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Liquid Crystals Volume 40, 2013 - Issue 1
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Original Articles

Dynamic imaging of enzymatic events at polyelectrolyte-disrupted phospholipid membranes using liquid crystals

Qiong-Zheng Hu Department of Chemistry, Gachon University, Seongnam-Si, South Korea
,
Hyunkyung Shin Department of Mathematics and Information, Gachon University, Seongnam-Si, South Korea
&
Chang-Hyun Jang Department of Chemistry, Gachon University, Seongnam-Si, South KoreaCorrespondence[email protected]
Pages 106-111 | Received 30 May 2012, Accepted 20 Sep 2012, Published online: 10 Oct 2012

References

  • Brogden , KA. 2005 . Antimicrobial peptides: pore formers or metabolic inhibitors in bacteria? . Nat Rev Microbiol. , 3 : 238 – 250 .
  • Gidalevitz , D , Ishitsuka , Y , Muresan , AS , Konovalov , O , Waring , AJ , Lehrer , RI and Lee , KYC. 2003 . Interaction of antimicrobial peptide protegrin with biomembranes . Proc Natl Acad Sci USA. , 100 : 6302 – 6307 .
  • Nagy , IB , Alsina , MA , Haro , I , Reig , F and Hudecz , F. 2000 . Phospholipid-model membrane interactions with branched polypeptide conjugates of a hepatitis A virus peptide epitope . Bioconjug Chem. , 11 : 30 – 38 .
  • Baumann , P , Tanner , P , Onaca , O and Palivan , CG. 2011 . Bio-decorated polymer membranes: a new approach in diagnostics and therapeutics . Polymers , 3 : 173 – 192 .
  • Wilkop , T , Xu , D and Cheng , Q. 2007 . Characterization of pore formation by streptolysin O on supported lipid membranes by impedance spectroscopy and surface plasmon resonance spectroscopy . Langmuir. , 23 : 1403 – 1409 .
  • Baksh , MM , Jaros , M and Groves , JT. 2004 . Detection of molecular interactions at membrane surfaces through colloid phase transitions . Nature. , 427 : 139 – 141 .
  • Brake , JM , Daschner , MK , Luk , YY and Abbott , NL. 2003 . Biomolecular interactions at phospholipid-decorated surfaces of liquid crystals . Science. , 320 : 2094 – 2097 .
  • Cremer , PS. 2004 . Label-free detection becomes crystal clear . Nat Biotechnol. , 22 : 172 – 173 .
  • Wise , AR , Nye , JA and Groves , JT. 2008 . Discrete arrays of liquid-crystal-supported proteolipid monolayers as phantom cell surfaces . ChemPhysChem. , 9 : 1688 – 1692 .
  • Luk , YY , Tingey , ML , Hall , DJ , Israel , BA , Murphy , CJ , Bertics , PJ and Abbott , NL. 2003 . Using liquid crystals to amplify protein-receptor interactions: design of surfaces with nanometer-scale topography that present histidine-tagged protein receptors . Langmuir. , 19 : 1671 – 1680 .
  • Hartono , D , Xue , CY , Yang , KL and Lanry Yung , LY. 2009 . Decorating liquid crystal surfaces with proteins for real-time detection of specific protein–protein binding . Adv Funct Mater. , 19 : 3574 – 3579 .
  • Price , AD and Schwartz , DK. 2008 . DNA hybridization-induced reorientation of liquid crystal anchoring at the nematic liquid crystal/aqueous interface . J Am Chem Soc. , 130 : 8188 – 8194 .
  • Kolusheva , S , Kafri , R , Katz , M and Jelinek , R. 2001 . Rapid colorimetric detection of antibody-epitope recognition at a biomimetic membrane interface . J Am Chem Soc. , 123 : 417 – 422 .
  • Park , JS and Abbott , NL. 2008 . Ordering transitions in thermotropic liquid crystals induced by the interfacial assembly and enzymatic processing of oligopeptide amphiphiles . Adv Mater. , 20 : 1185 – 1190 .
  • Brake , JM , Daschner , MK and Abbott , NL. 2005 . Formation and characterization of phospholipid monolayers spontaneously assembled at interfaces between aqueous phases and thermotropic liquid crystals . Langmuir. , 21 : 2218 – 2228 .
  • Park , JS , Teren , S , Tepp , WH , Beebe , D , Johnson , EA and Abbott , NL. 2006 . Formation of oligopeptide-based polymeric membranes at interfaces . Chem Mater. , 18 : 6147 – 6151 .
  • Hussain , A , Pina , AS and Roque , ACA. 2009 . Bio-recognition and detection using liquid crystals . Biosens Bioelectron. , 25 : 1 – 8 .
  • Hartono , D , Qin , WJ , Yang , KL and Lanry Yung , LY. 2009 . Imaging the disruption of phospholipid monolayer by protein-coated nanoparticles using ordering transitions of liquid crystals . Biomaterials. , 30 : 843 – 849 .
  • Sivakumar , S , Wark , KL , Gupta , JK , Abbott , NL and Caruso , F. 2009 . Liquid crystal emulsions as the basis of biological sensors for the optical detection of bacteria and viruses . Adv Funct Mater. , 19 : 2260 – 2265 .
  • Tan , H , Yang , S , Shen , G , Yu , R and Wu , Z. 2010 . Signal-enhanced liquid-crystal DNA biosensors based on enzymatic metal deposition . Angew Chem Int Edit. , 122 : 8790 – 8793 .
  • Lin , IH , Miller , DS , Bertics , PJ , Murphy , CJ , de Pablo , JJ and Abbott , NL. 2011 . Endotoxin-induced structural transformations in liquid crystalline droplets . Science. , 332 : 1297 – 1300 .
  • Hu , QZ and Jang , CH. 2011 . Orientational behaviour of ultraviolet-tailored 4-cyano-4’-pentylbiphenyl at the aqueous/liquid crystal interface . Liq Cryst. , 38 : 1209 – 1216 .
  • Wang , PH , Yu , JH , Zhao , YB , Li , ZJ and Li , GQ. 2011 . A novel liquid crystal-based sensor for the real-time identification of organophosphonate vapors . Sens Actuators B. , 160 : 929 – 935 .
  • Chen , CH and Yang , K.L. 2012 . Liquid crystal-based immunoassays for detecting hepatitis B antibody . Anal Biochem. , 42 : 321 – 323 .
  • Tan , LN , Orler , VJ and Abbott , NL. 2012 . Ordering transitions triggered by specific binding of vesicles to protein-decorated interfaces of thermotropic liquid crystals . Langmuir. , 28 : 6364 – 6376 .
  • Hu , QZ and Jang , CH. 2012 . Using liquid crystals to report molecular interactions between cationic antimicrobial peptides and lipid membranes . Analyst. , 137 : 567 – 570 .
  • Hu , QZ and Jang , CH. 2012 . Imaging trypsin activity through changes in the orientation of liquid crystals coupled to the interactions between a polyelectrolyte and a phospholipid layer . ACS Appl Mater Interfaces. , 4 : 1791 – 1795 .
  • Margot , A , Flaschel , E and Renken , A. 1997 . Empirical kinetic models for tryptic whey-protein hydrolysis . Process Biochem. , 32 : 217 – 223 .

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