Characterization of Photodamage to Escherichia coli in Optical Traps

Neuman, Keir C.; Chadd, Edmund H.; Liou, Grace F.; Bergman, Keren; Block, Steven M.

doi:10.1016/s0006-3495(99)77117-1

Cited by 617 publications

(488 citation statements)

References 37 publications

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“…This value is somewhat low compared to values given in Ref. 23, but the latter were measured for objectives without phase rings. The power losses due to the sample chamber and solution were not estimated and the data given in this work do not account for them.…”

Section: B Optical Setupcontrasting

confidence: 68%

Implementing both short- and long-working-distance optical trappings into a commercial microscope

Kraikivski

Pouligny

Dimova

2006

Review of Scientific Instruments

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Optical tweezers are now a widespread tool based on three-dimensional trapping by a tightly focused single laser beam. This configuration only works with large numerical aperture and short-working-distance (SWD) objectives, restricting optical manipulation to the high magnification end of the microscope nosepiece. Certain applications of optical trapping demand long-working distances (LWDs) at moderate magnification, imposing a more complex two-beam trapping configuration. In this article, we describe a complete setup that incorporates both SWD and LWD optical trapping functionalities into a single Axiovert 200M Zeiss microscope. We evaluate the performance of the setup in both trapping modes with latex particles, either fluorescent or not, of different sizes, in the 1–20μm range. We provide practical information allowing for optimal configuration of the two-beam geometry, in relation with longitudinal and lateral stabilities of the trap.

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Section: B Optical Setupcontrasting

confidence: 68%

Implementing both short- and long-working-distance optical trappings into a commercial microscope

Kraikivski

Pouligny

Dimova

2006

Review of Scientific Instruments

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“…It is well known that all common technologies have a strong impact both on the particles and on the surrounding medium, hence limiting the applicability of these techniques. As an example, optical (Neuman et al 1999;Leitz et al 2002;Rasmussen et al 2008) and electromagnetic (Seger-Sauli et al 2005) trapping increase the local temperature through light absorption or the Joule effect, making the trapping environment uncomfortable for cells. This is particularly problematic when the biological material is required to maintain its natural function, and hence needs to be in a condition as similar as possible to its biological environment (Yang et al 2008).…”

Section: Introductionmentioning

confidence: 99%

3D visualization of convection patterns in lab-on-chip with open microfluidic outlet

Gazzola

Scarselli

Guerrieri

2009

Microfluid Nanofluid

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Open-outlet microfluidics is getting more and more attention, thanks to the generation of capillarity-driven flows which simplify the connection with the macroworld. It is known that convection flows are generated at the interface with air, i.e., the meniscus. Several works have investigated evaporation-induced convection, but its effect on particle position control in open-outlet biodevices is still not characterized. In this paper, we present the results of 3D measurement of particle traces near the meniscus in an open-outlet vertical 400 lm micro-channel filled with a water-based saline solution. Using a standard optical microscope and a system of mirrors, we observe the 3D position of individual micro-beads floating in the solution, in a way akin to particle image velocimetry technique. A single vortex is generated at the meniscus and occupies the whole region under observation at a distance of 1.5-2.7 mm from the meniscus. The generation of the convection pattern and the vortex rotational speed are described. The convection patterns disappear when evaporation is inhibited, while both the vortex generation and the rotational speed are faster for highly saline solutions. These results are relevant to the design of biochips which require control of the particle position in a fluid since they emphasize that in open-outlet microfluidic systems not only the gravitational fall but also the convection drag must be counteracted.

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“…While optical tweezers can trap and manipulate individual gold nanorods as slender as 8 nm in diameter (29), heating and the creation of free radicals can have detrimental effects upon cell physiology (30,31). Endogenous particles such as lipid granules can be used as intracellular force handles (32), but the specific biological context of lipid granules and the aforementioned limitations with metallic nanostructures make it challenging to adopt optical tweezers for intracellular manipulation.…”

Section: Optical Ablation Of Intracellular Structuresmentioning

confidence: 99%

Biophysical Tools for Cellular and Subcellular Mechanical Actuation of Cell Signaling

Liu

2016

Biophysical Journal

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The ability to spatially control cell signaling can help resolve fundamental biological questions. Optogenetic and chemical dimerization techniques along with fluorescent biosensors to report cell signaling activities have enabled researchers to both visualize and perturb biochemistry in living cells. A number of approaches based on mechanical actuation using forcefield gradients have emerged as complementary technologies to manipulate cell signaling in real time. This review covers several technologies, including optical, magnetic, and acoustic control of cell signaling and behavior and highlights some studies that have led to novel insights. I will also discuss some future direction on repurposing mechanosensitive channel for mechanical actuation of spatial cell signaling.

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Characterization of Photodamage to Escherichia coli in Optical Traps

Cited by 617 publications

References 37 publications

Implementing both short- and long-working-distance optical trappings into a commercial microscope

Implementing both short- and long-working-distance optical trappings into a commercial microscope

3D visualization of convection patterns in lab-on-chip with open microfluidic outlet

Biophysical Tools for Cellular and Subcellular Mechanical Actuation of Cell Signaling

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