IDS-4 Poster Quick Links
• Dendrimer/Dendronized Polymer Synthesis and Characterization
• Medical Applications
• Technical Applications |
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| # | Presenter | Title |
| 1 | Hussein Al-Mughaid, Dalhousie University, Canada | Synthesis of Novel Glycodendrimers Based on Pentaerythritol |
| 2 | Chang-Qi Ma, Univ. of Ulm, Germany | Synthesis of Novel Thiophene Dendrimers |
| 3 | Chih-Fu Yeh, National Taiwan University, Taiwan | Synthesis and Characterization of Electro-active Starburst Block Copolymers |
| 4 | Jørn Christensen,
University of
Copenhagen,
Denmark | Redox Active PAMAM Dendrimers with a 1,4-Phenylenediamine Core |
| 5 | Michael Pittelkow,
University of
Copenhagen, Denmark | Convergent Synthesis of Internally Branched PAMAM Dendrimers |
| 6 | Richard Taylor, Miami University, USA | Divergent Synthesis of Polyurethane Dendrimers |
| 7 | Carmen Casado, Beatriz Alonso,
University Autónoma de Madrid, Spain | Ferrocenyl Dendrimers Decorated with Aza-Crown Ethers |
| 8 | Ajay Konda, South Dakota School of Mines and Technology, USA | Synthesis of Perfluorinated Aliphatic Polyether and Poly(propylene imine) Dendrimers |
| 9 | Rafael Martín-Rapún, Universidad de Zaragoza, Spain | Microphase Segregation in Semifluorinated Ionic Dendrimers |
| 10 | Chiranjeevi Pydi, South Dakota School of Mines and Technology, USA | Synthesis, Characterization and Potential Applications of Trifluoromethylated PAMAM Dendrimers |
| 11 | Anton Jensen, Central MI University, USA | Fullerene-Coated PAMAM and PPI Dendrimers |
| 12 | Chih-Chien Chu, Natl. Taiwan Univ., Taiwan | Synthesis and Characterization of Novel C60-anchored Star-shaped Polymers |
| 13 | Matthew Parrott, McMaster University, Canada | Water Soluble Carborane Containing Aliphatic Polyester Dendrimer |
| 14 | Michael Yurchenko, University of
Pennsylvania, USA | Synthesis of Arylamide Dendrimers with Flexible Linkers via Fischer’s Haloacyl Halide Method |
| 15 | Sami Nummelin, University of
Pennsylvania, USA | Self-Assembled Supramolecular Biphenyl Dendrimers |
| 16 | Sonia Brignell, University of
York, UK | Self-Assembly of Controlled Release Systems Using Dendritic Building Blocks |
| 17 | John Hardy, University
of York, UK | One and Two-Component Dendritic Gels: Control of Self-assembly via Structural Modification of the Dendritic Component |
| 18 | Andrew Hirst,
University of York, UK | Dendritic Self-Assembling Materials: Understanding Molecular Recognition Pathways and Gelation |
| 19 | Caiping Lin, State
University of New York,
USA | Amphiphilic Hydrogels Based on Hyperbranched Polymers and Star Poly(ethylene glycol)s |
| 20 | Jin Hu, Dendritech, Inc., USA | Silicon-containing Hyperbranched Polymers (HBPs) via Bimolecular Nonlinear Polymerization. A Novel Approach to Control the HBP Molecular Sizes |
| 21 | Stephane Mery, IPCMS Strasbourg, France | Preparation of Dendronized Polymers via Living Anionic Polymerization and their Surface Functionalization |
| 22 | Andreas Nyström, Royal Inst. Tech., Sweden | Synthesis and Rheological Investigation of a Set of First to Fourth Generation Dendronized Polymers with Different End Groups |
| 23 | Edis Kasëmi, ETH Zurich, Switzerland | Anionically Chargeable Dendronized Polymers |
| 24 | Hakan Atasoy, ETH Zurich, Switzerland | Introducing a Single and Selective Binding Site to the Backbone of Dendronized Polymers |
| 25 | Ajit Sharma, Central Michigan University,
USA | Polyacrylamide Gel Electrophoresis for Separation and Detection of Poly(amidoamine) Dendrimers with Various Cores and Surface Groups |
| 26 | Britton Carter, Central Michigan University,
USA | Capillary Electrophoresis of Various Cores and Surfaces of PAMAM Dendrimers |
| 27 | Minghui Chai, Central Michigan University,
USA | Probing Dendritic Structures via NMR |
| 28 | Rachel Miller, Central Michigan University,
