Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing
With increasing temperature, biological macromolecules and nanometer-sized aggregates typically undergo complex and poorly understood reconfigurations, especially in the adsorbed state. Herein, we demonstrate the strong potential of using localized surface plasmon resonance (LSPR) sensors to address...
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sg-ntu-dr.10356-810692020-06-01T10:01:43Z Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing Oh, Eunkyul Yorulmaz, Saziye Zhdanov, Vladimir P. Lee, Haiwon Cho, Nam-Joon Jackman, Joshua Alexander School of Chemical and Biomedical Engineering School of Materials Science & Engineering Chemical and Biomedical Engineering Materials Science and Engineering With increasing temperature, biological macromolecules and nanometer-sized aggregates typically undergo complex and poorly understood reconfigurations, especially in the adsorbed state. Herein, we demonstrate the strong potential of using localized surface plasmon resonance (LSPR) sensors to address challenging questions related to this topic. By employing an LSPR-based gold nanodisk array platform, we have studied the adsorption of sub-100-nm diameter 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) lipid vesicles on titanium oxide at two temperatures, 23 and 50 °C. Inside this temperature range, DPPC lipid vesicles undergo the gel-to-fluid phase transition accompanied by membrane area expansion, while DOPC lipid vesicles remain in the fluid-phase state. To interpret the corresponding measurement results, we have derived general equations describing the effect of deformation of adsorbed vesicles on the LSPR signal. At the two temperatures, the shape of adsorbed DPPC lipid vesicles on titanium oxide remains nearly equivalent, while DOPC lipid vesicles become less deformed at higher temperature. Adsorption and rupture of DPPC lipid vesicles on silicon oxide were also studied for comparison. In contrast to the results obtained on titanium oxide, adsorbed vesicles on silicon oxide become more deformed at higher temperature. Collectively, the findings demonstrate that increasing temperature may ultimately promote, hinder, or have negligible effect on the deformation of adsorbed vesicles. The physics behind these observations is discussed, and helps to clarify the interplay of various, often hidden, factors involved in adsorption of biological macromolecules at interfaces. NMRC (Natl Medical Research Council, S’pore) 2016-06-09T04:55:20Z 2019-12-06T14:20:46Z 2016-06-09T04:55:20Z 2019-12-06T14:20:46Z 2014 Journal Article Oh, E., Jackman, J. A., Yorulmaz, S., Zhdanov, V. P., Lee, H., & Cho, N.-J. (2015). Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing. Langmuir, 31(2), 771-781. 0743-7463 https://hdl.handle.net/10356/81069 http://hdl.handle.net/10220/40646 10.1021/la504267g en Langmuir © 2014 American Chemical Society. |
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Chemical and Biomedical Engineering Materials Science and Engineering Oh, Eunkyul Yorulmaz, Saziye Zhdanov, Vladimir P. Lee, Haiwon Cho, Nam-Joon Jackman, Joshua Alexander Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing |
| description |
With increasing temperature, biological macromolecules and nanometer-sized aggregates typically undergo complex and poorly understood reconfigurations, especially in the adsorbed state. Herein, we demonstrate the strong potential of using localized surface plasmon resonance (LSPR) sensors to address challenging questions related to this topic. By employing an LSPR-based gold nanodisk array platform, we have studied the adsorption of sub-100-nm diameter 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) lipid vesicles on titanium oxide at two temperatures, 23 and 50 °C. Inside this temperature range, DPPC lipid vesicles undergo the gel-to-fluid phase transition accompanied by membrane area expansion, while DOPC lipid vesicles remain in the fluid-phase state. To interpret the corresponding measurement results, we have derived general equations describing the effect of deformation of adsorbed vesicles on the LSPR signal. At the two temperatures, the shape of adsorbed DPPC lipid vesicles on titanium oxide remains nearly equivalent, while DOPC lipid vesicles become less deformed at higher temperature. Adsorption and rupture of DPPC lipid vesicles on silicon oxide were also studied for comparison. In contrast to the results obtained on titanium oxide, adsorbed vesicles on silicon oxide become more deformed at higher temperature. Collectively, the findings demonstrate that increasing temperature may ultimately promote, hinder, or have negligible effect on the deformation of adsorbed vesicles. The physics behind these observations is discussed, and helps to clarify the interplay of various, often hidden, factors involved in adsorption of biological macromolecules at interfaces. |
| author2 |
School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Oh, Eunkyul Yorulmaz, Saziye Zhdanov, Vladimir P. Lee, Haiwon Cho, Nam-Joon Jackman, Joshua Alexander |
| format |
Article |
| author |
Oh, Eunkyul Yorulmaz, Saziye Zhdanov, Vladimir P. Lee, Haiwon Cho, Nam-Joon Jackman, Joshua Alexander |
| author_sort |
Oh, Eunkyul |
| title |
Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing |
| title_short |
Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing |
| title_full |
Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing |
| title_fullStr |
Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing |
| title_full_unstemmed |
Contribution of Temperature to Deformation of Adsorbed Vesicles Studied by Nanoplasmonic Biosensing |
| title_sort |
contribution of temperature to deformation of adsorbed vesicles studied by nanoplasmonic biosensing |
| publishDate |
2016 |
| url |
https://hdl.handle.net/10356/81069 http://hdl.handle.net/10220/40646 |
| _version_ |
1681058340535271424 |