Despite the promise of the Edmonton protocol, the need to use immunosuppressive drugs and the severe shortage of human islets remain major barriers to clinical islet transplantation. An attractive strategy to overcome these two barriers is the technique of microencapsulation of islets prior to transplantation. Still, there are a number of issues that need to be resolved before this approach can become a clinical reality. Microencapsulated islet transplantation is currently performed in the unmodified peritoneal cavity because of the need for a large space to accommodate the large graft volume for which conventional islet transplant sites, such as the liver, are not suitable. The relatively large surface-to-volume ratio of microcapsules and the absence of a blood supply in the peritoneal cavity pose challenges to adequate supply of oxygen and nutrients to the encapsulated islets as well as exchange of glucose and insulin between the encapsulated islets and the systemic circulation. We will test the hypothesis that neovascularization of encapsulated islet transplants would enhance the viability of the islets because of adequate supply of oxygen and nutrients.
The specific aims of this proposal are: 1) To design an optimum delivery system for angiogenic proteins to induce neovascularization around alginate microcapsules. After encapsulating the novel HBGAM-R136K angiogen in either of the alginate layers of alginate-polyornithine- alginate microcapsules, we will first study its release kinetics in vitro and the nature and level of microvasculature in vitro using fluorescence and image processing techniques. We will then examine tissue angiogenic and fibrotic responses to the protein in in vivo studies. 2) To determine the function of islets encapsulated and transplanted with the angiogenic protein to induce neovascularization. Using an isograft model of normal Lewis rat islet donors and Streptozotocin-diabetic Lewis rat recipients, we will co- encapsulate islets with angiogenic protein, and will assess blood glucose and insulin levels for 90 days after transplantation in omentum pouches of recipients. 3) To determine the efficacy of the optimized model of this bioartificial pancreas in a rat allograft. We will isolate and encapsulate islets from normal Wistar-Furth rats and transplant them in diabetic Lewis rats. 4) To assess the bioartificial pancreas function in xenograft animal models - first, human islets transplanted in diabetic Lewis rats for 90 days;and second, human islet transplants in diabetic monkeys for 180 days.

Public Health Relevance

It is now clear that islet transplantation provides the best treatment option for individuals afflicted with Type 1 diabetes. However, the shortage of human islets and the need to use risky drugs to prevent transplant rejection remain major obstacles to routine use of islet transplantation in diabetic patients. The purpose of this project is to develop a viable strategy to overcome these two barriers and make islet transplantation a more appealing and widely used treatment option for diabetic patients.

Agency
National Institute of Health (NIH)
Institute
National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK)
Type
Research Project (R01)
Project #
1R01DK080897-01A2
Application #
7655762
Study Section
Bioengineering, Technology and Surgical Sciences Study Section (BTSS)
Program Officer
Appel, Michael C
Project Start
2009-09-05
Project End
2011-08-31
Budget Start
2009-09-05
Budget End
2010-08-31
Support Year
1
Fiscal Year
2009
Total Cost
$508,800
Indirect Cost
Name
Wake Forest University Health Sciences
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
937727907
City
Winston-Salem
State
NC
Country
United States
Zip Code
27157
McQuilling, John Patrick; Sittadjody, Sivanandane; Pareta, Rajesh et al. (2017) Retrieval of Microencapsulated Islet Grafts for Post-transplant Evaluation. Methods Mol Biol 1479:157-171
Sittadjody, Sivanandane; Saul, Justin M; McQuilling, John P et al. (2017) In vivo transplantation of 3D encapsulated ovarian constructs in rats corrects abnormalities of ovarian failure. Nat Commun 8:1858
Balaji, Shruti; Zhou, Yu; Opara, Emmanuel C et al. (2017) Combinations of Activin A or Nicotinamide with the Pancreatic Transcription Factor PDX1 Support Differentiation of Human Amnion Epithelial Cells Toward a Pancreatic Lineage. Cell Reprogram 19:255-262
McQuilling, John Patrick; Opara, Emmanuel C (2017) Methods for Incorporating Oxygen-Generating Biomaterials into Cell Culture and Microcapsule Systems. Methods Mol Biol 1479:135-141
McQuilling, John P; Sittadjody, Sivanandane; Pendergraft, Samuel et al. (2017) Applications of particulate oxygen-generating substances (POGS) in the bioartificial pancreas. Biomater Sci 5:2437-2447
Balaji, Shruti; Zhou, Yu; Ganguly, Anasuya et al. (2016) The combined effect of PDX1, epidermal growth factor and poly-L-ornithine on human amnion epithelial cells' differentiation. BMC Dev Biol 16:8
Pareta, Rajesh; McQuilling, John P; Sittadjody, Sivanandane et al. (2014) Long-term function of islets encapsulated in a redesigned alginate microcapsule construct in omentum pouches of immune-competent diabetic rats. Pancreas 43:605-13
Yalcinkaya, Tamer M; Sittadjody, Sivanandane; Opara, Emmanuel C (2014) Scientific principles of regenerative medicine and their application in the female reproductive system. Maturitas 77:12-9
Opara, Emmanuel C; McQuilling, John P; Farney, Alan C (2013) Microencapsulation of pancreatic islets for use in a bioartificial pancreas. Methods Mol Biol 1001:261-6
Gandhi, Jarel K; Opara, Emmanuel C; Brey, Eric M (2013) Alginate-based strategies for therapeutic vascularization. Ther Deliv 4:327-41

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