The Peter Attia Drive - #381 ‒ Alzheimer's disease in women: how hormonal transitions impact the female brain, the role of HRT, genetics, and lifestyle on risk, and emerging diagnostics and therapies | Lisa Mosconi, Ph.D.
Episode Date: January 26, 2026View the Show Notes Page for This Episode Become a Member to Receive Exclusive Content Sign Up to Receive Peter's Weekly Newsletter Lisa Mosconi is a world-renowned neuroscientist and the director ...of the Women's Brain Initiative at Weill Cornell Medicine, where she studies how sex differences and hormonal transitions influence brain aging and Alzheimer's disease risk. In this episode, Lisa explores why Alzheimer's disease disproportionately affects women and why longer lifespan alone does not explain their nearly twofold risk compared to men. She explains why Alzheimer's disease may be best understood as a midlife disease for women, beginning decades before symptoms appear, and how menopause represents a fundamental brain event that reshapes brain energy use, structure, and immune signaling. The conversation also examines what advanced brain imaging reveals about preclinical Alzheimer's disease, estrogen receptors in the brain, and why genetic risks such as APOE4 appear to affect women differently from men. Finally, Lisa discusses the nuanced evidence around menopause hormone therapy, the legacy of the WHI, her new CARE Initiative to cut women's Alzheimer's risk in half by 2050, and practical, evidence-based strategies to support brain health through midlife—including lifestyle, sleep, metabolism, mood, and emerging therapies such as GLP-1 agonists and SERMs (selective estrogen receptor modulators). We discuss: How Lisa's personal family history and scientific background led her to focus on the intersection of women's health, brain aging, and Alzheimer's disease (AD) [2:45]; The long preclinical phase of AD and the emotional burden carried by patients before dementia becomes severe [7:15]; How AD compares to other common forms of dementia: prevalence, pathology, symptoms, diagnostic challenges, and more [10:45]; Why AD disproportionately affects women: how AD is not simply a disease of old age or longevity but a midlife disease in which women develop pathology earlier [16:15]; Menopause as a leading explanation for women's increased Alzheimer's risk, and how advanced braining imaging can detect early changes in the brain [26:15]; How a new method for imaging estrogen receptors in the brain is changing how we think about the menopause transition [35:45]; What estrogen receptor imaging can and cannot tell us about hormone therapy's potential impact on brain health [48:45]; Lisa's studies on the relationship between levels of systemic estrogen and density of estrogen receptors in the brain [58:00]; Why blood estrogen levels poorly reflect brain estrogen signaling, and how tightly regulated brain hormone dynamics complicate our understanding of menstrual-cycle and lifestyle effects [1:02:15]; The CARE Initiative: Lisa's research program looking to slash AD rates in women [1:07:45]; The dramatic difference in AD risk between men and women associated with APOE4 [1:10:45]; What the evidence suggests about menopausal hormone therapy (MHT) and AD risk, and why timing, formulation, and uterine status appear to matter [1:12:00]; How the CARE initiative plans to study MHT and AD risk, within the practical constraints of a three-year research window [1:17:30]; How to think about starting hormone therapy during perimenopause: balancing symptom relief, hormonal variability, and individualized care [1:21:00]; Investigating selective estrogen receptor modulators (SERMs) as a targeted approach to brain health during and after menopause [1:25:00]; Why estrogen became wrongly associated with cancer risk and what the evidence actually shows [1:29:30]; Why better biomarkers are central to advancing women's Alzheimer's research [1:38:30]; Modifiable risk factors for dementia, the limitations of risk models, and questionable conclusions drawn from observational data [1:44:15]; GLP-1 agonists and brain health: exploring potential neuroprotective effects of GLP-1 agonists beyond metabolic benefits [1:49:00]; The importance of lifestyle factors in reducing risk of dementia: practical strategies for women to support brain health [1:53:45]; Why long-term, consistent lifestyle habits are essential for building cognitive resilience and protecting brain health over decades [2:01:15]; and More. Connect With Peter on Twitter, Instagram, Facebook and YouTube
Transcript
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Hey everyone, welcome to the Drive podcast.
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I guess this week is Lisa Mosconi.
Lisa is a neuroscientist, neuroimager, and the direct-examination.
of the Women's Brain Initiative at Weil-Cornell Medicine, where she leads research on how sex
differences, especially menopause and hormonal transitions, shape brain aging and Alzheimer's risk.
She's also a professor of neuroscience and a pioneer in brain imaging approaches that map
Alzheimer's disease decades before symptoms appear. In this episode, we talk about why Alzheimer's
disproportionately affects women and why women's increased lifespan over men does not fully explain
that 2x difference. Talk about the idea that Alzheimer's disease is actually a midlife disease for women
beginning long before symptoms, and how menopause is fundamentally a brain event and what happens
to brain energy, structure, and immune signaling during that transition. We talk about what advanced
imaging reveals about preclinical Alzheimer's disease. We talk about Lisa's work in imaging estrogen
brain receptors. We talk about APOE4, specifically other genetic risks and why they impact.
women seemingly more than men. Some of the nuanced evidence around menopausal hormonal therapy,
risks, benefits, timing, formulations, and why the WHA caused decades of confusion. Talk about Lisa's
new initiative called the CARE Initiative, a global effort to cut women's Alzheimer's risk in half by 2050,
along with some practical evidence-based strategies for supporting brain health throughout midlife
transitions, including lifestyle, sleep, metabolism, mood, and the involving role of medications,
including GLP-1 agonists and SERMs.
So without further delay,
please enjoy my conversation with Lisa Moscone.
Lisa, thank you so much for coming out to spend time with me today.
Thank you for having me.
This is actually a wonderful podcast because it combines two topics
that we have spent a lot of time on in this podcast.
It's two topics that we spend a lot of time on in our clients.
clinical practice, but it is probably, at least to my recollection, the first time I've brought
them into an intersection here. So one of them is all things that pertain to women's health,
in particular, the transition through pre-perry and post-menopause. Again, this is a topic
we care deeply about and have very strong points of view on. And then the other, of course,
is brain health, which I don't think there's a single person listening to this podcast who doesn't
appreciate both the role of the dementing diseases in how they truncate lifespan.
but perhaps much more importantly, how they truncate health span.
And the reason I wanted to talk with you today was because you sit at the intersection of
these two, which is you're asking the questions as they pertain specifically to women and brain
health.
So I just want to maybe start with a bit of your background.
So tell me how you came to find this as your focus.
It's quite personal for me.
So I was born and raised in Florence in Italy.
Which, by the way, I just want to say literally one of the great.
greatest places on this planet. It's really pretty. I never appreciated how pretty Florence is until I
moved. I'm quite proud. Whenever I go back, it's like, oh, this is really nice. As you may know, as people
may know, in Italy, families really live together. So I was born and raised in Florence. My parents live in
Florence. My grandparents were in Florence. And my parents are nuclear physicists, both of them. I come from an
interesting family where half of the family has a PhD, usually in physics, the other half is in the
army. So we're very disciplined scientists, some of us. And I grew up in this environment where
everything was about physics and biology and studying and learning. And I decided to apply that
knowledge to medicine. So I have a PhD in neuroscience and nuclear medicine, which is a branch of
radiology, I do a lot of brain scans. Around the time that I started studying neuroscience
and specifically memory and language, but I was very interested in memory, functionality and
cognition. My grandmother, who lived on the same landing as me and my parents, she started showing
signs of cognitive decline. My grandmother was the rock of the family. She was this really
strong, extremely intelligent woman who went through World War II when she raised a family.
My grandfather was a prisoner of war being in the army for a long time and nothing broke her
spirit until she started losing her memory, until she started losing the ability to communicate,
until she started losing the ability of taking care of us, where she could not remember how to cook.
And that really broke my grandmother and broke us and led to a diagnosis of Alzheimer's disease over time.
And what was even scarier is that my grandmother was one of four siblings, three sisters and one brother.
All three sisters developed Alzheimer's disease and passed away from it, whereas the brother did not and was spared, even though they all lived to the same age.
Which was what age?
My grandmother passed when she was in her late 80s.
And how long did she suffer with the disease?
When did it start?
At least a decade.
It was very subtle.
Very often Alzheimer's disease starts in a gradual way.
First, there's some mild cognitive impairment, which she was able to almost masquerade.
She had strategies to find the answer, keep going about today, without really telling us that she was having a hard time.
but then it became quite evident and in the end it was very severe because she was healthy
otherwise.
So her body was healthy but her mind was not.
So all three sisters basically succumbed to this in their late 80s, having the onset
in their late 70s, which again, I bring that up only to say this is a very typical
trajectory.
It's very typical.
Unfortunately, it is quite typical.
This might be a question beyond your research because I know you're not a clinician.
But given that you had such a personal experience, one of the things people often ask me is,
at what point do patients become aware of what's happening, such that it creates enormous distress for them,
versus when is the cognitive impairment so severe that they are no longer suffering?
And it's only those of us around them who are suffering.
But we could potentially take some solace in the fact that they are no longer suffering.
Do you have a sense of that from your experience?
Yes, there's research in these showing that we're now able,
now that we're getting better at diagnosing Alzheimer's disease,
not just using clinical tools, but using biological markers,
like brain imaging and biological fluids in blood.
Now, we can tell when a person is at risk for Alzheimer's
or is showing red flags for Alzheimer's fairly early on
and then is possible to correlate that with what the patient is,
telling you. Because the tests, the cognitive tests that we've been basing the Alzheimer's diagnosis
on for decades are quite...
Quite late. They're a little bit late. They're not quite sensitive to the earliest possible
manifestations of the disease, which are usually subjective. So what we're learning now
is that there's a phase, that is a pre-clinical phase, where the disease is underway.
You can see the proteins and the lesions, either in the brain or in bio-eurole.
biological fluids, but objectively, there is no impairment, there is no deficit at that point
on cognitive testing. Many patients would tell you that they don't feel the same. There's this idea
that they are aware that something is changing, that their performance is not the same, that they're
not performing as well as they used to, even just a few years prior. And it's very hard to say,
is it just aging or is it something more severe?
And now we're getting better at doing that,
but it looks like the pre-clinical phase of Alzheimer's disease
can last decades,
where the disease is underway,
it starts with negative changes in the brain
that very slowly but surely eventually exceed the brain's ability to compensate.
But it takes a long time.
The brain is an extremely resilient organ.
And unfortunately, many patients,
are in this gray area, if you will, where they know that something is amiss.
But when they come for a neurological evaluation, everything is fine.
When they go to see a neuropsychologist, they test with the normative value by age and education.
So it's really hard to provide counsel and to offer a treatment plan if we are not able
to diagnose the fact that they are, in fact, on the path towards Alzheimer's disease.
that could last decades. It could last a really, really long time until the deficits are such
that there is an objective diagnosis. And usually patients do experience discomfort and depression
and anxiety for years until dementia is severe enough. Did they start forgetting who they are?
Or they start forgetting that they have a family, perhaps, or they start forgetting why they are
where they are. So unfortunately, it's a heartbreaking disorder. Lisa, how much of what you just described
through the lens of Alzheimer's disease specifically is comparable in other forms of dementia,
such as Louisbody dementia or frontotemporal dementia or vascular dementia? I mean, maybe just for the
audience, we can put these all in context. Alzheimer's disease is the most common form of dementia,
but it is far from the only cause of dementia. So do you want to
maybe put it in the context of these others, both in terms of maybe some of the prevalence of
these, but also any of the subtle differences in what you just said as far as onset and
presentation? Yes. So dementia is an umbrella term that includes different disorders that are
typically categorized in terms of pathology, which is the kind of lesion that every disorder expresses
most abundantly, and also in terms of clinical symptoms and sometimes age of onset. Now, most people
are familiar with Alzheimer's disease, and they usually think that Alzheimer's and dementia may be
the same thing. It's a common misconception. Alzheimer's is the most common form of dementia,
accounting for about 70% of all dementia cases. There are other types of dementia now. We hear
more and more about frontotemporal dementia, for instance, because Bruce Willis, unfortunately,
has been diagnosed with that. In that case, the presentation is a little bit different. When we do
brain scans, actually, we can tell whether a patient has frontotemporal dementia or Alzheimer's
disease based on the pattern of changes in the brain. Frontotemporal dementia tends to occur a
little bit earlier in life and predominantly as associated with aphasia, which is disturbed
language production. Whereas Alzheimer's, it's more about memory function, is more about
forgetting things. However, at the end of the day, once the dementia, the different types of
dementia are quite severe, there is a lot of overlap in terms of symptoms, the may occur.
