Simple wavefront correction framework for two-photon microscopy of in-vivo brain
PT Galwaduge, SH Kim, LE Grosberg… - Biomedical optics …, 2015 - opg.optica.org
PT Galwaduge, SH Kim, LE Grosberg, EMC Hillman
Biomedical optics express, 2015•opg.optica.orgWe present an easily implemented wavefront correction scheme that has been specifically
designed for in-vivo brain imaging. The system can be implemented with a single liquid
crystal spatial light modulator (LCSLM), which makes it compatible with existing patterned
illumination setups, and provides measurable signal improvements even after a few
seconds of optimization. The optimization scheme is signal-based and does not require
exogenous guide-stars, repeated image acquisition or beam constraint. The unconstrained …
designed for in-vivo brain imaging. The system can be implemented with a single liquid
crystal spatial light modulator (LCSLM), which makes it compatible with existing patterned
illumination setups, and provides measurable signal improvements even after a few
seconds of optimization. The optimization scheme is signal-based and does not require
exogenous guide-stars, repeated image acquisition or beam constraint. The unconstrained …
We present an easily implemented wavefront correction scheme that has been specifically designed for in-vivo brain imaging. The system can be implemented with a single liquid crystal spatial light modulator (LCSLM), which makes it compatible with existing patterned illumination setups, and provides measurable signal improvements even after a few seconds of optimization. The optimization scheme is signal-based and does not require exogenous guide-stars, repeated image acquisition or beam constraint. The unconstrained beam approach allows the use of Zernike functions for aberration correction and Hadamard functions for scattering correction. Low order corrections performed in mouse brain were found to be valid up to hundreds of microns away from the correction location.
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