The Peter Attia Drive - #277 ‒ Food allergies: causes, prevention, and treatment with immunotherapy | Kari Nadeau, M.D., Ph.D.
Episode Date: October 30, 2023View the Show Notes Page for This Episode Become a Member to Receive Exclusive Content Sign Up to Receive Peter’s Weekly Newsletter Kari Nadeau is a physician scientist with expertise in treating... food allergies. In this episode, Kari first explains the fascinating workings of the immune system, exploring how it adeptly defends against bacteria and viruses but how the same system can lead to food allergies. She proceeds to explore the complexities of food allergies, detailing their typical developmental patterns, underscoring the significance of preventative approaches like early exposure, and highlighting the potentially life-threatening nature of severe food allergies. Kari illuminates the latest advancements in immunotherapies that not only mitigate allergy severity but also hold the potential to completely cure the patient. Additionally, Kari shares her concerns about the increasing levels of air pollution, elucidating its adverse effects on health while providing valuable suggestions for reducing exposure. We discuss: Kari’s motivation to study food allergies [4:00]; Overview of the immune system and the family of immunoglobulins [9:00]; How our immune system fights viruses, bacteria, or fungi, and some exceptions to the rule [13:00]; Why our immune system is generally better at fighting viruses than bacterial infections [18:45]; Differentiating a food sensitivity from a food allergy, and a discussion about celiac disease [25:30]; How food allergies develop, why they can be lethal, and factors contributing to the uptrend in food allergies [35:45]; The role of environmental factors in the onset of food allergies and strategies for prevention [50:15]; How immunotherapy helps to overcome, and even cure, food allergies [1:04:15]; Can immunotherapy work for environmental allergens like pollen? [1:24:00]; Air pollution: impact on health and tips for reducing your risk [1:25:30]; Resources for those wanting to learn more or find clinical trials related to food allergies [1:40:45]; and More. Connect With Peter on Twitter, Instagram, Facebook and YouTube
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Hey everyone, welcome to the Drive Podcast. I'm your host Peter Atia. This podcast, my
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My guess this week is Dr. Carrie Nadoo.
Carrie is the chair of the Department of Environmental Health at Harvard's School of Public
Health, a professor of climate and population studies and the interim director of the
Center for Climate Health and the Global Environment.
Carrie's research focuses on the study of immunologic mechanisms involved in the causes, diagnoses, and therapy for allergies
and asthma. Carrie earned her MD and PhD from Harvard Medical School in 1995, completing her
doctoral work in biochemistry and immunology. She's a member of the National Academy of Medicine
and has co-authored the book The End of Food Allergy, the first program to prevent and reverse a 21st century epidemic.
In this episode, we talk about how the immune system works.
When it comes to fighting bacteria and viruses,
now you might think, well, what does this have to do with food allergies?
Well, of course, it's because the same immune system
that correctly helps us fight off bacteria and viruses
incorrectly gets wound up when it comes to food allergies.
So, unfortunately,
you do need to understand how the immune system works in the correct way to understand how it can
go rogue. So, from there, we deep dive into food allergies and we distinguish them from food
sensitivity. So, I think many people listening to this will have some sort of food sensitivity,
and of course, that's also potentially mediated by parts of the immune system. We'll talk a little
bit about that. But really, what we want to focus on are true food allergies. And this can range from mildly
inconvenient to outright life-threatening and debilitating. It's really that latter area that we
want to focus on. So we talk about early exposure. We talk about what sort of immunotherapies
are available. Many people, for example, listening to this will understand that there are certain
people that have peanut allergies. If you have a peanut allergy and you don't carry an
EpiPen, you can end up losing your life. Well, I wanted to understand why that's happening.
I want to understand what parents might be able to do to reduce the risk of that developing
in their kids. And of course, for those who already suffer from those things, I want to understand
what are the immune-based therapies that can effectively
take a person who, in the presence of even microscopic quantities of those allergens, produce
a lethal anaphylactic reaction, and how can immunotherapy make those people safer in
that presence?
And this is the kind of work that Kerry has been doing, and for that reason, I wanted to
have Kerry on for some time.
We also talk a little bit about air pollution, which was a real bonus for this discussion
for me.
Because when I reached out to carry initially, I thought we would only talk about food allergy,
but as you may have heard me talk about on previous podcasts, I have a real interest in
getting deeper down the rabbit hole of air pollution, specifically PM2.5s.
We go into all of that in this episode, so be sure to stick around for that part as well.
So without further delay, please enjoy my conversation
with Carrie, they do.
I don't remember the last time we were together in person,
but I feel like it's been probably eight years or so.
Is that possible?
I think so.
It's been eight years and lots has happened, Peter, especially
of COVID, so it's nice to see you again. Yeah, yeah. I've always appreciated the
amount of time you used to make for me when I used to wander into your lab.
It's Stanford just to pick your brain. Again, I've always thought that the work
you were doing was so exciting, and I know that it ties into so much about
what people are interested in around
food allergies, even to some extent food sensitivities.
And I think also even based on your current role, you've now left Stanford, you're at Harvard,
I think it's also very interesting to discuss air pollution.
I think this is probably something that isn't getting enough attention with respect to health.
I know it's something I feel woefully deficient in my understanding, though I try
to pay attention to my PM 2.5s. I'm not sure what to do with the information sometimes.
So with all that said, let's maybe just give people a really quick background on why you're
the person to be talking about this. So you're an MD PhD. What did your PhD dissertation
focus on?
Yeah, I was really excited to my PhD in biochemistry, so I learned a lot about
toxicology and biochemistry, and I did my PhD in parasitology, actually. I worked on an enzyme
in a parasite called the trapanosome, which causes African sleeping sickness and another disease
called chagostasis. And I loved my work there because we were able to go to the very minute levels
of understanding of a chemical entity to be able to create a drug to target that entity,
to help people with that disease. So it was a great PhD, I loved it, and I also did that
at Harvard under Chris Walsh. So that's what my PhD was in, and then I did other work
in immunology and animal models as well.
And then your pediatrician by training clinically as well.
What led you then to study the field that brought me to you as a matter of interest a decade
ago around the field of food allergies?
It's all a build, Peter, and we think of our careers, all of these things mesh, but there
are certain nexus points in our careers.
And I believe that typically for me, it's been a patient
and it's been an inspiration to be able to move forward
in a field like food allergy.
So I did my MD training also at Harvard
and then trained in pediatrics at Children's Boston
as well as at Stanford.
And with that, I had the opportunity to become a fellow
in a field that I loved, which was allergy, asthma, and immunology.
And I had done a lot of immunology work when I did my PhD in parasites, because parasites are killed by the immune cells.
And especially this little molecule called IgE that tends to kill parasites, but it's not so great for allergies.
So this yang and yang of this molecule in biology as an immunologist
for me was also really interesting. But fast forward, I was a fellow on the words and I was
about to see a patient that I was being asked to consult on for milk allergy and he was in the
ICU and I was told that he had just drank a cup of milk and I'd had a bad reaction.
And by the time I arrived there, the unfortunate event of his death had already occurred.
His parents were already being asked to give consent for him to be a liver donor.
And so I took care of the person that was the liver recipient who also had a milk allergy. That really gave me pause, and number one inspired me,
and really initiated my efforts in food allergy
to understand the role of this molecule called IgE,
the role of the immune system, how food allergies
get started in the first place,
how in the world did a child with food allergy
who died then give his same food
allergy to the recipient of his liver.
So all of these things really started to catalyze my curiosity and I felt very blessed and
lucky at the time to be able to be in a lab.
And when you're a person that has this training, I feel that we're obligated in a way to be
able to use that training to best help mankind
and to best help those questions that parents ask us.
And so at the bedside of this particular young child that had died, unfortunately,
Dodo and Milk allergy, I'll never forget his father trembling asking why the Epipan
didn't work at the time, what can we do to help children in the future
never have to die again? And so I promised that father that I would do the absolute best to
prevent further deaths in children and adults with food allergy as well as help really make sure
that we educate about the use of injectable ep-and-effort devices and how to best use them to prevent
deaths to food allergies.
So that's my why.
And ever since then, I've always wanted to really help out
in this field.
It would be impossible, I think, for us to have this discussion
at the level of depth that I hope we can have it without
the listener understanding how the immune system works
under normal circumstances. You've already alluded to
one of the immunoglobulins, IgE. Does it make sense? You think to talk about the family of the immunoglobulins,
what they're there for, how we acquire them, and how they normally serve as well?
Sure. So we have certain
proteins in our blood that help protect us.
And that's what they're meant to do, and that's great.
And they exist in different concentrations, just like in a milkshake, you have different
proteins that exist in different concentrations.
And they're all there for nourishment purposes, sometimes for taste too.
But in our blood, the proteins in our blood that constitute immunoglobulins are
really helpful. We learned a lot about how important immunoglobulins were to protect
against COVID, for example. Everyone wanted to know their quote-unquote titers, and what
that means is immunoglobulin. So the main class, IgG immunoglobulin, Those are very protective. Those are proteins that are in high amounts,
and they float in our plasma, and in order to be really healthy, when we are healthy,
we have healthy amounts of immunoglobulin to protect us. The minute that someone is maybe
what we call under a drug like steroids or under other drugs that could affect your immune system that also reduces the amounts of these immunoglobulins.
So we know that these immunoglobulins are really important,
it's important to have good concentrations,
not too high, but good concentrations
and immunoglobulins in general
help protect us against infections
and they also help protect us against allergies.
Then there's another complimentary immunoglobulin suite
that doesn't just stay in our blood.
It also gets into our organs
because you want to protect all of the surfaces
around your organs as well, not just in your blood.
