Adaptive Optics Archives | Imagine Optic

Intense Laser Adaptive Optics: The ILAO-STAR

okobayter — Wed, 18 Dec 2024 12:50:55 +0000

Intense Laser Adaptive Optics: Having laid the groundwork for understanding the importance of wavefront correction in Part 1, we now turn our attention to the innovative technology behind ILAO-STAR. Discover how this advanced deformable mirror redefines precision and performance in the realm of high-power lasers.

ILAO-STAR : Customizability Meets Precision

Combining patented mechanical actuator technology with unparalleled customization options, the ILAO-STAR is engineered for applications that demand exceptional precision and stability. The mirror transforms large-scale mechanical actuator movements into on-demand nanometric adjustments of the spatial phase of laser light, providing precise optical aberration corrections with active-flat performance better than 10 nm RMS. This ensures diffraction-limited beam quality, meaning that the laser light is as focused and intense as possible.

One of Ilao-Star’s standout features is its exceptional reproducibility, with linearity exceeding 99.9% and hysteresis below 0.1%. Most notably, the ILAO-STAR deformable mirror distinguishes itself by eliminating intermediate wavefront shapes within the adaptive optics correction loop, thus, without the so-called “breathing effect” commonly seen in other systems.

ILAO-STAR : Redefining Intense Laser Adaptive Optics

ILAO STAR new Gen, the latest generation of ILAO-STAR deformable mirrors, simultaneously packs excellent reproducibility and single-movement optical aberration correction. Video 1 demonstrates the single-movement optical aberration correction capability of the ILAO STAR deformable mirror. Starting from peak-to-valley (PtV) wavefront deformation, a single iteration with unity close-loop gain yields an aberration-corrected beam with 23 nm root-mean-square (RMS) wavefront error; all while making a single movement, thus, without generating intermediate wavefront shapes within the adaptive optics correction loop.

Video 1. Single-movement optical aberration correction. The video shows the correction of a large amount of optical aberrations in only one close-loop iteration while making a single movement.

On the other hand, Video 2 exemplifies the excellent reproducibility of ILAO-STAR. The demonstration highlights the reproducibility of the deformable mirror by switching between saved wavefront corrector shapes. Initially, a distorted point spread function (PSF) is corrected by loading a saved actuator distribution, improving the Strehl ratio to over 0.95 and reducing wavefront RMS from ~420 nm to 20 nm. Switching to a shape-inducing astigmatism distorts the PSF again, but reloading the optimized shape restores the high Strehl ratio. This process demonstrates the DM’s ability to transition between configurations with high fidelity.

Video 2: Excellent Reproducibility of ILAO-STAR deformable mirror.

Leveraging high linearity and low hysteresis yielding exceptional reproducibility, and single-movement compensation, ILAO-STAR has opened the prospects of close-loop correction in the full-power mode of the laser and at an impressive rate of 10 Hertz, as recently demonstrated for state-of-the-art petawatt-class system [3].

Figure 5. Imagine Optic’s ILAO-STAR deformable mirrors deliver simultaneously excellent reproducibility and single-movement optical aberration correction, opening the possibility of close-loop correction in the full-power mode of the laser, and at a rate of 10 Hertz

Software Solutions for Enhanced Precision: Intense Laser Adaptive Optics

Imagine Optic complements the ILAO-STAR’s hardware capabilities with powerful software solutions. WaveTune™ provides optical wavefront correction and user-friendly controls, while PharAO™ manages end-of-chain aberrations with its Phase Retrieval adaptive optics system [8-9]. These tools enhance operational security, allowing the mirror to synchronize with laser pulses and adjust safely even during full-power operation of petawatt-class systems [3].

Conclusion

The ILAO-STAR sets a new benchmark in adaptive optics for high-power laser systems, offering unmatched precision and demonstrated capability to correct wavefront distortions of petawatt-class systems at full laser power, and at an impressive rate of 10 Hertz [3]. From particle acceleration to laser fusion, it empowers a wide range of cutting-edge applications.

Imagine Optic’s ILAO-STAR is a transformative solution for high-power laser systems, unlocking new possibilities in advanced research and technology. Learn more about how this innovative deformable mirror can redefine your laser applications by visiting Imagine Optic’s website.