USA | Fluorescence Studies of PAMAM Dendrimer Cavity with Anilinonapthalene Sulfonate under Physiological Conditions |
| 29 | Mary Cloninger, Montana State
University, USA | EPR Characterization of Heterogeneously-Functionalized Nitroxide-Labeled Dendrimers |
| 30 | Francisco Torrens, University de València,
Spain | Dimension Indices for Characterizing the Solvent-Accessible Surface |
| 31 | Vencislav Parvanov, Emory University, USA | Theoretical Investigation of PAMAM and DAO – TMPTA Dendrimers |
| 32 | Gang Li, Central Michigan University,
USA | Structure-Property Relationships Observed In Electrorheological Experiments Involving Suspensions of Dendrimers and Silica In Silicone Oil |
| 33 | Christopher Locke, Central Michigan
University, USA | Enhanced Polarizability of Microparticles with Surface-Attached Dendrimers |
| 34 | Onofrio Annunziata, Texas Christian
University, USA | Ternary Diffusion in Aqueous Salt Solutions Containing Macromolecules: Applications to Dendrimers in Solution |
| 35 | Jarmo Ropponen, University of Kuopio,
Finland | Thermal Studies of Aliphatic Polyester Dendrimers |
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| # | Presenter | Title |
| 36 | Loretta Sharma, Central Michigan
University, USA | Use of Poly(amidoamine) Dendrimers in the Biochemistry Laboratory |
| 37 | Ben Boyd, Monash University, Australia | Controlling the Pharmacokinetic and Biodistribution Behaviour of Poly-L-Lysine Based Dendrimers: Cationic Dendrimer Cores Capped with Anionic Surface Groups |
| 38 | Lisa Kaminskas, Monash University,
Australia | PEGylated Poly-L-Lysine Dendrimers: Impact of PEG Length and Dendrimer Size on their Pharmacokinetics and Biodistribution |
| 39 | Dzmitry Shcharbin, University of Lodz,
Poland | Dendrimers as Detoxication Agents |
| 40 | Anil Kumar, Indian Institute of
Technology, India | New Potentially Biodegradable Highly Functional Hyperbranched and Dendritic Polymers |
| 41 | Lori Kubasiak, Dendritic NanoTechnologies, Inc., USA | Core and Surface-Dependent Cytotoxicity of Poly(amidoamine) (PAMAM) Dendrimers |
| 42 | Cordell DeMattei, Dendritic NanoTechnologies, Inc., USA | Poly(amidoamine) (PAMAM) Dendrimers as siRNA Delivery Agents |
| 43 | Abhay Chauhan, Dendritic NanoTechnologies, Inc., USA | Core and Surface-Dependent Encapsulation and Release Properties of Poly(amidoamine) (PAMAM) Dendrimers |
| 44 | Bharathi Devarakonda, University of
Louisiana, USA | Effect of Poly(amidoamine) (PAMAM) Dendrimers on Paclitaxel Solubility and In Vitro Cytotoxicity Against Prostate Cancer (PC-3M) Cells |
| 45 | Bharathi Devarakonda, University of
Louisiana, USA | Enhanced Solubility, Dissolution, and Bioavailability of Furosemide when Combined with Poly(amidoamine) (PAMAM) Dendrimers |
| 46 | Kelly Marie Kitchens, University of Maryland,
USA | Poly(amidoamine) (PAMAM) Dendrimers as Oral Drug Carriers: Influence of Size and Surface Charge on Transepithelial Transport |
| 47 | Pakatip Ruenraroengsak,
University of London,
UK | Uptake and Mobility of Intrinsically Fluorescent Poly(lysine) Dendrimers in Caco-2 Cells |
| 48 | Keith Freel, Central Michigan University,
USA | Diffusion NMR Study of Drug Encapsulation into Dendrimers |
| 49 | Nathan Stasko, University of North Carolina-Chapel Hill, USA | Dendrimers as a Scaffold for Targeted Nitric Oxide Release |
| 50 | Barbara Klajnert, McMaster University, Canada | Interactions between Poly(amidoamine) Dendrimers and Model Lipid Bilayers |
| 51 | Suzie Ribeiro,
University of London, UK | Genetic Immunization with Dendriplexes Containing Plasmid Encoding Protective Antigen Protein Against Anthrax |
| 52 | Marine Guillot, ETH Zurich, Switzerland | Polycationic Dendritic Vectors for Gene Transfection |
| 53 | George Chen, Chinese University of Hong
Kong, China | Dendrimer-mediated ZBP-89 Gene Delivery on Inhibition of Tumor Growth |
| 54 | Guodong Zhang,
University of
Cincinnati, USA | Beta-Cyclodextrin/Oligoamine Dendrimers for DNA Delivery |
