The Peter Attia Drive - #03 - Ron Krauss, M.D.: a deep dive into heart disease
Episode Date: July 2, 2018Whenever I’m stumped on a patient case or in my thinking about lipids, Ron is one of the first people I turn to for insight. Ron is recognized globally for his research into lipidology and has worn ...many hats in his career, including clinician, lipidologist, nutrition, genetics, and drug research. In this episode, we explore heart disease at its origins before diving into the highly discussed, largely misunderstood, role of LDL and inflammation in atherosclerosis. Ron also shares his insights on the evidence for and against statins and other lipid-lowering therapies. My hope is that both the curious patient and the physician can get a lot out of this episode by being more informed about dyslipidemia and the interventions used to reduce the risk of atherosclerotic disease. We covered a lot of ground on this critically important topic. We discuss: The pathogenesis of atherosclerosis [7:00]; How early atherosclerosis begins [12:40]; Ron’s motivation for getting into lipidology [43:00]; How reading an article series in the NEJM in 1967 had a profound impact on him and his career [43:30]; How PCSK9 inhibitors work and why they may be under-utilized [47:00]; Mendelian randomization: nature’s randomized trial [49:15]; The “battle” between particle size and particle number [52:00]; The use of statins [1:04:45]; The role of chronic inflammation in atherosclerosis [1:24:15]; Why niacin may have been unjustly dismissed as a therapeutic option [1:40:45]; The HDL paradox: why drugs that raise HDL-C seem to raise (or have little impact on) heart disease risk [1:43:00]; Lp(a) [1:47:45]; And more. Learn more at www.PeterAttiaMD.com Connect with Peter on Facebook | Twitter | Instagram
Transcript
Discussion (0)
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 I've gathered 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 more information on today's episode and other
topics at peteratia-md.com.
In this podcast, I'm speaking with Dr. Ron Kraus.
Person 4 Most Ron is a very close friend and an amazing mentor.
I was introduced to Ron probably five years ago and have worked with him closely in a number
of capacities.
And he's always served as sort of one of the three or four lipidologists that when I get
stumped on a really difficult clinical case, he's the person that I'm reaching out to, along with a couple of these other folks
that hopefully will also have on the podcast at some point.
So he has certainly recognized globally for his research in lipidology.
He wears a ton of hats. He's a clinician, obviously a lipidologist.
His interest in nutrition, genetics, drug research is quite profound.
He obtained, I believe both his college degrees
and medical degrees from Harvard,
he's board certified in internal medicine,
endocrinology, and metabolism.
And currently he's a senior scientist
and the director of atherosclerosis research
at the Children's Hospital in Oakland.
So in this episode, we talk about a lot of stuff,
but obviously we're really focusing on atherosclerosis
and cardiovascular disease.
I was really excited to have this discussion with him because a lot of these topics I've
certainly covered in writing as some of you may know, I have that sort of nine part
straight dope on cholesterol series on the blog that I probably wrote about four, five
years ago.
Obviously, some of that's a little bit outdated.
I also was quite deliberate when I wrote that not to be prescriptive, meaning I don't really
get into this is the drug treatment you would do for this.
I largely avoided a lot of that stuff.
Whereas in this podcast, Ron and I get a little bit into this.
This podcast was pretty technical at times.
My hope is that both the curious patient will get a lot out of that.
Hopefully the physician will get a lot out of that, and hopefully the physician
will get a lot out of this, or the person that is also kind of on the front lines of having
to make decisions about how to treat dyslipidemia and reduce the risk of atherosclerotic disease.
I think a couple of really interesting things in this.
I actually, for the first time, learned about Ron's motivation for this, both his family
history and the five legendary articles that
he read in the England Journal of Medicine that largely shaped his career.
This is the stuff we talk about with Friedrichson, Levy and Leese, who I've written about in
the cholesterol series because these guys are sort of the fathers of this space.
We certainly get into one of the age-old debates about LDL particle size versus particle
number, lots of controversy here.
And I don't represent that we've necessarily resolved it,
but I think that's the beauty of talking
with really smart, sophisticated, nuanced people,
is they have the humility to say,
we don't know the answer sometimes.
We really dive deep into the whole statin discussion.
For reasons that aren't entirely clear to me,
this has become an increasingly controversial
area and somehow it's turned into a binary discussion.
Statons are good or statins are bad.
And very few things in life tend to be that binary.
So I'm sort of surprised that it's turned into that.
I don't remember if I even say this on the podcast, but certainly, people have probably
heard me say this before and I say it to patients all the time.
Statons are tools. and the most important thing
when you have a tool is knowing how to use it
and knowing when to use it.
So if you have a Phillips screwdriver,
it's really important to know that it's very good
at putting Phillips screws into things.
It's not good at putting nails into things.
It's not good at cleaning windows.
So I hope we can shed some light on that.
We talk a little bit about the really
interesting and recent stuff around chronic inflammation and the role that that plays in
atherosclerosis, even independent of cholesterol levels. And perhaps for me personally, one of the
most interesting things we discussed was another very controversial topic, which is around Niasin
and Niaspan, which is a branded version of that, which those of you who follow this
world will know that Niasin was basically kicked to the curb a couple of years ago.
And I think that Ron's insights into that are incredibly interesting and actually have
even made me re-question or re-evaluate, I guess, my willingness to ever consider using
it again. Ron does a great job explaining the HDL paradox, meaning why is it that all the pharmacologic efforts
to raise HDL seem to also raise heart disease
or at best make it no better.
And finally, we end with a discussion
of PCSK9 inhibitors, which I suspect
will have a completely dedicated podcast
to this topic at some point.
And we touch on LP-Litol-A, though later on
in the release of this podcast,
we're gonna have a dedicated discussion on LP Little A.
Okay, so with all that said,
you can find a ton more information,
including a lot of links to the papers
that Ron has mentioned, more information about Ron
in the show notes, which are at peteratiamd.com
forward slash podcast.
So without further ado,
here is my conversation with Dr. Ron Kraus. Well, I'm here with Dr. Ron Kraus today, and this is a really exciting topic for me.
People know I've written about this a lot. I talk about this a lot clinically, but the genesis of this discussion today is that about a month ago,
I called Ron to have a discussion with him about one of my patients in particular.
He was a patient who had a pretty elevated calcium score if I recall.
Pretty significant LED calcifications.
That's the artery in the left side of the heart.
But he was very hesitant to do any treatment and he wanted a second opinion, so I thought
we should involve Ron.
And Ron, I remember I was sitting in my kitchen, we spoke for probably half an hour.
And at the end of the conversation, I said, you know, Ron, I wish we recorded that conversation
because this is exactly the kind of stuff that I think a lot of physicians and patients
would benefit from.
And so I said, you know, why don't we do this again more formally and that brings us here
today.
Let's start with a big question,
but an important one for where we're going.
And that's basically the pathophysiology
of atherosclerosis.
A very recent review article I read
described it quite eloquently
as a smoldering inflammatory condition fueled by lipids.
What does that mean?
Well, first of all, thank you, Peter,
for asking me to talk
with you today and address this topic, which is, you know,
I have a deep and long standing interest in.
Hopefully I can address the issues
that you're also interested in.
And we'll have a good conversation.
Well, as we're as gross as, of course,
is the underlying process that leads ultimately
to vascular disease, particularly clinically
offense, heart attack and stroke.
It starts in childhood, as well known that there is early on the buildup of
cholesterol in the artery wall that forms what's called fatty streaks.
And that's a process that's actually a fairly normal condition, even to young
people.
And if it doesn't progress any further than that, it's really not hazardous. It's a way that arterial tissue can put
cholesterol in its cells, and some of that cholesterol is actually used for various
purposes. So that's not necessarily a pathologic process, but it can progress.
And when it progresses, there is a combination of factors that conspire
to make that fatty streak into a much more toxic process. And it is fueled by lipids,
the same lipids that lead to the fatty streak. But under conditions that many of us live under,
there are changes in the lipoproteins that are taken up by the artery and we'll talk about those
in more detail in a minute.
In particular, susceptibility to oxidation and the change in the properties that allows
them to stick more tightly to the artery wall.
When that happens, particularly the oxidative changes, it does trigger inflammation as a
very early part of this next phase of the disease process.
And inflammation is defined in one way as the accumulation of cells in the artery wall that
deliver various inflammatory molecules, things that ordinarily, if one bruises oneself or
has some sort of an injury, those inflammatory processes cause redness and accumulation, in
some cases, of clotting factors.
When that happens in the artery, that can convert this fatty streak into something that is
much more mildly.
And then there is a process that kind of feeds on itself.
And it does involve platelets and clotting factors in an important way.
It involves a number of inflammatory molecules. And if there's continuing input of these bad, anthropogenic, if you will,
alipoprotein particles, that can actually change the nature of the plaque.
And inflammation comes into play in a very serious way when that results in a breakdown
of the surface of the plaque, which ordinarily protects it from any kind of serious consequences.
So even fatty streaking developed,
which can develop into a plaque,
and a plaque in this case is essentially a larger fatty streake.
The plaque has a cholesterol,
but it also has all these other cells.
It's a much more complex phenomenon.
So that plaque is ordinarily,
under relatively benign conditions encapsulated by a fibrous
layer, but the inflammation in the release of various molecules can cause that fibrous
cap, that protective cap, to weaken and ultimately potentially rupture.
And when that rupture occurs, that is the beginning of the end, in terms of the process that
we're talking about here, most cases of heart attack and stroke involve
this type of acute rupture
and ultimately formation of a clot
that blocks the arterial flow.
So starting from a relatively benign process,
this can develop into something that's much more serious.
Now, when I was in medical school,
I remember in first year pathology lecture
the pathologist said, let's see a show of hands.
What is the most common first presentation of heart disease?
And you know, everybody puts up their hands
and says, a chest pain,
left shoulder pain, shortness of breath,
and he said, no, no, no, no, it's sudden death.
Yeah.
That was a little over 20 years ago.
Is that still true today?
Estimates I've heard,
and I think this is arguable
because these are really rough
rule of thumb calculations, somewhere in the range of 30%, possibly upper 30%, which
is still a huge number.
It's staggering.
It means that one third of people's first brush with the knowledge that they have atherosclerosis
is death.
And I have patients, and I'm sure you do as well, who will have died and come back. And so there is this process where there's an acute event that causes an irreversible change,
but for some people fortunately we can bring them back.
But together that represents really the basis for calling this disease the silent killer.
Because as you were saying, we don't, in those patients, have a medatory symptom.
Sometimes in retrospect, they are there.
I think that's the important reason for educating the public
as organizations like the American Heart Association does,
as to the first signs of heart disease,
because it may be, and it probably is true,
that a significant component of that 30%.
Right.
Upon further querying, there was some exercise in tolerance.
In recognition of it. Yeah. And it exercise intolerance in the rest of the day.
I recognize it.
Yeah.
And it's very hard sometimes.
One of the things that we'll be talking about is ways of assessing risk.
And those are still imperfect.
And we can't, with 100% certainty, use any kind of risk predictor to know if somebody's
destined to have a heart attack with certainty.
Yeah.
You said something at the outset, which is this is a disease that begins in infancy.
And I have very few textbooks and or papers that are, I refer to so frequently that they
actually sit on my desk in my office so that every time I'm with a patient, I can pull
them out.
But one of them was a book that was given to me by one of my mentors.
I consider you a great mentor, Tom Daye, spring a great mentor, Alan Snyder, I'm in
a great mentor.
And Alan gave me this textbook of pathology.
I think believe it's Stari is the author. mentor Alan Snyder, I'm in a great mentor and Alan gave me this textbook of pathology.
I think believe it's Stari is the author.
And while I believe the data represented there are somewhat dated because it was largely based
on the Vietnam cohort.
And Koreans.
Yes, where obviously smoking would have been a higher prevalence than today.
Right.