#HighPowerLasers #ILAOSTAR #AdaptiveOptics #WavefrontCorrection #PhotonicsInnovation #LaserApplications #PetawattLaser #BeamShaping #LaserTechnology #OpticalAberrationCorrection #PrecisionOptics

References:

[1] F. Lureau et al., “High-energy hybrid femtosecond laser system demonstrating 2 × 10 PW capability,” High Power Laser Science and Engineering, vol. 8, p. e43 (2020).

[2] C. Radier et al., “10 PW peak power femtosecond laser pulses at ELI-NP,” High Power Laser Science and Engineering, vol. 10, p. e21 (2022).

[3] R. S. Nagymihály et al., “The petawatt laser of ELI ALPS: reaching the 700 TW level at 10 Hz repetition rate,” Opt. Express 31, 44160-44176 (2023).

[4] H. Kiriyama et al., “Laser Output Performance and Temporal Quality Enhancement at the J-KAREN-P Petawatt Laser Facility,” Photonics 2023, 10(9), 997 (2023).

[5] H.-S. Mao et al., “High-quality spatial modes for petawatt-class lasers,” AIP Conf. Proc. 28 October 2016; 1777 (1): 110003 (2016).

[5] S Toth et al., “SYLOS lasers – the frontier of few-cycle, multi-TW, kHz lasers for ultrafast applications at extreme light infrastructure attosecond light pulse source,” J. Phys. Photonics 2 045003 (2020).

[6] R. Clady et al., “22 W average power multiterawatt femtosecond laser chain enabling 1019 W/cm2 at 100 Hz”, Appl. Phys. B 124, 89 (2018).

[7] S.J. Hawkes et al., “Laser wakefield acceleration with active feedback at 5 Hz,” Phys. Rev. Accel. Beams 22, 041303 (2019).

[8] F. Canova et al., “Wavefront Correction and Aberrations Pre-Compensation in the Middle of Petawatt-Class CPA Laser Chains,” in Conference on Lasers and ElectroOptics/Quantum Electronics and Laser Science Conference and Photonic Applications Systems Technologies, OSA Technical Digest Series (CD) (Optical Society of America, 2007), paper JThD125.

[9] N. Varkentina et al., “New adaptive optics control strategy for petawatt-class laser chains”, Quantum Electronics 47 (8) 711 – 717 (2017).

The post Intense Laser Adaptive Optics: The ILAO-STAR appeared first on Imagine Optic.

Optical Aberration Correction in High-Power Lasers: ILAO-STAR

okobayter — Fri, 13 Dec 2024 13:20:49 +0000

Figure 1. ILAO-Star 400 – ‘one of the Stars of Imagine Optic‘s ILAO-STAR deformable mirrors, meticulously crafted to meet the requirements of state-of-the-art Ultrashort Petawatt-class laser pulses.

High-power laser systems are at the forefront of technological innovation, enabling breakthroughs in numerous fields like particle acceleration, high harmonic generation, and laser fusion, to name a few. In the realm of high-power laser systems, precision isn’t just a requirement—it’s a necessity. Maintaining beam quality and maximizing on-target peak intensity demands sophisticated solutions for optical aberration correction, and Imagine Optic’s ILAO-STAR deformable mirror stands at the forefront of this innovation. Designed to overcome the challenges of wavefront distortion, the ILAO-STAR provides unmatched performance and adaptability, making it a cornerstone in advanced laser applications [1-9].

The Challenge of Wavefront Distortion in high-power lasers: Why Optical Aberration Correction Matters

High-power laser systems often face a critical issue: wavefront distortion. This can occur due to optical element misalignment, thermal effects in amplifiers, and mechanical constraints, all of which can degrade beam quality and reduce the intensity of focused light [6, 8]. For applications demanding maximal on-target peak intensity, such distortions in the spatial phase of the laser light degrade beam quality, reducing the focused intensity crucial for cutting-edge applications. That’s where the ILAO-STAR comes in to shape the spatial phase of intense laser light with nanometric precision.

Figure 2. Laser Light-Beam Shaping: Exploiting Imagine Optic’s ILAO-STAR deformable mirror to ‘craft’ a ‘butterfly’ intensity profile via wavefront manipulation of laser light with nanometric precision. Image of the Week – Optics & Photonics News, Optica (17/03/2023).

