bFGF and Poly-RGD Cooperatively Establish Biointerface for Stem Cell Adhesion, Proliferation, and Differentiation

Nan Jiang; Yong Wang; Yi-Xia Yin; Rui-Peng Wei; Guo-Liang Ying; Bin-Bin Li; Tong Qiu; Patrick van Rijn; Ge Tian; Qiong-Jiao Yan; Hong-Lian Dai; Henk J. Busscher; Shi-Pu Li; Ali K. Yetisen; Xiao-Yu Yang

doi:10.1002/admi.201700702

bFGF and Poly-RGD Cooperatively Establish Biointerface for Stem Cell Adhesion, Proliferation, and Differentiation

Nan Jiang, Yong Wang, Yi-Xia Yin^*, Rui-Peng Wei, Guo-Liang Ying, Bin-Bin Li, Tong Qiu, Patrick van Rijn, Ge Tian, Qiong-Jiao Yan, Hong-Lian Dai, Henk J. Busscher, Shi-Pu Li, Ali K. Yetisen, Xiao-Yu Yang

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Biointerface design is widely used to functionalize biomaterials with controllable physicochemical properties. Functionalized biointerface provides a versatile platform to connect biological entities and nonbiogenic materials. Existing nanofabrication approaches to create such a nanostructured biointerface involve in low stability of the functionalized nanolayer and simple functionalities that limit its applicability. Here, a stable nanolayered synthetic polypeptide (poly[LA-co-(Glc-alt-Lys)] and modified with arginine-glycine-aspartic acid, PRGD)/basic fibroblast growth factor (bFGF) biointerface is created via structural matching, charge interaction, and hydrogen bonding. The cooperative effect of the PRGD/bFGF biointerface shows multiple functionalities in promoting stem cell adhesion by 33% increase in cell adhesion to poly(d,l-lactic acid) substrate as compared to experiments on bare substrate as a control. Moreover, the biointerface enhances proliferation by 40% in cell density, potential differentiation by 62%, and gene expression by 40 and 80% respectively as compared to the control samples. The fabricated biointerface may have applications in nerve regeneration, tissue repair, and stem cell-based therapy.

Original language	English
Article number	1700702
Number of pages	8
Journal	Advanced Materials Interfaces
Volume	5
Issue number	7
DOIs	https://doi.org/10.1002/admi.201700702
Publication status	Published - 9-Apr-2018

Keywords

biointerface
cell proliferation
cooperative effect
growth factors
stem cell differentiation
FIBROBLAST-GROWTH-FACTOR
TISSUE ENGINEERING APPLICATIONS
NANO-BIO INTERFACE
BONE-MARROW
ALGINATE HYDROGELS
STROMAL CELLS
IN-VIVO
SURFACES
BIOMATERIALS
REGENERATION

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Jiang, N., Wang, Y., Yin, Y.-X., Wei, R.-P., Ying, G.-L., Li, B.-B., Qiu, T., van Rijn, P., Tian, G., Yan, Q.-J., Dai, H.-L., Busscher, H. J., Li, S.-P., Yetisen, A. K., & Yang, X.-Y. (2018). bFGF and Poly-RGD Cooperatively Establish Biointerface for Stem Cell Adhesion, Proliferation, and Differentiation. Advanced Materials Interfaces, 5(7), Article 1700702. https://doi.org/10.1002/admi.201700702

@article{9d15666d2d67494ab5365247ad6da806,

title = "bFGF and Poly-RGD Cooperatively Establish Biointerface for Stem Cell Adhesion, Proliferation, and Differentiation",

abstract = "Biointerface design is widely used to functionalize biomaterials with controllable physicochemical properties. Functionalized biointerface provides a versatile platform to connect biological entities and nonbiogenic materials. Existing nanofabrication approaches to create such a nanostructured biointerface involve in low stability of the functionalized nanolayer and simple functionalities that limit its applicability. Here, a stable nanolayered synthetic polypeptide (poly[LA-co-(Glc-alt-Lys)] and modified with arginine-glycine-aspartic acid, PRGD)/basic fibroblast growth factor (bFGF) biointerface is created via structural matching, charge interaction, and hydrogen bonding. The cooperative effect of the PRGD/bFGF biointerface shows multiple functionalities in promoting stem cell adhesion by 33% increase in cell adhesion to poly(d,l-lactic acid) substrate as compared to experiments on bare substrate as a control. Moreover, the biointerface enhances proliferation by 40% in cell density, potential differentiation by 62%, and gene expression by 40 and 80% respectively as compared to the control samples. The fabricated biointerface may have applications in nerve regeneration, tissue repair, and stem cell-based therapy.",

keywords = "biointerface, cell proliferation, cooperative effect, growth factors, stem cell differentiation, FIBROBLAST-GROWTH-FACTOR, TISSUE ENGINEERING APPLICATIONS, NANO-BIO INTERFACE, BONE-MARROW, ALGINATE HYDROGELS, STROMAL CELLS, IN-VIVO, SURFACES, BIOMATERIALS, REGENERATION",

