Current Trends in Cell TherapyCurrent Trends in Cell Therapy
Alexey Bersenev, MD, PhD
Children’s Hospital of Philadelphia
www.Hematopoiesis.info
www.StemCellAssays.com
twitter: @cells_nnm
Moscow, Sep. 27, 2010under the following license
Creative Commons Atribution Non-Commercial
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Trending is information processingTrending is information processing
Bersenev A. Cellular Therapy and Transplantation. 2010;2(7). 10.3205/ctt-2010-en-000084.01
www.Hematopoiesis.info www.StemCellAssays.com
Frequently discussed topics and outline of the talk:Frequently discussed topics and outline of the talk:
1. Link between stem cell self-renewal, expansion and cancer
2. Hematopoietic stem cell expansion for clinical use
3. Cord blood banking and use
4. Clinical trials and cell therapy activity
5. Paradigms shift in cell therapy
6. Cell therapy and Regenerative Medicine industry today
7. Cell products development
Cancer
Cell proliferation
Stem cell
self-renewal
HSC aging
Arf
Ink4a
Bmi-1
Hmga2
Sean Morrison group 2005-2008
Link between stem cell renewal, cancer and Link between stem cell renewal, cancer and agingaging
Stem cell renewal, expansion and cancer Stem cell renewal, expansion and cancer
1. Link between stem cell self-renewal, cancer, aging, regeneration seem to be universal across adult tissues
2. All regulators of SC self-renewal are very good candidates for targeted expansion
3. We can not uncouple self-renewal and cancer activation pathways (Wnt, Notch, SHH…)
Playing with stem cell self-renewal Playing with stem cell self-renewal is a dangerous game!is a dangerous game!
http://hematopoiesis.info/2010/07/07/do-we-really-need-hematopoietic-stem-cell-expansion-for-clinical-use/
Do we really need HSC expansion for clinical use?Do we really need HSC expansion for clinical use?
1. Unlike preclinical data we actually can not achieve expansion of engraftable long-term HSCs in clinic
2. In order to achieve significant clinical improvement we don’t need a lot of HSCs but we need a lot of progenitors
3. T-cells alone, without engraftable HSCs can induce graft-versus-tumor effect and eradicate neoplasm
4. Methods for HSCs engraftment improvement will be more clinically sufficient than chasing for increasing of HSCs number through expansion
5. Cost, scalability and commercialization issues
Two ongoing clinical trials for cord blood HSC expansion: Two ongoing clinical trials for cord blood HSC expansion:
1. Fred Hutchinson Cancer Center (Irwing Bernstein group. Nat Med 2010; 16:232)
Set up: CB isolated CD34+ cultured on immobilized engineered Notch ligand in SCF /Flt3L /TPO /IL-3 /IL-6 for 16 days
2. MD Anderson Cancer Center (Elizabeth Shpall group. Reported at ASH and other conferences 2008-2010)
Set up: CB isolated CD34+ or CD133+ in liquid culture in SCF /Flt3L /G-CSF /TPO for 2 weeksCo-culture with allogeneic related matched MSC or commercially available MSCs (Angioblast)
Expanded versus unmanipulated human cord blood Expanded versus unmanipulated human cord blood samples neutrophils engraftment kineticssamples neutrophils engraftment kinetics
Adapted from Elizabeth Shpall report at 10th Anniversary of Netcord Conference16-19 October 2008 - Mandelieu, France (modified)
time after transplant
hem
ato
po
ieti
c co
ntr
ibu
tio
n
one year
Lin-CD34+CD38-CD90+
CD45RA-
CD34+CD38-CD90-
CD45RA+
HSC
MLP
ETP
B/NK
CMP
CD34+CD38+CD10+
CD45RA+
CD34+CD38+Flt3+
CD45RA-GMP
MEP
CD34+CD38+Flt3+
CD45RA+
CD34+CD38+Flt3-
CD45RA-
MDP
MPP
Lin-CD34+CD38-CD90-
CD45RA-
Current map of human hematopoietic CD34+ populationCurrent map of human hematopoietic CD34+ population
Irv Weissman group Cell Stem Cell 2007; 1: 635 John Dick group Nat Immunol 2010; 11: 585
stem cell(<10% of CD34+ in bone marrow and
0.5-1% of CD34+ in cord blood)
progenitors(90-99% of CD34+)
CD34+
ex vivo expansion possibility
Summary of HSC expansion in clinic: Summary of HSC expansion in clinic:
