Optical Penetration of Shape-Controlled Metallic Nanosensors across Membrane Barriers

Da, Ancheng; Chu, Yanan; Krach, J; Liu, Yunbo; Park, Younggeun; Lee, Somin Eunice

doi:10.3390/s23052824

Cited by 3 publications

(2 citation statements)

References 60 publications

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“…The size of the elliptical Airy pattern would be limited by the diffraction limit; however, we anticipate that the ellipticity and the intensity of the elliptical Airy pattern would vary due to the dependence between the scattered field amplitude and the scattering cross-section of the target. As a model candidate of an anisotropic − nanostructured target to validate the fundamental reason that we can see the ellipse Airy pattern, we simulated the scattered electric field pattern of gold nanorods (Figure a). Here, we acquired the nanostructural information from the ellipse Airy pattern by phase-intensity and phase-ellipticity.…”

Section: Resultsmentioning

confidence: 99%

Interferometric Phase Intensity Nanoscopy (iPINE), Revealing Nanostructural Features, Resolves Proximal Nanometer Objects below the Diffraction Limit: Implications in Long-Time Super-Resolution of Biological Dynamics

Cui,

Kim,

et al. 2024

ACS Appl. Nano Mater.

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The ability to spatially and temporally map nanoscale environments in situ over extended time scales would be transformative for biology, biomedicine, and bioengineering. All nanometer objects, from nanoparticles down to single proteins, scatter light. Interferometric scattering stands as a powerful tool, offering ultrasensitivity and resolution vital for visualizing nanoscale entities. Interferometric scattering from an individual nanoparticle down to an individual protein has been detected; however, resolving adjacent nanometer objects with interferometric scattering has not yet been demonstrated. In this work, we present interferometric phase intensity nanoscopy (iPINE) to resolve adjacent nanometer objects with interferometric scattering. We demonstrate that multiphase and sensitivity of iPINE reveal ellipse Airy patterns correlated with nanostructural features. We show that eliminating background fluctuation by employing circularly polarized illumination in iPINE is essential to separate proximal nanometer objects below the diffraction limit. We envision iPINE for resolving a variety of adjacent nanometer objects from nanoparticles down to proximal proteins in situ over extended time periods for a wide range of applications in biology, biomedicine, and bioengineering. We expect iPINE to be especially important in applications of biological dynamics that require extended observation times.

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Section: Resultsmentioning

confidence: 99%

Interferometric Phase Intensity Nanoscopy (iPINE), Revealing Nanostructural Features, Resolves Proximal Nanometer Objects below the Diffraction Limit: Implications in Long-Time Super-Resolution of Biological Dynamics

Cui,

Kim,

et al. 2024

ACS Appl. Nano Mater.

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“…In particular, recently, significant efforts have been demonstrated in the incorporation of localized surface plasmon resonance (LSPR) nanostructures into SODIS. ,, Photothermal effect in the plasmonic nanostructure has been demonstrated as a potentially promising approach for SODIS since it allows the highly focused collection of sunlight and the straightforward energy conversion into heat . According to the plasmon decay mechanism, the photothermal effect in the LSPR nanostructure stems from the amplified movement of the conduction electrons, − and this results in the frequency of collisions with the lattice atoms. ,,, This lattice–lattice vibration in the nanostructure leads to the photothermal effect. ,− The generated heat power therefore directly relies on the light absorption which is a function of shape, size, and composition of the plasmonic nanostructure, especially with sub-nano-/nano-features. Researchers have investigated a variety of plasmonic nanostructures, including colloidal nanoparticles, a nanostructure-deposited substrate, a nanostructured packed bed, and batch reactors, to obtain the greatly improved photothermal effect. ,,− However, due to the lack of precise control over nano-features, such designs are frequently associated with difficulties in achieving highly efficient energy conversion processes.…”

Section: Introductionmentioning

confidence: 99%

Integrated Plasmonic Gold Nanoparticle Dimer Array for Sustainable Solar Water Disinfection

Krueger

Graves

Chu

et al. 2023

ACS Appl. Nano Mater.

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Plasmonic nanostructures, functioning as nanoantenna reactors to highly focus light and efficiently convert it into thermal/chemical energy, have a significant potential for sustainable solar water disinfection (SODIS). A high-density plasmonic nanogap-based reactor array opens a way of maximizing the photothermal effect, but achieving uniformity and large density in such a technology while scaling up remains challenging. In this study, we provide an integrative plasmonic dimer array (hPDA) that is uniform and has high density ensuring significantly enhanced SODIS performance. The hPDA is constructed by a combined fabrication of the self-assembled monolayer and block copolymer lithography approaches. This combination leads to a twodimensional hexagonal array of the Au dimer structures consisting of a 1.3 nm nanogap. The uniformity and high density of nanogaps of the hPDA result in the physically and optically stabilized dimer array, which allows strong light focusing and a rapid and highly efficient harvesting of photothermal energy in the visible region. Finally, the integrated hPDA with an optofluidic reactor enables 5-fold enhanced Escherichia coli (E. coli) disinfection. We anticipate that the hPDA will be useful in the scalable sustainable energy and environmental process that converts solar energy.

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Phase intensity nanoscope (PINE) opens long-time investigation windows of living matter

Cui

Liu

et al. 2023

Nat Commun

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Fundamental to all living organisms and living soft matter are emergent processes in which the reorganization of individual constituents at the nanoscale drives group-level movements and shape changes at the macroscale over time. However, light-induced degradation of fluorophores, photobleaching, is a significant problem in extended bioimaging in life science. Here, we report opening a long-time investigation window by nonbleaching phase intensity nanoscope: PINE. We accomplish phase-intensity separation such that nanoprobe distributions are distinguished by an integrated phase-intensity multilayer thin film (polyvinyl alcohol/liquid crystal). We overcame a physical limit to resolve sub-10 nm cellular architectures, and achieve the first dynamic imaging of nanoscopic reorganization over 250 h using PINE. We discover nanoscopic rearrangements synchronized with the emergence of group-level movements and shape changes at the macroscale according to a set of interaction rules with importance in cellular and soft matter reorganization, self-organization, and pattern formation.

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Optical Penetration of Shape-Controlled Metallic Nanosensors across Membrane Barriers

Cited by 3 publications

References 60 publications

Interferometric Phase Intensity Nanoscopy (iPINE), Revealing Nanostructural Features, Resolves Proximal Nanometer Objects below the Diffraction Limit: Implications in Long-Time Super-Resolution of Biological Dynamics

Interferometric Phase Intensity Nanoscopy (iPINE), Revealing Nanostructural Features, Resolves Proximal Nanometer Objects below the Diffraction Limit: Implications in Long-Time Super-Resolution of Biological Dynamics

Integrated Plasmonic Gold Nanoparticle Dimer Array for Sustainable Solar Water Disinfection

Phase intensity nanoscope (PINE) opens long-time investigation windows of living matter

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