Oxygen supply to encapsulated therapeutic cells

Therapeutic cells encapsulated in immunobarrier devices have promise for treatment of a variety of human diseases without immunosuppression. The absence of sufficient oxygen supply to maintain viability and function of encapsulated tissue has been the most critical impediment to progress. Within the...

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Veröffentlicht in:	Advanced drug delivery reviews 2014-04, Vol.67-68, p.93-110
1. Verfasser:	Colton, Clark K.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Cell Survival Cell transplantation Cell Transplantation - instrumentation Cell Transplantation - methods Diffusion Encapsulation Graft Rejection - prevention & control Humans Hypoxia Immunobarrier Immunoisolation Implanted devices Islets of Langerhans Transplantation Oxygen - administration & dosage Oxygen - metabolism Oxygen supply
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container_title	Advanced drug delivery reviews
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creator	Colton, Clark K.
description	Therapeutic cells encapsulated in immunobarrier devices have promise for treatment of a variety of human diseases without immunosuppression. The absence of sufficient oxygen supply to maintain viability and function of encapsulated tissue has been the most critical impediment to progress. Within the framework of oxygen supply limitations, we review the major issues related to development of these devices, primarily in the context of encapsulated islets of Langerhans for treating diabetes, including device designs and materials, supply of tissue, protection from immune rejection, and maintenance of cell viability and function. We describe various defensive measures investigated to enhance survival of transplanted tissue, and we review the diverse approaches to enhancement of oxygen transport to encapsulated tissue, including manipulation of diffusion distances and oxygen permeability of materials, induction of neovascularization with angiogenic factors and vascularizing membranes, and methods for increasing the oxygen concentration adjacent to encapsulated tissue so as to exceed that in the microvasculature. Recent developments, particularly in this latter area, suggest that the field is ready for clinical trials of encapsulated therapeutic cells to treat diabetes. [Display omitted]
doi_str_mv	10.1016/j.addr.2014.02.007
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The absence of sufficient oxygen supply to maintain viability and function of encapsulated tissue has been the most critical impediment to progress. Within the framework of oxygen supply limitations, we review the major issues related to development of these devices, primarily in the context of encapsulated islets of Langerhans for treating diabetes, including device designs and materials, supply of tissue, protection from immune rejection, and maintenance of cell viability and function. We describe various defensive measures investigated to enhance survival of transplanted tissue, and we review the diverse approaches to enhancement of oxygen transport to encapsulated tissue, including manipulation of diffusion distances and oxygen permeability of materials, induction of neovascularization with angiogenic factors and vascularizing membranes, and methods for increasing the oxygen concentration adjacent to encapsulated tissue so as to exceed that in the microvasculature. Recent developments, particularly in this latter area, suggest that the field is ready for clinical trials of encapsulated therapeutic cells to treat diabetes. 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subjects	Animals Cell Survival Cell transplantation Cell Transplantation - instrumentation Cell Transplantation - methods Diffusion Encapsulation Graft Rejection - prevention & control Humans Hypoxia Immunobarrier Immunoisolation Implanted devices Islets of Langerhans Transplantation Oxygen - administration & dosage Oxygen - metabolism Oxygen supply
title	Oxygen supply to encapsulated therapeutic cells
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