FoundMyFitness - #003 5 to 7x More Stem Cells from Placenta with Dr. Frans Kuypers
Episode Date: December 17, 2014In this interview, Dr. Rhonda Patrick talks to Dr. Frans Kuypers about his lab's discovery on how the human placenta is a rich source of pluripotent stem cells, and yet the placenta is thrown away aft...er delivery. In this episode, we discuss... (00:00) Introduction (04:39) The human placenta as a source of hematopoietic cells (11:30) Pluripotent cells can differentiate into any cell in the human body (13:03) Public banking of abundant pluripotent placental stem cells (18:06) Therapeutic applications of stem cells (22:56) Stem cells as part of a physician's toolkit (28:56) Epigenetics of induced pluripotent stem cells (34:49) Biogenerators could use young cells to produce growth factors and other chemicals (38:36) Transferring blood from young mice into old mice regenerates tissues using GDF11 (43:32) Opportunities and challenges of banking stem cells (52:49) Stem cells could eliminate deaths due to lack of bone marrow donors (56:37) The way we fund research isn't optimal for society If you're interested in learning more, you can read the full show notes here. Join over 300,000 people and get the latest distilled information straight to your inbox weekly: https://www.foundmyfitness.com/newsletter Become a FoundMyFitness premium member to get access to exclusive episodes, emails, live Q+A's with Rhonda and more: https://www.foundmyfitness.com/crowdsponsor
Transcript
Discussion (0)
Dr. Ronda Patrick here. In this week's podcast, I chat with Dr. Franz Kipers, whose lab made a huge
breakthrough in 2009 because they found that human placenta is a rich source of pluripotent
stem cells. They also developed a technique that allowed them to retrieve between five and seven
times more hematopoetic stem cells from the placenta than from cord blood, which is currently
a standard technique that's used to get hematopoetic stem cells used for bone marrow transplants.
Meanwhile, the placenta is discarded and thrown away after deletopoietal, which is used to get homoiettecels.
delivery, about 3.9 million times a year in the US alone. The ability to retrieve between
five and seven times more hematipotic stem cells from the placenta than from cord blood
is a pretty big deal in the case for bone marrow transplants, which are typically used to treat
a variety of different blood cancers like leukemias and lymphomas and also genetic blood
disorders like sickle cell anemia. In the case for blood cancers, oftentimes chemotherapeutic
treatment like radiation and other chemo drugs can wipe out the immune cells and red
blood cells in the body. Hematopoetic stem cells, which are multipotent, meaning they have the
capacity to form different cell types in the body, although they're very limited to the types of
cell they can form, can repopulate the immune cells and red blood cells, so they can form B&T lymphocytes,
red blood cells as well as other monocytes. In addition to these hematipoetic stem cells,
the placenta also has the capacity to form pluripotent stem cells, which means these stem cells
can form any type of cell in the body, including blood cells, immune cells, muscle cells,
lung cells, liver cells, kidney cells, brain cells, you get the point. Before we get started,
the technique that Franz and his lab developed is not consumer available yet. Now there are a couple
of companies that do offer to freeze down and bank placenta, but they use their own methods,
and we're not discussing those. So without further ado, I hope you enjoy listening to this
podcast as much as I enjoyed recording it.
Hi guys, thanks for joining me today. I'm pretty excited to have the opportunity to chat with Dr. Franz Kuypers,
who is a senior scientist at Children's Hospital, Oakland Research Institute, and happens to be one of my colleagues.
His current research focuses a lot on understanding the underlying mechanisms of thalassemia as well as sickle cell disease,
but that's not actually why I asked him to have a chat with us today. I actually am,
interested in some of his previous research that has to do with the identification of a
very rich source of stem cells from something that is discarded almost every day.
And that source happens to be the placenta.
So thank you for joining us, Franz.
Back in 2009, your lab made a huge breakthrough.
And that is that you found that the placenta is a rich source of what's called multiproans
sorry, pluripotent stem cells.
And for those of you that don't know what pluripotent stem cells are,
what that means is that pluripotent stem cells have the capacity to form almost every cell type
in the body from liver cells to kidney, muscle, and even brain cells.
So to me, this seems like a huge breakthrough, and I'm quite shocked that more people aren't
talking about this and that people are still throwing the placenta away,
every day. So I've heard you say, and I think I'll sort of quote here, that yes, there are
stem cells there, yes, they're viable, and yes, we can get them out. So maybe we can start there.
Sure, we can start there. And not to correct you, but sickle cell and thal, both of them are genetic
disorders, and they can only be cured with stem cells. So in other words, that led actually to me
looking at the placenta as a source because we also developed in this institute the use of
cord blood, sibling cord blood, to transplant individuals with leukemia or sickle cell disease or
talisemia. And so the reason that we started looking at the placenta is we started to look upstream
because the cord blood unit that is used a lot currently in bone marrow transplant
simply doesn't have enough stem cells to cure somebody like you or me.
So that's why we started looking at people at a adult.
An adult, yeah.
Okay.
And so obviously in the pediatric institution, you're interested in transplanting kids,
but for the adult population, you also would like to have a good source of stem cells.
So stem cells can, as you say, become any cell in your body, including your blood cells.
So if you have a bone marrow transplant, what you do in order to cure cancer,
or cure genetic disease, you need stem cells to do so.
Right.
So that's where that comes from.
So let me ask you, though, the difference between, for example, cord blood,
which I think a lot of the listeners are familiar with,
the fact that you can actually bank and freeze your cord blood,
is that these cord blood stem cells, they're mostly hematopoetic stem cells.
Yes, although people can, also show that they can differentiate
into other kind of stem cells.
But you know, one of the things that you have to keep in mind with all of this
is that people have heard about embryonic stem cells, right?
Because all of us start with one cell, okay, and that makes us, all right?
So everybody starts with one cell, you know, and that's how we start.
And so nine months later, obviously the baby is born,
but doing those nine months, that embryonic stem cell that starts at one cell
becomes now trillions of cells, right?