ILAO-Star: Tailored for High-Power Lasers

The ILAO-STAR deformable mirror, developed by Imagine Optic, is a groundbreaking innovation designed to address the challenges of wavefront distortion in the most extreme conditions. Designed specifically for high-power lasers, ILAO-STAR stands out with its extensive customization options, allowing seamless integration into diverse laser setups. The ILAO-STAR offers customizability of beam sizes (20 mm to 600 mm), intensity profiles (Gaussian, super-Gaussian, or top-hat), and beam shapes (circular, elliptical, rectangular, or square), making it suitable for a wide range of configurations, including multi-petawatt systems [1-5, 8-9].

Figure 3. 550 mm x 500 mm (left image), and 400 mm x 500 mm (right image) high-vacuum compatible ILAO-STAR deformable mirrors for multi-petawatt ultrashort laser pulses exhibiting rectangular (left) and elliptical (right) beam geometry at the plane of incidence.

Figure 4. 600 mm diameter high-vacuum compatible ILAO-STAR for State-of-the-art 10-Petawatt ultrashort laser pulses; human face for scale.

Moreover, ILAO-STAR’s reflective coatings—available in dielectric, metallic, or hybrid options—are optimized to withstand the demanding conditions of high-power laser systems. Additionally, its ability to operate at correction frequencies up to 10 Hz with high stability, puts it at the forefront for wavefront control of high repetition rate Petawatt-class laser systems [3].

In conclusion, the ILAO-STAR deformable mirror represents a significant advancement in optical aberration correction for high-power lasers. Its adaptability, performance, and customization options make it a valuable tool for researchers and engineers pushing the boundaries of laser technology. By effectively addressing wavefront distortion, the ILAO-STAR ensures optimal laser beam quality, maximizing intensity and enabling breakthroughs in fields ranging from particle acceleration to laser fusion.

But the innovation doesn’t stop here! Stay tuned for our next blog post, where we’ll dive into the features of the new generation of ILAO-STAR.

References:

[1] F. Lureau et al., “High-energy hybrid femtosecond laser system demonstrating 2 × 10 PW capability,” High Power Laser Science and Engineering, vol. 8, p. e43 (2020).

[2] C. Radier et al., “10 PW peak power femtosecond laser pulses at ELI-NP,” High Power Laser Science and Engineering, vol. 10, p. e21 (2022).

[3] R. S. Nagymihály et al., “The petawatt laser of ELI ALPS: reaching the 700 TW level at 10 Hz repetition rate,” Opt. Express 31, 44160-44176 (2023).

[4] H. Kiriyama et al., “Laser Output Performance and Temporal Quality Enhancement at the J-KAREN-P Petawatt Laser Facility,” Photonics 2023, 10(9), 997 (2023).

[5] H.-S. Mao et al., “High-quality spatial modes for petawatt-class lasers,” AIP Conf. Proc. 28 October 2016; 1777 (1): 110003 (2016).

[6] R. Clady et al., “22 W average power multiterawatt femtosecond laser chain enabling 1019 W/cm2 at 100 Hz”, Appl. Phys. B 124, 89 (2018).

[7] S.J. Hawkes et al., “Laser wakefield acceleration with active feedback at 5 Hz,” Phys. Rev. Accel. Beams 22, 041303 (2019).

The post Optical Aberration Correction in High-Power Lasers: ILAO-STAR appeared first on Imagine Optic.

Adaptive optics for Free Space Optics… and for fun!

okobayter — Fri, 21 Jul 2023 12:01:17 +0000

Adaptive Optics Space Optics –
Incredible as it may seem, the famous reporter Tintin was already thinking, back in 1941 in L’étoile mystérieuse, Hergé, that telescope-based images could be greatly improved thanks to adaptive optics!

Adaptive optics for Free Space Optics (FSO) applications is a technique that couples a deformable mirror, a wavefront sensor and a calculator. Together, these components enable the wavefront of an incoming beam, and therefore its phase, to be modified very rapidly. Adaptive Optics (AO) has been developed in the 80s to remove the effect of air turbulences and get diffraction limited images from ground-based telescopes. Almost all large telescopes dedicated to high-resolution imaging have now an AO system. Imaging of exoplanets is the new goal for the new generation of AO system for astronomy.

AO is now used in many different applications such as:

Adaptive Optics for Ultra-High Intensity Laser: Imagine Optic ILAO STAR deformable mirrors are optimized for this application, where stability and large diameters are more important than speed. The deformable mirror removes residual static aberrations due to misalignment and thermal effects.