The fact remains that when you look at autopsies of young people who died of unrelated reasons,
homicides, accidents, etc. and you look at the histologic sections of their coronary arteries,
it's amazing how many of them have lesions that are type three or beyond, type three meaning
obviously a type of pathological region where you go beyond fatty street.
Yes, indeed.
That's right.
So a subset of these use will have more advanced lesions and the studies that have been
done have linked all of the usual risk factors, smoking, certainly diabetes, hypertension,
and dislippidemia, all of, and in a lipid disorder, all of those have been associated with the
more advanced lesions in those individuals.
So is your point out even a more significant
plaque development in a current childhood?
I think the thing that's hard for people to understand
and I think it's true of most chronic diseases,
but I don't think any disease in any disease
it is as clear as it is with atherosclerosis,
which is the compounding nature of the disease.
You know, another great example of one of those questions that the professor asks that gets everybody stumped,
which is what's the greatest risk for heart disease?
Is it smoking?
Nope.
Is it high blood pressure?
Nope.
Is it dyslipidemia?
Nope.
It's age.
It's age.
I mean, and why is it age because it's exposure?
It's time.
It's area under the curve.
Yeah, that's exactly true.
Age, regardless of the risk factor that cuts across many of the diseases, chronic diseases
that we have to deal with cancer, for example.
And yeah, that's right.
It's a cumulative process that can progress at various rates depending on the condition.
So people, as you know, when we talk about who have genetically elevated, severely
elevated cholesterol levels, we'll have that process accelerated and have a disease Well, as you know, when we talk about who have genetically elevated, severely elevated
cholesterol levels, we'll have that process accelerated and have a disease so up clinically
early on.
Sometimes with these sub virginative disorders and the teens, whereas others, most of the
population, fortunately, who do have risk factors, show a gradual increase in the manifestation
of disease as a result of those risk factors as a function of
their age. You know, at last check, and I can't remember if it was JAMA or another journal, but it
was about a year ago, and they looked at some actuarial data for people out through being past
centenarians. And the only disease, once you normalized for a few things, the only disease that
increased monotonically by decade in risk was atherosclerosis.
From childhood, yeah.
Even cancer, actually, by think by the ninth decade, it started to come down.
Yeah, yeah.
It's definitely the latency period.
If a cancer also is a factor there as well,
so there's this sort of latency period where nothing happens
and then all of a sudden an older age pops up.
I'm sure a lot of people listening to this
are gonna say, okay, well, God,
I'm really confused by half the terms you guys just used.
So let's unpack some of them.
Beginning with, we use the term sometimes lipid,
cholesterol, lipoprotein.
We throw those terms around interchangeably,
but I think it's probably important
to give the average person a sense of an understanding.
So what is LDLC versus LDLP versus APOB, things like that?
Sure. The underlying concept that we are going to address is cholesterol, because that's really
the compound. It's the molecule that winds up causing plaques. So cholesterol is indeed an
important component of the plaque, and it gets into the plaque by uptake of cholesterol
from lipoprotein particles. And so lipoproteins are complex spherical macromalculose, big guys,
which come in varying sizes, and are composed of cholesterol along with other lipids, such as
triglyceride, and most importantly, perhaps for distinguishing the various types
of lipoproteins, is their protein content.
So there's a variety of different proteins that form the package that actually capsule
around the lipid.
So let me interrupt you for one second.
Is it just a point at clarification?
The reason we even need these lipoproteins is that cholesterol is hydrophilic, pardon me,
hydrophobic.
It repels water.
And so therefore, to move cholesterol through the bloodstream, you have to package it in
something that is hydrophilic or dissolves in water.
Right.
Right.
And for the techno files here, it's the cholesterol ester.
So there's two forms of cholesterol.
And it's the fatty form of cholesterol is cholesterol ester. The other's two forms of cholesterol, and it's the fatty form of cholesterol is cholesterol
ester. The other form is more waxy. So the fatty form is transported right from one tissue to
another, and that is the purpose of lipopropylines, not just cholesterol, of course, but triglycerase,
as I mentioned, even perhaps more importantly for many functions, energy metabolism, and other
compounds such as phospholipids, as well as passengers on the truck, certain vitamins,
etc. So these are packages that serve an important biologic function. They're not here to cause
heart attacks. We divide them into various categories, but the common parlance, the most typical
way that we think about cholesterol as a pathologic factor is when it's on LDL. So that's called LDL
cholesterol. And that measures the amount of cholesterol's called LDL cholesterol. And that measures the
amount of cholesterol on an LDL particle. And LDL is low density lipoprotein. So this is a form
of lipoprotein that is characterized by size and it's also characterized by its density,
which is related to its capacity to float because there's when there's fat in anything, it causes
the thing to float and that's to there's fat in anything it causes the thing
to float and that's to varying degrees defines different classes of lipoproteins and it's the LDL
that is the most strongly connected to cardiovascular disease risk and the cholesterol in LDL
which is measured commonly clinically as LDL cholesterol is what has been most widely associated with cardiovascular risk and forms
the basis for many of our recommendations for lowering risk.
But it's important to recognize that this is a tag on a much more complex substance,
a particle, and this will talk about, I think, very shortly, particle is what causes the
plaque to develop, and it brings the cholesterol with it.
So the LDL particle, the low density-like protein itself, the spherical molecule, or macromolecule,
which carries around cholesterol, astral, phospholipid, triglyceride, it has a signature on it,
doesn't it?
Something called APOB100.
That's right.
The key protein that holds this particle together that allows it to form a sphere and to encapsulate
the lipid cargo is called APOBROTINB.
There are two major forms of APOB.
The one that's found in LDL particles is called APOB100.
And oftentimes that is used as a surrogate
for measuring LDL particle concentration,
as we'll talk about.
And this is a big clinical distinction.
I think it is safe to say, at least in my,
you know, relatively modest sampling of physicians.
Most physicians, let alone most patients,
are not really clear on the distinction
between the number when they say LDL is 100.
They don't necessarily realize what they're saying is the LDL cholesterol is 100 milligrams
per desoliter, meaning if you took all of the LDL particles in the body, smash them apart,
gather the cholesterol ester.
The mass per unit volume is 100.
And that's very different from saying
how many of these particles do we have?
That's right, and that's important.
So that observation really forms
a very significant component of my history in this field
because I entered the field as a young fellow
knowing about LDL cholesterol.
It's interested in diet effects and drug effects
and heart disease,
but I learned about lipoproteins actually from a group of investigators in Berkeley, California,
who were part of a team that initially identified lipoprotein particles.
And over the course of the next ten or so years, I dug into that knowledge and discovered that
there are subtypes of the various forms of LDL, as well
as other laparotines, which we can talk about, perhaps in a few minutes, but focusing on the LDL,
there can be variation in the amount of cholesterol that is carried on the LDL particle,
but there's only one APOB for LDL. So APOB represents a pretty good signature for an LDL particle.
This found on some other particles, but it's primarily on LDL. But the amount of cholesterol
attached to that APOB as part of this particle can vary as can other lipid components.
And that results in variation in both the size, as I mentioned, and the density, so that some
forms of LDL have less cholesterol, and some have more cholesterol.
The ones that have less cholesterol are smaller, generally, and the ones that have more cholesterol
are larger, but they all have one able protein B. So there can be an important clinical
consequence of focusing on LDL cholesterol to the exclusion of
of APOB because it's the particle that is really the agent of damage in the
artery and measuring LDL cholesterol can under represent the number of LDL
particles compared with the measurement of APO protein B or APOB which is a much
better measure of the number of particles.
And when individuals have smaller particles because of this variation in lipid content,
they are actually at high risk of heart disease because those particles have properties
that render them more pathologic, more toxic. So there's a double whammy. If you have small particles,
first of all, clinical measurement of LDL cholesterol may under
represent a number of particles, and furthermore, those particles themselves are considered
by many, although there's still not total consensus on this point, to have greater pathologic
properties.
So, let's use a specific example.
So, if a patient has a blood cholesterol level, and let's just assume
it's LDL, a measured directly, not even calculated, and the LDL cholesterol is 100 milligrams
per desoleter. At the framing hand population, that would place them at about the 20th percentile.
But let's say that patient has an LDL particle number of 1,300 or 1,300 nanomole per liter.
And of course, in the units that tells you it's a number per unit volume, that places
them at the 50th percentile.
Now, at least to me, the literature is very clear on, in the case of discordance, which
of the two is driving risk.
I think both the Mesa population,
the multi-ethnic study of atherosclerosis, and the Framingham and Framingham offspring study
make it very clear that risk is tracking with the number of particles, not the cholesterol
concentration. Do you agree with that or am I missing something?
No, the data are out there. And just to take a step back, LDL cholesterol,
that clinical measurement, has worked reasonably well for a significant subset of the population
as a marker for LDL particles because most individuals have particles somewhere in the middle
of the LDL size and density range and the cholesterol content in those particles is fairly proportional to the number of LDL particles.
But where things break down is the increasing proportion of the population who have different
LDL particle distributions.
You need to consider that higher LDL particles with normal LDL cholesterol, which I will
answer your question.
Yes, it is associated with an increase in risk that's not reflected by LDL cholesterol. So that is the discordance we're talking about on the high end
and conversely individuals who have high LDL cholesterol, but normal levels of of April be will
tend to have disproportionately less heart disease risks than would be predicted from the LDL cholesterol.
So that's the discordance, which I think is pretty well
demonstrated in a significant subset of the population at both ends. But underlying that, and again,
there's some debate on this issue, it certainly reflects the numbers of particles, and that is
the bottom line. But it also reflects the types of those particles. So there's really two features
at both ends of that distribution, smaller cholesterol, two particles associated
with discordance at the low cholesterol, the apoprotein B ratio, and conversely larger LDL
particles associated with less risk at the other end.
And there may be systemic factors here at play because, you know, there are some pretty,
I think, pretty widely accepted data now. I think 10 years ago, this was a little more
obscure, but one of the greatest drivers of the discordance
in the wrong direction,
meaning the LDL particle is disproportionately higher
than the LDL cholesterol is metabolic syndrome.
In fact, there's a very beautiful graph
that I've written about at some point in my blog
that talks about how based on anywhere from zero to five
of the characteristics that an individual has
of metabolic syndrome, the proportion of discordance goes up. So it also could be that as discordance
rises, risk rises because of the other factors such as hyperinsulinemia, which itself may contribute
to intimal damage, inflammation, and other things. Is that possible? It is absolutely possible and likely to be true.
So this brings up a pattern, a lipoprotein pattern, that I will take some credit for having
to find in my own way about 25 years ago, 27 years ago now called the atherogenic dyslipidemia
or atherogenic lipoprotein phenotype, which is a constellation of lipid changes that includes higher triglyceride, lower HDL
cholesterol.
So that's the cholesterol in the protective form of lipoproteins being deficient and a
predominance of smaller LDL particles.
And so that triad, that lipid triad, has defined the atherogenic dyslipidemia and it folds
right into the metabolic syndrome.
Right. Two of those three make up two of your five criteria for metabolic syndrome,
which for the listener, would be low HDL cholesterol, high triglyceride,
high fasting glucose, high blood pressure, and girth, basically obesity.
Exactly. Drunkle obesity.
Yeah. So I remember being part of the discussions where that metabolic syndrome was defined. And it's a very interesting. Yeah, well, that started with insulin resistance as the centerpiece.
You can put various molecules and various processes toward the center. They all contribute.
And as you point out, hyperincylnemia, associated with insulin resistance is likely another marker
of another process related to glucose metabolism and its consequences.
And then the blood pressure connection is an intriguing one, but that's also part of
it.
But a lot of that is driven by increased growth.
I mean, it's sort of of the five conditions.
The one that I think is the most prevalent underlying factor that leads to the development
of metamaloxinium is increased abdominal fat, which is associated with increased
specific cholesterol fat.
This is a fat around the internal organs.
And you can have metabolic syndrome without that, but the vast majority of people that
certainly Caucasians, yeah.