1. Expanded CB unit doesn’t sustain long-term repopulation and is always overtaken by unmanipulated unit, which dominates the engraftment (Irwing Bernstein, 2010, Elizabeth Shpall, 2008-2010)
2. Total CD34+ number is expanded and correlates with rapid engraftment and improved neutrophil and platelet recovery
3. Stem cell expansion was not achieved
4. No engraftment failure observed and there was clear clinical benefit
5. We should continue to pursue expansion approaches, but focus on hematopoietic progenitors
approach examples phaseincrease yield of HSC by
isolation procedure1. cord + placental blood HSC (HemaCell
Perfusion system)2. improving CB processing (BioE PrepaCyte- CB)
preclinical - I
co-transplantation with few HSC sources
1. double unit CB transplant2. CB+MB or CB+BM from 3rd party
II-III- wide clinical use
split dosages CB transplant preclinical - I
manipulation of HSC homing and migration
1. Fucosyltransferase - ASC101 (Engraftin)2. CD26 inhibition (Diprotin A)
preclinical - I
manipulation of bone marrow niche
1. Parathyroid Hormone (PHT)2. new conditioning (anti-cKit or CD45 Ab)
preclinical -I
new route for transplant intra-bone BMT I-II
co-transplantation with cells engraftment
mesenchymal stromal progenitors ( Pluristem PLX-I)
I
hematopoietic progenitors expansion ex vivo
1. allo- myeloid progenitors (Cellerant CLT-08)2. mix of CD34+ progenitors (StemEx Gamida Cell)
I
HSCs expansion ex vivo Aryl Hydrocarbon Receptor Antagonists? experiment
Approaches used for improvement of HSC engraftment: Approaches used for improvement of HSC engraftment:
Trends in cord blood bankingTrends in cord blood banking
1. Private, public and hybrid banks will and should co-exist, but number of private banks could shrink
2. CB inventory: How many samples is enough? (For UK = 50,000 units)
3. Quality versus quantity (nearly 2/3 of samples delivered to public bank could be rejected)
4. If private banks want to play “the regenerative medicine game”, quality of samples should be improved!
5. How to calculate probability of use?
6. Allogeneic CB for non-hematological diseases will enter the clinical trials = game changer
Current use of cord blood Current use of cord blood
1. Currently much more inferior to other sources of HSCs: Allo BM >> Auto BM; if Auto: MPBSC >> BM; if Allo: MPBSC >> BM >> CB (2x)
2. Autologous CB procurement and transplantation is more expensive than MPBSC (Beguin Y, 2009)
3. Probability of suitable graft for adults (70kg) - 25% of inventory for Auto use, 5% - for Allo malignant disease; 0% - for Allo non-malignant disease (Beguin Y, 2009)
4. Number of CB transplants now more in adults than in children since 2006 (EuroCord, 2009)
5. About 40% of CB transplants in adults is double-unit transplants (EuroCord, 2009)
Autologous use of CB in Regenerative MedicineAutologous use of CB in Regenerative Medicine
1. Right now pediatrics only: 255 patients treated by April of 2010 (cerebral palsy = 166; brain injury = 35; type I diabetes = 24 and other indications) (Frances Verter, Parent's Guide to Cord Blood Foundation, ISCT’2010 report)
2. How to calculate the probability?cumulative number of allogeneic cord blood use is linear, whereas that number for autologous use is rising faster than exponential (Frances Verter, Parent's Guide to Cord Blood Foundation, ISCT’2010 report)
In adults: Regenerative Medicine will be most applicable in “aging boomers”. Would you store your sample for 60 or more years if there are other (cheaper and better) alternatives?
Allogeneic use of CB in Regenerative MedicineAllogeneic use of CB in Regenerative Medicine
1. Allogeneic CB could be as suitable as autologous CB
2. Matched unrelated allo CB transplant - same results (leukemia-free survival) with matched in children and adults
3. Questions:
Can we transplant HLA-mismatched CB cells into the patient with degenerative disease without fear of adverse immune reactions?
Can we transplant allogeneic CB cells with a regenerative purpose without myeloablative or immunosuppressive conditioning?
