Huberman Lab - Benefits & Risks of Peptide Therapeutics for Physical & Mental Health
Episode Date: April 1, 2024In this episode, I explain the major categories and types of peptides currently in use for therapeutic purposes. I discuss peptides for improving tissue rejuvenation and repair, promoting longevity, i...mproving muscle growth and fat loss, and boosting mood, vitality, and libido. I explain the biology of how these peptides work and both their potential benefits and risks. I also discuss peptide sourcing, dosages, cycling, routes of administration, and how peptides work in combination. This episode will help you better understand the rapidly expanding landscape of peptide therapeutics and how to evaluate if specific peptides might be advantageous towards achieving your physical or mental health goals. For show notes, including referenced articles and additional resources, please visit hubermanlab.com. Thank you to our sponsors AG1: https://drinkag1.com/huberman MateÃna: https://drinkmateina.com/huberman Levels: https://levels.link/huberman Joovv: https://joovv.com/huberman LMNT: https://drinklmnt.com/huberman Momentous: https://livemomentous.com/huberman Timestamps (00:00:00) Peptides (00:03:20) Sponsors: Mateina, Levels & Joovv (00:07:44) What is a Peptide? (00:12:06) Peptide Sourcing, Lipopolysaccharide (LPS) (00:14:48) Rejuvenation & Tissue Repair: BPC-157, Angiogenesis (00:21:50) BPC-157 & Tissue Injury; Mode of Delivery (00:27:53) BPC-157: Safety, Doses, Cycling, Tumor Risk (00:35:16) Sponsor: AG1 (00:36:43) Tissue Repair: Thymosin Beta-4, TB-500 (00:40:49) Growth & Metabolism: Growth Hormone, IGF-1, Risks (00:45:25) Secretagogues, Sermorelin, Tesamorelin, CJC-1295 (00:52:21) Sponsor: LMNT (00:53:44) Ipamorelin, Hexarelin, GHRP-3, MK-677; Risks & Timing (00:58:69) Peptides for Growth Hormone & IGF-1, Risk; Combinations & Dosing (01:06:12) Longevity: Thymosin Beta-4, Epitalon (Epithalon) (01:12:09) Vitality: Melanotan, PT-141 (Vyleesi), Risks (01:17:21) Vitality: Kisspeptin (01:21:46) Peptides, Potential Benefits, Side-Effects & Risks (01:24:19) Zero-Cost Support, Spotify & Apple Reviews, Sponsors, YouTube Feedback, Momentous, Social Media, Neural Network Newsletter Disclaimer
Transcript
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Welcome to the Huberman Lab Podcast,
where we discuss science
and science-based tools for everyday life.
I'm Andrew Huberman,
and I'm a professor of neurobiology and ophthalmology
at Stanford School of Medicine.
Today, we are discussing peptides.
Peptides are a topic
that's receiving a lot of attention these days,
in part because of the excitement
about the so-called GLP-1 analogs or agonists.
GLP-1 stands for glucagon-like peptides.
These are drugs used to treat type two diabetes
as well as drugs used to treat obesity.
Today, we are not going to discuss the GLP-1 analogs.
However, we are going to discuss some of the other peptides
that are receiving a lot of attention these days,
including peptides for tissue healing and repair, as well as peptides that are receiving a lot of attention these days, including peptides for tissue healing and repair,
as well as peptides that impact longevity and vitality.
Now in principle, any discussion about peptides
could be enormously vast.
And that's because there are so many different kinds
of peptides.
And by the way, I will explain what a peptide is
in just a few moments.
But for instance, insulin,
which is involved in regulating our blood sugar
or blood glucose levels is a peptide.
Oxytocin, which is sometimes called the love hormone,
although I wouldn't say that's the best description
of what oxytocin is.
It's a neuropeptide slash hormone
that is involved in everything from pair bonding
to socialization, but a bunch of other things as well.
Those are just two examples of peptides
that are familiar to most people, at least by name,
and that exist within the tens of thousands, if not hundreds of thousands examples of peptides that are familiar to most people, at least by name, and that exist within the tens of thousands,
if not hundreds of thousands of different peptides
that exist within our brain and body.
Today's discussion is going to focus on peptides
that are increasingly being used for therapeutic purposes.
And I want to point out something very important
about this topic area.
First of all, it is a topic area
for which there is a lot of confusion.
The mere naming of the peptides is confusing.
Oftentimes they're referred to simply by virtue
of acronyms and numbers like BPC157 or MK677,
et cetera, et cetera,
such that if you're not really familiar with them,
it can be a bit overwhelming and confusing.
Today, I'm going to provide a very simple
organizational framework that will allow you to understand
what these different therapeutic peptides are,
why certain ones may be advantageous for certain purposes,
of course, also highlighting the potential risks
and in some case, outright dangers.
And I'll tell you how they each work alone
and in combination toward achieving specific physical
and in some cases, even mental health goals.
I'd be remiss if I didn't say at the outset here
that a lot of what's happening
with applied therapeutic peptide biology
falls into one of three categories.
There are peptides that are being prescribed by physicians.
So these are prescription peptides for specific purposes.
These are FDA approved.
There are other peptides that reside
in kind of a gray market area.
You can purchase them online, but the safety and efficacy of other peptides that reside in kind of a gray market area. You can purchase them online,
but the safety and efficacy of those peptides
is a bit questionable, in some cases, very questionable.
And I'll give you some filters to determine
which category certain peptides fall into.
And then of course, there's the black market peptides.
It is possible to buy peptides online
through any number of different sources.
And of course, I do not suggest people purchase black market peptides.
It's very clear that a lot of them are contaminated with things that both in the short term,
but especially in the long term can be problematic.
So if you're interested in understanding or using therapeutic peptides,
today's episode is for you.
Before we begin, I'd like to emphasize that this podcast is separate
from my teaching and research roles at Stanford.
It is, however, part of my desire and effort to bring zero cost to consumer information about science and science related tools to the general public.
In keeping with that theme, I'd like to thank the sponsors of today's podcast.
Our first sponsor is Matina. Matina makes loose leaf and ready to drink yerba mate.
I often discuss yerba mate's benefits, such as regulating blood sugar,
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the ways that it can improve digestion
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I also drink yerba mate because I love the taste.
While there are a lot of different choices
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So much so that I decided to become a partial owner
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Although I must say, even if they hadn't allowed me to do that,
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is the cleanest tasting and best yerba mate you can find.
I love the taste of brewed loose leaf Matina yerba mate,
and I particularly love the taste of Matina's new canned cold brew zero sugar yerba mate,
which I personally helped them develop. If you'd like to try Matina, go to drinkmatina.com
slash Huberman. Right now, Matina is offering a free one pound bag of loose leaf yerba mate tea
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free bag of yerba mate loose leaf tea and free shipping. Today's episode is also brought to us
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using a continuous glucose monitor.
Now, blood glucose, sometimes referred to as blood sugar,
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And of course, I'm always telling people that they should get sunlight in their eyes as
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circadian rhythm, daytime mood, focus and alertness and improve sleep.
Now, in addition to sunlight, red light and near infrared light has been shown to have
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So what is a peptide?
A peptide is a small protein that's made up
of little chains of amino acids.
Now, the moment people hear protein,
they usually think proteins that you eat,
or perhaps they think about four calories per gram
of protein and that sort of thing.
Keep in mind that we have lots of different kinds
of proteins within our body that have nothing to do
with the proteins that we eat.
Now it is true that many of the amino acids
that comprise peptides, as well as other proteins
in the body come from the foods that we eat
because the amino acids again are the building blocks
of peptides and other proteins.
The basic way that we define a peptide is that it tends
to be a small protein, meaning chains of anywhere
from two to 50 amino acids.
That's really the strict definition of a peptide.
However, oftentimes peptides that are a little bit bigger,
so maybe 75 or 100 amino acids in length
will also be considered a peptide.
Now, if you start combining different peptides together,
you get what's called polypeptides.
And many of the proteins in the body are polypeptides.
So just to get a mental image of what a peptide is,
a peptide basically looks like beads on a string
where there are two to 100 beads
and each of those beads represents a different amino acid
and the arrangement of each amino acid
relative to one another,
that is their order along that string,
determines what the peptide is and what the peptide does.
The other thing that's important to understand
about peptides is that some peptides are hormones,
other peptides are merely called peptides, proteins.
Others are neuromodulators,
meaning they adjust the activity of neurons
and some peptides multitask and do many things.
In fact, I think it's fair to say that most peptides
have what are called pleiotropic effects,
meaning they affect many different aspects of cells.
And this is very important to understand
because unlike a lot of our discussion on this podcast
about dopamine or about specific hormones
like testosterone or estrogen,
when we talk about peptides, especially therapeutic peptides,
oftentimes we're talking about a single peptide
that does a bunch of different things
depending on the cell type,
the time of day or night that that peptide is present,
and even the different so-called
downstream effects of the peptide.
What do I mean by downstream effects?
Well, when a peptide binds to a receptor on a cell surface,
okay, and you can just think of that process
as a little parking spot on the surface of a cell
and the peptide, if it's available, will bind to that receptor and then set in motion
a kind of bucket brigade, a sort of conveyor belt of cellular processes.
For instance, activating one pathway for cellular growth and another pathway for cell migration,
for the cell to actually move and maybe another pathway to talk to another cell to stimulate, say, the growth of blood vessels.
