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[资源] 国内外知名生物材料研究组介绍【重金收集中】

请各位虫友将自己熟悉的生物材料届的研究组介绍给大家，无论是国内还是国际的都可以。
由于生物材料是一个涉及到多领域的交叉学科，可能有一些研究组不是那么闻名遐迩，但是在某一领域是具有自己的研究特色和相当出色的成果。有些很著名的大研究组从事的领域十分的广泛，其中有与生物材料相关的研究成果也很出色，可以将与生物材料相关的内容提取出来，单独介绍。
下面列出格式并举例供大家参考，海外的组请用英文，国内的组可以使用中文，但最好还是使用英文。
请跟贴的虫友最好付出一定的劳动，按格式将内容整理好。欢迎提供宝贵意见。

本帖的目的是希望为报考研究生，出国留学，寻求博后位置和求职就业的虫友提供参考。

【奖金】
提供信息1~3金币；
收集整理3个金币；
按格式整理5个金币；
完全按要求整理7个金币。

【格式】
Group Name: (研究组名称，若无，可用group leader名字命名)
Group Leader:
Affiliation:
Research Interest:
Research Highlight:
Representative Publication: (不多于5篇，包括专利)
Webpage:

【名录】请跟帖前务必对照无重复！
Aldo Boccaccini，Imperial College，第116楼
Angela Belcher，Massachusetts Institute of Technology，第100楼
Arto Urtti，University of Helsinki，第97楼
Buddy Ratner，University of Washington，第99楼
Chad Mirkin，Northwestern University，第25楼
Charles M. Lieber，Harvard University，第1楼
Christine E. Schmidt，The University of Texas at Austin，第1楼
David Kaplan，Tufts University，第103楼
Enrique Fernandez，Technical University of Catalonia，第37楼
Frank Witte，Hannover Medical School，第18楼
Henry J. Rack，Clemson University，第53楼
Hongjie Dai (戴宏杰)，Stanford University，第24楼
Huajian Gao (高华健)，Brown University，第16楼
Igor Zhitomirsky，McMaster University，第101楼
Joelle AMEDEE，Université Victor Segalen Bordeaux 2，第110楼
John Jansen，Radboud University Nijmegen，第43楼
Josep A. Planell，Universitat Politècnica de Catalunya，第38楼
K de Groot，Free University，第112楼
Kokubo Tadashi，Chubu University，第36楼
Jan Feijen，University of Twente，第49楼
Larry L. Hench，Imperial College，第111楼
Laurent Sedel，Hôpital Lariboisière，第39楼
Lemaitre Jacques，Swiss Federal Institute of Technology Lausanne，第35楼
Ma Jan，Nanyang Technological University，第27楼
Min Wang(王敏)，The University of Hong Kong，第113楼
Mitsuo Niinomi，Tohoku University，第55楼
Molly Stevens，Imperial College，第117楼
Nadrian C. Seeman，New York University，第50楼
Paul K. Chu (朱剑豪)，City University of Hong Kong，第1楼
Racquel Z . LeGeros，New York University，第107楼
Robert Langer，Massachusetts Institute of Technology，第46楼
Robin Wootton，University of Exeter，第17楼
Samuel I. Stupp，Northwestern University，第98楼
Shuming Nie (聂书明)，Emory University，第22楼
Song Li，University of California, Berkeley，第126楼
Subbu S. Venkatraman，Nanyang Technological University，第26楼
Xiaohu Gao (高�?虎)，University of Washington，第23楼
Xuejun Wen (文学军)，Clemson University，第124楼
Yang LENG，Hong Kong University of Science & Technology ，第106楼
常江，中科院上海硅酸盐研究所，第62楼
陈国强，清华大学、汕头大学，第54楼
陈晓农，北京化工大学，第65楼
成国祥，天津大学，第56楼
崔春翔，河北工业大学，第105楼
崔福斋，清华大学，第74楼
丁传贤，中科院上海硅酸盐研究所，第60楼
高长有，浙江大学，第67楼
顾忠伟，四川大学，第1楼
郝玉琳，中科院金属研究所，第68楼
黄楠，西南交通大学，第40楼
计剑，浙江大学，第77楼
李世普，武汉理工大学，第52楼
孔德领，南开大学，第69楼
李玉宝，四川大学，第44楼
刘昌胜，华东理工大学，第34楼
刘宣勇，中科院上海硅酸盐研究所，第61楼
刘万顺，中国海洋大学，第51楼
鲁雄，西南交通大学，第114楼
聂俊，北京化工大学，第76楼
庞代文，武汉大学，第14楼
申有青，浙江大学，第30楼
王均，中国科技大学，第109楼
王迎军，华南理工大学，第104楼
杨锐，中科院金属研究所，第68楼
俞耀庭，南开大学，第69楼
于振涛，西北有色金属研究院，第33楼
袁直，南开大学，第70楼
张立群，北京化工大学，第75楼
张兴栋，四川大学，第1楼
郑学斌，中科院上海硅酸盐研究所，第60楼
钟志远，苏州大学，第122楼
朱英杰，中科院上海硅酸盐研究所，第66楼

