Alternative modes for optical trapping and manipulation using counter-propagating shaped beams

Palima, Darwin; Lindballe, Thue B.; Kristensen, Martin; Tauro, Sandeep; Stapelfeldt, Henrik; Keiding, Søren Rud; Glückstad, Jesper

doi:10.1088/2040-8978/13/4/044013

Cited by 9 publications

(11 citation statements)

References 24 publications

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Section: Basic Concepts Of Optical Trappingmentioning

confidence: 99%

“…Different optical trapping methods based on counterpropagating beams have been reported since Ashkin's intial approach. Figure A shows a schematic of a counterpropagating beam optical trap . Lyons and Sonek developed a dual fiber trap system based on two coaxial optical fibers coupled to 1310 nm 20 mW continuous wave (cw) diode lasers .…”

Section: Basic Concepts Of Optical Trappingmentioning

confidence: 99%

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Strategies for Optical Trapping in Biological Samples: Aiming at Microrobotic Surgeons

Bunea

Glückstad

2019

Laser & Photonics Reviews

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Optical trapping and manipulation of objects down to the Ångstrom level has revolutionized research at the smallest scales in all natural sciences. The flexibility of optical trapping methods facilitates real‐time monitoring of the dynamics of biological processes in model systems and even in living cells. Different optical trapping and manipulation approaches allow displacement of nanostructures with subnanometer precision and force measurements with femtonewton precision. Due to inherent constraints of optical methods, most optical trapping experiments are performed in water or simple aqueous solutions. However, in recent years, there is an ever‐growing interest of shifting from simple aqueous media towards more biologically‐relevant media. Precise optical trapping and manipulation, combined with state‐of‐the‐art microfabrication, will enable the development of microrobotic “surgeons” with tremendous potential for biomedical and microengineering applications. This review introduces the basics of optical trapping and discusses its applications for biological samples, with focus on trapping in biological media and strategies for overcoming the challenges of optical manipulation in complex environments as a stepping‐stone for microrobotic “surgeons.”

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Section: Basic Concepts Of Optical Trappingmentioning

confidence: 99%

Section: Basic Concepts Of Optical Trappingmentioning

confidence: 99%

Strategies for Optical Trapping in Biological Samples: Aiming at Microrobotic Surgeons

Bunea

Glückstad

2019

Laser & Photonics Reviews

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“…An LCoS type SLM (Hamamatsu Photonics, Japan) with 800 × 600 pixels with a pixel pitch of 20 μm was used to actuate the shaped GPC output via a "Holo-GPC" configuration. 59 Holo-GPC works by multiplexing speckle-free GPC top-hats into holographically distributed 3-D locations in the sample volume by utilizing the convolution principle. 53,60 Hence, having Holo-GPC available is convenient for addressing multiple microspheres over a wideworking volume.…”

Section: Optical Catapulting Experimental Setupmentioning

confidence: 99%

Optical catapulting of microspheres in mucus models—toward overcoming the mucus biobarrier

et al. 2019

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Einstom L. Engay, Jesper Glückstad, "Optical catapulting of microspheres in mucus models-toward overcoming the mucus biobarrier," J.Abstract. The generalized phase contrast method is employed as an efficient "phase-only" laser beam-shaping technique in an optical setup built for catapulting microspheres through simple mucus models. The influence of the laser power and mucin concentration on the motion of the microspheres is investigated in terms of instant and average velocities on a 250-μm trajectory, corresponding to the mucus thickness in the human gastrointestinal tract. Increasing the laser power leads to higher velocities in all the tested samples, while increasing the mucin concentration leads to significant velocity decrease for similar laser input power. However, velocities of up to 95 μm · s −1 are demonstrated in a 5% mucin simple mucus model using our catapulting system. This study contributes to understanding and overcoming the challenges of optical manipulation in mucus models. This paves the way for efficient optical manipulation of three-dimensional-printed light-controlled microtools with the ability to penetrate the mucus biobarrier for in vitro drug-delivery studies. © The Authors. Published by SPIE under a Creative Commons Attribution 4.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

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“…The trapping module of the BWS has been previously described in detail. 8,13 Two independently addressable regions of a spatial beam modulating module are optically mapped and relayed as counter-propagating beam pairs in the sample. The trapping beams have a wavelength of 1070 nm and are operated at 5 mW.…”

Section: A the Biophotonics Worktationmentioning

confidence: 99%

BioPhotonics workstation: A versatile setup for simultaneous optical manipulation, heat stress, and intracellular pH measurements of a live yeast cell

Aabo

Bañas

Glückstad

et al. 2011

Review of Scientific Instruments

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In this study we have modified the BioPhotonics workstation (BWS), which allows for using long working distance objective for optical trapping, to include traditional epi-fluorescence microscopy, using the trapping objectives. We have also added temperature regulation of sample stage, allowing for fast temperature variations while trapping. Using this modified BWS setup, we investigated the internal pH (pHi) response and membrane integrity of an optically trapped Saccharomyces cerevisiae cell at 5 mW subject to increasing temperatures. The pHi of the cell is obtained from the emission of 5-(and-6)-carboxyfluorescein diacetate, succinimidyl ester, at 435 and 485 nm wavelengths, while the permeability is indicated by the fluorescence of propidium iodide. We present images mapping the pHi and permeability of the cell at different temperatures and with enough spatial resolution to localize these attributes within the cell. The combined capability of optical trapping, fluorescence microscopy and temperature regulation offers a versatile tool for biological research.

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Alternative modes for optical trapping and manipulation using counter-propagating shaped beams

Cited by 9 publications

References 24 publications

Strategies for Optical Trapping in Biological Samples: Aiming at Microrobotic Surgeons

Strategies for Optical Trapping in Biological Samples: Aiming at Microrobotic Surgeons

Optical catapulting of microspheres in mucus models—toward overcoming the mucus biobarrier

BioPhotonics workstation: A versatile setup for simultaneous optical manipulation, heat stress, and intracellular pH measurements of a live yeast cell

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