The blood is great, that's the highway
and to so many organs,
but it shouldn't be nice to have some immunoglobulin
protective molecules
that actually sit around your organs and help. So for example, that class is called IGA. The other class
was IGG. This class is IGA and we call that the secretory class. And that's also helpful in our saliva,
in our gut, especially women who are pregnant, they secrete it after pregnancy and their breast
milk. So these are things that we've learned as immunologists that really help protect
and enable health. When people are missing IgA, for example, if they don't make any IgA,
they actually have allergies. And the other immunoglobulin class that I'll talk about is called IgM. And IgM is what I call the Marines.
That is the type of immunoglobulin cell, IgM,
that goes out there first call.
They're there to fight infections,
but then the immunoglobulin G proteins come in afterwards,
and they stay for much longer.
IgMs don't stay for very long.
The final class is IgE.
So IgE, unfortunately in the past,
when we were in the field and fighting animals
and being out there in the wild,
IgE was very hopeful to fight parasites, for example.
It was very specific to parasites.
And now, unfortunately, IgE still exists in our blood.
It represents .005% of all the immunoglobulins in our blood.
So of all those classes, the IgE is the least represented.
It's the least concentrated, but it is unfortunately the most potent.
And I call it the match that lights the fire behind allergies.
And you think, well, why do we have such a skewed response?
Why do we still have this prehistoric molecule floating around in our blood that truly all
of us consider a bad actor?
And we think it's because of that prehistoric need to fight parasites, but importantly,
now fast-forward thousands and millions of years, it's still there and it unfortunately
has a skewed response in allergies.
So maybe just explain a little bit more about what the immunoglobulin does.
Let's just talk about it through the lens of an infection.
So what happens when you get a bacterial infection and what happens when you get a viral infection, and what happens when you get a viral
infection, those are two sort of different things, but yet they both kind of still involve
immunoglobulins, even though we think of one of those threats, the viral illness, being
more dealt with through the cellular immune system versus the human.
Maybe even you can explain what cellular versus human or immunity mean.
So, in general, what I'll explain today is how our immune system fights a virus or a
bacteria or a fungi, but there's always some exceptions to the rule, but I'll just talk
about the general pathway, and that I think helps people conceptualize what happens.
And I'm always amazed at the immune system, and there's a lot we still don't know.
So in all humility, as an immunologist, I learn every day what I don't know about
the immune system. But what we do know is that when something attacks us, like a virus,
like a bacteria, like a fungi, that enters into our lungs, our gut, our nose, those unfortunate
microbes, they know how to get into our body. So they get into our body and
they go through either the skin or they go through other organs. And then on the other
side is waiting for them a whole panoply of immune cells ready to attack. And so if a virus
gets in through the body, now typically it doesn't, we try to fight it right away,
but sometimes it does. And so, let's say a virus or a bacteria or a fungi gets into the body,
gets through our typical first layer, like a skin barrier, and it gets through. Then right away,
we have these cells called macrophages, and they literally just eat up things. So they bind on to the
virus or the bacteria or the fungi, eat it up, and then eat it up into small little bits.
And then they expose those small little bits on their surface, and then with those small
little bits on the surface, they actually then become the educator pieces for another group of cells called the T cell.
And that's what we call the cellular system.
Macrophages, antigen presenting cells, these little bits are called antigens.
And then the T cell comes along and says, huh, that's interesting.
I'm going to teach myself the T cell.
I'm going to teach myself how to operate within these little antigens.
What are these things?
How do I train the immune system to get rid of this thing?
So then the T cell says, all right, I'm going to start to understand what this new organism
is that just attacked my body and I want to fend against that.
I don't want that bacteria or that fungi or that virus in this body.
So the T cell becomes what we call a memory cell.
A memory T cell then teaches another cell called the B cell.
The T cell interacts with the B cell.
The B cell then starts to make immunoglobulins.
And that B cell makes the immunoglobulins.
Thanks for the teaching cell to train that B cell
to make the immunoglobulins thanks for the teaching cell to train that B cell to make the
immunoglobulins for the exact little antigens that that virus made or that bacteria made
or that fungi made.
So you have this little B cell.
B cell makes these immunoglobulins and then they bind to the antigen.
Now you have specificity in your cellular and your humoral immune system.
So the humoral comes from these antibodies that float in the blood,
and that's what we call the humoral immune system.
It's not attached to a cell, but it was made by a cell.
So those humoral related antibodies attach to the anagen,
and then another cell, again, back to that macrophage eating cell, that macrophage,
then recognize this whole system, and we call it antibody-dependent cell killing.
So now that the antibody recognizes this virus, and it recognizes all the viruses
that maybe you had across your whole gut, or your whole lung for that one specific virus that recognizes as foreign, and then these other cells called the macrophage come
back again and they chew the whole virus up and eliminate it from your body.
So that's a long system.
I just talked about things that take days to respond to, months to respond to.
And it took many years of science to figure that whole pathway out.
This is not something you learn at the bedside with some story your mom tells you.
This is a lot of science.
And that science has allowed us to understand the immune system
to number one, provide vaccines to people.
Because of the same system, we one, provide vaccines to people.
Because of the same system, we now know how to make immunoglobulins because of our vaccines.
And we know how long they can last for.
These memory T cells, for example, can last up to 100 years.
So I love the cellular, humoral part of the immune system because it's very instructive to fight microbes.
Unfortunately, it doesn't fight all microbes.
Some microbes need a little help with antibiotics,
with antiviral.
So the story that I showed you today isn't perfect.
So that's why you need to see the doctor.
You need to have other medicines, for example,
to try to help your immune system fight infections,
because there's holes in the immune system,
and we need to help it.
Why do you think our immune system is on balance so much better at fighting viruses than bacteria,
at least in terms of the clinically relevant ones? In other words, very few people will take an
antiviral drug in their life outside of a handful of unusual circumstances. Most people will go through
life with their immune system doing a very good job of
lopping off the head of two to three viruses a year that actually reached the
threshold of clinical significance. And yet most people don't go more than two or
three years without actually requiring an antibiotic to aid in the destruction
of a bacteria. Do you have a sense even teleologically, why that's the case?
This is an excellent question teleologically, as well as from an evolutionary point of
view, as well as really understanding how did viruses start in the first place?
How did a bacteria start in the first place?
What do they need to grow?
From the perspective of the virus, why do they need us?
From the perspective of bacteria, why do they need us?
Same thing for fungi. So when you think about a virus, they kind of flip from one organism to the other. They sometimes
can exist out in the wild. They don't necessarily need us, but sometimes like HIV, it needs some
of ourselves to be able to live inside, to be able to keep proliferating. So I'd say in general,
to be able to keep proliferating. So I'd say in general, there are some viruses that are, of course, very severe,
and they can cause fatal disease.
So on the spectrum, like you said, Peter, typically though, viruses aren't as bad as bacteria.
We don't typically need an antiviral because we can fight viruses.
It's a great question, though, because viruses can mutate in our body
like we saw with COVID,
and then all of a sudden we can't fight them as well.
But our body, because we make things like mucus,
that we have fevers, that we have these immune cells
that are really programmed to attack quickly,
they can chew up the viral proteins much better
and much more easily to destroy a virus
because a virus is really relatively speaking
compared to a bacteria is very simple.
So it doesn't take a lot for the immune system to say,
listen, didn't take me a lot of energy to wipe that out
because that virus is made out of simple things.
It's basically made of really simple Lego blocks.
But then you have the bacteria that's made of an enormous amount of Lego blocks,
and it is much harder to destroy that.
Same thing with fungi.
They are much more complex organisms.
They're made of many different materials,
so that it's harder for our immune system to kill every piece of the part and get rid of it.
So there are certain viruses though that we still get infected with, but that they don't cause fatalities.
So they've learned to kind of use us and then move on because they want to just keep proliferating, but they don't necessarily stick around for our immune system to kill it. They just keep being contagious.
So viruses are much easier at hopping from one person to the other.
Whereas bacteria, that's not so easy because they're heavier.
It's harder to take a bacteria and give it to another human.
With bacteria, also think that we have this bi-modal relationship,
and I want to make sure all your viewers know that there are some bacteria that are actually really good.
We don't know any viruses in particular that are actually good and beneficial for us, but our body lives with bacteria.
So I think our immune system has a little tougher time to know, what is this? Is this a good bacteria or just a bad bacteria?
So that's maybe also why it's easier to kill viruses
than bacteria.
We've learned to be tolerant to certain bacteria,
but not others.
And some of them escape our immune system
if they are bad bacteria because they know
that we have this tolerance to other bacteria
that are in the same class.
But it depends on where that bacteria is.
It's totally fine if this bacteria is in your gut,
but the minute it gets into your blood,
if it's the same bacteria, it's actually really dangerous.
So that's where our immune system has to figure out,
is this a bacteria in the gut?
I'm okay with that, or is this bacteria in the blood?
I'm not okay with that.
And bacteria tend to divide so fast,
just like viruses that for both virus and bacteria, these are difficult.
But when we talk about vaccines,
we luckily have used science for both
bacteria-ly mediated diseases,
as well as viral mediated diseases.
So it's really thanks to vaccines
that we've enabled the immune system to get boosted
for both types of infections.
But it's always hard to predict mutants,
to predict different infections that one would have.
But I think that your question is an excellent one.
I don't have all the answers.
It's funny.
I think there's an analogy there with cancer,
which is what makes cancer so challenging
for the immune system is that it's basically self
and it's very good at masking its non-self
entities. So even though it's genetically distinct from a non-cancer cell, it's very good
at hiding the neoantigen's. Sometimes they're not even coding proteins. In other words, sometimes
the mutation in the cancer cell doesn't lead to the generation of an antigen and therefore it can
go completely undetected, masquerading a cell.
Exactly.
And that's the sad part about cancer that are memory T cells that are supposed to be there
to protect us and monitor and make sure that any cancer cells could be killed right away.
Sometimes it's faked out in a way.
And that's where I think the car T cell therapy, a lot of the T-cell mediated, immune mediated therapies now, can enable and better instruct our immune
system. But that's not perfect either. So you're absolutely right, Peter. This ying and
yang of having the immune system do all that it can. But we can't expect so much. And one
of those areas in order to help our immune system.
