Trajectory angle determination in one dimensional single molecule tracking data by orthogonal regression analysis

Tran-Ba, Khanh-Hoa; Everett, Thomas A.; Ito, Takashi; Higgins, Daniel A.

doi:10.1039/c0cp01581d

Cited by 37 publications

(117 citation statements)

References 49 publications

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“…These materials offer 1D trajectories (such as in Figure 4). Recent investigations of MPS (71,(91)(92)(93)(94)(95) provide numerous examples, but similar results have also been obtained from phase-separated BCPs (90,102), MCPs (88), and LCs (82).…”

Section: Wide-field Video Microscopy: Anisotropic Single-molecule Trasupporting

confidence: 52%

“…Immobile molecules produced a U-shaped distribution owing to Step angle (°) When the diffusive step angles are measured relative to a fixed direction, these same data can be used both to detect 1D diffusion and to determine the average direction of the 1D motions. Tran Ba et al (93) employed such an analysis for initial assessment of molecular motions in CTABfilled MPS films (Figure 7a,b). Unfortunately, such determinations are of limited utility because the localization precision and single-frame step size are frequently of similar magnitude, yielding relatively broad step-angle distributions.…”

Section: Assessment Of Mass Transport Anisotropy From Step Directionmentioning

confidence: 99%

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Single-Molecule Investigations of Morphology and Mass Transport Dynamics in Nanostructured Materials

Higgins

Park

Tran-Ba

et al. 2015

Annual Rev. Anal. Chem.

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Nanostructured materials such as mesoporous metal oxides and phase-separated block copolymers form the basis for new monolith, membrane, and thin film technologies having applications in energy storage, chemical catalysis, and separations. Mass transport plays an integral role in governing the application-specific performance characteristics of many such materials. The majority of methods employed in their characterization provide only ensemble data, often masking the nanoscale, molecular-level details of materials morphology and mass transport. Single-molecule fluorescence methods offer direct routes to probing these characteristics on a single-molecule/single-nanostructure basis. This article provides a review of single-molecule studies focused on measurements of anisotropic diffusion, adsorption, partitioning, and confinement in nanostructured materials. Experimental methods covered include confocal and wide-field fluorescence microscopy. The results obtained promise to deepen our understanding of mass transport mechanisms in nanostructures, thus aiding in the realization of advanced materials systems.

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Section: Wide-field Video Microscopy: Anisotropic Single-molecule Trasupporting

confidence: 52%

Section: Assessment Of Mass Transport Anisotropy From Step Directionmentioning

confidence: 99%

Single-Molecule Investigations of Morphology and Mass Transport Dynamics in Nanostructured Materials

Higgins

Park

Tran-Ba

et al. 2015

Annual Rev. Anal. Chem.

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“…29,32,48,49,51 Such assessments require the accurate measurement of the inplane orientations of 1D trajectories. Therefore, trajectory angle accuracy also represents an important parameter upon which to judge the efficacy of TPG tracking.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…While some of the aforementioned methods have been applied in studies of diffusion in 1D nanostructured materials, 29,32,48,49 they are not well suited to tracking strongly anisotropic motions. Most 1D SMT studies to date have employed cost-functional methods with varying success.…”

mentioning

confidence: 99%

Trajectory-Profile-Guided Single Molecule Tracking for Assignment of One-Dimensional Diffusion Trajectories

et al. 2014

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A variety of algorithms exist for optical single molecule tracking in two and three dimensions. One general class of algorithms employs cost-functionals to link the individual fluorescent spots, produced by a molecule in sequential video frames, into trajectories. This method has also been used to track one-dimensional (1D) molecular motions for relatively low diffusion rates (i.e., D < 1 μm(2)/s). At high diffusion rates, the cost-functional approach often fails to accurately reproduce 1D trajectories, particularly when the molecules are closely spaced. In this paper, we present a new algorithm called trajectory-profile-guided (TPG) tracking that is designed specifically for 1D trajectories. TPG tracking involves an initial search for one-dimensionally aligned fluorescent spots (i.e., candidate molecules). Qualifying candidates are subsequently identified and linked into trajectories based on several criteria. We test the TPG algorithm's accuracy and precision against cost-functional based tracking using both simulated and experimental video data. The results show that TPG tracking more accurately reproduces the actual 1D trajectories, particularly at higher diffusion rates. TPG tracking is also shown to produce longer trajectories and more accurate estimates of trajectory aspect ratios (i.e., their dimensionality), molecular diffusion coefficients, and order parameters for aligned 1D trajectories over a wide range of diffusion coefficients.

