3. JDRF FY 2004: Geography
4. To Cure Type 1 Diabetes = �Developing Curative or “Cure” Therapeutics or Interventions Islet transplantation or regeneration
Immune tolerance or immunoregulation
Complications
Combination therapy will be required!
8. JDRF Five-Year Bold and Significant Outcomes on the Path to Cure Type 1 Diabetes Perform islet transplantation without chronic immunosuppression
Create a “universal donor” source of insulin-secreting cells for transplantation
Regenerate the body’s own beta cells
Prevent type 1 diabetes or reverse type 1 diabetes in new-onset disease by maintaining or restoring immune tolerance
Predict, prevent, reverse complications
Perfect a closed loop artificial pancreas
9. Islet Transplantation
12. Edmonton Protocol
15. Islet Transplantation: Source Improvements in islet isolation and preservation- culturing islets before infusion
Single cadaver donor pancreas
New sources for islets: in-vitro growth of human islets, porcine islets, embryonic and adult stem cells, living related islets
Non-heart beating donors
Age limits to include over 65
Obese
Infusion protocols- prevent bleeding at site on infusionNon-heart beating donors
Age limits to include over 65
Obese
Infusion protocols- prevent bleeding at site on infusion
19. As several scientists have pointed out, we know of only one definite path to create a beta cell and that is the path nature takes in going from an embryonic stem cell. So we must vigorously pursue this avenue of research in addition to searching for any possible adult stem cells that could be coaxed to become beta cells.As several scientists have pointed out, we know of only one definite path to create a beta cell and that is the path nature takes in going from an embryonic stem cell. So we must vigorously pursue this avenue of research in addition to searching for any possible adult stem cells that could be coaxed to become beta cells.
20. JDRF�Stem Cell Research $9M in FY04: $5M ES, $3M adult, $1M animal stem cells
Partnerships: Sweden, UK, France, Finland, Canada, Australia, Singapore
Animal-free hES lines being derived
D. Melton derived 28 new stem cell lines with JDRF and HHMI funding
22. Islet Transplantation Requires Chronic Immunosuppression to Prevent Alloimmune (Foreign) or Autoimmune Rejection Non-heart beating donors
Age limits to include over 65
Obese
Infusion protocols- prevent bleeding at site on infusionNon-heart beating donors
Age limits to include over 65
Obese
Infusion protocols- prevent bleeding at site on infusion
23. Immune Tolerance or Immunoregulation Non-heart beating donors
Age limits to include over 65
Obese
Infusion protocols- prevent bleeding at site on infusionNon-heart beating donors
Age limits to include over 65
Obese
Infusion protocols- prevent bleeding at site on infusion
24. Need to Replace Chronic Immunosuppression with Immune Tolerance or Immunoregulation to Prevent Islet Rejection Non-heart beating donors
Age limits to include over 65
Obese
Infusion protocols- prevent bleeding at site on infusionNon-heart beating donors
Age limits to include over 65
Obese
Infusion protocols- prevent bleeding at site on infusion
26. Beyond Edmonton: JDRF Centers Alabama – NHP (monkey) islet transplants without chronic immune suppression and stable for >5 years
Pennsylvania – NHP islet transplants without chronic immune suppression
Edmonton, Emory – NHP islet transplantation without lifelong drugs
Minnesota – Plans first ‘drug withdrawal’ clinical trial
Harvard– Power Mix in NHP w/o immune suppression
Harvard– Novel approach to “mixed chimerism” Deleted Birmingham in second bulletDeleted Birmingham in second bullet
27. Five-Year Bold and Significant Outcomes on the Path to Cure Type 1 Diabetes Performing islet transplantation without chronic immunosuppression
Creating a “universal donor” source of insulin-secreting cells for transplantation
Regenerating the body’s own beta cells
Preventing type 1 diabetes or reversing type 1 diabetes in new-onset disease by maintaining or restoring immune tolerance
Predicting, preventing, reversing complications
Perfecting a closed loop artificial pancreas
28. Regeneration: Why now? Normal turnover of beta cells
Physiological increase in beta cells in obesity and pregnancy
Regeneration occurs in animal models of diabetes, pancreatic injury- ? Mechanisms
Evidence of residual islets and function in type 1 diabetes
30. Can beta cell regeneration occur in established Type 1 Diabetes? Pancreatic beta cell regenerative capacity may remain clinically masked by
Poor glycemia control and/or other metabolic factors
Residual anti-beta cell specific autoimmunity
Increase by directing careful attention to:
Glycemia and lipid control
Control of anti-beta cell autoimmunity
Delivering factors that promote beta cell neogenesis, replication, or survival in vivo
32. Regeneration Therapeutics: Application Established Diabetes- restore beta cells
Prediabetes- maintain beta cell reserves of genetically identified high risk subjects
Early application to islet transplantation
33. Regeneration Research: Interim Application to Islet Transplantation Islet transplantation setting can be used to test regeneration discoveries, and in turn, interim regeneration discoveries and developments can be applied to benefit islet transplantation