We found in COVID, for example, people that slept better, people that ate a healthy diet,
people that exercised in general, their immune system was healthier.
So I think when we talk about these public health issues and COVID was the x-ray into our
soul of public health and public health
processes, but in that we learned a lot about what it takes to be healthy and what it takes to
have a healthy immune system to better fight viruses and microbes.
I'd like to actually come back to that because it's such an interesting topic. It's one of those
things where it seems obvious and self evident that all of those things are true. I think I would
also add stress to that. I think it's hard to understate the harm that hypercortisolemia and are ramped up sympathetic
system to having the immune system if we have time, like to come back to that and probe
a little bit about what the mechanisms are for that.
But what I really want to get to is now pivoting to this idea of what a food allergy is.
And I think it would maybe be a good idea
to differentiate between a food sensitivity
and an allergy.
Is that the right terminology that you would use?
Yeah, that's excellent.
So for a lot of my patients, this comes up all the time.
And I am inspired by how much knowledge my patients have,
they come to the table, or they don't come to the table
with knowledge already that they received from the internet or podcasts such as yours and others, as well
as just reading in general.
And finally, asking questions is so important.
If you don't know something, feel free to ask your doctor these questions.
This is critical, or a healthcare provider, or anyone.
But I've always been really
interested in this difference between food sensitivity and food allergy. So food sensitivity
means that you can bite a food and you're typically going to react to a chemical in that
food. Perhaps a protein, but it's mostly a small molecule, maybe a sugar, maybe a fat, maybe a spice.
And with that, people can get headaches,
people can get bloating.
Typical food sensitivity is lactose intolerance.
When you drink milk, for example,
one of the sugars in the milk is called lactose.
And if you don't have an enzyme in your gut
and in your body called lactase, you can't break down that sugar.
So that's why people take lactade milk, for example.
And there are some ethnicities that don't have that enzyme, so there is a bunch of people that in a certain population
really can't drink cow's milk because of that lactose sugar.
So that's a food sensitivity. People get bloating, people get headaches,
but they're not going to have a fatal reaction.
And just to be clear, Carrie,
the immune system is not reacting at all
in that state of a food sensitivity.
It can react.
Would you have enough lactose
and you keep drinking lactose
and your body says,
I don't like this sugar.
Why are you keeping giving me the sugar, I can't break it down.
What happens is it sends its immune cells
to try to break it down,
and that causes inflammation.
So, some people, when they take preservatives
as well, certain emulsifiers, these chemicals,
they can get into the body,
and our immune system doesn't like it.
It's foreign, a lot of our preservatives and unfortunate and most fires that hasn't
been seen by the body before, it's not something that's natural, so for some people their immune
system does react.
But it reacts with a different pathway than an allergic pathway.
It reacts with sometimes immunoglobulins, IgGs.
It reacts with something called a cytokine
that isn't great because it causes chronic inflammation.
So we do have some chemicals that are
associated with food sensitivities
that can activate the immune system
in a way that's not great for the human body. And so that's why if
someone does have bloating or headaches or they can still have rashes for food
sensitivity, you can still have rashes in your skin with certain chemicals that
you eat in foods. And if that's happening to you, then get yourself tested
because we want to make sure it's not a food allergy. But importantly, as we
don't have cures or therapy for food sensitivities,
we often will tell people, please avoid that food.
I have someone that has terrible bloating with mushrooms
because it's a certain chemical in the mushroom that bothers her immune system.
Why? I don't know.
But the minute she even smells the mushroom,
she gets this immediate reaction to her gut that causes her to vomit, but it's not a food
allergy.
It's an intense reaction of the nervous system to that food chemical.
Sometimes we see people who have kind of a low grade elevation of their C-reactive protein.
And we really like to see the very sensitive version of that below one. You'll
see these people that otherwise seem reasonable, but their C reactive protein is somewhere
between two and three. So it's two to three times higher than it should be. And it lingers
in this state for a very long period of time. There's clearly no infection that's been
brewing for that long. You query them a little bit more and you sort of realize that it
might be attributed to food. And I would say in my experience, the two foods that far and away account for the majority
of this, as determined by simple elimination and watching this go away, are first wheat-related
products and secondly dairy. So when I say wheat, I don't mean celiac disease, which I'd like you to explain
as a contrast, but rather some sort of low-grade sensitivity. And so what you're saying is there's
nothing going on in the IgE pathway, but there is something going on in the IgG pathway.
And again, C-reactive protein is made by the liver as basically a calling sign to the
immune system. You're sort of seeing, for lack of a better word,
you're seeing the sirens going constantly, which is CRP.
We can measure what we can measure.
And CRP's been around in our doctor's handbag for a while.
And it's actually a really good beacon like you
analogized because it does tell us something's going on there.
And it is a window into what's going on chronically
in the immune system.
So, yes, when I test the CRP levels in my patients with food sensitivities and they're
not able to eliminate that specific chemical, then I see the CRP in that range where I call
it simmering immune inflammation.
It's not a fire, but it's simmering.
And the problem with food
sensitive disease is I don't have a great way to diagnose them. I don't have a skin test.
I don't have an IGE test. I have to do elimination, and then I follow that CRP level until it can
try to get to zero. But that's not easy, because some of these chemicals are so systematically in our
food supply that it's hard to get rid of. So that's food
sensitivity. And I agree with you, milk and wheat are some of the most associated
culprits in food sensitivities, especially in the US. And that might be for a lot of
different reasons in terms of how we process and how we have detergents in our
milk and the same thing with our wheat products. It isn't us through the same
wheat that we ate when our ancestors ate it originally.
So maybe there's a lot of reasons for that.
But let me bring it to wheat.
This triangulation of food sensitivity,
siliac versus food allergy, and we'll get to food allergy.
But let me just transpose this interesting comment
you made about food sensitivity versus siliac.
So siliac is a very specific type of food sensitivity.
And it has a very marched out pathway
of immune reaction to that wheat,
and that wheat protein and specifically
is the gliadin, which is a part of the wheat.
And celiac disease also has genetics associated with it
and other autoimmune disease with it, as you know.
But that reaction is to a very specific part of the protein of the wheat,
and not everyone with a food sensitivity wheat has ciliac,
and certainly not everyone with ciliac will have the same type of reactions to wheat as the food sensitivity people do. Now, celiac, we take extremely seriously
because it can result in long-term problems with your gut.
It has its own special category,
but you shouldn't call yourself someone that has celiac
just because you have a food sensitivity to wheat.
There's a specific diagnosis that needs to occur
with a professional that specializes
in gastroenterology or in ciliac to be able to know if I truly have ciliac disease.
And if you do, then it's important to test family members and to really get under the
care of a good doctor.
Are we seeing any increase in the prevalence of ciliac disease or are we seeing any increase
in the prevalence of celiac disease, or are we seeing any increase in the prevalence
of food sensitivities? It certainly seems like it as a nonepidemiologist who pays attention
only to the world around him, but it seems like more and more people are saying, boy,
I'm really struggling to eat, fill in the blank.
On one side, I think that people are becoming more knowledgeable about this,
and they also feel they have agency as they should when they come to the doctor to be able to say,
I think I've a sense to me this food, and people take them seriously, and that's good.
And we need that because these symptoms are serious, they're affecting someone's quality of life,
we need to help.
And in the past, maybe they were poo-pooed and said,
oh, I can't help you, so I can't do anything about that.
But now, people like you and I can say,
well, let's test that CRP.
Let's see if we can be better detectives
and really try to help you,
because in the end, we want to help quality of life.
So yes, people I think are feeling more and more like
they can talk about it as well as
Celiac disease, but importantly, we have better diagnostics.
So I think that we as a community have gotten better at really diagnosing Celiac, so I think
that's another good reason why there might be more people with it.
I think people also are seeing an increase in food sensitivities in Celiac because of the
different ways that we just processed, because of the different detergents now and unfortunate
chemicals that are put into our foods.
So I think we have to be careful about that and hopefully the food industry and agriculture
will think carefully about those chemicals before they put them in because I've seen an
increase.
And when I tell people to not eat foods
with those chemicals in them,
they tend to not have food sensitivities.
So I think that perhaps, and I'll be interested
in your comment to Peter,
that might be one of the reasons
why there's more food sensitivity,
although I can't put my finger on it.
I feel like there's something going on,
and I know we're gonna talk about this also
on the food allergy side,
where I think we can probably speak with more clarity.
Let's not talk about that,
because I think this is the area
where let's just start with some statistics.
Do you have a sense of how many people in the United States
die in a year as a result of a food allergy?
Like the tragic story you told?
Yeah, thankfully it is extremely rare.
The reason why I hedged is because nowadays
with the codes in the emergency rooms
and understanding if someone died from a food allergy,
some emergency rooms, some intensive care units,
they're able to ascribe or attribute a certain reaction
exactly to a food.
Sometimes it's a little blurry.
So it is very rare.
There are people around the country in Michigan,
as well as in Chicago, that are epidemiologists.
I am not an epidemiologist,
although I love to work with epidemiologists.
So it is very rare.
People have claimed that it's one of the reasons why
people can have a fatal attack is because
they don't have access to an epi device where they don't have anticipatory guidance for what to do during a reaction.
So in my mind, any fatal reaction could have been avoided.
And that's why I learned from that case, even though the fatal reactions are rare, and
that's good, they could be avoided.
And when we learn about them, and I learn about one per month in the US,
and it's very sad every one of those stories
comes with a tragedy that's heart-wrenching.
But it compels me to keep trading my patients
on making sure they have two injectable epinephrine devices
at all times, making sure they know how to use it
within a minute, making sure that if it doesn't help,
their symptoms within a minute, making sure that if it doesn't help, there are symptoms within a minute that they use another right
away.
That it's okay to use an injectable epinephrine device because that's the only thing
that can actually prevent the unfortunate death.
And so I think the numbers right now in terms of death rates are getting lower, which is
good, because people are understanding more about this disease, and the communities understand that why we don't want to expose people unnecessarily to foods
that could kill them.