The pathology, the pathophysiology is different, but the symptoms at the end tend to overlap,
so it's quite difficult to do a good differential diagnosis. Louie body dementia is another
form of dementia that is due to mutation in the alpha-cineucline protein, so it's a little bit different
from Alzheimer's, where the main problem is an amyloid beta, is fibular amyloid beta production
and lesions that aggregate into plaques, and also neurofibrillated tangles inside neurons.
So each one in this dementia has a slightly different biological substrate.
Vascular dementia is also very common and tends to overlap with the other types of
dementia. In fact, very often we talk about mixed dementia. It's quite rare for a
patient to only have Alzheimer's, for instance, and not some vascular damage, is rare for a patient
to have only Alzheimer's disease and not also some features of Louis-Body dementia.
And for many, many years, the diagnosis was purely clinical, and was a little bit late.
You needed to have very clear-cut symptoms in order to be diagnosed as Alzheimer's or Louis-Body
or front-temporal dementia. Now that we have access to, by, you know, we have access to, by, you
biological markers, we're getting better and better, and the diagnosis has been done earlier
and earlier.
So that is hopefully leading to better therapeutic routes for each type of dementia and
development of pharmaceuticals that are able to.
Right now, we're trying to reverse the damage that, at least in Alzheimer's, makes results.
I think optimistically, we might say we're trying to halt progress.
Yes, we're trying to move away.
from trying to reverse the dementia or very severe lesions.
We're trying to move back in time.
We're trying to catch people when they're still relatively healthy
and the potential for delaying the onset of the symptoms,
or even preventing.
Hopefully the accumulation of the lesions in the brain is greatest,
is feasible.
So we're trying to work with people who are fairly young.
And that is very new in the field of Alzheimer's.
For even when I moved to New York, I was ready looking at Alzheimer's prevention, what could be done that was 20 years ago.
And I was working at NYU, New York University at the School of Medicine, with my mentor back then, Dr. Moni DiLeon, who's really a pioneer in the field of Alzheimer's prevention.
And his team was one of the very few teens in the world to work with individuals who were younger than 65.
because everybody else was looking at those who were 65 and older.
He was like, no, we need to start earlier than that.
The point you make about the overlap is really interesting.
It means that if you look at the prevalence of each type, it will not total 100%.
So you said 70% of dementia will have an Alzheimer's component.
What are the approximate numbers of frontotemporal, louis body, and vascular in terms of just aggregate presence?
It's interesting. I think it's difficult to really come up with specific numbers, especially for vascular dementia, because it's always kind of intermixed.
The body is usually around maybe 10, 20 percent, frontotemporal, but it lasts the same. But it depends. I don't know that we can really say.
We're going to talk a lot about Alzheimer's disease today, and we know that Alzheimer's disease occurs disproportionately in women. It's about two to one. Do any of the other forms of dementia disproportionately occur in women?
No. And that's actually something that was very interesting to us when we started looking at the association between female sex and Alzheimer's disease. Because when I started looking into this, this was a while ago, I would ask the question, is it just my family or is there a bigger lesson that we need to learn? And the answer was that we've known since the 1990s that after aging, after getting older itself, being a woman, is this?
strongest risk factor for developing Alzheimer's. But when I asked, can we do something about it,
the answer was mostly, well, the point is longevity, it's just aging. The idea is that women live
longer than men, and Alzheimer's is a disease of all day. So at the end of the day, unfortunately,
more women than men have Alzheimer's disease. But there are two things that contradict in part
this statement. And clearly, aging is important.
Yeah, the first one, by the way, is just a simple actuarial analysis. I did this myself 10 years ago back of the envelope because that was the first guess. The first time I thought about that question was maybe in 2015. And the obvious answer was, well, women on average live two and a half to three years longer. That must account for it. But if you actually go through even something as rudimentary as the CDC mortality tables and slice them by five-year increments, you can't explain the increased prevalence by a factor of two.
to one on that delta in age. But I'm sure you have a much more elegant explanation for why
this was not the case.
One thing that came to mind, obviously, was that the difference in the longevity gap
was not 10 years. It wasn't that wide. It was just a few years. And for instance,
in England, the gap is about two years, but Alzheimer's disease and dementia. The whole
category is the number one cause of death for women and not for men. But then the other
point is that if it was just aging, then women are
would have a higher prevalence of other age-related disorders and neurodegenerative disorders
relative to men, only they do not.
Right. Cancer and cardiovascular disease are also age-related.
But even within the dementias, right, for vascular dementias 50-50, Parkinson's disease
with dementia is more prevalent in men.
Yes. Frontotemporal dementia seems to be more prevalent in men.
A lewibody dementia is above 50-50.
So that just doesn't seem to be a good way or good reason to dismiss an important question.
Is it safe to say the scientific community today has stopped with that sort of excuse?
And we've now fully accepted the fact that there is something biologically different about women that is leading to this enormous mismatch?
I wish we could say they would have passed it.
Really?
Yes.
Yes.
It's still a subject of very active debate.
in my field.
Sorry, just to make sure I understand, we're debating why it's happening or we're debating
that age is the reason that it's happening.
We're debating that still.
Yes, we're still thinking that survival and longevity is something that may be driving
the higher prevalence.
And the argument for this is actually not a bad argument.
They say, prevalence is something that you look at cross-sectionally.
Yes.
But what about the incidents?
When does it come on?
Yes.
And the question is, if prevalence is higher but incidence is not, then it could be aging.
It could be age. That's right.
So the question is, do women develop Alzheimer's a higher rates than men?
And I'll just explain to the listener what that means. You and I obviously understand it.
Incidents is the number of cases that occur over a given period of time. So you might say the
incidence of this cancer is this many cases per 100,000 people per year. Prevalence, as you
stated, is the cross-sectional cumulative number of people at any point in time that have the
given condition? And so to your point, if the incidence is identical at every section in time,
but the prevalence keeps getting larger as time goes on, then you might have to ask the
question, are fewer women dying of the disease and therefore accumulating cases?
Yeah. And I think it's been very difficult to get a good estimate of incidents with,
the studies that we have because the diagnosis of Alzheimer's disease has changed over time
and we're catching more people now even earlier than we did in the past. So there are more and
more studies showing that the incidence is also higher among women, especially in countries
with low to middle socioeconomic status. Another way to think about this mathematically would be
because, as you said, incidents is very complicated because the diagnosis is so
complicated, it might be easier to look at mortality and tally up the mortality differences. Because if you
really think that you would reverse test this hypothesis, if you think incidence is too high,
you should see men dying at a much higher rate at a comparable stage of disease to women.
In other words, the women should be outliving the men with Alzheimer's disease if they're all getting
it at the same rate, which I don't think is the case, of course, but that would be a way to
test that hypothesis in the negative. Yes, that could be. In fact, in some countries, Alzheimer's
disease is actually the number one cause of death for women over 65. That's staggering.
Whereas her disease, yes. What countries? European countries and those in some parts of the United
States. So the data is just coming out because many scientists are in a way puzzled that longevity
has been the only explanation for the disparity. And we're not looking at risk in way.
that I think are doing more justice to the question that we could do before, especially by
looking at biological markers, because we can see that, and this is a lot of my research,
when we do brain imaging or we look at other biofluids in midlife, and we compare, let's say
that we have a population of men and women, or like 45 to 65, and all these participants,
all these people have a family history of Alzheimer's or perhaps the APOE4.
for genotypes. So they are technically at higher risk for Alzheimer's than the average person
than people who do not have these risk factors. If you look at the brain scans of men and
women, at least in my work, but it's been replicated many other scientists and other teams,
the women tend to show more red flags for Alzheimer's disease in midlife as compared to men
at the same age. And this is quite consistent. And we've also seen the progression of the
lesions in their brain tend to be faster in women. So then when you compare men and women who have
the same symptoms and the same level of dementia severity, the women's brains actually harbor more
pathology. So what seems to happen is that we start developing the lesions of Alzheimer's,
the pathology in the brain earlier on than men starting in midlife. And we live longer with it,
but we're able to compensate more in that the tests that we use to diagnose Alzheimer's
are heavily reliant on things like verbal memory, which women have a little bit of an advantage
in.
And so it's more difficult to diagnose Alzheimer's in women early.
Because they have a higher cognitive reserve in the metric you're using to test.
Yes.
So in a way, women are masking the fact that there is Alzheimer's in their brains, but not necessarily
overperforming. But starting at a higher reserve. Yes, starting at the higher level. So the idea is
that we live with Alzheimer's longer. And that may lead to a higher number of Alzheimer's patients
among women down the line. So that really changed the whole question about women's brain health
and Alzheimer's risk because what we and others have shown is that Alzheimer's is not a disease of old
age. It's a disease of midlife with symptoms that start in old age. Alzheimer's starts in midlife
with negative changes in the brain and that later on lead to the symptoms and the clinical
diagnosis of dementia. But then that changes the question, right? Because if Alzheimer's is
not a disease of old age, but it's a disease of midlife, a women have a higher risk of Alzheimer's
disease, a higher long-life, long-term risk of Alzheimer's diseases compared to men starting in midlife.
Then the question that we should be asking, I believe, is, well, what happens to women and not to men
in midlife that could then potentially explain the higher risk of Alzheimer's down the line?
Yeah, I just wrote that down.
I think that's such a profound statement, Lisa, and it actually reminds me of a statement I've made
many times on the podcast quoting one of our guests about something totally different,
which is osteoporosis. The guest said that, look, osteoporosis is a childhood disease. It just doesn't
manifest in childhood, but you reach your genetic ceiling of your bone density by the time, in the case
of a woman, by the time she's 18 or 19 years old. So if a woman isn't able to create enough
deformation in her bones and all of the things that lead to strong bones by the time she's 18, 19,
her risk has already started, even though that disease won't manifest until she's 60.
And I think your example is frankly even more terrifying, but it's well stated.
So let's talk a little bit about some of the theories for this.
I think you and I are in pretty strong agreement that age alone cannot explain this,
even if it partially contributes to it.
There must be some tail effective age.
Well, let's accept that.
The first idea that I think would pop into anybody's head if they're thinking about this for more than two minutes
is a fundamental difference between men and women is that men have a very gradual loss of androgens
throughout their life, but they're never shocked with androgen deprivation, whereas women have a
sudden and shocking loss of androgens at about the time you're talking about in the middle of
their life. They will lose their sex hormones. Of course, the question is, does that play a role?
So where does that idea fit into this and what other ideas fit into it that could explain this?
Again, this is a subject of very active debate in my field to the point that people almost feel like they have to take sides.
It's very interesting. It's an interesting time to be doing this work.
So I think a good way to answer is by, for instance, doing brain imaging, which is what we have been doing.
And back in 2017, we published the first study, which is,
which is bizarre to think about it, it was 2017,
but it was the first study showing the brains of women
before and after menopause.
Everything we had until up until that point was done after menopause,
looking at menopause more like an outcome.
Whereas we were looking at what happens during the transition to menopause,
which is the most neurologically active phase, if you will.
