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We hope you have enjoyed this limited-length demo
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1. Stem cells from the early embryo
- Prof. Janet Rossant
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2. A chemical approach to controlling cell fate
- Prof. Sheng Ding
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3. Niche oncogenesis
- Prof. David T. Scadden
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4. Gene expression analysis of pluripotent stem cells
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5. Cellular therapies for neurological Injuries: bioreactors, potency, and coagulation
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6. The aging of mitotic cells: regeneration and aging
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7. Stem cells derived from amniotic fluid and placenta
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10. Cardiac stem cell therapy
- Prof. Joshua M. Hare
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11. Stem and progenitor cells from peripheral blood
- Prof. Shay Soker
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12. Stem cells from adipose tissue
- Dr. Adam J. Katz
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13. Human hepatocyte isolation for clinical transplantation
- Prof. Stephen Strom
-
14. Building implantable human liver tissue from pluripotent stem cells
- Prof. David C. Hay
Printable Handouts
Navigable Slide Index
- Introduction
- Potential conflict of interest
- Hepatocyte transplantation
- Purpose of talk
- Whole liver, pediatric organ donor
- Hepatocyte transplantation diagram
- GMP level cell isolation
- Suture catheters into major vessels (1)
- Suture catheters into major vessels (2)
- Place liver into waterbath in a sterile plastic bag
- Connect perfusion solutions to pump (1)
- Connect perfusion solutions to pump (2)
- Connect perfusion solutions to pump (3)
- Liver perfusion (1)
- Liver perfusion (2)
- Tissue dissociation complete
- Chop tissue with sterile scissors (1)
- Chop tissue with sterile scissors (2)
- Suspend cells in plasmalyte
- Full beaker with plasmalyte and cells
- Fenwall bone marrow collection filter bag
- Filter unit with funnel & stainless steel pre-filter
- The various filters
- 600 ml collection bag
- Dispersal of cells for centrifugation & cell wash
- Terumo sterile tubing welder
- Welding the bag with cells to a waste transpack
- Balancing of both bags
- Centrifugation of cell and waste transpacks
- Pressing supernatant into waste transpack
- Hepatocyte pellet repeated wash
- Expressing each wash into the waste transpack
- Final cell product
- Test final cell product for bacteria and fungus
- Dispersing cells into aliquots suitable for infusion
- Cold storage of hepatocytes: Viaspan
- Post cold storage: Plasmalyte
- Hepatocyte transplant procedure
- Cell infusion
- Summary
- Conclusions / Future directions
- Acknowledgements
- Strom lab Pittsburgh
- Hepatocyte transplant team, KI
- Thanks
Topics Covered
- GMP level cell isolation from pediatric liver
- Liver perfusion
- Tissue dissociation
- Cell suspension
- Filtering into collection bags and waste transpacks
- Final product of hepatocyte pellet
- Testing final cell product for bacteria and fungus
- Dispersing cells into aliquots for infusion
- Cold storage and post cold suspension of hepatocytes
- Hepatocyte transplant procedure & Cell infusion
Links
Series:
Categories:
Therapeutic Areas:
Talk Citation
Strom, S. (2014, March 5). Human hepatocyte isolation for clinical transplantation [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved November 21, 2024, from https://doi.org/10.69645/AUUZ6596.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Stephen Strom has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
A selection of talks on Methods
Transcript
Please wait while the transcript is being prepared...
0:00
Hello.
I'm Stephen Strom.
I'm a Torsten och Ragnar Soderberg
Professor of Cell Transplantation
Regenerative Medicine at
the Department of Laboratory
and Medicine, Karolinska Institute
in the Division of Pathology.
I'm going to talk today
about the Human Hepatocyte
Isolation for Clinical Transplants.
Our group is the first to transplant
human hepatocytes into patients
with liver disease in America, and
my laboratory was the first one
to be approved by the FDA
for isolation of hepatocytes
for clinical
transplants so we'd like
to share this experience with you.