But in addition, there are increasing incidents and prevalence of food allergies in general
in the US.
So, for example, my colleague Ruchi Gupta out of Chicago, she published data that won in every 12 children in the classroom
in the US has a doctor's diagnosis of food allergy.
And we used to think that children would lose their food allergy, especially those with
milk and egg.
So it used to be thought even when I was training that children with milk and egg allergies
if they were under the age of five, there was like an 80% chance that they would lose these allergies by the time they were teenagers. But if it was peanut or any kind of
tree nut or shrimp or fish, they had an 80% chance of keeping it. Now, unfortunately, if you have a
milk or an egg allergy and you're under the age of five, you have a 50% chance of losing it.
So now we see more and more adults having food allergy. And the
other unfortunate thing, Peter, is that more adults when they get to adulthood are getting
food allergies. That's presumably about one in 30 adults will have some type of food
allergy when they're an adult. Whether or not that's because they had it when they were children
or because they gained it newly when they're an adult.
So the numbers are rising.
Luckily the death numbers are not,
but someone needs to do more research on that.
But this compels me as a food allergist
to really make sure that both children and adults
understand this disease and how to manage it. So let's talk about how this occurs. This compels me as a food allergist to really make sure that both children and adults understand
this disease and how to manage it.
So, let's talk about how this occurs.
Unless it varies by food, can we just pick a very specific example like a peanut?
That's great.
We talk about peanuts in the US, Peter.
I also want to get back to your original question about the incidence of prevalence of
food allergy.
It's occurring throughout the world.
It's not just a US problem. So peanut is also not just a US problem.
It's the UK or Australia, but not in Italy, for example.
In Italy, hazelnut is number one in terms of the sheets.
In Japan, it's fish in China, it's milk.
So we can talk about peanut today,
because it's an example of how our immune system reacts
to something, but it's a very similar immune reaction to a child in Japan who has fish allergy or a child
in China who has milk allergy or an adult in Italy who has hazelnut allergy. I've seen a
spectrum of allergies. I've seen people that have allergies to cinnamon. I've seen people that
have allergies to orange pit seats. All of these have proteins in them, so people can actually become allergic to these proteins.
People have allergies to the tan in proteins
from grapes in wine.
So I'll tell about the story of the peanut,
but I want people to know that it's not just about peanuts.
And many people that have allergies to one food
have allergies to other foods.
So people also need to know that if they have a child with a
food allergy, expect that it's highly likely that that child will develop another food allergy as
well. So be super careful, but also super vigilant about taking your child or yourself to the doctor
to keep on getting managed and diagnosed. So you have a peanut. And we think that one of the reasons why people start to have food allergies, it's not genetic, 70% to 80% of the time, it's environmentally related.
It's not related to genes in the family. So when a baby is born, perhaps their skin is a little rough and a little dry, and there might be microscopic holes in that skin.
And that happens a lot now. A lot of children have dry skin, and we can talk about that another time.
But with that little dry skin, that means the cells, my two hands here, are cells called epithelial cells,
their skin cells that typically are connected, and then with a nice beautiful barrier,
but unfortunately the dry skin, they kind of separate.
And our body doesn't know how to deal with this separation too well.
It thinks it's like a mosquito bite.
It's like, what the heck's happening?
I have a little hole in there.
And so it reacts to these types of holes
as if it was a mosquito bite.
So all of a sudden in the air, you have dust that
might contain hazelnut protein or in this case peanut protein. And that comes settling in and it
goes through this hole. And our body has a very prehistoric way of dealing with this back to those
parasites. So it comes in by just passive aeration,
it drops down the skin, the body tries to pick it up,
and it tries to sense this,
just like I explained in terms of the immune system,
those macrophages are like,
what the heck is this?
Is this good or bad?
And then it says, wait, this is bad.
I'm not supposed to have food through my skin.
I'm supposed to have food through my skin. I'm supposed to have food through my gut.
So the cell takes it up and activates the allergic pathway because it thinks it's a parasite.
It thinks it's a mosquito bite. So what happens is it takes it up and makes this molecule called IgE from that B cell. So the food gets taken up, gets processed,
it teaches a T cell to interact with that food antigen.
And then the B cell starts to make IgE
against that very same food antigen.
So the next time that baby eats that peanut,
even if it eats it through the gut,
that little IgE molecule will have been made by the BSO
and it's sitting around in the blood
and then it will bind to the peanut protein that the baby eats.
And when it does, even though like I said before,
the IgE is a very small percentage
of the concentration of proteins in the blood,
it is such a potent molecule.
And what I call it, it's the match that lights the fire behind allergies.
So you have this peanut that otherwise for you and me, Peter, we would be able to eat
and we view it as nutritious. But in a person with a already given
allergic reaction to peanut, That IgE binds to the peanut
and then this part of the IgE molecule, my arm,
that sets into another part of a cell as a receptor.
So it docs into the receptor after it binds to the peanut
and then that receptor on the cell surface activates histamine release of the cell, and that
occurs within minutes.
So the histamine goes through the body, and within six minutes causes swelling, can cause
mucus, and that mucus can be in your lungs, can be in your eyes, can be in your nose,
and it also releases histamine, that cell releases histamine, and
that histamine because itching on your skin.
Very similar, so what would happen if you got a mosquito bite, you want to itch, you want
to get rid of that mosquito, in the same way the body is trying to get rid of that food,
but unfortunately you've already eaten it, it's already in your body.
And so you see these reactions via IgGE and they release histamines.
And in my mind, it's a very skewed reaction.
The body's trying to do something that it was meant to do prehistoricly, but it doesn't
help the person at all.
In fact, the histamine becomes so high that it can cause sometimes death.
And within minutes, if you already have asthma,
if you already have lung issues,
that mucus can become so strong that it clogs up your lungs,
and that's what oftentimes can lead
to those very rare fatal reactions.
Or there's another chemical called Brida Kainin
that is released by these cells once that receptor
docs, when the IgE docs into the receptor, once that receptor tells the cell to release,
it releases histamine and it releases something called bradykainin.
That's another bad actor chemical.
The bradykainin can affect our blood pressure system that can lead to dizziness and can
lead to heart issues.
That's the second reason why people have fatal reactions.
So you can imagine when you take up an effron
through an industrial effron device,
that helps both the lung clear the mucus
and it helps the heart and the blood pressure stay strong
so that you don't have one of these
near fatal or fatal reactions.
But it all is linked to the immune system and how it reacts, and it's a very fast reaction.
It might be correct that the cell that's releasing the histamine is a massed cell.
I remember that.
Good, I was hoping you'd ask that.
So again, you're seeing both sides of the story for the immune system, the humoral response, which
is IgE, and now the cellular response.
So once that receptor gets docked into by the IgE, the cells that have that specific receptor
on them are called mast cells.
They're also called ESYNIFILES, and for those of you sort of listening, there's another
type of disorder called
eocinophilic disorders, which that's a different type of food allergy, but also
related, and then those mast cells exist in tissues, but they're not in the blood.
Eocinophils are in the blood. The other third type of cell is called the
baisifil. That's in the blood. So this is such a potent system because it's got
these cells ready to go. In the tissues, the mast cells, the muscles are in the blood. So this is such a potent system because it's got these cells ready to go.
In the tissues, the mast cells, the mast cells are in the skin, they're in the gut, they're in the lung,
in the eyes, in the nose, and then you also have these other cells floating around the blood that are also
secreting histamine and bradykina. And they're like the messengers across the whole system, and then you have the muscles embedded,
and the muscles can live a very long time in tissues.
So these basophils and eocinophils are in the blood, these muscles can live a long time
in the tissues, and that's why someone's reactions can build up over time sometimes, because
every time they eat that food or have that allergen exposure, their muscles are going to
remember because of
the immunoglobulins that bind to them.
Is the implication carry that each successive exposure gets worse?
As a follow-up to that question, how often is a person's first brush with a food allergy
a fatal one?
So we're only as good as our data.
We're only as good as epidemiological studies as well.
So typically, and this is again typical, there's always exceptions. If you learn about your allergies
before the age of two, those food allergic reactions are typically vomiting and hives, they're not
typically related to lung and heart. So babies, for example, although there are rare exceptions, toddlers and babies typically
do not have fatal reactions to their first ingestion of food.
But there's a lot behind this.
So if you actually dissect out who dies and who doesn't die from a food allergy, it's typically
people that already have a heart problem, already have a lung problem, or didn't get to the epiphen fast enough.
So, it would seem logical like you're inferring that with every dose that you take, your reaction
could get worse and worse with the same dose.
But it depends.
It depends, for example, if you're at elevation.
It depends if you already have a cold.
It depends if you have arrow allergies and you're allergic to a dog and a dog came by
you that week and you also ate a peanut.
So there's a lot that changed that, but yes, in general, if all things being equal, each
time you ate it, your immune system would remember more and more, and will boost up that response.
Now luckily, with therapy, there's a way to retrain your immune system, but that takes
regular interaction with the food every day.
Not every week.
If you take it every week, it actually boosts your immune system to become more allergic.
Take it every day.
So there's something to their circadian rhythm and the diurnal cycle which we haven't
talked about this yet.
But what I love about the immune system is it can be trained and you just need to know
how to train it and you can train it away from becoming allergic and train it into becoming
more protective.
I absolutely want to focus on that because it's, I think, the most hopeful aspect of all
of this, but I want to kind of go back and understand more
these environmental factors that are predisposing
children and adults to these factors.
So you mentioned one, which was dry skin.
I can only imagine after listening to this,
everyone is going to be lathering up themselves
and their children and we're going to make L'Oreal
or whoever makes nice skin lotion
very very happy. Are there any other factors that we've identified that seem to be predisposing people?
There's some factors if they're lacking they also predispose people so people have talked about
having good microbiome, good dirt and that helps decrease the likelihood of food allergies.