In other words, lots of different or pleiotropic effects.
This is important because when we're talking
about peptide therapeutics, rarely if ever,
are we talking about a very targeted
and very specific effect of these peptides.
And this is important both in terms of thinking
about what effects you're going to get
of taking a given peptide if you decide to do that,
as well as potential side effects,
as well as things like how to adjust dosage
and how long to take a peptide,
whether or not to cycle the peptide, et cetera.
So I just gave you a very simple description
of what a peptide is and the fact that they have
pleiotropic, meaning many different effects,
both within cells and across different cell types,
and of course, across different organ systems.
So rarely, if ever, will you hear
that a peptide does one thing.
Most often, the peptide does anywhere
from four to maybe even a thousand different things.
And again, we can go back to our basic examples
of peptides like insulin, like oxytocin,
and say, for instance, oxytocin,
it's known to be involved in milk letdown during lactation.
It's also known to be involved in pair bonding
in both males and females,
as well as pair bonding between parent and child,
maybe even parent and pet.
So the point is that if you want
a specific biological effect,
maybe you want to repair a given injury,
or you'd like to get more growth hormone in order,
I don't know, to get leaner
or to recover from exercise more quickly or to feel more growth hormone in order, I don't know, to get leaner or to recover from exercise more quickly
or to feel more vitality.
Yes, there are peptides that can impact those pathways,
but always, always, always, if you take peptides,
especially therapeutic peptides,
designed to promote activity within a given pathway
for a specific purpose,
you are going to activate other pathways as well.
There's simply no way to remove the pleiotropic feature
of peptide therapeutics.
Nowadays, there's a lot of interest
and indeed growing interest in peptide therapeutics.
And there are really three different paths
by which people obtain these peptides.
The first is by prescription
from a board certified medical doctor.
So some peptides have been approved for one use,
but they can be prescribed also for off-label use.
And here we're talking about FDA approved
clinically tested peptides.
But in many cases, they've been clinically tested
for one particular area of medicine.
So for instance, the peptide sermorelin,
which promotes the release of growth hormone
has been FDA approved for the treatment of short stature,
but it is often now prescribed for other things as well,
where a physician and their patient
agree that augmenting the growth hormone pathway would be useful. Now, regardless of the specific
use in mind, it's absolutely clear that the safest and best situation, if one is going to use
therapeutic peptides, is to use prescription therapeutic peptides, where the prescription
comes from a board certified physician. And the reason for that is several fold.
First of all, sometimes these peptides
come from pharma companies.
Other times they are made by a compounding pharmacy.
But in both situations, they are cleaned
of what's called lippie polysaccharide or LPS.
LPS is something that can accumulate
in the manufacturing process of some of these peptides.
And it's something that you really want to remove
from the peptide before you ingest it or inject it.
Most peptides are injected,
either subcutaneously or into the muscle,
although some can be taken orally or even a topical cream.
We'll talk a little bit about different modes of delivery
a little bit later.
In any case, getting the LPS out
and making sure that the peptide is pure is very important.
The reason is that LPS causes an immune response.
And while a tiny amount of LPS
might not cause a massive immune response,
the accumulation of many, many LPS exposures
can start to become problematic.
And the other sources of peptides,
which are gray market and black market,
oftentimes do contain the same peptide
that one would get from a prescription from a board certified physician,
but very often they haven't cleaned out
the lipid polysaccharide, they haven't removed the LPS,
and that can start to create problems over time.
And of course, in the case of black market sources,
especially oftentimes the peptides are not
what they claim to be on the label
or from a particular source.
So that's especially problematic.
So I want to be very clear about my stance on this.
If you are going to explore peptide therapeutics,
I highly, highly recommend, indeed,
I implore you to do so with a board certified physician
and to acquire peptides through a reliable source
where the LPS has been removed,
which typically means from a pharma company
or from a compounding pharmacy.
Okay, so let's talk about specific peptides
for specific purposes.
Today, we're going to cover four general areas
in which peptide therapeutics can be useful.
The first is for rejuvenation and repair
of basically any tissue,
but in particular, muscle and connective tissue, so sports type injuries,
but also things like gut.
So for people that suffer from IBS,
irritable bowel syndrome, or from colitis,
or from other gut issues,
there is a potential use for therapeutic peptides.
Then we're going to discuss therapeutic peptides
for metabolism and growth of frankly, all tissues.
As soon as people hear metabolism and growth,
generally people think of fat loss and muscle growth.
And indeed those fall under this category,
but there are a bunch of other tissues
for which you may want to improve metabolism
and perhaps growth as well.
So we'll get into that.
Then we'll discuss therapeutic peptides
specifically for longevity, both staving off tumor growth,
as well as potentially,
and I want to highlight potentially, increasing lifespan,
although this is a very experimental area at present.
And then we'll talk about therapeutic peptides
for increasing vitality, both mood and libido
in both men and women.
Okay, so let's discuss peptides for rejuvenation
and repair of tissues.
Now, it's pretty common to injure a given tissue,
to strain a tendon or tear a ligament or break a bone
or any number of different things.
This is just part of life.
If you play sports or if you exercise frequently,
sooner or later, people tend to get injured.
And when one does,
there's a lot of different things one can do.
There's a lot of debate nowadays
about whether or not you should emphasize cold
or whether or not you should emphasize heat.
There seems to be a growing movement
towards emphasizing the use of heat
to increase blood flow to a given tissue
as opposed to cold.
We've covered some of this on other podcasts.
We'll cover it more on future podcasts.
But if you happen to injure yourself,
typically what your physician will say is rest,
maybe do some physical therapy.
And indeed those are excellent things to do,
but one of course would ask,
is there anything I can take in order to accelerate
the healing of a given injury?
And for that purpose,
a lot of people over the years have explored
the use of different peptides,
in particular one that exists within the body naturally,
and that is involved in wound healing and repair.
And that peptide is BPC,
which stands for Body Protection Compound 157.
BPC 157 is a synthetic peptide.
It's manufactured in a laboratory to resemble a peptide
that exists naturally within our gut.
Now, why would we have a naturally occurring peptide, a protein within our gut
that's involved in wound healing and repair?
Now, the answer to this is entirely clear.
And as I always say, anytime you want to answer a question
about kind of why something evolved to be a particular way,
you have to remember that neither I nor anyone else
who was involved in the design phase,
it just is what it is.
So we have to be careful about making up just-so stories
about why something is doing what it's doing
or how it got there.
So why would there be a peptide within the gut
that's involved in tissue healing and repair?
Well, in order to understand that,
it's important to understand that the lining of your gut
all along its length involves a bunch of different layers
of cells that turn over at a pretty frequent rate.
So unlike your brain cells that for instance,
after about age 25, you're not adding
or deleting many brain cells,
at least provided there's no injury
or neurodegenerative disease,
you're not removing a lot of those brain cells,
but you're also not adding many brain cells.
There are a few areas of the brain,
like the olfactory bulb and the dentate gyrus
at the hippocampus where there is some turnover,
but for the most part, the neurons you have at about age 25
are the neurons that you're going to have
for the rest of your life.
Your gut is very different.
Within the milieu of the gut,
you have a lot of turnover of cells.
And the turnover of cells in the gut is in many ways,
the same sort of turnover process
that's involved in wound healing and repair.
Like if you cut your skin,
another tissue or organ in this case,
that involves a lot of turnover of cells. Because as you know, if you cut your skin, at tissue or organ in this case, that involves a lot of turnover of cells.
Because as you know, if you cut your skin,
at some point it will heal up.
First there'll be a scab, then that scab will give way
as the tissue underneath it mends.
And that mending of the tissue is the addition
of new skin cells as well as other cell types.
So the fact that there is a peptide in our gut
that can be involved in tissue turnover,
and tissue turnover is equivalent to tissue repair
is not all that surprising.
Now it's important to understand
that anytime we're discussing tissue rejuvenation,
that is cellular turnover or tissue repair,
so any kind of wound healing, a small wound or a big wound,
it almost certainly is going to involve angiogenesis,
which is the development of new vascular supply or blood supply.
Now, of course, vascular supply arrives
by capillaries, veins, and arteries.
And typically when we're talking about angiogenesis
in the context of tissue rejuvenation and repair,
we're talking about the addition of new capillaries
and or blood vessels.
And that means the addition of new,
what are called endothelial cells,
which are the cells that make up the walls of those blood vessels. And that means the addition of new, what are called endothelial cells, which are the cells that make up the walls
of those blood vessels.
So put simply, if you want to rejuvenate a tissue
or you want to repair a tissue,
you need additional blood supply.
And one of the clear effects of BPC 157
is to both encourage cellular turnover
as well as cellular migration.
So new cells and cells moving into a given area,
as well as new blood supply through the promotion
of this process we call angiogenesis.
So you can imagine, for instance,
that maybe you injure your elbow.
And you do so in a way that impacts
a bunch of different tissues.
Maybe some of the nerve cells,
the neurons there are severed, okay, or crushed.
So that might lead to some pain there,
but it might also lead to some inability
to move that joint or that limb,
as well as you could previously.
Probably also some damage or some crushing
to some ligament tissue and some tendon tissue,
maybe even to some musculature.
A bunch of different tissues are impacted.
And one of the things that BPC-157
has been shown to do in animal studies,
and I really want to emphasize animal studies,
because that's where the vast, vast, vast majority
of data on BPC-157 come from.
