Niancao Chen scite author profile

The ability to regulate cell-material interactions is important in various applications such as regenerative medicine and cell separation. This study successfully demonstrates that the binding states of cells on a hydrogel surface can be programmed by using hybridized aptamers and triggering complementary sequences (CSs). In the absence of the triggering CSs, the aptamers exhibit a stable, hybridized state in the hydrogel for cell-type-specific catch. In the presence of the triggering CSs, the aptamers are transformed into a new hybridized state that leads to the rapid dissociation of the aptamers from the hydrogel. As a result, the cells are released from the hydrogel. The entire procedure of cell catch and release during the transformation of the aptamers is biocompatible and does not involve any factor destructive to either the cells or the hydrogel. Thus, the programmable hydrogel is regenerable and can be applied to a new round of cell catch and release when needed.

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Aptamer-functionalized superporous hydrogels for sequestration and release of growth factors regulated via molecular recognition

Battig

Huang

Chen

et al. 2014

Biomaterials

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Cell adhesion on an artificial extracellular matrix using aptamer-functionalized PEG hydrogels

et al. 2012

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Endonuclease-responsive aptamer-functionalized hydrogel coating for sequential catch and release of cancer cells

Chen

Zhang

et al. 2013

Biomaterials

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Chimeric Aptamer–Gelatin Hydrogels as an Extracellular Matrix Mimic for Loading Cells and Growth Factors

et al. 2016

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It is important to synthesize materials to recapitulate critical functions of biological systems for a variety of applications such as tissue engineering and regenerative medicine. The purpose of this study was to synthesize a chimeric hydrogel as a promising extracellular matrix (ECM) mimic using gelatin, a nucleic acid aptamer and polyethylene glycol (PEG). This hydrogel had a macroporous structure that was highly permeable for fast molecular transport. Despite its high permeability, it could strongly sequester and sustainably release growth factors with high bioactivity. Notably, growth factors retained in the hydrogel could maintain ~50% bioactivity during a 14-day release test. It also provided cells with effective binding sites, which led to high efficiency of cell loading into the macroporous hydrogel matrix. When cells and growth factors were co-loaded into the chimeric hydrogel, living cells could still be observed by day 14 in a static serum-reduced culture condition. Thus, this chimeric aptamer-gelatin hydrogel constitutes a promising biomolecular ECM mimic for loading cells and growth factors.

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Niancao Chen

Programmable Hydrogels for Controlled Cell Catch and Release Using Hybridized Aptamers and Complementary Sequences

Aptamer-functionalized superporous hydrogels for sequestration and release of growth factors regulated via molecular recognition

Cell adhesion on an artificial extracellular matrix using aptamer-functionalized PEG hydrogels

Endonuclease-responsive aptamer-functionalized hydrogel coating for sequential catch and release of cancer cells

Chimeric Aptamer–Gelatin Hydrogels as an Extracellular Matrix Mimic for Loading Cells and Growth Factors

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