Children who grow up on farms for example have a really good exposure to animals.
They tend not to have as many food allergies interestingly enough, so I call that the dirt hypothesis.
Also, growing up with a lot of animals, like dogs, also helps reduce the likelihood, and that's probably due to the microbiode.
But importantly, this vitamin D seems to also play a role, so having enough vitamin D in your blood also decreases the risk of food allergies.
Being around too much detergent, that's what I call the dry skin hypothesis.
Unfortunately, a lot of our clothing being washed in detergents, our dishwasher, having
really potent, concentrated detergencies days, it's not getting rinsed away enough so
that the skin and babies, it heals so well,
but it is somewhat more sensitive than let's say adult skin.
And so because of that, they tend to have dry skin due to all these other issues
and let alone detergents, but also, anytime in life, whether or not you're a child or a baby or an adult. If you have pollution or tobacco smoke, that also causes dry skin
and itchiness and not just the skin on the surface, but also in your bodies. Anything that touches
the air has skin cells. So that means our lungs, that means our gut. So all of these features
that I talked about can affect the skin. We think that through the skin allergies can begin.
It's not the only hypothesis.
We also think that it's really important to make sure that when you look at your overall diet,
that you diversify that diet really early and often,
so that if you can take certain proteins and feed that to your children when they're young and have that diversity in the diet, that that can actually prevent the advent of food allergies later on in life.
So we talked about dirt, we talked about dogs, we talked about detergents, we talked about vitamin D, and we talked about diversity in diet. So I call that the Ds. But importantly, that dry skin
does seem to be a conduit by which food allergies start. But what I didn't say was DNA. And
that's important because a lot of parents, a lot of people will say, oh, my parents gave
this to me. Or this is in my gene, so there's no way I can do anything about that. And that's
not true. So there are certain allergies that can be passed
on from one generation to the next. But even those diseases, if you change your behaviors,
that can also improve and decrease the likelihood of having food allergies. So I hope that was
helpful. When people do listen, I hope when they do try to improve their skin barrier,
When people do listen, I hope when they do try to improve their skin barrier, if there is an emollient you can buy, try to stay away from the emollients that are based with petroleum
products or paraffin products or vaseline because what science has now shown us is that
because those are not natural to the skin.
Our skin doesn't really like wax or petroleum products, Vaseline is a petroleum
product. That tends to increase the bacteria on our skin and that can make overall the
skin inflammation worse. So try to choose products that have natural lipids that give the
skin back what they're missing. How does one look for that on the label? What would be the
signs of that? The natural lipids are like ceramide.
So I don't work for any companies.
I don't really know which companies have ceramide, but I know one company, Sarrava, has ceramide
in it.
So try to look for those emolients that actually replete the skin with what it is depleted
from, which are its natural lipids.
And then also try to rinse things.
Now we are in a water shortage and we have to be careful too,
with not using too much water, but if you can choose
ecologically friendly detergents, because eco-friendly detergents,
eco-friendly foods tend to be better for our own bodies.
And I'd love to know your own opinion about that, Peter.
But that's what I typically tell my patients.
Try to avoid detergents that are not eco-friendly,
because they're probably not so friendly to your body.
One of those questions about this,
any relationship with breastfeeding?
You mentioned it earlier with respect to IgA.
Does a child who's breastfed or not breastfed?
Do we see any difference in the incidence of food allergies?
There have been a lot of my colleagues in Europe that have tested this.
Now, because breastfeeding is now so much the standard that it's hard to do these studies now,
because the World Health Organization has recommended breastfeeding, which is wonderful,
and that's really important to start feeding incense other types of foods between four to six months of age. But in general, breastfed infants do do better in
terms of their overall gut health in terms of their overall health in
general, but it has not been shown definitively that by breastfeeding you can
prevent food allergies. But it is very helpful towards creating an overall
healthy immune system. So I, in
general, tell all my families, if you can breastfeed, please do. But the ulterior unfortunately,
is that some children, it's very rare, but they can have an allergy to a protein in the mom's
breast milk. So if your child does start to have issues with your breastfeeding, go see a doctor and
then see and make sure that they don't have an allergy to your own milk, but that's very,
very rare.
And nowhere in that discussion of the D's did I hear, I guess you talked about diversity
of diet, but I want to talk specifically about the antigen.
So what is the case for and against early exposure to nuts as a vehicle to prevent the onset of one of these allergies?
I think about the last 15 years, I feel like I've heard pediatricians go in various directions on this.
At first it was, and I think about the suit lens of my kids. So it's like sometimes we were told
absolutely don't let them see a nut. Don't have nuts in the house for the first two years
to, hey, make sure they're eating nuts and peanut butter.
So where are we today on that?
I agree, Peter.
It's been confusing.
There's been a lot of flip-flopping.
And unfortunately, there were well-meaning people 20 years ago
that made guidelines based on not a lot of data.
I think that people were seeing there was an increase
in food allergy throughout the world,
and that's probably due to many different things,
but they reacted in a way to say,
oh, we don't have enough science,
but we're really worried.
So let's just tell people to avoid those foods
and hopefully that can prevent this epidemic
from increasing.
And unfortunately, the minute those guidelines came forward,
and it was also during the time that I was raising my kids,
the minute those guidelines came forward,
you started seeing a hockey stick in the epidemic.
It actually started to increase in those countries
that did not follow those guidelines.
It stayed flat.
That's a very telling case,
even though it's not a randomized intervention, that says,
when you avoid foods at a young age, you paradoxically predispose to the allergy.
Exactly.
So let's talk about that.
The importance of guidelines, I agree, they're very important, and oftentimes guidelines are
made by people that really think hard, and they use the data that's at hand,
but we're only as good as our data. So, fast forward, 20 years afterwards, the world had different data.
The world said, wait a minute, we now think that through the skin, allergies begin,
through the diet, allergies can stay quiet. We now know that the gut is really important for tolerizing to those
antigens. The immune system in the gut is meant to
tolerize. The immune system in the skin, in our lungs and in our skin skin, is actually
meant to be activated and react. So when you think about that dry skin hypothesis, of course,
it's going to be promotional of allergic pathways, but when you think about taking things through the gut, it's going to be promotional of tolerogenic pathways.
So we learned a lot in the last 20 years.
So when the same people came together and wrote the guidelines 20 years afterwards, they
said, wait a minute, it's very clear now, and many guidelines have changed Peter now
to say, we need to diversify the diet. We need to tell our country's population to start having children eat foods in small amounts,
like tree nuts, like fish, like milk, like egg, like peanut, and to be able to have that
early and often and regularly so that we can try to prevent food allergies.
So, that's the general mantra.
The guidelines have now switched. Same thing for people who are pregnant. so that we can try to prevent food allergies. So that's the general mantra.
The guidelines have now switched.
Same thing for people who are pregnant.
It used to be thought women who are pregnant
based on a very small study, only 20 individuals,
but that was the only study that was available 20 years ago
that those pregnant women should avoid
peanuts and tree nuts, but actually fast forward 20 years after
there was a much bigger study done,
and that showed that definitively it's okay to have peanuts and tree nuts when you're pregnant.
It's actually healthier with omega-3s.
Of course, people who already have food allergies shouldn't be eating these foods when you're pregnant
or if you're a child, but in general, it's a way to prevent food allergies now,
among many other things like we talked about.
But it does seem to be important, and it goes back to those instrumental recipes of the
immune system.
If the immune system can probe the antigen, know that it's safe, know that it's not going
to harm the immune system or the body, it then becomes tolerant.
But in order to give it that instruction sheet,
in order to give it that recipe, you need to feed and you need to get exposed regularly.
And we think regularly means every day to every other day. And you'd say, well, wait a
minute, why my grandmother didn't have to feed me these foods or my mother didn't have
to feed me these foods regularly, What all of a sudden changed?
And we think that the environment is changing.
We know the environment is changing all around us.
Unfortunately, with different detergents, with different emulsifiers, with different chemicals
in our food, with different pollutants, with different viruses, it's changing.
So now we take the science and we have a better instruction sheet for patients and I'm grateful for that, but it is all based on evidence.
Do you think the gene never gets back in the bottle? Do we ever get back to the levels we had 30 years ago?
Or do you think that even if we can get dietary practices to where we were, which is to say we're at a place where parents are encouraged to liberally and diversely sample food for their kids.
These environmental issues, the detergents, the dryness of skin, all those things, the low
vitamin D, presumably because kids are playing outside less these days and their indoors
more.
And all of the things that we understand that it never quite gets back to the level it
was when I was a kid.
I got to tell you, when I was a kid, I did not know another child that had a food allergy.
All through grade school, middle school, high school, there was not another child in my
zip code that had a food allergy.
Today, my kids can't take nuts to school.
You can't have nuts on an airplane today.
So I can't tell how much of this is overreaction.
There's clearly a logfold change, but I can't tell how much of it is also just a disease
of the brain, if that makes sense.
No, but you're right to ask that, and lots of epidemiologists have now tested it.
It's real.
I mean, this is not just people thinking they have allergies, and when you and I are growing
up, they didn't.
This is real.
There were people very rarely that had a milk allergy, pion allergy, but the allergists
never really focused on them.
Now, the typical allergists, and we have allergists that have worked in the community for 80 years.
Their offices have shifted from being offices where arrow allergians were what they took
care of all the time, to now its foods.
And that's not because someone thinks that they're alert to food. This is a real diagnosed food allergy.
And I think your question is a good one,
but I don't think we're ever going to get back to 30 years prior,
because we have different practices where we have different ways
of processing food, different environmental exposures.
Because this is mostly environment,
if I have identical twins born to the same mom and dad, I can have one twin develop a
food allergy and the other one doesn't.
And typically that's an adulthood.
And the one twin that develops a food allergy, they're the ones that have been out in pollution
more.
They've eaten not such a healthy diet.
They've a lot of preservatives or they smoke or they eat a lot of fast food or they
have under a lot of stress and they they are under a lot of stress and they
don't get a lot of sleep.
