Towards quantitative single cell analysis using optical tweezers and microfluidics
Abstract
Experiments on single cells have the potential to uncover information that would not be
possible to obtain with traditional biological techniques, which only reflect the average
behavior of a population of cells. In the averaging process, information regarding
heterogeneity and cellular dynamics, that may give rise to a nondeterministic behavior at
the population level, is lost. In this thesis I have demonstrated how optical tweezers,
microfluidics and fluorescence microscopy can be combined to acquire images with high
spatial and temporal resolution that allow quantitative information regarding the
response of single cells to environmental changes to be extracted.
Two main approaches for achieving the environmental changes are presented, one where
optically trapped cells are moved with respect to a stationary flow, and one where the
fluid media are moved relative to cells positioned stationary on the bottom of a
microfluidic device. Both approaches allow precise and reversible environmental changes
to be performed. The first approach achieves environmental changes in less than 0.2 s,
and is thus suited for studies of fast cellular processes. This is approximately ten
times faster than the second approach, which is, however, more convenient for studies
over longer periods of time where statistical information on a large number of individual
cells are requested. The experimental approaches are verified on different signalling
pathways in Saccharomyces cerevisiae, where the main focus is the HOG pathway.
The cellular response is followed either via brightfield images, where the volume changes
of cells are monitored, or through fluorescence images where the spatio-temporal
distributions of GFP tagged proteins are extracted.
A possible approach to increase the throughput using stationary flows is demonstrated by
introducing holographic optical tweezers, allowing several cells to simultaneously be
trapped and exposed to environmental changes. Automated image analysis combined with 3D
manipulation is shown to allow the temporal resolution to be increased, or enable studies
over longer periods of time thanks to the reduced photobleaching.
Parts of work
I. Eriksson, E., Enger, J., Nordlander, B., Erjavec, N., Ramser, K., Goksör, M., Hohmann, S., Nyström, T. & Hanstorp, D. (2007). A microfluidic system in combination with optical tweezers for analyzing rapid and reversible cytological alterations in single cells upon environmental changes. Lab on a Chip, 7, 71-76.::doi::10.1039/b613650h II. Eriksson, E., Scrimgeour, J., Granéli, A., Ramser, K., Wellander, R., Enger, J., Hanstorp, D. & Goksör, M. (2007). Optical manipulation and microfluidics for studies of single cell dynamics. Journal of Optics A: Pure and Applied Optics, 9, S113-S121.::doi::10.1088/1464-4258/9/8/S02 III. Eriksson, E., Scrimgeour, J., Enger, J. & Goksör, M. (2007). Holographic optical tweezers combined with a microfluidic device for exposing cells to fast environmental changes. Proceedings of SPIE, Vol. 6592, 65920P.::doi::10.1117/12.721859 IV. Eriksson, E., Keen, S., Leach, J., Goksör, M. & Padgett, M. J. (2007). The effect of external forces on discrete motion within holographic optical tweezers. Optics Express, 15(26), 18268-18274.::doi::10.1364/OE.15.018268 V. Eriksson, E., Engström, D., Scrimgeour, J. & Goksör, M. (2009). Automated focusing of nuclei for time lapse experiments on single cells using holographic optical tweezers. Optics Express, 17(7), 5585-5594.::doi::10.1364/OE.17.005585 VI. Eriksson, E., Sott, K., Lundqvist, F., Sveningsson, M., Scrimgeour, J., Hanstorp, D., Goksör, M. & Granéli, A. (2009). An experimental approach for quantitative studies of single cells in dynamically changing environments. Unpublished manuscript. VII. Schaber, J., Angel Adrover, M., Eriksson, E., Pelet, S., Petelenz, E., Klein, D., Posas, F., Goksör, M., Peter, M., Hohmann, S. & Klipp E. (2009). Biophysical properties of Saccharomyces cerevisiae and their relation to HOG pathway activation. Unpublished manuscript.
Degree
Doctor of Philosophy
University
University of Gothenburg. Faculty of Science.
Institution
Department of Physics ; Institutionen för fysik
Disputation
Onsdagen den 29 april 2009, kl 9.00, sal Pascal, Matematiska vetenskaper, Hörsalsvägen 1
Date of defence
2009-04-29
emma.eriksson@physics.gu.se
Date
2009-04-03Author
Eriksson, Emma
Keywords
Optical tweezers
holographic optical tweezers
microfluidics
lab-on-a-chip
fluorescence microscopy
spatial light modulator
single cell analysis
quantitative systems biology
GFP
Saccharomyces cerevisiae
Publication type
Doctoral thesis
ISBN
978-91-628-7751-4
Language
eng