Positioning individual bacteria at pre-defined locations in a gel matrix might provide insights into how cells develop and behave, claim researchers in the UK and Sweden.
Positioning individual bacteria at pre-defined locations in a gel matrix might provide insights into how cells develop and behave, claim researchers in the UK and Sweden.
Using the force exerted by focused light beams - a technique known as ’holographic optical tweezers’ - Jonathan Cooper from the University of Glasgow, and colleagues in the UK and Sweden, arranged individual E. coli cells into microscopic patterns and then set them into a fixed position within a gelatin matrix.
This flexible approach allows cells to be arranged into a variety of complex patterns. The resulting 2D and 3D cell structures stayed intact for many days and could be sealed, moved to different locations and re-imaged using confocal and multi-photon microscopy. In addition, when supplied with appropriate nutrients, the entrapped E. coli cells stayed alive for several days.
Motivated by a desire to use recent discoveries in bioengineering and optics to develop new tools for biologists, the researchers ’hope to explore how arranging just a few cells on a micro-scale may influence their subsequent behaviour’. One of the challenges they face in the application of this technology beyond the research bench involves the creation of larger arrays that have a more general commercial interest. Ultimately, the ability to manipulate cells spatially into well-defined arrays may have a number of potential applications, including tissue replacement therapy and stem cell research. Kathryn S Lees
References
P Jordan, J Leach, M Padgett, P Blackburn, N Isaacs, M Goksör, D Hanstorp, A Wright, J Girkin and J Cooper, Lab Chip, 2005, 5, 1224, (DOI: 10.1039/<MAN>b509218c</MAN>)
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