And so we had, in the first study, we had three groups of women, premenopausal with a regular menstrual cycle, perimenopausal, irregular menstrual cycles, and postmenopausal up to age 65.
So no more menstrual cycles for over a year.
No, hormone replacement therapy in that group.
No, no hormone replacement therapy.
And then we had age-matched men because pre-menopausal women tend to be younger than the post-menopausal ones.
And what we found was that before menopause, at the premenopausal stage, regular menstrual cycles, there were barely no differences between women's brains and men's brains.
And sorry, Lisa, what type of scan are you using for this?
So we're doing different brain scans. We use MRI to look at brain volume, to look at presence of lesions in the brain.
Let's be very technical because I think this really matters. So we're going to talk about lots of different types of scans.
today, but the way I typically try to explain this to my patients and to the listeners of this podcast
and feel free to correct this oversimplification as someone who's trained in a radiographic
field. I always want patients to understand the difference between imaging modalities and functional
modalities. So when you look at a test like an MRI, you are doing it for anatomical resolution.
And again, you can choose how you do that. You can T1 versus T2.
flare versus that, you can highlight white matter versus gray matter, you can highlight the vascular
system, but you're looking for anatomic resolution. Conversely, if you do something like an FDG
PET scan, you're not looking at anatomic information, you're looking at functional information.
You want to understand how metabolically active in the case of FGGPET the cells are. Ct CT scans tend
to be much more anatomic, et cetera. Would you agree with that way to think about them and how do
you think of the suite of different radiographic studies that can be used?
Yes, I think what's most important is what you're measuring. You can use different tools to measure
different things. And the really good definition is whether you're looking for structure,
information, for functional information, for biochemical or pathological information. With MRI scans,
what you can do is look at the anatomy of the brain for sure, is to look at volumetrics. You want to
make sure that some parts of your brain are really nice and dense with neurons. Whereas if we find
signs of atrophy, that could be a risk factor for future dementia. Like, there's one part of the
brain that we always look at is the medial temporal lobe, which is a combination of structures that
are quite primitive, if you will, and that they're highly involved in memory function and also
emotional regulation. And there's one structure in particular, the hippocampus, which is considered
a biomarker for Alzheimer's risk, because the hippocampus, you really want it to be as big as
possible. We want the volume to be really nice and large. But when we find reductions in volume
and thinning of the structure, the hippocampus and the parahepocampal gyrus, which is right below,
that is a risk factor for Alzheimer's. Doesn't mean you have Alzheimer's. It means that that is a
red flag for potential Alzheimer's risk down the line. And then, like you mentioned, this is called
the T1 MRI, we usually use it for volumetrics, also to make sure that there are no brain tumors,
that are no obvious vascular damage stroke. So that's a good first line. It's a good first baseline,
but we also do usually T2M flare scans that give you additional information on other parameters
that are important, like if you have gliosis in your brain, which is a bit non-specific,
but it is a sign of white matter integrity damage.
It's like little punctuations in the brain that tend to emerge with aging,
but could also be a sign of inflammation or vascular insults.
So it's good to monitor that.
We can look at the vascular system in the brain.
What I also like to do when we have it in all our biomarker panels,
is that we use MRI with some modifications so we can do DTI,
diffusion sensor imaging, where you can see the structural connectivity.
of your brain, all the different fibers that connect different neurons, and you can extract
a lot of information from those images. And then we also use a modified version of an MRI
to look at blood flow with ASL, arterial spin labeling, which is completely non-invasive,
and it's also really quick. But it is helpful to look at whether the brain receives enough
blood flow at any given time. And then we use petroscopy.
we do 3.1P, phosphorus 3D1 magnetic resonance petroscopy, to look at ATP production in the brain.
So far it's the only technique, except there's one potential with PET that's still being established,
but this technique can give you a good read on the ratio of phosphocryotene to ATP production,
which we find to also be a potential biomarker for brain stress almost,
When the brain is in a state of energetic damage or crisis, that could signify that the neurons
are under metabolic stress.
So we do that too.
And this is all MRI, so we can do everything in less than an hour.
And you will get all that information on multiple sequences of one scan?
Yes.
We can do everything.
Well, it's different scans.
Yeah, I mean, you run the patient through different sequences, but under one table time.
Yes, one table time.
We do need to switch the coil.
for this petroscopy scan.
So we bring you out to the scanner for just a minute.
We switch the coils and go back in.
How many coils do you need for that scan?
At least 306, but I think more potentially.
You switch from the hydrogen to the phosphorus,
but that's just something the technician does.
This is something you would have a really hard time doing
outside of the brain because of motion.
Yes.
Oh, yes.
One advantage of the brain is you lock that head in place,
and it's a short distance under the magnet.
Yes. So those are really good images. And then we also do positron emission tomography or pet scans.
We use FDG, like you mentioned, that looks at metabolic activity in the brain. And we also use another
tracer. It's called C-11 PIB, Pittsburgh Compound B, which shows Alzheimer's plaques in the brain.
Is that what we would colloquially refer to as an amyloid pet?
Yes, it's the amyloid pet. It's just the tracer. It's the carbonated as the C-11, which means that
You can do the FDG and the PIB right away back to back.
You don't have to wait and bring the patient back the next day.
So you can do everything quickly.
And another advantage is that PIB has a very clearer signal than the fluorinated tracers, which is helpful.
The signal to noise ratio tends to be a little bit higher.
So you get a clear read, which is helpful for people who are younger.
because we're not using it diagnostically, we're using it for research.
And the read is a little cleaner, so we get a better signal to noise ratio, I think.
But other people think it too.
It's all the matter of whether or not you need to make it.
You need to have a cyclotron right there.
You need to have a chemist that can make it for you and then just run upstairs that you inject
because it decays really quickly.
So you need to have this big nuclear medicine capability on site.
If you don't or if you prefer to use a fluorinated tracer that you can buy commercial,
then it's perfectly fine.
But this is all the scans that we are doing.
And now, I'm really excited about this.
We're also doing brain estrogen imaging.
So this is the first time that people have been trying to measure estrogen and hormones in the brain for a really, really long time.
It's very hard to do it for a number of reasons.
Back in 2019, I went to my radiochemistry department and I said,
we think that menopause is very important for Alzheimer's risk for women.
And we assume that is the decline in estrogen levels that drive the increased cellular aging
and biomarker risk of Alzheimer's in women.
But that needs to be proven because all the information we have is from rats.
So we need to see what happens in women.
And we also need a tool to measure what hormone therapy is doing in the brain.
And they said to me, well, that sounds really, really great, but we don't have it.
And sorry, you wanted to measure estrogen or estrogen receptor density?
I would like to measure both. What I can measure today is estrogen receptor density.
Okay.
So what we do is that we have estradiol, and we label estradial, the hormone, with a fluorineatein molecule.
It's just attached to the estradial.
Then there's an injection.
The estradial goes in the body, but accumulates in the brain.
and the way it works is that this little molecule mimics estradiol itself and looks for the target.
I think your listeners know this, but the way the hormones work is that the hormone is like a key that needs to open a lock,
and the lock is the receptor, and every type of hormone has a specific receptor.
So estrogen has estrogen receptors.
Progesterone has progesterone receptors.
The way the distracer works is called fluorineatein-a-te in fluorostradial, is that it goes
up in the brain and it looks for the estrogen receptors. It binds to the receptors and it works
like it kind of jams the lock. So the receptor just is almost frozen in time for the period of
time that the estrogen is there. And then the F-18 molecule starts shooting our gamma rays
and we can take a picture of that from the outside and then we use filter back projection
and other techniques to get an image of the brain,
and we can use that with kinetic modeling
to get a measure of estrogen receptor density
in every part of the brain.
So we can finally do that,
and just in 2024,
we published the first proof-of-concept study
showing that we can get a signal,
especially in the pituitary gland,
where the signal is specific,
Like it's not confounded by metabolize or by blood-bain barriers.
And this is not counterintuitive.
I mean, we would expect to see a high-density of estrogen receptors in the pituitary gland,
independent of the disease we're talking about, just because we want to see the feedback.
I mean, I guess we'd expect to see it in the hypothalamus even more.
Yes.
Because we would want to get feedback for FSA and LH.
Is that your thinking?
Yes, totally my thinking.
The blood brain barrier is a big issue.
But the pituitary is slightly...
Isn't the hypothalamus is outside, right?
The pituitary is outside.
The pituitary is outside.
The pituitary is half and half.
Yep.
So the back is protected by the blood brain barrier.
The anterior part is not.
So the tracer goes in really easily, which is helpful to us.
Yep.
So for now, this is what we're doing.
We're able to measure estrogen receptor density in the pituitary.
Just go back to that for a second.
How is estrogen getting across the blood brain barrier outside of that access to half of the pituitary?
There are transporters.
And what's the time course? So if you injected me in the arm through my IV, how long until it traverses and does it only traverse in the free component? Does the estrogen have to be unbound or does it bind to albumin or something else?
It does bind. Yes. That's why we need kinetic modeling. So the timing is relatively fast. If we inject now, we can see uptake within minutes. And then what we do is that we can't.
seeing the tracer accumulating up in the brain.
So we do a time activity curve or trace of uptake in the brain
relative to the tracer kinetics in blood.
And we need both to get a good sense of how much is actually sticking to the receptors
and for how long and how much is just pushed back into the circulation.
So the whole scanning time is 90 minutes, but the peak of uptake is within 30 to 35.
So I would say between 30 and 50 minutes is when you get the most signal.
And then you start to saturate.
Yes.
Also, there's a component of blood flow that you need to disentangle.
There's a whole mathematical model that we're using.
It's called the Logan plot.
And I mean, I don't know if your listeners want to know this.
I don't know if they do, but I do.
Okay, good.
So what we do is then we have spent so much time trying to find a good reference region for the modeling.
Because if you have a reference region that you know to be free or almost free of estrogen receptors.
Right.
It's your negative control.
You can subtract it out.
Yes, that's exactly.
The problem that it took a long time we had to talk to pre-clinical scientists, to cell biologists, to pathologists, to people who have
really specialize in the estrogen receptors. And I've been working with Dr. Roberta Diaz-Brington,
who's a legend in my field. She's been doing this for, I don't know, 40 years. She knows
everything about estrogen receptors. And working with her and looking at all the post-borne
studies, we found that there's a very specific part of the cerebellar cortex. Is this part of the
brain that people say is mostly involved in movement control, but has a number of different
functionalities and there are estrogen receptors deep in the white matter of the cerebellum.
But if you look at, let's say this is the cerebellum from the side, if you look at the inferior
most part of the gray matter at the cerebellum, like the thinness layer possible towards
the posterior inferior part, that seems to be consistently void of estrogen receptors.
Whatever receptors are found there tend to be beta receptors.
three types of estrogen receptors, alpha, beta, and GPR.
And this tracer that we use is more specifically looking for estrogen receptor alpha.
Oh, interesting.
So you're not using 17 beta?
You're using the 17 alpha, estradiol?
Yes.
Oh, that's interesting.
Why?
I would have guessed you used the beta.
I can talk about this for a very long time.
Number one is not being developed.
Yes.
Even though it's the biologically active estradiol, right?
Right.
Yeah.
But not in tumor.
Interesting.
In tumors is the alpha.
And these tracers were developed for oncology.
Yes.
Got it.
Okay.
Yes.
Because they, of course, care about breast tissue.
Absolutely.
Yeah.
Of course.
Yep.
Yes.
Yes.
So it's hard to make ligands for pet.
It takes ears and ears.
You're working with what was developed off the shelf.
Yes.
We basically repurposed a tracer that is commonly used now in oncology to see if we could just
applied to the brain, which I think is win-win situation because we don't have to reinvent the
wheel. So by using this reference region, the other thing that needs to happen is that the signal
needs to be the same. Let's say if you're looking at women who are premenopausa, paramenopausea,
paramenopausea, post-manopausea, the signal in that reference region needs to be invariant,
which we demonstrated. Therefore, we were able to do kinetic modeling using the cerebellum,
that specific part of the cerebellar cortex as the reference.
