Nanoplasmonic Ruler for Measuring Separation Distance between Supported Lipid Bilayers and Oxide Surfaces.

Unraveling the details of how supported lipid bilayers (SLBs) are coupled to oxide surfaces is experimentally challenging, and there is an outstanding need to develop highly surface-sensitive measurement strategies to determine SLB separation distances. Indeed, subtle variations in separation distance can be associated with significant differences in bilayer-substrate interaction energy. Herein, we report a nanoplasmonic ruler strategy to measure the absolute separation distance between SLBs and oxide surfaces. A localized surface plasmon resonance (LSPR) sensor was employed to track SLB formation onto titania- and silica-coated gold nanodisk arrays. To interpret measurement data, an analytical model relating the LSPR measurement response to bilayer-substrate separation distance was developed based on finite-difference time-domain (FDTD) simulations and theoretical calculations. The results indicate that there is a larger separation distance between SLBs and titania surfaces than silica surfaces, and the trend was consistent across three tested lipid compositions. We discuss these findings within the context of the interfacial forces underpinning bilayer-substrate interactions, and the nanoplasmonic ruler strategy provides the first direct experimental evidence comparing SLB separation distances on titania and silica surfaces.

[1]  S. Wiedmer,et al.  Nanoplasmonic Sensing and Capillary Electrophoresis for Fast Screening of Interactions between Phosphatidylcholine Biomembranes and Surfactants , 2018, Langmuir : the ACS journal of surfaces and colloids.

[2]  Lin Guo,et al.  Quantitative investigation on the critical thickness of the dielectric shell for metallic nanoparticles determined by the plasmon decay length , 2018, Nanotechnology.

[3]  F. Brown,et al.  Lipid diffusion in the distal and proximal leaflets of supported lipid bilayer membranes studied by single particle tracking. , 2018, The Journal of chemical physics.

[4]  G. Russo,et al.  Cholesterol affects the interaction between an ionic liquid and phospholipid vesicles. A study by differential scanning calorimetry and nanoplasmonic sensing. , 2017, Biochimica et biophysica acta. Biomembranes.

[5]  Taisuke Kojima Combined Reflectometric Interference Spectroscopy and Quartz Crystal Microbalance Detect Differential Adsorption of Lipid Vesicles with Different Phase Transition Temperatures on SiO2, TiO2, and Au Surfaces. , 2017, Analytical chemistry.

[6]  Vladimir P Zhdanov,et al.  Indirect Nanoplasmonic Sensing Platform for Monitoring Temperature-Dependent Protein Adsorption. , 2017, Analytical chemistry.

[7]  A. Neimark,et al.  Adhesion of Phospholipid Bilayers to Hydroxylated Silica: Existence of Nanometer-Thick Water Interlayers. , 2017, Langmuir : the ACS journal of surfaces and colloids.

[8]  Nam-Joon Cho,et al.  Probing the Interaction of Dielectric Nanoparticles with Supported Lipid Membrane Coatings on Nanoplasmonic Arrays , 2017, Sensors.

[9]  Nam-Joon Cho,et al.  Probing Spatial Proximity of Supported Lipid Bilayers to Silica Surfaces by Localized Surface Plasmon Resonance Sensing. , 2017, Analytical chemistry.

[10]  A. Mechler,et al.  Nanoviscosity Measurements Revealing Domain Formation in Biomimetic Membranes. , 2017, Analytical chemistry.

[11]  Giacomo Russo,et al.  Unraveling Interactions between Ionic Liquids and Phospholipid Vesicles Using Nanoplasmonic Sensing. , 2017, Langmuir : the ACS journal of surfaces and colloids.

[12]  L. Lechuga,et al.  Recent advances in nanoplasmonic biosensors: applications and lab-on-a-chip integration , 2017 .

[13]  Vladimir P Zhdanov,et al.  Influence of Divalent Cations on Deformation and Rupture of Adsorbed Lipid Vesicles. , 2016, Langmuir : the ACS journal of surfaces and colloids.

[14]  Jie He,et al.  Localized Surface Plasmon Resonance Biosensing: Current Challenges and Approaches , 2015, Sensors.

[15]  M. Stockman,et al.  Nanoplasmonic sensing and detection , 2015, Science.

[16]  Zhilei Zhao,et al.  Self-assembly formation of lipid bilayer coatings on bare aluminum oxide: overcoming the force of interfacial water. , 2015, ACS applied materials & interfaces.

[17]  Fredrik Höök,et al.  Influence of the Evanescent Field Decay Length on the Sensitivity of Plasmonic Nanodisks and Nanoholes , 2015 .

[18]  Joshua A. Jackman,et al.  Contribution of temperature to deformation of adsorbed vesicles studied by nanoplasmonic biosensing. , 2015, Langmuir : the ACS journal of surfaces and colloids.

[19]  Nam-Joon Cho,et al.  Controlling lipid membrane architecture for tunable nanoplasmonic biosensing. , 2014, Small.

[20]  Joshua A. Jackman,et al.  Nanoplasmonic biosensing for soft matter adsorption: kinetics of lipid vesicle attachment and shape deformation. , 2014, Langmuir : the ACS journal of surfaces and colloids.

[21]  N. Tufenkji,et al.  Direct detection of the gel-fluid phase transition of a single supported phospholipid bilayer using quartz crystal microbalance with dissipation monitoring. , 2014, Analytical chemistry.