What therapeutic benefit would we expect after allogeneic CB cell therapy in immunocompetent (non-conditioned) patient?
Non-hematopoietic stem /progenitor cells in CB for Non-hematopoietic stem /progenitor cells in CB for regenerative medicineregenerative medicine
1. What is unique stem and non-stem cells properties CB can offer that is not available in BM? Pluripotent SC candidates: USSC, VSEL, MAPC – are not unique
2. MSC number is inferior to other sources (BM)
3. EPC - highly allo-immunogeneic
4. In case of autologous use: What cell viability and potential will be after 30-70 years of storage? Will standards in 50 years comparable with current collection and storage practice?
Cell therapy activity in numbers:Cell therapy activity in numbers:
1. The feasibility and safety of cell therapy has been established in over 3000 patients with heart diseases (Behfar A, et al, 2010)
2. MSC: 101 trials total launched and available for analysis (www.ClinicalTrials.gov); 59 allo- , 42 auto-; 21 trials were completed in 2010; total number of patients treated - 5344
3. HSC transplantation for autoimmune diseases in Europe: 1122 patients were treated in 30 countries. 85% 5-years overall survival and 43% 5-years progression-free survival (Saccardi R., EBMT 2010)
4. Cellular therapy activity survey 2008 in Europe: 1040 patients treated - 376 (36%) with allo- and 664 (64%) with auto- cells. Non-hematopoietic use: 454 total. Indications: cardiovascular, neurological and tissue repair (EBMT activity survey 2008)
Current view on transdifferentiation of adult SC (HSC or MSC) Current view on transdifferentiation of adult SC (HSC or MSC) as rationale for regenerative cell therapiesas rationale for regenerative cell therapies
1. lack of assays, false positive results and artifacts;
2. fusion
3. genetic material transfer by microvesicles/ exosomes or phagocytosis of apoptotic bodies
4. even if phenomenon of transdifferentiation exist, it can not justify therapeutic potential of injected cells
Paradigm shift in understanding therapeutic efficiency of Paradigm shift in understanding therapeutic efficiency of mesenchymal stem cells (MSC)mesenchymal stem cells (MSC)
1. long-term engraftment of transplanted MSC was not demonstrated in human
2. trophic function and immunomodulation as mechanisms (indirect or paracrine; growth factors; angiogenesis)
3. differentiation is not the mechanism of action
4. it becomes more like a drug therapy but not as cell replacement transplantation where mechanism is differentiation
Paradigm shift – manipulation of endogenous cells instead of Paradigm shift – manipulation of endogenous cells instead of cell injection – cell therapy without the cellscell injection – cell therapy without the cells
1. Manipulation by homing/ migration
2. Differentiational mobilization
3. Stem cell niche manipulation
4. Cell therapy in citu
Controlled (differentiational) mobilization - experimentControlled (differentiational) mobilization - experiment
1. MSC: substance P, VEGF+AMD3100
2. EPC: VEGF alone, VEGF+AMD3100, SDF-1,Ang-1, AMD3100 4 hours
3. HPC: AMD3100, G-CSF, S1P, Flt3L 5 days
4. HSC: Flt3L 10 days
Pitchford S. et al. Cell Stem Cell 2009; 4:62
Cell therapy in citu Cell therapy in citu
1. PEGylated fibrinogen, bound with recombinant SDF-1 heart patch of Jianyi Zhang
2. In situ bioreactive devices (iBD) of David Mooney
http://hematopoiesis.info/2009/06/04/future-of-implantable-cell-capturing-devices/
•PLG matrix with mobilized GM-CSF and tumor antigen. G-CSF attracts dendritic cells, which start to expand and present tumor antigen.
The place of cell therapy in Regen industryThe place of cell therapy in Regen industry
cellbio
scaffoldgene
protein
Regen /Cell Tx
Biotech
healthcare industry
Pharma
biologic
Smallmolecule
tissue
chemical
RNAi
Regenerative Medicine replaces or regenerate human cells, tissue or organs, to restore or establish normal function (Chris Mason, 2008)
cell therapy
tissue engineering
scaffold /biomatrix
gene therapy
growth factors /proteins
Medical Devicepolymerscaffold
microRNA
Where cell therapies will play a role?Where cell therapies will play a role?
