| Poster Programme |
| P 1.01 |
A heterogeneous two-hybrid system in Escherichia coli based on polyhydroxyalkanoates synthesis regulatory proteins PhaR
Z.H. Wang, P. Ma, J. Chen, J. Zhang, Shantou University/PRC |
| P 1.02 |
The behaviour of neural stem cells on Polyhydroxyalkanoate nanofiber scaffolds
X.Y. Xu, Shantou University/PRC; X.T. Li, Hong Kong University/PRC; S.W. Peng, J.F. Xiao, C. Liu, G. Fang, K.C. Chen, Shantou University/PRC; G.Q. Chen, Tsinghua University, Beijing/PRC |
| P 1.03 |
Zinc alginate and calcium alginate nanocomposite fibres for application in regenerative medicine
M. Bogun, G. Szparaga, P. Król, Technical University of Lodz/PL |
| P 1.04 |
Synthesis, characterization and application of poly(acrylic acid)-graft-cassia javanica seed gum
V. Singh, S.K. Singh, P.K. Tandon, University of Allahabad/IND |
| P 1.06 |
Plasticized cellulose acetate (CA) for foaming applications
S. Zepnik, A. Kesselring, R. Kopitzky, C. Michels, Fraunhofer Institute for Environmental, Safety and Energy Technology UMSICHT, Oberhausen/D; H.-J. Radusch, University Halle-Wittenberg/D |
| P 1.08 |
Characterization of a novel extracellular medium-chain-length poly(3-hydroxyalkanoate) depolymerase from Streptomyces venezuelae SO1
J. Gangoiti, M. Santos, M.J. Llama, J.L. Serra, University of the Basque Country, Leioa/E |
| P 1.09 |
Multi-functional P(3HB)microsphere /45S5bioglass®-based composite of scaffolds for bone tissue engineering
L. Francis, M. Decheng, University of Westminster, London/UK; A.R. Boccaccini, University of Erlangen-Nürnberg/D; I. Roy, University of Westminster, London/UK |
| P 2.01 |
Bioxamine: diamines from renewable resources
J. Pfeffer, S. Schaffer, T. Haas, Evonik Degussa GmbH, Marl/D |
| P 2.02 |
Formation of new polyhydroxyalkanoate containing 3-hydroxy-4-methylvalerate monomer in Burkholderia sp.
N. Lau, K. Sudesh, University Sains Malaysia, Penang/MAL; T. Tsuge, Tokyo Institute of Technology, Yokohama/J |
| P 2.03 |
Evaluation of PHA production by isolates from sewage sludge
D.C.P. Lício, K.C. Lopes, L.F. Silva, J.G.C. Gomez, University of Sao Paulo/BR |
| P 2.04 |
Raw Starch as carbon source for the production of PHB in the marine bacterium Saccharophagus degradans
Y. Gonzalez-Garcia, M.A. Rosales, J. Cordova, O. Gonzalez-Reynoso, University of Guadalajara, Zapopan/MEX |
| P 2.05 |
In vitro mutagenesis of the type IV polyhydroxyalkanoate synthase in Bacillus cereus SPV
P. Basnett, University of Westminster, London/UK; S. Philip, University of Nottingham/UK; A. Markiv, I. Roy, University of Westminster, London/UK |
| P 3.01 |
Study on misciblitiy of PVC/feather keratin by dilute solution viscometry
Sh. Akhlaghi, A. Sharif, M.R. Kalaee, Islamic Azad University Tehran South Branch, Tehran/IR |
| P 3.02 |
Crystallization and degradation of polyhydroxybutyrate with modified silica
S. Hong, S.C. Huang, Yuan-Ze University, Chung-Li/RC |
| P 3.03 |
Production and characterization of functionalized medium-chain-length polyhydroxyalkanoates containing thioester groups in the side chain
V. Morales, I.F. Escapa, M.A. Prieto, Centro de Investigaciones Biologicas, Madrid/E; V. Martino, E. Pollet, L. Avérous, LIPHT-ECPM, Université de Strasbourg/F |
| P 3.05 |
Synthesis, properties and biological activity of poly(acrolein-co-vinylpyrrolidone) and its oxime and phenylhdrazone derivatives
D. Mete, Ö. Özarslan, Abant Izzet Baysal University, Bolu/TR; O. Güven, Hacettepe Unviversity, Ankara/TN |
| P 3.06 |