[22]  M. Filler,et al.  Influence of Dielectric Anisotropy on the Absorption Properties of Localized Surface Plasmon Resonances Embedded in Si Nanowires , 2014 .

[23]  M. A. Otte,et al.  Trends and challenges of refractometric nanoplasmonic biosensors: a review. , 2014, Analytica chimica acta.

[24]  Matthew I. Hoopes,et al.  Effect of melatonin and cholesterol on the structure of DOPC and DPPC membranes. , 2013, Biochimica et biophysica acta.

[25]  Andreas B. Dahlin,et al.  Promises and challenges of nanoplasmonic devices for refractometric biosensing , 2013, Nanophotonics.

[26]  C. Langhammer,et al.  Nanoplasmonic sensing for nanomaterials science , 2012 .

[27]  N. Grigorchuk Effect of Surface Plasmon Linewidth Oscillations on Optical Properties of Metal Nanoparticle Embedded in a Dielectric Media , 2012 .

[28]  V. Zhdanov,et al.  Real time indirect nanoplasmonic in situ spectroscopy of catalyst nanoparticle sintering , 2012 .

[29]  Konstantins Jefimovs,et al.  Investigation of plasmon resonances in metal films with nanohole arrays for biosensing applications. , 2011, Small.

[30]  J. Hafner,et al.  Localized surface plasmon resonance sensors. , 2011, Chemical reviews.

[31]  O. Orwar,et al.  Molecular phospholipid films on solid supports , 2011 .

[32]  R. Bashir,et al.  Lipid bilayer coated Al2O3 nanopore sensors: towards a hybrid biological solid-state nanopore , 2011, Biomedical microdevices.

[33]  Igor Zorić,et al.  Indirect nanoplasmonic sensing: ultrasensitive experimental platform for nanomaterials science and optical nanocalorimetry. , 2010, Nano letters.

[34]  A. Alessandrini,et al.  Supported lipid bilayers on mica and silicon oxide: comparison of the main phase transition behavior. , 2010, The journal of physical chemistry. B.

[35]  Fredrik Höök,et al.  Quartz crystal microbalance with dissipation monitoring of supported lipid bilayers on various substrates , 2010, Nature Protocols.

[36]  T. Lane,et al.  Quantification of the layer of hydration of a supported lipid bilayer. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[37]  B. Kasemo,et al.  A combined nanoplasmonic and electrodeless quartz crystal microbalance setup. , 2009, The Review of scientific instruments.

[38]  J. Israelachvili,et al.  Formation of supported bilayers on silica substrates. , 2009, Langmuir : the ACS journal of surfaces and colloids.

[39]  N. Melosh,et al.  Formation and characterization of fluid lipid bilayers on alumina. , 2008, Langmuir : the ACS journal of surfaces and colloids.

[40]  T. Ujihara,et al.  Lipid bilayer membrane with atomic step structure: supported bilayer on a step-and-terrace TiO2(100) surface. , 2008, Langmuir : the ACS journal of surfaces and colloids.

[41]  L. Liz‐Marzán,et al.  Modelling the optical response of gold nanoparticles. , 2008, Chemical Society reviews.

[42]  D. Cole,et al.  Molecular Structure and Dynamics in Thin Water Films at the Silica and Graphite Surfaces , 2008 .

[43]  Jeffrey N. Anker,et al.  Biosensing with plasmonic nanosensors. , 2008, Nature materials.

[44]  Marcus Textor,et al.  Optical anisotropy of supported lipid structures probed by waveguide spectroscopy and its application to study of supported lipid bilayer formation kinetics. , 2008, Analytical chemistry.

[45]  H. Fredriksson,et al.  Hole–Mask Colloidal Lithography , 2007 .

[46]  Fredrik Höök,et al.  Supported lipid bilayer formation and lipid-membrane-mediated biorecognition reactions studied with a new nanoplasmonic sensor template. , 2007, Nano letters.

[47]  R. V. Van Duyne,et al.  Localized surface plasmon resonance spectroscopy and sensing. , 2007, Annual review of physical chemistry.

[48]  Fredrik Höök,et al.  Improving the instrumental resolution of sensors based on localized surface plasmon resonance. , 2006, Analytical chemistry.

[49]  R. Macdonald,et al.  Surface properties of dioleoyl-sn-glycerol-3-ethylphosphocholine, a cationic phosphatidylcholine transfection agent, alone and in combination with lipids or DNA. , 2006, Langmuir.

[50]  John F. Nagle,et al.  Structure of Fully Hydrated Fluid Phase Lipid Bilayers with Monounsaturated Chains , 2006, The Journal of Membrane Biology.

[51]  S. Boxer,et al.  Probing the structure of supported membranes and tethered oligonucleotides by fluorescence interference contrast microscopy. , 2005, Langmuir : the ACS journal of surfaces and colloids.

[52]  Fredrik Höök,et al.  Intact Vesicle Adsorption and Supported Biomembrane Formation from Vesicles in Solution: Influence of Surface Chemistry, Vesicle Size, Temperature, and Osmotic Pressure† , 2003 .

[53]  Erich Sackmann,et al.  Electrical properties of supported lipid bilayer membranes , 2002 .

[54]  B. Kasemo,et al.  Van der Waals Interaction during Protein Adsorption on a Solid Covered by a Thin Film , 2001 .

[55]  V. Zhdanov,et al.  Simulation of adsorption kinetics of lipid vesicles , 2000 .

[56]  U. Seifert,et al.  Adhesion of Vesicles and Membranes , 1991 .