We've collected about 2,000
livers for hepatocyte isolation,
so we have some considerable
experience in this area.
0:39
Although I don't believe there's
any conflict of interest,
I put this slide in there.
I am a stockholder in Stemnion,
which is a stem cell company
interested in placental stem
cells and Yecuris, which
is a company interested in making
mice with humanized livers for drug
discovery and drug
metabolism research.
But none of the products
from Yecuris or Stemnion
are used in any of these slides
I'm going to present today.
So what we're interested in
is really this field called
hepatocyte transplantation,
and this is
a cellular therapy
for liver disease.
1:12
So what we try to do with
hepatocyte transplantation
is shown on this slide, which is
to "bridge" patients to whole organ
transplant, or possibly repopulate
their liver if they're dying
of acute liver failure, or
to correct metabolic defects.
So in the bridge technique,
what we try to do
is to keep a person alive long
enough to receive an organ.
So about 10% to 15% of the
patients who are waiting for liver
transplant in America can
die on the waiting list.
So what we can do in
some of these cases
is to actually transplant
hepatocytes, isolated liver cells
into their liver to give them
enough liver support to keep them
alive for several
days, in which time
you hope to get a whole
organ for transplant.
We call that the "bridge" technique.
The second use of a
hepatocyte transplantation
is really for
repopulation of the liver
of acute liver failure patients.
So in this slide, it says FHA.
F, which is fulminant
hepatic failure.
And this is a person who's
dying of acute liver failure.
And this is an urgent
case for liver transplant
of course, when they
present in the hospital.
And oftentimes, liver is not
available for these people
in sufficient time
to keep them alive.
In these cases, we can
transplant isolated hepatocytes
into their liver or
sometimes into their spleen,
and provide temporary liver support.
What has happened in at
least two of our patients
is that they have recovered
after the cell therapy
without the whole organ transplant.
So there are two
reports from our group,
and now there's five total
reports in the world of recovery
of patients from acute liver
failure without the need
of a whole organ transplant.
So that's really the second
use of hepatocyte transplant,
to try to keep a person alive,
and repopulate their liver
during this acute
liver failure phase.
It's important with these acute
liver patients is that we really
can't transplant enough
hepatocytes into their liver
to support the entire function.
But what we can do is keep
then alive long enough
for their native
liver to regenerate.
So without native
liver regeneration,
this cellular therapy
really would not work.
But it is sufficient to keep
a personal alive long enough
to allow their native
liver to regenerate.
And the third and most useful case
for use of hepatocyte transplants
is really for the correction
of metabolic defects.
These are mostly pediatric patients.
These are young
children obviously that
are born with a metabolic defect.
The defects that we're talking
about are single gene mutations
in certain enzymes that
are mainly affecting the liver.
The two types of diseases, or the
two most frequently diseases that
are transplanted with
hepatocytes would
be ornithine transcarbamylase
deficiency, or OTC deficiency.
This is a problem with
ammonia metabolism.
The second most common disease that
is transplanted with hepatocytes
would be Criglar-Najjar.
This is a problem with
metabolism of bilirubin.
And the native liver cannot
metabolize these compounds,
and then the patients will end
up dying of CNS problems from
the buildup of the toxins, either
the ammonia or the bilirubin.
So what we can do in these cases
is transplant isolated liver cells
into the patient's
liver, and then give them
metabolic activity that's missing.
So the livers that we use
are from an organ donor,
and they are proficient in the
enzyme that's missing in the child.
So therefore, we can try to
repopulate their liver up
to about 10% of
their recipient liver
can be repopulated
with donor hepatocytes.
And if we can get to that
level of repopulation,
we can get basically
a complete metabolic
correction of the disease.
The patient still has the disease,
but they would show no symptoms
of the disease because we've
provided enough metabolic activity
in the transplanted cells to
accommodate all of the ammonia,
metabolism, or the
bilirubin metabolism
for instance, that these
patients would require.
So these are the main reasons
for doing hepatocyte transplants.
And on the next slide we will tell
you basically, how do you do this?