Dipole-spread-function engineering for simultaneously measuring the 3D orientations and 3D positions of fluorescent molecules

Abstract: Interactions between biomolecules are characterized by where they occur and how they are organized, e.g., the alignment of lipid molecules to form a membrane. However, spatial and angular information are mixed within the image of a fluorescent molecule–the microscope’s dipole-spread function (DSF). We demonstrate the pixOL algorithm to simultaneously optimize all pixels within a phase mask to produce an engineered Green’s tensor–the dipole extension of point-spread function engineering. The pixOL DSF achieves … Show more

“…Robust single-molecule imaging, especially in vivo , necessitates an estimation algorithm that can reliably detect and estimate parameters from emitters whose images overlap [41, 42]. Early algorithms for measuring simultaneously SM orientations and positions either cannot cope with image overlap [9, 11, 23], are very computationally expensive [18], or can become stuck in local minima leading to correlated orientation and position biases [14]. To facilitate Deep-SMOLM’s robustness to these imaging conditions, we train it using simulated images containing both well-separated and overlapped DSFs corrupted by Poisson shot noise (SI section 4.ii).…”

“…Here, we demonstrate a deep learning-based estimator, called Deep-SMOLM, for simultaneously estimating 3D orientations and 2D positions of single molecules from a microscope implementing an engineered dipole-spread function [14]. Compared to traditional optimization approaches, Deep-SMOLM achieves superior estimation precision for both 3D orientation and 2D position that is on average within 3% of the best-possible precision (Fig.…”

“…2); otherwise, directly estimating orientation angles [ θ, ϕ , Ω] is ill-conditioned and unstable. Importantly, for high-performance DSFs, each brightness-weighted orientational moment contributes approximately equally to the final DSF shape [12, 14]. Further, we have designed 3D orientations and 2D positions to be orthogonally encoded into the intensities and spatial positions, respectively, of Gaussian spots within Deep-SMOLM’s output images (Fig.…”

“…To remedy these issues, we use a polarization-sensitive microscope that splits fluorescence into x- and y-polarized detection channels, along with a pixOL phase mask placed at the pupil or back focal plane (Fig. 11) [14]. The resulting pixOL DSF changes dramatically for molecules oriented in various directions (Fig.…”

“…Researchers have used molecular orientations [1] to elucidate the architectures of amyloid aggregates [2][3][4], the organization of proteins in actin filaments [5,6], and changes in lipid membrane polarity and fluidity induced by cholesterol [4,7,8]. To effectively use limited photon budgets in single-molecule (SM) imaging, dipole-spread functions (DSFs), i.e., the vectorial extension of the optical microscope's point-spread function, must be engineered to encode additional information about a molecule's 3D orientation [5,[9][10][11][12][13][14][15]. However, simultaneously estimating the 3D orientation and position of an emitter is challenging because 1) it is difficult to estimate SM parameters in 5-dimensional space (3D orientation, wobble, 2D position) without getting trapped in local minima instigated by severe Poisson shot noise [4,14],…”

Deep-SMOLM: Deep Learning Resolves the 3D Orientations and 2D Positions of Overlapping Single Molecules with Optimal Nanoscale Resolution

“…Robust single-molecule imaging, especially in vivo , necessitates an estimation algorithm that can reliably detect and estimate parameters from emitters whose images overlap [41, 42]. Early algorithms for measuring simultaneously SM orientations and positions either cannot cope with image overlap [9, 11, 23], are very computationally expensive [18], or can become stuck in local minima leading to correlated orientation and position biases [14]. To facilitate Deep-SMOLM’s robustness to these imaging conditions, we train it using simulated images containing both well-separated and overlapped DSFs corrupted by Poisson shot noise (SI section 4.ii).…”

“…Here, we demonstrate a deep learning-based estimator, called Deep-SMOLM, for simultaneously estimating 3D orientations and 2D positions of single molecules from a microscope implementing an engineered dipole-spread function [14]. Compared to traditional optimization approaches, Deep-SMOLM achieves superior estimation precision for both 3D orientation and 2D position that is on average within 3% of the best-possible precision (Fig.…”

“…2); otherwise, directly estimating orientation angles [ θ, ϕ , Ω] is ill-conditioned and unstable. Importantly, for high-performance DSFs, each brightness-weighted orientational moment contributes approximately equally to the final DSF shape [12, 14]. Further, we have designed 3D orientations and 2D positions to be orthogonally encoded into the intensities and spatial positions, respectively, of Gaussian spots within Deep-SMOLM’s output images (Fig.…”

“…To remedy these issues, we use a polarization-sensitive microscope that splits fluorescence into x- and y-polarized detection channels, along with a pixOL phase mask placed at the pupil or back focal plane (Fig. 11) [14]. The resulting pixOL DSF changes dramatically for molecules oriented in various directions (Fig.…”

“…Researchers have used molecular orientations [1] to elucidate the architectures of amyloid aggregates [2][3][4], the organization of proteins in actin filaments [5,6], and changes in lipid membrane polarity and fluidity induced by cholesterol [4,7,8]. To effectively use limited photon budgets in single-molecule (SM) imaging, dipole-spread functions (DSFs), i.e., the vectorial extension of the optical microscope's point-spread function, must be engineered to encode additional information about a molecule's 3D orientation [5,[9][10][11][12][13][14][15]. However, simultaneously estimating the 3D orientation and position of an emitter is challenging because 1) it is difficult to estimate SM parameters in 5-dimensional space (3D orientation, wobble, 2D position) without getting trapped in local minima instigated by severe Poisson shot noise [4,14],…”

Deep-SMOLM: Deep Learning Resolves the 3D Orientations and 2D Positions of Overlapping Single Molecules with Optimal Nanoscale Resolution

Dipole-Spread Function Engineering for Six-Dimensional Super-Resolution Microscopy

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