Parallel mapping of optical near-field interactions by molecular motor-driven quantum dots

Groß, Heiko; Heil, Hannah S.; Ehrig, Jens; Schwarz, Friedrich W.; Hecht, Bert; Diez, Stefan

doi:10.1038/s41565-018-0123-1

Cited by 16 publications

(16 citation statements)

References 34 publications

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“…With a completely different approach, using molecular motors or microfluidic chambers allows having deterministic information about the position of a single emitter in close proximity of a nanostructure [129,130]. Such approaches, that benefit from an a priori knowledge of the emitter's position, will be described in Section 4.4.…”

Section: Intensity-based Experimentsmentioning

confidence: 99%

“…The results [130] show mean fluorophore brightness Ī and the quantum dot decay rate as function of position next to a plasmonic nanowire (photons are collected from the nanowire ends). The approach of Groß et al [129] leverages the fact that quantum dots constrained to 1D trajectories, defined by randomly deposited microtubules, can be accurately tracked. The sample in this work consisted of 1D slits in a metal film, illuminated from below and imaged from above.…”

Section: Overcoming Localization-artifactsmentioning

confidence: 99%

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Super-resolution imaging: when biophysics meets nanophotonics

et al. 2021

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Probing light–matter interaction at the nanometer scale is one of the most fascinating topics of modern optics. Its importance is underlined by the large span of fields in which such accurate knowledge of light–matter interaction is needed, namely nanophotonics, quantum electrodynamics, atomic physics, biosensing, quantum computing and many more. Increasing innovations in the field of microscopy in the last decade have pushed the ability of observing such phenomena across multiple length scales, from micrometers to nanometers. In bioimaging, the advent of super-resolution single-molecule localization microscopy (SMLM) has opened a completely new perspective for the study and understanding of molecular mechanisms, with unprecedented resolution, which take place inside the cell. Since then, the field of SMLM has been continuously improving, shifting from an initial drive for pushing technological limitations to the acquisition of new knowledge. Interestingly, such developments have become also of great interest for the study of light–matter interaction in nanostructured materials, either dielectric, metallic, or hybrid metallic-dielectric. The purpose of this review is to summarize the recent advances in the field of nanophotonics that have leveraged SMLM, and conversely to show how some concepts commonly used in nanophotonics can benefit the development of new microscopy techniques for biophysics. To this aim, we will first introduce the basic concepts of SMLM and the observables that can be measured. Then, we will link them with their corresponding physical quantities of interest in biophysics and nanophotonics and we will describe state-of-the-art experiments that apply SMLM to nanophotonics. The problem of localization artifacts due to the interaction of the fluorescent emitter with a resonant medium and possible solutions will be also discussed. Then, we will show how the interaction of fluorescent emitters with plasmonic structures can be successfully employed in biology for cell profiling and membrane organization studies. We present an outlook on emerging research directions enabled by the synergy of localization microscopy and nanophotonics.

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Section: Intensity-based Experimentsmentioning

confidence: 99%

Section: Overcoming Localization-artifactsmentioning

confidence: 99%

Super-resolution imaging: when biophysics meets nanophotonics

et al. 2021

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“…[ 1–4 ] Microtubule mechanical properties (Young's modulus ≈1 GPa; persistence length 1–10 mm [ 5–8 ] ) and ability to generate forces of up to 5 pN due to polymerization [ 9 ] are key features that enable such roles, and have led to utilization within engineered nano‐ and microelectromechanical systems (NEMS/MEMS). In tandem with molecular motors, microtubules have been employed within high efficiency rectifiers, [ 10,11 ] biosensors, [ 12–14 ] direction‐specific sorters and transporters, [ 15–18 ] force‐meters, [ 19 ] as nanopatterning agents, [ 20–22 ] and even for parallel nanocomputing. [ 23 ] Interestingly, in addition to such mechanical roles, microtubule‐based systems can also exploit the highly negative charge (47 e − ) that tubulin dimers exhibit at physiological pH values.…”

