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start [2017/07/20 19:56] Jon Daniels [The Implementation] |
start [2024/05/01 09:37] (current) Jon Daniels [The Implementation] |
===== The Idea ===== | ===== The Idea ===== |
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The //diSPIM// is a flexible and easy-to-use implementation of Selective Plane Illumination Microscopy (//SPIM//) that allows for dual views (//d//) of the sample while mounted on an inverted (//i//) microscope. The diSPIM was co-developed by the lab of [[http://www.nibib.nih.gov/about-nibib/staff/hari-shroff|Hari Shroff]] at NIH/NIBIB and [[http://www.asiimaging.com/|Applied Scientific Instrumentation]] (ASI). SPIM is also referred to as [[http://en.wikipedia.org/wiki/Light_sheet_fluorescence_microscopy|light sheet fluorescence microscopy]] or LSFM because it uses a sheet or plane of light to illuminate the sample perpendicular to the imaging direction. | The //diSPIM// is a flexible and easy-to-use implementation of Selective Plane Illumination Microscopy (//SPIM//) that allows for dual views (//d//) of the sample while mounted on an inverted (//i//) microscope (i.e. the SPIM objectives are upright). The diSPIM was co-developed by the lab of [[http://www.nibib.nih.gov/about-nibib/staff/hari-shroff|Hari Shroff]] at NIH/NIBIB and [[http://www.asiimaging.com/|Applied Scientific Instrumentation]] (ASI). SPIM is also referred to as [[http://en.wikipedia.org/wiki/Light_sheet_fluorescence_microscopy|light sheet fluorescence microscopy]] or LSFM because it uses a sheet or plane of light to illuminate the sample perpendicular to the imaging direction. |
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===== The Implementation ===== | ===== The Implementation ===== |
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Two objectives are placed at right angles above a sample mounted horizontally in an open dish, each objective 45 degrees from vertical. A light sheet is created from one objective and imaged using the other objective. A stack of images is collected by moving the light sheet through the sample. For a few users, the 3D information from a single view or stack is sufficient (iSPIM). For dual-view systems, the role of the two objectives is reversed to collect another stack from a perpendicular direction, and then the two datasets can be computationally merged to yield a 3D dataset with isotropic resolution (the usual problem of poor axial resolution is overcome by information from the other view). The dual-view diSPIM thus has two (usually symmetric) optical paths including two scanners and two cameras. | Two objectives are placed at right angles above a sample mounted horizontally in an open dish, usually each objective 45 degrees from vertical. A light sheet is created from one objective and imaged using the other objective. A stack of images is collected by moving the light sheet through the sample. For some applications the 3D information from a single view or stack is sufficient (iSPIM). For dual-view systems, the role of the two objectives is reversed to collect another stack from a perpendicular direction, and then the two datasets can be computationally merged to yield a 3D dataset with isotropic resolution (the usual problem of poor axial resolution is overcome by information from the other view). The dual-view diSPIM thus has two (usually symmetric) optical paths including two scanners and two cameras. iSPIM is a subset of diSPIM with a single camera and scanner but otherwise nearly identical. |
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{{ :dispim_on_ramm.jpg?direct&250|}} | {{ :dispim_on_ramm.jpg?direct&250|}} |
The diSPIM "head" can be mounted on various inverted microscopes including ASI's RAMM frame (shown here). diSPIM systems can be obtained from various [[docs:system integrators]]. Various open-source and proprietary software packages are available for both data acquisition and data processing. Most of the underlying microscope hardware is identical regardless of the system integrator and software used. | The diSPIM "head" can be mounted on various inverted microscopes including ASI's RAMM frame (shown here). diSPIM systems can be obtained from various [[docs:system integrators]]. Various open-source and proprietary software packages are available for both data acquisition and data processing. Most of the underlying microscope hardware is identical regardless of the system integrator and software used. |