author = "Nan Jiang and Yong Wang and Yi-Xia Yin and Rui-Peng Wei and Guo-Liang Ying and Bin-Bin Li and Tong Qiu and {van Rijn}, Patrick and Ge Tian and Qiong-Jiao Yan and Hong-Lian Dai and Busscher, {Henk J.} and Shi-Pu Li and Yetisen, {Ali K.} and Xiao-Yu Yang",

year = "2018",

month = apr,

day = "9",

doi = "10.1002/admi.201700702",

language = "English",

volume = "5",

journal = "Advanced Materials Interfaces",

issn = "2196-7350",

publisher = "Wiley",

number = "7",

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Jiang, N, Wang, Y, Yin, Y-X, Wei, R-P, Ying, G-L, Li, B-B, Qiu, T, van Rijn, P, Tian, G, Yan, Q-J, Dai, H-L, Busscher, HJ, Li, S-P, Yetisen, AK & Yang, X-Y 2018, 'bFGF and Poly-RGD Cooperatively Establish Biointerface for Stem Cell Adhesion, Proliferation, and Differentiation', Advanced Materials Interfaces, vol. 5, no. 7, 1700702. https://doi.org/10.1002/admi.201700702

TY - JOUR

T1 - bFGF and Poly-RGD Cooperatively Establish Biointerface for Stem Cell Adhesion, Proliferation, and Differentiation

AU - Jiang, Nan

AU - Wang, Yong

AU - Yin, Yi-Xia

AU - Wei, Rui-Peng

AU - Ying, Guo-Liang

AU - Li, Bin-Bin

AU - Qiu, Tong

AU - van Rijn, Patrick

AU - Tian, Ge

AU - Yan, Qiong-Jiao

AU - Dai, Hong-Lian

AU - Busscher, Henk J.

AU - Li, Shi-Pu

AU - Yetisen, Ali K.

AU - Yang, Xiao-Yu

PY - 2018/4/9

Y1 - 2018/4/9

N2 - Biointerface design is widely used to functionalize biomaterials with controllable physicochemical properties. Functionalized biointerface provides a versatile platform to connect biological entities and nonbiogenic materials. Existing nanofabrication approaches to create such a nanostructured biointerface involve in low stability of the functionalized nanolayer and simple functionalities that limit its applicability. Here, a stable nanolayered synthetic polypeptide (poly[LA-co-(Glc-alt-Lys)] and modified with arginine-glycine-aspartic acid, PRGD)/basic fibroblast growth factor (bFGF) biointerface is created via structural matching, charge interaction, and hydrogen bonding. The cooperative effect of the PRGD/bFGF biointerface shows multiple functionalities in promoting stem cell adhesion by 33% increase in cell adhesion to poly(d,l-lactic acid) substrate as compared to experiments on bare substrate as a control. Moreover, the biointerface enhances proliferation by 40% in cell density, potential differentiation by 62%, and gene expression by 40 and 80% respectively as compared to the control samples. The fabricated biointerface may have applications in nerve regeneration, tissue repair, and stem cell-based therapy.

AB - Biointerface design is widely used to functionalize biomaterials with controllable physicochemical properties. Functionalized biointerface provides a versatile platform to connect biological entities and nonbiogenic materials. Existing nanofabrication approaches to create such a nanostructured biointerface involve in low stability of the functionalized nanolayer and simple functionalities that limit its applicability. Here, a stable nanolayered synthetic polypeptide (poly[LA-co-(Glc-alt-Lys)] and modified with arginine-glycine-aspartic acid, PRGD)/basic fibroblast growth factor (bFGF) biointerface is created via structural matching, charge interaction, and hydrogen bonding. The cooperative effect of the PRGD/bFGF biointerface shows multiple functionalities in promoting stem cell adhesion by 33% increase in cell adhesion to poly(d,l-lactic acid) substrate as compared to experiments on bare substrate as a control. Moreover, the biointerface enhances proliferation by 40% in cell density, potential differentiation by 62%, and gene expression by 40 and 80% respectively as compared to the control samples. The fabricated biointerface may have applications in nerve regeneration, tissue repair, and stem cell-based therapy.

KW - biointerface

KW - cell proliferation

KW - cooperative effect

KW - growth factors

KW - stem cell differentiation

KW - FIBROBLAST-GROWTH-FACTOR

KW - TISSUE ENGINEERING APPLICATIONS

KW - NANO-BIO INTERFACE

KW - BONE-MARROW

KW - ALGINATE HYDROGELS

KW - STROMAL CELLS

KW - IN-VIVO

KW - SURFACES

KW - BIOMATERIALS

KW - REGENERATION

U2 - 10.1002/admi.201700702

DO - 10.1002/admi.201700702

M3 - Article

SN - 2196-7350

VL - 5

JO - Advanced Materials Interfaces

JF - Advanced Materials Interfaces

IS - 7

M1 - 1700702

ER -

bFGF and Poly-RGD Cooperatively Establish Biointerface for Stem Cell Adhesion, Proliferation, and Differentiation

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Keywords

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