Yeah, and non-calculations populations such as the such as the Stations who don't have
increased waist still can have increased fat internally
as part of the syndrome.
But it's probably acting on an underlying genetic predisposition, which is very common.
And so, and there's many other factors that come into play as part of the syndrome.
But I would say that just lipidemia is probably both clinically and pathologically the one
that I think has the most substance in terms of a direct causal connection to cardiovascular
disease.
Yeah, and I'll tell you, it's a very interesting historical footnote, Gary Tobs, a mutual
friend of ours, and I don't know if this actually was in any of his books, or I might have
read this in one of the outtakes, but it was an interesting footnote, which was basically
at the time of the Framing Him study, which I'm talking about the very, very first Framing Him study,
which was really a two-part study, of course.
One of the things that came out of that study
was that low HDL cholesterol and high triglycerides
was four times more predictive of atherosclerosis
than elevated LDL cholesterol.
Now, that rings true with what we just said
about metabolic syndrome.
Nowhere in the five criteria of metabolic syndrome was high LDLC.
It's low HDLC and high trig, but it's interesting that the LDL cholesterol story really took
off and at least Gary argued, I believe, if I'm remembering the argument, that part of
that had to do with the fact that the, got I'm blanking on the name of the, the first trial, there was the LRCCP,
but then there was the one before it.
Oh, it had a funny name, like, improve it or something, but it wasn't, it was like,
you know, it was a trial of, the library, the library trial, you think?
The library trial was LRCCP.
No, that was, that was close to our, I mean, so I think that's when you're thinking,
oh, okay, okay, I think you're thinking of this LRC.
Yeah, I was, I was, and so part of the LRC. You were at NID.
Yeah, that's where I got my training in Liptids
before I came out to Berkeley, actually.
That's why I got my first dose.
And that study was going on at that time,
and there was a lot of nail biting.
Well, and the argument here was, look,
we kind of spent, we lost a decade and a half
between, say, 1980 and 1995,
when we missed the role of insulin resistance because we
really went down this LDL cholesterol rabbit hole and didn't necessarily see the bigger picture.
And one of the things I hope we have time to talk about today, because it's actually something
that I spend more time scratching my head about than anything else is you look at a drug like Niasin, which lowers APOB, LDLC, and raises HDLC.
So in theory, it's doing everything in the right direction.
And yet when it comes to outcomes, it's a very confusing picture.
So maybe later on this afternoon, we can get to that because I think that's, there's
going to be some rich info in there.
If you put that on a table, I'll be happy to pick it up when you're ready.
I'm ready to launch it to that. I cannot wait.
We're definitely going to do that.
So, okay, let's talk a little bit about a paper that you were an author on this year.
It was the European Atherosclerosis Society consensus statement.
Now, you and I were joking about this a while ago that you almost couldn't believe this
paper needed to be written, but sometimes there's a benefit in writing it.
And what was the conclusion of that paper?
Or more to the point consensus statement,
it was more than just a paper.
I mean, it was really a tour de force.
So this paper assembled a multiple lines of evidence
addressing the question, this LDL caused heart disease,
is LDL a causal factor for heart disease?
And just to be clear, the counter argument is sure people
with high LDL are more likely
to get heart disease that can't be disputed.
The epidemiology is clear.
The counter argument is, but LDL is not a causal role.
That's right.
And it's associated with that.
Efforts to lower LDL cholesterol are not fully justified as a means of attacking the
cause.
I don't want to be responsible for having stated that incorrectly
because I still can't quite believe anybody
would hold that opinion,
but that was my understanding that led to the
who coming together to counteract that perception
that lowering LBL was not beneficial.
But there are many people.
I mean, not that I spend terrible amounts of time on Twitter,
but it's a pretty commonly held view at least in the vocal minority that love to
Write about this and talk about this that hey LDL cholesterol is a myth like heart disease has nothing to do with this
And the problem is and it's a come out in the paper to some extent, but I'll tell you there is a second
component to that effort that is still being written
It was planned and will be a two-part series.
The first part is assembling all the evidence
from epidemiology, clinical trials, genetics, et cetera,
that speak to the causality.
And the second one was really relating all of this information
to the role of L.D.L. in the path to physiology
of atherosclerosis.
And that paper is a work in progress.
But it clearly goes to papers assemble just about And that paper is the work in progress, but it could be those two papers
assemble just about all the evidence when needs to support the use of LDL cholesterol. And when will that second paper be out?
I can't tell you.
We don't even know.
It has taken longer if we thought.
Well, we'll certainly link to the first one in the show notes because that was published in early
2018.
Yeah, we expected it next year or so.
But one thing I do want to say because there's a caveat
and part of my life as a researcher,
as well as a clinician, is recognizing
the complexity of what we're dealing with.
In discussions such as this,
it's important to keep the concepts straight forward
and understandable to the best to be possible.
But the flip side of that is the risk
of oversimplifying a complex situation.
So when I just said that the evidence
is that lowering LDL cholesterol is beneficial,
that's not always true.
And so when it can point, if one is so inclined
to the evidence that under certain conditions
and certain populations with certain approaches,
the only LDL cholesterol does not result
in reduced heart disease risk.
And to the extent that you consider that
to be a fatal flaw in the argument,
that can be, I think, brain misleading
because it's not the fact is that LDL is causal,
but there are other circumstances that modify
that causality to the extent that some forms of LDL under certain conditions and this may not be uncommon can be elevated
without pathologic consequences.
And so lowering LDL in those cases may not give benefit in that.
We know that there is heterogeneity in the clinical response when it looks at how do
you ask for protection with LDL lowering treatment.
So I have to absolutely extend the simple notion of LDL
causality to saying that when has to look very carefully at the arguments against LDL
causality because they latch on to piece of piece of information that are really misleading.
It's just because lowering LDL cholesterol is not always beneficial.
It doesn't mean that LDL is not pathological.
And the second component of that is the focus on LDL cholesterol is not always beneficial, it doesn't mean that LDL is not pathological.
And the second component of that is the focus on LDL cholesterol that goes back to our
initial discussion here today as a marker for a causal mechanism, but it's the particles
that are causal.
And LDL cholesterol, as we just talked about, does not always mirror the number of LDL
particles.
Now, I don't think we should necessarily take the time to go through the paper in incredible
detail, but it did touch on eight criteria for causality, plausibility, strength, biological,
gradient, the temporal sequence, the specificity, consistency, coherence, and then the relative
risk reduction or risk reduction with an intervention.
Among those, I found the Mendelian randomization
to also be very compelling.
So when I talk about this with people,
I generally talk about the natural experiments,
such as the people with PCS-K9 mutations,
both hypofunction or gain a function,
loss a function, PCS-K9, the FH patients, the Mendelian
randomization and the intervention.
If you were going to bring up three points from the paper that you think probably are
most relevant, what would they be?
Well, you've just touched on probably the number one strongest argument.
It's really where we, those of us who have been in the field for decades started
with being impressed with the role of genetic elevations of LDL, very, very strong evidence.
I would put that probably right at the top.
And you talked about this condition, familiar hyperclestrolemia, when there's two doses
of an abnormal gene, the LDL levels in the skyrocket.
I referred to that a little while ago,
as the condition that can lead to heart disease early in childhood, it's unequivocal. In fact,
the reason I got a little bit taken aback by the need to do this more extensive review, which I think, by the way, was quite a good exercise, both for those of us who did it,
and people hopefully who read it. But all you have to do is look at a eight-year-old child with cholesterol levels that are
eight or nine times normal, who's candidate for liver and heart transplant to know that
that's it, that's causal.
But the genetic support is beyond that.
Right. Now in those cases, the genetic defect is one in the LDL receptor.
Correct. So closing the loop on how this works, right?
The body makes cholesterol.
The body, so every cell in the body makes cholesterol.
Then cholesterol gets recirculated,
ends up mostly back in the liver.
It gets secreted.
Some of it in bile gets reabsorbed,
and this process continues.
But it's this LDL clearance,
mostly via LDL receptors in the liver,
that seems to be where a lot of these genetic things go awry.
That's right. Yeah, the liver really is the factory, as well as the disposal plant, if you will.
Most of the cholesterol that winds up in the blood is released in terms of
lipoproteins that are synthesized by the liver, and then they come back to the liver ultimately after they've
done their thing, so to speak,
deliver their cargo or interacted with cells in various ways and come back to the liver.
And a large portion of that return is mediated by these receptors that latch onto April beat.
It's April B that is the kind of the key that binds to the lock that snaps up the LDL and the liver
and it grades he grades it and
exweats it into bile. And that's the way we dispose of cholesterol. There are
other mechanisms involving HDL, but the receptors are a key determinant and
do represent a mechanism by which most of the drugs that we use to lower
cholesterol act to increase LDL receptor mediated disposal of LDL particles.
And I'm just going to connect that concept to something you brought up earlier. And that is the
duration of exposure to, in this case high levels of LDL, we talked about it as a function of age,
in the reviewers, the longer the exposure. But there's also a dynamic aspect to LDL metabolism that we just touched on.
That is particles are produced actually precursors of LDL, which are called LDL, which is carried
mostly, try, this is right, and apoprotene B as well.
Those particles are being actively secreted.
They interact with peripheral tissues and receptors and other transporters that handle
various lipids and various ways, and enzymes, etc. There's a lot of processing that goes on.
And then what's left comes back to the liver through all the other receptors. Now, if that
process happens briskly, if there is a nice fast turnover, if you will, of those particles,
fast turnover, if you will, of those particles. You can just see that there is less time for the arteries to be exposed to any of those pathologic forms of lipoproteins. They can be scooped
up. But what underlies, at least to me, a common concept, a common underlying factor that
connects various lipid traits to heart disease risk is the extent to which
they influence the circulation time.
That is the length of time that a particle is circulating in the blood so that particles
are not being cleared by LDL receptors efficiently.
They will circulate longer and have more opportunities for mischief.
What is the typical half-life of a VLDL particle?
So very low-density lipoproaking, ideal intermediate density and low density?
I'm probably going to get this wrong, and this is where I don't want to have to go back and look at the textbook and I just over.
Well, directionally.
Yeah, so particularly for a larger VLDL attract this right, the half-life is half an hour an hour, two hours, it's pretty rapid because that particle is rapidly subject
to enzymatic digestion.
Well, let me just jump to the LDL.
So the LDL that are formed from those precursors, you know, more like 12 to 24 hours or longer.
So it turns out that smaller particles have a longer resonance time because they are less
avidly removed by LDL receptors.
So there's a range of circulation times for LDL,
in some cases, days actually.
And then, IDL are somewhere in the middle.
The intermediate density of that bepotians are IDL,
is what you're referring to.
That's the step between VLDL and LDL,
that is involved in their metabolism.
So it's these longer exposure times,
and these intermediate particles can include,
and do include, very pathologic forms as well.
And so there are disorders and metabolic syndrome
coming back to that is one of them,
where the clearance of those intermediate particles,
which also comprise what we call remnants,
partial breakdown products of VLDL on the way to forming LLDL.
Those intermediate particles can have much longer exposure
times, and they can be subject to various pathologic effects
involving oxidation, the position of partial digestion
products of various lipids that cause them to be more toxic.
And those particles can be damaging even
with a shorter residence time because they're so toxic.
So that gets into what I was referring to earlier as a semi-degrainer complexity of beyond
thinking just about LDL cholesterol, thinking about LDL particles, thinking about the types
of LDL particles in terms of the pathophysiology, and then also thinking about the role of these
remnant lipoproteins.
They all participate in this potential risk.
And it comes down in my view in the end
to the length of time that a particle
with certain pathologic effects
is circulating in the blood.
And this VLDL cholesterol, VLDL remnant problem
is one that is unfortunately very often missed
even by relatively astute clinicians.
Your textbook case is these type threes,
these hypertrageless
redeemias who have normal APOB, normal LDLC, you think they're relatively low-risk,
you sort of miss the fact that their VLDL cholesterol is 75 milligrams per
desolate and they have these just devastating atherosclerotic plaques.