Well, it's been shown to increase blood flow
to a given area by virtue of increased angiogenesis.
So basically to promote the development
of new blood vessels to the entire injury site.
And the way it does that is very interesting.
BPC-157 somehow is able to recognize
injured blood vessels and injured capillaries,
and then to promote the activity of a given enzyme
called ENOS or endothelial nitric oxide synthase,
which then causes more blood vasculature to form
at the injury site and around the injury site.
That in turn allows for the delivery, not just of blood,
but for the stuff that's contained within blood,
including growth factors that then promote
the further rejuvenation of different cell types
in the given area.
So the things that could potentially lead
to repair of muscle, repair of ligament,
repair of tendon, et cetera.
And then BPC 157 is known to further encourage
the growth of capillaries and veins within the injury area.
So it both calls in the development of new vasculature
and it promotes the growth of that new vasculature.
BPC157 is also known from animal studies
to encourage fibroblast migration and growth
within a site of injury.
Fibroblasts are a key cell type within an injury
and they provide some of the really firm,
strong substrate for bridging injuries
and that allow different things like tendons and ligaments
to restore themselves from say torn or partially torn
to a complete tendon or ligament.
Now there's a very long and kind of interesting history
of the use of gastric juices.
Okay, I know the term might make a few people queasy,
but gastric juices to promote tissue healing and repair.
Now there's a whole history of focusing on gastric juices
or at least the stomach environment
for keeping given tissues alive
so that they can be repaired later.
I know this sounds a bit gruesome,
but one can find in the historical medical literature,
instances of people say severing off a finger
or even a hand or things of that sort.
And then it being placed by a surgeon, of course,
or in some cases, these were battlefield situations
into the gut as a way to preserve that finger or hand
and keep it alive essentially.
And then to graft it back on
or to make an attempt to graft it back on
so that the person could then use those fingers
or that hand again.
And while not always successful, it was clear,
or at least the idea started to form
that tissues that were placed inside the milieu of the gut
stood a better chance of being grafted back on.
Now you could think of a number of different factors
that could impact the improved grafting
of tissues placed in the gut
until the graft could take place.
You know, it could be the heat of the environment.
It could be the fact that the hand or finger
is not exposed to things out in the world.
So less bacteria, et cetera.
Nonetheless, physicians were intrigued by the idea
that maybe something within the gut itself,
and in particular within gastric juices,
were beneficial for preserving
and maybe even rejuvenating tissues.
And one particular peptide compound turned out to be BPC,
body protection compound,
which again is synthesized as BPC 157.
So there's a real logic here,
but what we haven't really addressed is
if one has an injury, let's say to the hand
or to the arm or to the leg or to the ankle
or to the Achilles tendon,
how is it that body protection compound
that normally would exist within the gut
actually access that injured tissue?
Now, this still remains somewhat of a mystery.
It is clear that BPC-157 can exit the gut,
but how it gets traffic to particular sites
within the body that are injured still isn't clear.
That said, within the community of people
that use BPC-157 for therapeutic reasons
for tissue rejuvenation and repair,
there's been an ongoing debate
as to whether or not you can take it systemically,
that is to inject it or even take it orally
and that it will find the site of injury, right?
It'll go direct itself to the site of injury
or whether or not it's more beneficial
to inject it directly to the site of injury.
And here there's really no formal science.
I want to be really clear.
When we talk about BPC-157,
we can look to a pretty large literature
of peer-reviewed studies,
dating back to about 1993 is when the first kind
of rigorous study of BPC-157 really began.
And there are a lot of studies in rats, in mice,
and a few other species as well.
To my knowledge, there is only one study on humans
and it's not a clinical trial.
And frankly, it's not the best performed study
and that's putting it mildly.
It's more kind of self-report of people recovering
from a given injury, whether or not they took BPC-157
or they didn't.
So when we talk about BPC-157,
we're talking about a pretty unusual circumstance
whereby many, many people are now taking it.
Very likely hundreds of thousands,
perhaps even now into the millions,
but we actually have essentially no human data
as to how BPC-157 works in humans and why it does seem,
because this seems to be the quote unquote,
anic data to accelerate healing
of a variety of different injuries.
Okay, so it's an unusual circumstance
and it's kind of an unusual thing
for us to talk about here on the podcast.
Yes, we've talked about supplements
and yes, we've talked about different hormone therapies
and yes, we've talked about any number of different things
but it's pretty unusual to have so much animal literature.
I even would go so far as to say quality studies
of BPC 157 and its effects in animal models such as rats and mice,
and such a dearth of formal rigorous exploration
of BPC-157 in humans.
And at the same time, a,
gosh, let's just call it what it is,
a really rich set of ANIC data,
meaning that many, many people,
perhaps even most people who take BPC-157,
by the way, the typical route of taking BPC-157
is either to inject it subcutaneously or into the muscle.
And to do that, regardless of where the injury is,
they'll do that in one particular site.
So subcutaneously, just a few inches off the belly button
or into the shoulder or something of that sort
if they're doing it intramuscularly.
Or in some cases, people will direct it
to the site of injury by injecting more local.
Like if you have an elbow injury,
they'll put it into the muscle right above the elbow
or subcutaneously right above the elbow.
And we're now in a situation where we don't know
if we're dealing with pure placebo effect
or we are dealing with real effects.
And so because of the lack of the human clinical studies,
we don't know whether or not we're dealing
with a situation of robust placebo effects.
I did an episode all about placebo effects
and placebo effects are, and can be oh so real.
They really can really trick you into thinking
that a given compound is doing something
when in fact it's not doing anything different
than would an injection of saline, of salt water.
But in this case, there's just such an overwhelming amount
of what I call ANIC data.
And there are so many people using BPC-157 now
and are interested in starting to use BPC-157
that I'd be remiss if I didn't discuss it
despite this gap in the human clinical literature.
So what do we know from the ANIC data?
The ANIC data seemed to indicate that the mode of delivery,
that is whether or not systemic or local,
doesn't seem to matter that much.
Although some people, for for whatever reason will purport
that local injections serve recovery of the tissue
more readily than systemic injections.
Now there are a couple of things to understand
about BPC 157, besides the fact that in animal studies
it's been shown to increase fibroblast migration
to a site of injury, as well as endothelial cell
and vascular growth to a site of injury.
And the first thing is that injury seems to be important.
There does seem to be something that the injury signals
to BPC 157 to create new vasculature
and fibroblast growth there at the site of injury.
There's no evidence from these animal studies,
at least to my knowledge,
that BPC 157 systemically increases vascular growth,
although one could imagine that it might, right?
And for that reason, I'll talk about some cautionary notes
about BPC-157 as it relates to tumor growth
and cancers and diseases, in particular of the eye,
that involve overgrowth of vasculature.
But before I do that, I want to talk a little bit
about the safety of BPC-157.
One of the reasons why it's being used so extensively
is that it does seem to have very high safety profiles,
at least with respect to the lethal dosing, right?
In order to find out the lethal dose of something,
as you can imagine, unfortunately,
the way these studies are done
is they give animals more and more,
that is higher and higher doses of a given compound,
find out at what point about 50% of the population
of those animals starts to die.
And then that's the so-called LD50,
or at least that's one crude way of describing it.
The LD50 of BPC157 is incredibly high, okay?
It is as high as two grams, okay?
Two grams, 2000 milligrams that is,
per kilogram of body weight.
Now that does not mean, please hear me on this,
that does not mean that anyone should be taking
high dosages of BPC-157.
The typical therapeutic doses that are prescribed
are anywhere from 300 to 500 micrograms subcutaneously,
maybe two or three times per week.
And that is typically done for a course of about eight weeks.
And then people typically cycle off
for anywhere from eight to 10 weeks.
Now, when I say typically, I mean typically,
because there are individuals
that take BPC-157 consistently.
They just take it every day
and they'll just take it indefinitely without any breaks.
I think that is a bad idea.
And I want to also state
that I am not suggesting anyone run out and take BPC-157.
Today's episode is really about giving you information
so that you can make the determination
whether or not you even want to take BPC-157
or another peptide.
And of course, to really seriously consider
the sourcing issue that we talked about earlier.
Now, what would be a reason to avoid taking BPC-157?
Well, the first relates to something
that many people take BPC-157 for
because they believe it's good for them.
And in some cases potentially could be,
which is that in addition to increasing
fibroblast migration and angiogenesis,
blood vessel development within a site of injury,
BPC-157 is known to have a small,
but nonetheless meaningful impact
on upregulating growth hormone receptors. Now, this can be a good thing if you're trying to upregulating growth hormone receptors.
Now, this can be a good thing
if you're trying to upregulate growth hormone receptors
at a given injury site, so that growth hormone,
which comes from the pituitary,
and then we'll talk a bit about more later,
then can have a heightened level of action at that tissue,
and growth hormone is involved
in tissue turnover and repair.
This is evident from childhood
where kids heal from wounds much faster
than adults heal from wounds.
There's other reasons why kids heal from wounds
more quickly than adults that relate to things
like stuff secrete from the thymus, et cetera.
We'll talk about that as well.
But this idea of increasing growth hormone receptors
at the site of injury or around the site of injury
by injecting BPC-157 locally to the injury
or even taking it systemically
is one thing that many people think of as advantageous
and that's why they want to take BPC-157.
