Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet Microenvironment

Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet Microenvironment

The transplantation of porcine islets of Langerhans to treat type 1 diabetes may provide a solution to the demand for insulin-producing cells. Porcine islets encapsulated in agarose–agarose macrobeads have been shown to function in nonimmunosuppressed xenogeneic models of both streptozotocin-induced...

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Main Authors: Robert W. Holdcraft, Lawrence S. Gazda, Lisa Circle, Hollie Adkins, Steven G. Harbeck, Eric D. Meyer, Melissa A. Bautista, Prithy C. Martis, Melissa A. Laramore, Horatiu V. Vinerean, Richard D. Hall, Barry H. Smith
Format: Article
Language:English
Published: SAGE Publishing 2014-08-01
Series:Cell Transplantation
Online Access:https://doi.org/10.3727/096368913X667033
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spelling doaj-17541ac89a784e29b54c90e95fdaf0a12020-11-25T03:15:32ZengSAGE PublishingCell Transplantation0963-68971555-38922014-08-012310.3727/096368913X667033Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet MicroenvironmentRobert W. Holdcraft0Lawrence S. Gazda1Lisa Circle2Hollie Adkins3Steven G. Harbeck4Eric D. Meyer5Melissa A. Bautista6Prithy C. Martis7Melissa A. Laramore8Horatiu V. Vinerean9Richard D. Hall10Barry H. Smith11The Rogosin Institute–Xenia Division, Xenia, OH, USAThe Rogosin Institute, New York, NY, USAThe Rogosin Institute–Xenia Division, Xenia, OH, USAThe Rogosin Institute–Xenia Division, Xenia, OH, USAThe Rogosin Institute–Xenia Division, Xenia, OH, USAThe Rogosin Institute–Xenia Division, Xenia, OH, USAThe Rogosin Institute–Xenia Division, Xenia, OH, USAThe Rogosin Institute–Xenia Division, Xenia, OH, USAThe Rogosin Institute–Xenia Division, Xenia, OH, USAThe Rogosin Institute–Xenia Division, Xenia, OH, USABob Evans Farms, Inc., Columbus, OH, USANewYork-Presbyterian Hospital, New York, NY, USAThe transplantation of porcine islets of Langerhans to treat type 1 diabetes may provide a solution to the demand for insulin-producing cells. Porcine islets encapsulated in agarose–agarose macrobeads have been shown to function in nonimmunosuppressed xenogeneic models of both streptozotocin-induced and autoimmune type 1 diabetes. One advantage of agarose encapsulation is the ability to culture macrobeads for extended periods, permitting microbiological and functional assessment. Herein we describe optimization of the agarose matrix that results in improved islet function. Porcine islets (500 IEQs) from retired breeding sows were encapsulated in 1.5% SeaKem Gold (SG), 0.8% SG, or 0.8% Litex (Li) agarose, followed by an outer capsule of 5% SG agarose. Insulin production by the encapsulated islets exhibited an agarose-specific effect with 20% (0.8% SG) to 50% (0.8% Li) higher initial insulin production relative to 1.5% SG macrobeads. Insulin production was further increased by 40–50% from week 2 to week 12 in both agarose types at the 0.8% concentration, whereas islets encapsulated in 1.5% SG agarose increased insulin production by approximately 20%. Correspondingly, fewer macrobeads were required to restore normoglycemia in streptozotocin-induced diabetic female CD(SD) rats that received 0.8% Li (15 macrobeads) or 0.8% SG (17 macrobeads) as compared to 1.5% SG (19 macrobeads). Islet cell proliferation was also observed during the first 2 months postencapsulation, peaking at 4 weeks, where approximately 50% of islets contained proliferative cells, including β-cells, regardless of agarose type. These results illustrate the importance of optimizing the microenvironment of encapsulated islets to improve islet performance and advance the potential of islet xenotransplantation for the treatment of type 1 diabetes.https://doi.org/10.3727/096368913X667033
collection DOAJ
language English
format Article
sources DOAJ
author Robert W. Holdcraft
Lawrence S. Gazda
Lisa Circle
Hollie Adkins
Steven G. Harbeck
Eric D. Meyer
Melissa A. Bautista
Prithy C. Martis
Melissa A. Laramore
Horatiu V. Vinerean
Richard D. Hall
Barry H. Smith
spellingShingle Robert W. Holdcraft
Lawrence S. Gazda
Lisa Circle
Hollie Adkins
Steven G. Harbeck
Eric D. Meyer
Melissa A. Bautista
Prithy C. Martis
Melissa A. Laramore
Horatiu V. Vinerean
Richard D. Hall
Barry H. Smith
Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet Microenvironment
Cell Transplantation
author_facet Robert W. Holdcraft
Lawrence S. Gazda
Lisa Circle
Hollie Adkins
Steven G. Harbeck
Eric D. Meyer
Melissa A. Bautista
Prithy C. Martis
Melissa A. Laramore
Horatiu V. Vinerean
Richard D. Hall
Barry H. Smith
author_sort Robert W. Holdcraft
title Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet Microenvironment
title_short Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet Microenvironment
title_full Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet Microenvironment
title_fullStr Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet Microenvironment
title_full_unstemmed Enhancement of in Vitro and in Vivo Function of Agarose-Encapsulated Porcine Islets by Changes in the Islet Microenvironment
title_sort enhancement of in vitro and in vivo function of agarose-encapsulated porcine islets by changes in the islet microenvironment
publisher SAGE Publishing
series Cell Transplantation
issn 0963-6897
1555-3892
publishDate 2014-08-01
description The transplantation of porcine islets of Langerhans to treat type 1 diabetes may provide a solution to the demand for insulin-producing cells. Porcine islets encapsulated in agarose–agarose macrobeads have been shown to function in nonimmunosuppressed xenogeneic models of both streptozotocin-induced and autoimmune type 1 diabetes. One advantage of agarose encapsulation is the ability to culture macrobeads for extended periods, permitting microbiological and functional assessment. Herein we describe optimization of the agarose matrix that results in improved islet function. Porcine islets (500 IEQs) from retired breeding sows were encapsulated in 1.5% SeaKem Gold (SG), 0.8% SG, or 0.8% Litex (Li) agarose, followed by an outer capsule of 5% SG agarose. Insulin production by the encapsulated islets exhibited an agarose-specific effect with 20% (0.8% SG) to 50% (0.8% Li) higher initial insulin production relative to 1.5% SG macrobeads. Insulin production was further increased by 40–50% from week 2 to week 12 in both agarose types at the 0.8% concentration, whereas islets encapsulated in 1.5% SG agarose increased insulin production by approximately 20%. Correspondingly, fewer macrobeads were required to restore normoglycemia in streptozotocin-induced diabetic female CD(SD) rats that received 0.8% Li (15 macrobeads) or 0.8% SG (17 macrobeads) as compared to 1.5% SG (19 macrobeads). Islet cell proliferation was also observed during the first 2 months postencapsulation, peaking at 4 weeks, where approximately 50% of islets contained proliferative cells, including β-cells, regardless of agarose type. These results illustrate the importance of optimizing the microenvironment of encapsulated islets to improve islet performance and advance the potential of islet xenotransplantation for the treatment of type 1 diabetes.
url https://doi.org/10.3727/096368913X667033
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