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国内外知名生物材料研究组介绍【重金收集中】
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???λ???????????????????????о????????????????ǹ?????ǹ?????????? ????????????????????о??????????????????λ?ú???????????????ο??? ?????? ??????? ?????????????????????????? ???????????8???? ????1?? ????2?? ???? 3?? ???? 4?? [ Last edited by zhangwj on 2009-7-21 at 23:33 ] |
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he Stupp laboratory, Northwestern University
★ ★ ★ ★ ★ ★ ★
zhangwj(金币+7,VIP+0):谢谢分享! 2-26 23:37
zhangwj(金币+7,VIP+0):谢谢分享! 2-26 23:37
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Group Name: The Stupp laboratory Group Leader: Samuel I. Stupp Affiliation: Institute for BioNanotechnology in Medicine, Northwestern University Research Interest: cell interactions with a variety of self-assembled structures to design functional materials for regenerative medicine; regenerative scaffolds for wound healing and repair of skeletal, neural and cardiac tissues. Research Highlight: The biomaterials subgroup focuses on cell interactions with a variety of self-assembled structures to design functional materials for regenerative medicine. These structures vary from the nanoscale (e.g., peptide amphiphile nanofibers) to the microscale (e.g., porous biodegradable scaffolds). Projects are underway to design synthetic biomaterials that interact in specific, controllable ways with cells and proteins. Every project in this subgroup combines the tools of cell biology, chemistry, and materials science to examine some aspect of cellular interaction with a defined material. The cells vary from primary mesenchymal and nerve cells, isolated within our own labs, to well-established infinite cell lines. These cells are then allowed to interact with a variety of self-assembling materials, to determine effects on cell adhesion, phenotype, morphology, metabolism, toxicity, and/or gene expression. Translational and pre-clinical studies are underway in collaboration with colleagues at Northwestern's Feinberg School of Medicine, the Institute for BioNanotechnology in Medicine, and elsewhere to image, track and use these materials in vivo as regenerative scaffolds for wound healing and repair of skeletal, neural and cardiac tissues. Representative Publication: (不多于5篇,包括专利) Spoerke, E. D.; Anthony, S. G.; Stupp, S. I.; “Enzyme Directed Templating of Artificial Bone Mineral” Advanced Materials, 21(4), (2009) 425-430. Bansiddhi, A.; Sargeant, T. D.; Stupp, S. I.; Dunand, D. C. “Porous NiTi for Bone Implants: A Review” Acta Biomaterialia, 4(4), (2008) 773-782 Capito, R.; Azevedo, H.; Velichko, Y. R., Mata, A.; Stupp, S. I. “Self-Assembly of Large and Small Molecules Into Hierarchically Ordered Sacs and Membranes” Science, 319, (2008) 1812-1816. Palmer, L. C.; Newcomb, C.; Kaltz, S. R.; Spoerke, E. D.; Stupp, S. I.; “Biomimetic Systems for Hydroxyapatite Mineralization Inspired By Bone and Enamel” Chemical Reviews, 108 (11), (2008) 4754-4783. Webpage: http://stupp.northwestern.edu/research/biomaterials.html |
98楼2009-02-26 04:39:44
The Rater laboratory
★ ★ ★ ★ ★ ★ ★
zhangwj(金币+7,VIP+0):谢谢分享! 2-27 10:53
zhangwj(金币+7,VIP+0):谢谢分享! 2-27 10:53
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Group Name: The Rater laboratory Group Leader: Buddy Ratner Affiliation: Univ of Washington, Chemical Engineering. Research Interest: • Synthesis and characterization of polymeric biomaterials • Surface analysis by ESCA, SIMS, STM, FTIR-ATR, AFM • Plasma deposition of thin films • Tissue Engineering • Scaffolds Research Highlight: They engineer new biomaterial surfaces using a wide range of technologies. For example, radio-frequency plasma deposition (a method borrowed from microelectronics) can readily place interesting thin films on existing medical device surfaces. These films can be used in the precision immobilization of key signaling molecules. They also synthesize new polymers that can be biostable, environmentally