| 55 | Siew-Eng How,
University of Southhampton, UK | DNA Alkylation with Amplified Alkylating Agents |
| 56 | Ankur Desai, Central Michigan University,
USA | Bioconjuation of PAMAM Dendrimers with Oligonucleotides to Form “Modified Primers” and its Application in MultiGEN Technology |
| 57 | Nicoleta Bogdan,
University of Quebec
at Montreal, Canada | Glycodendrimer Coated Gold Nanoparticles as Sensors for Lectins and Fimbriated Bacteria |
| 58 | Meir Israelowitz, Biomimetics Technologies, Inc., Canada | Mechanism of Infrared Sensation and Transduction by the Beetle Melanophila acuminata |
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| # | Presenter | Title |
| 59 | Conrad Siegers,
University Freiburg, Germany | Branched Systems for Increased Light-Harvesting via Fluorescent Resonant Energy Transfer in the Dye-Sensitized Solar Cell |
| 60 | Giacomo Bergamini, Università di Bologna, Italy | Cyclam-Cored Dendrimers: Light-Harvesting Antennas, Sensors and Host-Guest Systems |
| 61 | Jeffrey Krause,
University of Florida,
USA | Energy Transfer in Dendrimers |
| 62 | Steffen Hackbarth, Humboldt University
of Berlin, Germany | Ultrafast Energy Transfer Between Pheophorbide a Molecules in Dendrimers of Different Generations |
| 63 | Steffen Hackbarth, Humboldt University of
Berlin, Germany | Energy Transfer and Excitonic Interactions Between Chromophores in Novel Fullerene-Dendron-Pyropheophorbide a Supramolecules |
| 64 | Anis Rahman, Applied Research & Photonics, Inc., USA | Dendrimer Based Photonic Waveguide and Process |
| 65 | Anis Rahman, Applied Research & Photonics, Inc., USA | Erbium Doped Dendrimer Waveguide Amplifier |
| 66 | Toyoko Imae, Nagoya University, Japan | Radical-uptake into Aggregate of Copolymer with Linear Polyelectrolyte Block and Hydrophobic Block Carrying Pendant Dendritic Moiety in Water |
| 67 | Sebastian Roller, University Dortmund, Germany | Dendritic Polyglycerol as High-Loading Soluble Polymeric Support for Stereoselective Catalysis |
| 68 | Daming Fan, Central Michigan University, USA | Interaction of the PAMAM Dendrimer Core and G1 with Metal Species |
| 69 | Jennifer Bridwell, Central Michigan
University, USA | Molecular Simulation of PAMAM Dendrimer Complexation of Platinum(II) |
| 70 | Michael Zhuravel, Dendritic NanoTechnologies,
Inc., USA | Synthesis and Ion Conductivity Properties of Polyether Dendronized Polymers |
| 71 | Young Hie Kim, Oklahoma State
University, USA | Amphiphilic Block Copolymers on a Dendrimer Core as Templates in Emulsion Polymerization of Styrene |
| 72 | Arsen Simonyan, State University of New York, USA | Linear–Dendritic Supermolecules as Nano–Scale Reactors for Green Chemistry |
| 73 | Jason K. Vohs, Central Michigan University, USA | Dendrimer-Assisted Growth of Carbon Nanostructures and Metal Nanoparticles |
| 74 | Leela Rakesh, Central Michigan University, USA | Molecular Simulation of Vapour Adsorption in the Thin Film of Gold Nano Particle with Poly(propylene imine) (PPI) Dendrimer Composite |
| 75 | Leela Rakesh, Central Michigan University, USA | Diffusion of Hydrogen and Methane in PAMAM Dendrimers in Both the Presence and Absence of Metal Moieties Using Molecular Simulation |
| 76 | Steven Kaganove, Dendritech, Inc., USA | Polyamidoamine-Organosilicon (PAMAMOS) Dendrimer Coatings for Vapor Phase Cyanide Removal |
| 77 | Claire Hartmann-Thompson, Dendritech, Inc., USA | Hydrogen-Bond Acidic Hyperbranched Polymers for Surface Acoustic Wave (SAW) Sensors |
| 78 | Claire Hartmann-Thompson, Dendritech, Inc., USA | Inorganic-Organic Polyamidoamine (PAMAM) Dendrimer-Polyhedral Oligosilsesquioxane (POSS) Hybrid Nanomaterials |
| 79 | Abhijit Sarkar, Dendritech, Inc., USA | Colorimetric Biosensors Based on PAMAM Dendrimer-Polydiacetylene Nanoconstructs |
| 80 | Abhijit Sarkar, Dendritech, Inc., USA | PAMAMOS: A New Class of Siliconized Dendrimers |