Yeah, and that was again one of my experiences, when I was at the NIH, I was at the NIH at a time
working with Dr. Fredrickson and Levy when the various...
Just for the listener, it's important for them, I think, to understand the luminaries
that you just described, right?
Fredrickson, Levy and Levy's, I mean, let's put these guys in context, right?
This is, you had people that figured out that there was this thing called cholesterol,
but it was really those three that did the pioneering work
in the 1970s that laid the groundwork
for fractionating, figuring out all of the different sub-particle.
Late 60s.
Late 60s, early 70s.
No, it was late 60s.
I'll just give you a slight anecdote
since you paused me on this. I would have always
been interested in heart disease because it runs in my family. As a medical student, I read a series
of five articles that was published in the New England Journal of Medicine, and I think you're
referring to the three authors, Fedrickson, Levy and Lee's, that completely transformed me.
It was a epiphany because those five articles
describe lipid disorders in terms of genetic types,
different lipoprotein profiles that had
different metabolic effects, different consequences,
and burn-filens differently by various diets.
And I thought this was absolutely
the most important lead I could imagine.
So I made it my business when it came to deciding
what I was going to do after my medical training is to come down to the NIH and work with those guys.
And I was fortunate enough to be able to do that. And it was really in the era where what was called
the Fredrickson typing system identified these various forms. And the one you just referred to, the genetic forms of lipids that we
don't often always consider, it was called type three. And that was characterized by abnormalities
in receptor-mediated clearance of these remnant particles through a mutation in April protein
E or variant of April protein. And that also was fascinating. And I happen to be in California
when the APOE is were discovered. So I sort of feel like one of these characters
that just shows up at the appropriate time.
It was called the Arge Rich Pep Died
and the history is just, I wrote a,
we wrote a review actually of the early history
of L'Apo protein research,
which I would commend to the...
Let's put that on the list here.
It was in the journal lipid research in 2016.
In fact, I just got a fan letter for that article
because anybody that's seriously interested
in this field should probably understand the origins.
In fact, I got a letter, we have that paper was published.
I got an email from Joe Goldstein
who is the other one of the other.
Oh, yeah, another letter.
Icons in the fields.
He said everybody that goes into lipid research
should be this paper.
So it's not a book.
I don't make any money off of it,
but we're gonna make sure that people
don't get smart on that screen.
Anyway, paying back to these remnants,
I think particle for particle,
the remnants are probably the most pathologic particles of all
because of this ramp and ethosgroicist
when there's elevation of remnants.
Unfortunately, this condition of type three
is fairly rare, it's like one in 10,000.
But it does illustrate the same biology.
I've seen so.
So you've seen so.
Right.
So when I was starting to say, actually initially what I was
starting to say when I was at NIH and my training, I saw all
these things.
All the types were there.
You collected them.
We had patients who had the type 3.
We had type 1, which was a serious elevation of triglyceride.
Type 2 was familiar hypercholestroeninia.
It goes on and on.
So yes, and it's really striking.
I tell my students, I lecture on this
to students at Berkeley.
I show them pictures of what are called xanthomas,
which are deposits of cholesterol, lipids, and tissues.
And you have these very characteristic lesions
that used to be
rampant in patients before we had adequate recognition and treatment. As a manifestation
of the underlying pathology that also affects the arteries, the cholesterol that winds
up in the arteries can also break into the skin. And these are just very striking illustrations
of the role of genetics. So it gets back to your earlier question about causality.
There are so many situations where genetics helps in establishing causality, and this certainly
is one of them. After that, you asked me, what are you know, one, two, and three? You asked me how
many of my top three are. Even before we leave FH, I think the other nice thing about the PCS K9 mutation, you know,
FH is only showing you the change in one direction.
But with PCS K9, you see both directions.
That's right.
I believe the hyper functioning were the first people identified, correct?
Yes.
So these people had an enzyme PCS K9.
It hyper functioned.
Therefore, this enzyme's one of its roles
is to degrade the LDL receptor.
And so they had fewer LDL receptors,
they had more LDL, they looked a lot like FH patients, correct?
Yeah, yeah, I just begin for the technical
where it was on the phone.
Oh, it's actually not, it's not an enzyme.
It kind of behaves like an enzyme,
but it actually drives LDL receptors
into the garbage disposal machinery in the cell called lysos, but it actually drives LDL receptors into the garbage disposal
machinery in the cell called lysosomes and it causes the LDL receptors to be broken down.
But it's the same end basalt as you get less LDL receptors, higher LDL cholesterol.
And then the mutations in the other direction are the ones that led to the development of
PCSK9, the loss of function, antibodies to PCSK9 mimic the loss of function, and everybody's CPSK9 mimic the loss of function mutations, which lower LDL.
And that's one of my, you know,
when I get to tell these stories one day,
I'll look back and say that was my aha moment
because I think that paper came out in 2006
in the New England Journal of Medicine.
It was either O406, but I remember this well,
which was the discovery of those families
with the hypo functioning ECSK9.
These people walked around with an LDL cholesterol between 10 and 20 milligrams
per desolate. Two things about them stood out. The first, they never got heart
disease. The second, they didn't seem to suffer any other consequences that you
might concern yourself with.
Right. Yeah. One of those patients, classically, I think a physical therapist, somebody that was very active,
and had an LDL of in the teens, which is, you know, 1-6 normal, and is doing fine.
Yeah, so that's another use of genetics in a way to confirm that lowering a LDL, not
necessarily using all the ways that LDL can be lowered,
but at least certainly that form of LDL lowering is healthy.
And probably most forms of LDL lowering are healthy.
We have very little evidence to the contrary.
Do you want to say anything about the Mendelian randomization?
It's, you know, I think it's not a the most intuitive concept to people, but it is actually
a very powerful concept.
So the principle of Mendelian magnetization,
first of all, Mendel,
regular Mendel was a 19th century monk
who discovered the principle of inheritance of traits
and peas, actually.
The idea is that these genetic variants
are randomly distributed in the population.
So that assumption underlies this concept of many,
many of the randomization because then you can say that the occurrence of a genetic
variant in the population or or a collection of variants can be their single or multiple
variants that are associated with a biomarker such as LDL cholesterol can be used to test the causality of LDL
by looking at another relationship and that is the association of those genetic variants
with the disease process. So for example, and so I'm going to give you an example because it's
really a little bit abstract without an example, and we'll talk about PCSK9. So the PCSK9 loss
of function mutation causes a lowering of LDL. There is independent evidence that that mutation
is associated with reduced cardiovascular disease risk. Nothing to do with LDL, just the genetic
association with outcomes. That relationship parallels very closely the relationship of that variant, LDL cholesterol.
The difference is that the risk associated with
a genetic variant, the risk of heart disease,
is actually less than would be
predicted from the LDL cholesterol using standard risk relationships,
because this is lifelong exposure.
This gets back to the exposure issue.
So a genetic marker like this,
and the Mendelian Mendemiss minimization model tells you that lifelong exposure to a genetic variant that
either races or lowers risk, has effects that can be attributed to LDL
because that the LDL change is predicts that risk relationship.
Yeah, whereas a lot of the conventional risk models are basically looking at
maybe a decade of risk or something like that, and they're always going to fall short, both under and overestimating
long-term risk. So in the paper that you referred to that came out of this European consensus,
there was a heavy dose of Mendelian manifestation. One of the either the main author or one of the
key authors did a very good job of showing how the genetic markers for, they're connected to LDL receptor
levels, both so PCSK9, others are associated with higher receptor activities. Well,
predict cardiovascular risk much more robustly than do the results of clinical trials.
Clinical trials only last five to six years. So that risk reduction, which is parallel, but is displaced because the magnitude of that
effect is blunted because it's not a lifelong exposure.
So it's very instructive.
Yeah.
Let's go back to something else you said a few moments ago that I think is, I would say
10 years ago, I don't remember when Jim Ottvost's analysis came out, but Jim, who's
an incredibly thoughtful person in this field, wrote a paper that basically said, once
you normalize for the number of LDL particles, the size doesn't matter.
Now, a moment ago, you said that your intuition is that that actually that's not correct, that
particle for particle, a small particle is more authentic. Is that a fair assessment of your thought?
It is definitely an assessment of my thought. And unlike what we've just been talking about,
we don't have a way showing incontrovertibly that that's true. So when tries to sort of
dance around this question by using statistics, Can you use statistics to factor out everything
with which the particle size,
and let me clarify one other thing before I go on
and that is the reason particle size got on the map
was that I wrote a paper, I think in the 80s,
actually probably 30 plus years ago,
in which the only test we had was particle size measurement.
And we showed the particle size,
small particle size is related to risk.
But we also said it was associated with lower HD
on higher triglycerides.
So that was the definition of this triad
that we just talked about.
And we never said that the particle size was independent.
We never actually said that.
We never said it was related to independently the risk.
It was a marker for this whole syndrome.
The particle size context that I was referring to early on in our discussion today was not
the size of particles, but the numbers of particles of differing sizes.
That's a somewhat different concept.
So there are techniques that measure the given number for whether most of the LDL and
the blood is larger.
And they typically bifurcate this at something like 20.5 nanometers or something like that.
And the other thing I'm going to say because this is a lot, I'm going to say it because
there's an opportunity to say it.
If you measure those particle sizes correctly, the distribution in the population is bi-modal.
That means there is a discrete subset of the population that has smaller LDL particles.
Now, that says nothing about their heart disease risk. That just, that says that there's something going on
that tips in a quantum way towards the small LDL trait.
And that is the marker for the metabolic syndrome.
So that's not about heart disease risk.
That's a metabolic marker.
The heart disease risk depends on the magnitude of that small LDL mode.
If you have a lot of, if you have a lot of LDL particles that are small, that's bad.
Now, the argument that outvows and others have made using
statistics that I will come back to in a minute as to why I
think this is a flawed approach is that if you knew certain
statistical corrections for interrelationships of various
particles with each other,
there is a significant relationship to risk of larger LDL as well.
So that's not untrue. A larger LDL can be a plastic.
I recall as long as something is less than 70 nanometers, it can enter the subenditheal
space. So any small, any larger or small LDL can enter the space. So it gets back to residence time.
Yes. How long do they stay?
How long do they do your residence time?
So it turns out, so this is going to be a little bit complicated,
but I'm going to try, maybe, no, no, we have an audience
that's willing to handle complicated.
I don't need to work through this with you,
because I know what I want to say,
and I just want to make sure that I say it clearly.
Let's talk about larger LDL.
So this, in this large LDL mode, that signifies
sort of the flip side of metabolic syndrome. It generally identifies people who have not only
larger LDL, but higher HDL cholesterol and lower triglyceride. So that's a low risk syndrome.
And often low insulin. That's right. And so quite apart from the question, are these particles better or worse, they signify
a metabolic profile where there's a pretty brisk circulation of those particles and the
exposure to the artery wall is very low.
Now if you have an LDL receptor defect, it also causes large LDL, the LDL accumulating
right FH patients, right have large LDL particles.
Right. So why is that? Why is that bad? It's because of the residents time is much higher.
Right. And so neither I, well, there's some people that have taken some of my own work
and taken it to an extreme that I don't feel is justified. And that is to say that
large LDL are not atherogenic at all. They certainly can be. There's no question about that.
The question is, are they equally anthropogenic
to smaller particles or any other particles
in the LDL spectrum?
And I'm just, I'll just say this, the work that you're referring
to did not address that.
All it said was that you can show that this large LDL
are associated with risk.
And then the second thing is that if you adjust
the total LDL particles for the peak size of LDL,
the peak size is not associated with risk.
So those are two different statistical manipulations,
neither of which, neither of which,
disprove the hypothesis that smaller LDL
carry more anthropogenic risk.
And we have an example of something I'm going to tell you again genetically,
which may or may not be something that your audience is familiar with.