And part of that trillions of cells, right?
is the baby. And part of the trillion is the placenta because they both grow at the same
time because the placenta is the interface between mom and the baby. And so after the baby
is born, you can then consider to draw blood from the placenta because nobody is
harmful to the baby is born. Mom will deliver the placenta. Normally it goes into the bucket
and it's just thrown out. So that's where you get your cord blood out of that placenta
with the cord that is still attached.
And so it makes sense to say, well, if you can get cord blood out of it,
and you throw away that big chunk of human tissue,
which happens to be the placenta,
is there nothing there to look at?
And obviously that's when we went upstream and said,
well, we have cord blood, but what is actually in the placenta?
Because in contrast to embryonic stem cells,
there is no ethical issue at all.
One, two, is that if you want to have stem cells that will represent the genetic pool of the human race,
it's a very good idea to just look at placenta because babies are born all the time.
And whether you're in Japan or whether you're in Kazakhstan or in Holland or whatever you are, babies are born.
And that placenta from that baby obviously is the same as the genetic background of that particular population.
of that particular population.
So the whole idea with using placental derived stem cells
is that you have now a source of stem cells
that is very cheap, very easy to get.
You get trillions of them, so you don't have to do
all kind of difficult things.
Trillions of them.
Oh yeah, trillions of them.
Wow, so how many-
Compared to cord blood, how many stem cells do you get from core?
Well, I mean, you know, you have to keep in mind
that these numbers look big, okay?
But I can also tell you that if you take one microliter,
which is one square millimeter of blood,
it has about four million cells in it, okay?
So, and you, as we sit here,
we have in the order of, let's see, 10 to the 12th,
which is a number that looks extremely big, right?
But these are trillions of cells that we have
in our body as blood, and we have trillions of cells
in a body that makes us.
So these numbers look big, okay?
Yes.
And they are big.
But relative cord blood stem cells relative to placental stem cells.
Oh yeah, relative.
Relative.
How much more stem cells?
Well, let's look at this.
Cord blood will be maybe 100 milliliters, which is about three ounces of blood, right?
Okay.
Now a placenta is one kilogram is about two pounds of human tissue.
So in other words, if you simply compare that, then obviously you get many, many more cells,
in the placenta than you have in core blood.
Okay?
So that are, it's just a rich resource.
And the big difference between embryonic derived stem cells and the placenta is, is that
it's very difficult to take one embryonic stem cell and grow it until you get trillions of cells.
Because that embryonic stem cell doesn't stay your stem cell, it becomes different kind of cells, right?
On the other hand, if you take the placenta, nature made that for you, and unless we are
better in growing embryonic stem cells to trillions, we let nature do its job and they do a great
job.
And they've been doing that for millions of years.
So why don't we use it?
So the whole argument with this one is that don't throw your placenta out.
Let's see whether we can use it.
And yes, we have shown in 2009 the paper that you refer to, but we had another paper in
2012 that really shows that in the human term placenta. So this is the placenta that is
normally thrown out. No problem with some people want to keep the placental, but most people
don't even see it. So we say, well, keep it. And then if you do that properly, you can tease
out of those placentas cells that can become any kind of cell in your body.
So it can be, yes, we have shown that. So in other words, what you can do,
do, you can take a placenta, snip it up, put it in cell culture, that's what you can do
in the lab, and then you can tell the cells, hey, I want you to become a neuron, or hey,
I want to become you to become a fat cell, or whatever you want.
And by feeding him a certain kind of, you know, feeding medium, then they say, okay, fine,
if you want me to do that, I'll do that.
And then you get cells that look like neurons, or you could cells that look like heart
cells or whatever you have.
So let me ask you.
that multi-potency or pluripotency like you talked about.
Right. So in other words, the pluripotent or multi-potent essentially means that you have
the potency so you can to become multi so you can become anything. And so the whole trick
here is that if you do that properly, you can now get different kind of cells from placenta. And
so that also means that if you don't think where the placenta is coming from, then you can
get different kind of cells with the genetic background from where the placenta.
the placenta came from.
So in other words, you can then create cell lines, if you want to call it that way, or cell resources,
if you want to call it that way, that not only can become anything, but also will then have
the genetic background such that it may fit whoever needs it, okay?
Because there are two options here, either you are born and you keep your placenta somehow
for later use when you're 80 years old, you know, whatever.
Or you have enough placenta stored in placenta banks that you just go there and find
one that will fit you.
So there are two different ways that you can, you know, you can deal with that.
And people obviously don't deal with that right now, but that's the future and that's
where we'll go for.
Can they?
So is there, you mentioned that you have a, I think you have a patented procedure for
saving the placenta, freezing it down, so that you can later than...
Yeah, we have that.
Now, is this something that's commercially available?
Not yet.
Not yet.
So the whole thing with this one goes.
First of all, you show the proof of principle in an academic setting, like we're here.
Okay?
And then in order to bring it to the next step, sure, you can start with a small company,
and you can say, hey, here, this is how to do it, right?
I mean, you have a startup company, so this is how we're going to do it.
And so that means that you then show, okay, if you do it this way or that way or this way or that way,
then yes, you can store your placenta.
And it's not that you can just put it in your freezer in the kitchen, okay?
It's a little bit more complex.
Because what you want to make sure is that what you put in your freezer
also will be alive when you get it out of your freezer.
Right.
Right?
So you cannot just take your placenta after the baby is born
and put it in your freezer in the kitchen
and hope that it will still be okay in 10 years from now.
Ain't going to work.
So you have to develop technologies,
and that's what we have done,
to put anti-freeze in that placenta such that you can then put them into liquid nitrogen.
So in other words, it's not what you have in your kitchen.
I mean this is minus 200 degrees centigrade, so very, very cold.
But if you do that properly, then those placentas that you then store in your liquid nitrogen
can be pulled out later, thawed very carefully,
and then the cells that are in there say, okay, here we are,
and then you can put them into cell culture,
and you can grow them. So that process of going from collecting the placenta, freezing them,
getting them out, teasing the cells out of that tissue, growing them in a way that they become
whatever you want them to be, that is obviously a complex technical procedure. That is one. Okay,
now we're good at that. We know how to do that. But now you get in, how do you store that?
