This comprehensive guide provides detailed instructions for upgrading the system to the two-photon configuration. Assuming that you have already built the one-photon version of the system, the upgrade primarily involves two main steps. First, you need to fiber couple a two-photon femtosecond pulsed laser into a negative hollow-core optical fiber. Additionally, the fiber's numerical aperture at the output side should be increased for compatibility with the light-sheet unit. Secondly, if not already implemented, the objectives used in the light-sheet unit must be replaced with objectives optimized for near-infrared transmission. Finally, a filter must be installed in the detection path to block the infrared laser. These modifications will enable efficient two-photon imaging with the system.
- Part List
- Building Instructions
- Multiphoton Light-Sheet Unit
- A Comprehensive Guide for Achieving Efficient Fiber Coupling of the Femtosecond Two-Photon Laser
- Introducing Our Developed Negative Curvature Hollow Core Crystal Fiber
- The Optical Path for Laser-to-Fiber Coupling
- Tips and Techniques for Laser Coupling into the Broadband Hollowcore Crystal Fiber
- Mastering the Handling of Hollow Core Fibers: Tips and Techniques
- Selecting the Optimal Coupling Lens: Criteria and Considerations
- Let's Get Started: Building the System
- Increasing the Fiber Numerical Aperture for Compatibility with the Light-Sheet Unit
- Modifying the Fluorescence Detection Path to Block Infrared Illumination
- Alignement of the setup
- Example of High-Resolution Zebrafish Brain Recordings in One- and Two-Photon Mode (elav3:H2B-GCaMP6)
Table of contents generated with markdown-toc
These parts are milled from an aluminum block. If you do not have a mechanical workshop in-house then you can send the *.step files that we provide below to an online milling service. For parts with threaded holes, join the mechanical drawings to the .step file.
- Custom part for compatibility with a MaiTai laser: View the 3D model or download the CAD model as a step file and the Mechanical drawing.
The multiphoton light-sheet unit is basically identical in its design to the one-photon multicolor design. To build the two-photon system follow the building instruction of the 1P-Multicolor system but take into account the following modification:
For both the collimation and illumination objectives (step (9) of the building instruction of the Light-sheet Unit), use the Olympus LMPLN5xIR/0.1 objective optimized for near-infrared transmission. Although it is not optimized for visible wavelength, one can use this objective for one-photon imaging as well. To screw it into the light-sheet cube use a thread adaptor.
Together with GLO Photonics, we selected an HC-NCF fiber whose optical characteristics are ideally suited for laser delivery in the context of combined one- and two-photon light-sheet microscopy.
The outer fiber diameter is 200 ± 2 μm and the fiber coating diameter is 600 ± 30 μm. The fiber has an air-filled 30 μm-in-diameter core surrounded by a ring of eight non-contacting ~10 μm-in-diameter cladding tubes. In this so-called hypocycloid fiber structure, the negative curvature of the core contour is created by the tubes surrounding the core. Tube diameters, inter-tube distance, tube wall thickness, and core size together control the fiber transmission spectrum. They yield two broad transmission bands that are compatible with 1, 2, and 3P imaging, respectively (see figure above): One in the near-infrared from 700 - 1500 nm (I), and another in the visible spectrum from 400 - 535 nm (II). Within these spectral bands, the loss is less than 300 dB/km (corresponding to a transmission efficiency of more than 93% for a one-meter-long fiber), and the pulse dispersion is less than 1 ps/(nm·km) of spectral pulse width.
The fiber is commercially available as a patch chord cable with standard FC/PC connectors. This proves extremely convenient as it allows one to disconnect and reconnect the fiber to the optical setup without the need for subsequent realignment on either end. The small core diameter compared to the infrared wavelength further ensures near single-mode guidance.
The Gaussian beam properties of the laser are also well preserved at the fiber output with M^2 values of 1.23 and 1.18, measured at 1030 nm and 515 nm laser wavelength respectively. The near-field and far-field profiles are symmetric with minimal ellipticity of 97.25% and 85.57%. The mode field diameters at 1/e^2 are 23 ± 1 μm and 26 ± 1 μm, respectively, which correspond to a fiber's numerical aperture (NA) of approximately 0.02. Due to negligible interactions between the light and the fiber material, the fiber exhibits a very high damage threshold: we could not observe any fiber damage up to the maximal tested peak powers of 40 μJ at 1030 nm and 10 μJ at 515 nm for 400 fs pulses, corresponding to an average laser power of 20W and 4W, respectively. These characteristics demonstrate that high-quality Gaussian beams can be delivered with this fiber across a broad spectral range with high transmission and low dispersion, which is a prerequisite for its application in high-resolution microscopy.