So genetics being equal, exposures in early life being equal, there are certain behaviors
that now we're seeing or more associated with food allergy like air pollution.
I don't think we'll ever go back, but luckily science has helped us so that we know what
to do now and how to change our behavior so
that we can try to prevent food allergies from worsening.
So let's now talk about the work that you've been, well, I'd like you to put the context
around your role.
I mean, of course, I think of you as pioneering this work.
I'm sure you'll elucidate us all with how many people are pioneering this work.
But you and I met, like I said, about a decade ago, through a mutual patient of mine
who at the time was being treated by you.
Quite frankly, I was just sort of blown away
at the fact that a person who once had
an anaphylactic reaction to nuts
was going through an immunotherapy-based
sensitization program with you at Stanford.
And then all of a sudden,
didn't have an anaphylactic reaction to nuts.
This was mind-boggling to me, and I'm forever in your debt for graciously letting me wander
around your lab and sitting around chatting with me over coffee.
So can you give us a bit of a sense of what this revolution is about?
It's sort of hard to wrap our head around when you consider the lethality of these conditions.
We take this so seriously, and that particular family has been so engaged like so many other families,
that this is a disabling disease.
My colleague, Kim Yates, has done so much work in the series,
as well as other families, to be able to educate and organizations like Fair and others have really moved the needle forward.
So when you think about food allergies, it becomes in a child's mind or an adult's mind,
something they have to live with and it's not fun and it can affect their social lives
or quality of life.
So they come to the table often wanting to know what's the best therapy now.
And compared to when we started with your patient, we have a lot more therapeutic options.
And that's always good in any field to have options, especially for our patients.
So any of these decisions that I'll talk about today, they're really personal.
They're really something that the doctor, the healthcare provider should talk to the patient
about and see what's the best for me.
But in general, again, getting back to that immune system, getting back to
the regular eating of foods so that you can start retraining it to tolerize to those
foods, to see them as natural and not unnatural. This has been going on for about a hundred
years. And even though to us and to many others, this is something new, and we did work at
Stanford, but actually other work at other
institutions in the country and other work in Europe had already been done. So what I was doing
is building upon other evidence and clinical trials that had been done. And I worked very
closely with the Food and Drug Administration, the FDA, because you don't want to do anything
that's not safe, and that you wouldn't want to do anything that's not safe and that you wouldn't want
to do for your own children if they had the disease.
So with that in mind, I learned a lot about the immune system.
What you do in immunotherapy at the very basic level is give the person back the very same
thing that they're allergic to.
And this was done a hundred years ago with dog allergies, with cat allergies, with grass allergies,
with lull allergies.
People would actually start to take these things, but inject them.
A lot of your patients might have done allergy shots when they were little, but those are
ways that we've learned as immunologists that, oh, you can retrain the immune system.
You can train a body so that they are no longer allergic to cats, for example. But you need to keep taking those allergy shots in
general. So the same thing for food. You don't want to give a food allergy shot
because the food in and of itself is very potent. And because it's a very specific
IgE-mediated disease, foods, if injected into into you can be extremely dangerous.
So we don't give it via injections.
Just to be clear, the allergy example, let's say it's cat, dander or whatever, is the
shot giving you a little bit of that dander?
Is it sensitizing to you a little bit of it?
And how frequently does the patient need that to achieve the symptom-free existence?
Initially, you need to take it almost daily, daily to a week.
And then once your body starts to build up that immune muscle,
you only need to take it about once a month.
But you will do that for life.
Well, some people do it for life.
Some people do it for five years.
If you stop it after five years,
you have a 25% chance of re-engaining your allergy.
Another 25% chance of having it just be less, but there.
And then you have a 50% chance of having it be resolved for the rest of your life.
But you need to be on five years of immunotherapy, depending upon the arrow allergy.
And we're talking environmental allergies.
Yeah, and is the reason that you can get away with doing that
because it does not induce anaphylaxis in the reason that you can get away with doing that because it does
not induce anaphylaxis in the way that the food does? So it's just the severity of the
IgE mass cell reaction. Exactly. And we still are trying to understand why that is. Why
is grass allergy not as bad as peanut allergy? So people are still trying to figure that out. Why is dog allergy not as bad as peanut
allergy? But given that it is for immunotherapy, like we said, you give small amounts of that
specific allergen back to the patient, whether or not it be a shot for environmental allergies
or whether it be orally for a food allergy, you give it back in small amounts, you start with a small
spec that you can hardly see and then you increase that dose by 25% every two weeks, but
you're giving it every day and then you increase it step by step every two weeks, you increase
the dose, but you're giving it daily and you want to do that in a doctor's office, you
want to be really careful about that.
So we did it in our clinical trials.
Over time, you readjust the immune system.
Now it takes a while, right?
This person has had their allergy and it's been quite severe for them.
So to retrain the embedded memory aspect of the immune system takes time.
And what happens over time in the immune system is those little T cells start to be taught that,
oh, wait a minute, this antigen, it seems okay.
I'm getting it every day, boy, I need to re-adjust myself.
I need to reframe my mindset.
And instead, T cells start to reframe their mindset.
You start creating another whole layer of memory
T cells that become tolerant to that antigen, and then they teach the B cell to forget making
IgE. In fact, we want you to make more IgA. We want the B cell to make more IgG because
that's protective. And so that's what happens over time.
During the first year of immunotherapy, you're slowly going up, you're slowly readjusting.
And in our patient's case, that's exactly what happened.
That person was readjusting their immune system, readjusting their immune muscle to then
switch from an IgE-mediated bad reaction to instead creating protective molecules that could protect the patient
against the allergy.
The IgE can still be there, but you have this huge amount of protective, what I'm going
to call blanket, so that that IgE doesn't have anywhere to go.
When it wants to bind to the receptor, that blanket of immunoglobulins don't allow it to bind to the receptor.
We all have IgE, all of us do, but some of it works and some of it doesn't.
In the case of the person with the anaphylactic reaction to peanuts, do they ever go above the 0.005% IgE concentration?
How high does it go just for comparison? IgE is typically specific. You have to have an IgE to a specific food to be able to have
that reaction, and yes, typically some people with peanut allergies will be over that point
0, 0, 5% or anyone with allergies. Their IgE is higher. And just so you know, a virus can also
increase IgE, non-specifically. Your body just starts making IgE probably
against the virus. So a very prehistoric type of reaction, but importantly, Peter, for
every IgE molecule, we can make 100 IgG molecules that protect against that IgE molecule circulating
and becoming potent. And that's what's happening during the time of immunotherapy.
You're making a huge amount of IgG molecules to bind against that IgE becoming what I call
pathological.
So it's a ratio thing.
Just give me a sense of scale.
So on the very first cycle, that first two week cycle, what fraction of a peanut
is being given in the capsule? How small is it? I'm sure it's less than a single peanut,
obviously.
Yeah. It's about one-two-hundredth of a peanut. You start very low and you go very slow.
Because in the end, you want to retrain that immune system,
but you don't want to activate it too much.
Now, during that retraining,
sometimes your muscles get sore, right?
Sometimes you will see some hives,
sometimes you will get a little itchy throat,
your body will have these little reactions,
but I call them simmering reactions,
but you do need to take it every day,
and then you start to see the switch from
IGE to IgG.
And again, the T cells are responsible for that.
Many other cells are too.
But in general, if you stop the therapy, this beautiful pathway of tolerance then starts
to go back to the original pathway. So it's really protection.
It's very rare that a person completely flips and becomes non-allergic.
Does that make sense?
It's really what you're doing in the immunotherapy is changing your threshold
and creating more protection molecules around you
and creating more protective cells around you.
And when does that switch flip? You're on the typical immunotherapy regimen.
It flips at around nine months to a year.
And again, just to give people a context of the doses we're talking about, someone comes
in with an allergic reaction to peanuts.
For two weeks, they're going to take a capsule that contains one-two-hundredth of a peanut
that goes according to plan, they will
increase that by twenty-five percent for another couple of weeks. A month into this thing,
they're still basically taking one two hundredth of a peanut, but you will continue to do that.
They will not hit the threshold of a full peanut by the end of the year. They're really,
really micro-dosing this in the true sense of the word. Well, you're super smart because you do the math.
But in general, we've worked it out thanks goodness to the science where we know the steps.
There are going to be certain steps of this where you don't have to increase by 25%.
So once you get up to about 40 to 60 milligrams and that's only after a couple of weeks,
we start to go up those steps, you start to skip.
And then you can go even higher
than we double, they can quadruple.
So by the end of the year, you are at about a peanut
to two peanuts worth, and that was done with science.
There were dose finding studies,
there were maintenance finding studies,
and we do this for milk and egg and tree nuts
and peanuts all the same time.
That's the other thing, because I told you you a lot of people have more than one allergy.
We had to work this out scientifically to go low and slow,
but within reason so that we could eventually, within a year,
make sure that that flip was happening in the immune system
and make sure that by the end of the year, if they didn't want to continue anymore,
we at least needed to get them up to an accidental ingestion of that food.
So we were very careful to design this, and that's, in
essence, why this needs to be a drug, because all that science, you can't do this at
home, all that science enables you to know, when do I push the immune system to go
quadruple? When do I not? And what are you using? Are you looking at the IGE
IgG level? Are you simply doing this
based on the absence of symptoms in the presence of the administration?
Thanks to a lot of pioneers who were in those trials, including our patient. We were taking
blood every two months, every three months. We were using blood biomarkers to let us know,
oh, look at that. The cell immune system has started to switch.
Oh, look at that.
Isn't that interesting?
The human immune system has switched.
So that's how we knew to change our protocol.
That's how we knew it shouldn't take 10 years to do this
because there was this natural switching that was happening
underneath in the blood.
So we use those markers to then re-adjust and recreate our
regimen so that you could go low and slow in the beginning. But then by about
three months we knew that the muscles were starting to change so we could hike
up the dose a little bit more by six months even more. By year we knew we had
it because by that time the immune system had switched but that took a lot of time and effort and blood draws from those original pioneer patients to give
us the science by which we could perfect this regiment.
