Hydrogel Biomaterials for Stem Cell Microencapsulation

Choe, Goeun; Park, Junha; Park, Hansoo; Lee, Jae Young

doi:10.3390/polym10090997

Cited by 107 publications

(92 citation statements)

References 94 publications

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“…Slowly degrading materials compatible with SC culture could also be used. MCs made of materials that have been developed with the purpose of being bio-chemically degraded in vivo in the context of skeletal tissue engineering and drug delivery systems become more relevant in this case (169)(170)(171)(172). For instance, Zhou et al have developed an alginate-fibrin microbead that starts to degrade and release cells 4 days after injection in a calcium phosphate cement scaffold (173).…”

Section: Scenario 2: Non-edible Degradable Microcarriersmentioning

confidence: 99%

Microcarriers for Upscaling Cultured Meat Production

2020

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Section: Scenario 2: Non-edible Degradable Microcarriersmentioning

confidence: 99%

Microcarriers for Upscaling Cultured Meat Production

2020

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“…17,18 However, scaling these methods to the levels needed for transplants can be challenging. An excellent review of the different methods used to create microspheres from PEG or HA, including photolithography, micromolding, and emulsion, can be found in Choe et al 19 We developed a novel method for producing hydrogel microspheres, termed core-shell spherification (CSS). This method was strategically designed for use with hydrogels with much slower gelation rates compared to alginate, enabling the production of microspheres with a variety of chemical, physical, and bioactive properties.…”

Section: Introductionmentioning

confidence: 99%

A Versatile Microencapsulation Platform for Hyaluronic Acid and Polyethylene Glycol

Harrington

Ott²,

Karanu³

et al. 2021

Tissue Engineering Part A

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Cell microencapsulation is a rapidly expanding field with broad potential for stem cell therapies and tissue engineering research. Traditional alginate microspheres suffer from poor biocompatibility, and microencapsulation of more advanced hydrogels is challenging due to their slower gelation rates. We have developed a novel, noncytotoxic, nonemulsion-based method to produce hydrogel microspheres compatible with a wide variety of materials, called core-shell spherification (CSS). Fabrication of microspheres by CSS derived from two slow-hardening hydrogels, hyaluronic acid (HA) and polyethylene glycol diacrylate (PEGDA), was characterized. HA microspheres were manufactured with two different crosslinking methods: thiolation and methacrylation. Microspheres of methacrylated HA (MeHA) had the greatest swelling ratio, the largest average diameter, and the lowest diffusion barrier. In contrast, PEGDA microspheres had the smallest diameters, the lowest swelling ratio, and the highest diffusion barrier, while microspheres of thiolated HA had characteristics that were in between the other two groups. To test the ability of the hydrogels to protect cells, while promoting function, diabetic NOD mice received intraperitoneal injections of PEGDA or MeHA microencapsulated canine islets. PEGDA microspheres reversed diabetes for the length of the study (up to 16 weeks). In contrast, islets encapsulated in MeHA microspheres at the same dose restored normoglycemia, but only transiently (3-4 weeks). Nonencapsulated canine islet transplanted at the same dose did not restore normoglycemia for any length of time. In conclusion, CSS provides a nontoxic microencapsulation procedure compatible with various hydrogel types.

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“…As demonstrated, the cell sheet was capable of wrapping other cells, and thus the cellular Furoshiki should provide an alternative approach for constructing complex, higher-order cellular microstructures. Although the main focus of this study is to investigate the potential of a confluent cell monolayer in a self-wrapping co-culture technique, we envisioned a possible application of the cellular Furoshiki either in the development of in vitro disease model for the drug screening application 3,72,73 and or the tissue engineering for the prevention of the rejection of immunosuppression in transplantation [74][75][76] .…”

Section: Discussionmentioning

confidence: 99%

Construction of higher-order cellular microstructures by a self-wrapping co-culture strategy using a redox-responsive hydrogel

Ramadhan

Kagawa

Moriyama

et al. 2020

Sci Rep

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In this report, a strategy for constructing three-dimensional (3D) cellular architectures comprising viable cells is presented. the strategy uses a redox-responsive hydrogel that degrades under mild reductive conditions, and a confluent monolayer of cells (i.e., cell sheet) cultured on the hydrogel surface peels off and self-folds to wrap other cells. As a proof-of-concept, the self-folding of fibroblast cell sheet was triggered by immersion in aqueous cysteine, and this folding process was controlled by the cysteine concentration. Such folding enabled the wrapping of human hepatocellular carcinoma (HepG2) spheroids, human umbilical vein endothelial cells and collagen beads, and this process improved cell viability, the secretion of metabolites and the proliferation rate of the HepG2 cells when compared with a two-dimensional culture under the same conditions. A key concept of this study is the ability to interact with other neighbouring cells, providing a new, simple and fast method to generate higherorder cellular aggregates wherein different types of cellular components are added. We designated the method of using a cell sheet to wrap another cellular aggregate the 'cellular furoshiki'. the simple selfwrapping furoshiki technique provides an alternative approach to co-culture cells by microplate-based systems, especially for constructing heterogeneous 3D cellular microstructures.

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Hydrogel Biomaterials for Stem Cell Microencapsulation

Cited by 107 publications

References 94 publications

Microcarriers for Upscaling Cultured Meat Production

Microcarriers for Upscaling Cultured Meat Production

A Versatile Microencapsulation Platform for Hyaluronic Acid and Polyethylene Glycol

Construction of higher-order cellular microstructures by a self-wrapping co-culture strategy using a redox-responsive hydrogel

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