Enhance success of current islet transplant protocols
Grow islets from a single donor organ to transplant multiple recipients
Safely transplant adequate number of islets from a living-related donor
34. Regeneration: Clinical Trials� GLP-1/Exendin-4/Exenatide-4/Incretin mimetics (Glucagon-Like Peptide-1)
C Greenbaum- At-risk
K Herold- New onset diabetes with anti-CD3
D Harlan- Established type 1 diabetes with immunosuppression
C Ricordi- Islet transplantation setting
(Amylin)
EGF and Gastrin; GLP-1 and Gastrin
(Transition Therapeutics/NovoNordisk)
INGAP (Islet NeoGenesis Associated Protein)
(GMP/Procter and Gamble Pharmaceuticals)
35. JDRF Regeneration Program: “Regeneration of Beta Cell Function” Goal driven program with milestones
Team Science- interdisciplinary, interactive teams from diverse scientific fields and from both academia and industry, attract new scientists (to date- 17 scientists in the program)
Fast-track
Accountability
Focused on solving problems
36. Five-Year Bold and Significant Outcomes on the Path to Cure Type 1 Diabetes Performing islet transplantation without chronic immunosuppression
Creating a “universal donor” source of insulin-secreting cells for transplantation
Regenerating the body’s own beta cells
Preventing type 1 diabetes or reversing type 1 diabetes in new-onset disease by maintaining or restoring immune tolerance
Predicting, preventing, reversing complications
Perfecting a closed loop artificial pancreas
37. Clinical Interventions in Type 1 Diabetes
38. Clinical Interventions in Type 1 Diabetes
39. Clinical Interventions in Type 1 Diabetes
41. Treatment of New Onset Type I Diabetes with Non-Mitogenic anti-CD3 Antibody 3 Clinical Trials completed to date
JDRF sponsored- European Phase II trial – Multicenter – Placebo Controlled- 80 patients with recent onset Type I diabetes (<4 weeks insulin treatment)- one week antibody treatment
Outcome- preservation of insulin secretion and secondarily decreased insulin dose requirements at 6, 12, 18, 24 months after treatment
Long term effects from activation of immunoregulation
42. Treatment of New Onset Type I Diabetes with Non-Mitogenic anti-CD3 Antibody: Next Steps Prolong the therapeutic effect
Combine with regeneration therapeutics- e.g. Exenatide
Apply to high risk prediabetes to prevent onset of Type 1 diabetes
43. Five-Year Bold and Significant Outcomes on the Path to Cure Type 1 Diabetes Performing islet transplantation without chronic immunosuppression
Creating a “universal donor” source of insulin-secreting cells for transplantation
Regenerating the body’s own beta cells
Preventing type 1 diabetes or reversing type 1 diabetes in new-onset disease by maintaining or restoring immune tolerance
Predicting, preventing, reversing complications
Perfecting a closed loop artificial pancreas
44. Recent work by Michael Brownlee’s group suggests that overproduction of mitochondrial
superoxide is the principle pathogenic insult underlying the activation
of these four major pathways to hyperglycemia induced injury.
This may explain why single pathway inhibitors have not worked well in clinical trialsRecent work by Michael Brownlee’s group suggests that overproduction of mitochondrial
superoxide is the principle pathogenic insult underlying the activation
of these four major pathways to hyperglycemia induced injury.
This may explain why single pathway inhibitors have not worked well in clinical trials
45. Common Pathways in Complications
46. Research Management Acceleration Strategy Focus on Cure therapeutic Goals
Leverage/Coordinate/Integrate all funders of type 1 research
Rapid response to opportunities
Translate 30 years of basic science discovery to commercial application for development of therapeutics
Address the funding gap between basic science and clinical development, while continuing to support innovative discovery
52. Questions
53. Research Has Already Significantly Improved the Lives of People with Diabetes DCCT – we now know how to reduce the threat of complications
Vast improvement in monitors/insulin delivery
Laser Treatment for Retinopathy
Statins to reduce risk of heart disease
>400 people “cured” by islet transplantation
Several successful experimental treatments of complications
Several successful experimental treatments that have stopped progression of diabetes
54. Recent New Research Developments Better understanding of immunology of type 1 diabetes
Better understanding of pathogenesis of complications
Improved immunosuppression and new approaches to induce immune tolerance
New insights into genetics of diabetes
55. Important Diabetes Discoveries and Developments in Last Decade Success of Islet Transplantation
Ability to predict accurately risk of diabetes (genetics, antibodies)
Interventions in new-onset diabetes to preserve beta cells
DCCT study insights of importance of glucose control to prevent complications
Improvement in glucose monitoring
57. Auto-immunity�Intervention Trials Clinical
Anti-CD3 Phase II clinical trial – New York/Belgium
IL2 and rapamycin in new onset – Joslin
Anti-CD3 plus Exendin4 – New York/San Francisco
MMF + daclizumab – Denver
Pre-clinical
Anti-CD20 – Penn
Thymoglobulin – Genzyme