The following schematic and 3D model that you can interactively explore show a possible optical path for the laser coupling. You can adapt the arrangement to the space availability on your setup (mirror, M, lens, L, dichroic, D, wave plate, W, polarizer, P, beam trap, BT):
If you do not have space on your table you can mount a platform on top of your IR-pulsed laser source and bring the laser beam with a periscope up to the platform.
In the following, we propose a step-by-step explanation of how to build this optical path and how to align the optical components to achieve optimal fiber coupling. But before we begin, we will give some preparatory notes and general background:
For the alignment we will follow a protocol well explained in an excellent YouTube tutorial that you find here and that we advise you to watch carefully before starting. The video explains a first pre-alignment step based on the backpropagation of a laser in the reverse direction. To use this trick first connect a standard single-mode fiber to the coupling unit. Use a fiber tester to inject a visible laser through the fiber. Then follow the steps as in the tutorial to co-align the alignment laser and the IR laser. Then disconnect the fiber and connect the hollow core fiber. If the first step was done correctly you should have enough transmission through the fiber to be able to further optimize the fiber coupling as described in the tutorial. To watch the video just click on the snapshot:
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Here you find the fiber spec sheet of our hollow-core negative curvature fiber
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Attention !: The hollow core fiber front face is not protected and cannot be easily polished, which is a standard procedure used for conventional single-mode fibers. Work clean and remove dust before connecting the fiber to a porte. Also never try to clean the fiber outlet with ethanol or acetone because these solutions will enter the fiber core by capillary forces making the fiber unusable. You can use a fiber inspection scope to inspect the fiber core.
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The fiber has a very high damage threshold but only if the laser is well coupled. So it is advised to do the alignment procedure at low laser power. This improves also laser safety. You can control the laser intensity with a rotatable lambda wave plate installed in series with a polarizor.
- For efficient optical coupling and suppression of higher laser modes, the diameter of the laser spot projected onto the fiber input side has to match the mode field diameter of the fiber. Or in other words, the opening angle of the focused laser beam has to match the numerical aperture of the fiber. Our fiber has a numerical aperture of 0.02 (see fiber spec sheet). The numerical aperture of the coupling system is given by
$\textrm{NA} = \frac{D}{2 f}$ , with$D$ the diameter of the laser beam at the position of the coupling lens, and$f$ the coupling lens' focal length. The laser company normally gives the beam width and the beam divergent angle. In our case, the Ti:Sapphire laser (MaiTai, Coherent, USA) has an output beam waist$<1.2\textrm{mm}$ and a divergent angle of$<0.001\textrm{mrad}$ . We measured a beam diameter of 1.6mm at the position where we decided to install the coupling unit and we thus chose a coupling lens with focal length$f = \frac{D}{2\textrm{NA}} = \frac{1.6\textrm{mm}}{2\cdot 0.02} = 40\textrm{mm}$ . We got reasonable coupling with the achromatic coupling lens. If you want to further optimize the coupling you can use an objective as coupling lens. And you can install a telescope to adjust the beam diameter to match the fiber numerical aperture with the chosen coupling lens focal distance. Further tips for fiber coupling can be found in the manual from GLO-photonics. - To measure the laser beam diameter, you may use either a beam profiler (Thorlabs BC207VIS/M) or the moving knife technique. For the latter, fix a razor plate on a linear translation stage. For this use a thin plate holder, a right angle clamp and a post system. Then move the knife perpendicular to the laser path step-by-step out of the laser beam while measuring the laser intensity as a function of the knife-edge position. The measured normalized power as a function of knife-edge position,
$x$ , can be fitted by$P_N(x)=0.5\left[1 + erf \left(\frac{x-x0}{w_{e^{-1}}}\right)\right]$ . The fit parameter$w_{e^{-1}}$ is the beam radius at$e^{-1}$ . You can also read$w_{e^{-1}}$ from the graph as half of the distance between the positions where the normalized power has a value between 0.08 and 0.92. Note that the beam diameter,$D$ ,relevant to calculate the numerical aperture is measured at$e^{-2}$ and is thus given by$D = 2 \cdot w_{e^{-2}} = 2 \cdot \sqrt{2} w_{e^{-1}}$
- Position the motorized flip mount (FM) holding a protected silver mirror directly after the infrared laser output to hijack the laser for coupling into the optical fiber. Flipping the mirror allows you to select the setup into which you want to direct the laser. Alternatively, you can use a beam splitter to use the laser source on both setups simultaneously. The pertinence of the latter solution depends on the laser power that you need in both setups for your experiments. For a standard scanning two-photon system, you will generally need less than 100mW. A MaiTai laser has an average output power of 1.8W at 915nm wavelength. With a 90:10% beam splitter and assuming 50% loss of laser power until the sample you can perform light-sheet microscopy with an average laser power of 400mW and two-photon scanning on the standard system with a mean power of 90mW.
