And actually, it has a side effect that it also can prevent a lot of other diseases in the world.
So it was like going back to aging and the risk of aging for age-related diseases,
and how impactful and cheap it could be compared to treating cancer or something like that.
So I think the prevention of aging is really a good place to be.
And I think because we went from hope to promise and we have to realize the promise,
the thing of life is going to be very different in the next decade with our advance.
Last question and not to end on a downer, but let's try to figure out where a blind spot could be. Where could we be wrong? Obviously you and I share more in common in terms of philosophy and
points of view than I even realized before we spoke. But where could we be wrong?
before we spoke, but where could we be wrong? So, you know, I'll tell you what's my optimism.
You know, we have, the European have nine pillars of aging and we have seven pillars of aging
and they're all interconnected.
And when I say interconnected, I just spend the time with Ana Maria Querva this morning. When she fixes optoffogy, she fixes also metabolism.
Okay, when you start doing things in any ones of those pillars,
you start improving the others.
Now, where we could be wrong is we don't know
what is the impact of each of those pathway in humans, okay?
Most of our data is kind of animal data.
But I think our fallback is that we all age,
the advantage of in aging is that aging is universal. Every animal has the skin, the hair, the
skeletal, the frailty. It's very universal. And those treatments are, in reforming,
repamizing, you give it to any animal, it almost delays the aging there. So I don't think
we're going to be wrong. I think that maybe some pathways will not be so effective. Some of them
will be harder to treat maybe, but I think we have to affect three, four and we're right on our way
to do better. And that's just the beginning. And in the tame study, will it be one to one male to female?
Yes.
So we'll also avoid that other.
And have you powered it such that men
and women are different animals?
Well, no, because all our data on metformin
and we looked carefully to the DPP and other,
they didn't see any gender effects on any of the outcomes.
So we are assuming that-
So your power is though
the gender is different.
That's not like we would do maybe rep amising.
Yeah. Well, near this has been fantastic. You know, I was sick the last two days. My voice
is gone. I feel like crap. I was like, maybe we should postpone it. But then when I woke
up this morning, I was like, there is no way we are postponing this discussion because I cannot wait to have this discussion. So thank you so much for
coming over. It was great. It was, you know, it was great because you asked really great
questions. And also, I'm now quite hungry and I'll be happy to have dinner with you now.
So we are going to put together a seminar on how not to
colorically restrict tonight, only tonight.
All right, thank you, near.
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