responsive, biodegradable and/or porous (i.e., scaffolds). The new surfaces and materials made in Rater laboratory are studied in contact with proteins, blood, living cells and tissues (in vivo and in vitro). Recently, there has been considerable interest in tissue engineering in the Rater laboratory. Tissue engineering exploits all the above principles in the context of tissue and organ reconstruction and regeneration. Specific tissue engineering projects in the Ratner lab aim toward heart muscle, esophagus, bone, cartilage, bladder, vagina and cornea. A new project seeks to model cancer tumor microenvironments using tissue engineering ideas. Biomaterials/biocompatibility projects ongoing in his laboratory include: drug delivery devices, porous scaffolds, tissue engineering, angiogenesis, healing in soft tissue, bioelectrode performance, bioattachment, biorecognition, polyurethanes, hydrogels, biodegradable polymers, non-fouling surfaces, blood-contacting materials, and bacterial biofilms/infection Biomaterial surfaces are the only part of a biomaterial or medical device that is seen by the body. They adapt methods developed in the physics and microelectronics communities to problems in biology and medicine. They use electron spectroscopy for chemical analysis (ESCA), secondary ion mass spectrometry (SIMS), infrared spectroscopy, scanning probe microscopies, surface plasmon resonance and sum frequency generation to observe surface structure and biological interactions. Representative Publication: (不多于5篇,包括专利) • “A Paradigm Shift: Biomaterials that Heal,” B. Ratner, Polymer International, 56:1183–1185, 2007. • “Investigation of the Foreign Body Response with an Implanted Biosensor by In Situ Application of Electrical Impedance Spectroscopy,” F.B. Karp, N.A. Bernotski, T.I. Valdes, K.F. Bohringer, B.D.Ratner, IEEE Sensors, 8(1):104–112, 2008. • "Biomedical Surface Science: Foundations to Frontiers," D.G. Castner, B.D. Ratner, Surface Science 500, 28–60, 2002. • "Development of an electrospray approach to deposit complex molecules on plasma modified surfaces," K.J. Kitching, H-N. Lee, W.T. Elam, E.E. Johnston, H. MacGregor, R.J. Miller, F. Turecek, and B.D. Ratner, Review of Scientific Instruments 74(11), 4832–4839, 2003. • "Biomaterials: Where We Have Been and Where We Are Going," B.D. Ratner and S.J. Bryant, Annual Reviews of Biomedical Engineering, Vol. 6:41–75, 2004. Webpage: http://depts.washington.edu/bioe/people/core/ratner/ratner.html |
99楼2009-02-27 06:53:20
Biomacromolecular materials group at MIT
★ ★ ★ ★ ★
zhangwj(金币+5,VIP+0):谢谢分享! 2-27 10:53
zhangwj(金币+5,VIP+0):谢谢分享! 2-27 10:53
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Group Name: Biomacromolecular materials group Group Leader: Angela Belcher Affiliation: MIT, Materials Science and Engineering and Biological Engineering Research Interest: biomaterials, biomolecular materials, organic-inorganic interfaces and solid state chemistry Research Highlight: The focus of the Biomolecular Materials Group is understanding and using the process by which nature makes materials in order to design novel hybrid organic-inorganic electronic and magnetic materials on new length scales. The group uses these materials in applications as varied as solar cells, batteries, medical diagnostics and basic single molecule interactions related to disease. The research of the lab is highly interdisciplinary and brings together the fields of inorganic chemistry, materials chemistry, biochemistry, molecular biology and electrical engineering. The current research topics in her research lab include 1) biomimetic synthesis of non biological inorganic phases with novel electronic and magnetic properties directed by proteins and synthetic analogs, 2) synthesis and self-assembly of smart polymers to pattern size restricted metals and semiconductors to make devices with novel electronic and optical properties on length scales that surpass current lithographic capabilities, 3) design and synthesis of biocomposite materials that show exceptional strength and regularity and 4) surface modification of high surface area inorganic phases applied to high surface area catalysts, biosensors and environmental remediation. Representative Publication: (不多于5篇,包括专利) 1. *Sinensky, A. K., Belcher, A. M. “Label-free and High Resolution Protein/DNA Nanoarray Analysis using Kelvin Probe Force Microscopy.” Nature Nanotechnology, 2, 2007, 653-659. 