Uniform intensity in multifocal microscopy using a spatial light modulator

Multifocal microscopy (MFM) offers high-speed three-dimensional imaging through the simultaneous image capture from multiple focal planes. Conventional MFM systems use a fabricated grating in the emission path for a single emission wavelength band and one set of focal plane separations. While a Spat...

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Veröffentlicht in:	PloS one 2020-03, Vol.15 (3), p.e0230217-e0230217
Hauptverfasser:	Amin, M Junaid, Petry, Sabine, Yang, Haw, Shaevitz, Joshua W
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Calibration Cameras Crosstalk Emission Emissions Engineering and Technology Focal plane Genomics Imaging Imaging systems Light Luminous intensity Methods Microscopy Molecular biology Nanoparticles Physical Sciences Pixels Planes Research and Analysis Methods Sensors Setting (Literature) Spatial light modulators Three-dimensional imaging Wavelengths
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creator	Amin, M Junaid Petry, Sabine Yang, Haw Shaevitz, Joshua W
description	Multifocal microscopy (MFM) offers high-speed three-dimensional imaging through the simultaneous image capture from multiple focal planes. Conventional MFM systems use a fabricated grating in the emission path for a single emission wavelength band and one set of focal plane separations. While a Spatial Light Modulator (SLM) can add more flexibility as a replacement to the fabricated grating, the relatively small number of pixels in the SLM chip, cross-talk between the pixels, and aberrations in the imaging system can produce non-uniform intensity in the different axially separated image planes. We present an in situ iterative SLM calibration algorithm that overcomes these optical- and hardware-related limitations to deliver near-uniform intensity across all focal planes. Using immobilized gold nanoparticles under darkfield illumination, we demonstrate superior intensity evenness compared to current methods. We also demonstrate applicability across emission wavelengths, axial plane separations, imaging modalities, SLM settings, and different SLM manufacturers. Therefore, our microscope design and algorithms provide an alternative to the use of fabricated gratings in MFM, as they are relatively simple and could find broad applications in the wider research community.
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subjects	Algorithms Calibration Cameras Crosstalk Emission Emissions Engineering and Technology Focal plane Genomics Imaging Imaging systems Light Luminous intensity Methods Microscopy Molecular biology Nanoparticles Physical Sciences Pixels Planes Research and Analysis Methods Sensors Setting (Literature) Spatial light modulators Three-dimensional imaging Wavelengths
title	Uniform intensity in multifocal microscopy using a spatial light modulator
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