Model-based aberration corrected microscopy inside a glass tube

Daniël W.S. Cox; Tom Knop; Ivo M. Vellekoop

doi:10.1111/jmi.13402

Model-based aberration corrected microscopy inside a glass tube

Daniël W.S. Cox^*, Tom Knop, Ivo M. Vellekoop

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Microscope objectives achieve near diffraction-limited performance only when used under the conditions they are designed for. In nonstandard geometries, such as thick cover slips or curved surfaces, severe aberrations arise, inevitably impairing high-resolution imaging. Correcting such large aberrations using standard adaptive optics can be challenging: existing solutions are either not suited for strong aberrations, or require extensive feedback measurements, consequently taking a significant portion of the photon budget. We demonstrate that it is possible to precompute the corrections needed for high-resolution imaging inside a glass tube based on a priori information only. Our ray-tracing-based method achieved over an order of magnitude increase in image contrast without the need for a feedback signal.

Original language	English
Pages (from-to)	316-323
Number of pages	8
Journal	Journal of microscopy
Volume	298
Issue number	3
Early online date	16 Mar 2025
DOIs	https://doi.org/10.1111/jmi.13402
Publication status	Published - Jun 2025

Keywords

UT-Hybrid-D
a priori
aberration correction
digital twin
fluorescence
laser scanning
lumen
microscopy
model based
nonlinear
organ-on-a-chip
ray tracing
spatial light modulator
tube
two-photon
wavefront shaping
2PEF

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10.1111/jmi.13402Licence: CC BY

Journal of Microscopy - 2025 - Cox - Model‐based aberration corrected microscopy inside a glass tubeFinal published version, 1.38 MBLicence: CC BY

Cite this

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title = "Model-based aberration corrected microscopy inside a glass tube",

abstract = "Microscope objectives achieve near diffraction-limited performance only when used under the conditions they are designed for. In nonstandard geometries, such as thick cover slips or curved surfaces, severe aberrations arise, inevitably impairing high-resolution imaging. Correcting such large aberrations using standard adaptive optics can be challenging: existing solutions are either not suited for strong aberrations, or require extensive feedback measurements, consequently taking a significant portion of the photon budget. We demonstrate that it is possible to precompute the corrections needed for high-resolution imaging inside a glass tube based on a priori information only. Our ray-tracing-based method achieved over an order of magnitude increase in image contrast without the need for a feedback signal.",

keywords = "UT-Hybrid-D, a priori, aberration correction, digital twin, fluorescence, laser scanning, lumen, microscopy, model based, nonlinear, organ-on-a-chip, ray tracing, spatial light modulator, tube, two-photon, wavefront shaping, 2PEF",

author = "Cox, \{Dani{\"e}l W.S.\} and Tom Knop and Vellekoop, \{Ivo M.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Journal of Microscopy published by John Wiley \& Sons Ltd on behalf of Royal Microscopical Society.",

year = "2025",

month = jun,

doi = "10.1111/jmi.13402",

language = "English",

volume = "298",

pages = "316--323",

journal = "Journal of microscopy",

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T1 - Model-based aberration corrected microscopy inside a glass tube

AU - Cox, Daniël W.S.

AU - Knop, Tom

AU - Vellekoop, Ivo M.

PY - 2025/6

Y1 - 2025/6

N2 - Microscope objectives achieve near diffraction-limited performance only when used under the conditions they are designed for. In nonstandard geometries, such as thick cover slips or curved surfaces, severe aberrations arise, inevitably impairing high-resolution imaging. Correcting such large aberrations using standard adaptive optics can be challenging: existing solutions are either not suited for strong aberrations, or require extensive feedback measurements, consequently taking a significant portion of the photon budget. We demonstrate that it is possible to precompute the corrections needed for high-resolution imaging inside a glass tube based on a priori information only. Our ray-tracing-based method achieved over an order of magnitude increase in image contrast without the need for a feedback signal.

AB - Microscope objectives achieve near diffraction-limited performance only when used under the conditions they are designed for. In nonstandard geometries, such as thick cover slips or curved surfaces, severe aberrations arise, inevitably impairing high-resolution imaging. Correcting such large aberrations using standard adaptive optics can be challenging: existing solutions are either not suited for strong aberrations, or require extensive feedback measurements, consequently taking a significant portion of the photon budget. We demonstrate that it is possible to precompute the corrections needed for high-resolution imaging inside a glass tube based on a priori information only. Our ray-tracing-based method achieved over an order of magnitude increase in image contrast without the need for a feedback signal.

KW - UT-Hybrid-D

KW - a priori

KW - aberration correction

KW - digital twin

KW - fluorescence

KW - laser scanning

KW - lumen

KW - microscopy

KW - model based

KW - nonlinear

KW - organ-on-a-chip

KW - ray tracing

KW - spatial light modulator

KW - tube

KW - two-photon

KW - wavefront shaping

KW - 2PEF

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DO - 10.1111/jmi.13402

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VL - 298

SP - 316

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JO - Journal of microscopy

JF - Journal of microscopy

IS - 3

ER -

Model-based aberration corrected microscopy inside a glass tube

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