Well, we are not going to store 100,000 placentas here, okay? We're not. But they
maybe companies that are interested in that.
So what we try to do is convince people who currently collect cord blood and store that or other
people to, yes, hey, don't only store cord blood, store the whole placenta, don't throw
it out.
And it obviously doesn't necessarily mean that you have to store every placenta from every
baby that is born.
So what I said earlier, what you need to do is you have to see, okay, how many different
kind of placentas do we need to store in order to have a match for you or for me or whoever
needs it, okay? That's one way of doing it. And the other option is obviously if you have a
baby and you say, well, my baby is born and I want to keep the placenta because when the baby
is now 20 years old, he needs it, well, you could do that too, right? I mean, these are different
kind of ways of doing that. But currently, that was your question, is it commercially available?
Not yet. Will it be commercially available? Yes. When? I don't know. I hope next year,
I better probably made a couple of years from now. I mean, that takes time, you know?
Yes. Are you looking for some venture capital?
Obviously we do.
Okay, well I definitely hope someone steps up to the plate.
No, no, no, they should.
I mean, the point is that we have, I mean, the whole idea with this kind of, and it is not unique.
I mean, it's the same kind of with a startup company in electronics or whatever you have.
There's a lot of startup companies in biology that have, they think at least, good ideas.
And I think obviously this is a great idea.
And then bring it into the commercial realm of things, that's a very different story.
Because obviously I don't have the millions to develop it into a commercial product.
But obviously if people would help with that and partner with that,
and obviously that's what we currently are doing, looking for partners and some of them we have.
And, you know, so you have to build that towards something that then becomes a commercial enterprise.
And it can only become a commercial enterprise if people buy your product, right?
Exactly. So I want to step back and it sounds like, I mean, this is to me is obvious. I mean, someone should definitely back this up like ASAP. I mean, I find money. I'd be doing it. I agree with that too. But back to a little bit of the biology here. So the ability to use these stem cells that are pluripotent, you know, from the placenta to for therapeutic applications. For example, you mentioned cancer. I know that leukemia has a lot of blood cancers. I mean, people that they undergo chemotherapy, radiation.
they lose a lot of their immune cells,
and they end up having to wait for bone marrow transplants,
which oftentimes they can't find a match.
And so, you know, you've got, you know, 50% of the time,
people can't find someone to have their bone marrow donated.
So what sort of therapeutic applications are we talking about here
with these stem cells that can be harvested from, you know,
I think there's something like 3.8 or 3.9 million births
just in the U.S. alone every year.
I mean, so that's almost 4 million percent of the trash.
Do the numbers here, you know.
Right. So what does this mean, you know, for, you know, you also mentioned cord blood.
We know cord blood doesn't have nearly as many stem cells.
It also can't form as many different types of cells.
But there's a small amount of these cord blood cells that have been used to treat childhood leukemia, for example.
So what can these placental stem cells do in terms of therapy?
Yeah, okay.
So in a lot of which we open up a few.
field which is currently obviously in development because you read in the papers all the time
what you can do with stem cells and whatever, you know, there's a big promise there.
The thing is cord blood is a good example because it has been used and hundreds of kids have
been cured with the use of cord blood. So yes, those stem cells that form new blood because it
replaces your bone marrow have been used and have been very successful. There are obviously studies
going on to see whether you can use stem cells for other reasons.
Now one thing to keep in mind as an example, if you cut yourself, right, then you have obviously
blood is coming out and stuff and then it will be repaired because after a while you know you
don't see it anymore, you have a little bit scar there but obviously it is repaired.
Now that is because there are stem cells in your own skin that do that, right?
And so that also means that what you can think about
using those stem cells to not only repair that if you find a good match,
you know, because you talked about a match,
and in bone matter you need a good match.
Otherwise, your body will recognize the new cells as not good,
or the other way around, the new cells that come in recognize you as not good,
and that's not matching.
That is not good at all.
Right.
That's very, very bad.
So basically the immune system is going to pack.
Yeah, I mean, that's what the immune system should do.
Right.
I mean, they have to recognize something that is not you.
Absolutely.
and they have to kill it, right?
Or the other way around, if you get new immune cells,
they will recognize you as, hey, I don't recognize you,
I'm gonna attack you in the skull graphus or social disease.
So that's when you talk about good matching.
And that matching means that the stem cells
that you then give to individual should really fit.
And that's also what I said,
if you look for the genetic pools that you look at,
you have to look for the fits, right?
And so if you store enough placentas
or enough core blood or stem cells in general,
that would fit anybody in this planet
or the better part of that, then you're pretty good.
Now, where could you use it for?
That was your question.
Bowmerich transplant, obviously.
But you have to think about anything
that needs to replace something in your body
that doesn't work properly anymore.
And obviously if you get older,
you get many more problems like that, right?
Right.
But in principle, every cell in your body
has the same DNA.
All of them. So you have to wonder why my finger looks different than my nose. Well,
because there's a program that tells, hey, I mean, I want to be a finger and I want to be a nose.
But it actually means that every cell in principle can either become a finger or a nose.
Right. So that also means that if you now provide stem cells that will become new heart tissue,
well, you could use it to repair somebody who has a,
damaged heart after, you know, a heart infarct. For instance, you could also use stem cells
to replace cells in your eye because for whatever reason your eyes don't work properly.
You could use stem cells because you, by walking in the sun, your whole your life, you get,
you know, patches of your skin that are not good anymore, you know, and they will have to be removed.
Now then it means that your skin either has to do it himself or you can give stem cells.
to give you a new nose or whatever you want.
So it is obviously a little bit science fiction
because obviously we are not able to do it right now,
but that's where it will go.
So in the next decades what we will see is that these pluripotent stem cells,
stem cells that are able to become any tissue,
will now become a tool in the toolbox of a physician
to repair whatever needs to be repaired.
Okay?
So it's not happening tomorrow.
Part of it is already in place, like bone marrow transplant.
You know, part of it may already work to help to repair burn victims with repairing, you know,
whatever they have, damage on their skin.