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The choice of diSPIM objectives is limited because they must be co-focused without bumping into each other. The most commonly-used objectives for diSPIM are 40x water-dipping objectives with a NA of 0.8 (Nikon CFI Apo 40XW NIR). The Olympus 20x/0.5 objective is another possibility((According to the manufacturer's drawings the objectives co-focus exactly when they touch, which also implies zero gap between objective and coverslip. However, in practice they co-focus with a gap comparable to the 40x/0.8, with ~200um between the objective bottom and coverslip.)) as is the Nikon 10x/0.3. ASI and Special Optics have co-developed an [[http://www.asiimaging.com/index.php/cleared-tissue-objective|custom objective for cleared tissue]] that is suitable for the diSPIM and can image cleared tissue up to 5 mm deep in slab form or within a 12 mm spherical envelope. Single-sided systems (iSPIM) have much more flexibility because the illumination objective can be a low-NA long-WD objective. | The choice of diSPIM objectives is limited because they must be co-focused without bumping into each other. The most commonly-used objectives for diSPIM are 40x water-dipping objectives with a NA of 0.8 (Nikon CFI Apo 40XW NIR). The Olympus 20x/0.5 objective is another possibility((According to the manufacturer's drawings the objectives co-focus exactly when they touch, which also implies zero gap between objective and coverslip. However, in practice they co-focus with a gap comparable to the 40x/0.8, with ~200um between the objective bottom and coverslip.)) as is the Nikon 10x/0.3. ASI and Special Optics have co-developed two [[http://asiimaging.com/docs/cleared_tissue_objective|objectives for cleared tissue]] that are suitable for the diSPIM and can image cleared tissue up to 5 mm deep in slab form or within a 12 mm spherical envelope. Single-sided systems (iSPIM) have much more flexibility because the illumination objective can be a low-NA long-WD objective. |
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Most often sCMOS cameras are used for SPIM imaging. There are working diSPIM systems with Hamamatsu Flash4, Andor Zyla, and PCO Edge cameras, and support for Photometrics Prime 95B was added May 2017. | Most often sCMOS cameras are used for SPIM imaging. There are working diSPIM systems with Hamamatsu Flash4 and Fusion, Andor Zyla, PCO Edge, and Photometrics Prime 95B cameras. |
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ASI makes a compact fiber-coupled 2D galvo or "scanner" which is an integral part of the system. The original version of the scanner creates the light sheet by fast scanning in one axis and moves the sheet through the sample using the other axis ((i.e. the diSPIM is a digital light sheet microscope or DLSM in its original implementation)). There is also a scanner version with a cylindrical lens for static light sheet generation available from ASI as of end-2016. The output of the excitation laser (or laser launch) simply is fed into the scanner; it is helpful to have a 2x1 optical switch or dual-output laser launch so the excitation can all be steered to the scanner in the active light path. | ASI makes a compact fiber-coupled 2D galvo or "scanner" which is an integral part of the system. The original version of the scanner creates the light sheet by fast scanning in one axis and moves the sheet through the sample using the other axis ((i.e. the diSPIM is a digital light sheet microscope or DLSM in its original implementation)). There is also a scanner version with a cylindrical lens for static light sheet generation available. The output of the excitation laser (or laser launch) simply is fed into the scanner; it is helpful to have a 2x1 optical switch or dual-output laser launch so the excitation can all be steered to the scanner in the active light path. |
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For applications where [[hardware:environmental control]] is important, the diSPIM can easily be fitted with an incubator enclosure and appropriate equipment to keep samples alive and happy. | For applications where [[hardware:environmental control]] is important, the diSPIM can easily be fitted with an incubator enclosure and appropriate equipment to keep samples alive and happy. |
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The bottom objective (the inverted microscope) typically has a lower-magnification objective and less expensive camera for locating the sample. Epi-illumination can easily be added. | The bottom objective (the inverted microscope) typically has a lower-magnification objective and less expensive camera for locating the sample. Epi-illumination can easily be added. |
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| For dedicated cleared tissue imaging setups the ct-dSPIM variant is employed where the SPIM head is mounted on posts and the sample is placed on an XYZ stage (usually without an inverted microscope but it is possible to add one). This has advantages especially for larger samples. |
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