However, for some people,
perhaps people who have a tumor in a given area,
an increase in growth hormone receptors
in and around the tumor could potentially increase
the growth of the tumor.
And that's one of the major issues with BPC-157
that's not often discussed,
which is that if you have a tumor
and tumors thrive on increased blood flow
because they like to consume growth factors
and increased blood flow means increased growth factors
and other things that can not just sustain,
but actually grow the tumor,
well, then by taking BPC-157,
you may be either maintaining
or accelerating the growth of a tumor
that would otherwise be removed or stay small.
In other words, BPC-157 is a potential tumor growth risk.
So if you have knowledge of a given cancer
or you're concerned about tumors at all,
I would encourage you to be very cautious
about the use of BPC-157.
In fact, one way that BPC-157
creates this increase in angiogenesis,
this increase in vasculature,
is through upregulation of something called VEGF,
V-E-G-F, which is vascular endothelial growth factor.
Now, there is a common treatment for cancers,
which is Avastin.
Avastin is a VEGF inhibitor.
It's a drug that's designed to fight tumors,
to reduce tumor size, and does so by inhibiting VEGF.
Whereas BPC-157 is doing the exact opposite.
It is increasing levels of VEGF to increase angiogenesis.
So by logical extension,
if you're concerned about tumors or cancer of any kind,
BPC-157 is probably not something that you want to explore.
So if BPC-157 carries these risks,
why are so many people interested in taking it or taking it?
I think in large part that's due to the fact that
the ANIC data about BPC-157 is just so strong.
People report all sorts of things like,
they recovered from their shoulder injury much faster.
There are these kind of outrageous claims
about people recovering from complete tissue transections.
And indeed there, the animal data are pretty impressive.
I went into the data that looked
at sciatic nerve regrowth after injury,
Achilles tendon regrowth after injury.
And some of these studies in rats involved
a complete transaction, not just a partial tear
but a complete cut of a given ligament
or tendon or nerve pathway.
And indeed the data are pretty impressive
that when BPC 157 is applied systemically, right?
So given, you know, at the level of the gut,
somehow it's able to travel to the site of injury,
recognize that something needs to be done there
in particular angiogenesis and fibroblast infiltration.
And it does seem that on average,
that these tissues repair faster
than they do if BPC-157 is not provided.
But again, the tumor concerns and the lack of human data repair faster than they do if BPC-157 is not provided.
But again, the tumor concerns and the lack of human data
are a real concern that everyone should be made aware of.
I do not think that BPC-157
is not without its quote unquote side effects.
I do think that we are now in a state
of widespread experimental use of BPC-157,
even though it can be obtained clean without LPS
from compounding pharmacies and by prescription,
there are a lot of people taking BPC-157.
And I just want to return to the point I made earlier,
which is that, you know, BPC-157 is typically taken
in these dosages of about 300 to 500 micrograms,
you know, two to three times per week,
maybe even five days per week.
If you're going to go down this path of taking BPC-157,
I would encourage you to take the minimal effective dose
to not just simply do it every day
and certainly to not do it continuously.
And of course, to monitor your other health metrics
for anything that could potentially resemble cancer
or tumor growth.
Because obviously stimulating angiogenesis for wound repair
sounds like a great thing,
recovering and being able to do your workouts
or play your sport or move about more comfortably.
Of course, a wonderfully attractive thing to do.
Isn't that what we all want?
But obviously not with the trade-off of growing a tumor
or developing a cancer or accelerating a cancer.
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Okay, so we're still talking about peptides
for tissue rejuvenation and repair.
And we spent quite a bit of time on BPC 157
because that's one getting a lot of attention nowadays.
There's another one that's getting increasing attention
that's worth mentioning, which is thymacin beta-4
and a related peptide, which is TB 500,
which is basically a truncated or a shortened version
of the thymacin beta-4 peptide.
Remember the peptide are these strings of amino acids
like beads on a string.
And thymus and beta-4 is something
that the body produces naturally
from this thing called the thymus,
which is present in children
and then disappears as we get older.
And it's well known, again, this is correlative,
but it's well known that children
recover more quickly
from injuries and indeed the degree of tissue regrowth
and the repair of wounds with minimal scarring
is so much greater in young children
and in children than it is in adults.
And this is what gave rise to the idea
that perhaps some of the peptides
that are secreted from the thymus,
such as thymus in beta-4,
could be involved in tissue rejuvenation and repair.
And that's what led to the laboratory synthesis
of thymus and beta-4, the full length peptide made in a lab,
not by the thymus and then adults take it, okay?
Or TB 500, which is this truncated,
slightly shortened version of thymus and beta-4,
which acts similarly to thymus and beta-4,
but has a kind of different mode of action,
lasts a little bit longer, et cetera.
Now, again, we're in a situation
where there are vast amounts of animal data,
studies on mice or rats typically,
that show that thymus and beta four
can increase the rate and or thoroughness
of wound healing and repair.
But again, there are more and more people
now taking thymus and beta four
for the purposes of tissue rejuvenation and repair
and report positive effects.
Now, when we say positive effects,
we have to stand back and say,
well, what's the control experiment?
How would they know how quickly they would heal
without the thymus in beta four?
And there's simply no way to address that question.
My whole purpose in doing this episode is to highlight
how these different molecules ought to work,
how they've been shown to work in animal models,
and therefore how they might be working in humans.
But again, in the absence of clinical trials,
we still don't know if and how they are working in humans.
Nonetheless, a lot of people are now starting to take
especially TB 500.
It's often taken in combination with BPC 157.
And at the level of mechanism,
the difference between BPC 157 and thymus and beta four
is that thymus and beta four is that thymus and beta four
really promotes the growth and infiltration
of all sorts of different cell types associated
with tissue rejuvenation and especially wound healing
and repair.
It's been shown to promote stem cell proliferation.
It's been shown to increase the growth
of the so-called extracellular matrix,
the stuff around the cells that keeps the area
around the cells kind of rigid,
so that the tissue or the organ has more stability, right?
You can't just have a bunch of cells
with a bunch of empty space around them
where they can move about.
You want to have some rigidity to the whole thing.
So the idea is that thymosin beta-4 is promoting
the aggregation of a bunch of things
associated with tissue healing.
I've noticed out there that a lot of people talk
about TB 500, that is thymus and beta four,
in the context of being growth promoting.
As far as I know, it isn't growth promoting.
It doesn't impact the growth hormone pathway
or other pathways associated with tissue growth.
Rather, it's involved in tissue repair.
So what I just discussed are the two major players
or the two most often used peptides nowadays
for tissue rejuvenation and repair.
We've got BPC 157, which you can just basically frame up
in your mind as promoting angiogenesis and wound repair
through a variety of mechanisms,
but mainly the addition of new vasculature to the wound site.
And then we've got thymus and beta-4,
which is sometimes referred to as TB 500,
which is just a shorter synthesized version
of thymus and beta-4, which is a molecule known
to come from the thymus in children.
Whether or not it's solely responsible,
I doubt it's solely responsible in fact,
for the better tissue healing and repair seen in children
as opposed to adults, we don't know.
And yet it does seem at least anecdotally
that people are taking TB 500 again,
either alone or in combination with BPC 157,
and at least to their mind are reporting more thorough or more rapid tissue
rejuvenation and repair.
So the next category of peptide effects
that I'd like to talk about
are the effects of certain peptides
on metabolism and growth.
And any discussion about metabolism and growth,
by definition has to include a discussion
about growth hormones.
So basically where we're headed
is a discussion about peptides
that can increase amounts
of growth hormone that are released in our brain
and body to have specific effects,
in particular increases in metabolism
and increases in either muscle growth
and in some cases repair of tissues as well,
although mainly muscle growth and fat loss.
For those of you that aren't familiar with growth hormone,
growth hormone is a hormone that we naturally make.
It's secreted from a gland called the pituitary gland.
The pituitary sits near the roof of the mouth
and it extends out of the stock of the brain
such that it can release hormones
into the general bloodstream.
The pituitary is connected to the brain, however,
so it can get input from a brain area called the hypothalamus.
And within the hypothalamus,
there are neurons that can send signals to the pituitary
telling it to either release growth hormone
or to suppress the release of growth hormone.
Now, early in life, when we are infants, children,
teenagers, and so on, we secrete tons of growth hormone,
in particular during the early hours of sleep each night.
We also secrete growth hormone a little bit
throughout the day, but it's really in sleep in which we have the greatest degree of growth each night. We also secrete growth hormone a little bit throughout the day, but it's really in sleep
in which we have the greatest degree
of growth hormone release.
This is one reason why babies and kids and teenagers
sleep so much is there's a lot of growth hormone release
and we tend to grow, that is the tissues and limbs
of our body tend to grow during sleep.
Now, it's been well-documented that after about age 30,
which is typically when people experience
their full stature, their full height,
although sometimes there's a little bit of wiggle room
around that age, typically after 30,
the amount of growth hormone that's released each night
and throughout the day is reduced by about 15%
for every decade of life.
As a consequence, all of the things that growth hormone does
like encouraging higher metabolism, fat loss,
the growth of muscle tissue, et cetera,
is dramatically reduced as we go from 30 to 40 to 50
and on and on.
It's also the case that naturally released growth hormone
tends to have positive effects on our mood
and overall feelings of wellbeing.
So it's also tied to our feelings of vitality
or having feelings of energy to do things.