Adaptive Optics for Ophthalmology: Imagine Eyes RTX1 can acquire high-resolution images of the retina in vivo. AO is needed to remove all aberrations originating from the patient’s eye.

Adaptive Optics for Microscopy: Imagine Optic mu-DM deformable mirror has been designed to meet the specific needs of bio imaging (stability, dynamic, accuracy). Aberrations, particularly present when the focusing plane is deep in the sample, are compensated for to restore optimum resolution and signal intensity.

Adaptive optics Space Optics

AO for high resolution imaging

A couple of years ago, a bunch of geeks (passionate amateur astronomers and AO experts) at Imagine Optic launched a project codename “CIAO” to validate they can build a simple, very easy-to-install setup, AO system capable of removing all static aberrations (mirrors misalignment, gravity and thermal effects) and reducing the effect of air turbulence in order to acquire better quality images.

What we got was a Plug & Play Adaptive Optics accessory with great performance at an incredible price point!

Left: Some of us actually see the AO effect
Right: With a one-meter diameter telescope and no aberrations, we can reveal details of Mars that have never been seen from Earth

The CIAO Adaptive Optics System has now been tested on many kinds of telescopes (200mm up to 1.3m diameter, f/22 to f/8 aperture) to see how images are enhanced by this affordable system.
For instance, we were able to:

– see the Airy spot on a 1.3m diameter telescope with a seeing of 1.8 arcsec.
– prove that with a very bad seeing of 2.2 arcsec, a tip-tilt correction is surely not enough on a 355mm diameter telescope to get diffraction limited images as seen on image below:

The effect of atmospheric refraction is clearly visible on the image obtained with AO

AO for single mode fiber injection | Adaptive Optics Space Optics

CIAO efficiency has been evaluated for applications requiring the light received by a telescope to be injected into a single-mode fiber (Free Space Optics, satellite communication, Stellar interferometry, etc.). A first successful demonstration has already been conducted in the visible spectrum: we have proved that the coupling efficiency is improved and we have obtained an average flux level, at the fiber output, multiplied by a factor of 5. The second phase is now ongoing to establish the performance of a SWIR Adaptive Optics for Free Space Optics system, and the whole Imagine Optic team is fully committed to tackle the challenges of this new upgrade.

Left: AO OFF. Right: AO ON stabilizes the focal spot on the core of an optical fiber

Whether or not you consider yourself an AO geek, do not hesitate to contact us: we’ll be happy to discuss with you what adaptive optics solution for FSO best suits your needs …

Acknowledgments

Many people are involved in this work, all of them must be gratefully thanked: François Colas (IMCCE), Jean-Luc Dauvergne (S2P/Ciel & Espace, YouTube channel), Guillaume Blanchard (ESO), Pierre Guiot and Cateline Lantz (IAS), not forgetting the Imagine Optic teams.

The post Adaptive optics for Free Space Optics… and for fun! appeared first on Imagine Optic.

Lattice Light-Sheet with Adaptive Optics: precise and robust aberration correction in thick samples.

ImagineAdmin — Thu, 01 Dec 2022 09:34:34 +0000

Light-Sheet Fluorescence Microscopy, a successful bio-imaging method.

As a remarkable answer to the growing interest in rapid 3D visualization of biological samples in vivo, Light-sheet Fluorescence Microscopy (LSFM) has become a valuable tool for biologists. Indeed, it enables optical sectioning of a sample with low photo-toxicity and low photo-bleaching at a very fast imaging rate. Many implementations of LSFM now exist, with a great number of commercial and home-made solutions. Among all those instruments, Lattice Light-Sheet Microscopy (LLSM) stands out as one of the most efficient techniques for fast 3D imaging at sub-cellular scale. However, sample-induced aberrations are still limiting for in-depth observations inside thick tissues.

Active Image Optimization (AIO) enables deeper and better resolved LLSM

To get rid of these aberrations, Adaptive Optics (AO) was integrated in some LLSM setups, providing signal and resolution enhancement, but often at the cost of much more complex systems. In order to propose a simpler and cheaper solution, a team of researchers from Université de Bordeaux (CNRS, France) and Imagine Optic recently developed an original approach, so-called Active Image Optimization (AIO) (full publication here : https://doi.org/10.1364/BOE.471757).

