Dual beam fibre trap for Raman micro-spectroscopy of single cells

PRT Jess, Veneranda Guadalupe Garces-Chavez, D Smith, Michael Mazilu, L Paterson, Andrew Clive Riches, Charles Simon Herrington, Wilson Sibbett, Kishan Dholakia

Research output: Contribution to journalArticlepeer-review

Abstract

Raman spectroscopy permits acquisition of molecular signatures from both cellular and sub-cellular samples. When combined with optical trapping we may interrogate an isolated cell reducing extraneous signals from the local environment. To date, experimental configurations have employed combinations of the single beam optical tweezers trap and Raman spectroscopy, using either the same beam or separate beams for Raman interrogation and trapping. A key problem in optical tweezers is the ability to hold and manoeuvre large cells. In this paper, we use a dual beam fibre trap to hold and manoeuvre cells combined with an orthogonally placed objective to record Raman spectra. The dual beam trap, due to its divergent light fields, offers an as yet unexploited ability to hold and move large cellular objects with reduced prospects of photodamage. We additionally show how this system permits us to move large primary human keratinocytes ( approximately 30 microns in diameter), such that we may record Raman spectra from local parts of a trapped cell with ease. Finally, we develop a rudimentary microfluidic system used to generate a flow of cells. Using our dual beam trap, combined with this flow system, we hold and acquire Raman spectra from individual cells chosen from a sample of HL60 human promyelocytic leukemia cells. (c) 2006 Optical Society of America.

Original languageEnglish
Pages (from-to)5779-5791
Number of pages13
JournalOptics Express
Volume14
Issue number12
DOIs
Publication statusPublished - 12 Jun 2006

Keywords

  • OPTICAL TWEEZERS
  • LIVING CELLS
  • SPECTROSCOPY
  • DIFFERENTIATION
  • PARTICLES
  • SYSTEM

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