Section: Figurementioning

confidence: 99%

Revealing and Attenuating the Electrostatic Properties of Tubulin and Its Polymers

Kalra

Patel

Eakins

et al. 2020

Small

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Tubulin is an electrostatically negative protein that forms cylindrical polymers termed microtubules, which are crucial for a variety of intracellular roles. Exploiting the electrostatic behavior of tubulin and microtubules within functional microfluidic and optoelectronic devices is limited due to the lack of understanding of tubulin behavior as a function of solvent composition. This work displays the tunability of tubulin surface charge using dimethyl sulfoxide (DMSO) for the first time. Increasing the DMSO volume fractions leads to the lowering of tubulin's negative surface charge, eventually causing it to become positive in solutions >80% DMSO. As determined by electrophoretic mobility measurements, this change in surface charge is directionally reversible, i.e., permitting control between −1.5 and + 0.2 cm2 (V s)−1. When usually negative microtubules are exposed to these conditions, the positively charged tubulin forms tubulin sheets and aggregates, as revealed by an electrophoretic transport assay. Fluorescence‐based experiments also indicate that tubulin sheets and aggregates colocalize with negatively charged g‐C3N4 sheets while microtubules do not, further verifying the presence of a positive surface charge. This study illustrates that tubulin and its polymers, in addition to being mechanically robust, are also electrically tunable.

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“…The hybrid and isolated nature of these structures show promise in lab-on-a-chip devices, as electrical interfaces with cells, and for generating electromagnetic fields at the micron scale, to name a few. The size and hybrid nature of these structures are particularly advantageous for the precise mapping of optical near-field interactions between nanostructured materials and optical emitters in biosensing, light harvesting and quantum communication applications (Groß et al, 2018). Additionally, researchers will continue to use them as a foundational technology behind the single-molecule biophysical scientific enterprise.…”

Section: Structure Type: Hybrid Isolated Structuresmentioning

confidence: 99%

From isolated structures to continuous networks: A categorization of cytoskeleton‐based motile engineered biological microstructures

Andorfer

Alper

2019

WIREs Nanomed Nanobiotechnol

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As technology at the small scale is advancing, motile engineered microstructures are becoming useful in drug delivery, biomedicine, and lab-on-a-chip devices. However, traditional engineering methods and materials can be inefficient or functionally inadequate for small-scale applications. Increasingly, researchers are turning to the biology of the cytoskeleton, including microtubules, actin filaments, kinesins, dyneins, myosins, and associated proteins, for both inspiration and solutions. They are engineering structures with components that range from being entirely biological to being entirely synthetic mimics of biology and on scales that range from isotropic continuous networks to single isolated structures. Motile biological microstructures trace their origins from the development of assays used to study the cytoskeleton to the array of structures currently available today. We define 12 types of motile biological microstructures, based on four categories: entirely biological, modular, hybrid, and synthetic, and three scales: networks, clusters, and isolated structures. We highlight some key examples, the unique functionalities, and the potential applications of each microstructure type, and we summarize the quantitative models that enable engineering them. By categorizing the diversity of motile biological microstructures in this way, we aim to establish a framework to classify these structures, define the gaps in current research, and spur ideas to fill those gaps. active matter, biomimicry, biomolecular motor protein, cytoskeletal networks, microscale devicesThe challenges of biomedical research and development often lie at the interface between the medical intervention and the biological material. The relevant scale of this interface is on the order of nanometers (molecular scale) or smaller for drug developers, and the relevant scale of this interface is on the order of millimeters (tissue scale) or larger for biomedical device designers. However, there is an emerging class of biomedical solutions with scale on the order of micrometers (cellular scale).

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Parallel mapping of optical near-field interactions by molecular motor-driven quantum dots

Cited by 16 publications

References 34 publications

Super-resolution imaging: when biophysics meets nanophotonics

Super-resolution imaging: when biophysics meets nanophotonics

Revealing and Attenuating the Electrostatic Properties of Tubulin and Its Polymers

From isolated structures to continuous networks: A categorization of cytoskeleton‐based motile engineered biological microstructures

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