【征集名录】8金币！
William Bonfield，University of Cambridge，
曹阿民，中国科学院上海有机化学研究所，
邓正华，中国科学院成都有机化学分院，
杜福胜，北京大学，
甘志华，中国科学院化学研究所，
高家诚，重庆大学，
顾忠伟，四川大学，
关绍康，郑州大学，
黄世文，武汉大学，
江雷，中科院化学所，
蒋锡群，南京大学，
金岩，第四军医大学，
景遐斌，中国科学院长春应用化学研究所，
李晓光，首都医科大学，
李子臣，北京大学，
马建标，天津理工大学，
史林启，南开大学，
帅心涛，中山大学，
王均，中国科学技术大学，
王身国，中科院化学所，
翁杰，西南交通大学，
奚廷斐，中国药品生物制品检定所，
张二林，沈阳金属研究所，
张先正，武汉大学，
郑玉峰，北京大学，
钟振林，武汉大学，
钟志远，苏州大学，
卓仁喜，武汉大学，

举例1：

Group Name:
Plasma Laboratory

Group Leader:
Paul K. Chu

Affiliation:
City University of Hong Kong

Research Interest:
Using Plasma Immersion Ion Implantation - Deposition (PIII-D) technique to synthesize thin films and modify the surface properties of materials for biomedical applications.

Research Highlight:
Significant progress has been made to develop more biocompatible artificial heart, cardiovascular, and blood vessel stent materials and catheters. Crystalline silicon wafers can be made bioactive and conducive to the growth of apatite (bone) using hydrogen plasma implantation. This is a significant development enabling better integration of biosensors and bioMEMS with human tissues. Using patent pending plasma surface modification and thermal treatment technologies, the leaching of toxic Ni from NiTi is significantly mitigated while the shape memory and super-elastic properties can be tailored and retained. These inventions have led to another pending patent on a “gradual correction"surgical technique that obviates the need for multiple surgeries for patients with spinal deformities like scoliosis and major back injuries. Plasma-sprayed TiO2 coatings have been made bioactive for the first time using a special fabrication process involving plasma implantation, nanofabrication technology, and UV irradiation. This is a significant development as plasma-sprayed titanium dioxide coatings have always been regarded as bio-inert. The novel nano-structured TiO2 coatings support the growth of bones and the work has profound impact on artificial prostheses and orthopedic materials.

Representative Publication:
1) P. K. Chu and X. Y. Liu (Editors), Biomaterials Fabrication and Processing Handbook, CRC Press / Taylor and Francis, Boca Raton, USA (2008).
2) J. Jiang, K. F. Huo, Z. W. Wu, et al., Silicon Induced DNA Damage Pathway and Its Modulation by Titanium Plasma Immersion Ion Implantation, Biomaterials, Vol. 29, No. 5, Pages: 544-550 (2008).
3) Zhang W, Chu PK, Ji JH, et al., Plasma Surface Modification of Poly vinyl chloride for Improvement of Antibacterial Properties, Biomaterials, Vol. 27, No. 1 Pages: 44-51 (2006).
4) X. Y. Liu, P. K. Chu, and C. X. Ding, Surface Modification of Titanium, Titanium Alloys, and Related Materials for Biomedical Applications, Materials Science and Engineering: Reports, Vol. 47, No. 2-4, Pages: 49-121 (2004).
5) P. K. Chu, J. Y. Chen, L. P. Wang, et al., Plasma Surface Modification of Biomaterials, Materials Science & Engineering: Reports, Vol. 36, No. 5-6, Pages: 143-206 (2002).

