A compact holographic optical tweezers instrument

Gibson, Graham M.; Bowman, Richard; Linnenberger, Anna; Dienerowitz, Maria; Phillips, David B.; Carberry, David M.; Miles, Mervyn J; Padgett, Miles J.

doi:10.1063/1.4768303

Cited by 38 publications

(23 citation statements)

References 42 publications

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“…1 and 2, is similar to that of our recent work developing a compact optical tweezer system [20]. Focussing is achieved by moving the objective lens on a motorised stage (LS-50-M, ASI) which is mounted vertically within the aluminium frame of the microscope.…”

Section: Designmentioning

confidence: 85%

A multi-modal stereo microscope based on a spatial light modulator

et al. 2013

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Spatial Light Modulators (SLMs) can emulate the classic microscopy techniques, including differential interference (DIC) contrast and (spiral) phase contrast. Their programmability entails the benefit of flexibility or the option to multiplex images, for single-shot quantitative imaging or for simultaneous multi-plane imaging (depth-of-field multiplexing). We report the development of a microscope sharing many of the previously demonstrated capabilities, within a holographic implementation of a stereo microscope. Furthermore, we use the SLM to combine stereo microscopy with a refocusing filter and with a darkfield filter. The instrument is built around a custom inverted microscope and equipped with an SLM which gives various imaging modes laterally displaced on the same camera chip. In addition, there is a wide angle camera for visualisation of a larger region of the sample.

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Section: Designmentioning

confidence: 85%

A multi-modal stereo microscope based on a spatial light modulator

et al. 2013

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“…2 and 3, is similar to the compact optical tweezer system. 20 The inverted microscope objective is focussed by a motorised stage (LS-50-M, ASI) that is mounted vertically inside an aluminium frame of the microscope. Positioning of the sample is achieved by moving a motorised X-Y stage (MS-2000, ASI).…”

Section: System Configurationmentioning

confidence: 99%

Spatial light modulation for improved microscope stereo vision and 3D tracking

et al. 2013

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We present a new type of stereo microscopy which can be used for tracking in 3D over an extended depth. The use of Spatial Light Modulators (SLMs) in the Fourier plane of a microscope sample is a common technique in Holographic Optical Tweezers (HOT). This set up is readily transferable from a tweezer system to an imaging system, where the tweezing laser is replaced with a camera. Just as a HOT system can diffract many traps of different types, in the imaging system many different imaging types can be diffracted with the SLM. The type of imaging we have developed is stereo imaging combined with lens correction. This approach has similarities with human vision where each eye has a lens, and it also extends the depth over which we can accurately track particles.

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“…Stable 3D trapping is impossible at such a low NA when using a single trapping beam. To overcome this problem, we have modified our portable holographic optical tweezers instrument [5] (see Fig. 1(a)) to produce two counter propagating beams [12,13].…”

Section: Methodsmentioning

confidence: 99%

“…The possibility of precisely sizing a colloidal probe particle is crucial for retrieving absolute viscosity measurements from the center of mass dynamics of the probe bead [2]. Holographic optical tweezers (HOT) [3][4][5] offer a powerful tool for microrheological studies [6][7][8] and, when combined with DHM, allow for a full 3D and multipoint particle tracking for viscosity measurements [2]. The need for a high numerical aperture for stable axial trapping has confined HOT to situations where samples could be accessed using short working distance objectives.…”

Section: Introductionmentioning

confidence: 99%

Holographic tracking and sizing of optically trapped microprobes in diamond anvil cells

et al. 2016

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We demonstrate that Digital Holographic Microscopy can be used for accurate 3D tracking and sizing of a colloidal probe trapped in a diamond anvil cell (DAC). Polystyrene beads were optically trapped in water up to Gigapascal pressures while simultaneously recording in-line holograms at 1 KHz frame rate. Using Lorenz-Mie scattering theory to fit interference patterns, we detected a 10% shrinking in the bead's radius due to the high applied pressure. Accurate bead sizing is crucial for obtaining reliable viscosity measurements and provides a convenient optical tool for the determination of the bulk modulus of probe material. Our technique may provide a new method for pressure measurements inside a DAC.

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A compact holographic optical tweezers instrument

Cited by 38 publications

References 42 publications

A multi-modal stereo microscope based on a spatial light modulator

A multi-modal stereo microscope based on a spatial light modulator

Spatial light modulation for improved microscope stereo vision and 3D tracking

Holographic tracking and sizing of optically trapped microprobes in diamond anvil cells

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