And that's because growth hormone
potently increases ATP production,
which is involved in energy and metabolism in our cells.
And as a consequence, our overall feelings of energy
to just do things, mental or physical.
Now there's another hormone called IGF-1
or insulin growth factor one,
which is produced by the liver.
Insulin growth factor one
does many things similar to growth hormone and it actually is released
in response to growth hormone.
So basically the way this works is that there's a signal
that comes from the hypothalamus called growth hormone
releasing hormone.
And then that signal stimulates the anterior pituitary
to release growth hormone.
Growth hormone then is circulated throughout the blood.
It also can access the brain itself
and it does different things in different tissues.
But again, increases ATP production for energy.
It is going to cause tissue repair in some cases.
It's also going to encourage growth of tissues,
not just muscles, but other tissues.
And that's why it's involved in helping us achieve
our full height, our full stature.
When growth hormone reaches the liver,
it stimulates the release of IGF-1,
which in turn does a number of things that are both synergistic and different.
That is, it works both similarly to growth hormone and does some things in parallel that
are a little bit different as well. In particular, things related to regulation of blood sugar
metabolism, et cetera, all things associated with kind of youthfulness, vitality, and energy.
So it's impossible for me to say that growth hormone and IGF-1 do just one thing each.
They do lots of different things
in lots of different tissues.
But hopefully from the description I just gave,
you could see why some people might be interested
in augmenting or increasing levels of growth hormone.
Now, growth hormone has been sequenced and synthesized.
So you can buy a synthetic version of growth hormone.
And indeed, some people will take
prescription growth hormone.
They'll take this by, typically it's an injection
that's given subcutaneously at night
and they achieve growth of tissues,
including muscle, et cetera.
Keep in mind that growth hormone is indiscriminate
with respect to which tissues it grows.
So if you happen to have an existing tumor
on a given body part or within a given body part,
it will encourage growth of that tumor as well.
That's one of the reasons some people are cautious about taking growth hormone. Another reason why many people
are cautious about taking growth hormone is that it is subject to what's called negative feedback.
If your blood levels of growth hormone are too high by virtue of injecting growth hormone,
well, then the pituitary can register that and the brain can register that. And then there's a
negative feedback that shuts down growth hormone.
As a consequence, people have developed
peptide therapeutics that stimulate
the release of growth hormone
and thereby the release of IGF-1,
but not by directly stimulating the growth hormone pathway.
Typically what these peptides are,
are these are peptides that mimic the sorts of things
that are typically released from the hypothalamus
onto the pituitary and in that way, stimulate the sorts of things that are typically released from the hypothalamus onto the pituitary,
and in that way, stimulate the release of growth hormone
and downstream IGF-1.
So what these things are typically called are secretagogues.
These are peptide molecules that have been synthesized
in a laboratory that stimulate the release
of growth hormone and thereby stimulate
the production of IGF-1.
Now there are two general categories of peptides
for stimulating the release of growth hormone.
The first category oftentimes are referred to
as the GHRH peptides for growth hormone
releasing hormone peptides.
Now that name has certain problems
that we'll get to in a moment,
but let's just leave it there for the time being.
The second category are what's called
the growth hormone releasing peptides, right? Before we said growth hormone releasing hormones, that's the time being. The second category are what's called the growth hormone releasing peptides, right?
Before we said growth hormone releasing hormones,
that's the first category.
Second ones are the growth hormone releasing peptides.
You can already tell why this is getting confusing.
Here's what I'm going to do.
Rather than use that nomenclature,
which is the typical nomenclature that's used,
and I must say for which there's a lot of errors
when I look out there on various YouTube videos
and I look within even some of the reviews
that have been written,
people get things confused as to whether or not
a given peptide that one would use as a therapeutic
falls into one or the other category.
And you'll see in a minute,
it's a really important distinction.
Instead, what I'm going to call these
are category one peptides and category two peptides, okay?
In general, category one peptides
are going to be the ones that have been most thoroughly
tested in humans in some cases.
In fact, in several cases are FDA approved
for certain conditions and yes are prescribed
for other off-label effects.
Again, this would be under what I'm calling type one
growth hormone secreting peptides is Cermerelin.
Cermerelin is a synthetic compound
designed to mimic naturally occurring growth hormone
releasing hormone that is FDA approved
for the treatment of short stature.
So you can get this by prescription.
Sometimes it comes from a compounding pharmacy.
Other times it comes directly from Pharma
for the name brand.
In any case, Cermerelin has been shown to mimic
what is normally released from the hypothalamus
and stimulates the pituitary to release growth hormone.
And it does indeed cause increases
in circulating growth hormone and increases in IGF-1.
By the way, the typical dosages of Cermerelin that are taken
are anywhere from 200 to 400 micrograms.
Typically that's done at night before sleep
for the reasons that we talked about before.
And typically people will take it anywhere
from three times per week or five times per week.
There are some disadvantages to taking it continuously
seven days per week for long periods of time.
There's some desensitization that can occur.
Not much, but some can occur.
So taken in that way,
sermorelin has been shown to increase circulating levels
of growth hormone and IGF-1. And the reason why a lot of people seek way, sermorelin has been shown to increase circulating levels of growth hormone and IGF-1.
And the reason why a lot of people seek to take sermorelin
is because they like the effects it produces.
They like the vitality, they like the muscle growth,
they like the fat loss.
It also can increase the amount of deep sleep that you get.
I'll just be completely forthcoming.
I've taken sermorelin on and off
for the last couple of years.
I typically will take it anywhere
from one to two nights per week. I typically will take it anywhere from one
to two nights per week.
And I stopped taking it almost completely.
I'll still take it every once in a great while.
But the reason I stopped taking it is that I noticed
that it made the sleep in the early part of my night
very, very deep, very robust.
But then I would wake up wide awake
or I would sleep till morning.
And then at least according to my eight sleep sleep tracker
or my whoop sleep tracker,
I wasn't getting nearly as much rapid eye movement sleep
as I normally would.
So at least in my case, and again, this is anecdotal,
it seemed to sort of replace rapid eye movement sleep
with more deep sleep.
And rapid eye movement sleep is critical
for all sorts of things that deep sleep can't achieve
and vice versa. So you really want both.
So this is one reason why I've basically stopped taking
Sormoril and I'll occasionally take it
every once in a while.
But in general, I just, you know, stop taking it
because whatever the positive effects might've been
if I had taken it more consistently,
the effects in depleting rapid eye movement sleep
were just something I didn't want and don't want.
And by the way, that effect on increasing deep sleep,
that non REM sleep is something
that's pretty well documented.
The other, what I'm calling type one,
growth hormone promoting peptide is Tessamerelin.
This goes by the brand name Agrifta,
and it's an FDA approved drug
for the reduction of visceral adiposity in HIV patients.
So we have subcutaneous fat
and we have visceral fat around our organs.
Visceral fat can be really problematic.
And for some people who have HIV
or even for people who don't have HIV,
the deposits of visceral fat
can be problematic for their health.
And tessamerelin, again, also called agrifta,
has been shown to reduce visceral adiposity.
It also seems to produce some of the other same effects
that sermorelin produces.
The differences between the two relate to small differences
in the amino acid sequence for one peptide versus the other.
Tessamerelin is a bit more long lasting than sermorelin
and therefore is taken typically about three times per week,
not five times per week.
Now, the third most commonly used peptide in this category
of what I'm calling type one growth hormone secreting
peptides is CJC1295.
Gosh, I wish there was an easier name.
CJC1295 is basically a variant
of a different growth hormone secreting peptide
that was synthesized previously
to which they add what's called a DAC,
a drug affinity complex.
It's a sequence that makes it very long lasting.
So CJC1295 typically is only taken twice per week
or even once per week,
because its effects on increasing growth hormone
in IGF-1 last several days,
which may sound great to you,
especially if you're somebody that doesn't like
taking injections because these things in general
have to be delivered by injection.
But keep in mind that CJC 1295 has entered clinical trials.
There was a death within one of the clinical trials
that was related to cardiovascular dysfunction.
It's known to cause some fluid retention
and increased fluid volume,
which may have been related to that cardiovascular death.
We don't know, okay?
This is all kind of speculation.
But I would say if you are somebody considering using
a growth hormone
secreting peptide, the type one category is perhaps,
and I'll give my explanation for why I believe this
to be the case, perhaps the most advantageous category
to explore, and as I mentioned before,
you've got the options of sermorelin and tessemorelin,
both of which are FDA approved and for which there's both
animal and human data.
CJC 1295, despite still being in clinical trials,
does have this kind of stain of a death
within the clinical trial.
And to my mind, given that there are decent alternatives
in sermorelin or tessamerelin,
I don't know why anyone would specifically select CJC 1295
until all these safety issues have been resolved.
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Okay, so there are definitely other synthetic growth hormone
releasing hormone peptides that are out there,
but I think these three that we've covered,
Cermerellin, Tessamerellin, and CJC1295
account for the vast majority
of those that I put into category one.
The other category, which I'm going to call category two,
you'll also hear a lot about,
and they operate a little bit differently.
These peptides encourage the release of growth hormone,
but they do so either by mimicking
or stimulating the release of another peptide called ghrelin.
Some of you may be familiar with ghrelin
because ghrelin is a peptide that increases
in concentration when we are hungry.
So it stimulates hunger
and it also stimulates anxiety somewhat.
