Extended depth of field microscopy for rapid volumetric two-photon imaging

Thériault, Gabrielle; Koninck, Yves De; McCarthy, Nathalie

doi:10.1364/oe.21.010095

Cited by 104 publications

(86 citation statements)

References 18 publications

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“…Axicons are refractive optical elements shaped as a cone (McLeod, 1954), which deviate light toward the optical axis by an angle β simply calculated from Snell's refraction law. The complete details of this method are presented in a previous paper (Thériault et al, 2013). …”

Section: Methodsmentioning

confidence: 99%

“…The transverse resolution ρ and the DOF L of the two-photon excitation at full-width at half maximum are given by:

ρ = m \frac{1.629 λ}{2 π \sin β} and L = m^{2} \frac{0.577 w}{\tan β}

where λ is the wavelength of the laser beam and m = Ff 1 / f 2 f α is the magnification applied to the Bessel beam while being relayed to the sample, with focal lengths F of the microscope objective, f 1 and f 2 of relay lenses in the scanning system and f α of the lens after the axicon. The advantage of this approach is that it allows adjusting the DOF independently (without changing the resolution) by using a simple telescope (Thériault et al, 2013). …”

Section: Methodsmentioning

confidence: 99%

“…Different approaches have been recently proposed to shape the distribution of light at the sample into a Bessel-Gauss beam (Botcherby et al, 2006; Dufour et al, 2006; Thériault et al, 2013), which is characterized by an intense central lobe and is nondiffractive, i.e., the central lobe has a constant radius.…”

Section: Introductionmentioning

confidence: 99%

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Extended two-photon microscopy in live samples with Bessel beams: steadier focus, faster volume scans, and simpler stereoscopic imaging

Thériault

Cottet

Castonguay

et al. 2014

Front. Cell. Neurosci.

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Two-photon microscopy has revolutionized functional cellular imaging in tissue, but although the highly confined depth of field (DOF) of standard set-ups yields great optical sectioning, it also limits imaging speed in volume samples and ease of use. For this reason, we recently presented a simple and retrofittable modification to the two-photon laser-scanning microscope which extends the DOF through the use of an axicon (conical lens). Here we demonstrate three significant benefits of this technique using biological samples commonly employed in the field of neuroscience. First, we use a sample of neurons grown in culture and move it along the z-axis, showing that a more stable focus is achieved without compromise on transverse resolution. Second, we monitor 3D population dynamics in an acute slice of live mouse cortex, demonstrating that faster volumetric scans can be conducted. Third, we acquire a stereoscopic image of neurons and their dendrites in a fixed sample of mouse cortex, using only two scans instead of the complete stack and calculations required by standard systems. Taken together, these advantages, combined with the ease of integration into pre-existing systems, make the extended depth-of-field imaging based on Bessel beams a strong asset for the field of microscopy and life sciences in general.

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Section: Methodsmentioning

confidence: 99%

“…The transverse resolution ρ and the DOF L of the two-photon excitation at full-width at half maximum are given by:

ρ = m \frac{1.629 λ}{2 π \sin β} and L = m^{2} \frac{0.577 w}{\tan β}

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

Extended two-photon microscopy in live samples with Bessel beams: steadier focus, faster volume scans, and simpler stereoscopic imaging

Thériault

Cottet

Castonguay

et al. 2014

Front. Cell. Neurosci.

Self Cite

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show abstract

“…Several approaches have been demonstrated for generating a Bessel beam under two-photon excitation. The most common approach involves the use of an axicon (conical lens) [8, 9, 10]. Other approaches employed a phase mask [11], or alternatively a spatial light modulator (SLM) [12], with the latter allowing for great flexibility in generating different types of Bessel foci with shaped axial intensity profiles.…”

mentioning

confidence: 99%

Three-photon fluorescence microscopy with an axially elongated Bessel focus

Rodríguez

Liang

et al. 2018

Opt. Lett.

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Volumetric imaging tools that are simple to adopt, flexible, and robust, are in high demand in the field of neuroscience, where the ability to image neurons and their networks with high spatiotemporal resolution is essential. Using an axially elongated focus approximating a Bessel beam, in combination with two-photon fluorescence microscopy, has proven successful at such an endeavor. Here we demonstrate three-photon fluorescence imaging with an axially extended Bessel focus. We use an axicon-based module which allowed for the generation of Bessel foci of varying numerical aperture and axial length, and apply this volumetric imaging tool to image mouse brain slices and for in vivo imaging of the mouse brain.

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“…Here, the SLM is tuned to provide programmable illumination needed to simultaneously excite all neurons at different focal points while the wavefront coding via the phase mask makes it possible to simultaneously accept light from neurons at all different focal points. Fast axial scanning by changing focal position has been attempted by several methods: adaptive aberration correction with DM [53], extended DOF with a scanning axicon [54,55], and two photon microscopy with diffractive optical elements (DOE) [56]. For high spatiotemporal resolution, a two photon microscope with simultaneously focusing multiple excitation beams at different positions was developed.…”

Section: Isot 2015mentioning

confidence: 99%

Optomechatronics for Biomedical Optical Imaging: An Overview

Cho

2015

MATEC Web of Conferences

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Abstract. The use of optomechatronic technology, particularly in biomedical optical imaging, is becoming pronounced and ever increasing due to its synergistic effect of the integration of optics and mechatronics. The background of this trend is that the biomedical optical imaging for example in-vivo imaging related to retraction of tissues, diagnosis, and surgical operations have a variety of challenges due to complexity in internal structure and properties of biological body and the resulting optical phenomena. This paper addresses the technical issues related to tissue imaging, visualization of interior surfaces of organs, laparoscopic and endoscopic imaging and imaging of neuronal activities and structures. Within such problem domains the paper overviews the states of the art technology focused on how optical components are fused together with those of mechatronics to create the functionalities required for the imaging systems. Future perspective of the optical imaging in biomedical field is presented in short.

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Extended depth of field microscopy for rapid volumetric two-photon imaging

Cited by 104 publications

References 18 publications

Extended two-photon microscopy in live samples with Bessel beams: steadier focus, faster volume scans, and simpler stereoscopic imaging

Extended two-photon microscopy in live samples with Bessel beams: steadier focus, faster volume scans, and simpler stereoscopic imaging

Three-photon fluorescence microscopy with an axially elongated Bessel focus

Optomechatronics for Biomedical Optical Imaging: An Overview

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