Webpage
http://www.cityu.edu.hk/ap/plasma/default.htm

举例2：

Group Name:
The Schmidt Lab

Group Leader:
Christine E. Schmidt

Affiliation:
The University of Texas at Austin

Research Interest:
Semiconductor-Cell Interfaces; Biomimetic Synthetic Polymers; Natural-Based Biomaterials; Mechanisms of Cell Migration; Genetic Strategies for Tissue Repair

Research Highlight:
The group are working in collaboration with scientists with different backgrouds to better understand and repair tissues in the nervous and cardiovascular systems. Most of their current research is applied to the nervous system. They analysed various biomaterials (e.g., an electrically conducting polymer) that can be used to specifically stimulate, and guide, nerves to regrow their severed axons. They also studied the mechanisms of axon extension and nerve repair so that we can better design devices to help promote regeneration. Ultimately, nerve guidance channels (conduits) could be used to aid the repair of damaged peripheral nerves, such as would be required for facial and hand reconstruction, and ultimately, could be used to aid the regeneration of damaged spinal cord. In the cardiovascular system, they have used advanced cell culture approaches and a novel biomaterial scaffold (acellular vascular tissue) in an attempt to grow a living blood vessel. This vascular graft could ultimately be used for blood vessel reconstruction procedures (e.g., coronary artery bypass surgeries).

Representative Publication:
1) Guimard, N., N. Gomez, C.E. Schmidt (2007). Conducting Polymers in Biomedical Applications. Progress in Polymer Science. 32: 876-921.
2) Gomez, N., J.Y. Lee, J.D. Nickels, C.E. Schmidt (2007). Micropatterned Polypyrrole: Combination of Electrical and Topographical Characteristics for Stimulation of Cells. Advanced Functional Materials. 17: 1645-1653.
3) Sanghvi, A.B., K.P-H. Miller, A.M. Belcher, C.E. Schmidt (2005). Biomaterials functionalization using a novel peptide that selectively binds to an electrically conducting polymer. Nature Materials. 4: 496-502.
4) Winter, J.O., T.Y. Liu, B.A. Korgel, C.E. Schmidt (2001). Biomolecule-directed interfacing between semiconductor quantum dots and nerve cells. Advanced Materials.13: 1673-1677.
5) Schmidt, C.E., V.R. Shastri, J.P. Vacanti, and R. Langer (1997). Stimulation of neurite outgrowth using an electrically conducting polymer. Proceedings of the National Academy of Sciences. USA 94: 8948-8953.

Webpage:
http://www.bme.utexas.edu/faculty/schmidt/index.html

举例 3：

Group Name:
Lieber Research Group

Group Leader:
Charles M. Lieber

Affiliation:
Harvard University

Research Interest (Specified):
Bio-Nano Interface: Biological/Chemical Sensing includes Single particle detection, Large-scale addressable arrays, Detection of disease biomarkers and Small molecule detection. Nanodevice-Cell Hybrid Structures. Assembly & Interconnection.

Research Highlight:
They have pioneered the underlying science and application of nanoscale field-effect transistors for real-time label-free electrical detection of biological and chemical species in fluid solution. Nanowire devices represent nearly ideal sensor elements since their sizes are matched to that of biological macromolecules. Current interests are focused primarily on detection within the context of biological systems, although our projects range from ones pushing fundamental limits of detection to application of these devices to important biological problems such as detection of diseases and biowarfare agents. They have an active and growing program investigating this interface in several types of cells with a goal of creating systems that can process information using the unique attributes of both the biological and nanoelectronic components. They are also pursuing efforts that merge other complementary attributes of biology and nanotechnology. They are exploring the use of specific biomolecular interactions available in protein and protein/small molecule systems, to direct in a highly specific manner reversible and irreversible organization of nanostructures. Moreover, they are exploring biological systems as a means for 'building' new types of two-dimensional and three-dimensional interconnections between functional nanostructures and nanostructure arrays.

Representative Publication:
1) F. Patolsky, B.P. Timko, G. Zheng and C.M. Lieber, "Nanowire-Based Nanoelectronic Devices in the Life Sciences," MRS Bull. 32, 142-149 (2007).
2) F. Patolsky, B.P. Timko, G. Yu, Y. Fang, A.B. Greytak, G. Zheng and C.M. Lieber, "Detection, Stimulation, and Inhibition of Neuronal Signals with High-Density Nanowire Transistor Arrays," Science 313, 1100-1104 (2006).
3) G. Zheng, F. Patolsky, Y. Cui, W.U. Wang and C.M. Lieber, "Multiplexed electrical detection of cancer markers with nanowire sensor arrays," Nat. Biotechnol. 23, 1294-1301 (2005).
4) W.U. Wang, C. Chen, K. Lin, Y. Fang and C.M. Lieber, "Label-free detection of small-molecule-protein interactions by using nanowire nanosensors," Proc. Natl. Acad. Sci. USA 102, 3208-3212 (2005).
5) F. Patolsky, G. Zheng, O. Hayden, M. Lakadamyali, X. Zhuang and C.M. Lieber, "Electrical detection of single viruses," Proc. Natl. Acad. Sci. USA 101, 14017-14022 (2004).