1. Offers cures, not just manage symptoms
2. Can actually replace and repair tissue
3. Persistent potential
Regenerative Medicine cell therapy industry todayRegenerative Medicine cell therapy industry today
1. New sector of advanced healthcare
2. Regen is the profitable business!
3. Minimum baseline of 675,000 therapeutic units manufactured and 323,000 patients treated with FDA/EMA approved cell therapeutics
4. Regenerative medicine cell therapy - $100–200 million per year industry
Chris Mason, Elisa Manzotti Regen Med 2010; 5:307
Regenerative Medicine business models:Regenerative Medicine business models:
1. banking
2. cell & tissue acquisition
3. cells, kits and reagents for research
4. devices
5. logistics/ shipping
6. consulting
7. IP/ licensing/ patenting
8. contract manufacturing
9. cell lines for toxicology and drug screening
10. veterinary cell therapy
11. therapies
Cell therapy business models: Autologous and AllogeneicCell therapy business models: Autologous and Allogeneic
Autologous:1. physiological limit - number, function and proliferative
potential could decline with age
2. immunogenicity is zero but could be at some degree if product is manipulated extensively; potential tumorigeneicity
3. personalized cell product could be highly complex and business model is not always clear
Allogeneic:1. “of-the-shelf” with different level of manipulations ex vivo
2. manufactured by companies and available on the market
3. scale up manufacturing
4. “cost of goods” could be brought down by outsourcing (contract manufacturing)
5. reasonable cost
6. immunogenicity at different degree, potential tumorigeneicity
7. clear business model
Features of autologous cell products:Features of autologous cell products:
For acute disease:
1. minimally manipulated (cell processing, separation, washing)
2. can be embedded in healthcare (all steps could be done in the hospital)
3. cheap
For chronic disease:
1. usually extensively manipulated ex vivo (cell separation, expansion, differentiation, gene-modification)
2. manufacturing usually outsourced (contract manufacturing)
3. product manufacturing scaled out
4. expensive
http://celltherapyblog.blogspot.com/2009/02/how-many-cell-therapy-products-are-in.html
Cell products in development and on the market:Cell products in development and on the market:
Number of cell products in different phases of development:
78 Pre-clinical77 Phase I89 Phase II33 Phase III
67 Commercial
Total number of companies - stakeholders in the cell therapy sector ~ 700. This includes ~250 therapeutic companies with ~340 cell-based therapeutic products (Lee Buckler, Cell Therapy Group, 2009)
Cell product is defined as any cell-based product involving live cells ‘produced’ ex vivo intended for therapy
product brand FDA approval
donor profitability cost-effectiveness
price,USD
Carticel Genzyme 1997 autologous yes yes 17,000-38,000
Apligraf Organogenesis 1998 allogeneic yes yes ~1,200 per use
Provenge Dendreon 2010 autologous ? ? 93,000 (31,000 x3)
Cost/ profitability of approved cell products in US:Cost/ profitability of approved cell products in US:
Only about 2.2% of the overall cell therapy market is spent on manufacturing
http://celltherapyblog.blogspot.com/2008/08/cell-therapy-manufacturing-market.html
~ 12% of cell therapy product manufacturing is currently outsourced to private, industry contract manufacturers
Allogeneic versus Autologous Manufacturing Summary
Master Cell BankLot Tested
Working Cell BanksLot Tested
Patient DosesLot Tested
Cell E
xpan
sion
Cell E
xpan
sion
or P
urificatio
nTesting
Patient or Donor
Cell Ampoule or Dose
Submitted for Testing
Allogeneic / Universal Donor Autologous / Patient Specific
courtesy of Jon Rowley, LOnza
The value of stem cells in cell therapy productsThe value of stem cells in cell therapy products
1. We can not support and activate self-renewal and stem cell expansion without risk of carcinogenesis
2. Adult stem cells (MSC, HSC), expanded ex vivo, loosing stemness and ability to long-term engraftment
3. The mechanism of therapeutic action of injected stem cells (MSC, HSC) still unknown
4. We have very hard time in characterization and development of stem cell products - potency and safety assays
5. At the most indications, all we need is well characterized progenitors and mature cell types
6. Overall, the value of stem cells as a product in cell therapy currently is low