There's another genetic syndrome that involves a variant that affects a vision of the genome,
which is responsible for synthesizing a protein called Sordel and SORTIL.
That genetic variant was discovered,
probably six or seven or eight years ago now,
and was associated with both high risk of cardiovascular
disease and high LDL cholesterol.
And in fact, the association of that genetic variant
with cardiovascular disease was as strong, if not slightly stronger,
than the associations of genetic variants in the LDL receptor itself. So this was a new player in the spectrum of causal factors,
again, relating a genetic mechanism that raises LDL to, in on cardiovascular disease risk through a pathway that doesn't involve
the LDL receptor.
This is not an LDL receptor story.
What we published as part of the initial description of this variant and this relationship
to cholesterol metabolism is that in two-intimated populations using two independent methods,
it's specifically associated with small and very small LDL, not large LDL at all. So here's your genetic variant that as far as we can tell, affects.
So it's not affecting clearance?
Well, we don't know about clearance. I can't tell you about clearance.
All I can say is it's not LDL, we're septum-mediate clearance.
There may be, we don't know.
This could be Neiman-Pixil.
We're one like one clearance from.
So if you can ask me later on what one of the experiments that I would do if I had
all the resources in the role that would relate to this mechanism because because the genetic association it's not clear exactly what's being
affected by the genetic variant. It's not clear how it works, but what's definitely clear is that that variant is associated in terms of lipoprotein changes or anything else that we can measure
in the usual risk factor range exclusively with small and very small and very small. It's
even a subtype of small yield yield, but it's that collection of smaller particles that is somehow
affected by this variant. Now, do those patients have elevated triglycerides or low HGLC? No.
No, it's exclusive. So that was that counters the counters the argument that I would say, gosh, maybe these small particles ultimately
are just a marker for an inflammatory metabolic dysregulation.
They largely are.
But this example is a subtype.
So this gets into what you might consider a new one.
So I'll tell you another anecdote.
When I first kind of discovered that people had all these different forms of L.D.L.
This is again in the 80s. I don't know how many. This is 35 years ago now. I was invited to give a talk, a couple of talks actually,
various meetings, one of which was in San Diego actually, and others where I presented this data.
And it was using not the current methodologies, but a very elaborate procedure involving the ultra-centrifuge,
which separates these particles into various fractions.
And I have a picture of what I showed
on the wall of my office because it's so emblematic
of the existence of these discrete forms of LTL.
And I remember talking about this to very intelligence
and experience people in the field.
And it was considered as oteric.
And for about 15 years, nobody paid any
attention to it because it was felt, you know, nobody else had methods to show what we had been
showing in large populations. Fortunately, later on, that was remedied by more widely available
methodologies that we were partly responsible for. But the bottom line is that the recognition of
these various forms of LDL, we tended to simplify to avoid having people think it was too esoteric.
So we talked about large and small as if there were only two forms and these two modes, etc.
And all that's true. But within both of those, but the small LDL, there's yet another subtype.
LDL mode within both of those, but the small LDL, there's yet another subtype.
And it's this very small LDL. So the garden variety small LDL that is generally measured by techniques that are being used such as NMR and I'm a ability method.
Why are you making sure it's the small LDL that you're talking about? It's part of this
generalized metabolic syndrome. But this very small guy looks like it's another pathway.
It's another pathway.
And it's a pathway that has a strong genetic association
with risk.
And we are, I'll just say this to this audience,
we are trying to do some studies
and this gets back to the studies I'd love to do
to test the hypothesis.
These particles may be secreted directly.
So this might be a mechanism that spits out
a pathologic form of LDL without going through.
Through the VLDL pathway.
Without going through the VLDL pathway,
that's a hypothesis that we're now.
So it sounds like almost like an LP little A type issue.
In a way it is, yeah, that's a good point.
It's a particle that we don't know how to lower,
like an LP little A, what we were saying to learn,
how to lower up, that's another topic, I guess. We're to learn, how to lower up. That's another topic, I guess. We're not going to get to Elkulele today. That's another topic. But yeah, so it's a
genetic factor that is associated with risk that we don't yet know what to do with.
So, let's go back to something that you've kind of touched on a little bit, which is
can LDL cholesterol, slash LDL particles, slash APOB, be too low. And I'm referring specifically to a pharmacologic intervention.
So I think we've already established that the people so genetically blessed to have hypofunctioning
PCSK9 seem to be completely fine.
But if someone came along and said, look, I'm walking around at the 30th percentile of the
population, I want to walk around at the first percentile of the population.
I'm going to pharmacologically lower it. Is there a downside?
Right. So, I guess I'm hung up on genetics today because I think the best scenario to consider
and evaluating the pros and cons of RELO LDL, our genetics syndrome was associated with RELO LDL.
We just talked about one of them. So, PCSK9, lots of function mutations are an example of what you're asking. Those individuals have lifelong
exposure to very low LDL. And as far as we can tell, do fine. There are people who have abnormalities
in the APOB protein that results in impaired production of LDL, ultimately, and most people do very
well. Now we have less heart disease, they think it's a live longer.
So this is the genetic evidence for the safety and the benefit
really of having very low LDL.
That doesn't imply that we can extrapolate
those genetic observations to all treatments.
Now for the PCSK9 inhibitors,
if we assume that the use of the antibodies to lower PCSK9
therapeutically mimic the genetic effect, then one would have the same confidence that this
would not be hazardous.
You don't yet know that they're not other effects of these antibodies.
It may not necessarily fully mimic the genetic effect.
But by and large, I think it is a vote of confidence that those treatments that lower that that particular treatment with PCS can add in a mission
probably does not allow a risk but have no significant downsides and for the LDL lowering
But we don't know the clinical trials of any of the drugs of lower LDL have not been long enough to know
what the lifelong effects might be
So if you look at the most widely prescribed class of drugs for lipid lowering, it's obviously
going to be statins.
And statins really do two things.
You know, they have a direct effect, which is they inhibit the first committed step of
cholesterol synthesis.
And so that directly lowers the burden of cholesterol there by lowering the burden of
lipoprotein.
But in many ways, their indirect effect is at least as strong, which is the liver in response to this, upregulates the LDL
receptor, and you get enhanced clearance. Now, the latter, we certainly have a genetic
model to look at. Do we, for the former? Do we know of people who have deficient cholesterol
synthesis outside of the extreme?
We know that there are certainly inborn areas of metabolism that are uniformly fatal.
This is a family opus.
Yeah, yeah, yeah.
But sort of outside of those people are there.
People walking around with low cholesterol or the defect is in cholesterol synthesis that
would give us confidence that, hey, inhibiting cholesterol synthesis can't be that bad.
I'd have to say I don't know that there is such a genetic variant.
There are genetic variants in the rate limiting enzyme, HMG query dark taste, that is the
target of statins that affect LDL levels in heart disease, risk in the expected direction.
But those variants have a modest effect size.
They are not big time of players to knock down LDL to those same
real low. That's what makes the PCSK9 story so exceptional. It's just nothing quite like it.
So the answer is to my knowledge, no, we don't have that kind of evidence that would apply to very
low LDLs that are induced by genetic factors. And that's a scenario that I think I clinically struggle with.
And I suspect there's going to be at least one other person listening to this that's
going to share that struggle, which is I do get a little bit nervous when I have a patient
who's risk of atherosclerosis is so high, for example, a patient with a significant
family history and a very elevated L.P. little A, just as an example.
So you've got, you know, and you know,
I seem to collect these patients.
So you've got these folks and they've got
a clinical burden of disease.
So they've, you know, they're CT and Gogram shows soft plaque,
their calcium score shows that they've got calcifications,
their L.P. little A is through the roof.
And they're tolerating their statins,
meaning they don't have the myelgyz,
their CK elevations or any of those things.
But to get their LDL where it needs to be
in a patient like that, I'm going to put
to the fifth or 10th percentile.
I have effectively by all means
that I can measure almost shut off cholesterol synthesis.
In those patients, I panic because of a couple of papers
that I've seen that look at the opposite end of the spectrum, which is
you know, they look at
markers of cholesterol synthesis in patients who are medicated and then the risk of dementia.
In particular, there's a paper that looked at those muscle-all levels and
it found that if the level was below 0.5, which is you know, generally very low on the scale we look at, and
they use that as a cutoff on the receiver operating characteristic curve, the area under
that curve, which again can vary from somewhere between about 0.5 to 1, 0.5 meaning it's a
useless test.
It's a coin toss.
One is a perfect test.
They're coming in with AUCs of the ROC at 0.87, 0.89.
That's quite suggestive of this. And certainly,
biochemically, there's a plausibility to this, right? We understand that every tissue in the body
has the ability to borrow cholesterol from elsewhere. That doesn't appear to be the case in the brain.
The lipoproteins don't seem to be able to traffic across the blood-brain barrier. So,
I guess that's just one area where I certainly don't know an answer, but I've become, I think, clinically much more quick to move
people to PCSK9 inhibitors when I get uncomfortable with the degree of cholesterol synthesis.
Do you think I'm paranoid? You've opened up a big topic all by itself, I think, that is
the off-target effects of cholesterol. If we consider the target,
that's not even the proper term.
It's the off-tissue target because it's the tissue targeting of statins
to the liver, inhibiting HMG-cleroductase in the liver. That is the therapeutic goal.
That's right. That's actually all you're really trying to do. That's right.
But we can't. We have to hit all of these peripheral tissues as well. Wow. Oh, that's right. That's that's actually all you're really trying to do. That's right. But we can't. We have to hit all of these peripheral tissues as well. Oh, that's right. So there's something called pharmacokinetic. So the last 16 or 17 years, I have been leading a program in studying statin pharmacogenetics, which is I just want to explain this again, because I know you and I are sitting here in this session. We understand this, but I want to make sure the list of understands the point you just made it's so important. In an ideal world, a statin would be a dream drug if it only inhibited cholesterol synthesis
and meaning HMG-CoA reductase activity in the liver, such that the liver would upregulate
and you wouldn't impact peripheral tissue metabolism, cholesterol metabolism, for example, in
the brain and the muscles, et cetera.
Unfortunately, that's not the case. So, I'll let you continue.
Right, so this has to do with me, with at least my exposure to this set of issues through
the role of pharmacology.
So I have been hanging out with pharmacologists for the last 15 years through this pharmacogenomics
program.
It's obvious even without that experience that factors that affect the disposition of statins
like any other drug are important determinants of clinical outcomes.
So the disposition, that term, refers to getting it to any of the tissues, but you want to
get statins to deliver.
For the most part, statins are very efficiently removed by the liver.
So that tends to offset some of the concerns that you have.
However, there is variation in the genes as well as other factors that affect a statin
disposition.
The nature of the statin itself, its chemical composition, the presence or absence of
certain genetic variants, when in particular that's been well studied, that affects the
amount of statin in the blood that prevents it from getting to deliver. Under those conditions,
there is a greater likelihood that the statin will wind up somewhere else. And that can
be muscle, which is the most common symptom, but it can be all the other tissues. And part
of my research experience right now is delving in to all of these other effects that go beyond
the desired inhibition of HMU query ductase in the liver that are actually, quote, on target
effects.
So I'm going to come back to the brain in a minute because I've been extremely interested
in the issues that you describe, and I'll come back to that.
But there is a condition that's even more,
I think, clearly connected to an unexpected effect of stat, and that is its tendency to
increase blood sugar and increase the risk of diabetes. That's been demonstrated now.
What's the relative risk?
It's about, you know, if you talk to cardiologists, they'll say the relative risk is small because
the benefit is much
weighted. Well, that risk is about 10% on average. We have
published a paper over what period of time? Over, you
know, duration of the clinical trial, six or seven years,
up to six or seven years. But we've published that that risk
can be significantly higher in women than men, perhaps
this higher 30% or plus. And so do we think that that
effect is due to dysregulated glucose uptake in the muscle?