The AIO method is based on two steps : first, an original light-sheet auto-focus process using a sequence of sample images ensures accurate coplanarity between the illumination & imaging planes, then a sensorless, image-based iterative AO optimization is performed, providing aberration correction at the emission path. Based on this method, the authors determined an optimal merit factor for their samples of interest, i.e. fixed organotypic mouse brain slices. As a proof of the efficiency of AIO, researchers were able to retrieve normal average spine head sizes down to 40 µm, as compared to enlarged structures imaged without AIO.

The developed setup corresponds to both hardware and software add-ons to a standard LLSM system, based on AO kit Bio, a set of adaptive optics components (HASO 4 First Shack-Hartmann WaveFront Sensor, MirAO 52-e deformable mirror and Wavekit Bio SDK) from Imagine Optic. This kit can be used in a various range of set-ups, such as in, for example, a conventional Light-Sheet microscope.

The post Lattice Light-Sheet with Adaptive Optics: precise and robust aberration correction in thick samples. appeared first on Imagine Optic.

One more prototype of a microscope with adaptive optics: this time for 2-photons!

ImagineAdmin — Tue, 19 Jul 2022 09:16:22 +0000

A custom-built 2-photon microscope incorporating a new, fast adaptive optics (AO) approach now provides its first AO-enhanced images.

When targeting high-resolution imaging of biological samples at large depths, non-linear microscopy, and in particular 2- or even 3-photon fluorescence microscopy, is usually a technique of choice. Due to near-infrared illumination and intrinsic optical sectioning capability, multiphoton microscopy provides deep 3D imaging with virtually no background and a great versatility enabled by the use of 2D scanning in the illumination path. This method is now widely employed for neuroimaging, particularly in scattering media such as rodent brain. However, as for all high-resolution optical microscopy techniques, its performance is severely reduced as a consequence of optical aberrations induced by the sample, especially in depth, which strongly degrades the illumination point spread function (PSF) resulting in a significant loss of signal and contrast.

Recently, we demonstrated a new, fast and simple AO approach, as well as its integration in a light-sheet microscope (more details here). This new AO method is based on direct wavefront sensing without the need for a guide star, enabling both fast correction (typ. 1 to 5 s) and reduction of the constraints of use. Aiming to provide users with an easy operation of AO in multiple microscopy modalities, Imagine Optic, together with a team of researchers from Ecole Supérieure de Physique et de Chimie Industrielle (ESPCI, France) and Ecole Normale Supérieure (ENS, France), adapted AO to the excitation path of a custom-built two photon microscope. This wavefront sensing approach was demonstrated to be particularly efficient in scattering conditions (publication here).

Our prototype microscope is using one of Mirao line of large stroke, high stability deformable mirrors and allowed us to acquire first images of ex vivo samples mainly consisting in fixed fluorescent mouse brain slices, at depths reaching 200µm (see upper figure, representing a maximum projection over 10µm brain slice). Only 4 iterations of the closed-loop optimization, corresponding to 2-3 seconds, were necessary to achieve this aberration correction. AO correction enabled an average three times increase of the signal, providing sharper morphological details such as axons or dendrites. These latest results have been recently presented at the SFO congress in Nice (France): Imperato S. et al., Extended scene adaptive optics for 2 photon Neuroimaging in the mouse brain, 05 Jul. 2022. They offer a great promise, specifically regarding the next steps of in vivo recording of functional signals, as well as product development.

These results have been achieved in the frame of the INOVAO project (funding Agence Nationale de la Recherche, ANR-18-CE19-0002).

#AdaptiveOptics #Microscopy

The post One more prototype of a microscope with adaptive optics: this time for 2-photons! appeared first on Imagine Optic.

Building a fast adaptive optics light-sheet microscope: first light !

ImagineAdmin — Tue, 14 Jun 2022 09:11:05 +0000

A custom-built light-sheet microscope containing our newly developed fast adaptive optics approach, is now ready for systematic testing with various biological samples.

Light-sheet fluorescence microscopy proved many advantages when imaging biological samples, providing high speed, low phototoxicity, large field of view, 3D capability together with optical sectioning. However, and in particular when imaging deep, sample-induced optical aberrations usually limit the image quality. Adaptive optics (AO) can compensate for such aberrations, but currently at the expense of either slow speed or complicated setups, which are not yet ready to be used routinely.

