Electrospinning of Manmade and Biopolymer Nanofibers-Progress in Techniques, Materials, and Applications

被引:204
作者
Agarwal, Seema [1 ]
Greiner, Andreas
Wendorff, Joachin H.
机构
[1] Univ Marburg, Dept Chem, D-35032 Marburg, Germany
关键词
ELECTRICALLY FORCED JETS; POLYMER NANOFIBERS; COMPOSITE NANOFIBERS; BENDING INSTABILITY; HOLLOW NANOFIBERS; FIBERS; SUBMICROMETER; METAL; TUBES; MELTS;
D O I
10.1002/adfm.200900591
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
Electrospinning of nanofibers has developed quickly from a laboratory curiosity to a highly versatile method for the preparation of a wide variety of nanofibers, which are of interest from a fundamental as well as a technical point of view. A wide variety of materials has been processed into individual nanofibers or nanofiber mats with very different morphologies. The diverse properties of these nanofibers, based on different physical, chemical, or biological behavior, mean they are of interest for different applications ranging from filtration, antibacterial coatings, drug release formulations, tissue engineering, living membranes, sensors, and so on. A particular advantage of electrospinning is that numerous non-fiber forming materials can be immobilized by electrospinning in nanofiber nonwovens, even very sensitive biological objects such as virus, bacteria, and cells. The progress made during the last few years in the field of electrospinning is fascinating and is highlighted in this Feature Article, with particular emphasis on results obtained in the authors' research units. Specific areas of importance for the future of electrospinning, and which may open up novel applications, are also highlighted.
引用
收藏
页码:2863 / 2879
页数:17
相关论文
共 96 条
[31]   Electrospinning and electrically forced jets. I. Stability theory [J].
Hohman, MM ;
Shin, M ;
Rutledge, G ;
Brenner, MP .
PHYSICS OF FLUIDS, 2001, 13 (08) :2201-2220
[32]   Electrospinning and electrically forced jets. II. Applications [J].
Hohman, MM ;
Shin, M ;
Rutledge, G ;
Brenner, MP .
PHYSICS OF FLUIDS, 2001, 13 (08) :2221-2236
[33]   Structurally and chemically heterogeneous nanofibrous nonwovens via electrospinning [J].
Holzmelster, Andreas ;
Rudisile, Markus ;
Greiner, Andreas ;
Wendorff, Joachim H. .
EUROPEAN POLYMER JOURNAL, 2007, 43 (12) :4859-4867
[34]   Poly(p-xylylene) nanotubes by coating and removal of ultrathin polymer template fibers [J].
Hou, HQ ;
Jun, Z ;
Reuning, A ;
Schaper, A ;
Wendorff, JH ;
Greiner, A .
MACROMOLECULES, 2002, 35 (07) :2429-2431
[35]   A review on polymer nanofibers by electrospinning and their applications in nanocomposites [J].
Huang, ZM ;
Zhang, YZ ;
Kotaki, M ;
Ramakrishna, S .
COMPOSITES SCIENCE AND TECHNOLOGY, 2003, 63 (15) :2223-2253
[36]   A facile technique to prepare biodegradable coaxial electrospun nanofibers for controlled release of bioactive agents [J].
Jiang, HL ;
Hu, YQ ;
Li, Y ;
Zhao, PC ;
Zhu, KJ ;
Chen, WL .
JOURNAL OF CONTROLLED RELEASE, 2005, 108 (2-3) :237-243
[37]   A scanning tip electrospinning source for deposition of oriented nanofibres [J].
Kameoka, J ;
Orth, R ;
Yang, YN ;
Czaplewski, D ;
Mathers, R ;
Coates, GW ;
Craighead, HG .
NANOTECHNOLOGY, 2003, 14 (10) :1124-1129
[38]  
KIM HJ, 2004, J KOREAN FIBER SOC, V41, P424
[39]   Thermal properties of electrospun polyesters [J].
Kim, JS ;
Lee, DS .
POLYMER JOURNAL, 2000, 32 (07) :616-618
[40]   Tissue engineering, stem cells, and cloning: Opportunities for regenerative medicine [J].
Koh, CJ ;
Atala, A .
JOURNAL OF THE AMERICAN SOCIETY OF NEPHROLOGY, 2004, 15 (05) :1113-1125