Planar Airy beam light-sheet for two-photon microscopy

Hosny, Neveen A.; Seyforth, James; Spickermann, Gunnar; Mitchell, Thomas J.; Almada, Pedro; Chesters, Robert; Mitchell, Stephen J.; Chennell, George; Vernon, Anthony C.; Cho, Kwangwook; Srivastava, Deepak P.; Forster, Robert; Vettenburg, Tom

doi:10.1364/boe.395547

Cited by 34 publications

(27 citation statements)

References 33 publications

(50 reference statements)

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“…We anticipate the benefit demonstrated in this work can be obtained for any implementation of 2P-SPIM, including using Bessel [10,27,29] or Airy [31,32] beams instead of Gaussian beams, as long as the laser peak intensity remains lower than in the point-scanning case. The nonlinear photodamage threshold involved in 2P-SPIM using different beam shapes would however require further investigations.…”

Section: Discussionmentioning

confidence: 91%

“…In multiphoton light-sheet microscopy, adjusting the laser pulse frequency remains an attractive yet unexplored strategy to balance signal and photoperturbation. Indeed, most multiphoton light-sheet microscopes described so far [4,[10][11][12][13][25][26][27][28][29][30][31][32] were implemented using a mode-locked Ti:sapphire laser at f ∼80 Mhz, which is the most commonly used laser source in multitphoton microscopy. However, this choice is questionable and may not take full advantage of light-sheet illumination and its orthogonal geometry.…”

Section: Introductionmentioning

confidence: 99%

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Fast in vivo multiphoton light-sheet microscopy with optimal pulse frequency

Maioli¹,

Boniface²,

Mahou³

et al. 2020

Biomed. Opt. Express

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Improving the imaging speed of multiphoton microscopy is an active research field. Among recent strategies, light-sheet illumination holds distinctive advantages for achieving fast imaging in vivo. However, photoperturbation in multiphoton light-sheet microscopy remains poorly investigated. We show here that the heart beat rate of zebrafish embryos is a sensitive probe of linear and nonlinear photoperturbations. By analyzing its behavior with respect to laser power, pulse frequency and wavelength, we derive guidelines to find the best balance between signal and photoperturbation. We then demonstrate one order-of-magnitude signal enhancement over previous implementations by optimizing the laser pulse frequency. These results open new opportunities for fast live tissue imaging.

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Section: Discussionmentioning

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Fast in vivo multiphoton light-sheet microscopy with optimal pulse frequency

Maioli¹,

Boniface²,

Mahou³

et al. 2020

Biomed. Opt. Express

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show abstract

“…We have also demonstrated that rotation to a standard Airy beam profile gives a modest increase in the useable field of view, with no loss of resolution. Creation of an Airy beam profile in a light sheet microscope is straightforward to implement, either by the positioning and rotation of a cubic phase mask 17,52 or cylindrical lens 19,22 , or by design of SLM pattern 55 . Experimentalists using an Airy beam light sheet microscope should strongly consider use of the symmetric rotated Airy beam (SRA) beam profile rather than the standard Airy beam profile to realise the increase in useable FOV and resolution uniformity afforded by this beam type.…”

Section: Discussionmentioning

confidence: 99%

“…Analysis of the empirical data showed that the FOV was extended slightly (4%) using the SRA profile, whilst it was reduced slightly (7%) in the NSRA profile, when compared to the Airy profile (Fig 1f; Airy, 130 µm; SRA 136 µm; NSRA 121 µm). Larger improvements to effective FOV are expected when using different combinations of objective and Airy beam profile, with an improvement of up to 33% demonstrated 52 .…”

Section: Symmetrical Rotated Airy Improves Resolution Across Fovmentioning

confidence: 99%

“…For developing a deconvolution-free SHG-LSM method we tested two alternate orientations: with the secondary lobes placed symmetrically above and below the imaging plane, termed Symmetrical Rotated Airy (Fig 1b; SRA), or with all secondary lobes being either above or below the imaging plane, termed Non-Symmetric Rotated Airy (Fig 1b, NSRA). A recent publication by Hosny et al uses the term Planar Airy Light Sheet which is the same case as our Symmetrical Rotated Airy 51 . In this work, we distinguish the two beam types by their symmetry about the illumination plane.…”

Section: Symmetrical Rotated Airy Improves Resolution Across Fovmentioning

confidence: 99%

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Label-free and Multimodal Second Harmonic Generation Light Sheet Microscopy

Hanrahan

Lane

Johnson

et al. 2020

Preprint

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Light sheet microscopy (LSM) has emerged as one of most profound three dimensional (3D) imaging tools in the life sciences over the last decade. However, LSM is currently performed with fluorescence detection on one- or multi-photon excitation. Label-free LSM imaging approaches have been rather limited. Second Harmonic Generation (SHG) imaging is a label-free technique that has enabled detailed investigation of collagenous structures, including its distribution and remodelling in cancers and respiratory tissue, and how these link to disease. SHG is generally regarded as having only forward- and back-scattering components, apparently precluding the orthogonal detection geometry used in Light Sheet Microscopy. In this work we demonstrate SHG imaging on a light sheet microscope (SHG-LSM) using a rotated Airy beam configuration that demonstrates a powerful new approach to direct (without any further processing or deconvolution) 3D imaging of harmonophores such as collagen fibres in biological samples. We provide unambiguous identification of SHG signals on the LSM through its wavelength and polarisation sensitivity. In a multimodal LSM setup we demonstrate that SHG and two-photon signals can be acquired on multiple types of different biological samples. We further show that SHG-LSM is sensitive to changes in collagen synthesis within lung fibroblast 3D cell cultures. This work expands on the existing optical methods available for use with light sheet microscopy, adding a further label-free imaging technique which can be combined with other detection modalities to realise a powerful multi-modal microscope for 3D bioimaging.

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