So there are all kind of things that are currently happening, and it goes really into that direction.
So these multipotent or pluripotent stem cells will, I really are the future of tissue repair,
if you want to call it like that.
Yeah.
Yeah. So, I mean, I know that they're doing a lot of work now in this regenerative medicine field
with induced pluripotent stem cells where they're taking skin cells. And there, you mentioned
this genetic program while they're throwing in some of these gene factors that can say to this
skin cell, hey, I want you to become a stem cell. And then, once you're a stem cell, then I'm
going to decide what other cell type you're going to become. And, you know, there's a lot of
promise in this field because they're now able to basically take just a skin cell, which we are
sloughing off every day, and make them into these pluripotent stem cells. And there's been a lot of
work in animal models where they've now been able to regenerate, you know, neurons, lost
neurons or spinal cord. Well, yeah. But I mean, they are made, as you know, we are not smart
enough as humans currently to make these iPS, the induced pre-reported stem cells in a way
that, yes, you have to somehow tell, because what I just said before, this becomes a finger,
this becomes a nose, so somehow you tell the cell what to do, right? So you can actually
say, okay, guys, why don't you go back in your development like a skin cell? You're not a skin cell
anymore, we make you now back into a stem cell. Doing that obviously needs to be done by
pretty harsh treatment. And as a result of you, you end up with cells that are not necessarily,
I mean, I don't want to use as a human dose cells, okay? I mean, you can do some kind of study. I mean,
obviously these studies are done, but we by far not ready to use that for a human being. Because
you really, you really have to be very, very careful with that. Yes. Because what you do, by
modulating cells, you know, and bringing them them back to be more priming.
you turn on genes that also mean that yes they grow now and uncontrolled growth has
also another name it's called cancer right okay so in other words if you are not
very very smart in telling the cell what to do the cell will take on its own life
keeps on growing and that's what you call a tumor right so you have to be very
very careful that's one and two you could also ask yourself well do I
want to take a cell for my skin, which definitely has been along for 60 years, right?
And it is not necessarily as good anymore as the teenager, which I call the stem cells that I have,
that are only nine months old. Because obviously during life, you know, as we live,
aging happens. Aging happens to the individual. Aging happens to the cells. And so that
means in time your cells get older and older and older and older. And you can
see that if you look at an individual, you look different when you're 80 years old and
when you're 20 years old, right? And so that means that all the cells getting older. So then
you can ask yourself, well, sure, I can reprogram it to become something else by taking
a skin cell from a 60 year old. But hey, you still have a cell that happens to be around
already for 60 years. And there's nothing you can do about that because that's how you start.
You cannot just take time back, okay? There's no way. So there are a lot of
arguments to be made that those if we even if we would be very very smart and
being able to really do a very good job in using those IPS cells you still
end up with cells that you start off with that are pretty old that's one too is
that they still if you have an IPS cell they still have to grow into a cell line
and you start with a couple of cells how do you get trillions of cells you have
to grow them. And in order to grow them to become of therapeutic use, you have to have a lot of cells.
And then the problem is it's not only that you have to be smart how to program them to become
whatever, but then you still have to grow them, you know, and cells have the tendency of
differentiating, becoming a little bit different because they all talk to each other, okay?
So that's how we start as a human being. You start with one cell. Now look at me. I mean, I don't
look, my cells look different.
And the reason for it is that all those cells talk to each other.
And that happens in the cell culture too.
So that means it is very difficult to keep all those cells exactly the same, you know,
in order to use it for therapeutic use.
So obviously I'm talking about where would you get them and I say, well, you know,
if you're smart enough to get young cells from a placenta and you have tons of them,
hey, it's not bad.
So I'm not saying that IPS are not good.
I just say IPS or embryonic stem cells or placental cells or core blood cells.
They're all different resources that you may use for whatever you want to use it for.
And it's not that one kind will take over everything and the others are not good.
This is just another resource, which I think is a wonderful resource that we shouldn't throw out.
I agree.
You mentioned something on your first point you were making about the IPS cells, how they're age, they're older.
And there's been a whole slew of publications that have been looking at the epigenetic
marks on cells as they age.
And there's a complete program, an epigenetic program.
So epigenetic means these are not changes in the DNA sequence itself, but there are these
factors that'll sit on top of your DNA, so to speak, and they can turn genes on.
So genes are doing what they're supposed to do, or they can turn genes off.
of genes, even though they're there, aren't doing necessarily what they're supposed to do.
But what they found is that there's an epigenetic program that happens with aging,
and you can compare, and they've done this in people, they've taken blood cells from young individuals
and old, you know, different ages, and they've seen there's patterns,
methylation patterns, for example, and they can take a blood cell from a person and guess their age
and they get within five years plus or minus, which is quite striking to me.
So it'd be interesting, you know, one, with this induced pluripotent stem cells, you're right.
If you get them from an older person, this is an age cell, it has a different epigenetic.
Can you put an epigenetic program back?
Can you?
That's the question.
Well, that is currently, I mean, that's what I'm saying.
Ultimately, we may be smart enough, we're not there.
But ultimately, we may be smart enough to take a cell from me as a 60-year-old,
It's okay, we're going to modify you not only to become anything that we want, but also turn back time and the epigenetic program or whatever you have there.
Modify everything, go back and be smart enough that you end up with a cell that looks like I would look when I was born.
All right?
Now, if we are there, then, yeah, that would be wonderful and then we can start again.
But we're not there yet.
You're right.
So in other words, yes, I mean, there's a lot of promise.
There's a lot of promise in these different resources.
And obviously where we are now is completely different than we were a decade ago.
Because we wouldn't even have thought about this, okay?
So yes, I mean, things are developing very rapidly.
And I will be the last one to predict where we will be in 10 years from now
because, I mean, there are probably things happening that I didn't even think of, okay?
But what I'm saying currently today, as we are, we have a good resource,
is cord blood to replace bone marrow in kits that needed with leukemia or whatever.
Yes, we are developing another resource coming from the same kind of angle, which is the
placenta.