And by doing that, we show the estrogen receptor density in the pituitary gland
starts increasing during the perimenopausal window,
but is actually higher after menopause,
which goes completely against whatever knowledge we had from pre-clinical studies.
Although, let's think about it for a second.
Let's think about it.
Okay.
I don't know that I would think that that.
That's counterintuitive because as estrogen levels decline, you would almost expect the pituitary in a greater and greater appetite for estrogen to upregulate expression of receptors to say, I want more, I want more, I want more.
And we know that it's screaming for estradiol because it's secreting more and more FSAH and LH.
So is that effectively what you think is happening?
I think that's what's happening, but that does not happen in rodents.
all the models that we had for menopause are based on preclinical work and animal models.
And what happens in rats is that most studies utilize an ovaryectomy.
So it's a surgical removal of the ovaries of the female rat.
So you induce menopause surgically.
Yes.
And what the studies have found is that there is an initial overexpression of the estrogen receptors,
but then there's a sudden crash.
So the window of opportunity is very narrow.
And when you translate into human ears,
there's like an inverted u-shape,
but it's more like a little, like a Gaussian curve.
It's so narrow that within no more than five years
after the final menstrual period,
the idea is that the estrogen receptors have declined
to have the density that they used to have prior.
And that's the prediction you would have had in women.
Yes, but we didn't find that at all.
We found that up to age 65, estrogen receptor density was still nice and high.
So this is totally off topic, Lisa, but I just want to park this on the side so that we can come back to it.
And hopefully between the two of us, we'll remember what I'm about to suggest.
Would this not potentially suggest that a woman in her 60s who went through menopause 10 to 15 years sooner,
who was not treated with menopausal hormone?
therapy would still be a candidate given that she clearly has upregulated her estrogen receptors
in her CNS and therefore at least physiologically suggests an appetite for estrogen.
Yes.
Okay.
We'll come back to that in detail because, as you know, we just keep banging on all the greatest
hits of the mantras of modern medicine, which says, even if someone has finally come around
to say maybe menopausal hormone therapy is not the worst thing you can do to a woman. I'm being facetious.
You better give it to her the day she enters menopause. God forbid, we take all of these women who
are out there who were in their 60s who were deprived of hormones 10 years ago and give them hormones.
Their window is closed. The door is shut. That was the concern. And in fact, when we were writing
the protocol for this study, I said to my team, we're going to do 35, 16.
And they're like, we should do maybe 55.
I said, no, no, no.
We're going to do 65.
We're going to try and map the whole window of opportunity.
And they're like, I don't think that's a good idea.
It's a little, it'll be far ahead.
And when my, and I say, well, we're just going to do it.
When the results were coming in, you know, and sometimes you have a feeling.
No, yeah, sometimes you have to trust your intuition.
And it's a more interesting question.
It's a more interesting question.
I think it's worth it.
Maybe, obviously, we will concentrate around age 52, 53, but let's try to map the extremes,
because we keep talking about this window of opportunity, like, we know what it is,
but it's speculative at this point because we have not been mapping it using biological
indicators.
So anyway, we did it.
And I think it paid off because obviously all the women in the study are naive to hormone
therapy, so no one was taking hormones of any type.
Does that mean that the premenopausal women obviously were off oral control?
And how long had they been off oral contraceptive?
In the very first study, it was interesting that most of them had never used.
Breastmento was very interesting.
So really, really a naive population.
But at least three years.
There was the exclusionary criteria.
And for the postmenopausal women, they were all never users of hormone therapy.
Now, there we have hundreds of women in the study.
be more flexible and account for different things statistically or try to stratify between past
users, hormone therapy, never users, current users. We also have users now, which is very interesting.
And what are you seeing in users?
It's now published that, so I'm not sure that I'm allowed to talk about, but just anecdotally
or descriptively for now, we do see that the window is shift, the curve is shifted.
So we now have women who are older than 65, and we're starting to see where the estrogen
receptors are starting to come down in terms of density. But then the hormone therapy users,
for now, it seems like the curve does not stop at that age. It looks like maybe there is
preservation of density. And then the question is, is this a good thing or not? Because we don't
know if the estrogen receptors are functional. We don't know if the transcription are functional. We don't know
if the transcriptional pathways are still working the way they're supposed to do.
Like, are we stimulating receptors that are not functioning?
We should maybe explain to people what we mean.
So let's riff off each other on this.
But steroids work by driving these transcriptional factors.
So when estrogen or testosterone binds to the receptor,
what it's really doing, what matters is what it's doing inside the cell.
It has to go into the cell.
It has to go to the nucleus.
It has to bind to the DNA.
and it has to say, hey, start making RNA that's going to make protein, that's going to do those things.
And it's that process of transcription and translation that matters.
And so what you're saying is, hey, don't get too excited, Peter.
All we're able to check with this assay is, does the hormone bind to the receptor?
The assay can't measure whether the mechanism of that is translated all the way through to protein.
Yes, because the idea is then there's a system.
There's a supply and demand system, which is like the brain is calling.
for hormones and the ovaries are delivering the hormones. As long as the feedback loop is stable,
we know that usually the estrogen receptors are doing what they're supposed to do, which is
more blood flow to the brain, more energy production in the brain, a stronger immune system,
more neuroplasticity, more synaptic growth. But we also know that with age and with disease,
the estrogen receptors, as many other receptors, may start to malfunction.
They may also go through conformational changes.
That means that the output may not be as good.
Say more about that.
I mean, if I'm going to be honest with you, that's a terrifying thought.
What can we point to in the periphery to help us understand that,
where it's easier to study this question?
I was thinking oxidative stress.
Okay.
Right.
So estrogen, one functionality that estrogen does is to attach itself to estrogen receptors in the mitochondria.
And the mitochondria are the energy factory of every cell in the body, including neurons.
What the mitochondria do is that they transform energy into ATP, or they take the byproduct of glucose metabolism,
and there's a stratos called the electron transport chain that produces oxidated stress and free,
radicals at the same time that they're making ATP.
Usually the balance favors ATP, but if the estrogen receptors change confirmation that may lead
to a less favorable balance where more oxidative stress is being produced relative to the amount
of ATP that is being made.
So yes, there's still energy that's being produced, but there's more oxidative stress,
and this is an issue in the brain.
But couldn't there be other explanations for why we see the inefficiency of the electron
transport chain there?
Like, I'm thinking of something even more basic.
Couldn't we do a similar experiment of 35, 45, 65-year-old women and look at the periphery,
and look at MRNA expression of something very straightforward in response to estradiol
administration?
So you take hormone-naive women, inject all three of them with estradiol, and men
measure for equal amounts of estradiol, how much MRNA gets produced for something that we would
predict.
That's a clinical trial.
Yes.
But according to this hypothesis, we would expect to see declining MRNA, which would
suggest at least possibly that something, and of course, to make it a really cool study,
you'd still want to do the labeling study to assume you're getting at least equal amounts
of binding.
You would normalize.
You would basically say, look, I'm going to take the strength of the binding signal.
and I'm going to normalize it to the MRNA that comes out.
Yeah, you could if you had the money and funding agents.
Well, not for this.
No, but that's an interesting question.
There are so many interesting questions.
But this is a jugular question.
Yeah.
This question implies, can we throw more estrogen at the problem?
In fact, as you know about the periphery before the brain, studies have shown that timing is really important.
So if you have tissues, neuronal, tissues that are healthy, and you introduce estrogen,
estrogen is supportive of the neurons.
But if the neurons are diseased, if there is a schematic damage, there's amyloid pathology
surrounding the tissues or tangles inside the neurons, then estrogen makes it worse.
What's the evidence for that?
It's the studies that Dr. Brinton has done many years ago looking at how estrogen impacted
mitochondrial function.
This is specifically mitochondria, but there seems to be evidence for that in clinical studies
as well, like the Women's Health Initiative, which you have very elegantly unpacked.
There's clearly an age-related benefit-to-risk ratio when it comes to hormone therapy
and brain health.
And many people have argued that the women, in the Women's Health Initiative,
the memory study component that looked specifically at dementia incidents,
those women were potentially too old to start taking therapy, hormone therapy,
at that age, and granted, different formulations, higher doses of hormones,
is not what we do clinically today.
nonetheless, it confirmed this kind of timing hypothesis,
especially for those whose MRI scans showed evidence of an existing,
not the pathology necessarily, but for instance, vascular lesions
or white matter hyperintensities.
In sub-analysis, the idea is that women who already harbor damage in their brains
may not be responsive to hormone therapy, the same way
that women with healthier brains would be.
This is completely to be demonstrated.
So two comments.
The first is, do you think we have a sense of the difference
between the two variations on that theme?
One variation is, once disease has set in,
estrogen is unlikely to reverse it,
but that's different from estrogen will exacerbate it.
Yes.
Let's unpack that.
The second is, as you pointed out,
in the Women's Health Initiative,
we were dealing with oral conjugated equine estrogen, which is known to actually slightly increase
coagulation, which of course would be an enormous concern for exacerbating the vascular
that would accompany this disease. And therefore, whereas we don't see that at all with
topical estrodial, we don't see any evidence of an increase in vasculopathy. We don't see any increase
in ASCBD risk.
So therefore we might assume that, hey, topical estradial is much safer that much is a strong
word, but is safer than oral estradiol, and that we might not see that risk.
So given those two comments...
And also the progestin.
That's exactly right.
The progestion is a whole, I mean, my belief still remains that if there is some meaningful,
clinically meaningful uptick in the incidents, though not mortality of breast cancer,
the progestin is the most likely culprit.
But also for vascular damage. So the NPA, the kind of progestin that was used in the women's health
initiative has later on been shown to potentially increase the risk of vascular damage. And that's
the reason we don't use it. Yeah, so couple that with conjugated equine estrogen taken orally.
Those are getting a bad rap. They still serve a purpose. I would like to see more research done
on the very specific types of hormone therapy because there are so many different.
options that one can work with. And what I would really like to see is what these therapies do
in the brain. Because everything you said makes perfect sense. But it's not been seen. I want to see
it. We can do it. We have the tools now. In your study, obviously, you have to be clean and
as neat as possible. So you have to normalize everybody to the same point. I assume you were
injecting a bioidentical. Well, actually, did you inject? We just inject the lig. We just inject the lig.
Yes.
Yes.
It's just the ligand.
I got it.
And then we work with the menopause clinic at WalcottNet Medicine, which is what I work, or the Obigine Department.
And we have women who are now going on hormone therapy for menopause.
The best majority is transdermal.
Yes.
Estradial with or without micronized progesterone.
That's kind of standard of care.
Today is not necessarily always.
But the women that we tend to recruit for this study, obviously, like you said,
that need to be similar in terms of what kind of therapy they're taking.
I also want to see the CEEs compound.
I would like to see oral estrogen and the other formulations and see if we get the differential signal or not.
Yeah, I think that would be very interesting.
But I think the most important question would probably be answered through the lens of the formulation of the day,
which is going to be transdermal estradiol and, as you said, oral, microcontradial.
synchronized progesterone. I've done a bad job of navigating on this on this journey because I've
taken us so far off the path into these details. But look, I think you have to sort of follow your
bliss. This is incredibly fascinating. Let's bring it back up for people to kind of the surface level
from the ocean floor. We've established through this discussion that something is happening in the
brain of a woman. Oh, by the way, I meant to ask one final question on that topic. You had male
controls age-matched?
For which study?
For the estrogen ligand study?
No, we're doing only women.
Got it.
Okay, so I was going to ask, so we don't know if in a man's brain the estrogen ligands
remain constant or I would predict we'll go up slightly as he ages because his
estradial is going down with testosterone.