With the aim to provide a systematic benefit of using adaptive optics in light-sheet microscopy, Imagine Optic, together with a team of researchers from Ecole Supérieure de Physique et de Chimie Industrielle (ESPCI, France), developed a prototype of adaptive optics light-sheet fluorescence microscope. To compensate for sample-induced aberrations, this microscope contains a deformable mirror on the emission pathway and it can benefit from both sensorless and direct wavefront sensing-based adaptive optics approaches. The latter technology is based on our newly developed wavefront sensing approach (full description here) which enables fast adaptive optics correction – typically within 1 to 3 seconds – without the need for a guide star in the sample.

This new aberration detection and correction approach already demonstrated a significant improvement of the image quality in neuroscience samples (see an example here and in the previously mentioned publication). With this microscope setup we are now able to demonstrate and quantify the gain brought by adaptive optics in light-sheet microscopy for various biological samples. In particular it provides significant signal increase when imaging small structures close to the diffraction limit, especially when imaging deep, and/or when small signals need to be observed with a decent signal-to-noise ratio. Everybody who is interested in discussing AO for light-sheet and/or testing their samples are welcome to contact us.

These results have been achieved in the frame of the INOVAO project (funding Agence Nationale de la Recherche, ANR-18-CE19-0002).

The post Building a fast adaptive optics light-sheet microscope: first light ! appeared first on Imagine Optic.

Adaptive optics microscopy direct wavefront sensing approach is more resilient to scattering.

ImagineAdmin — Tue, 03 May 2022 09:50:31 +0000

Custom-designed Shack-Hartmann wavefront sensor enables accurate control of an adaptive optics loop in scattering conditions for the imaging of neuronal structures.

Adaptive Optics approaches in fluorescence microscopy

Although many Adaptive Optics (AO) approaches have been proposed in fluorescence microscopy, the presence of scattering deeper in biological samples, typically dictates the use of sensorless AO methods. In situations where scattering severely limits the use of a guide star, either based on fluorescent beads or involving a de-scan of fluorescence signal to enable the correction of optical aberrations, a classical Shack-Hartmann wavefront sensor cannot be used. However, sensorless AO – even if instrumentally simpler – provides a correction of aberrations at the cost of time-consuming iterative process of typically tens of seconds. Moreover, the quality of the correction is also driven by algorithmic parameters such as the choice of an adequate image quality metric.

Direct wavefront sensing for more accurate AO in microscopy

As a new step towards a faster and more accurate AO in microscopy even in scattering conditions, a team of researchers from Ecole Supérieure de Physique et de Chimie Industrielle (ESPCI, France), Ecole Normale Supérieure (ENS, France) and Imagine Optic recently proposed the use of an extended-source Shack-Hartmann wavefront sensor as a direct wavefront sensing device, which is more resilient to scattering than existing methods (full publication here). Even in low-signal to background conditions, a successful AO correction was demonstrated deep in the brain tissue in less than a second. Interestingly, researchers demonstrated that this device can also be used to quantitatively characterize the scattering properties of the sample.

As for all AO setups, the proposed method benefits from the almost perfect linearity of the wavefront corrector, in this case the Mirao 52e electromagnetic deformable mirror [FH1] , as well as from its high dynamic range and intrinsic achromaticity, e.g. considering its use in 2-photon microscopy setups. Keep posted to know more about our upcoming compact, high-resolution deformable mirror (µ-DM), that was recently presented here.

These results have been achieved in the frame of the INOVAO project (funding Agence Nationale de la Recherche, ANR-18-CE19-0002). #adaptive optics microscopy direct wavefront sensing

The post Adaptive optics microscopy direct wavefront sensing approach is more resilient to scattering. appeared first on Imagine Optic.

Nuclear pore complex imaging using adaptive optics

CharlotteAdmin — Tue, 22 Feb 2022 10:58:35 +0000

The group of Siegfried Musser from Texas AM University recently published an article in Nature Cell Biology where they used a MIRAO 52E deformable mirror to perform nuclear pore complex imaging using adaptive optics in super resolution. Super resolution microscopy techniques, such as PALM and STORM, open the possibility to visualize the smallest intracellular components, lying well beyond the diffraction limit of light and which are not otherwise accessible using conventional fluorescence microscopy methods. One of such small intracellular structures, is a nuclear pore complex (NPC). Embedded in the nucleus membrane NPCs are massive multiprotein complexes that act as passageways for the transport of molecules into and out of the nucleus. With a molecular mass of 125 MDa in vertebrates, the NPC is one of the largest and most complex protein structures of eukaryotic cells and yet is still smaller than diffraction limit.