And yes, that will be a resource that can be used.
And at the same time, yes, sure, we should keep on working on embryonic stem cells and
see how we can be smarter to understand these patterns of epigenetics and whatever you have.
Yes, we should try to make smarter protocols and better recipes to make iPS cells to make
PS cells such that they become anything and turn them back in time.
Those kind of things all happen at the same time.
And so it just depends what we want to do.
And so the only point that I want to make is that, yes, we have a resource that nature
provides us, use it.
I mean that's essentially what I want to say.
And so, yes, we may be smarter than nature at a certain point to doing certain things,
but at this point, why don't we use it?
I agree with you.
I mean, so that is, so it is not a competition between iPS and embryonic and whatever.
All of them will happen at the same time and you pick what you need and you do what you need and, you know, and that's how it goes.
Right.
Yeah.
So that's the way I see.
Exactly.
I think something with the placenta, placental stem cells that also is very interesting is the ability to be able to form neurons, you know.
And so if you think about in the context of neurodegenerative diseases, Parkinson's disease, Alzheimer's disease, this could be a good.
game changer. I mean, people are out there researching, trying to find a cure, you know, trying to
find obviously ways that you can delay, you know, these age-related diseases are also very important.
But to me, it seems as though being able to make neuronal stem cells, you know, for the hippocampus,
substantial Niagara, you know, all these different brain regions. I mean, our brain atrophy happens
with age. It happens accelerated.
Yeah, wet on my glasses. I mean. Exactly. So the fact that these placental stem cells,
you said can form neurons as well.
And so to me, it seems like why wouldn't we start using
this rich source that we have to start forming neurons
and doing these studies where we can say, OK,
can we replace damaged neurons, first, obviously,
in mice, but also ultimately in humans?
I get, you know, have you been able to show
that a placental stem cell can form a neuron?
Has that been shown by you or others?
Are you aware?
Well, we have, and I don't know if I have it on my wall, but otherwise you can look in the paper that I published, we have shown that.
You have shown that.
So we have shown that.
So they can become neurons, they become any cell that you want in a sense, right?
Because you're able to tease them.
Now whether there will be a functional brain cell, that's a different story, okay?
Because if you show that cells get the characteristics of neurons in a petri-day,
what you do in stem cell lab, it is not necessarily means that I can suddenly replace somebody
brain cell, okay? That's a little bit, that's another step, all right? So another thing that
I want to mention to you is what is important to keep in mind if you talk about stem
cells and regenerative medicine. One of the things is that what you have to think about
is that cells are never living by themselves. They live in a community.
It's like a village.
If you want to have, if you go in a village and you want to buy a sandwich, right?
You need a whole bunch of different folks to work for you.
You need somebody who makes, you know, grows the corn that has to go to the bakery,
who makes whatever, and then you need, you know, the butcher who gives you the whatever,
the ham that you want to have and you get another, you know, etc., etc.
So it's like a village, you know.
So that means that sells stock to each other.
Like in the village, hey, I want to have this, I want to have that.
So the way that cells talk to each other, they don't get on the phone, all right?
They don't have that.
But they use chemicals that they generate, spit out, and then the guy next door says, oh, that's
what you want, and then that guy will spit out another chemical that goes to another guy,
is oh, that's what you want.
And ultimately you end up with a community of cells that together become whatever you need
to be.
It's the same thing as in the village and buying your sandwich.
But it means that it's not only the cells that are important, it is also the chemicals
that they spit out that are important.
These are the signals that let you do whatever.
So you have to think about if you have a damaged tissue.
You cut yourself.
So what does that mean?
Well that means obviously cells are screaming murder because I mean something happened to them.
So they send out signals, hey, we need to do something.
They send signals to other cells, we need to do something.
And before you know, it starts to grow and you repair your tissue.
So then you have to think about, okay, how could they use young cells like from placenta
to help with that?
Do I need the cells to replace the damaged cells or do I simply need cells that help with this
whole process of talking to each other?
And so one of the things you can think of and that has nothing to with matching now.
Because I can, I mean, you know, that is the kind of stuff that I'm also developing, which
is very different, is that you say, well, you can have a biogenerator, which essentially
is just a tube with cells in it, okay?
And you let them talk to damaged tissue, which are the signals that come out.
Those signals now come to those stem cells, that, oh, we need to do something.
And they start to make growth factors, and they can start to make order, and that comes out
on the other end, and that goes back to your damaged heart or liver or whatever you have.
and that will then help the liver to regenerate better.
And that's the kind of stuff that I'm thinking about doing now
with pediatric liver transplants in UCSF as an example.
You say, well, it's not necessarily that you have to replace those cells,
but maybe the cells that I have can help to generate an environment
that that liver that was damaged and was taken out from that baby
is now being able to grow better,
I help, you know. So in other words, it is a little more complex story than just talking
about a cell replacing a cell. It is also thinking about a cell population that talks to other
guys and generates chemicals, growth factors, and cytokines and whatever you want to call
them. And these chemicals help tissue to regenerate. So that means regenerative medicine
is more than just replacing cells. I mean, there are many more things that go along
with that. So if you talk about an iPS cell or an embryonic stem cell, yes, I mean, you can talk
about that cell that can then grow there. But you could also think about, well, maybe I should
use those cells to generate growth factors to help you and me to have my nose repaired a little
bit faster. I am so glad you pointed this out because it reminds me of recent headlines where
Amy Wagers, for one at Harvard and some others, found that when they transplant, for example,
blood from young mice into old mice.
Something happens that are able to regenerate liver, heart.
It was a growth factor.
That is exactly what I was going at.
So in other words, it does not, because you really have to think about if you have,
and that's also coming with the age of cells comes back,
if you have these nine-month-old cells, you know,
they have been developed over the last nine months into the placenta and the baby.
So they are vigorously making anything that fetus needed to become a baby, all right?
Or the placenta to grow itself.
So these are cells that are really programmed to make growth factors and do anything they want at a high rate.
So why don't we use them?
Yes.
And so these placenta cells are making growth factors.