Yeah.
So the idea is that the brain compensates for changes in estradio levels and other hormone
levels by increasing the density of the estrogen receptors.
So when usually the brain really loves stability, the human brain is built for stability.
So when hormones are fluctuating throughout the menstrual cycle, the concentration overall is still
predictable.
So the brain is to make very little effort to maintain a certain number of receptors.
This is another thing that is very interesting.
The receptors are not just there.
They just happen to be in the membranes or in the day.
The brain needs to make them.
So it's an active process.
And when estradiol levels increase, then the brain needs to make fewer receptors.
So we see this decrease in estrogen receptor density.
But when estrogen level, estradiol levels come down, then there is this compensatory
adjustment with the brain will overexpress or make more of these receptors in order to just grab
every little bit of estradiol that is in the circulation. The question is, when does this mechanism
crash? Eventually, estradiol levels will be permanently low and the brain is going to have to
give up because making receptors is a very metabolically expensive process. So eventually,
there will be a state or a stage where estradial is low and the estrogen receptors are low or gone.
But when does that happen? It's after 65. It's a lot. It's a state,
seems like. In our studies, it seems to be after 65s. And what I'm trying to do now is to get more
people to also use ligand. And we're also working to make new ligands that could look at the
better receptors that can give us better signal in other parts of the brain. Like we want to look
at the hippocampus, the amygdala, the frontal cortex, but serious single cortex, we higher
specificity and better signal to noise ratio. How quantitative is your assay? It's fully quantitative.
You know what would be so cool. First of all, how much radiation does it expose?
Very little. Very little.
Okay. How many millisiever?
It's six miliqutis.
Is that the equivalent to six milicevert?
No.
That's less. That's 0.6 millisever?
It's less than one.
Yeah. Okay. This would be a very cool study.
Just out of pure curiosity. Very expensive.
So you might not do this.
I would love to take a group of 35-year-old women and scan every one of them the day they get their period.
And then every five days for 30 days.
And just because that's your natural experiment of exactly what you just described.
That is going to be the absolute highest, absolute lowest level of estrogen and progesterone in the brain in a 30-day window.
And the fact that it's quantitative means you can now really develop a sense of how quickly can this compensation occur.
And what's the highest high and the lowest low?
Yes.
And then compare then to estrogen level.
levels in blood. Yes. I think it's so important to clarify that estrogen levels in the circulation
have nothing to do or very little to do with estrogen levels in the brain. Really? Yes. Oh, okay. So say more
about that. That's the problem they were having, I think, clinically, is that we can measure estrogen in blood.
But that will tell you nothing about whether or not you're having half flashes or forgetfulness or any
or the neurological symptoms of menopause, because...
Because we don't know the receptor density.
We don't know the receptor density,
and also the brain levels of estradiol are very highly regulated,
and it's basically all the hormones in the brain are sheltered from changes in the circulation.
So these transporters are active?
They're active, yes.
The brain calls for hormones.
Let's talk more about that.
I thought this was like a passive diffusion.
No, not necessarily. There are periods of time, but it could be in times where it's not,
which is why you can't just push stuff inside the brain. It's so hard to get a tracer
that goes in because the brain doesn't want a lot of molecules, a lot of things, just can't
come through. This is unbelievable. Yes, it's so difficult to come up with this brain.
So you're telling me that if we did my thought experiment of every five days or every day,
It's just a thought experiment.
Every single day you draw a woman's blood throughout her cycle,
and you're going to see estradiol go from next to nothing to 200 and back down.
You see that in blood.
Yes, that's what I'm saying.
Yes.
In the brain, we don't know.
And so you're saying in the brain, it could be uncorrelated.
Certainly would not be partially, partially correlated.
There has to be a response, but it can't be as dramatic.
So what do you think is driving it?
Let me ask a question a different way.
this is now becoming a very complicated thought experiment.
If you did this on a woman every single day for a year,
and she had, say, 12 normal cycles throughout a year.
But one of those months, she had the flu.
And one of those months, she was sleep deprived.
Because, you know, whatever was happening.
One of those months, she was under a lot of emotional stress.
One of those months, she was eating well.
One of those months, she was eating garbage food.
one of those months, you see where I'm going with this.
Yes, you will need a control for every single one of those months.
Of course, because they're twins.
So I'm going to give you, we have identical twins.
I see.
And so you have one of her sisters is perfectly doing the same thing every time.
But also she kind of serves as her own control in a way, right?
Because there must be a month that she's okay.
Yes, there's a month when she's perfectly okay in January.
In January.
I don't know why, but January.
But you see where I'm going.
What I want to sort of understand is how much do the externalities of her life.
which obviously impact her peripheral physiology and must impact her central physiology.
How much do you think, if you had to predict, how much would you guess those are the drivers
of the brain's demand for estrogen?
Hopefully they're not the drivers.
Hopefully hormonal production and hormonal demand is queued mainly by hormonal needs for
the brain because if that weren't the case, we would have.
have a lot of trouble thinking straight. And I think that's one of the reasons that the brain
really very tightly regulates entry of nutrients or chemicals from the circulation, because
if the levels of receptor activity were to fluctuate too quickly or too frequently, that could
lead easily to cognitive impairment or to mental confusion or to an inability to just
function. But at the same time, it is important. Your lifestyle has an impact. I don't know that the
impact would be visible on a month by month. This is hopefully not. But over time, the poor lifestyle,
sleep deprivation, high stress levels, that in theory would negatively impact the brain itself,
making perhaps the receptors are not as functional as they used to be. Or estrogen uptake is not
as tightly regulators are carefully planned as it used to be, and then there could be glitches
that are more long-term. Does it make sense? It makes sense. It basically says we are only at
ankle-deep water at this point in terms of our understanding of this process. Yes. Yeah, it's really
just the beginning. And this is a reason that I launched CARE, which is my new program of research. Can I
mention? Of course. So I just launched a $50 million program of research sponsored by Welcome
Leap, which is an independent subsidiary of the Welcome Trust. It's called Care, cutting Alzheimer's
risk through endocrinology. As I mentioned, is 50 million unrestricted, which is amazing for this
specific question. And care is effectively the largest research program on women's brain health,
menopause and Alzheimer's disease ever attempted. And what we're doing with care is, it's like
the movie Oppenheimer. I think people are familiar with that movie where Dr. Oppenheimer was in
charge of designing a research program and then basically inviting other scientists from all over
the world to work with him on a sprint. It's called a sprint. So it's a three-year, just three
years. It's a high-risk, high-reward research initiative, which for them ended up with the atomic
bomb. With us, we'll hopefully end with a means to half the risk of Alzheimer's disease for women
by the year 2050. That is our target. We estimate that if everything goes according to plan and we
hit all our marks, then we should be able to reduce the risk of Alzheimer's for an estimated 330 million
women globally and given current global conversion rates to Alzheimer's, we could potentially
prevent 55 million new Alzheimer's patients among women in the next, hopefully, 25 years.
And one of the things that we're doing with care is, so we have three different components.
Trust one speaks a lot of what we've been discussing so far.
we want to understand how neuroendocrine aging and specifically hormones really speak to Alzheimer's risk
for women because all the predictive models that we have so far are sex aggregated. So we look at
things at risk factors that work for men and women, but they can do genderless. The fact that sex
has been removed statistically, but there are things. How is that even possible? That's the vast
majority of models. So when we say that we do talk about this now, that Alzheimer's risk is
multifactorial, but potentially preventable in about 45% of cases. The 45% comes from studies
that have looked at all sorts of risk factors in cohorts that combine men and women. And more often
do not, the predictive models adjust for sex as a covariate. So you want to see.
statistically to remove the effects of sex and see whether diet is associated with Alzheimer's.
We can't get the raw data and re-insert.
Yes, this is what we're doing with here.
Okay.
Okay, good.
Yes, yes, yes.
So whatever we know about Alzheimer's freak so far is genderless.
It works for men and women, which is still, it's a wonderful start.
To give you one example, you're saying when we sit around and say that having an APOE3 and an APOE4 gene
increase your risk of Alzheimer's disease by about 2x, that should be more nuanced. We should say
in a man, it increases it by X, and a woman it increases it by Y. Sixfold. It's sixfold
increase in it. So that's something I did not know. We usually talk about this, at least I usually
talk about it, without differentiating between sex. Clearly, that's a mistake. So if we're talking
about comparing people who are heterogeneous, so one copy three, one copy four versus two copies three,
what's the relative risk increase for women specifically?
So women who are heterozygous for the APO-E4 allele have a four-fold increase in dementia risk
as compared to non-carriers.
But women who have two copies of the E4 allele, then the risk is between 12 and 15 times higher
relative to non-carriers.
Yeah, so this is about twice the risk of men.
Yeah.
Yes. Okay, let's now talk a little bit about the role that hormone replacement therapy or menopausal hormone
therapy can play in women with or without an E4 allele. Let's also talk about it in the context of
initiation of therapy at an appropriate time just to start. So what do we know about this?
This is a tortured part of our field of research, because, unfortunately,
Unfortunately, there's only one clinical trial that's ever looked at hormone therapy and Alzheimer's incidence in women.
And that's the Women's Health Initiative Memory Study.
Which, of course, had a lot of hair on that dog.
Yeah.
Yes.
In that specific study, the risk of dementia was increased for women who were taking the combined estrogen progestogen therapy, which in that case, like you said, it's oral conjugated equine estrogen and MP.
and the risk was also 50% higher for women who were taking only oral estrogens following a hysterectomy.
However, that risk increase was not significant.
Now, that's the only clinical trial we have, looking at the incidence of Alzheimer's disease
relative to hormone therapy use, and all the women were postmenopausal and by a long shot.
Unfortunately, we don't have clinical trials where hormone therapy is,
given in midlife for relief of menopausal symptoms, which is the appropriate indication,
where we also measure the incidence of dementia because those trials are just not feasible.
It would be like a 20-year, 30-year trial, and it's just not possible to do that way.
In that case, observation of research offers more information about whether there is a
differential beneficial effect relative to initiation timing.
and we do know that observation of research is subject to bias.
So this is just more descriptive than definitive.
However, it is interesting that meta-analysis,
which are statistical integration of all available data,
do show the timing of initiation matters,
and also the type of formulation.
So women who do not have a uterus who have received a hysterectomy,
which is the surgical removal of the uterus,
with or without the ovaries, are typically treated with estrogen-only therapy. They don't have to.
You can also have a progestogen, but generally practice says, let's just go with estrogen,
whereas women with a uterus need a progestogen, whether a synthetic progestin or micronized
or what people say, bioidentical progesterone. Now, if you look at these two factors, when you start,
which is within 10 years of the final menstrual period, or ovaries, or ovaries, you start, you're in the final menstrual period,
or over 10 years, so the final menstrual period and whether you have a uterus or not.
This is what the study, the observation of research so far shows a 32% reduced risk of
Alzheimer's of dementia for women with a hysterectomy who have undergone a hysterectomy
and they're taking estrogen-only therapy. Significant. Very consistent risk reduction
across all the studies available, almost all the studies. We have now one from Northern Europe.
does not show that protective effect. This is when hormone therapy is initiated within 10 years
at the final menstruate period. For women with the uterus, starting hormone therapy within 10 years,
there's a 23% risk reduction, which is however at trend level. Some studies show an increased risk.
Most studies show a reduction in risk, so we need to better understand what's happening there.
When we look at starting hormone therapy more than 10 years after the final menstrual period,
there is no obvious benefit for estrogen-only therapy for women with a hysterectomy,
and there is an increased risk for women with a uterus who were taking estrogen and progesterogen of any type.
We do not yet have enough studies.
I'm pre-enting your question.
I can see it forming.