So you may be wondering why would anyone want to increase
levels of growth hormone and ghrelin.
And the reason is that the ghrelin itself can impact
the growth hormone pathway pretty potently.
So you can get really robust increases in growth hormone,
but because there are ghrelin increases as well,
you get big increases in hunger and anxiety in some people
and lesser in others.
Now the different names of the peptides
in this type two category are ones that you'll hear
kicked around a lot these days, things like ipomerelin.
Okay, so don't get ipomerelin confused with tessamerelin.
Right, tessamerelin is a type one growth hormone
releasing hormone peptide.
Ipomerelin is in this category too.
So it's definitely going to increase ghrelin,
which is going to increase hunger.
It does have certain advantages,
in particular that it increases growth hormone release
by two mechanisms.
It increases it directly,
and it tends to suppress something called somatostatin.
Somatostatin is a bit of a break
or an antagonist on growth hormone release.
So with hypermuralin, you're essentially removing the break
on growth hormone release,
allowing more growth hormone to be released
such that you get a lot of growth hormone released.
It also tends to really improve sleep,
but again, by increasing the amount of deep sleep,
we don't know whether or not it does that
at the expense of rapid eye movement sleep.
So, ipremerelin is the most commonly discussed one
in this type two category.
The other one that you'll hear about is called hexarelin.
Hexarelin is available by prescription
and it is the strongest stimulator of growth hormone release, which leads many people to think, okay, is called hexarelin. Hexarelin is available by prescription and it is the strongest stimulator
of growth hormone release,
which leads many people to think,
okay, I want hexarelin.
That's the one that's going to give me
the biggest growth hormone pulse.
And indeed the growth hormone pulses from hexarelin
can be as great as two or three times more
than with the other growth hormone secreting peptides
that we've talked about.
However, we know that hexarelin
can also dramatically increase prolactin,
which can cause suppression in libido,
it can cause fluid retention,
it can cause a kind of feeling of malaise,
especially at high levels.
And perhaps most problematically,
hexarelin can desensitize the receptors
for growth hormone releasing hormone,
such that your system will no longer respond
either to the hexarelin or to any other
peptide or perhaps most importantly to any endogenous that is naturally made growth hormones,
excuse me, releasing hormone that you would make. Okay. So that's something to really consider.
If you're going to explore hexarelin, make sure please that you're working with a physician,
make sure that you're not taking too much of it or for too long and keep an eye on those prolactin
levels because those can be problematic if they get too high.
And, you know, by my read,
I can't see why anyone would use high doses of hexarelin,
maybe low doses of hexarelin
if your doctor thinks that's what's appropriate for you,
but you'd really want to avoid that receptor desensitization
because you could essentially turn off the system permanently.
Now there are a bunch of other,
what I'm calling type two growth hormone promoting peptides.
These include GHRP2, GHRP3, GHRP6.
Again, different amino acid sequences,
all designed to achieve the same thing,
which is more growth hormone.
Things like GHRP3 can potently increase growth hormone,
but are known to also potently increase prolactin
and cortisol leading to more than a doubling
of circulating cortisol,
which depending on how well regulated it is
across the time of day can be problematic.
In other words, you want cortisol levels pretty high
in the early part of the day,
but you want them very, very low
in the later part of the day and at night.
And keep in mind that almost always
these growth hormone peptides,
whether or not they're type one or type two peptides
are taken before bed,
typically 20 or 30 minutes before sleep.
Always it's suggested that they be taken
at least an hour and a half after eating any food
and that you don't eat for at least 30 minutes afterwards.
Because if you happen to have elevated blood sugar
or you've got food in your gut,
they're not going to have as potent an effect
at increasing growth hormone and IGF-1.
So again, you want to avoid food in the hour and a half,
probably two hours before taking them,
and certainly in the half hour or longer after,
which is why most people take them right before going to
sleep and add or augment that big growth hormone pulse
that occurs in the early part of the night.
And then many people have perhaps heard of what's called
MK-677, which is simply an oral version,
a non-injectable, but oral version of these GHRPs.
And it tends to have the same issues
that the other GHRPs have, which are elevated cortisol,
and in some cases, elevated prolactin as well.
Okay, so if we just kind of zoom out from all this,
we can say that, yes, indeed, there are synthetic peptides
that can potently increase growth hormone in IGF-1.
I explained the rationale for why people would want that
or perhaps to explore that.
I'm certainly not suggesting anyone do this.
Again, I am suggesting that if you do explore it,
you work with a board certified physician
and that you get these compounds
from a quality compounding pharmacy
or by their name brand prescription.
In type one, we've got sermorelin and tessamerelin.
Both are FDA approved for certain purposes.
They're being used off label for increasing growth hormone
and IGF-1 for the sorts of things we're talking about here.
They are taken anywhere from three times per week
to five times per week.
Keep in mind, tessamelan lasts a little bit longer
than sermerelin.
CJC 1295 is the third in that category
of type one growth hormone secreting peptides,
but it may, again, may, we don't know,
have some safety issues that still need to be resolved,
making sermerelin and testimelan, at least to my mind,
better options should you decide to go down this path.
The type two growth hormone releasing peptides
include things like hexarelin,
which are very potent at increasing growth hormone,
but can potentially increase other things as well.
But of more concern is really that it can cause
receptor desensitization,
maybe even turn off the whole receptor pathway.
That would not be good.
Ipamerelin, again, increases growth hormone directly
and allows more of it to be released
by suppressing its break, its natural break,
which is somatostatin.
And then the GHRP2, 3, 6, and MK677,
all of which can potently increase growth hormone,
need to be considered in light of the fact
that they cause big increases in cortisol.
And in some cases can cause some receptor internalization
or desensitization as well,
although not as potently as hexarelin.
So hopefully that description clarifies
some of what you've heard out there
about these different compounds
and their different names, et cetera.
It can be very confusing.
I did take the liberty of designating a type one
and a type two category.
I did that for sake of clarity
because there are a lot of different acronyms
and numbers, et cetera,
that can be really confusing to people.
And I hope that that will be useful
in facilitating further discussions
about these compounds going forward.
Two additional brief, but important points.
Many of the peptide vendors that are out there
and physicians that are working with peptides
will combine different growth hormone promoting peptides.
So they'll, for instance, have sermorelin or tessimerelin
in combination with hexurelin, or they'll use ipamerelin in combination with hexorelin,
or they'll use hypermerelin in combination with CJC1295.
While I'm not opposed to that approach,
you just want to make sure that the dosing,
or I should say the relative dosing of each peptide
is such that you're avoiding unnecessary increases
in prolactin and cortisol,
and that you're not hitting a pathway redundantly.
That's actually the logic of combining different things.
These different amino acid sequences,
these different peptides that is,
are designed to stimulate different modes of action
for the same peptide.
So the naturally occurring peptide goes
and does a bunch of things, those pleiotropic effects,
and these different peptides
that are of different amino acid sequences
are designed to, you know,
reduce visceral adiposity a bit more,
or promote deep sleep a bit more,
or to promote muscle growth a bit more.
So when people are combining different things in cocktail,
it's not necessarily a bad thing,
but you want to make sure that you're working
with someone who's very familiar with peptides,
you know, really has been in the peptide space
for a long time and understands how these things work
alone and in combination.
And there are some excellent physicians that are doing that.
And we plan to have at least one of them
on the Huberman Lab podcast as a guest
in the not too distant future.
And you can bet that this conversation
will facilitate your understanding of that discussion.
The second point is that there are of course risks
to taking anything, but in particular to exploring augmentation
of the growth hormone pathway.
When people take growth hormone itself,
there are common risks such as carpal tunnel syndrome.
That has to do in part with the fact
that it can potently increase cartilage growth.
There can be active changes in the structure
of one's head and face and body.
There's a so-called lean but distended gut.
So people that aren't carrying a lot of subcutaneous fat
but that the gut becomes extended.
Sometimes you can get changes in the face,
like the kind of a thickening of the bone above the brow.
You'll see that.
And sometimes people will look quite different
after taking growth hormone for a series of time
than they did before.
It can really change one's stature
and shape
to a considerable degree.
It also can create a kind of a skin texture
that is a little bit unnatural or unusual.
You sometimes can see this in people
that take a lot of growth hormone.
In general, when people take growth hormone
promoting peptides, the changes in body structure
are not as dramatic as when people take growth
hormone itself, but body shape changes and cosmetic changes aside, keep in mind that anytime we augment
growth hormone, either by taking growth hormone directly as a synthetic compound or by taking a
peptide that increases the amount of growth hormone that we release. We are increasing our tumor growth risk and our cancer risk.
And that's because growth hormone and IGF-1
are somewhat indiscriminate in terms of the tissues
that they promote the growth of.
So if you have a tumor someplace and it's small,
taking exogenous growth hormone
or increasing the amount of growth hormone that you release
by taking one of these peptides that we discussed
will increase the size of that tumor, it's very likely. And you can imagine that if you by taking one of these peptides that we discussed will increase the size of that tumor.
It's very likely.
And you can imagine that if you're taking a peptide
to increase growth hormone
and you're taking something like BPC-157,
something that a lot of people are starting to do nowadays,
you could potentially increase both the size
and the vascularization of a given tumor.
So just keep that in mind,
just as there are anti-cancer drugs
that focus on the VEGF pathway
to try and discourage vascularization of tumors,
there are drugs that discourage the release of growth hormone
to discourage the growth of tumors.