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“…11,44,47 Figure 3 provides representative trajectory data obtained under common SMT conditions. In these particular data, the angle of a single step can only be determined to within ∼±26°.…”

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confidence: 99%

Following Single Molecules to a Better Understanding of Self-Assembled One-Dimensional Nanostructures

Higgins

Tran-Ba

Ito

2013

J. Phys. Chem. Lett.

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Single-molecule tracking (SMT) methods are now being employed to probe the morphologies and mass-transport characteristics of self-assembled one-dimensional (1D) nanostructures. Such nanostructures are found in surfactant-templated mesoporous metal oxides, phaseseparated block copolymers, and lyotropic liquid-crystal mesophases. This Perspective begins with a review of investigations in which SMT methods have been employed for in situ visualization of 1D nanostructures and their ability to guide and support 1D diffusion of fluorescent probe molecules. New orthogonal regression methods for the quantitative characterization of 1D nanostructure alignment and order are subsequently discussed. Recent investigations in which the confined orientational motions of single molecules are probed by single-molecule emission polarization measurements are highlighted. These data are used to access high-precision estimates of the effective lateral nanostructure dimensions. The results reveal the important role played by nanoconfined solvents and soft material nanostructures in restricting probe molecule motions. M aterials incorporating ordered, oriented 1D nanostructures have myriad potential applications as membranes and monoliths for use in chemical sensing, catalysis, separations, batteries, and fuel cells. 1,2 Interest in these materials arises in part because both nanostructure size and local chemical composition can be controlled to achieve chemical selectivity. For the purposes of this Perspective, relevant materials include both organic and inorganic assemblies such as lyotropic liquid-crystal mesophases, 3,4 surfactant-templated mesoporous metal oxides, 1,5−14 and phase-separated block copolymers. 2,15,16 Before any of these can be employed in commercial devices, much remains to be learned about the local alignment, organization, continuity, and accessible internal dimensions of their 1D nanostructures. This Perspective highlights recent investigations of these attributes by in situ single-molecule tracking (SMT) methods.One-dimensional nanostructures are commonly investigated by small-angle X-ray and neutron scattering (SAXS and SANS), scanning and transmission electron microscopy (SEM and TEM), and atomic force microscopy (AFM). 1,2,17−20 SAXS and SANS have provided valuable data on the materials' periodicity and, hence, nanostructure size and organization. In porous materials, pore size and surface area are frequently determined by gas adsorption measurements. 21 Scattering anisotropy data have revealed the 1D nature of many such materials and have yielded quantitative measurements of average nanostructure order. 12 SEM, TEM, and AFM afford a microscopic view of these same characteristics. Unfortunately, such methods provide little or no direct information on the partitioning and mass-transport characteristics of greatest relevance to many of their applications.The dynamics and directionality of molecular mass transport within 1D nanostructures have previously been investigated by nuclear magnetic resonance (NMR) sp...

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Trajectory angle determination in one dimensional single molecule tracking data by orthogonal regression analysis

Cited by 37 publications

References 49 publications

Single-Molecule Investigations of Morphology and Mass Transport Dynamics in Nanostructured Materials

Single-Molecule Investigations of Morphology and Mass Transport Dynamics in Nanostructured Materials

Trajectory-Profile-Guided Single Molecule Tracking for Assignment of One-Dimensional Diffusion Trajectories

Following Single Molecules to a Better Understanding of Self-Assembled One-Dimensional Nanostructures

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