We can't yet separate progestins from my own.
micronized progesterone, we cannot yet look at each specific type of hormone therapy because
the data is just not there. We need to do more research. Also, I will add, this is a fairly
all-fashioned way to look at this question. I would argue that today with the tools that we have
and the data they were able to collect, what would make more sense? And I'm sure you were going to
say, wouldn't it be better to, yes, it would be better to start hormone therapy,
today and look at biological markers of Alzheimer's as the therapy is progressing.
In fact, what would be ideal is to start hormone therapy today.
Look at the estrogen receptors, use brain estrogen imaging to monitor whether the therapy
is doing what is supposed to be doing, and also look at biological markers of Alzheimer's to
make sure, or at least to test, whether they're either not showing up,
or they're being delayed in their progression or evolution relative to a placebo group,
which is what we're trying to do now with care.
Fantastic job anticipating both questions I had and saving me from answering them.
Does this mean that one of the initiatives in care is actually a prospective,
randomized trial that will administer MHT at the appropriate time during perimenopause?
I have a whole soapbox on why we have to start this in perimenopause.
You don't wait till menopause.
And then we prospectively follow the various markers.
Half is yes.
So we only have three years.
Running a clinical trial in three years is just not feasible from start to finish.
So what we're going to do in the three years, our goal is to provide evidence a convincing
scale that hormone therapy has or doesn't have, but we're going to do.
We're hoping it might have a beneficial effect on biological markers of Alzheimer's by working
with women who spontaneously decide to start hormone therapy.
So you don't have to enroll in randomize.
You follow women who do go on hormone therapy and women who do not.
And that's what you can do in three years.
How will you match them for health consciousness?
There's an inherent, I think, bias that slips into women who opt into hormone replacement
therapy because the barrier to entry is high. Most women who want hormone replacement therapy
are going to face an uphill battle with their doctor who, no disrespect, but their doctor is
ignorant, busy, just believes it's bad. And so the women who ultimately end up on hormone replacement
therapy had to jump through a few hoops. They're also probably a little bit more health conscious
on average because they're willing to go through the brain damage of having to beat the system and fight
and make sure that they can get what they rightly deserve.
Whereas the woman who says, I'm not going on hormone replacement therapy, it's less
of an active decision.
It's probably more of a passive decision.
Now, of course, I can come up with some examples.
Maybe you have women with a very strong family history or personal history of breast cancer
that might be equally health conscious, but they decide to opt out for reasons that have
to do with that.
So that might be one way to match them.
But otherwise, you have to be very careful with this type of analysis.
Yes.
Because the healthy user bias runs deep.
Yes, absolutely. It's one of the concerns with observation of research. The other concern is that women with the most symptoms are also more likely to start hormone therapy. And there seems to be an association between more hot flashes like the severity and frequency of hot flashes, especially at night and amyloid beta levels in plasma and white matter hyperintensities in the brain. So there's a few things that we need to
ascertain. And I think the way to do it is number one with education and they think that a lot of
my colleagues and you and your colleagues are doing a fantastic job of making sure that women
understand the hormone therapy is on the table. And then they can come to us the research sites
where they also have access to the gynecology department, to the menopause clinics, where our
clinicians are open to the notion that if you do have the symptoms of menopause, and if you're
willing, interested in starting hormone therapy, that is perfectly doable. So I think by working
with us, certainly there shouldn't be much of a barrier to access hormone therapy, if indicated,
we do follow professional guidelines. Is there any woman who is in that perimenopausal transition
who you think needs to be cautious of hormone replacement?
as far as her brain health is concerned?
I think the concern about starting hormone therapy before menopause is that hormone levels
are fluctuating.
Using birth control, for instance, by blocking ovulation, will make sure that once you do
go on birth control, you receive a standard dose of hormones that have been tested, and that
can be clearly monitored, right?
You know exactly what dose you're given at any given time.
Whereas with hormone therapy for menopause, depending on what you're doing, you can't really do a blood draw every day or every moment.
So the concern is once your level of estradiol are low enough, then we should be fine.
But if they're spiking and you put more hormones in the systems, you may amplify the spike.
Our view is that once women are symptomatic, so we're not doing this based on blood.
Yes.
But women can be symptomatic for a year.
six months or three years. There's just so much variability in this system, but there's evidence
that as soon as they're symptomatic, both from an estrogen and progesterone standpoint,
although the estrogen tends to be the symptoms that dominate, the benefits accrue
immediately with respect to vasimotor symptoms, bone health, cognitive performance in the short term,
sexual health and sexual function, and that waiting until a woman has completely stopped
her fsh is 40 and her estradiol is unmeasurable, at which point everybody would say, yep, she's in
menopause. You could spend five years getting to that point from the moment you started having
symptoms. And again, there's evidence that you've actually taken steps backwards with respect to
health. Now, what's the trade-off? The trade-off is you're going to have loops, meaning, you know,
you're going to have ovulations that force their way through the system and you're going to have all
sorts of estradial spikes. I can tell you that clinically, most women are far less bothered by this
than the reverse. At the end, it's really about feeling better. To your point, this requires nuance.
This is not a set it and forget it policy. This is something where, you know, and I had Rachel Rubin on the
podcast, this is where doctors like Rachel matter because they understand how to titrate the system.
they understand, oh, you know what, even though normally you might put somebody on 200 milligrams
of micronized progesterone when they're fully in menopause, you might only need 50 milligrams today,
and you might only need 100 milligrams next year. So it's not an on-off switch.
It's more like a precision medicine type of approach. It would be so good to have more research
happening in parallel, because I notice that there are many clinicians who are now open to,
to working with their patients, to address the needs of the patients,
and kind of base what they're doing on their own experience
and their relationship with the patient.
I think for them, and I know a lot of them and friends with many of them,
what I think would be lovely to have is data that really works in parallel,
so you have maybe not clinical trials yet,
but at least some information that can help guide the diagnostic process.
And the challenge is there's not a natural owner to doing that study. It's not as simple as
here's the latest version of a GLP1 agonist and we're going to go out and we're going to test
whether it's more or less efficacious for weight loss or type 2 diabetes where there's an obvious
sponsor for that research. Here we're talking about drugs that are cheap and not protectable.
One thing that is probably interesting is the selective estrogen receptor modulators.
Yeah, so let's talk about serms a little bit.
The serms are very interesting compounds because, like we were talking about before,
there are different types of estrogen receptors, at least three types that we know of,
the estrogen receptor, alpha, beta, and g-per.
And they are distributed differently in different parts of the body.
For instance, within the brain, we have some structures like the pituitary gland and the hypothalamus
that contain similar amounts of estrogen receptor alpha and beta,
but are predominantly alpha,
because they're more reproductive tissues.
So the alpha receptor is more abundant or more expressed in reproductive tissues,
whereas the beta receptor, for instance, is more expressed in the cognitive parts of the brain.
So what some scientists and clinicians have been trying to do
is to develop compounds that selectively
attach themselves to the beta version of the estrogen receptors.
And for instance, I'll go back to Robbie, Dr. Robbie Brinton,
she developed what I believe to be the first neuroserm.
So it's a neurological selective estrogen receptor modulator
that comes from plants, actually.
She looked at all different phytoestrogens
and compounding them together into a formulation that's been shown.
shown to bind with very high affinity to estrogen receptor better specifically. And that means
that, at least in animals, she tested that very thoroughly in animals and she did a phase
one clinical trial. We're now doing a phase two B in women. But what she found is that this
specific substance leaves your reproductive organs alone, but goes up into the brain.
and binds to the estrogen receptor beta with high affinity, therefore stimulating cognition
in terms of memory, for instance, or executive function, and also supports mitochondrial activity
because she's done a lot of work of mitochondria and seems to improve neurogenesis as well.
That's pre-clinically.
So we're not looking at whether that formulation can improve brain energy levels in women,
and hopefully memory performance.
And also we are hoping reduce the risk of developing Alzheimer's plaques.
And we are working with women who are very early postmenopausal.
Is this pre-I-ND or is this in phase one yet?
This is phase two.
But this considered a supplement.
So the FDA considers this a supplement.
Because it comes from plants.
Yeah.
What's the name of it?
Phytotherm.
Phytocerm.
Yes.
To be clear, it's a grass-approved FDA supplement?
Yes, it is approved by the FDA.
So the purpose of these studies is to be able to make claims.
It's not regulatory.
It's not regulatory.
They have done all the regulatory phase.
We are now doing a clinical trial very specifically to test whether it supports cognitive function
and brain energy levels in women at risk for Alzheimer's.
And Rob is also looking at half flashes and visomather's syndrome.
in a separate clinical trial.
The reason I brought it up is that I think is a fairly unexplored avenue
for support of brain function and also for relief of menopausal symptoms in women.
Because it makes sense to go for the source of the symptoms that they have flashes,
the eyesweds, the insomnia, mood symptoms, cognitive symptoms.
They start in the brain.
So it would be wonderful to have a molecule that's never been associated with an increased risk of cancers to any reproductive organs and just goes into the brain.
It does what it's supposed to be doing in the brain.
But then we miss the activity in sexual organs.
We miss the bones.
I mean, there's still so many benefits.
Well, not the bones.
I think there are estrogen receptor beta in the bones.
But you're not going to get it with a serum.
No, with this specific serum.
No, but there may be other serms that are developed in the future.
But we have the perfect one.
It's called estradiol.
Why are we afraid of this?
I mean, I think this is the problem, right?
We have to stop giving the fear-mongering people an excuse, which is there is no evidence
that estrogen causes breast cancer.
This is a fallacy.
This is a complete fallacy.
The Women's Health Initiative data by itself makes it very clear.
Not a single additional woman died of breast cancer as a result of taking even the conjugated
equine estrogen. If there was any increase in incidence, but not mortality of breast cancer,
it was due to the MPA, which, again, how many women take MPA today? Today, no, it's been
discontinued. So we have no women taking MPA today. Women are all taking bioidentical,
micronized progesterone. I want to be very careful that I never let someone have that out of saying,
but estrogen causes cancer. It doesn't. There's no evidence that it's causing cancer. Yeah, I think the word
cause has been misleading women for a really long time.
It has.
The idea is that you have no risk of cancer, you have no cancers already, and somehow you
take this molecule, this estrogen molecule, and boom, you get cancer.
That's not what's happening.
No, but that's what women are being led to believe.
Yeah.
And again, the analogy that we should have women understand is the analogy between testosterone
and prostate cancer.
Yeah, that's a good one.
This is a very good analogy because it has been unequivocally demonstrated that testosterone
either endogenously or given exogenously does not drive prostate cancer.
Does that mean that when we have a man for whom we're treating him for prostate cancer,
if he's not a surgical candidate that we don't do androgen deprivation therapy?
No, of course not.
We do androgen deprivation therapy.
But once a man has surgical therapy for his prostate cancer, guess,
What? We resumed testosterone replacement therapy. He had prostate cancer. We're giving him testosterone. But guess what? Doesn't increase his risk. So here's why I believe that we're so brain damaged on this topic. The urologist has a marked advantage over the clinician who treats breast cancer. And it comes down to a very simple protein called PSA. It's the PSA that gives the urologist and the urologic oncologist a marked advantage.
which is we can always follow PSA.
So when you have a man who has a Gleason 3 plus 3,
which is a cancer,
and you're trying to decide,
okay,
he has prostate cancer,
but is it the kind that's going to kill him,
or is it the kind that's just going to stay in his gland
and stay localized?
You watch and wait those men.
We don't operate on a Gleason 3 plus 3,
even though it's cancer.
But do we chemically castrate that man?
Not a chance.
If his testosterone is 900, we rejoice.
If his testosterone is 300 and he's feeling symptoms of hypogonadism, do we give him testosterone?
Absolutely, we do.
And we follow the PSA and we follow the MRI.
And if we need to do a biopsy, we do a biopsy.
And if his cancer changes, we treat him.