There's also, you know, stem cells can replace damaged organelles in other cells like mitochondria.
So, you know, these placental stem cells are like you said, not.
months old, they're young, their mitochondria are healthy.
So not only can we replace the damaged cells, you know, damaged muscle, liver, possibly brain,
but we could also potentially have different growth factors that these placental stem cells are
treating.
You use them as bioreactors.
That's what you do.
Because, I mean, if you look at the soup, let's put it, call it the soup that they make,
there are hundreds or thousands of factors in there, right?
There are some of them that are a lot, some of them are very little.
But again, I mean it's like cooking.
I mean that one little ingredient which is only a very little bit makes the difference
whether it tastes good, yes or no, okay?
So it's the same thing what the cells make, they make this big mixture of chemicals that
help to grow stuff like you indicated in these mice.
But you need all these little things in the right amount otherwise it doesn't taste good.
So it's very, very difficult for us, I mean sure we can use all kind of technology to take
the soup and analyze it.
it and say, well, we get 99% of this and 1% of that and whatever you have, right?
But ultimately the complete recipe that the cells make as the result of a screaming kind
of, hey, we need something, right?
That is what it's need.
It's very difficult for us to really make that.
So my argument is, well, don't try to reinvent the wheel.
You know, use the cells to let them make what they told by other cells to do.
to make and let's use it, right?
Because it will be very difficult, and that's what you see in studies like you mentioned.
We find very, very interesting data by this concept, you know, that cells can help, can
do things in order to make other things work, right?
And so yes, that's another part of regenerative medicine that we should not forget, okay?
So it's not necessarily only the cells that now become another cell, it is also the cell
that can do things that the other cells need.
Right?
And supply these factors to make those cells do things that they're not doing because they're old.
Right.
And so in other words, yes, I mean they try to, but you know, obviously as you mentioned, I mean
the epigenetic reprogramming that happens over time makes them, yeah, maybe we're a little
bit not able to make those growth factors anymore.
What do you want?
So in other words, why don't it gives the other cells that can do it, right?
Yeah. You mentioned this thing of having this placental stem cell bank, so to speak, almost like, I mean, we've got blood banks now where people donate blood and they, you know, they bank it.
And, you know, I was thinking for me, you know, well, I haven't had a child yet and, well, you know, when I do have a child, if, you know, that placenta, which is obviously the stem cells in the placenta are from the fetus, right?
So they're technically.
Well, I mean, they're both. I mean, you know, you have to think about, they're both coming from this one.
cell, which is when, you know, when you get this one, egg cell, get sperm, boom, here we go.
That's the one that one, that's the ultimate embryonic stem cell.
You start at one cell.
And that one cell, obviously in time becomes a lot of cells, and part of these cells
become your placenta and part of these cells become your fetus.
And that keeps on going and in the end you end up with a baby and you end up with a turn
placenta.
So in a sense, both of them are made by the same starting materials.
Now the placenta is a little bit more complex because part of it is mom and part of it is baby, right?
Because that is the interface, you know, how the baby gets oxygen and nutrients from mom, right?
But after that delivery, yeah, you can tease it out and you can take the baby's part and then, you know, you can get your cells that you want.
Now, should we bank it?
Should you bank it?
Well, as you probably know is there are, I don't know, 250, 300, 300,000.
cord blood banks on the planet currently.
And these are banks that store cord blood.
Yes, I do know that.
And so these cord blood banks have different,
there are two different attitudes.
One is that there are banks that are called
private cord blood banks.
So that means that if you are ready to deliver a baby,
they can collect that cord blood
and put it in a bag and store it for you.
The other opportunity is that you
well, I don't care, I want to store it for anybody who wants to use it.
And that's called the public corporate bank.
So in other words, they don't store it for you, but they still store it for anybody who needs it.
Okay, these are the two different types of cord blood banks that currently exist.
All right?
And both of them are aimed for the same thing.
Those cells in cord blood could be used to transplant if somebody needs a bone marrow transplant.
Now, you can take the same kind of system.
say, well, we're not only going to collect cord blood, we also going to collect a placenta.
Right.
Why not?
And so we developed the technology that, yeah, if you put antifreeze in it, you can put
a whole placenta in the freezer.
Or what you could do, that's another thing that we have developed, we can pull cells out
and make a second bag and put the back into the freezer.
I mean, there are different ways of doing that.
But the bottom line is there is a resource that is currently going to biological waste that
I say, well, don't do that.
It stored it as a placenta as a whole, store it as a bag, where you get part of it out.
I mean, there are all kinds of different ways of doing that.
And I think ultimately it will come to the fact that at least part of, maybe all of the
cord blood banks, as an example, we say, okay, we can store your cord blood, we can also store
your placenta.
Do you want that yes or no?
Or for a public bank, they can say, well, we're going to store cord blood and the placenta
because you never know somebody may need it, right?
And so that is where it will go in the next decade.
And there will be people who, you know, who think that it makes sense from a public health
point of view to store them or for themselves to store it.
Or, I mean, there are different kind of scenarios, but it comes down to the same thing.
Don't throw away your presenter.
Keep it.
All of the above.
I think, you know, I recently banged my wisdom teeth.
Oh, you did?
Well, I didn't.
Yes, I did because I had to get them removed and they were impacted.
I don't recommend, if you don't have to get them removed, it's really traumatic, so I wouldn't
recommend it.
But if you do, there's dental pulp in the wisdom teeth that is also, has stem cells, which
are mesenchymal, so they can form cells that are like of the cartilage, bone, and also,
you know, other tissue types that are relatives of neurons, not quite neurons, but they're
getting there.
So the fact that they're banking these, you know, my dental pulp from my teeth,
and not the placenta to me is just absurd.
And I'm actually a little frustrated right now
because I feel like there's so much possibilities
with these placental stem cells that, I mean,
even while we're teasing out all the little details
about can a neuron be functional and things like that,
we should be freezing this down.
We should be doing that.
It's all a commercial issue.
So it's all a commercial issue.
It's all a commercial issue because you have to look at it.