Green route for fabricating photoluminescent adsorbent nanocomposite based on guar gum
V. Singh, S.K. Singh, S. Pandey, University of Allahabad/IND |
| P 3.07 |
Preparation and some properties of TCP/aceto-butyric chitin copolyesters nanocomposites
Z. Draczynski, Technical University of Lodz/PL |
| P 3.08 |
Reactive blend of poly(lactic acid)(PLA) and soy protein concentrate(SPC)
N. Pinsurong, S. Suttiruengwong, M. Saedan, Silpakorn University, Nakhon Pathom/THA |
| P 3.09 |
Compatibilized polylactic acid/rhermoplastic starch by reactive extrusion blend
J. Leadprathom, S. Suttiruengwong, P. Threepopnatkul, M. Saedan, Silpakorn University, Nakorn Pathom/THA |
| P 3.11 |
Characterization of PHAs from pure and open mixed cultures
F. Maurer, P. Jannasch, C. Malengreaux, Lund University/S; P. Johansson, P. Magnusson, A. Werker, AnoxKaldnes, Lund/S |
| P 4.01 |
Characterization of an extracellular poly-(L-lactic acid) (PLA) hydrolase of a PLA-degrading Amycolatopsis sp. strain isolated from northern Thailand soil
A. Siazar, S. Lumyong, Chiang Mai University/THA; D. Jendrossek, University of Stuttgart/D |
| P 4.02 |
Construction of a Xanthomonas sp. 35Y RoxA deletion mutant for expression of recombinant RoxA variants
N. Hambsch, J. Birke, D. Jendrossek, University of Stuttgart/D |
| P 5.01 |
Prediction of transcriptional terminators of phaC1 gene in Pseudomonas species
J. Mozejko, M. Królicka, S. Ciesielski, University of Warmia and Mazury, Olsztyn/PL |
| P 5.02 |
Effect of growth and polyhydroxyalkanoates accumulation in Cupriavidus taiwanensis grown in the medium with and without heavy metal cadmium
C. Chien, L. Wang, Yuan Ze University, Chung-Li/RC |
| P 5.03 |
Novel intracellular PHB depolymerase from Azohydromonas lata
E. Hüper, D. Pfeiffer, D. Jendrossek, University of Stuttgart/D |
| P 5.04 |
A regulatory protein of Ensifer meliloti involved in biopolymers synthesis
S. Povolo, S. Casella, University of Padova, Legnaro/I |
| P 5.05 |
Cloning and characterizing a thermostable polyhydroxyalkanoate synthase from a thermophile Cupriavidus sp.: improved the thermal stability and specific activity of PHA synthase enhance the PHA accumulation in Escherichia coli.
D.-S. Sheu, Y.-W. Lai, W.-M. Chen, R.-C. Chang, National Kaohsiung Marine University/RC |
| P 5.06 |
The use of metabolomics in microbial engineering for PHA biosynthesis
Y. Guo, G.Q Chen, Tsinghua University, Beijing/PRC |
| P 5.07 |
Stabilized multi-copy integration of heterologous pathways by Cre-loxp system for enhanced PHB production
X. Gao, G.Q. Chen, Tsinghua University, Beijing/PRC |
| P 5.08 |
Verification of PHB depolymerase activity from PHB depolymerase
database
A. Sznajder, D. Jendrossek, University of Stuttgart/D |
| P 5.09 |
PHA production coupling with formate pathway in metabolically engineered Escherichia coli under anaerobic conditions
R. Wang, G.Q. Chen, Tsinghua University, Beijing/PRC |
| P 5.10 |
Identification of genes involved in PHA monomer degradation by DNA microarrays analysis
A. Chung, G.Q. Chen, Tsinghua University, Beijing/PRC |
| P 5.11 |
Crystal structure of Paucimonas lemoignei PhaZ7 PHB depolymerase: insights into polymer binding and hydrolysis
S. Wakadkar, A. C. Papageorgiou, University of Turku/FIN; S. Hermawan, D. Jendrossek, University of Stuttgart/D |
| P 5.12 |
Metabolic engineering of Cupriavidus necator by chromosomal recombination for efficient biosynthesis of poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) from vegetable oil.