It's not perfect yet, but it's much better than where we were 10 years ago.
If at the end of a year you kind of alluded to this, a patient says, look, I can't handle
coming in here every day to do this anymore.
I'm sort of done with this. Is it on average safe to assume that they may never be able to just go out willingly
and eat nuts, but if they accidentally ingest a nut here and there, or there's dust from
a nut in a food and you referred to as an accidental ingestion that they're going to be fine?
Is that directionally, right?
You're absolutely right.
On one side, we want to make sure that we reach the goals of the patient.
Typically, a patient wants to get up to accidental level ingestion.
Because of that, we say, okay, we'll try to get you up to 600 milligrams by the end of
the time.
We also know that 600 milligrams is what the FDA also thinks is the appropriate threshold.
So we're grateful for that knowledge
across many other communities and institutions.
So we try to get that up to 600, but you're right.
Oftentimes people say, well, I'm done.
I really don't want to have to do this every day.
Can you please tell me if I could take my dose weekly
or if I can take it every other day?
And what dose is safe enough?
For maintenance, for example, we try to get them up to two peanuts a day, but sometimes
they go off to college.
They don't want to have to take a nut every day.
But we tell them that you kind of have to because we don't know what will happen if you stop.
And that's what we told them five years ago.
Now we have some long-term follow-up.
Now across many countries, people are sharing data
and saying, what makes sense for patients?
Can you predict who can stop therapy
and who might not be able to stop therapy?
Who can go down on their dose during long-term follow-up
and who might not be able to go down their dose?
So we're learning, but in general, it's much better to take about one nut or two nuts a day,
every day after you finish your therapy with a doctor.
And just to be clear, do they ever transition to the point where they can do this
as outpatients on their own or do they always have to do this in a doctor's office?
After about a year, even after six months, if people get up to that one to two peanuts a day,
or hazelnuts or glasses of milk, you can say, all right, you're done now, and you can go home,
and do this at home, and then let me know how you're doing. So yes, after you get to that threshold,
we definitely let you go home. And that depends on the clinical trial, though, but nowadays,
in the clinic,
that's what we do. Are people undergoing this therapy outside of clinical trials yet?
They are, Peter, and that's been going on for a while. We were very careful to say that if you do
decide to do it in an outside clinic, try to get your health insurance to approve. We want to
democratize this. We don't want it to be only available to certain populations
because everyone gets food allergy and sees no boundaries in terms of ethnicities or
socioeconomic status, especially people of color have a much higher rate of anaphylaxis
unfortunately because of access to health care.
So that's a whole nother topic for social determinants of health.
But yes, there are clinics that are offering this, and there are clinics, for example,
latitude in New York City and San Francisco now, that offer specific regimens that are
based on science and evidence to be able to offer therapy.
So there are unique clinics out there that are specializing in food allergy care to
be able to help patients based on scientific methods.
What fraction of patients who continue this protocol get to the point where they completely
shed the allergy altogether and at some point will go on to eat as many peanuts as they
want.
I always like to start any conversation with the patient that this is possible.
Some patients just want to be able to eat one to two peanuts for their life and just
know that they're not going to have an excellent
ingestion, they're willing to do that. And they believe that is the word cure. But for me as a doctor, I kind of push my own standard a little bit higher.
Like, cure should be eating at live and not having to worry at all. So in that definition of cure, if you take the dose for at least two years,
you have a 20% chance of being in the cure category.
20% after stopping after two years. After five years, you have a 60% chance. So time on
dose matters as well. And again, it's all recalibrating, re-educating the immune system.
And many people ask me, well, are there some people that are refractory?
And you'll know that term because of people that are refractory to cancer therapy. But in allergy,
there's no refractoriness per se. If sometimes people have too much abdominal pain or they have too
many hives, or their asthma gets worse every time they have the dose, that's where I'll say, hey, it might not be worth it.
There's too many side effects here.
This bothers you too much.
We try to decrease the dose so that we personalize it for them,
but some people just say this is too much now,
I really don't want to go through it.
So those people will stop doing it.
But in general, if you stay with it,
you'll get the benefit from it.
What percentage, if any, of people going through
the clinical trials required epinephrine during
the administration of the immunotherapy?
Nowadays, because we go so low and slow,
it's a very rare percent.
So about one in 10,000,
and some clinical trials, one in 100,000, it's rare.
Is there any allergen that is not amenable to this type of therapy?
As you said, you mentioned a few others, right?
Shrimp, other fish, nonchalfish.
Is there anything that we've uncovered which this therapy does not work?
It's again, back to that very elemental nature of the immune system.
Proteins, any protein, you can do this with, which is great. Very carefully,
if you're allergic to a protein, which is what we're talking about today, you can do this.
There are very rare allergies where you're allergic to a sugar. It's called alpha-gal,
and we don't think you can do this type of regimen with alpha-gal allergies because that's a sugar.
So with proteins, the immune system has this very elemental way of
readjusting and recalibrating and become tolerant.
Well with sugars, it's a little different, but luckily sugar
mediated food allergy, it's one of a kind, it's called alfagal
and it's very rare. But it is occurring more in the
southeastern part of the United States because it's so
sure to tick bite. So that's another whole area, maybe in the future, Peter, for you to look at.
But right now, there is nothing that we have not been able to desensitize a patient to
with food allergies that we've tried to.
Going back to sort of the environmental allergies here in Austin, we have this thing called cedar
fever.
The cedar trees give off a ton of pollen and knock on wood, unfortunately it hasn't
afflicted me.
I know so many people here who for a period of, gosh, I think it's sort of December January
or November, December January, where they can't function without Benadryl and Zerteck. I've asked around on behalf of friends to see if there are immunologists and allergists
here that have an immunotherapy regimen, and to my surprise, nobody does.
Would this be an easy thing to address?
Cedar allergies are interesting because the cedar protein itself is something called a
protease sometimes, so it can start to grade proteins. It's a little weird, but ceter allergies are very serious.
And yes, there are people that have developed immunotherapy for ceter.
It's interesting that I can't find them in Austin.
I'll have to connect with you offline for this, or a lot of people here who I know would
be interested in that.
Yeah, it's the same rubric.
You can desensitize to it, although it takes a lot of care, maybe that's why. Importantly, cedar allergies are something just like other tree allergies, they're really
to be cared for, and they can give you lots of mucus and asthma.
So I hope that those individuals you take care of can get some benefit, but immunotherapy,
so I call it proactive therapy and reactive therapy.
Reactive therapy are all those anti-histamines.
People need to take proactive therapy and reactive therapy, reactive therapy are all those anti-histamines. People need to take proactive therapy
is the immunotherapy to readjust your immune system,
but you need both.
I wanna now talk a little bit about air pollution
just for a moment.
Tell folks what's a PM 2.5 and why should somebody care?
10 years ago, I didn't really understand
all of the PM 2.5 jargon either,
so I wanna just make sure in all humility, this is something that we all need to learn out. Every single one of us
even if we're in a research station in Antarctica. Because air pollution
unfortunately is rising, we need to know that there are no boundaries when wildfire
smoke happens in Australia. It can circumnavigate the world within four days. And PM 2.5 is a way that we,
as a society, have given a measure to air pollution, but it's not everything in air pollution.
It's particulate matter. It's the particles in air pollution that are 2.5 microns in size.
Now you think, well, what in heaven's name is that?
2.5 microns.
What does that mean to me?
Well, if you think of like a little red blood cell, that's a micron.
So you think about particles that are basically about twice the size of a red blood cell.
And those are floating around in the air.
And why do they do that?
Well, that's because partially combusted fuel, combusted fuel from our cars. If you don't have
an electric car, combusted fuel from industry, when it breaks up petroleum, when it breaks up,
any kind of product would fire as well. Little particles escape into the air, and those particles
are not what you see as sutt on your car. They are not what you see as brown dust on your house.
These are particles that are so small,
they continue to be aerated,
and they can float in the air around the whole world.
And they're so small that they can penetrate into our lungs.
And why do we care about that size 2.5 microns?
That's because it can get through our lungs
and into our blood.
It's dangerous also because PM 2.5
as a defined measure of air pollution
has about 200 different chemicals in it, 200.
And of those 200, some of those are what we call
volatile organic compounds.
These are compounds that you smell when you smell like markers like xylene or in the old
days mothballs naphthalene.
So these are chemicals that are not good for the body.
They are from combusting fuel.
If anyone of your listeners is a chemist, these are what we typically call six-membered rings.
They're organic chemists, sort of nightmares, because they smell horrible.
And I didn't like them when I was doing organic chemistry when I was a student.
I don't like them now, because now I know what they can really do to your body.
They can cause cancer.
They can increase asthma.
They can increase cardiovascular disease, stroke,
and wildfire smoke is even more potent as an air pollutant than PM2.5. We also measure PM2.5
for wildfire smoke because wildfire smoke basically is biomass burning, but unfortunately wildfires
aren't burning just trees anymore. They're also burning commercial buildings.
So what goes up in well fire smoke compared to let's say just diesel from the cart, which is bad enough.
But in addition with wildfires, you're burning up your upholstery, you're burning up your paint thinner,
you're burning up your detergents underneath your sink, your shampoos. That's all going up in the air.
And that's also measured as PM 2.5 because all those particles are so small, they're also going into your shampoo. That's all going up in the air and that's also measured as
PM2.5 because all those particles are so small. They're also going into your lungs.
So with wildfire smoke, we also have to be super careful. So for any person that's getting
exposed to any PM2.5, you can look on website, you can go look at air now, you can go look
at the NOAA website and know in your region what air quality index you have that day
if it's in the green zone great if it's in the yellow zone please start wearing a mask basically a
mask that you used to wear in COVID because those masks are very important to reduce the risks of
those exposures to your lungs especially especially for children and elderly patients.
