Zwitterionically modified alginates mitigate cellular overgrowth for cell encapsulation

Foreign body reaction (FBR) to implanted biomaterials and medical devices is common and can compromise the function of implants or cause complications. For example, in cell encapsulation, cellular overgrowth (CO) and fibrosis around the cellular constructs can reduce the mass transfer of oxygen, nut...

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Bibliographic Details
Main Authors: Liu, Qingsheng, Chiu, Alan, Wang, Long-Hai, An, Duo, Zhong, Monica, Smink, Alexandra M, de Haan, Bart J, de Vos, Paul, Keane, Kevin, Vegge, Andreas, Chen, Esther Y, Song, Wei, Liu, Wendy F, Flanders, James, Rescan, Claude, Grunnet, Lars Groth, Wang, Xi, Ma, Minglin
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2019
Subjects:
Engineering
Biomedical Engineering
Diabetes
Transplantation
Biotechnology
Metabolic and endocrine
Alginates
Animals
Betaine
Carbonic Acid
Cell Encapsulation
Cell Proliferation
Diabetes Mellitus
Experimental
Type 1
Dogs
Fibrosis
Foreign-Body Reaction
Islets of Langerhans Transplantation
Mice
Rats
Swine
Carbonic acid
Online Access:https://escholarship.org/uc/item/05s7r1f0
Description
Summary:Foreign body reaction (FBR) to implanted biomaterials and medical devices is common and can compromise the function of implants or cause complications. For example, in cell encapsulation, cellular overgrowth (CO) and fibrosis around the cellular constructs can reduce the mass transfer of oxygen, nutrients and metabolic wastes, undermining cell function and leading to transplant failure. Therefore, materials that mitigate FBR or CO will have broad applications in biomedicine. Here we report a group of zwitterionic, sulfobetaine (SB) and carboxybetaine (CB) modifications of alginates that reproducibly mitigate the CO of implanted alginate microcapsules in mice, dogs and pigs. Using the modified alginates (SB-alginates), we also demonstrate improved outcome of islet encapsulation in a chemically-induced diabetic mouse model. These zwitterion-modified alginates may contribute to the development of cell encapsulation therapies for type 1 diabetes and other hormone-deficient diseases.

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