So if you're listening to this, you might be thinking,
well, why in the world would anybody take this stuff?
Well, people like the effects
of having elevated growth hormone.
They like the effects of recovering
from an injury more quickly,
but there's always going to be a trade-off between potential benefit and potential risk.
The one thing that we can say for these growth hormone secretagogues,
sermorelin, tessamerelin in particular, is that they are FDA approved as compounds.
However, they are not approved for all the purposes that people are taking them for,
such as cosmetic effects, et cetera.
So I'm certainly not being disparaging of people that decide to make the choice to take these compounds.
That's your right entirely.
But I do think that you should be informed
about the potential risks.
And if you are somebody who's considering
taking any of these compounds,
there are certain considerations
that you definitely should pay attention to.
So for instance, how old are you?
If you're younger than 30,
I don't know why you'd want to augment growth hormone
unless you and your doctor decide
that there's a clinical need
or some other urgent need to do so because you why you'd want to augment growth hormone unless you and your doctor decide that there's a clinical need or some other urgent need
to do so because you're already making a lot
of growth hormone.
If you're older than 30 and you're interested
in using these compounds, to me, it stands to reason
that of course you want to make sure
that you don't have any tumors or cancers
that you could potentially exacerbate.
But in addition to that, that you really think
about using the minimal effective dose
and that you use perhaps even the mildest of these different compounds
in order to make sure that you don't desensitize
any of the receptor pathways.
And of course, there is no reason why anyone
should use these compounds
unless they absolutely feel they need to,
and there's a potential benefit there.
I personally, as I mentioned before,
tried Cermerelin for a short while.
The reductions in rapid eye movement sleep
were problematic enough for me
that I decided to just not take it. And it's not something that I've returned to except every once in a short while. The reductions in rapid eye movement sleep were problematic enough for me that I decided to just not take it.
And it's not something that I've returned to
except every once in a great while,
I might do it to augment deep sleep just a little bit.
The next category of peptide effects
that we're going to discuss
are peptides involved in longevity.
And this is actually going to be a pretty quick discussion
because really the main one in this category
besides thymus and beta-4,
remember thymus and beta-4 we talked about earlier?
This is a peptide that's naturally released from the thymus
and the thymus is a structure that depletes over time
as children age.
So some people will take thymus and beta-4
as kind of a longevity agent,
hoping that it will increase repair of tissues,
recovery from exercise, et cetera.
But it's not really aimed at longevity per se.
It's really aimed at replacing something
that's present in youth and then tends to dissipate
as we get older.
That is the thymus and related peptides from the thymus.
But the big one in the category of peptides
to potentially, I want to highlight potentially,
improve longevity is epithalin.
Epithalin is also sometimes spelled and pronounced epithalin.
Okay, don't ask me why.
And as with BPC 157,
there are quite a few animal studies exploring epithalin
and its effects on various tissues,
as well as the naturally occurring peptide
that it's meant to resemble.
Epithalin is a peptide that secreted from the pineal gland.
The pineal gland is a gland
that most people associate with melatonin release,
and that's because the cells within the pineal gland is a gland that most people associate with melatonin release. And that's because the cells within the pineal
called pinealocytes secrete melatonin at night.
It's what makes us feel sleepy and go to sleep.
Melatonin is suppressed by light viewed by the eyes.
There's actually a pathway that goes from the eyes
into the brain.
There are a couple of stages that go up
through the cervical ganglia and from the brainstem
and up to the pineal and suppress melatonin release.
Now the pineal makes other things besides melatonin.
It also makes a peptide called epithalamin.
Epithalamin is a peptide that is naturally released
from the pineal, especially early in life,
and that's associated with various anti-inflammatory effects
on other cells and tissues in the body.
And it does appear to be able to adjust telomere length, which is a feature of cells that's
thought to be associated with the longevity of cells or how long they live.
Keep in mind that the relationship between telomeres and longevity is a controversial
one.
People were very excited about this some years back.
Then people batted down that idea showing that telomere length was not associated with
longevity, especially in humans.
And now it's sort of a back and forth within the field.
Keep in mind that epithalin,
again, also sometimes written and pronounced epithalin,
is designed to mimic this naturally occurring peptide,
epithalamin, okay?
So the nomenclature can get a little bit confusing.
And what you'll find is that epithalin is available
as a synthetic compound.
It can be obtained in clean form from compounding pharmacies.
And a good number of people will use it
as a longevity agent based largely on animal data
that it can suppress tumor growth.
It can increase telomere length,
and to some extent that it can recalibrate
the circadian rhythm changes and the disruptions
in the patterns of melatonin that occur as animals
and perhaps as humans age.
This is an important point, the pineal gland,
despite being very, very small, about the size of a pea
and sitting kind of in the mid area of the brain
for you aficionados, it sits, you know,
kind of like right on the roof of the diencephalon.
And what it does is it will release melatonin each night
in darkness, it can release epithalium,
and at those times it can go and have these myriad effects
on restoring the brain and body during sleep.
There are other things that occur during sleep
that are essential, but those are key components
of the restorative features of sleep.
Now we know that as we age,
the amount of melatonin that we release is decreased
such that if you look in babies and teens, et cetera,
melatonin levels are very, very high
compared to people of middle age and of elderly age.
Likewise, epithelium levels decrease with time.
And as a consequence,
markers of tissue inflammation also increase as we age
because you're sort of removing
this anti-inflammatory compound that's released each night.
Now there are a bunch of theories
as to why the pineal regresses with age.
There's some kind of wild ones about fluoride
and depletion of the pineal.
I'll do a whole episode on the pineal at some point
and we'll explore that.
Some of them are very niche.
Some of them are frankly completely false and others have some merit and we'll explore that. Some of them are very niche. Some of them are frankly, completely false
and others have some merit and are starting to gain some data
within the standard scientific community.
The overall point here about peptides for longevity
can be summarized very easily.
The logic is just as we have a thymus early in life,
thymus secretes certain things
and those things seem to accelerate robust tissue healing early in life.
And as the thymus disappears,
tissue healing gets less robust.
That's the logic for taking things
like thymus and beta-4, TB 500.
So too, we have a tissue, the pineal,
that secrete certain things early in life
that are associated with lots of deep sleep
and robust tissue repair and long cellular life.
The logic then is by taking epitalin,
you can mimic this peptide that's normally released
from a nice, young, healthy pineal,
and in that sense, encourage anti-inflammation pathways
as well as cellular longevity pathways.
That's the basic idea.
And again, it rests largely on the animal data for
which, yes, there's some interesting studies showing suppression of age-related ocular diseases.
There's some nice studies showing telomere expansion. There's some nice studies showing
that several features of brain aging and body aging can indeed be partially offset by things
like epithelin peptides, but it is indeed a leap that people are taking
when they are deciding or taking epithalin
in order to extend their life, right?
The logic is all there,
but the pieces are sort of clujed together
between what we know about the animal studies,
what we know about the naturally occurring compounds
that these peptides are designed to mimic,
and yet there are still no clinical trials
that point directly to taking X amount of epithelin
several times per week as a way to extend life.
The fourth and final category of peptide effects
that we're going to talk about are effects on vitality,
both mood and libido.
And really the main players within this category of peptides
are the so-called melanocyte stimulating
hormone related peptides, okay?
Just to give you a little bit of background,
remember the pituitary?
The pituitary gland, that stalk that extends out of the brain
and can release growth hormone from the anterior pituitary,
well, it's got a middle segment or a medial segment,
and there's a hormone that's released from there
called melanocyte stimulating hormone.
Melanocyte stimulating hormone has the effect of stimulating pigmentation of the skin by activating what are called melanocyte stimulating hormone. Melanocyte stimulating hormone has the effect
of stimulating pigmentation of the skin
by activating what are called melanocytes
that exist within the skin.
So the peptides, melanotin-1, melanotin-2,
melanotin-3, melanotin-4, melanotin-5,
because there are five of them, are different peptides.
That is peptides with different amino acid sequences,
all of which mimic naturally occurring
melanocyteulating hormone,
but that act preferentially on one set of melanocytes
simulating hormone receptors or another
in order to get different effects.
So let's back up a little bit
and talk about the melanocortin system, right?
The melanocortin system is a system whereby viewing light
or getting light on the skin,
typically ultraviolet light of the ultraviolet B type.
Okay, there's two different types of ultraviolet light,
but basically sunlight is what the system evolved
to respond to, shown to the eyes and or to the skin,
stimulates the melanocortin system.
It goes from the eyes to the hypothalamus,
from the hypothalamus to the pituitary,
and then the melanocyte stimulating hormone
is then released into the bloodstream,
can travel to the melanocytes
and cause pigmentation of the skin.
This is what is responsible for tanning.
There's also a pathway whereby the light stimulates
the melanocyte stimulating hormone system,
and in parallel, it stimulates the release of dopamine.
Now, for any of you that have lived in a part of the world
in which it's very, very dark with very short days
in the winter and longer days
and a lot of sunlight during the summer,
you're probably familiar with the fact
that when the sun comes out, people start feeling better.
They have more energy, they're more motivated.
A number of different systems related to mood
and libido tend to increase.
This is the consequence of sunlight activating
the melanocortico system.
And by the way, this system is very active
in other animals as well.
Animals that are white or tend to be of pale color
during the winter.