- Next install the optics to control the laser intensity. Position the lambda wave plate and the polarizor in series.
- Before switching on the laser, prepare for laser safety in the room and wear laser safety glasses to protect your eyes!
- Install the power meter to measure the laser power after the polarizer (P)
- Switch on the laser and rotate the wave plate until the transmitted laser power is minimal.
- Increase again slowly the laser power until you start seeing the laser spot on the IR detection card
- Close the laser shutter
- Position the two protected silver mirrors (M1, M2 & M3) mounted in kinematic mirror mounts. With mirror M2 and M3 you will later align the laser with the fiber axis. A good distance between these two mirrors is about 20cm. Adjust the height of the posts that hold the mirrors with the height of your laser beam. Tighten them on the optical table with Universal Post Holders.
- Install the long pass dichroic mirror (D) that is transparent for the infrared laser but reflects the visible spectrum. This will allow later the coupling of an additional visible laser into the same fiber.
- Mount the differential xyz-translation stage (MAX313D/M) at about 20cm from the mirror M3. With this stage, you will position the fiber outlet precisely into the focal point of the coupling lens. You might have to mount this stage on a platform to match the beam height (Custom piece for compatibility with a MaiTai laser: Mechanical drawing, .stl file and .step file). Alternatively, you can lower the beam path with a periscope.
- Install the half-wave plate (W2) mounted in a high-precision rotation mount to adjust the polarization of the laser. For the highest signal in two-photon microscopy, the laser polarisation needs to be aligned with the light-sheet plane. You can do this later by rotating this waveplate until you observe a maximum of the fluorescence signal.
- Fix the mounting bracket onto the non-moving front of the xyz-stage and mount onto it a SM1-Compatible Flexure Stage Mount to hold the coupling lens L1.
- Screw the coupling lens into the holder (AC254-040-B-ML)
- Mount the SM1-compatible flexure stage mount onto the moving platform of the xyz-stage and screw into this mount the FC/PC fiber adapter plate with its external SM1 threading. This FC/PC adapter will later receive the optical fiber.
- Attach the single mode fiber for prealignment to the FC/PC adaptor plate.
- Attach the other side of the fiber to the cable continuity tester for pre-alignment.
- Switch on the red laser of the continuity tester. You should see the laser exiting out of the other side of the fiber
- Adjust the distance of the coupling lens (L1) relative to the fiber outlet until the red laser light from the continuity tester is well collimated by the coupling lens.
- Now follow the alignment steps explained in the YouTube tutorial. Eventually, watch the video again.
- Now that you know how to do it ensure laser safety in the room and wear laser safety glasses to protect your eyes!
- Prepare a VIS/IR Detector Card to visualize the invisible infrared laser
- Open the laser shutter.
- Now move the two mirrors M2 and M3 to co-align the red laser and the IR laser as was explained in the video.
- Switch off the laser shutter
- Detach the single-mode fiber from the coupling unit
- Attach the negative curvature broadband hollow core fiber to the coupling unit.
- Position the power meter before the coupling lens and adjust the power to about ???mW.
- Install an FC/PC adaptor plate and fix to it the other end of the fiber. Install the power meter just after the fiber to measure the transmitted laser power.
- Open again the laser shutter. You should measure laser transmission through the fiber.
- Now adjust the mirrors M2 and M3 as was described in the video until you get > 90% laser transmission.
- Close the laser shutter
- Fix the fiber coupled laser onto the table.
- Position mirror M3 and M4 with a distance of about 20cm between each other such that mirror M4 is placed about 20cm from the coupling lens. As mirrors choose again protected silver mirrors mounted in kinematic mirror mounts to align the laser with the fiber axis. Select the length of the posts compatible with the height of your laser beam.
- Attach the fiber splitter to the laser that you purchased with the prealigned fiber coupler.
- Install a prealigned fiber collimators L2 that you mount into a kinematic mirror mount using an adaptor and positioned onto the adequate posts and its universal post holder.