Breaking the diffraction limit

While numerous 3D light microscopy methods have been developed over the last few decades, single-molecule astigmatism imaging provides the highest spatial localization precision in X, Y and Z, and its useful Z-range matches well to that necessary to monitor cargo trafficking through NPCs. Although the simplest approach to achieve astigmatism imaging is via a cylindrical lens, here researchers used MIRAO 52E deformable mirror both to correct sample-induced aberrations and to add a small amount of astigmatism for 3D imaging. This way they demonstrated exceptional-quality calibration curves which ensured the highest localization precision in Z.

Nuclear pore complex imaging using adaptive optics: the Z calibration and localization precision using 60nm rms astigmatism introduced with the deformable mirror. (d) The Z dependence of spot widths in X and Y was obtained from Z-stack images (100ms/frame, 41 steps, step size 25nm) of five different 100nm beads embedded in 2% agarose, λ(ex)=647nm; ~2,500–3,500 photons per spot. (e) The difference between X and Y widths was approximately linearly dependent with Z. (f) The variation of X, Y and Z localization precision values along the Z axis. Localization precisions were defined as the standard deviation of position in X, Y and Z over 100 images of 100nm beads.

Even though here researchers decided to implement standalone adaptive optics components, the same results could be obtained using MICAO 3DSR – a plug & play adaptive optics system from Imagine Optic. This device is compatible with any inverted-frame microscope and our MICAO 3DSR offer automatically includes installation services and long-term support in order to create a hassle-free experience for our customers.

If you’re interested in finding out more about our line of Microscopy and Adaptive Optics solutions, you can reach us at sales@imagine-optic.com or through the contact form (red enveloppe on the side).

The post Nuclear pore complex imaging using adaptive optics appeared first on Imagine Optic.

Adaptive Optics Light-Sheet Microscopy for functional Neuroimaging

CharlotteAdmin — Fri, 16 Jul 2021 16:38:55 +0000

Watch or rewatch the presentation given by Antoine Hubert (Imagine Optic and ESPCI) at the European Conference on Biomedical Optics (ECBO) on June 21st. Antoine presents his latest results on an Extended-Scene Shack-Hartmann wavefront sensing-based adaptive optics system for light-sheet microscopy in the drosophila brain.

If you’re interested in finding out more about our line of Wavefront Sensors and Deformable Mirrors or Adative Optics solutions for Microscopy, you can reach us at sales@imagine-optic.com or through the contact form (red enveloppe on the side).

The post Adaptive Optics Light-Sheet Microscopy for functional Neuroimaging appeared first on Imagine Optic.

WaveSuite goes full 64 bits: 3x processing speed, no-limit RAM & M2

CharlotteAdmin — Tue, 13 Jul 2021 10:22:49 +0000

WaveSuite 4.3 optical metrology and adaptive optics software completes the full transition to 64-bit compilation and overhauls previous limitations in RAM management and processing speed linked to 32-bit architecture legacy.

This version of WaveSuite is a landmark for metrology and Adaptive Optics software, bringing huge benefits to our clients and users and synchronizing the version numbering of the three softwares:
– Waveview 4.3, the bench mark in wavefront metrology
– Wavetune 4.3, for perfect loop control
– Wavekit 4.3, a versatile and comprehensive SDK in C, LabVIEW and Python.

The first benefit is the end of the 4 GB RAM limit, allowing virtually unlimited image buffers and/or up to 4x phase point measurement at full speed. All applications’ performance will benefit from this breakthrough, especially those involving high-frequency/high-resolution sampling.

The second major benefit is to processing speed, with computing speed up 3x allowing for quicker calculations of wavefronts, intensity, PSF, MTF, and most importantly the LIFT algorithms that power our new HASO LIFT series with 272 x 200 and 680 x 500 phase point sampling.

Last but not least, the M2 function returns, thanks to these memory and speed improvements with better than laser beam simulations.

WaveSuite4.3 is the version currently being delivered with new wavefront sensors, optical metrology systems and deformable mirrors. It will soon be available as an upgrade for compatible hardware. If you would like more information, please get in touch with us at sales@imagine-optic.com.

The post WaveSuite goes full 64 bits: 3x processing speed, no-limit RAM & M2 appeared first on Imagine Optic.