2. *Khalil, A.S., Ferrer, J.M., Brau, R.R., Kottmann, S.T., Noren, C.J.,Lang, M.J., and Belcher, A.M. “Single M13 bacteriophage tethering and stretching.” Proceedings of the National Academy of Sciences, 104 (12), 4892–4897, 2007. (cover) 3. *Chiang, C. Y., Mello, C.M., Gu, J., Silva, E.C.C.M., Van Vliet, K.J., and Belcher, A. M. “Weaving Genetically Engineered Functionality into Mechanically Robust Virus Fibers.” Advanced Materials, 19, 826–832, 2007. (cover) 4. *Nam, K. T., Kim, D. W., Yoo, P. J., Chiang, C. Y., Meethong, N., Hammond, P. T., Chang, Y. M., Belcher, A. M. “Virus Enabled Synthesis and Assembly of Nanowires for Lithium Ion Battery Electrodes,” Science, 312, 885-888, 2006. 5. *Yoo, P. J., Nam, K., Qi, J., Lee, S. K., Park, J., Belcher, A. M., Hammond, P. T., “Spontaneous assembly of viruses on multilayered polymer surfaces,” Nature Materials, 5, 234-240, 2006. Webpage: http://belcher10.mit.edu/ [ Last edited by saltlight on 2009-2-27 at 17:24 ] |
100楼2009-02-27 07:17:02
Molly Stevens, Imperial college, London
★ ★ ★ ★ ★
zhangwj(金币+5,VIP+0):谢谢分享 4-18 17:53
zhangwj(金币+5,VIP+0):谢谢分享 4-18 17:53
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Group Name: Molly Stevens Group Leader: Professor Molly Stevens Affiliation: Biomedical Materials and Regenerative Medicine; Research Director for Biomedical Material Sciences in the Institute of Biomedical Engineering, Imperial College, London. Research Interest: Research in regenerative medicine within her group includes the directed differentiation of stem cells, the design of novel bioactive scaffolds and new approaches towards tissue regeneration. She has developed novel approaches to tissue engineering that are likely to prove very powerful in the engineering of large quantities of human mature bone for autologous transplantation as well as other vital organs such as liver and pancreas, which have proven elusive with other approaches. This has led to moves to commercialise the technology and set-up a clinical trial for bone regeneration in humans. In the field of nanotechnology the group has current research efforts in exploiting specific biomolecular recognition and self-assembly mechanisms to create new dynamic nano-materials, biosensors and drug delivery systems. Research Highlight: Directed differentiation of stem cells. Design of novel bioactive scaffolds and new approaches towards tissue regeneration. Bone tissue engineering Exploiting specific biomolecular recognition and self-assembly mechanisms for new dynamic nano-materials, biosensors and drug delivery systems. Representative Publication: 1. Tsigkou, O, Jones, JR, Polak, JM, et al , Differentiation of fetal osteoblasts and formation of mineralized bone nodules by 45S5 Bioglass((R)) conditioned medium in the absence of osteogenic supplements., Biomaterials, 2009, ISSN: 1878-5905 2. de Mel, A, Jell, G, Stevens, MM, et al , Biofunctionalization of Biomaterials for Accelerated in Situ Endothelialization: A Review, BIOMACROMOLECULES, 2008, Vol: 9, Pages: 2969 - 2979, ISSN: 1525-7797 3. Stevens, MM, Biomaterials for bone tissue engineering, MATER TODAY, 2008, Vol: 11, Pages: 18 – 25 4. Lipski, AM, jaquiery, C, Choi, H, et al , Nanoscale engineering of biomaterial surfaces, ADVANCED MATERIALS, 2007, Vol: 19, Pages: 553 - + 5. Mart, RJ, Osborne, RD, Stevens, MM, et al , Peptide-based stimuli-responsive biomaterials, SOFT MATTER, 2006, Vol: 2, Pages: 822 - 835, ISSN: 1744-683X Webpage: http://www3.imperial.ac.uk/people/m.stevens Sample Text |
117楼2009-04-08 10:32:11