I mean, we have currently the,
ability to do it. Okay? So in other words, if I would get now a placenta tomorrow in principle,
I could take the placenta, use my technology, put it into liquid nitrogen and store it.
Okay? But doing that will cost money because I have to get it, I have to do something with it.
There's time and effort and materials involved. And then I have to put it into liquid nitrogen. Well, then I have something that I put in the freezer.
Now that freezer needs liquid nitrogen, cost money.
That freezer needs to get new liquid nitrogen every week.
But they're freezing cord blood.
They're freezing.
I understand that.
Dental folks, themselves.
And so, yeah, you don't have to convince me, okay?
So, but the point is, I understand that you have to then have people who think, yes, we should do that right now.
I agree with you, okay?
So who would do that?
Well, go ahead.
Set up a company and let's do it.
You know, let's put the money there.
Okay.
So, you have a company.
What's the name of this company called?
Well, it's very classical.
It's called Pla Salus.
Pla Salus.
And what is the coming from?
Can you spell that?
P-L-A-S-A-L-U-S.
And the reason for that name is Playa is from Placenta,
which is the Latin word for the cake form organ that the placenta is.
And then I thought, well, you know, we use placenta for health,
why don't I use the Latin word for health, which is Salus, S-A-L-U-S.
So that's where the name came from, Plasales.
So what came this company?
So what we do as a company?
We provide the technology that allows you to deal with the placenta in the ways that we talked about.
So we provide the knowledge, the know-how, how to take a placenta, do whatever what you want to do in order to get hematopoetic stem cells out of there.
Do whatever you need to do in order to get cells out of there.
get cells out of there that can become pluripotent or multi-potent cells.
Do whatever you need to do in order to take that placenta, freeze the whole placenta.
We develop the technology, we provide that technology, all right?
And so that is the whole basis for that company, but you have to realize this is a startup.
So we have two directors, two janitors, and they're all the same people.
So my colleague and mine, so Vladimir Serikov, you know, obviously, you know, obviously, you
is not here today, but Flavarva Serekov and me, we are the directors, the janitors, and whatever
of that company, okay? So that's what we do. And we try, and we formed that company simply
to take our technology, which we have proven now in an academic sense, and try to commercialize
that, all right? And so that means that then gives you the opportunity to talk to corporate banks
or whatever you have and say, well, guys, we feel that it is a great idea. Go for.
it and then it depends a little bit who wants to put money on the table and how that goes
in order to start that because no matter how you look at it, it's a great idea what you
said, take a percent, I store it right now, I agree with that.
But what you need for that, somebody who takes it and stores it and you need storage facility
and you need a building that it goes in.
And before you know you talk about a lot of money.
But that kind of investment needs to be done, needs to come and it will come if there is
a feel for commercial viability.
Because in our country, if you don't make money out of it, it won't happen, okay?
Most of the time.
And so that then gets into why would you store placenta as well for medical use?
Well, you know also how the whole medical insurance system and whatever we have in the
US is pretty complex, put it this way, okay?
So that all goes into the same thing.
Where is the money coming from?
Because it's wonderful to store your placenta.
But who is going to store it for what?
And who's going to pay for it?
Because that's the question that you get.
Well, the consumer.
The consumer can pay for it.
You know, I pay right now, I paid $625 to get the whole process done.
Right.
And now I pay $125 a year to have them stored in liquid nitrogen.
And that is exactly what they do with cord blood.
Yes.
Because that is your private cord blood bank.
That's one of them that I just talked about.
That is, can we collect your core blood?
Yes.
You want to pay for it?
Yes. You want to store it? Yes. Okay, you get a bill every year and we store it for you.
And consumers are interested in doing that. Well, you know, and that is, if you get a company who says,
well, we don't only want to, you know, store cord blood or your dental stem cells, we also
want to store placentas because you've got enough people who are interested in doing that, who
will take off, okay? Well, I'm going to be advocating this placental stem cell because, I mean,
this needs to happen. And if you're just looking for someone to license the technology,
you know, some venture capital to back this up, you know, I really, really, really hope that
someone steps up to the plate and does that because, well, for selfish regions, I want to freeze
my future placenta. So you need somebody to offer that opportunity. Yeah, and also other people's
placentia. Like you said, if... Because that is the other part, right? I mean, the private one is
your placenta. And that is really you want to do it for yourself. Yes. And it's
fine but there's another part to it is that well maybe we as a society however we
want to pay for it same thing as medical insurance right how do you want to pay
for somebody who needs it tomorrow because what you mentioned earlier on
thousands of people die every year because they do not have a proper resource for
their bone marrow transplant or whatever they need thousands of them all right
And so that means that those people, if they would have that resource, would not die.
And that we as a society would be able to provide that to those people.
And they pay themselves.
They're part of that society too, because that's what medical insurance is, right?
Yes.
You pay not only for yourself, you also pay for somebody else.
But if you need it, hey, there's money for you to be treated.
So that's the same kind of thing.
So that takes it out of you storing it for yourself and paying.
It's more like, you know, how, and so you see, obviously, then that becomes in a much more complex story.
It does.
How do we as a society take care of ourselves?
I do agree with that.
I think with four million, just talking about the U.S. alone with four million placentas every year, you know, you're talking about the possibility of extending human lifespan dramatically.
because neurodegenerative diseases, heart attacks, infarctions, liver disease, lung cancer,
you know, leukemia.
I mean, just we're talking about tuning up humans every so often, giving them these growth factors
they need, possibly replacing some cells that are lost, and extending lifespan.
So, I do agree with you.
I mean, I have the vision.
I can see it.
Yeah, no, I have that vision too.
And it's just a matter of getting it to the next step.
Well, the future looks really bright.
And the future looks bright.
And your research, thanks to your research, has made it brighter.
So I thank you for that.
And I really hope that is it plus, can you say it again?
Plasalis.
Placalus.
So is there a website of people are interested in going to?
It's called plasalis.com.
Placalus.com.
I don't know whether I have it on the screen.
Oh, here we go.
Okay.
So you've got your.
Here we go.
This is my website.
Very simple website.
