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W2072552158 endingPage "6477" @default.
W2072552158 startingPage "6471" @default.
W2072552158 abstract "A surface sensitive second order nonlinear optical technique, sum frequency generation vibrational spectroscopy, was applied to study peptide orientation on polymer surfaces, supplemented by a linear vibrational spectroscopy, attenuated total reflectance Fourier transform infrared spectroscopy. Using the antimicrobial peptide Cecropin P1 as a model system, we have quantitatively demonstrated that chemically immobilized peptides on polymers adopt a more ordered orientation than less tightly bound physically adsorbed peptides. These differences were also observed in different chemical environments, for example, air versus water. Although numerous studies have reported a direct correlation between the choice of immobilization method and the performance of an attached biological molecule, the lack of direct biomolecular structure and orientation data has made it difficult to elucidate the relationship between structure, orientation, and function at a surface. In this work, we directly studied the effect of chemical immobilization method on biomolecular orientation/ordering, an important step for future studies of biomolecular activity. The methods for orientation analysis described within are also of relevance to understanding biosensors, biocompatibility, marine-antifouling, membrane protein functions, and antimicrobial peptide activities." @default.
W2072552158 created "2016-06-24" @default.
W2072552158 creator A5024040295 @default.
W2072552158 creator A5029388040 @default.
W2072552158 creator A5043124433 @default.
W2072552158 creator A5047855284 @default.
W2072552158 creator A5054123780 @default.
W2072552158 date "2009-12-04" @default.
W2072552158 modified "2023-09-27" @default.
W2072552158 title "Orientation Difference of Chemically Immobilized and Physically Adsorbed Biological Molecules on Polymers Detected at the Solid/Liquid Interfaces in Situ" @default.
W2072552158 cites W1554521817 @default.
W2072552158 cites W1970004456 @default.
W2072552158 cites W1979723206 @default.
W2072552158 cites W1980656139 @default.
W2072552158 cites W1985941691 @default.
W2072552158 cites W1986000353 @default.
W2072552158 cites W1986001588 @default.
W2072552158 cites W1986502138 @default.
W2072552158 cites W1987176498 @default.
W2072552158 cites W1988589833 @default.
W2072552158 cites W1990251640 @default.
W2072552158 cites W1992024262 @default.
W2072552158 cites W1992958095 @default.
W2072552158 cites W1997502624 @default.
W2072552158 cites W1998622466 @default.
W2072552158 cites W1999651381 @default.
W2072552158 cites W2001784720 @default.
W2072552158 cites W2002216556 @default.
W2072552158 cites W2007699797 @default.
W2072552158 cites W2008577210 @default.
W2072552158 cites W2011833640 @default.
W2072552158 cites W2013896356 @default.
W2072552158 cites W2015755767 @default.
W2072552158 cites W2017415483 @default.
W2072552158 cites W2017805495 @default.
W2072552158 cites W2021246523 @default.
W2072552158 cites W2024707673 @default.
W2072552158 cites W2025421485 @default.
W2072552158 cites W2032736963 @default.
W2072552158 cites W2034337706 @default.
W2072552158 cites W2035612881 @default.
W2072552158 cites W2037019009 @default.
W2072552158 cites W2037855380 @default.
W2072552158 cites W2037904817 @default.
W2072552158 cites W2040211368 @default.
W2072552158 cites W2040498942 @default.
W2072552158 cites W2044284129 @default.
W2072552158 cites W2045111209 @default.
W2072552158 cites W2045354562 @default.
W2072552158 cites W2047835003 @default.
W2072552158 cites W2051290691 @default.
W2072552158 cites W2052483779 @default.
W2072552158 cites W2055465627 @default.
W2072552158 cites W2056154520 @default.
W2072552158 cites W2056976674 @default.
W2072552158 cites W2059939467 @default.
W2072552158 cites W2062284931 @default.
W2072552158 cites W2064133581 @default.
W2072552158 cites W2066103755 @default.
W2072552158 cites W2066512277 @default.
W2072552158 cites W2067821192 @default.
W2072552158 cites W2073454318 @default.
W2072552158 cites W2074423542 @default.
W2072552158 cites W2075190292 @default.
W2072552158 cites W2077815718 @default.
W2072552158 cites W2078374046 @default.
W2072552158 cites W2079468421 @default.
W2072552158 cites W2080545692 @default.
W2072552158 cites W2082486318 @default.
W2072552158 cites W2087569555 @default.
W2072552158 cites W2089231026 @default.
W2072552158 cites W2089738031 @default.
W2072552158 cites W2092598726 @default.
W2072552158 cites W2093374359 @default.
W2072552158 cites W2104224344 @default.
W2072552158 cites W2113018925 @default.
W2072552158 cites W2115024294 @default.
W2072552158 cites W2119200410 @default.
W2072552158 cites W2120893753 @default.
W2072552158 cites W2130313059 @default.
W2072552158 cites W2130974803 @default.
W2072552158 cites W2137419733 @default.
W2072552158 cites W2137458512 @default.
W2072552158 cites W2144423928 @default.
W2072552158 cites W2158789628 @default.
W2072552158 cites W2159976263 @default.
W2072552158 cites W2160864796 @default.
W2072552158 cites W221965625 @default.
W2072552158 cites W4233751197 @default.
W2072552158 cites W4234422402 @default.
W2072552158 cites W4235455886 @default.
W2072552158 cites W4247666721 @default.
W2072552158 doi "https://doi.org/10.1021/la903932w" @default.
W2072552158 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/2860701" @default.
W2072552158 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/19961170" @default.
W2072552158 hasPublicationYear "2009" @default.
W2072552158 type Work @default.
W2072552158 sameAs 2072552158 @default.