{"id":41,"date":"2016-10-21T13:25:15","date_gmt":"2016-10-21T11:25:15","guid":{"rendered":"https:\/\/www.ciscem2021.de\/?page_id=41"},"modified":"2020-02-07T10:03:21","modified_gmt":"2020-02-07T09:03:21","slug":"posters","status":"publish","type":"page","link":"https:\/\/www.livingmaterials2020.de\/program\/posters\/","title":{"rendered":"Posters"},"content":{"rendered":"
Stable Biofilm Catalysts Controlled by Genetically Encoded Logic Gates Living glue systems that autonomously perform diverse mechanical repair tasks Conductive hybrid inkjet inks with biological functionalities Synthesis of SiO2 Reinforced PolyEtherEtherKetone (PEEK) Biomaterial of Improved Mechanical Strength and Thermal Stability for Potential Biomedical Application Synthesis of biosurfactant stabilized silver nanoparticles and their potential application for biomedical and therapeutic purposes Living Therapeutic Materials:\u00a0Light-mediated smart drug release from hydrogel-encapsulated bacteria Self-Shaping Smart Structure: Computational Design and 4D-Printing for Surface Shifting Material Systems Inspired by the Butterwort (Pinguicula grandiflora) Streptomyces albus based living therapeutic materials for sustained drug release Noncanonical amino acids in a cell free TX-TL system<\/em> Biomediated synthesis of materials<\/em> Inhibition of Bioadhesion by Subcellular Surface Topography, Dynamic Lipid Layer and Chemical Textures<\/em> Interfacing DNA Nanotechnology with Living Systems<\/em> Two-photon degradable hydrogels for dynamic control of\u00a0cellular microenvironments<\/em> Designing soft materials for \u2018the living\u2019: hydrogels based on the luciferin ligation for cell encapsulation Electrically conductive hydrogel-metal hybrids structured with 3D printing Engineered Viruses for Selective Metal Ion Binding<\/em> Active, compartmentalized nanocomposites Synthesis of a hybrid material suitable for animal cell encapsulation in cell therapy <\/em> Engineering C. crescentus to secrete a crosslinking enzyme in a Hydrogel-based Living Material<\/em> Soft matrices based on thiol-methylsulfone chemistry for 3D cell culture Hybrid microenvironments for the ex-vivo expansion of Hematopoietic Stem Cells L. lactis optogenetic gene expression system for tissue engineering applications<\/em> Bacterial lighthouses \u2013 living sensors for fast pathogen detection<\/em> Modeling the phase behavior of stimuli-responsive tissue-mimicking microgels<\/em> Living materials with programmable functionalities grown from engineered microbial co-cultures<\/em> Photodegradable bioadhesive hydrogels for 3D cell encapsulation<\/em> Synthetic biology-inspired design of biomaterials featuring feedforward and feedback circuits<\/em> Spatio-temporal organization of matter during biofilm morphogenesis: the role of water<\/em> <\/p>\n <\/p>\n","protected":false},"excerpt":{"rendered":" Preliminary list as of February 07, 2020<\/p>\n Stable Biofilm Catalysts Controlled by Genetically Encoded Logic Gates Living glue systems that autonomously perform diverse mechanical repair tasks Conductive hybrid inkjet inks with biological functionalities Synthesis of SiO2 Reinforced PolyEtherEtherKetone<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":37,"menu_order":3,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"footnotes":""},"acf":[],"yoast_head":"\n
\n<\/em>Recep Erdem Ahan<\/strong>
\n<\/em>Bilkent University, Ankara, TR<\/p>\n
\n<\/em>Bolin An<\/strong>
\n<\/em>Massachusetts Institute of Technology, Cambridge, MA, USA<\/span><\/p>\n
\n<\/em>Indra Backes
\n<\/strong>INM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\n<\/em>Fisseha Bezza<\/strong>
\n<\/em>University of Pretoria, Pretoria, ZA<\/p>\n
\n<\/em>Fisseha Bezza<\/strong>
\n<\/em>University of Pretoria, Pretoria, ZA<\/p>\n
\n<\/em>Shardul Bhusari<\/strong>
\nINM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\n<\/em>Tiffany Cheng<\/strong>
\n<\/em>Institute for Computational Design, Stuttgart, DE<\/p>\n
\n<\/em>Priyanka Dhakane<\/strong>
\nINM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\nMarc Finkler<\/strong>
\nSaarland University, Saarbr\u00fccken, DE<\/p>\n
\nYvonne Gmach<\/strong>
\nTechnical University of Munich, Straubing, DE<\/p>\n
\nRalf Helbig<\/strong>
\nIPF Dresden, Dresden, DE<\/p>\n
\nAndreas Herrmann<\/strong>
\nDWI \u2013 Leibniz-Institut f\u00fcr Interaktive Materialien, Aachen, DE<\/p>\n
\nQiyang Jiang<\/strong>
\nINM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\n<\/em>Minye Jin
\n<\/strong>INM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\n<\/em>Michael Klos
\n<\/strong>INM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\nNuriye Korkmaz<\/strong>
\nKIST Europe Forschungsgesellschaft mbH, Saarbr\u00fccken, DE<\/p>\n
\n<\/em>Mariano Laguna<\/strong>
\n<\/em>INM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\nMyriam Neumann<\/strong>
\nUniversity of Namur, Namur, BE<\/p>\n
\nMaria Orozco Hidalgo<\/strong>
\nLawrence Berkeley National Laboratory, CA, USA<\/p>\n
\n<\/em>Julieta I. Paez
\n<\/strong>INM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\n<\/em>Michaela Petaroudi
\n<\/strong>Centre for the Cellular Microenvironment, University of Glasgow, Glasgow, UK<\/p>\n
\nAleixandre Rodrigo-Navarro<\/strong>
\nCentre for the Cellular Microenvironment, Glasgow, GB<\/p>\n
\nFlorian Schr\u00f6per<\/strong>
\nFraunhofer-Institut f\u00fcr Molekularbiologie, Aachen, DE<\/p>\n
\nBaeckkyoung Sung<\/strong>
\nKIST Europe, Saarbr\u00fccken, DE<\/p>\n
\nTzu-Chieh Tang<\/strong>
\nMIT Department of Biological Engineering, Cambridge, USA<\/p>\n
\nMaria Villiou<\/strong>
\nINM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n
\nHanna Wagner<\/strong>
\nUniversity of Freiburg, Freiburg, DE<\/p>\n
\nRicardo Ziege<\/strong>
\nMax-Planck-Institute of Colloids, Potsdam, DE<\/p>\n
\nRecep Erdem Ahan
\nBilkent University, Ankara, TR<\/p>\n
\nBolin An
\nMassachusetts Institute of Technology, Cambridge, MA, USA<\/p>\n
\nIndra Backes
\nINM \u2013 Leibniz Institute for New Materials, Saarbr\u00fccken, DE<\/p>\n