There is evidence, and we're deeply involved with these studies, of direct pathologic effects
on muscle energy metabolism. That's more closely connected with muscle symptoms than with diabetes,
but insulin resistance is certainly another factor
that could be involved, and the muscles could be involved.
Liver could be involved.
So that's one situation where there may be on target effects, even in the liver that
might contribute to this.
We think it's probably not liver.
We think there's probably effects either beta cells and cells that produce insulin and or the tissues that insulin acts on, such as
such as the muscle being the most important. Right, right. So it's the
reason I haven't been more specifically at us. We really don't know. There's
a number of theories all of which sort of collectively could be true in
different individuals, but the net effect is not trivial.
Is it dose dependent?
Yes.
Well, there are some evidence that a glycemic effect is dose dependent.
In fact, this was very limited information on this, actually, but there is some evidence.
Are there some stands that seem to be, for example, when you look at sympathestatin,
it seems to have a much higher incidence of myalgyz or CK elevation.
When we look at the entire suite of statins, do we see some that seem higher risk for diabetes,
some that seem lower risk?
Yes.
And again, this is sort of a collection of observations from various sources.
One of the statins that's most recently been introduced is, let me call it, Patevestatin.
Livellow.
Yeah, livellow.
That group in France has shown,
pre-commissingly recently, that this is not associated
with the IBs risk.
This is kind of my go to statin.
Before I moved to a PCSK9,
and this is my last line statin.
It's not that potent, as you know.
That's right.
That's the problem, you sort of, you know,
you know, you, that, but once in a while,
you'll save someone, you'll get a guy who can't tolerate anything, but he tolerates this and you're That's the problem. You sort of, you know, you know, you know, but once in a while you'll save someone, you'll, you'll get a guy who can't tolerate anything. Yeah.
But he tolerates this and you're off to the race. Same here. Exactly. Um, so it's probably
the low or potency and it's probably its chemical characteristics. Again, when I'm, but when I'm
saying right now, it's still not established in a conclusive way, but it does suggest that
there is differences in the stands. And that being one has less association of risk
And the one that's probably most commonly associated with risk and we've seen this and studies that we've not yet even published all of them as a
Tour of a statin appears to be a
Lippetor by it's right now have a higher risk. So there's interest and we don't think that that's just due to the fact that it's so ubiquitous. No.
So would that be a reason because I got to tell you, I think when I'm confronting a patient
for the first time with a stat and I am generally almost tossing a coin between Crestor and
Lippetor as a first line agent, very quick to flip between them if I see, you know, an
ECK bumper, LFT bump, but what you're saying would almost suggest that if it's a person
who's not incredibly insulin sensitive where none of this probably matters
You know someone who's borderline you'd lean towards Crestor over Lipitor. Yeah, this is sort of putting on my
clinical judgment hat rather than my scientists have
But that's but unfortunately like for many of us
We still look we have to make decisions. You like to use evidence-based criteria
But this is actually one of the things that I struggle with
the evidence-based criteria.
We don't have the evidence that allows me to give an answer
to that other than saying, yes, I agree that that's what I would do.
And I'm also going to back up a little bit and make sure
that I have not conveyed the impression that a turbostat
and is a diabetogenic drug.
It's still a minority of the population, and we think
through genetic factors that contribute to that, we try to measure it. I mean, that's
sort of the other thing that I sort of sell patients is that this isn't going to sneak
up on a one day we wake up with diabetes. I use plenty of a torus statin, and I have at
least bit concerned about it and the patient who's risked merits statin treatment. And because,
as the cardiologists are quick to point out, the benefits of statin treatment
with any of the statins, cardiovascular risk and patients with diabetes far outweighs the risk of
actually developing diabetes. And there's even some evidence that the microvascular complications
might be improved. So, so you can argue that statins are not causing a damaging effect through
this mechanism. But it does raise just a little bit of a caution.
In fact, it's a caution.
I think it should lead to more widespread monitoring of glucose on stands, just so that
when it can detect those individuals who may have an adverse effect.
But it's still a minority of the population, and it's not something that should be considered
a hazard of drug use for our front end.
Yeah, I think for me, I am, I mean, I sort of, you know, talked to patients and I say,
look, I think there are short-term things that we're generally going to figure out in
three months, which is my algeost plus or minus a CK elevation. So either your muscles are
going to get sore with or without an elevation in CK, which is a way that we can measure
the breakdown of muscle and changes in your liver function test. We look for those elevations.
I don't know about you, but I see a lot more LFT bumps when combined with Zedia
than just statin alone.
I find a lot of patients I have that tolerate any dose
of a statin than you add Zedia.
It seems to me like 20% of people
just immediately have an LFT bump.
I haven't seen that often,
but I have seen it, yes.
And then I talk about the long-term stuff,
which is actually, I think, in many ways,
what we should be more concerned with,
because the short term stuff,
like you figure that out in 10 seconds, right?
But it's the, and the diabetes doesn't worry me
as much for all the reasons you've said,
which is it doesn't sneak up on you
and you can measure the progress.
But for, maybe I'm being overly cautious
and I've had many in argument with many cardiologists
that I share patients with who, you know, will have a patient on a maximum dose of a stat.
And if I'll give you one example, I've got a patient who came to me on 80 milligrams
of lipitor.
Still wasn't quite at goal.
We added the 10 of Zedia.
So then he was at goal.
And given his burden of disease, goal for this guy is about 700 nanomole per liter of
LDLP. But, you know, he had no cholesterol
synthesis that we could speak of. So put him on a PCSK9 inhibitor, that took his LDL down to
like 200 an animal per liter. So I said, great, let's back off the lipitor. And his cardiologist just
thought, like, I, this was malpractice. And, you know, it took many a discussion to just even get that back
to 40, and my goal is to hopefully get them down
to maybe 20 of Lepotor so that I can actually see
some cholesterol synthesis come back.
It's interesting.
But again, now we're also a little outside
of evidence-based medicine, and this is more
the art than the science.
That's right, and it's a fascinating issue to deal with
because we are conducting an experiment in the
global populations, certainly in the US, that has never been done before, and that is
prescribing statins to millions of people as a lifelong treatment without knowing what
the downstream effects are beyond the clinical trial data that we have, which is limited.
And we can call it genetics, but it doesn't necessarily mimic
the effects of using a statin drug for 40 years.
And so I'm just going to say very briefly
that I don't want to open the lid on the discussion
that many of the naysayers have used to say that statins
should be avoided because they can have
long-term effects. But I will say that's like saying driving should be avoided because driving
that some negative effects. Right, but there are things that we don't know that certainly I would
like to learn and hopefully our own research project will contribute to this. As to what may be affecting certain subsets
of the population with prolonged use
by understanding the mechanisms that might be operating
in tissues like the muscle, pancreas and the brain.
And so that by understanding those mechanisms
and perhaps developing markers for people
that may have increased likelihood of these undesirable effects that
we may be able to guide our treatment more effectively.
That's really the goal of this pharmacogenetic treatment.
Do we understand the mechanism of the myelges?
I tend to give patients, you bake one all, but honestly, the trials are, and I explained
to them, I said, look, I use it as a practice, but I can't point to amazing data.
What do we think is going on there?
We just talked earlier about the European consensus group
that I was on, whether it was the second one that I was on,
and that was...
Statinside effects.
Statinside effects.
And so the first paper, and that series came out
with a year or so ago, and that was on myopathy.
The second paper is, I think, just out,
and it describes the data, the related diabetes,
cognitive function, et cetera. The first paper attempted to address the question you asked
among other things and that is what's going on here. And all we have is a diagram that
has many points of attack where one of the things that we're actually working on, one of
my colleagues in my research program is mitochondrial targeting of
statins. There may be on target effects that is a normal response to statins in some people,
or maybe in a significant percentage population, may affect mitochondrial function in ways that
generally are not clinically important, but which in some people could be magnified and lead to
changes in muscle function and muscle number, muscle cell number. That's a hypothesis that
I'm speaking to now is the lack of a clear single mechanism that we can point to. That's
just one of several possibilities. The effects on a coinsam Q, you become all what you mentioned,
and it's certainly been out there. But as you say, very high placebo effect.
I ain't to reverse that. That's right. It has not been that successful. One of my patients,
I said, Dr. Actually, I'll say this for whatever it's worth. This is one of the clinical
pros. I have a doctor who was really a very good observer who wound up getting a liquid form
of coinsam Q as opposed to a capsule.
Capsule didn't work. His muscle symptoms dramatically disappeared or improved for the liquid form.
So maybe there's issues of absorption. Who knows?
Well, I do think there is actually, I mean, we've just empirically used a wheat test co-Q10
levels in the blood. And I've noticed for what it's worth that virtually every version doesn't show
up. The only one I have found, and just to be clear, I don't get paid by this company at
all, but there's a brand made by Jero, which I, Jero, I think is probably the best supplement
maker I've seen. And we've had some other stuff tested. But Jero's ubiquinol is so readily
absorbed because, you know, the clinical trials call for 600 milligrams.
I don't think I have a patient on more than 400.
In fact, most people at 200 milligrams
of the Jero variant reach systemic levels
that are above our on-statin target.
Again, does that mean anything?
I actually have no clue.
But for what it's worth, I've noticed
that on most other versions and variants of ubiquinol,
we just do not measure it in the blood. Yeah, I certainly don't have that experience.
It's very interesting to learn, but again, how the, how this, how that's working is.
Yeah, right. The other thing I just mentioned along those lines, again, it deals with
diving deeper into the biology of the system. There's about 20 intermediates on the way to ubiquinol.
It's just as complicated a pathway as cholesterol synthesis.
And so we don't know whether there may be other targets in that pathway, just happens to
be the end result.
So there's lots to learn about how statins impact biology in ways that could affect health.
And it's in part because we have such a large population who is doing this experiment, basically. And it's also because of the centrality of mechanisms
that statins affect.
So it's not just cholesterol, it's pre-cursures
of steroid hormones that are in this pathway.
And it's these other pathways that can affect intermediates
like ubecranol and other phynaceol.
There's lots of other downstream products
that are affected by statins
that may have biological effects
that tell us something about what the drug is doing
in the physiological way,
but may also have pathologic consequences in some people.
What do you make of the evidence for and against the case
that, and this is not a common argument,
but it is one that shows up enough, which is,
okay, statins do reduce events, but it's not by lowering LDL. That's a, an unintended consequence,
or an intended consequence that is true, true, and unrelated, but the benefits of statins
actually come from the endothelial health and or inflammatory reduction. Right. So this is another deep topic, which is obviously clinically important to people
understand what it is they're treating and why it gets back to a couple of issues.
One is the causality of LDL, which we discussed a while ago. LDL is causal. That's established beyond doubt. So the benefits of drug induced
LDL lowering, let's say statins, have to be considered as operating in part through that
mechanism. Otherwise, let's at least can see that in part otherwise you're just ignoring
reality. So that's number one. Number two is, is that the most important factor? Is it
the only factor? The answer is it's certainly not the only factor.
There's no doubt in my mind anyway.
I'm not sure how much of this is opinion versus evidence, but well, there's certainly
anti-inflammatory effects.
And there's a lot of work that, like the friend Paul Riker has been involved with to
help establish...
Paul Riker's at NIH.
No, he's at...
He's at Brigham.
He's at Brigham, yeah.
Yeah, yeah.
Early on establishing the importance of C-reactive protein as a marker for inflammatory No, he's at the brigham. He's at the brigham. Okay. Yeah.
Early on establishing the importance of C reactive protein as a marker for inflammatory
risk, not just the part disease, but.
And we should detour on that topic because it's so important, right?
There was a recent trial that looked at low dose of methotrexate, which is an ant-
No, it was an IO.
It was an interleukin one.
Well, it weren't there, too.
There was the IO.
But the methotrexate isn't out yet.
Oh, okay. Maybe I'm just, it's the there, too. There was the I-1. And the trixate isn't out yet. Oh, okay, maybe I'm just...
It's the other one.
Okay, okay.