- We selected the collimation lens focal distance with the formula:
$f_{collimation} = f_{coupling} \cdot \frac{NA_{fiber}}{NA_{laser fiber}} = 40\textrm{mm} \cdot \frac{0.02}{0.13}$ which boils down to the fact to choose the collimation lens focal distance such that the collimated laser beam diameter matches the diameter of the infrared beam that we previously coupled into the fiber using the chosen coupling lens.
- We selected the collimation lens focal distance with the formula:
- Attach one of the outputs of the fiber coupler to this collimator lens.
- Attach the other side to the FC/PC connector plate on the xyz-stage of the coupling unit. If the fiber is to short you can extend it with a fiber-to-fiber connector and the single mode fiber that you have used in the previous pre-alignment step.
- prepare laser safety and switch on the laser at the lowest power possible where you can see with the VIS/IR Detector Card the laser.
- Now use the mirror M3 and M4 to co-align the two laser beams that travel in the reverse direction through the system as explained in the alignment YouTube tutorial.
- Switch off the laser and replace the single-mode fiber that is connected to the coupling unit with the negative curvature fiber.
- Switch the laser again on.
- You should detect with the power meter a transmission through the fiber.
- Adjust mirror M3 and M4 until you have more than 75% percent of transmission
At 915nm wavelength, the central two-photon absorption peak of GFP and of its calcium sensitive derivative GCaMP, we delivered through 1.5m fiber length 100fs laser pulses with 98% power transmission efficiency and minute pulse dispersion of 28nm (1dB/km·nm) that we fully precompensated with the Deepsee element of the MaiTai laser source. At 488nm, the one-photon excitation maximum of GFP and GCaMP, we achieved a transmission efficiency of ~75%.
- The collimation and illumination objective form a one-to-one telescope. If we would simply connect the hollow core fiber to the light-sheet unit as we did in the 1P-Multicolor system then the light-sheet thickness would correspond to the mean field diameter of the hollow core fiber which is
$23\mu m$ (fiber spec sheet). To get the same resolution as in the one-photon implementation we have to install an extra lens after the fiber to demagnify the laser waist from the fiber output to about$5\mu m$ and at the same time to increase the divergence angle of the laser to match the numerical aperture of the collimation objective. The numerical aperture of the fiber is 0.02 and thus a factor 5 times smaller compared to the numerical aperture of the detection objective. - With a lens with a focal distance of f = 2mm and a numerical aperture of 0.5 you can demagnify the laser output from the fiber by a magnification of m = 0.2. Mount this lens via an adaptor into the lens tube which you prepared in step (5-7) of the manual of the 1P-Multicolor unit.
- Place the lens at a distance
$s = f \left( \frac{1}{m} - 1\right) = f \left( 5 - 1\right) = 4 \cdot f = 8\textrm{mm}$ after the fiber output. The lens refocuses the laser at a new position$s' = f \cdot \left[ 1 + \frac{1}{s/f - 1} \right] = 1.2 \cdot f = 2.4\textrm{mm}$ after the lens down to a waist of$w_0^{'} = m \cdot w_0 = 0.2 \cdot 23 \mu m = 4.6\mu m$ with an angle of divergence of the laser corresponding to a numerical aperture of$m \cdot 0.02 = 0.1$ thus matching the numerical aperture of the collimation objective.
Focusing of spherical Gaussian beams by Sidney A. Self
- Install in addition the multiphoton short-pass emission filter to block also the pulsed infrared laser source.
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Align the system in one-photon mode following the instructions provided for the 1P-Multiphoton system. This alignment procedure will also align the two-photon pathway.
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Align the polarization of the two-photon laser within the light-sheet plane. Visualize the two-photon laser using a fluorescein solution. Rotate wave plate W2, which is installed in front of the xyz-translation stage in the fiber coupling optical pathway. Continue rotating the wave plate until the fluorescence signal is maximized, indicating the optimal position.
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Note that the alignment and transmission efficiency of the hollow-core fiber in the infrared are not affected by fiber bendings. However, bending the fiber will indeed affect the polarization by changing its direction and ellipticity. Once you have set the rotation angle of wave plate W2, it is crucial not to move the fiber any further. If the fiber is inadvertently moved, the rotation angle of the wave plate will need to be readjusted accordingly to ensure optimal performance. For further information regarding the dependency of light-sheet fluorescence microscopy on polarization, please refer to Vito et al. Optic Express 2020.
Example of High-Resolution Zebrafish Brain Recordings in One- and Two-Photon Mode (elav3:H2B-GCaMP6)
- Left: one-photon mode excited @ 488nm
- Right: two-photon mode excited @ 915nm