I think it's the fact that we don't have the equivalent of the PSA for breast tissue.
And in fairness, and in fairness to those who have.
to make these decisions, we miss the blood biomarker that allows us to cheaply and easily
track the disease. But that doesn't change the underlying pathophysiology. I have nothing against
serms. I didn't mean to get on my soapbox. But I don't want women to come away from this discussion
thinking estrogen is bad. Oh my God. They should be coming away with the opposite, which is estrogen
is very important for their brains. Estrogen is certainly on the table. And I think that we have put
ourselves in a difficult situation where now we need to re-educate, not just the patients, but also
the entire medical and scientific community based on newer data. I don't know how this really
happened, but we have been stuck with the Women's Health Initiative for decades. It doesn't
happen in other fields of research, don't you think? No, it did. This has happened, I think,
in other fields of research. Yeah, sure. Think about the literature or think about
the phobia around dietary cholesterol. Oh, okay. Think about how much you can't eat the yolk of an
egg, you can't eat shrimp. Yes, I was thinking. Dietary cholesterol raises cholesterol on the blood that
causes heart disease. I mean, but did it all come down to one trial? Because this is just one trial.
That's a fair point. You're right. In the case of dietary cholesterol, it came down to
a couple of epidemiologic studies, a couple of clinical trials, none of which asked the question
exactly, but the public was either misled or confused about the difference between the chemical
structure of dietary cholesterol, which is astirified versus non-asterified endogenously produced
cholesterol. And the story is much more complicated. To your point, though, the women's health
initiative cost more than a billion dollars 25 years ago. Yeah. And therefore, it's not going to be
replicated. So it was a study that had at least three or four fatal flaws in the design, some of
which I think are justifiable. The most fatal flaw in my mind is they just used a garbage formulation
of estrogen and progestin. But that's what they had. Exactly. And it's not the only thing they had,
but they made the decision to use, yeah, they made the decision to use what doctors were prescribing most
frequently. I think that's a forgivable mistake. The real fault lies with the PIs and the media,
who I believe very nefariously promoted a false agenda. Again, when was the last time the NIH
did a press conference on a study like, really, press conference? Post-game analysis,
really? That's what we're going to do? That's strange. Very strange. And I think there are
certain members of the media who I will refrain from naming who simply got it in their
mind that this was the way it was and they have been completely immune to any form of logical
intervention to show them otherwise. Even when seven and even 19 years later, subsequent analyses
find the same thing. Nineteen years later, we see the same, and by the way, to my knowledge,
that's the most recent publication. Maybe there's something even newer. But 19 years post,
we're seeing not one additional woman died of breast cancer in the season.
CEEE plus MPE group relative to placebo.
And that's even with the MPE, the MPA, rather.
Where's the press release on that?
I know.
I know.
There's a tendency, I think, to amplify the negative results as opposed to the positive
result, like even with the association with Alzheimer's.
There are a few studies that came out of Northern Europe showing that hormone therapy
in those are retrospective studies that looked at women.
who have Alzheimer's today, and we're taking hormone therapy starting before the Women's
Health Initiative crash.
And in those studies, there is an association between taking hormone therapy at any age
and an increased risk of dementia.
There are two studies.
They're all over the news.
All over the news.
Hormone therapy causes Alzheimer's.
Right.
But the 10 studies that show the opposite, it's crickets.
Yes.
Yes.
There are studies with like half a million women from the United States.
where, by the way, the vast majority of studies
shows a protective association
that just never make the news.
And that I find is a pity
because it leads to a very unbalanced conversation
where so many women today are like,
oh, I need to go off the hormone therapy
because of this observational study
that is a correlational study, right?
Not even a trial.
But I think it's so hard to disentangle
scientific information when it's a headline.
You're hit by the headline.
And it's very hard to really understand the context and the nuances and just the fact that even in these studies they make the headlines, those women were taking hormones before the women's Health Initiative crashed.
You can see that they start with a certain number of women in the study, and then the number just plummets.
Right.
So at the end, you're left with this subpopulation of women who just happened to be still on hormones.
I won't even pretend to disentangle that I could predict the biases that are inherent in that type of a study.
Observational research is hard.
That's like the worst example of observational epidemiology.
I couldn't disentangle that.
Like, I couldn't even tell you what corrections you would need to make.
I think your intuition a few moments ago was the right one, which is the only way we're going to get better data on this.
It's by generating the right data.
Yeah, we don't need more observational epi on this question.
What we need are better and better biomarkers that allow us to do more rigorous prospective
randomized control trials.
We need RCTs and we're not going to get hard outcomes because it takes too long and it's
going to cost too much.
But we could look at C2N.
We could look at PTAO, we could look at any of the other brain metabolomics.
We could look at so many things.
And so I guess my question for you is clinically, I mean, most people listening to us aren't
going to have access to an estrogen tracer. They have to be in a clinical trial.
Or in the studies way to do. Yeah. Yeah. So clinically, what do you think of C2N? What do you think
of the commercially available versions of PTAO and these other studies? Do you think that these
are ready for prime time? Do you think that prevention or a diagnosis? Yeah, do you think that
physicians and women could use these as tools to track interventions that they're making? Oh, to
track interventions. Oh, yes. Yes, totally. This is what we're doing.
with care. So we're using
these specific... You're using commercially
available assays. Sometimes.
We do have the machines
by the smosa, and so we
are, our centers, our
sites, basically, they
run their own assays,
but it's the same machines that are
used by commercial entities.
And we are using those
as surrogate outcomes of Alzheimer's risk.
We're using not just the brain scans,
but also the blood-based
biomarkers, because they're much cheap.
They're minimally invasive.
They're easier to read.
We do need to have more long-term data
to really establish their predictive value
for each individual.
Right now, they're being used either diagnostically,
which I think is very smart,
or for research to try and better understand
if we can't use those markers to really predict
who is of risk and who's not
and what is the positive predictive value,
a negative predictive value for any given individual.
And I think studies like CARE and other prospective cohort studies
and large-scale biorepositories,
I think they're so important, like the UK Biobank,
thousands and thousands and thousands of blood samples
that can be used and analyzed for these purposes.
So one way to maximize the potential of observational research,
in a three-year span, is to leverage data from all over the world.
Because a lot of the information we have comes pretty much always from the same studies,
mainly North America, some European studies.
And the population in those studies tends to be quite homogeneous,
predominantly white, individuals with a certain level of education, overall healthy.
So what we're trying to do is to get data from all over the world.
So with care, we have access to female-specific data from six continents.
We don't have it from Antarctica.
But we do have data coming from six continents.
And all together with the other scientists involved in care,
we are estimating receiving data from over 20 million women,
especially longitudinal data.
So that's going to be a treasure box of data for scientists who are interested in
addressing these questions. And yes, that's what we're going to do. So that's the first component
of care is to firmly establish neuroendocrine aging and really reproductive history for women.
All these different factors that seem to emerge already puberty and then are perhaps even more
unmasked during pregnancy in the post-partum period and then tend to repeat themselves around
menopause. There seems to be a continuum. Like you can kind of leverage a woman.
reproductive history, is a potential stress test for future cognitive decline and Alzheimer's disease
or the opposite, cognitive resilience. This is something that has never quite been done
formally and in a standardized fashion, so we are trying to do it now. For instance, high blood pressure
is a risk factor for Alzheimer's, for both men and women. It may be even worse for women.
some studies suggest, as a suggestion, but effectively preeclampsia during gestation, right,
during when a woman is pregnant, is effectively a stress test on the body. It gives you a preview
of whether or not you may have chronic hypertension when you're older. And usually if it starts
during pregnancy, it may present itself again during menopause and then it may remain stable.
same for mood changes. If during puberty your neuroendocrine system is activated in such a way
that you're more likely to suffer from anxiety or from depressive episodes or from mood changes,
then things may stabilize as you get older, but then they could actually come back during pregnancy
and that could be unmasked again during menopause. It's so common for women and we know that
midlife depression is a risk factor for Alzheimer's, more for women than for men. So we're trying
to put it all in context, not just what happens to you today, but what happened to you in the past.
I believe, and I'm sure you might agree, that hormonal history should be considered a vital
sign. That was nice. Yeah. So do we know if, let's take two examples. Let's take the blood
pressure example. Hypertension is a risk factor for Alzheimer's disease in men and women.
And vascular. Yeah, vascular health in general.
Mention. Do we know if when we see hypertension being a greater driver of risk in women than in men,
that we're not picking up the same underlying risk that is being driven by something else,
such as the neuroendocrine system? We do not know that. So we don't know if independently these
are all the case. Absolutely. There are very few studies that.
have looked at neuroendocrine variables at all. Very few. In fact, if you look at the Lansack
Commission for those interested in Alzheimer's disease, whenever it comes to Alzheimer's prevention,
we look at the recommendations of the Lansett Commission, which every few years produce an update.
And as of 2024, we have this risk model that accounts for approximately 45% of all Alzheimer's cases,
So modifiable risk.
Modifiable risk.
So there are 14 modifiable risk factors that have been established to be meaningful and replicable by the Lancet Commission
that altogether account for about 45% of Alzheimer's risk.
And those are sex aggregated risk factors.
They're valid for both men and women.
What is completely missing there is anything that is female-specific or male-specific.
And what they say, they have a section about menopause and hormone therapy.
And they conclude that hormone therapy may increase the risk of Alzheimer's,
especially for women with an oophorectomy.
We were all like, what happened?
One just has to be somewhat dismissive of these things.
I mean, I realize it's easy for you and I to be dismissive of them because we know.
I'm not dismissive.
I'm really like, what can we do to,
change this because it's so important with women who do get an opherectomy to also be aware
the hormone therapy.
No, no, no, no, but just to make sure I understand.
Yes.
They're claiming that it's not the ophorectomy, that it's the hormones that follow
the euphrectomy?
Well, we do know that undergoing an ophrectomy before menopause increases associated with
an increased risk for Alzheimer's, but what they say is the hormone therapy, can also increase
the risk of Alzheimer's disease, especially for women.
So what's the data for that?
It's a couple of studies.
Yeah, my point is it's total nonsense.
The studies that suggest that if a 40-year-old or a 35-year-old woman undergoes an opherectomy,
that she's better off without hormones than she is with hormones,
I mean, I just don't believe those studies.
I don't believe those observational data.
Yeah.
I mean, do you?
I think observation of research needs to be cautious.
But specifically those studies.
Well, do I believe the studies? That's the study that was done.
Let me reframe it. If your 35-year-old sister was in a car accident or had an ovarian cyst rupture or something like that and needed to undergo an opherectomy, she's 35 years old, she is now sitting in front of you in menopause. She's mechanically, chemically, in menopause, and she's got hot flashes and she's got all the symptoms that a 35-year-old woman would absolutely have in spades because of the abruptness of this. And she came to you and said, do you think I would be better off with or without hormones? What would you suggest?
with hormones. I think this standard occur at this point.
But do you think you would be increasing her risk of Alzheimer's disease by telling her that?
No, that's why I'm so puzzled.
No, no, no, no. We're in alignment. We're in alignment. I mean, whatever we know about hormone
therapy is that is especially beneficial for women who experience early menopause and especially
when early menopause is triggered by an ophorectomy. This is in professional guidelines.
My only point here is that these commissions sometimes cherry pick data to fit their agenda.
That's the point.
Why is that an agenda?
Is it even an agenda?
I don't know.
What is concerning to me is that neuroendocrine factors that are important for women, I think it's undeniable,
are not part of these recommendations for Alzheimer's prevention.
And when they do identify.
Well, they are.
They are, but they're in the wrong direction.
This one is.
It's not positioned as a recommendation.
It's more like we don't know enough.
I want to pivot and ask you about something else.
This is not something you think about.
That's fine.
But it's something we are thinking about a lot.
Okay.
