A Supramolecular Hydrogel Inspired by Elastin

Self-assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study on a supramolecular hydrogel beating the elastin repeating peptide of VPGAG. The visco-elasticity property, morphology of the nanostructures,...

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Published inChinese journal of chemistry Vol. 29; no. 10; pp. 2182 - 2186
Main Author 丁磊 王淑芳 武文洁 胡月晗 杨翠红 谭鸣 孔德领 杨志谋
Format Journal Article
LanguageEnglish
Published Weinheim WILEY-VCH Verlag 01.10.2011
WILEY‐VCH Verlag
Wiley
Wiley Subscription Services, Inc
Subjects
Chemistry
Chemistry, Multidisciplinary
hydrogel
Hydrogels
peptide
Physical Sciences
Science & Technology
self-assembly
supramolecular
弹力
弹性蛋白
水凝胶
生物功能材料
纳米结构
荧光显微镜
超分子
透射电子显微镜
DRUG
self-assembly
CELLS
supramolecular
peptide
ENZYME
NANOFIBERS
hydrogel
PH
RELEASE
SCAFFOLDS
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Abstract Self-assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study on a supramolecular hydrogel beating the elastin repeating peptide of VPGAG. The visco-elasticity property, morphology of the nanostructures, and aromatic stacking in the self-assembled nanostructure were characterized by a rheometry, transmission electron microscope (TEM), and fluorescence microscope, respectively. The biocompatibility of the gelator was also proved by an MTT assay. Though the supramolecular hydrogel failed to exhibit a high elasticity like elastin, the thixotropic hydrogel might have potentials for the applications in fields of cell culture, controlled-drug release, etc.
AbstractList Self-assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study on a supramolecular hydrogel beating the elastin repeating peptide of VPGAG. The visco-elasticity property, morphology of the nanostructures, and aromatic stacking in the self-assembled nanostructure were characterized by a rheometry, transmission electron microscope (TEM), and fluorescence microscope, respectively. The biocompatibility of the gelator was also proved by an MTT assay. Though the supramolecular hydrogel failed to exhibit a high elasticity like elastin, the thixotropic hydrogel might have potentials for the applications in fields of cell culture, controlled-drug release, etc.
Self-assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study on a supramolecular hydrogel bearing the elastin repeating peptide of VPGAG. The visco-elasticity property, morphology of the nanostructures, and aromatic stacking in the self-assembled nanostructure were characterized by a rheometry, transmission electron microscope (TEM), and fluorescence microscope, respectively. The biocompatibility of the gelator was also proved by an MTT assay. Though the supramolecular hydrogel failed to exhibit a high elasticity like elastin, the thixotropic hydrogel might have potentials for the applications in fields of cell culture, controlled-drug release, etc.
Self‐assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study on a supramolecular hydrogel bearing the elastin repeating peptide of VPGAG. The visco‐elasticity property, morphology of the nanostructures, and aromatic stacking in the self‐assembled nanostructure were characterized by a rheometry, transmission electron microscope (TEM), and fluorescence microscope, respectively. The biocompatibility of the gelator was also proved by an MTT assay. Though the supramolecular hydrogel failed to exhibit a high elasticity like elastin, the thixotropic hydrogel might have potentials for the applications in fields of cell culture, controlled‐drug release, etc. A thixotropic supramolecular hydrogel inspired by elastin was reported in this study.
Self‐assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study on a supramolecular hydrogel bearing the elastin repeating peptide of VPGAG. The visco‐elasticity property, morphology of the nanostructures, and aromatic stacking in the self‐assembled nanostructure were characterized by a rheometry, transmission electron microscope (TEM), and fluorescence microscope, respectively. The biocompatibility of the gelator was also proved by an MTT assay. Though the supramolecular hydrogel failed to exhibit a high elasticity like elastin, the thixotropic hydrogel might have potentials for the applications in fields of cell culture, controlled‐drug release, etc .
Author Wang, Shufang
Hu, Yuehan
Yang, Zhimou
Wu, Wenjie
Yang, Cuihong
Tan, Ming
Kong, Deling
Ding, Lei
AuthorAffiliation Tianjin University of Science & Technology, Tianjin 300457, China Key Laboratory of Bioactive Materials, Ministry of Education, College of Life Sciences, Nankai University, Tianjin 300071, China
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Issue 10
Keywords DRUG
self-assembly
CELLS
supramolecular
peptide
ENZYME
NANOFIBERS
hydrogel
PH
RELEASE
SCAFFOLDS
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Ding, Lei Wang, Shufang Wu, Wenjie Hu, Yuehan Yang, Cuihong Tan, Ming Kong, Dehing Yang, Zhimou( 1. Tianjin University of Science & Technology, Tianjin 300457, China;2. Key Laboratory of Bioactive Materials, Ministry of Education, College of Life Sciences, Nankai University, Tianjin 300071, China)
Self-assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study on a supramolecular hydrogel beating the elastin repeating peptide of VPGAG. The visco-elasticity property, morphology of the nanostructures, and aromatic stacking in the self-assembled nanostructure were characterized by a rheometry, transmission electron microscope (TEM), and fluorescence microscope, respectively. The biocompatibility of the gelator was also proved by an MTT assay. Though the supramolecular hydrogel failed to exhibit a high elasticity like elastin, the thixotropic hydrogel might have potentials for the applications in fields of cell culture, controlled-drug release, etc.
self-assembly, hydrogel, supramolecular, peptide
the National Natural Science Foundation of China - No. 31070856
the Tianjin Technology Support Project - No. 07ZCKFSH03600
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Snippet Self-assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study...
Self‐assembly prevails in nature and learning from nature will lead to biofunctional materials. Inspired by the protein of elastin, we reported in this study...
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SubjectTerms Chemistry
Chemistry, Multidisciplinary
hydrogel
Hydrogels
peptide
Physical Sciences
Science & Technology
self-assembly
supramolecular
弹力
弹性蛋白
水凝胶
生物功能材料
纳米结构
荧光显微镜
超分子
透射电子显微镜
Title A Supramolecular Hydrogel Inspired by Elastin
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https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fcjoc.201180378
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Volume 29
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