Topographically Flat Nanoplasmonic Sensor Chips for Biosensing and Materials Science

Nugroho, Ferry Anggoro Ardy; Frost, Rickard; Antosiewicz, Tomasz J.; Fritzsche, Joachim; Langhammer, Elin; Langhammer, Christoph

doi:10.1021/acssensors.6b00612

Cited by 12 publications

(25 citation statements)

References 56 publications

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“…More recently, the concept of “indirect nanoplasmonic sensing” has become popular whereby the entire sensor surface is coated with a thin, conformal dielectric layer, oftentimes silica or titanium oxide [ 45 ]. This approach has broadly enabled the fabrication of fluidic, two-dimensional supported lipid bilayers (SLBs) on nanodisk [ 14 , 46 , 47 , 48 , 49 ] and nanohole [ 50 , 51 , 52 ] architectures, opening the door to a wide range of studies involving protein binding [ 11 , 47 , 53 , 54 , 55 ] as well as vesicle adsorption and deformation [ 56 , 57 , 58 , 59 , 60 , 61 ]. As these fabrication approaches gain traction, there has been renewed emphasis on varying the membrane composition to modulate SLB–substrate interactions (e.g., via membrane surface charge) as well as employing the nanostructured sensing platforms to study membrane interactions pertaining to various classes of molecules and nanomaterials such as amphipathic peptides [ 49 ], graphene oxide sheets [ 62 ], and ionic liquids [ 63 ].…”

Section: Introductionmentioning

confidence: 99%

Probing the Interaction of Dielectric Nanoparticles with Supported Lipid Membrane Coatings on Nanoplasmonic Arrays

Ferhan

Junren

Jackman

et al. 2017

Sensors

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The integration of supported lipid membranes with surface-based nanoplasmonic arrays provides a powerful sensing approach to investigate biointerfacial phenomena at membrane interfaces. While a growing number of lipid vesicles, protein, and nucleic acid systems have been explored with nanoplasmonic sensors, there has been only very limited investigation of the interactions between solution-phase nanomaterials and supported lipid membranes. Herein, we established a surface-based localized surface plasmon resonance (LSPR) sensing platform for probing the interaction of dielectric nanoparticles with supported lipid bilayer (SLB)-coated, plasmonic nanodisk arrays. A key emphasis was placed on controlling membrane functionality by tuning the membrane surface charge vis-à-vis lipid composition. The optical sensing properties of the bare and SLB-coated sensor surfaces were quantitatively compared, and provided an experimental approach to evaluate nanoparticle–membrane interactions across different SLB platforms. While the interaction of negatively-charged silica nanoparticles (SiNPs) with a zwitterionic SLB resulted in monotonic adsorption, a stronger interaction with a positively-charged SLB resulted in adsorption and lipid transfer from the SLB to the SiNP surface, in turn influencing the LSPR measurement responses based on the changing spatial proximity of transferred lipids relative to the sensor surface. Precoating SiNPs with bovine serum albumin (BSA) suppressed lipid transfer, resulting in monotonic adsorption onto both zwitterionic and positively-charged SLBs. Collectively, our findings contribute a quantitative understanding of how supported lipid membrane coatings influence the sensing performance of nanoplasmonic arrays, and demonstrate how the high surface sensitivity of nanoplasmonic sensors is well-suited for detecting the complex interactions between nanoparticles and lipid membranes.

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Section: Introductionmentioning

confidence: 99%

Probing the Interaction of Dielectric Nanoparticles with Supported Lipid Membrane Coatings on Nanoplasmonic Arrays