Then as spring arrives,
the sunlight stimulates this very same system
and leads to darkening of the pelage.
So their hair goes from white or gray to brown
or even dark black or some combination of those.
And in combination, dopamine is increased,
libido is increased,
and the animals start breeding
in the spring and summer months.
Okay, so this is a well-conserved system across species,
and it exists to some extent in us as well.
So there are essentially five different synthetic peptides
called Melanotan-1, 2, 3, 4, and 5,
each of which is designed to mimic
melanocyte-simulating hormone,
but each of which activates different receptors
to different degrees,
and some can cross the blood-brain barrier and some can't.
And as a consequence, some impact mood and libido,
and others don't.
The simple way to look at this is that Melanotan-1
does not cross the blood-brain barrier.
It does, however, stimulate the melanocytes of the skin,
so it leads to tanning or darkening of the skin.
Melanotan-2, 3, 4, and 5 also lead to darkening of the skin
by way of activating melanocytes in the skin,
but because they can cross the blood-brain barrier,
they cause effects that are at the level of psychology,
really, and at the level of appetite
and things of that sort.
In general, the pattern is to increase mood and libido
and to decrease appetite.
Things that are associated with the transition
from winter to spring and summer months
in humans and in other animals.
Now, one of the things about the peptide literature
is that it loves acronyms and numbers.
And so there's a peptide PT-141
that falls into this category
of activating the melanocorticoid system.
And PT-141 is also known as the prescription drug, Vilece.
PT-141 or Vilece is FDA approved
for the treatment of premenopausal hypoactive sexual desire. So this is FDA approved for the treatment of premenopausal hypoactive sexual desire.
So this is FDA approved for the treatment of women
that have suppressed libido.
However, men also will take Vilece
for hypoactive sexual desire.
This is obviously prescribed off label by physicians,
but keep in mind, as with the other peptides in this pathway,
Vilece will stimulate pigmentation.
So whether or not you consider that a side effect
or a benefit depends on, I guess,
your baseline level of pigmentation
and how much level of pigmentation you actually want.
Now there are some side effects
associated with these compounds.
One of the more common ones is nausea.
And that's because there are melanocytes
simulating hormone receptors all throughout the gut.
They can also cause flushing of the skin
and they can cause blood pressure to increase.
Also folks with melanoma should be very cautious
about using any of the peptides that stimulate melanocytes
because that could potentially exacerbate melanoma.
The next peptide in this category,
peptides for vitality and libido, is kisspeptin.
Kisspeptin is a peptide that wasn't discovered
that long ago.
As you can recall, when the first papers
about kisspeptin came out.
And basically kisspeptin is a peptide
that is naturally made within the brain
and it's upstream of some of the hypothalamic signals
that activate the pituitary for sake
of hormone production
and reproduction.
So I'll just walk you through this pathway.
It's actually quite simple.
You've got the pituitary,
you're now familiar with the pituitary,
and the pituitary releases two different hormones
in both males and females.
It releases luteinizing hormone
and it releases follicle stimulating hormone.
If you watched the episodes that we did
about testosterone and estrogen,
if you watched the episode that I did about testosterone and estrogen, if you watched the episode that I did
on male and female fertility,
if you watched the episode that I did
with Dr. Michael Eisenberg from Stanford
or Dr. Natalie Crawford,
who's an OBGYN specializing in fertility,
we talked a lot about LH and FSH.
Basically, FSH, as the name suggests,
stimulates the growth of the follicle,
the egg in the female,
and it stimulates sperm production in males.
Luteinizing hormone stimulates testosterone production
from the gonad in males,
and it also stimulates estrogen production,
and to some extent testosterone production in females as well.
So we need LH and FSH to stimulate the gonads,
the ovary or the testes.
The hormone that stimulates LH and FSH release
is called GnRH or gonadotropin releasing hormone.
And it comes from the hypothalamus.
So GnRH is a signal that promotes LH and FSH release.
Now that raises the question, what turns on GnRH?
And the signal that turns on GnRH is kisspeptin.
Kisspeptin in other words is further upstream
from GNRH and LSH and FSH.
It's a cascade.
It goes kisspeptin, GNRH, LH, FSH, testosterone, estrogen.
Okay, that's the pathway.
Now it's very clear that kisspeptin is involved
in the activation of puberty,
the transition from pre-pubertal
to post-pubertal stages of life.
It's also involved in any of the sort of downstream effects
of having elevated LH and FSH, including elevated vitality,
which includes both energy and in some cases, libido.
So there's naturally occurring kisspeptin
and there's now synthetically generated kisspeptin
designed to mimic naturally occurring kisspeptin. And it's now synthetically generated kisspeptin designed to mimic naturally occurring kisspeptin.
And it's actually prescribed
for what's called hypothalamic amenorrhea.
Hypothalamic amenorrhea is the loss
or the absence of periods of menstrual cycles
that are the consequence of deficits
within the hypothalamus itself.
So not something within the ovary
or a lack of the pituitary to make LH or FSH,
but a deficit of the hypothalamus to promote LH and FSH
and the downstream hormones, testosterone and estrogen.
Incidentally, there are also kisspeptin antagonists, okay?
Drugs that are designed to suppress kisspeptin
and those are used to treat some of the symptoms
of menopause, including night sweats
and some of the, what are called vasomotor symptoms.
So kisspeptin is obviously a key player
in this whole pathway of steroid hormone release.
The steroid hormones being testosterone and estrogen.
There are other steroid hormones as well, of course.
Now there are folks within the landscape
of peptide therapeutics,
folks meaning physicians and other practitioners
who said, ah, well, here's a peptide
that is known to promote all these hormone pathways
that are associated with vitality, libido, et cetera.
And so there are people who take KISS Peptin peptides
as a way to stimulate these pathways.
And they're doing so for the specific purpose
of increasing vitality as it relates to libido and mood
and to get the downstream increases
on testosterone and estrogen.
And of course, some people are taking KISS Peptin peptides
to treat hypothalamic or mannuria. And as I mentioned, some people are taking kisspeptin peptides to treat hypothalamic or mannaria.
And as I mentioned,
some people are taking kisspeptin antagonists.
They're trying to block the kisspeptin pathway
in order to reduce some of the vasomotor
and other symptoms of menopause.
I will say, despite the fact
that the kisspeptin pathway is well-known,
and despite the fact that the kisspeptin peptide
is designed to mimic a naturally occurring peptide
that has a pretty constrained set of functions
in the hypothalamic pituitary system
and their downstream effects on the gonads.
The use of KISS-Peptin to increase vitality in libido
is a bit of a, let's just say,
it's a little bit of a wild card.
We don't yet know all the effects of KISS-Peptin.
Again, it was fairly recently discovered.
We have it in mind that it's involved in these pathways,
but I should say every time we look at a given peptide,
whether or not it's ghrelin or hypocretin or exin,
or it's GLP-1, what we find is that, again,
there are these pleiotropic effects.
There is rarely, if ever, one specific effect.
And it's not just a concern about side effects
that we want to take these pleiotropic effects
into consideration. It's the fact that even though we know a lot about side effects that we want to take these pleiotropic effects into consideration.
It's the fact that even though we know a lot
about the human body and the various hormones
and neuromodulators like dopamine, serotonin, et cetera,
that are made, this landscape of peptides
is an enormous one.
And it's one for which we are just now really starting
to appreciate how many different peptides
the human body and brain make.
Again, I don't think it's an overestimate
to say that there are probably hundreds of thousands
of different peptides, each with multiple
and sometimes even overlapping and synergistic effects.
So I do understand the excitement about peptide therapeutics.
I think for a lot of people that want to improve
their physical health and mental health,
they want to recover from injuries more quickly.
Maybe they're seeking particular aesthetic changes
or mood changes, et cetera.
I understand the gravitational pull
and the excitement of peptides,
but I have noticed that the discussion around peptides,
because it's in contrast often
to the discussion around hormone therapies
like testosterone therapy and estrogen therapy,
people I think inadvertently assume
that peptides are all safe or innocuous or that they are potent enough
to do certain things that we want,
but that because they're not hormone therapies per se,
that they are free of side effects and risk.
And in addition to wanting to teach you about
some of the biology of these peptides and how they work
and what they're designed to do,
as well as some of their potential therapeutic benefits
under the right conditions.
Again, working with a really good board certified physician
and making sure that the sourcing is really clean
and that you're doing regular blood testing
and you're monitoring for any potential tumor growth,
et cetera.
I also want to emphasize that these are very potent compounds.
They have lots of different effects
and we are in the early stages
of exploring peptide therapeutics.
Again, I'm not here to tell you what to do or what not to do, but if you have it in of exploring peptide therapeutics. Again, I'm not here to tell you what to do
or what not to do,
but if you have it in mind that peptide therapeutics,
because they aren't hormone therapies,
are not without their potential risks, you would be wrong.
All of that said, it's very exciting to see
what's happening with peptide therapeutics.
I'm excited about their potential
for both the treatment of disease
as well as for augmentation of mental and physical health.
And I think it's an exciting landscape
that certainly motivated my desire to do this episode
and get you familiar with them,
or at least with some of them.
And it's something that we're definitely going to be
exploring more on this podcast,
both with expert guests and in solo episodes going forward.
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Thank you once again for joining me for today's discussion
about the science and application of peptide therapeutics.
And last but certainly not least,
thank you for your interest in science.