J. Mifune, S. Nakamura, T. Fukui, Tokyo Insitute of Technology, Yokohama/J |
| P 5.13 |
Evaluation of promoters for gene expression in PHA-producing Cupriavidus necator
I. Orita, K. Ohsawa, S. Nakamura, T. Fukui, Tokyo Institute of Technology, Yokohama/J |
| P 5.14 |
Pathway engineering for Poly (3-hydorxybutyrate) synthesis in Escherichia coli: ldhA mutants have increased biomass and polymer production from glycerol
P.I. Nikel, University of Buenos Aires, University of San Martin/RA; A. Giordano, A. de Almeida, M.J. Pettinari, University of Buenos Aires/RA |
| P 5.15 |
PCR screening of PHA synthase genes in Brazilian soil samples of Atlantic Forest
Y.P. Galindo, K.C. Massini, G. Padilla, J.G.C. Gomez, L.F. Silva, University of Sao Paulo/BR |
| P 5.16 |
PHA production coupling with formate pathway in metabolically engineered Escherichia coli under anaerobic conditions
R. Wang, G.Q Chen, Tsinghua University, Beijing/PRC |
| P 5.17 |
Use of 13C for metabolic fluxes analysis in the process of PHAMCL production from carbohydrates by Pseudomonas sp. LFM046
L. Kawai, N. Merchan-Castellanos, L. Silva, University of Sao Paulo/BR; G. Fonseca, Federal University of Campo Grande/BR; J. Gomez, M.K. Taciro, University of Sao Paulo/BR |
| P 5.18 |
Investigation of the role of ß-oxidation upper pathway genes in PHA accumulation
M. Guzik, A. Hume, K. O'Connor, University College Dublin/IRL |
| P 5.19 |
A highly conserved gene of unknown function is involved in PHB accumulation of Synechocystis sp. PCC 6803
M. Schlebusch, K. Forchhammer, Tübingen University/D |
| P 5.20 |
Comparison of the production of polyhydroxybutyrates by three types of microorganisms
L. Garcia-Gonzalez, Flemish Institute for Technological Research, Mol/B; S. Vangeel, S. Van Roy, B. Lemmens, H. Elslander, A. Borburgh, M. Maesen, K. Vanbroekhoven, L. Diels, W. Dejonghe, VITO, Mol/B |
| P 5.21 |
The PHA depolymerase engineering database: a systematic analysis of sequence-structure-function relationships of the highly diverse PHA depolymerase family
T.M. Hamm, J. Pleiss, University of Stuttgart/D |
| P 5.22 |
Localization of proteins involved in PHB metabolism in Ralstonia eutropha
P. Kaufmann, S. Reinhardt, D. Jendrossek, University of Stuttgart/D |
| P 5.23 |
Molecular modelling of binding of an extracellular short chain PHB depolymerase from Penicillium funiculosum to a PHB interface
P. Tessaro, J. Pleiss, University of Stuttgart/D |
| P 5.24 |
Engineering monomer specificity of the P.oleovorans PHA synthase via site directed mutagenesis and error-prone PCR
J.S.F. Barrett, F. Srienc, University of Minnesota, St. Paul/USA |
| P 5.25 |
Production of poly hydroxy alkanoate biopolyesters from glycerol
N. Pisutopaisal, H.T. Wattanaphon, King Mongkut´s University of Technology North Bangkok, Bangkok/THA |
| P 5.26 |
PHA synthase fusion dimers
S. Sangiambut, University of Cambridge/UK; S. Sato, National Institute of Advanced Industrial Science and Technology/J; E. Sivaniah, University of Cambridge/UK; T. Tsuge, Tokyo Institute of Technology/J |
| P 5.27 |
Electron microscopy studies of granule formation in phaZ knockout strains in Ralstonia eutropha
E. Reimer, RWTH Aachen/D; C. Brigham, D. MacEachran, J. Quimby, C. Rha, Massachusetts Institute of Technology, Cambridge/USA; A.J. Sinskey, Massachusetts Institute of Technology/USA |
| P 6.01 |
Poly-(3-hydroxybutyrate) purification using different commercial surfactants from recombinant Escherichia coli XL1-blue
W.J. Ting, Y.C. Peng, Y.N. Chou, H.S. Wu, Yuan Ze University, Zhongli City/RC |
| P 6.02 |
Stability process for recovery of poly-(3-hydroxybutyrate) from recombinant Escherichia coli XL1-blue
W.J. Ting, J.C. Tseng, Y.C. Peng, H.S. Wu, Yuan Ze University, Zhongli City/RC |
| P 6.03 |
Polyhydroxyalkanoates production from whey by Haloferax mediterranei