Ferhan

Junren

Jackman

et al. 2017

Sensors

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“…Protein adsorption onto metal nanoparticles can be directly measured, or a thin layer of a dielectric material can be deposited on top of the sensor surface in order to study protein adsorption onto dielectric coatings, in which case the underlying nanoparticles serve as indirect nanoplasmonic transducers. − In such sensors, the substrate surface is corrugated on a length scale that is comparable to the nanoparticle size. In a few cases, topographically flat nanoplasmonic substrates based on embedding the nanoparticle transducers in a dielectric matrix have also been reported. , In order to monitor Δλ max shifts, the optical extinction spectrum is typically acquired by ultraviolet–visible spectroscopic measurements in transmission mode, and the measurement readout is ensemble-averaged across a large number of nanoparticles within the spot of incident light. Compared to conventional optical sensor techniques (e.g., SPR, ellipsometry, reflectometry), LSPR-based nanoplasmonic sensors are technically simple to operate and have smaller probing volumes that confer lower sensitivity to bulk refractive index changes such as minor temperature variations .…”

mentioning

confidence: 99%

“…In a few cases, topographically flat nanoplasmonic substrates based on embedding the nanoparticle transducers in a dielectric matrix have also been reported. 25,26 In order to monitor Δλ max shifts, the optical extinction spectrum is typically acquired by ultraviolet−visible spectroscopic measurements in transmission mode, and the measurement readout is ensemble-averaged across a large number of nanoparticles within the spot of incident light. Compared to conventional optical sensor techniques (e.g., SPR, ellipsometry, reflectometry), LSPR-based nanoplasmonic sensors are technically simple to operate and have smaller probing volumes that confer lower sensitivity to bulk refractive index changes such as minor temperature variations.…”

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confidence: 99%

Indirect Nanoplasmonic Sensing Platform for Monitoring Temperature-Dependent Protein Adsorption

et al. 2017

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The development of highly surface-sensitive measurement approaches to monitor protein adsorption across different temperatures would advance understanding of how thermally activated processes contribute to the denaturation of adsorbed proteins. Herein, we established an indirect nanoplasmonic sensing approach to monitor the temperature-dependent adsorption and denaturation of bovine serum albumin (BSA) protein onto a silica-coated array of plasmonic gold nanodisks. A theoretical model was developed to explain how the denaturation of an individual, adsorbed protein molecule influences the localized surface plasmon resonance (LSPR) measurement response and provided an analytical framework to estimate the effect of temperature-dependent protein denaturation on the corresponding adsorption kinetics. The sensing performance of this measurement platform was also characterized across the tested range of temperatures. With increasing temperature (up to 50 °C), it was observed that adsorbed proteins undergo greater denaturation. Circular dichroism spectroscopy and dynamic light scattering experiments verified that individual BSA monomers in bulk solution had increasingly lower conformational stability at higher temperatures within this range, which correlated with the extent of denaturation in the adsorbed state. At higher temperatures, distinct kinetic profiles arising from multilayer/aggregate formation on the sensor surface were also detected. Taken together, our findings identify that the high surface sensitivity and temperature stability of LSPR sensors make them broadly useful analytical tools for monitoring thermally activated biomacromolecular interaction processes.

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“…Recent progress in INPS have witnessed the construction of topographically at nanoplasmonic sensors whereby the Au nanodisk transducers are embedded within the support substrate and coated with a at layer of oxide material 36,37 (Fig. 4A).…”

Section: Indirect Nanoplasmonic Sensingmentioning

confidence: 99%

“…The three-dimensional sketch shows the three "layers" of the device, i.e., the wells in the fused silica substrate, the Au nanodisks grown inside the wells, and the topographically flat SiO 2 capping layer. Reproduced with permission from ref 36…”

mentioning

confidence: 99%

Biologically interfaced nanoplasmonic sensors

et al. 2020

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Topographically Flat Nanoplasmonic Sensor Chips for Biosensing and Materials Science

Cited by 12 publications

References 56 publications

Probing the Interaction of Dielectric Nanoparticles with Supported Lipid Membrane Coatings on Nanoplasmonic Arrays

Probing the Interaction of Dielectric Nanoparticles with Supported Lipid Membrane Coatings on Nanoplasmonic Arrays

Indirect Nanoplasmonic Sensing Platform for Monitoring Temperature-Dependent Protein Adsorption

Biologically interfaced nanoplasmonic sensors

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