Encapsulation of Islets in Rough Surface, Hydroxymethylated Polysulfone Capillaries Stimulates VEGF Release and Promotes Vascularization after Transplantation

The transplantation of encapsulated islets of Langerhans is one approach to treat type 1 diabetes without the need of lifelong immunosuppression. Capillaries have been used for macroencapsulation because they have a favorable surface-to-volume ratio and because they can be refilled. It is unclear at present whether the outer surface of such capillaries should be smooth to prevent, or rough to promote, cell adhesions. In this study we tested a new capillary made of modified polysulfone (MWCO: 50 kDa) with a rough, open-porous outer surface for islet transplantation. Compared with free-floating islets, encapsulation of freshly isolated rat islets affected neither the kinetics nor the efficiency of glucose-induced insulin release in perifusion experiments. Free-floating islets maintained insulin secretion during cell culture but encapsulated islets gradually lost their glucose responsiveness and released VEGF. This indicated hypoxia in the capillary lumen. Transplantation of encapsulated rat islets into diabetic rats significantly reduced blood glucose concentrations from the first week of implantation. This hypoglycaemic effect persisted until explantation 4 weeks later. Transplantation of encapsulated porcine islets into diabetic rats reduced blood glucose concentrations depending on the islet purity. With semipurified islets a transient reduction of blood glucose concentrations was observed (2, 8, 18, 18 days) whereas with highly purified islets a sustained normoglycaemia was achieved (more than 28 days). Explanted capillaries containing rat islets were covered with blood vessels. Vascularization was also observed on capillaries containing porcine islets that were explanted from normoglycaemic rats. In contrast, on capillaries containing porcine islets that were explanted from hyperglycemic rats a fibrous capsule and lymphocyte accumulations were observed. No vascularization on the surface of transplanted capillaries was observed in the absence of islets. In conclusion, encapsulated islets can release VEGF, which appears to be an important signal for the vascularization of the capillary material. The rough, open-porous outer surface of the polysulfone capillary provides a site well suited for vascular tissue formation and may allow a prolonged islet function after transplantation.

[1]  S. Sumi,et al.  Immunohistochemical Analysis of Vascular Endothelial Growth Factor and Hepatocyte Growth Factor, and Their Receptors, in Transplanted Islets in Rats , 2003, Surgery Today.

[2]  S. Sigrist,et al.  Influence of VEGF on the Viability of Encapsulated Pancreatic Rat Islets after Transplantation in Diabetic Mice , 2003, Cell transplantation.

[3]  S. Sigrist,et al.  Induction of Angiogenesis in Omentum with Vascular Endothelial Growth Factor: Influence on the Viability of Encapsulated Rat Pancreatic Islets during Transplantation , 2003, Journal of Vascular Research.

[4]  A. Halestrap,et al.  Matrix volume measurements challenge the existence of diazoxide/glibencamide‐sensitive KATP channels in rat mitochondria , 2003, The Journal of physiology.

[5]  M. Doser,et al.  Areal Density Measurement is a Convenient Method for the Determination of Porcine Islet Equivalents without Counting and Sizing Individual Islets , 2003, Cell transplantation.

[6]  E. Ryan,et al.  Current status of islet cell transplantation. , 2003, Advances in surgery.

[7]  K. Ulrichs,et al.  The Morphology of Islets within the Porcine Donor Pancreas Determines the Isolation Result: Successful Isolation of Pancreatic Islets can Now be Achieved from Young Market Pigs , 2002, Cell transplantation.

[8]  A. Shapiro,et al.  Successful islet transplantation: continued insulin reserve provides long-term glycemic control. , 2002, Diabetes.

[9]  G. Reach,et al.  A novel model of solute transport in a hollow-fiber bioartificial pancreas based on a finite element method. , 2002, Biotechnology and bioengineering.

[10]  P. Carlsson,et al.  Graft vascular function after transplantation of pancreatic islets , 2002, Diabetologia.

[11]  A. Szewczyk,et al.  Mitochondria as a Pharmacological Target , 2002, Pharmacological Reviews.

[12]  P. de Vos,et al.  Considerations for successful transplantation of encapsulated pancreatic islets , 2002, Diabetologia.