Webpage:
http://cmliris.harvard.edu/

举例 4：

Group Name:
国家生物医学材料工程技术研究中心

Group Leader:
中心名誉主任：张兴栋
中心主任：顾忠伟

Affiliation:
依托于四川大学

Research Interest:
主要从事生物医学材料、医用植入体、组织工程、控释系统及先进制造工艺技术的研究、开发和应用

Research Highlight:
http://www.biomater.com/yanjiukaifachengguo.asp

Representative Publication:
http://www.biomater.com/shangyehuachanpin/chanpinshow.asp?c_id=25
http://www.biomater.com/shangyehuachanpin/chanpinshow.asp?c_id=26

Webpage:
http://www.biomater.com/

[ Last edited by zhangwj on 2009-7-21 at 23:33 ]

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Larry L. Hench Group

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zhangwj(金币+5,VIP+0):thanks 4-1 14:57

Group Name:
Larry L. Hench Group

Group Leader:
Larry L. Hench

Larry L. Hench is currently Professor of Ceramic Materials in the Department of Materials, and he is also Co-Director of the Tissue Engineering and Regenerative Medicine Centre at Imperial College. He assumed the Chair of Ceramic Materials at Imperial College in December 1995, following 32 years at the University of Florida where he was Graduate Research Professor of Materials Science and Engineering, Director of the Bioglass® Research Center and Co-Director of the Advanced Materials Research Center. He completed B.S. and PhD degrees at the Ohio State University in 1964.

In 1969 Professor Hench discovered Bioglass®, the first man-made material to bond to living tissues. This unique range of soda-calcia-phospho-silica glasses is used clinically throughout the world for repair of bones, joints and teeth. This development, together with the accompanying studies of the mechanisms of glass surface reactions and chemical processing of materials, has led to many international awards, including the MRS Von Hippel Award and publication of nearly 520 research papers, 22 books and 23 patents. Dr. Hench's studies of sol-gel processing of silica has led to the development of a new generation of gel-silica optical components (Gelsil®

, including net shape-net surface micro-optics, diffractive optics and porous optical matrices for environmental sensors tissue engineering and solid state dye lasers. These products, now commercially manufactured, have led to numerous advanced technology awards in the optics industry.

Affiliation:
Imperial College (UK)

Research Interest (Specified):
Bioglass

Research Highlight:
His current research is focused on the newly emerging field of tissue engineering. Pioneering studies in collaboration with Professor Julia Polak more recently led to the discovery of a family of genes that are regulated by bioactive materials. This discovery is being used to create a new generation of Materials for regeneration and repair of tissue.

Representative Publication:
1) Hench, LL, Polak, JM, Third-generation biomedical materials., Science, 2002, Vol: 295, Pages: 1014 - 1017, ISSN: 1095-9203
2) Peitl, O, LaTorre, GP, Hench, LL, Effect of crystallization on apatite-layer formation of bioactive glass 45S5, J BIOMED MATER RES, 1996, Vol: 30, Pages: 509 - 514, ISSN: 0021-9304
3) Saravanapavan, P, Hench, LL, Low-temperature synthesis, structure, and bioactivity of gel-derived glasses in the binary CaO-SiO2 system., J Biomed Mater Res, 2001, Vol: 54, Pages: 608 - 618, ISSN: 0021-9304
4) Gough, JE, Clupper, DC, Hench, LL, Osteoblast responses to tape-cast and sintered bioactive glass ceramics., J Biomed Mater Res A, 2004, Vol: 69, Pages: 621 - 628, ISSN: 1549-3296
5) Beilby,R.C., Pryce,R.S., Hench,L.L., et al , Enhanced derivation of osteogenic cells from murine ES cells following treatment with ionic dissolution products of 58S sol-gel glass, Tissue Engineering, 2004, ISSN: 1076-3279

Webpage:
http://www3.imperial.ac.uk/people/l.hench