It'd be the other one's out.
Yeah.
It used an interleukin one.
It was a 1 or 6, yeah, yeah, yeah, yeah.
Yeah, one.
And so that was a very interesting trial.
That was a trial.
Yeah, that was okay, that's right.
So that was a trial that said, look, we can make no change to the Lypa protein.
We reduce inflammation in a subset of patients.
These patients had to have an elevated C-reactive protein, if I recall, and you reduced events. And we may see the same thing
with this methodorexate study. And I think that speaks to... Or not. Yeah. Either way, it's an
important finding. Exactly. So, you know, with the reason I asked the question, among others is...
Can you be at the statins, right? Yeah. Okay. Because then you can say, well,
what does statins do to this pathway? Well, they do lower inflammatory signaling down
this same pathway. And again, risker was a pioneer in studies such as the Jupiter trial
and earlier ones as well that were analyzed, the predicted benefit or the associated benefit
of LDL lowering against CRP lowering is from market for inflammation. So this goes back
to using CRP as a market for inflammation. And achieving a lower level of CRP at a higher
level of LDL was associated with benefit, achieving a lower level of LDL with a higher
CRP with benefits. So they both contributed to risk and so targeting both
LDL to less than 70. I think it was in CRP less than I think two milligrams for less later
I think but targeting those two risk markers together gave the greatest benefit to each contributed and I think that
Model stands up pretty well that it is a double wham, and one of the reasons stands are so effective is probably
because of their unique ability to hit inflammation as well as al-Ghambatabu, something gets back
to the PCSK9.
That's exactly where I was going to go, which is I've got a number of patients that are
coming to me saying, look, Peter, I don't care about the cost of the PCSK9 inhibitor,
get me off this stat, and I just want to be of the PCSK9 inhibitor, get me off this
statin. I just want to be on a PCSK9 inhibitor to which I say, the only issue I take with that
is, and I don't have a problem doing it in the patient who is completely statin intolerant.
Can I have a couple of these patients where they absolutely need to be unlippered lowering
therapy and they absolutely can't even tolerate, you know, live-alow. So, you know, there
we just do what we have to do.
But the trials don't actually tell us how well PCSK9 inhibitors work in isolation, right?
Relative to non-treatment. So, and then that's just sort of the evidence-based reason for,
hey, it would be ideal if we could at least keep you on some modest amount of a statin.
And then secondly, there's, it's not clear the PCS can anybody attacks that other mechanism.
It's a mechanistic aspect to this.
And it's not just inflammation down the interleukin CRP pathway.
It's also there's nitric oxide synthesis, the text nitric oxide being a basic dilator.
So I think there is a good mechanistic case as well as the clinical evidence case for
not abandoning statins in favor of PCSK
and that unless of course patients are statin and tolerant.
Where do you think the effect?
So one of the things I sort of tried to divide this is men, women, primary, secondary
prevention, right?
That's a nice two by two square.
I don't think there's any, I mean, again, I'm not talking about the blogosphere or Twitter,
but like if you actually look at evidence, is there any dispute in the efficacy of statins
in secondary prevention for men or women?
No.
No dispute.
No, there's no dispute.
So we won't even need to talk about that.
Let's talk about primary prevention.
The variability in clinical trials
when you look at primary prevention,
especially in women, but I think for men
to some extent as well.
Both in the NNT, so that means the number needed to treat,
so in, you know, the NNT of so that means the number needed to treat, so the NNT, of course, being
the reciprocal of the absolute risk reduction.
So when NNT of 100 means you have a 1% risk reduction, you need to treat 100 people to
prevent an event.
When you look at the summary data on this, it's amazing how all over the map it is.
So how would you rate the strength of the evidence? Just just a quick question,
Ron, I'll just give you 30 seconds to answer this. Now, the strength of the evidence in primary
prevention for statins in either men or women. Okay, well, let me start with women and then
me also specify that you need to think about cardiovascular events and then mortality from
cardiovascular events. Right. So we'll talk about major adverse cardiac events, so myocardial infarction, stroke versus death.
So there is evidence, again, importantly, from the Jupiter trial, which had a very large
enrollment of women, but collectively in other trials as well, for the benefit of statins
for high risk primary prevention in women. And the high-risk caveat
is really important here because it really speaks to this very fine gradation between high-risk
primary prevention and secondary prevention because if you're at a high enough risk and
haven't had a heart attack, you may be five seconds away from the heart attack.
Yeah, well, you may have had a silent MI that was missed.
Right.
So that distinction could be a little bit fuzzy, but technically at least the evidence is
there for primary prevention of cardiovascular events and women.
It's not really there, at least to my reading.
I may be wrong about this because I haven't gone back and double checked, but I haven't
seen evidence for benefit on mortality for primary prevention.
In the women women.
And in men, it's kind of weakish for mortality, but it's certainly present for events.
And is it also possible that one of the things I try to explain to if I'm giving a lecture or
something to students is you look at a paper and you see no statistical benefit.
The first question you must ask yourself
was was this study powered adequately to detect a difference?
And it's very often the case that there could have been an effect,
but we didn't, it was too small to see
with the number of subjects.
I feel like in some of the primary prevention trials,
duration might be the bigger issue.
It's if you're only looking at seven years, which is probably
the outer limits of where these trials look, it might simply be that when you're talking about a
1% absolute risk reduction over seven years, it's not really that interesting. Of course, a 1%
risk reduction over seven years over 30 years is an enormous difference.
Alan Snyderman is actually working on a paper now that looks at 30-year risk, because
of course all the risk calculators are based on 10-year risk, which I think has value,
but also has great limitation.
And I guess I think that's part of what I struggle with this clinically, which is, we never
want to expose a patient to something unnecessarily.
And there's no substance you're going to put in your body, whether it's, you know, vitamin
C versus a stat, and that comes with zero risk.
So how do you weigh that benefit?
Yeah.
Well, you know, this really speaks to need for much better markers that could help us
predict benefit versus adverse effects, so that we can identify not just the high risk
candidate for statins based on conventional markers, but individuals in whom we have evidence for
mechanisms that would be benefited by stat and treatment that would argue strongly for benefit.
And on the other side markers, ideally, that could assess risk for
adverse effects, not just symptoms, but underlying pathology, for example. And again, without,
because I want to come back briefly to your question about kind of the function, because
I sort of escaped talking about that, because I feel this is because you forgot, because
you're cognitive function. No, it's an effect.
But the opposite. Quite the opposite. I've put it in a part of my brain that has made
me not forget that there can be effects that are long term that we simply can't assess
easily. And so one of them could be kind of a function. But having said that there's
no evidence in our consensus paper that just came out and sat in intolerance.
No evidence really.
Well, at the population level, I would say it's the opposite.
At the population level, I think we see that the risk
if anything goes down a little bit.
Yeah, and there's a cardiovascular.
There's a vascular.
That's exactly right.
It's a vascular element that even contributes
to classical Alzheimer's disease.
But again, the data are really not compelling.
They're not compelling.
No, this is the challenge. This is personalized medicine means at the end,
I don't care about the population. I care about the one person sitting in front of me
at this moment when we have to make a decision.
Exactly. Exactly. But what's intriguing and what you've,
what's your question opened up and F be careful because I don't want to go down
the rabbit hole on this one, To the extent that statins influence mechanisms
that interact with cholesterol transport in the brain,
an apopotene e, which we mentioned
is a variant that causes types of rehab,
but in the apopotene e is a key protein
that has a variant, another variant
that increases the risk for Alzheimer's disease.
We're looking at ways that cholesterol and metabolism intersects
with that pathway.
And inconceivably, that's just one example of a gene
that could interact with statins.
And if the statins are getting past the blood brain barrier,
in some cases, an inflammation might be a factor
that could predispose to that.
You could start to have imagined effects
that could go either way,
but could perhaps potentiate this function. That's just a completely off the, you know, out of
the... No, no, look, I mean, that's exactly, I mean, that's sort of the hand waving that I use,
right? So when I have patients that have one or two copies of an ApoE4 gene, I am that much more
careful with them with statin use and until proven otherwise.
Yeah, and we don't know and we don't know. I mean, I actually there's a wonderful group of
APOE4 carriers that has formed a sort of a support very large that I've interacted with.
They came to my lab. There's about 30 members of this group that came. And I gave a talk about apopotene, E, and nutrition, actually.
I had to sort of be careful because these people
were just anxious for advice.
What do we do?
We've got this apoe for variant.
What do I do with my diet?
And I told them, you know, we've done a lot of studies
along these nights, but we don't know what the effect
then disease and disease risk is.
But there's one other cumulative effect that I'm going to mention without, again,
turning the tables on the value of statins.
And that is getting back to the muscle effect because if there is a,
the adverse effect on mitochondrial function, which we can,
we can show that, another is showing that.
And if they're individuals who, for one reason or another,
are at risk for muscle wasting,
it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it's called, it time, and this is just, I'm telling this out at the, probably near
the end of this discussion as a kind of, just a thought, is it may argue for, after a certain
age, not worrying so much about high dose statin treatment, unless the patient is at really
high risk.
And because, when it may be adding, in elderly individuals and exposure.
Yeah, you're creating a new risk in the presence of another risk reduction.
Right, and it's the experiment that we probably are never going to be able to do.
And so it just has to sort of be cognizant.
I've had patients, and again, I actually take care of a number of physicians, actually,
my clinical work, who asked me, you know,, I've reached age 75 or 80, and you
have done well, if you know, had family history, I'm going to be fine now. And it's a difficult
question to answer because we don't have the evidence base behind age 75. That was really
where the cholesterol guidelines that came out a few years ago stop because that's where the
evidence stopped. We do have benefit in older individuals who are at higher risk, but we don't know
what the trade office in terms of adverse effects that people that don't really need to be taking
it any longer.
Now you were involved in one of the ATP guidelines, correct?
Yeah, well, I was on the ATP for, on the last panel that handed it off to the American
Heart Association, American College of Cardiology.
I was connected with it when it was part of the NIH guidelines.
Now you took issue with something, didn't you?
Well, there were some concerns that I and others had regarding the scope of the effort
originally, and this is my personal experience with it, when I was brought on, I was expecting,
and we originally talked about having a wide range of topics to discuss, not just LDL
lowering, but how we managed triglycerides, the role of HDL, emerging risk factors,
L-Pyla-Lay, we had probably 15 or 16 high priority
questions. And I was intending to be involved heavily on the
discussion of some of these other risk factors. I thought the
LDL story was obviously important. And it had to address, should we update
the guidelines, that's what it was really designed to be.
And to turn out in the end, that because of various changes in support of the whole
program, the number of questions was reduced down to just three and they all had to do with
LDL lowering and the evidence for it. And it was very heavily dependent on trials that were
available to provide evidence-based conclusions. So that means that the effort was really limited
to a very strict interpretation of evidence-based guidelines. And that led to an abandoning of the LDL targeting that we had, the LDL levels that have been used
to guide management of risk were abandoned because there was no study that actually addressed
specifically that question that is does reaching a certain target reduced risk.
And I personally got rather discouraged at the limitation that we were under.
Eventually, it's sort of got a little bit softened actually after I left the committee. rather discouraged at the limitation that we were under.
Eventually, it's sort of got a little bit softened,
actually, after I left the committee.
I think there was a little bit more tolerance
of potential role, but basically by being that narrow,
we not only lost a lot of important questions
and lipid management, just more in the rest,
triglyceride, et cetera, et cetera.
Metabolic syndrome wasn't really touched on at all.
So it was disappointing to me.
And I felt my LP a little bit.
I felt my LP a little bit.
And so I felt my role in the LDL lowering side was sort of limited.
I'd actually been involved with being consultant to companies that may love the LDL lowering
drugs.
So I had to actually, excuse myself, from even the decision process.
So it was a really point where I just wasn't able to contribute the way I thought I could.
So I decided to step off.
I could continue this discussion probably for six more hours.
But there is one other thing I want to go back to that we did talk about.