[13]  M. Doser,et al.  In Vitro Test of New Biomaterials for the Development of a Bioartificial Pancreas , 2001, Annals of the New York Academy of Sciences.

[14]  H. Ammon,et al.  Kapillarmembranen aus modifizierten Polysulfonen , 2001 .

[15]  M. Menger,et al.  Revascularization and Microcirculation of Freely Grafted Islets of Langerhans , 2001, World Journal of Surgery.

[16]  N. Heyne,et al.  Improved diffusion properties of a new polysulfone membrane for the development of a bioartificial pancreas. , 2001, Transplantation proceedings.

[17]  H. Planck,et al.  Macroencapsulation of rat islets without alteration of insulin secretion kinetics , 2001, Experimental and clinical endocrinology & diabetes : official journal, German Society of Endocrinology [and] German Diabetes Association.

[18]  E. Ryan,et al.  Islet transplantation in seven patients with type 1 diabetes mellitus using a glucocorticoid-free immunosuppressive regimen. , 2000, The New England journal of medicine.

[19]  M. Menger,et al.  Exocrine contamination of isolated islets of Langerhans deteriorates the process of revascularization after free transplantation. , 2000, Transplantation.

[20]  G. Steil,et al.  Improved Vascularization of Planar Membrane Diffusion Devices following Continuous Infusion of Vascular Endothelial Growth Factor , 2000, Cell transplantation.

[21]  J. Schrezenmeir,et al.  The effect of alginate and hyaluronate on the viability and function of immunoisolated neonatal rat islets. , 1999, Biomaterials.

[22]  L. Aiello,et al.  Hypoxia induces vascular endothelial growth factor gene and protein expression in cultured rat islet cells. , 1998, Diabetes.

[23]  R. Calafiore Actual perspectives in biohybrid artificial pancreas for the therapy of type 1, insulin-dependent diabetes mellitus. , 1998, Diabetes/metabolism reviews.

[24]  I. Rustenbeck,et al.  Direct effects of diazoxide on mitochondria in pancreatic B‐cells and on isolated liver mitochondria , 1998, British journal of pharmacology.

[25]  G Reach,et al.  Reversal of diabetes in non-obese diabetic mice by xenografts of porcine islets entrapped in hollow fibres composed of polyacrylonitrile-sodium methallylsulphonate copolymer. , 1997, Diabetes & metabolism.

[26]  L. Orci,et al.  Vascular endothelial growth factor is increased in devascularized rat islets of Langerhans in vitro. , 1997, Transplantation.

[27]  R. Bretzel,et al.  Islet transplantation in immunoseparating membranes for treatment of insulin-dependent diabetes mellitus. , 2009, Experimental and clinical endocrinology & diabetes : official journal, German Society of Endocrinology [and] German Diabetes Association.

[28]  N J London,et al.  FUNCTIONAL STUDIES OF RAT, PORCINE, AND HUMAN PANCREATIC ISLETS CULTURED IN TEN COMMERCIALLY AVAILABLE MEDIA , 1995, Transplantation.

[29]  S. Genuth,et al.  The effect of intensive treatment of diabetes on the development and progression of long-term complications in insulin-dependent diabetes mellitus. , 1993, The New England journal of medicine.

[30]  V. Grill,et al.  B-cell insensitivity in vitro: reversal by diazoxide entails more than one event in stimulus-secretion coupling. , 1993, Endocrinology.

[31]  C. Colton,et al.  Effect of Hypoxia on Insulin Secretion by Isolated Rat and Canine Islets of Langerhans , 1993, Diabetes.

[32]  B A Solomon,et al.  Xenotransplantation of canine, bovine, and porcine islets in diabetic rats without immunosuppression. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[33]  R. Bretzel,et al.  Bioartificial pancreas: the use of different hollow fibers as a diffusion chamber. , 1989, Transplantation proceedings.

[34]  P. Lacy,et al.  A Method for the Mass Isolation of Islets From the Adult Pig Pancreas , 1986, Diabetes.

[35]  S. Woodward How Fibroblasts and Giant Cells Encapsulate Implants: Considerations in Design of Glucose Sensors , 1982, Diabetes Care.