So that's a PM 2.5 means, and I want people to really understand that it's measurable.
It means something biologically that's important.
It means something medically, but it also can be measured by well-meaning agencies like
the EPA, like we use in California, something called purple air, and you can actually
look on the web.
The purple air monitors can actually tell you what PM 2.5 measurements are in the air.
Not all countries have that.
We're lucky in the US that our US agencies measure PM 2.5 on a regular basis so that we can
map that to our zip codes.
Do you recommend that people, because there's a lot of PM 2.5 monitors that you can buy for
your own home, is it necessary or do you feel that if you are just looking at these databases,
you get a good enough sense, because I can't tell which problem they're solving for.
Are they basically trying to say, you need to make sure you don't have particular matter
in your home, because if you do, by the way, it might be that you have a leaking stove, or I mean, that would probably turn up as carbon monoxide or something else,
versus, no, you just need to know what the level is outdoors because that might be the day you choose not to do your 10 mile run if it's a red day.
All those things. So, first of all, if you know that you have to be outdoors and you're an immigrant farm worker and you have to be out there for eight hours no matter what and the air quality index is 100,
like it was yesterday here in California and we had people out in the fields,
they should know that they should wear a N95 mask.
And N95 will sufficiently prevent PM2.5s from getting in?
Not perfectly, but at least it reduces the risk.
No mask completely reduces those small organic molecules, those six member drinks from getting
through the mask, but at least it's better than nothing.
So typically that's what I'll say.
And I'll definitely say to my patients, please don't exercise during any air quality index
that's greater than let's say 50
because even though they might not feel it during the hour that they exercise outside,
it definitely affects their immune system. There were studies done in London for example where
people would exercise out in streets that had a certain air quality index and in London you can
actually do this because there's micro PM 2.5 measurements in Hyde Park versus in Broad Street.
So they did this research and they knew that even if people exercised out for one hour
in clean air versus polluted air, their immune system changed for a whole day based on that
one hour of exercise.
Be careful.
And yes, indoor air is very important.
Our lives are spent indoors for more than 90% of them.
That means 90% of the time that we're on this planet, we're spending it indoors.
That's typical for the average US citizen.
So having a purple air-menor indoors is actually helpful, especially if you live in a place
where lots of wildfire smoke or air pollution pollution because you can't assume that your air pollution
is being filtered appropriately and you can't assume that you're being protected because
oftentimes you can't smell this and you can't see it.
It is so small that you need a special detection monitor to know if it's there.
Now, if you do have bad indoor air, you can buy a murve filter. You can buy a filter in your air conditioning or central air, or
you buy a stand-up filter to reduce the exposure. So, all these things are
available to people, and in certain states they are available freely for
families that can't afford them. So, just to be clear, let's say you do this
exercise. You buy the purple filters, you figure
out that, hey, actually, either, I live in an area where there's enough pollution outdoors,
and of course it's easily able to get indoors through windows and doors, or just for whatever
reason, there's something in the house that's producing these compounds.
Option one is you just get stand-up HEPA filters for the house, but you're saying option
two is there are certain filters
you can put in your HVAC that will do the same thing.
And what are those called again?
They're called MIRV.
They're MIRV 13 or higher.
Don't buy a MIRV 7 or 8.
MIRV 13 reduces all of the major PM2.5,
as well as pollens, as well as other chemicals,
but you need to change them off
and because they're getting clogged up.
I don't work for purple air,
but you can buy any of these monitors
that can monitor external outside air and indoor air,
and you can buy them and get to know the difference.
It's good to ventilate your home,
so you don't want your home to also,
like you said, be collecting its own toxins,
and that can happen if you have a
gastro or a wood stove. So yes, in general knowing and measuring your PM 2.5 is going to be helpful to
your health because you can manage accordingly. Do you have a sense because I've never been able to
get a great answer to this question. Carrie, it's actually one of the reasons I did not include this in my book. I wanted to include a section on air pollution in the book,
and in the end, I didn't for a couple of reasons, but biggest reason was I couldn't get a really
clear sense of the mortality impact. I couldn't quantify it the way I could quantify it for
smoking obesity and some of these other things. So coupled with the fact that the book was already
about 50% longer than anybody wanted it to be,
do you have a sense of the magnitude of this?
And for example, like what's the difference between,
even quantifying the exposure is a little difficult.
It's not like packers of cigarettes where we can say,
40 pack your history versus zero pack your history,
translates to this much difference in outcome. Yeah, actually now Peter, you can. So the WHO just put a report out, the AQLI just put a report
out from University of Chicago. I'll send it to you. I want to make sure you have this because
you have such a wide, amazing opportunity to influence people through your bandwidth.
And Peter, I feel like you are in this incredible position to make this impact
with others. You are a trusted voice. And because of that comes the privilege of
being a trusted voice, but also that accountability and responsibility of knowing all the
science. And so what I'll do is send you this report because it has now been
put into exactly those
terms.
And it's more dangerous than tobacco smoke because it is so prolific.
And I'll give you this report because in the first page, it shares with you the context
of how pollution has killed about 8 to 10 million people a year now.
And that's attributed directly to air pollution.
What is the final common pathway?
Is it majority through cardiovascular disease, cancer?
Where do we think the actual mortality comes from?
Exactly, especially in low-to-middle-income countries,
it's cardiovascular disease and lung disease.
In quote unquote, more westernized countries,
it's more associated with stroke,
long-term cardiovascular disease, and cancer. So I'll send you this. I think it's important
for you to know. Air pollution has now, thanks to a lot of science, that you can disaggregate
what deaths are due to air pollution versus what deaths are due to tobacco smoke. There's
a multiplicity of effect here,
but now the epidemiologist really have the data right,
and you can sink your teeth into this data
and know that it's accurate.
Well, Carrie, this is very interesting.
I know we were a little bit short on time today,
so I'll kind of just ask you one final question.
When you go back to the child who died in the ICU,
the child who was kind of your patient zero,
you alluded to it, but we never really got to it.
Tell me, why did the FB pen not work?
When that father asked you about that,
what happened there?
They hadn't renewed the FB pen, it had expired.
They hadn't gone to the doctor for at least five years.
And they assumed that their child had grown out
of a milk allergy because that's what people told them
would happen, but they never got their IgE retested, they never went back to their allergist, and so they
still had the epiphen that had been given to them five years prior and it expired.
In addition, it was for a different weight.
It was for Epi Jr. and he had gained, and of course grown, so if he were to even get an
epi that was not expired, you should have gotten a different dose. So it interlates all these
aspects about the fact that you cannot know just what typically happens to a
patient. If that happens to you, you need to actually go to a doctor and get your
onset of data to figure out how to best manage your disease. It also taught the
lesson of you've got to keep updating your disease. It also taught the lesson of,
you've got to keep updating your EpiPen
and making sure that it's renewed
and not using an expired chemical
or any expired drug.
And then lastly, that as you grow,
you need a different dose.
Wasn't there a big controversy a couple of years ago
when a company that was selling EpiPens
decided egregiously for no apparent reason
other than just malicious greed to jack the prices up.
Has that resolved and are Epipens now relatively inexpensive
again?
That's right, that company was my land
and they were making Epipens and that's why I called
an injectable Epidepern device because now there's a lot
of them.
Thank goodness the FDA, other agencies got involved and said, okay, this is not right.
You cannot keep charging that enormous amount of money.
And so then what we call generic Epidephirn device has started to be made.
Other companies started to hit the road.
There's other devices now that can be used called the AVICUE.
So I think luckily now, thanks to many industries involved in this,
there's also potentially a nasal epi that can be used. So yes, that company was seen
as providing methods that were not ideal at all, and that was stopped, thank goodness,
because no one should be charged that amount of money for a life-saving drug.
What were they charging for EpiPens?
Oh, it was like 400 up to 600 for some of my patients.
That luckily now is being covered by insurance, but again, third party payers also need to make
sure that they can reimburse for these life-saving medications.
Well, Carrie, this is really interesting stuff.
Look, I've learned a lot today, certainly getting the differences in some of the immunology
here. Also, I think the PM 2.5 story is something that I look
forward to digging into a little bit more, especially as someone who does spend a lot of time
outside, maybe no more than 10% of the time like anybody else, but it seems like I spend
more time outside, so I'd certainly like to be aware of that.
Anyway, thank you very much for most of all your work. I've seen firsthand the impact
it has had on people's lives.
And I know that there are probably a lot of people who are hearing about this for the
very first time today.
There are people who are listening to us or watching us who know somebody who suffers
from a devastating anaphylactic reaction, who probably at this point in time are completely
unaware that such a therapy exists.
As my final point is, what would you suggest for those people?
Someone listening or hearing this who is being blown away by what you're telling them.
Where can they either find a clinical trial or find a non-clinical trial provider who's
able to walk them down this pathway?
Well, first of all, thank you, Peter.
Thank you for your excellent questions, as always, and really excited to be on the show.
And thank you for your curiosity and your care
and this podcast.
For people that are learning about this newly,
what's wonderful is you can get on your computer,
do a search on clinicaltrials.gov,
look under the category of food allergy,
and you can find out what clinical trial nearby you
is actually ongoing for food allergy therapy.
And there's a lot more than there were just five years ago.
So that's good.
There's like 17 companies in the space now.
I'm really excited about the future.
There is a lot of hope and promise.
Within that hope and promise, there are more clinics around the country as well that are
specializing in food allergy.
I gave you one example of latitude, but there are others as well.
And so with that in mind, I would go to your health care provider, ask them questions.
If you feel like they don't have time or they haven't really answered the questions in
the way that you learned about today, go online and find out those clinics that specialize
in food allergy therapy.
And again, not everyone fits with everyone, so give it a test, see if you like that structure
and then you can try.
And I hope the best because that possibility is there, that reality is there, and I hope
everyone tries to undergo therapy.
Kerry, thank you so much.
This was absolutely fascinating.
Thank you.
Thanks for your great questions.
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