%0 Journal Article %1 Bohrer2018 %A Bohrer, Christopher H. %A Yang, Xinxing %A Lyu, Zhixin %A Wang, Shih-Chin %A Xiao, Jie %D 2018 %I Cold Spring Harbor Laboratory %J bioRxiv %K 3D mle software superresolution %P 304816 %R 10.1101/304816 %T Improved single-molecule localization precision in astigmatism-based 3D superresolution imaging using weighted likelihood estimation %U https://www.biorxiv.org/content/10.1101/304816v1.abstract %X Astigmatism-based superresolution microscopy is widely used to determine the position of individual fluorescent emitters in three-dimensions (3D) with subdiffraction-limited resolutions. This point spread function (PSF) engineering technique utilizes a cylindrical lens to modify the shape of the PSF and break its symmetry above and below the focal plane. The resulting asymmetric PSFs at different z-positions for single emitters are fit with an elliptical 2D-Gaussian function to extract the widths along two principle x- and y-axes, which are then compared with a pre-measured calibration function to determine its z-position. While conceptually simple and easy to implement, in practice, distorted PSFs due to an imperfect optical system often compromise the localization precision; and it is laborious to optimize a multi-purpose optical system. Here we present a methodology that is independent of obtaining a perfect PSF and enhances the localization precision along the z-axis. By utilizing multiple calibration images of fluorescent beads at varying z-planes and characterizing experimentally measured background distributions, we numerically approximated the probability of observing a certain signal in a given pixel from a single emitter at a particular z-plane. We then used a weighted maximum likelihood estimator (WLE) to determine the 3D-position of the emitter. We demonstrate that this approach enhances z-axis localization precision in all conditions we tested, in particular when the PSFs deviate from a standard 2D Gaussian model.

@article{Bohrer2018, abstract = {Astigmatism-based superresolution microscopy is widely used to determine the position of individual fluorescent emitters in three-dimensions (3D) with subdiffraction-limited resolutions. This point spread function (PSF) engineering technique utilizes a cylindrical lens to modify the shape of the PSF and break its symmetry above and below the focal plane. The resulting asymmetric PSFs at different z-positions for single emitters are fit with an elliptical 2D-Gaussian function to extract the widths along two principle x- and y-axes, which are then compared with a pre-measured calibration function to determine its z-position. While conceptually simple and easy to implement, in practice, distorted PSFs due to an imperfect optical system often compromise the localization precision; and it is laborious to optimize a multi-purpose optical system. Here we present a methodology that is independent of obtaining a perfect PSF and enhances the localization precision along the z-axis. By utilizing multiple calibration images of fluorescent beads at varying z-planes and characterizing experimentally measured background distributions, we numerically approximated the probability of observing a certain signal in a given pixel from a single emitter at a particular z-plane. We then used a weighted maximum likelihood estimator (WLE) to determine the 3D-position of the emitter. We demonstrate that this approach enhances z-axis localization precision in all conditions we tested, in particular when the PSFs deviate from a standard 2D Gaussian model.}, added-at = {2020-03-23T21:12:34.000+0100}, author = {Bohrer, Christopher H. and Yang, Xinxing and Lyu, Zhixin and Wang, Shih-Chin and Xiao, Jie}, biburl = {https://www.bibsonomy.org/bibtex/201e9fc86e0f5a9a4c2579032220395f0/kfriedl}, doi = {10.1101/304816}, file = {:C$\backslash$:/Users/Karoline/AppData/Local/Mendeley Ltd./Mendeley Desktop/Downloaded/Bohrer et al. - 2018 - Improved single-molecule localization precision in astigmatism-based 3D superresolution imaging using weighted li.pdf:pdf}, interhash = {6aaf57ef6ead43c5f7a4ca5b6d70b3a7}, intrahash = {01e9fc86e0f5a9a4c2579032220395f0}, journal = {bioRxiv}, keywords = {3D mle software superresolution}, month = apr, pages = 304816, publisher = {Cold Spring Harbor Laboratory}, timestamp = {2020-03-23T22:14:59.000+0100}, title = {{Improved single-molecule localization precision in astigmatism-based 3D superresolution imaging using weighted likelihood estimation}}, url = {https://www.biorxiv.org/content/10.1101/304816v1.abstract}, year = 2018 }