Steve Simmert scite author profile

The cytoskeleton gives a cell its shape and plays a major role in its movement and division. It's also helps organise the content of cells and is the base for intracellular transport. Important components of the cytoskeleton are microtubules, which are hollow cylindrical beams (25 nm in diameter) that assemble from protein building blocks called tubulin. Deficiencies in microtubules are related to many diseases including cancer and Alzheimer. Given their important role, microtubules are heavily investigated in many laboratories. One way to study microtubules is to isolate them from cells and image them using light microscopy. Over the years a number of imaging techniques have been used. These techniques have a number of drawbacks which are addressed by ongoing efforts which this work is a part of. Here, we present a method based on light interference that produce high quality images of microtubules. The technique is cheap and easy to implement making it accessible to a wide base of researchers.

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LED-based interference-reflection microscopy combined with optical tweezers for quantitative three-dimensional microtubule imaging

Simmert¹,

Abdosamadi²,

Hermsdorf³

et al. 2018

Opt. Express

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Optical tweezers combined with various microscopy techniques are a versatile tool for single-molecule force spectroscopy. However, some combinations may compromise measurements. Here, we combined optical tweezers with total-internal-reflection-fluorescence (TIRF) and interference-reflection microscopy (IRM). Using a light-emitting diode (LED) for IRM illumination, we show that single microtubules can be imaged with high contrast. Furthermore, we converted the IRM interference pattern of an upward bent microtubule to its three-dimensional (3D) profile calibrated against the optical tweezers and evanescent TIRF field. In general, LED-based IRM is a powerful method for high-contrast 3D microscopy.

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Label-free high-speed wide-field imaging of single microtubules using interference reflection microscopy

Mahamdeh

Simmert²,

Łuchniak

et al. 2018

Preprint

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SummaryWhen studying microtubules in vitro, label free imaging of single microtubules is necessary when the quantity of purified tubulin is too low for efficient fluorescent labeling or there is concern that labelling will disrupt its function. Commonly used techniques for observing unlabeled microtubules, such as video enhanced differential interference contrast, dark-field and more recently laser-based interferometric scattering microscopy, suffer from a number of drawbacks. The contrast of differential interference contrast images depends on the orientation of the microtubules, dark-field is highly sensitive to impurities and optical misalignments, and interferometric scattering has a limited field of view. In addition, all of these techniques require costly optical components such as Nomarski prisms, dark-field condensers, lasers and laser scanners. Here we show that single microtubules can be imaged at high speed and with high contrast using interference reflection microscopy without the aforementioned drawbacks. Interference reflection microscopy is simple to implement, requiring only the incorporation of a 50/50 mirror instead of a dichroic in a fluorescence microscope, and with appropriate microscope settings has similar signal-to-noise ratio to differential interference contrast and fluorescence. We demonstrated the utility of interference reflection microscopy by high speed imaging and tracking of dynamic microtubules at 100 frames per second. In conclusion, the image quality of interference reflection microscopy is similar to or exceeds that of all other techniques and, with minimal microscope modification, can be used to study the dynamics of unlabeled microtubules.

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LED-based interference-reflection microscopy combined with optical tweezers for quantitative three-dimensional single microtubule imaging

Simmert

Abdosamadi

Hermsdorf

et al. 2018

Preprint

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Optical tweezers combined with various microscopy techniques are a versatile tool for single-molecule force spectroscopy. However, some combinations may compromise measurements. Here, we combined optical tweezers with total-internal-reflection-fluorescence (TIRF) and interference-reflection microscopy (IRM). Using a light-emitting diode (LED) for IRM illumination, we show that single microtubules can be resolved with high contrast. Furthermore, we converted the IRM interference pattern of an upward bent microtubule to its three-dimensional (3D) profile calibrated against the optical tweezers and evanescent TIRF field. In general, LED-based IRM is a powerful method for high-resolution 3D microscopy.OCIS codes: (180.3170) Interference microscopy; (120.4570) Optical design of instruments (350.4855); Optical tweezers or optical manipulation.

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Label Free High Speed Wide Field Imaging of Single Microtubules using Interference Reflection Microscopy

Mahamdeh

Simmert

Łuchniak

et al. 2018

Biophysical Journal

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Steve Simmert

Label‐free high‐speed wide‐field imaging of single microtubules using interference reflection microscopy

LED-based interference-reflection microscopy combined with optical tweezers for quantitative three-dimensional microtubule imaging

Label-free high-speed wide-field imaging of single microtubules using interference reflection microscopy

LED-based interference-reflection microscopy combined with optical tweezers for quantitative three-dimensional single microtubule imaging

Label Free High Speed Wide Field Imaging of Single Microtubules using Interference Reflection Microscopy

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