Deformation of single cells - Optical two-beam traps and more

Research output: Chapter in Book/Report/Conference proceedingArticle in proceedingsResearchpeer-review

Standard

Deformation of single cells - Optical two-beam traps and more. / Nielsen, Kirstine Sandager; Rungling, Tony B.; Dziegiel, Morten Hanefeld; Marie, Rodolphe; Berg-Sørensen, Kirstine.

Complex Light and Optical Forces XIII. ed. / Enrique J. Galvez; Jesper Gluckstad; David L. Andrews. SPIE, 2019. 1093516 (Proceedings of SPIE - The International Society for Optical Engineering, Vol. 10935).

Research output: Chapter in Book/Report/Conference proceedingArticle in proceedingsResearchpeer-review

Harvard

Nielsen, KS, Rungling, TB, Dziegiel, MH, Marie, R & Berg-Sørensen, K 2019, Deformation of single cells - Optical two-beam traps and more. in EJ Galvez, J Gluckstad & DL Andrews (eds), Complex Light and Optical Forces XIII., 1093516, SPIE, Proceedings of SPIE - The International Society for Optical Engineering, vol. 10935, Complex Light and Optical Forces XIII 2019, San Francisco, United States, 05/02/2019. https://doi.org/10.1117/12.2513407

APA

Nielsen, K. S., Rungling, T. B., Dziegiel, M. H., Marie, R., & Berg-Sørensen, K. (2019). Deformation of single cells - Optical two-beam traps and more. In E. J. Galvez, J. Gluckstad, & D. L. Andrews (Eds.), Complex Light and Optical Forces XIII [1093516] SPIE. Proceedings of SPIE - The International Society for Optical Engineering Vol. 10935 https://doi.org/10.1117/12.2513407

Vancouver

Nielsen KS, Rungling TB, Dziegiel MH, Marie R, Berg-Sørensen K. Deformation of single cells - Optical two-beam traps and more. In Galvez EJ, Gluckstad J, Andrews DL, editors, Complex Light and Optical Forces XIII. SPIE. 2019. 1093516. (Proceedings of SPIE - The International Society for Optical Engineering, Vol. 10935). https://doi.org/10.1117/12.2513407

Author

Nielsen, Kirstine Sandager ; Rungling, Tony B. ; Dziegiel, Morten Hanefeld ; Marie, Rodolphe ; Berg-Sørensen, Kirstine. / Deformation of single cells - Optical two-beam traps and more. Complex Light and Optical Forces XIII. editor / Enrique J. Galvez ; Jesper Gluckstad ; David L. Andrews. SPIE, 2019. (Proceedings of SPIE - The International Society for Optical Engineering, Vol. 10935).

Bibtex

@inproceedings{75268deee30f4da3b9bb54ce31233f6d,
title = "Deformation of single cells - Optical two-beam traps and more",
abstract = "An optical two-beam trap composed from two counter propagating laser beams is an interesting setup due to the ability of the system to trap, hold, and stretch soft biological objects like vesicles or single cells. Because of this functionality, the system was also named the optical stretcher by Jochen Guck, Josep Kaas and co-workers almost 20 years ago. In a favorable setup, the two opposing laser beams meet with equal intensities in the middle of a fluidic channel in which cells may ow past, be trapped, stretched, and allowed to move on, giving the promise of a high throughput device. Yet, single beam optical traps, aka optical tweezers, by far outnumber the existing optical stretchers in research labs throughout the world. The ability to easily construct an optical stretcher setup in a low-cost material would possibly imply more frequent use of the optical stretching technique. Here, we discuss advantages and disadvantages of choice of material and methodology for chip assembly and chip production. For high throughput investigations of stretching deformation of single cells, optical stretching is, however, out-performed by hydrodynamic deformability assays. As we will discuss, injection molded polymer chips may with advantage be applied both for optical stretching and for hydrodynamic deformability experiments.",
keywords = "Optical and hydrodynamic stretching, Polymer micro uidic chips, Red blood cells, Single cell biophysics",
author = "Nielsen, {Kirstine Sandager} and Rungling, {Tony B.} and Dziegiel, {Morten Hanefeld} and Rodolphe Marie and Kirstine Berg-S{\o}rensen",
year = "2019",
doi = "10.1117/12.2513407",
language = "English",
series = "Proceedings of SPIE - The International Society for Optical Engineering",
publisher = "SPIE",
editor = "Galvez, {Enrique J.} and Jesper Gluckstad and Andrews, {David L.}",
booktitle = "Complex Light and Optical Forces XIII",
note = "Complex Light and Optical Forces XIII 2019 ; Conference date: 05-02-2019 Through 07-02-2019",

}

RIS

TY - GEN

T1 - Deformation of single cells - Optical two-beam traps and more

AU - Nielsen, Kirstine Sandager

AU - Rungling, Tony B.

AU - Dziegiel, Morten Hanefeld

AU - Marie, Rodolphe

AU - Berg-Sørensen, Kirstine

PY - 2019

Y1 - 2019

N2 - An optical two-beam trap composed from two counter propagating laser beams is an interesting setup due to the ability of the system to trap, hold, and stretch soft biological objects like vesicles or single cells. Because of this functionality, the system was also named the optical stretcher by Jochen Guck, Josep Kaas and co-workers almost 20 years ago. In a favorable setup, the two opposing laser beams meet with equal intensities in the middle of a fluidic channel in which cells may ow past, be trapped, stretched, and allowed to move on, giving the promise of a high throughput device. Yet, single beam optical traps, aka optical tweezers, by far outnumber the existing optical stretchers in research labs throughout the world. The ability to easily construct an optical stretcher setup in a low-cost material would possibly imply more frequent use of the optical stretching technique. Here, we discuss advantages and disadvantages of choice of material and methodology for chip assembly and chip production. For high throughput investigations of stretching deformation of single cells, optical stretching is, however, out-performed by hydrodynamic deformability assays. As we will discuss, injection molded polymer chips may with advantage be applied both for optical stretching and for hydrodynamic deformability experiments.

AB - An optical two-beam trap composed from two counter propagating laser beams is an interesting setup due to the ability of the system to trap, hold, and stretch soft biological objects like vesicles or single cells. Because of this functionality, the system was also named the optical stretcher by Jochen Guck, Josep Kaas and co-workers almost 20 years ago. In a favorable setup, the two opposing laser beams meet with equal intensities in the middle of a fluidic channel in which cells may ow past, be trapped, stretched, and allowed to move on, giving the promise of a high throughput device. Yet, single beam optical traps, aka optical tweezers, by far outnumber the existing optical stretchers in research labs throughout the world. The ability to easily construct an optical stretcher setup in a low-cost material would possibly imply more frequent use of the optical stretching technique. Here, we discuss advantages and disadvantages of choice of material and methodology for chip assembly and chip production. For high throughput investigations of stretching deformation of single cells, optical stretching is, however, out-performed by hydrodynamic deformability assays. As we will discuss, injection molded polymer chips may with advantage be applied both for optical stretching and for hydrodynamic deformability experiments.

KW - Optical and hydrodynamic stretching

KW - Polymer micro uidic chips

KW - Red blood cells

KW - Single cell biophysics

U2 - 10.1117/12.2513407

DO - 10.1117/12.2513407

M3 - Article in proceedings

AN - SCOPUS:85064880258

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Complex Light and Optical Forces XIII

A2 - Galvez, Enrique J.

A2 - Gluckstad, Jesper

A2 - Andrews, David L.

PB - SPIE

T2 - Complex Light and Optical Forces XIII 2019

Y2 - 5 February 2019 through 7 February 2019

ER -

ID: 229116647