Literature DB >> 21710996

Enhancing the stiffness of electrospun nanofiber scaffolds with a controlled surface coating and mineralization.

Wenying Liu1, Yi-Chun Yeh, Justin Lipner, Jingwei Xie, Hsing-Wen Sung, Stavros Thomopoulos, Younan Xia.   

Abstract

A new method was developed to coat hydroxyapatite (HAp) onto electrospun poly(lactic-co-glycolic acid) (PLGA) nanofibers for tendon-to-bone insertion site repair applications. Prior to mineralization, chitosan and heparin were covalently immobilized onto the surface of the fibers to accelerate the nucleation of bone-like HAp crystals. Uniform coatings of HAp were obtained by immersing the nanofiber scaffolds into a modified, 10-fold-concentrated simulated body fluid (m10SBF) for different periods of time. The new method resulted in thicker and denser coatings of mineral on the fibers compared to those produced by previously reported methods. Scanning electron microscopy measurements confirmed the formation of nanoscale HAp particles on the fibers. A mechanical property assessment demonstrated a higher stiffness with respect to previous coating methods. A combination of the nanoscale fibrous structure and bonelike mineral coating could mimic the structure, composition, and function of mineralized tissues.

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Year:  2011        PMID: 21710996      PMCID: PMC3144316          DOI: 10.1021/la2018105

Source DB:  PubMed          Journal:  Langmuir        ISSN: 0743-7463            Impact factor:   3.882


  13 in total

1.  Variation of biomechanical, structural, and compositional properties along the tendon to bone insertion site.

Authors:  Stavros Thomopoulos; Gerald R Williams; Jonathan A Gimbel; Michele Favata; Louis J Soslowsky
Journal:  J Orthop Res       Date:  2003-05       Impact factor: 3.494

2.  Material science. Spinning continuous fibers for nanotechnology.

Authors:  Yuris Dzenis
Journal:  Science       Date:  2004-06-25       Impact factor: 47.728

3.  The outcome and repair integrity of completely arthroscopically repaired large and massive rotator cuff tears.

Authors:  Leesa M Galatz; Craig M Ball; Sharlene A Teefey; William D Middleton; Ken Yamaguchi
Journal:  J Bone Joint Surg Am       Date:  2004-02       Impact factor: 5.284

4.  Biomineralization: A crystal-clear view.

Authors:  Helmut Cölfen
Journal:  Nat Mater       Date:  2010-12       Impact factor: 43.841

5.  Collecting electrospun nanofibers with patterned electrodes.

Authors:  Dan Li; Gong Ouyang; Jesse T McCann; Younan Xia
Journal:  Nano Lett       Date:  2005-05       Impact factor: 11.189

Review 6.  Biomimetic electrospun nanofibers for tissue regeneration.

Authors:  Susan Liao; Bojun Li; Zuwei Ma; He Wei; Casey Chan; Seeram Ramakrishna
Journal:  Biomed Mater       Date:  2006-07-28       Impact factor: 3.715

7.  Covalent immobilization of chitosan and heparin on PLGA surface.

Authors:  X H Wang; D P Li; W J Wang; Q L Feng; F Z Cui; Y X Xu; X H Song
Journal:  Int J Biol Macromol       Date:  2003-11       Impact factor: 6.953

8.  Putting Electrospun Nanofibers to Work for Biomedical Research.

Authors:  Jingwei Xie; Xiaoran Li; Younan Xia
Journal:  Macromol Rapid Commun       Date:  2008-11-19       Impact factor: 5.734

9.  The heparin-Ca(2+) interaction: the influence of the O-sulfation pattern on binding.

Authors:  Franck Chevalier; Ricardo Lucas; Jesús Angulo; Manuel Martin-Lomas; Pedro M Nieto
Journal:  Carbohydr Res       Date:  2004-04-02       Impact factor: 2.104

10.  The effect of surface charge on hydroxyapatite nucleation.

Authors:  Peixin Zhu; Yoshitake Masuda; Kunihito Koumoto
Journal:  Biomaterials       Date:  2004-08       Impact factor: 12.479
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  20 in total

1.  Electrospinning and Electrospun Nanofibers: Methods, Materials, and Applications.

Authors:  Jiajia Xue; Tong Wu; Yunqian Dai; Younan Xia
Journal:  Chem Rev       Date:  2019-03-27       Impact factor: 60.622

2.  Bioinspired Scaffold Designs for Regenerating Musculoskeletal Tissue Interfaces.

Authors:  Mohammed A Barajaa; Lakshmi S Nair; Cato T Laurencin
Journal:  Regen Eng Transl Med       Date:  2019-12-17

3.  Toughening of fibrous scaffolds by mobile mineral deposits.

Authors:  Justin Lipner; John J Boyle; Younan Xia; Victor Birman; Guy M Genin; Stavros Thomopoulos
Journal:  Acta Biomater       Date:  2017-05-19       Impact factor: 8.947

4.  Regulation of astrocyte activity via control over stiffness of cellulose acetate electrospun nanofiber.

Authors:  Seul Ki Min; Sang Myung Jung; Jung Hyeon Ju; Yeo Seon Kwon; Gwang Heum Yoon; Hwa Sung Shin
Journal:  In Vitro Cell Dev Biol Anim       Date:  2015-06-20       Impact factor: 2.416

Review 5.  Engineering complex orthopaedic tissues via strategic biomimicry.

Authors:  Dovina Qu; Christopher Z Mosher; Margaret K Boushell; Helen H Lu
Journal:  Ann Biomed Eng       Date:  2014-12-03       Impact factor: 3.934

Review 6.  Rational design of nanofiber scaffolds for orthopedic tissue repair and regeneration.

Authors:  Bing Ma; Jingwei Xie; Jiang Jiang; Franklin D Shuler; David E Bartlett
Journal:  Nanomedicine (Lond)       Date:  2013-09       Impact factor: 5.307

7.  Strong and tough mineralized PLGA nanofibers for tendon-to-bone scaffolds.

Authors:  Pavan V Kolluru; Justin Lipner; Wenying Liu; Younan Xia; Stavros Thomopoulos; Guy M Genin; Ioannis Chasiotis
Journal:  Acta Biomater       Date:  2013-08-06       Impact factor: 8.947

8.  The mechanics of PLGA nanofiber scaffolds with biomimetic gradients in mineral for tendon-to-bone repair.

Authors:  J Lipner; W Liu; Y Liu; J Boyle; G M Genin; Y Xia; S Thomopoulos
Journal:  J Mech Behav Biomed Mater       Date:  2014-08-17

Review 9.  Electrospun nanofibers for regenerative medicine.

Authors:  Wenying Liu; Stavros Thomopoulos; Younan Xia
Journal:  Adv Healthc Mater       Date:  2011-12-16       Impact factor: 9.933

10.  One-step method for the preparation of poly(methyl methacrylate) modified titanium-bioactive glass three-dimensional scaffolds for bone tissue engineering.

Authors:  Xiao Han; Huiming Lin; Xiang Chen; Xin Li; Gang Guo; Fengyu Qu
Journal:  IET Nanobiotechnol       Date:  2016-04       Impact factor: 1.847
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