J. Pais, Universidade Nova de Lisboa - Requimte, Caparica/P; T. Gameiro, I. Farinha, UNL-FCT-Requimte, Caparica/P; L. Serafim, CICECO- UA, Aveiro/P; M.A. Reis, UNL-FCT-Requimte, Caparica/P |
| P 6.04 |
Biosynthesis of medium-chain-length PHA by two Pseudomonas strains using waste rapeseed oil
S. Ciesielski, J. Mozejko, G. Przybylek, University of Warmia and Mazury, Olsztyn/PL |
| P 6.05 |
Characterization of polyhydroxyalkanoates producing bacteria enriched from activated sludge
S. Ciesielski, E. Klimiuk, P. Kowal, T. Pokoj, University of Warmia and Mazury, Olsztyn/PL |
| P 6.06 |
PHB-based polyester-urethanes, blends and composites
H. Seliger, H. Haeberlein, BiotechnologieZentrum (TFU), Ulm/D; R. Kohler, Reutlingen University/D |
| P 6.07 |
Microwave-assisted synthesis of aliphatic polyesters - development of the first commercial plant-
T. Nakamura, R. Nagahata, Y. Mori, AIST, Tsukuba/J; K. Kunii, H. Soga, S. Sugimoto, Shikoku Instrumentation, Takamatsu/J; K. Takeuchi, AIST, Tsukuba/J |
| P 6.08 |
Integration of phaCAB into E. coli K12 chromosome for PHB production
S.Y. Chen, S.Y. Wang, Yuan Ze University, Chung-Li/RC; P.C. Soo, Tzu Chi University, Hualien/RC |
| P 6.09 |
Bio-oil valorisation using mixed microbial cultures for bioplastics production
R. Moita, P.C. Lemos, The New University of Lisboa/P |
| P 6.11 |
Modification of PHA biopolymers by addition of carbon nanotubes
R. Russell, Australian Nuclear Science and Technology Organisation, Sydney/AUS; S.I. Yun, Jeonju Institute of Machinery and Carbon composites/ROK; G.E. Gadd, P.J. Holden, Australian Nuclear Science and Technology Organisation, Sydney/AUS |
| P 6.12 |
Atmospheric pressure, a suitable way to increase the oxygen transfer rate during production of mcl-PHA by Pseudomonas putida KT2440?
S. Follonier, B. Henes, Empa - Swiss Federal Laboratories for Materials Testing and Research, St. Gallen/CH; S. Panke, ETH Zurich, Basel/CH; M. Zinn, Empa - Swiss Federal Laboratories for Materials Testing and Research, St. Gallen/CH |
| P 6.13 |
Utilization of low-cost agricultural feedstock as carbon source to produce medium-chain-length polyhydroxyalkanoates by engineered strains
S. Le Meur, Empa - Swiss Federal Laboratories for Materials Testing and Researchute of Technology, St. Gallen/CH; M. Zinn, Qu. Ren, Empa - Swiss Federal Laboratories for Materials Testing and Research, St. Gallen/CH; T. Egli, Eawag, Dübendorf/CH |
| P 6.14 |
A novel downstream process based on cell aggregation of Escherichia coli by cohesin-dockerin interaction from the cellulosome of Clostridium cellulolyticum
J. Yin, G.Q. Chen, Tsinghua University, Beijing/PRC |
| P 6.15 |
The development of a sterilization-free, high-density and continuous fermentation process for PHA production by a Halomonas strain
D. Tan, G.Q. Chen, Tsinghua University, Beijing/PRC |
| P 6.16 |
Production of PHAmcl with variable composition by the mutant strain Pseudomonas sp. LFM693 using different glucose/propionic acid ratios
R.C.S. Rocha, E.A. Brandi, N.F.G. Machado, D.P.S. Martinez, L.F. Silva, J.G.C. Gomez, University of Sao Paulo/BR |
| P 6.17 |
PHA production by recombinant E. coli harboring the operon phaCAB from R. eutropha and interrupted on the prpC gene
J. Bocanegra, J. Gomez, L. Silva, University of Sao Paulo/BR; J. Pradella, Center for Science and Biotechnology of Bioethanol, Campinas/BR |
| P 6.18 |
One-step production of lactate-containing polymers by engineered bacteria
T.W. Lee, Y.K. Jung, KAIST, Daejeon/ROK; S.J. Park, KRICT, Daejeon/ROK; S.Y. Lee, KAIST, Daejeon/ROK |
| P 6.19 |
Metabolic engineering of Escherichia coli for polylactic acid production
T.W. Lee, Y.K. Jung, T.Y. Kim, KAIST, Daejeon/ROK; S.J. Park, KRICT, Daejeon/ROK; S.Y. Lee, KAIST, Daejeon/ROK |
| P 6.20 |
Efficient production of polylactic acid and Its copolymers by metabolically engineered Escherichia coli
T.W. Lee, Y.K. Jung, S.Y. Lee, KAIST, Daejeon/ROK |
| P 6.21 |
High-cell-density cyclic fed-batch fermentation