And I think it's the nice and question.
I know you're forgotten. No, I sure have not.
So what does nice and do, right?
So first of all, I don't think anybody actually really understands the mechanism by which
nice and lowers a bobe.
Do I mean, is that generally? Yeah. That's right. I would say that's a fear of statement. But Niasin is a drug that
lowers LDL, particle cholesterol. It also raises HDL cholesterol quite significantly. In fact,
I've seen it raise HDL cholesterol more than I've seen anything in those CTEP inhibitors.
So it seems like the dream drug. It's doing everything right. Now it does also
create some insulin resistance and it seems to do that at a higher level than even statins do. But
do you think that that's the explanation for why the hard outcome data aren't there and why
Niesin has fallen so far out of favor that you know actually called in Niesin for a patient about
a year ago. It was we're kind of doing an experiment. He couldn't tolerate a stat and couldn't afford a PCSK9 inhibitor. We were really reaching for straws and we couldn't
even get niacin form. I mean, we literally couldn't even get his insurance company to pay for niacin.
So it is person-in-on-grata. Help me understand that.
Okay, so my disclosure is I still use a lot of niacin. So why do I do that?
In the light of these trials. So let me just back up then
and say that the trials, the high profile trials that led to the dismissal of niacin as a therapeutic
option. One was, it came high and the other was, it wasn't, it wasn't, it was, it was, it was,
it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was,
it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, it was, to both involved the following criterion. And that is, niacin was tested as an HDL raising agent
in the setting of LDL being at a low level
as a result of intensive statin plus or minus
sedia to bring LDL cholesterol levels to a low enough level
that it would be considered a non-factor.
That is that the niacin effect due to LDL would be minimized.
Whereas the HDL,
how do we assess the level of niacin exclusively on its HDL raising properties
because we've maximized LDL lower?
That's right. So they were designed to test whether the HDL increase
with niacin is beneficial.
And the answer is, from those trials, I'd say unequivocally
no. That is, the HDL raising effect of niacin is not protective. That's the conclusion to
take away. That, in my view, was beating, maybe not a dead horse, but a pretty sick one,
because I never really was totally convinced that raising HDL itself would be beneficial.
Even though I was part of the really a study that showed
that if you genetically treat mice with a gene
that raises HDL, you can reduce the arthroscrosis.
I mean, there is a protective effect,
but I was of the opinion that the association
of HDL cholesterol across the population with risk fell
into the same category as the LDL, small LDL story, and the triglycerides, so it's part
of a interrelated metabolic syndrome. And I felt that the most important pathologic features
of that syndrome were not low HDL, but the high levels of small LDL and triglycerides.
And both of those components have been not just the LDL, but the trig levels of small LDL and in triglycerides. And both of those components have been,
not just the LDL, but the triglyceride related risk have been pretty clearly shown to be
causal. And the HDL was a marker for that. That was actually my guess just based on my behavior.
And there could be another issue here, right? Which is to raise, I mean, there are known HDL-like progenymias where very high HDL is actually
afterogenic because they're so dysfunctional, they can't actually dilipidate.
Exactly.
So the simple-minded idea that raising HDL by any means would be beneficial, just like
lowering LDL by any means would be beneficial, was disproven by those studies.
Plus all of the CTEP inhibitors. That's all of the C-TEP inhibitors.
That's right, none of the C-TEP inhibitors.
There's something fundamentally pathologic
about that effect on HDL
that overrides any potential benefit
that maybe do to other factors.
In the case of the two major niacin trials,
there was some lowering of LDL,
but as you point out the HDL increase
was fairly substantial. And those particles are basically hung up in plasma. It gets back
a little bit to this resonance time issue that I was talking about regarding LDL. Well,
here's the situation for HDL, but these particles are just sort of like the toilet is plugged.
Yeah. You prevent them from doing their job. Right.
So you're not delivering cholesterol efficiently back to the liver for excretion, and those
particles are hanging around long enough that who knows what properties they may be
acquiring that might possibly override some of the benefits of the LDL-oring effect.
So does that mean that Nyson has no benefit?
Well, there was a study that preceded those two studies that was carried out by Greg Boundon
actually was one that led to the A&P which I realized now is the one I was forgetting
the way.
Oh, that's for the LRC.
Okay.
That was a multifactor response, yeah, yeah.
Going back to hats.
Right.
So hats was a statin plus niacin, and there was other combination of approach, which included
niacin.
And that study showed benefit to levels.
One was the intended and point was quantitative angiographic progression,
measuring the narrowing of the coordinate vessels,
which is now not used.
We now realize that's not particularly helpful.
It happened to be correlated with that endpoint.
And in fact, in that study,
even though it was initially underpowered
to detect the benefit on endpoints,
it did, that intervention did reduce risk of events.
It was a successful trial.
We analyzed data from
that study using four different methods to look at live reporting particles. So part of this
was to see whether we could learn something more than what's in the standard lipid measurements
would tell us. And what it did tell us is that the small and very small LDL lowering
cheap by NISON, which it does do was associated with vascular benefit in that study.
Whereas the HDL, to the extent of nothing else was explanatory, and that was independent
of all the standard lipids.
So we have this in the literature from just one study, and I wish we would have access
to other types of data that could support this.
But it spoke to a therapeutic effective Niasin that would be lost in these larger trials
because the statin hammer had lowered the LDL low enough
so that additional benefit is probably just lost in the noise.
It's too small, it's underpowered.
It's lost in the noise.
So the failure of those trials speaks to the success of statins
and the failure of HDL raising.
Those are the two things that take away.
But Niasin, I think in the patients,
I'm just, we have small LDL particles.
I still use it and I like to see that.
Well, that's what I want to ask you.
Let's talk me through the perfect Niasin patient.
Well, the perfect patient with Niasin is actually twofold.
And we weren't going to talk about LPA,
but you did bring it up earlier in our mission.
And so it's this genetic factor that is sort of the wild card twofold and we weren't going to talk about LPA, but you did bring it up earlier and I'm saying.
So it's a genetic factor that is sort of the wild card in ethosgroicis.
It's certainly damaging.
And we'd like to lower it.
So Nias and can lower LPA the lay by up to 25% or so.
And there is not conclusive, but to me, clinically impressive evidence that if you have a combination of high
LPA and small LDL, you're just a time bomb for catheterous growth.
So if you have high levels of, you know, high particle number of the small LDL type plus
LPA, LL, elevations, and there's always always a strong family history of heart disease
and the patients are going to be at high risk at a young age because nice on lower cell P.A. and because nice and
lower the small, the old particles.
So nice.
And then you think specifically targets smaller particles over larger particles.
Yeah.
Preferentially.
Sorry.
Yeah.
Yeah.
The lower is that pathway.
It's not clear whether or not that's the VLDL pathway or not.
Honestly, we don't know.
It gets back to your earlier statement that we don't know the mechanism. Yeah. or not. Honestly, we don't know, it gets back to your earlier statement
that we don't know the mechanism really as well.
We just don't know the mechanism.
But in that combination, that really is the patient
that, and I've got patients like that who have.
And you put that patient on that over a PCS-K9 inhibitor
if they could afford it?
Well, there's another.
Because you're going to get a 30% reduction
on LPLL at least through the PCS-K9.
That's right.
There's another, that's right, that's another angle.
This PCS canine has a similar new to LP
alluring effect plus it has a gangbusters bigger effect
than no the O particle, OLEO levels.
So no, I wouldn't use it over PCS canine.
The argument there is largely financial.
Yes, and what insurance recovery you can buy nice
in that the local shop off the shelf, long know, a long-correcting NIS and a safe, both of the safe form, for pennies.
You know, you're going to pay an air-nighter, $14,000 for a PCSK-9.
I've had patients like you who have been willing to do that, who have been willing to sort of-
Just pay out a pocket, that's right.
And that is the same category of patient and I probably would consider that even more effective.
Although one other thing, a little tweak here.
And that is that both statins and PCS can inhibitors
because they work, as you said,
by up-regulating LDL receptors, as in the case of PCS can
end, that's the mechanism.
Exclusively.
Right.
For it stands, it's the part of the mechanism.
That effect primarily lowers medium and larger size of BCS can end, that's the mechanism. Exclusively, yeah. It stands at the part of the mechanism.
That effect primarily lowers medium and larger size LDL particles and has a less therapeutic
effect than smaller particles and none on the very small LDL.
So there's a gradation of effect, which relates to the structure of the LDL, being more or
less capable of interacting with LDL receptors and the larger particles
interact well. And so, regulating LDL research.
And this explains why we sometimes see a widening of the discordance in the statinized patient
because they're lowering LDL, see more than LDL P because you're selecting out the larger
more cholesterol density.
And so that applies to any mechanism that operates the LDL receptors, which is what most of I'll see more than LDLP because you're selecting out the larger, more cholesterol dense. That's right.
That applies to any mechanism that operates the LDL receptors, which is what most of the
drugs do, even as that of my...
What does that mean for NISON?
NISON lowers the small and very small LDL very nicely.
There's a complementarity there to statins.
I think that's part of what attracts me to using it.
Again, I don't use nowadays because of potency of the statin's ability to get LDL down
to target and such.
I have proportionate patients, the availability of PCSK9.
I'd have to say, there's fewer patients that I'm starting on, nice, but there's still
candidates out there that I think would benefit from this, this hitting small LDL, hitting
LPLLA in ways that complement the benefits of stents.
The only patient I've put on nice in the last four years is a really interesting case.
He's a guy with, he doesn't have FH, but he's clearly got some snips of FH because his
LDL is incredibly high, but normal synthesis, normal triglycerides, and normal absorption markers.
So, you know, his steriles are normal.
This is a clearance problem.
Unable to tolerate a single statin, including one milligram of live-alow.
So we went to RepaFa, and there is no effect.
And we switched to Prolulant, no effect. That's really interesting. So he's missing this anepotope that's
just I would I would like the DNA from that patient because I would be happy to introduce
you to a can't genetic variant that might explain that actually. Okay. Yeah. So you use
niacin. Yeah. I mean, it's it's like basically going to be what niacin and aphoresis. I mean,
it's this a really tough case. Yeah. Well, again, I mean, you know, I think it's it's like basically going to be what? NIS and a foresis. I mean, it's a really tough case.
Yeah, well, again, I mean, I think it's legitimate to say
that there's probably less, if you were at Candaceous NIS
and with the availability of this potential
for using PCSK9, and certainly with,
and commission with stands.
But I would say the patients with moderately elevated
triglycerides and the 150 to,
you get a little fennified, right?
Yes, I do, actually, despite that's another subset question.
That is a subset of patients who may benefit based on subset analysis, subgroup analysis
of the clinical trials.
But unfortunately, it's just not a very potent patient.
But niacin, I will use as an alternative approach to lowering the triglycerides and
lowering the small LDL.
That's elegant. That's something. I mean, if just on a personal level, that's certainly an amazing
and insightful pearl that I've gathered from our discussion today.
I appreciate you seeing that.
Well, and with that, Ron, I want to say, first of all, I consider you a great friend and an
unbelievable mentor. I feel so fortunate to have benefited
from your knowledge and peers of yours over the last decade. And your generosity is unparalleled
in terms of any time I can pick up a phone and call you and run a tough case by you. You're
always there to do so. So I greatly appreciate that. I also think we need to do this again
sometime because I literally have twice as many questions as we've got to. I also think we need to do this again sometime because I literally have
twice as many questions as we've got to. I wanted to get into saturated fat, fructose,
apoe. There's all these other things that I know you are just an expert on that I know people
are going to want to hear about. So I'm going to have to come back to San Francisco and we'll have
to continue this discussion hopefully during the Warriors off off season. Happy to do that, Peter, and thank you
for your kind words, and it's been a pleasure
talking with you.
I think the opportunity to help people understand
some of these complex issues is something
you've been very good at, and I'd be able
to compete with you through that.
Thank you so much, Mark.
Okay.
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