Placalus placental stem cells for health.
www.
P-L-A-S-A-L-U-S dot com.
That's right.
And that's where we can find...
And so if they can find me, you know, I mean, you can find me also.
Yeah, they can find this stuff, okay?
But, you know, the whole idea is don't throw it out.
Use it.
Yes, please.
So we need to get this into the consumer world.
Yes, and that's what we're working on very hard.
You know, we have some leads.
Well, thank you.
And anybody who listens to it, who is interested, give me a call.
Yeah.
If I ever make, make, you know, enough money to be able to back this up, I definitely will.
Right.
I mean, if I would have the money, it would start at the radio.
You know, I'd understand.
So unfortunately, there is, in a lot of medical research, what we do in this building,
what Bruce Ames is working on or what I'm working on, you know,
it really is the academic part of the story where you try to develop new technology,
new things that will ultimately pay off.
and you publish papers and you do your stuff
and you have great ideas
but then take it to the next step
yeah that takes time
I mean because obviously
they're all kind of things you know
it's how do you store it you have to get FDA approval
and you know all that whole mix
to go from a great idea
that can be shown in the lab
to something that will be of use
to the general public is a big step
yeah often definitely
Yes, and I think that, you know, unfortunately, you know, in the United States, we are not, and now I say it likely, not the best at funding research in general over the last decades. It's going down all the time.
Particularly creative research. And the problem with that one is that new ideas, and it's not my idea, it's everybody's good idea, do not get developed in a way they should actually as,
a society like we are because we have much more potential than we actually banking on currently.
And so the National Institute of Health, as an example, has been retracting over time continuously.
And so at the same time that we want to have better options to extend your life to improve
the quality of life, because that's actually much more important.
So improving the quality of life for our population or the population in the world in a sense,
stands on research that is done in basic research, translational research, clinical research.
And that kind of research needs money to be done.
And so it would behoove the Congress to put more money towards that,
because that will improve the quality of our population.
And then the next step, obviously, if you have good ideas,
how to get it into practice, that also needs funding.
And that we as a society feel that it is beneficial.
not only you and me, but in general, then yes, that can be done.
And that's what we have to step up the plate, you know. That's what we need to do.
Yeah, I agree. You know, and sometimes relying on government isn't, I think we're now moving into an era where we're able to get information to the people and people themselves are passionate about, you know, wanting to improve the quality of their lives.
And they're saying, hey, I want to fund this. And so now you start to skip the government and say, well,
NIH. Go crowdfunding. You know, crowdfunding. You know, that's, that's, that's becoming more and more of an
option where now it's like people are saying, hey, I've got some money, I want to fund your great idea.
I want to, you know, fund this, you know, possibility of having placental stem cells frozen down and,
you know, banked so that we can later use them at the individual level and also at, you know,
more of the societal level. So that's another. They're different approaches. They, they ultimately come down
via different roads into the same thing.
Crowdfunding, you pay directly.
You can also pay your taxes
and then it comes in that direction.
I mean, sure, we won't make this a political talk
because we're not here for that at all.
But, you know, all of those things come from a similar angle
and different countries, different societies
have different angles on doing that.
You know, the countries that do this differently
than what we do.
But the bottom line is that if you want to improve,
health, you really have to do the basic research and get it into the clinic and how to do
that. That's a challenge. And so in a sense we complain about the fact that we cannot
store placentas right away. But the other thing that I must say is I'd also do a fair
amount of work with parts of the world where this is a luxury to even talk about. If you
go to the African continent as an example, people
will die every day, thousands, hundreds of thousands of them with things that can very easily
be altered, very easily.
And so what is always frustrating to me if you work in healthcare research and you have very
simple things that can be done, then it's simply not done for whatever reason that would really
improve the quality of life of that part of the population.
And you know when I was in Benin, you know, what was it, two years ago or something, that was
like that, you really go there and you work with those people and you look at what they do
and then you wonder, oh, we are very lucky where we live, you know.
Yeah. And it is really devastating to see kids die for reasons that are absolutely unnecessary
and will not happen here in Oakland, in the Bay Area. Absolutely not. There's not even,
you don't even think about it.
Such as nutrient deficiency.
Anything.
I mean, you can go anything.
I mean, it may be that they're vaccinated against what I've got to disease, but they don't have clean water.
They don't, I mean, you know, you can name it.
I mean, so it's amazing.
And what we currently then hear about the whole Ebola issue in Africa, right?
You have to wonder why the few people who came over here, you know, survived and did well.
Well, most of the people in Sierra Leone or whatever they are, just die.
Right, difference in care, health care.
Just difference in care.
And one of the things that they figured out now in Liberia is an example,
and we talk about something that has nothing to with stem cells,
but they found out that if you are able to give proper nutrition,
proper care to a patient infectively Ebola,
the chances of surviving really shoot up.
By how much?
significant. I mean, you know, you cannot really say how much because you have to do enough.
But this is more anecdotal, but it really shows that if you're able to take care of somebody,
you know, in a very simple, basic way, you suddenly becomes life or death.
Wow.
And so what I'm saying is that what we are complaining about with our placental cells,
I always try to with a little bit back in a bigger perspective what we as a human race do.
And I think, yes, we should do that.
Yes, this is just one other example is that we have resources that we can use for the betterment of the quality of life, not only for us, but for everybody.
Because for the same token that we could use it, we could use it for anybody on this planet, you know.
Right, yeah.
So we have to keep that in mind.
No, it's very important, how fortunate we are to be able to be here researching, you know, regenerative medicine.
I feel very privileged that I have the opportunity to do.
do this kind of stuff and I have the opportunity given to me that yes I will be able to do
my little things and have fun with it but at the same time create something that may be good
for people and may be helping but it's really I feel privileged doing that and I keep that always
in mind I mean when I wake up in the morning and I come whatever whatever kind of wild idea
and can bring that into practice that's wonderful right and I feel privileged doing that.
It's a great mindset to have.
Anyway.
Thank you so much, Franz.
You might have welcome.
Really enjoyed the discussion.
Okay.
I'll catch you guys next time.