of a poly(3HB)-accumulating thermophilic bacterium,
Chelatococcus sp. MW10
M.H.A. Ibrahim, National Research Centre, Cairo/ET; A. Steinbüchel, Universität Münster/D |
| P 6.22 |
Production of bacterial cellulose using residues of the portuguese agro-food and agro-forestry industries
P. Carreira, L. Pedro, E. Trovatti, L.S. Serafim, C.S.R. Freire, A.J.D. Silvestre, C.P. Neto, University of Aveiro/P |
| P 6.23 |
Metabolic flux analysis of medium-chain-length polyhydroxyalkanoates production in chemostat culture
M.K. Taciro, J.G.C. Gomez, L.F. Silva, University of Sao Paulo/BR; R.A.M. Piccoli, Instituto de Pesquisas Tecnológicas do Estado de São Paulo/BR; J.G.C. Pradella, Centro de Ciência e Tecnologia do Bioetanol, Campinas/BR |
| P 6.24 |
Production and characterisation of polyhydroxybutyrate and its co-polymers from R.eutropha
S. Bagheriasl, University of Birmingham/UK; I. Radecka, Wolverhampton University/UK; M. Jenkins, A. Stamboulis, University of Birmingham/UK |
| P 6.25 |
Production of polyhydroxyalkanoates by rhizobacteria underneath Nickel-hyperaccumulators from serpentine ecosystem
A. Pal, Serampore College/IND; A.K. Paul, University of Calcutta/IND |
| P 6.27 |
Enhanced and economical production of poly(3-hydroxybutyrate), a biodegradable polymer and its applications
E. Akaraonye, University of Westminster, London/UK; M. Safarikova, Institute of Systems Biology and Ecology AS CR, Ceske Budejovice/CZ; T. Kashavarz, I. Roy, University of Westminster, London/UK |
| P 6.29 |
Online monitoring of PHA storage during fermentation
J. Ackermann, D. Janetz, University of Applied Sciences Dresden/D; T. Maskow, Helmholtz Centre for Environmental Research - UFZ, Leipzig/D |
| P 6.30 |
Biosynthesis of P3H4PE by Burkholderia cepacia IPT064 using unrelated carbon sources
R.C.S. Rocha, J.G.C. Gomez, University of Sao Paulo/BR; R.A.M. Piccoli, Institute for Technological Research/BR; J.G.C. Pradella, Brazilian Bioethanol Science and Tecnhology Laboratory, Campinas/BR |
| P 6.31 |
Poly(3-hydroxybutyrate) production with indigenous vibrio sp. M20 isolated from marine environment
Y.H. Wei, H.S. Wu, Yuan Ze University, Taoyuan/RC |
| P 6.32 |
Extraction of bacterial poly(3-hydroxybutyrate) USING 1.2 - propylene carbonate
L.K.M. Quines, G.M.F. Aragao, J.L. Ienczak, M. Schmidt, W. Schmidell, Federal University of Santa Catarina, Florianopolis, SC/BR |
| P 6.33 |
Poly(3-hydroxybutyrate)produced by Cupriavidus necator using soybean oil miniemulsion as culture suplementation
J.L. Ienczak, G.M.F Aragao, M. Schmidt, L.K.M Quines, W. Schmidell, Federal University of Santa Catarina, Florianopolis/BR |
| P 6.34 |
Degradation of poly(3-hydroxyoctanoate) catalysed by medium-chain-length Pseudomonas fluorescens GK13 depolymerase to produce (R)-3-hydroxyoctanoic acid monomers
M. Santos, J. Gangoiti, M.J. Llama, J.L. Serra, University of the Basque Country, Leioa/E |
| P 7.01 |
Biosynthesis of poly(3-hydroxybutyrate-co-3-hydroxyvalerate) with co-expressed propionate permease (prpP), Beta-ketothiolase B (bktB) and propionyl-CoA synthase (prpE) in Escherichia coli
C.T. Huang, Yuan Ze University, Chung-Li/RC; Y.T. Horng, P.C. Soo, Tzu Chi University, Hualien/RC |
| P 7.02 |
Identification of yeast strains for the synthesis of alpha,omega-dicarboxylic acids
S. Huf, University of Stuttgart/D; W. Wagner, Fraunhofer IGB, Stuttgart/D; T. Hirth, University of Stuttgart, Fraunhofer IGB, Stuttgart/D; S. Zibek, S. Rupp, Fraunhofer IGB, Stuttgart/D |
| P 7.05 |
In vitro synthesis of poly (3- hydroxybutryate) by high density enzyme-particle: (1) Construction, expression and purification of phaB synthase in recombinant E. coli
L. Chen, Jinan University, Guangzhou/PRC; I.C. Chiang, Yuan Ze University, Taoyuan/RC; X. Huang, Jinan University, Guangzhou/PRC; J.C.W. Lan, Yuan Ze University, Taoyuan/RC |
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