Which is, do you believe that independent of weight loss and insulin sensitivity,
GLP1 agonists, are going to have a protective effect in the brain?
I think it's really interesting.
And it makes sense.
See, that's the thing.
biological plausibility needs to be present for any study to be done.
And sorry, I just want to complete my train of thought.
When you do observational research, which is also relative to the GLP ones,
you need to have a hypothesis that is based on something.
You can't just do a fishing expedition.
You need to have preclinical work showing, for instance,
that once you have a new phectoratomy, estrogen is beneficial.
if you start right after the surgery, you keep taking it until the natural age of menopause.
That we know from preclinical research.
That is your biological plausibility.
So then you do translational research.
You power your observational study to assess a hypothesis that is based on preclinical work.
That is still observational, but is solid.
If instead your study is showing the opposite, there's some issue there.
So that is my concern when it comes to some kind of research that gets published.
It gets published because that's the day-to-day you have.
And regardless of whether or not your conclusions are in alignment with clinical research,
you publish it anyway.
That's a question mark for me.
And everybody falls back on the Women's Health Initiative.
Once they find an increased risk, it's like, well, the Women's Health Initiative found
so-and-so, even though it goes against biological plausibility.
So for the GLP ones, I think there's a lot of the potential.
There's actually someone I know who's developing ligands or tracers for GLP ones in the brain.
And I think that's going to be really interesting.
Do you have a sense of what the mechanism of action would be beyond two things that are important, which are metabolic?
We completely, it's totally logical that even if you have some insulin resistance absent diabetes, making that better is going to make it better.
We appreciate that obesity is accompanied, even if it doesn't come with diabetes, it's still
accompanied by inflammation.
And as we reduce inflammation, yes, all those things.
Yes.
But the real question I'm asking is if I took someone just like you, and I'm assuming I know
I can see your health and you're in perfect health, but you are at high risk for Alzheimer's
disease.
Were there take a GOP1?
Yes.
We put you on a micro dose of terseptide, low enough dose that I'm not going to take weight off
you because I don't want to take any weight off you. I don't want you to suffer the consequences of
sarcopenia or anything like that. Is that going to provide protection for your brain? This is the
question I want to know. This is the study I want to see done. And of course, you can only study this
prospectively with very good brain biomarkers. We're not going to be able to do this study for 20
years and follow a bunch of women. But if we have, as I think we are, getting to the place where we
have really good biomarkers, can we start to ask this question?
scientifically. We can start. The question is never interest. I think so many scientists are
interested in testing it. The problem is always funding. It's really expensive to do this
kind of research and do it well. And who is going to sponsor it? Hopefully the NIH. I mean,
historically, the NIH has been the biggest source of research fundings in the United States.
this is clearly a national level problem.
It's a bipartisan problem.
Hopefully, this is happening is not my field necessarily,
but even just the fact that people are developing ligands and tracers for GLP ones,
everywhere in the world, including the brain, I think, is a strong indication that there is a lot of interest.
As of today, I don't know how to answer.
I really don't know how to handicap that.
the data look somewhat promising, though. I have seen some unpublished data, which, as you pointed
out a few minutes ago, I mean, you have to take that with caution. So there's lots of things that you have
to be mindful of, but I have seen some unpublished data that suggests that very low, 2.5 milligrams of
terseptide, as an example, is meaningfully reducing blood-based and CSF-based markers of neuroinflammation
and protein aggregation.
And again, we're talking very small numbers here.
You know, we're talking like n of 20.
Yeah, but you have to start somewhere.
Yeah, you're pilot.
And that's really interesting.
So I wondered if you had a more informed point of view, but it sounds like you're equally
interested, but yeah.
Well, Lisa, this has been a very interesting discussion.
It's really the discussion I wanted to have was kind of this intersection of the brain
and Alzheimer's disease.
Unfortunately, I feel like we are still a little bit in the dark because, you know,
while it appears that the neuroendocrine differences between men and women probably account for the
majority of these differences, there may still be other things, right? We still don't understand if
women are more susceptible to hypertension, dyslipidemia, insulin resistance, sleep disturbances, all of
the other risk factors. We don't know if they're disproportionately affecting women. And so I guess
we're left with the following question. Ultimately, if you're listening to this podcast,
you might take interest in all the nuances we've talked about, but if you're a woman, you
want to know, what should I be doing different? What should I be doing different than I'm already
doing? And so what is the answer to that question? If you're already paying great attention
to your sleep, if you're already paying great attention to your nutrition, if you're insulin
sensitive, if you're managing all of these things that we've talked about, is the big takeaway
from this discussion that if you're on the fence about hormone replacement therapy, it's probably
something that should be in your purview and you should probably think about it more seriously.
What would you say to a woman who's either about to go through menopause in menopause or just
out of menopause who's coming at this purely through the lens of her brain?
I don't know that many women who really check all the boxes.
I think whenever patients come to the clinic, to the Alzheimer's Prevention Clinic,
a Walcott Medicine, which Richard Isaacson launched, I think it was 2013.
most of our patients come to us because they're really scared that they may be experiencing
early onset dementia. And we go through a series of tests, and more often than not,
these are midlife women. What they're describing could be attributed to midlife changes,
including menopause. In some cases, clearly, there's an increased risk of Alzheimer's. There
needs to be mitigated. At this point, what we do for our patients,
Alzheimer's prevention is predominantly behavioral. So the ABCs, if you will, of Alzheimer's prevention
are lifestyle-based and then include managing medical conditions like high blood pressure,
insulin resistance, diabetes, obesity, all the cardiovascular risk factors. That can be done with
a combination of tools that leverage diet, exercise, stress reduction, sleep,
hygiene and whatnot, and also medical pharmaceutical routes when appropriate.
For women specifically midlife, I do think that having a serious menopause conversation is important,
not just for the short term, not just for the symptoms of menopause that one may be
experiencing today, but because the research is moving so fast. And I do feel,
As a midlife woman, I do pay attention to all the things you mentioned.
I am extremely conscious about my lifestyle and so disciplined, it's almost ridiculous.
Like this morning I couldn't find anything that I wanted to eat for breakfast or I just skipped it.
Because I'm not going to have a bagel for singing in the morning.
I want to have all those answers, but we need to also wait for the research to get done
so that we can then give women the right information.
It's the first principle of medicine, right?
First of all, do no harm.
And I think as long as lifestyle is concerned,
it is important to be very consistent.
And I think a lot of people, especially in this country,
try a lot of different things.
And then maybe those things don't work out.
They feel like they're not working out
and they switch from a keto diet to a veganism
and then go back to something else.
And I think consistency is important.
We do know that some very specific patterns are conducive to brain health.
And I think it's important to embrace them and stick with them for long enough time.
Like exercise, yes, but there's so many different ways to exercise.
That at least we have information that is specific to women, including women in midlife,
which is the association between intensity and gains, where gains,
where gains is not building muscle mass, but more like for health, overall health,
follows almost like an inverted U shape, where moderate intensity exercise, if performed frequently
enough, is conducive to the greatest gains, which I think is the zone too.
It is, but it turns out to be a little bit more complicated in that intensity matters and
duration matters, and it depends on how much time an individual has. And so the less time an
individual has, the more they have to prioritize intensity. That makes sense. The more time they have,
the distribution curve actually skews to lower intensity. But if you're in sort of a sweet spot in
the middle, then you're probably going to get the most bang for your buck at a modest level
of intensity, which might actually be even north of zone two. I'm overdue for a discussion on this,
because I feel like sometimes I talk about this and I ironically create confusion by not being
nuanced enough, which is a rare accusation for me.
I can't imagine.
So I think I need to provide a little more nuance on that.
But you know what I take from what you're saying, Lisa, which I agree with, by the way,
that is the single most important thing to do is maximize the known lifestyle levers
because it buys us more time.
And I am more optimistic today than I was five years ago about treatments for dementia.
Yes.
Five years ago, I was in a state of despair.
I thought this is a disease that will never be treatable.
I really believe that once the proteins started folding in the brain, like there was just
nothing that could be done.
And now when I look at treatments like clotho and just full disclosure, I'm a co-founder of a company
that is trying to develop a clotho injection.
And I look at the potential around GLP1 agonists,
and I look at the ways that we're getting better understanding of hormones,
and I look at other molecules, exercise memetic proteins.
I'm starting to think, we just need to hold on long enough.
Like if you can delay the onset of something by 10 years through all of these modifications,
that could be the difference between a normal cognitive life and a cognitive life that
cut short. And unfortunately, that's not the answer to the person who's 75 today who has dementia.
And that is tragic. And I wish I could say, don't worry, tomorrow we're going to have something
that's going to reverse this. I don't believe that personally. Maybe that makes me a pessimist.
But I absolutely believe that in a decade, we're going to have things that are going to make a real
difference. And therefore, if you're sitting here and you're 60 years old and you can keep checking all
those boxes, as you said, that could be the difference between you being the candidate who
gets the rescue before you're fully in the throes of the disease versus not.
I completely agree. And whenever I mention lifestyle and people are always, oh, yeah, sure,
but really it's so important and not that many people are as consistent throughout the years.
And when we talk about brain health, I think it's important to understand that the brain is not the same as the rest of the body and people are so used to seeing results quickly.
Within a matter of weeks, you can lose a couple of inches or you can grow muscle.
The brain is built for stability, whereas the rest of the body is built for change.
If you want to make an impact on your brain cells, you need to hit them frequently enough and long enough that that you're not.
change is going to be recorded as an epigenetic mutation, or is an epigenetic change,
or is something structurally permanent. And that, thank goodness, takes a really long time.
Thank goodness, it's a long time on the bad end. Yes. But that's the price you pay on the good end.
Yes. So the good news is it takes a while to cause damage. The bad news is it takes a while to create
resilience. Yes. But you can create resilience, which I think needs to be emphasized that this
is not like a woo-woo, which you wash a thing. It really can give your brain cognitive resilience
and brain reserve, which is what you want in the end. You want your neurons to be strong.
And you do that by having your body, for instance, move. We know the movements produces BDNF in the
brain, produce iridine in the brain that support the health and growth of your dendritic,
your synaptic extensions, for instance. We know that if you're
reduce inflammation, if you reduce oxidative stress, which is something you need to do from the
outside, your brain will do better, will age less. So these are all things that are very realistic
that every one of us can do on a daily basis. We can all make good choices that support the health
of our brains in the long term or not. And then it will show, it may not show today, but it may show
10 years from now. So this is really the time, I think, to invest in brain health. Because at the end of
today, we all want our cognitive lifespan to match our lifespan. This is what we're trying to do.
And then we do research as fast as we can. I was so happy to have the opportunity to launch care
because it's very high-speed research that should deliver in three years. I was joking with my
daughter that by the time she goes through puberty, I may be going through menopause. And I want an
answer by that. Yeah. So hopefully. I'm really grateful for the grant you have. And I think,
frankly, I did the math on this once. I believe that the entire Manhattan project in today's
dollars was about $3, $4 billion, which, by the way, that's a paltry sum of money for what it
accomplished, right? I mean, it changed the course of history for all it's good and bad. But,
that $3 to $4 billion is a trivial investment for the United States government. I would love to
see an investment of that size to tackle this question because if you think about what you're
going to be able to accomplish in three years with $50 million, can you imagine what a,
I hate to use the term because it's so overdone, but what a moonshot would look like here.
And look, it might have to just come from the private sector as it has in your case through
the welcome trust. But nevertheless, I'm sure there's somebody out there listening who's
thinking about what this type of a moonshot could look like.
That would be wonderful and scientists from all over the world are ready to do this kind of work
and really hope they would be able to do more.
Well, thank you for taking time away from both your family and your work to come out and visit
and share your insights with us.
Thank you for your time.
I appreciate it.
Thank you for listening to this week's episode of The Drive.
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