BMC Cell Biology (Oct 2010)

The individual-cell-based cryo-chip for the cryopreservation, manipulation and observation of spatially identifiable cells. II: Functional activity of cryopreserved cells

  • Thaele Michael,
  • Howitz Steffen,
  • Greuner Martin,
  • Deutsch Assaf,
  • Sobolev Maria,
  • Moshkov Sergei,
  • Namer Yaniv,
  • Ehrhart Friederike,
  • Shafran Yana,
  • Zurgil Naomi,
  • Afrimzon Elena,
  • Meiser Ina,
  • Zimmermann Heiko,
  • Deutsch Mordechai

DOI
https://doi.org/10.1186/1471-2121-11-83
Journal volume & issue
Vol. 11, no. 1
p. 83

Abstract

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Abstract Background The cryopreservation and thawing processes are known to induce many deleterious effects in cells and might be detrimental to several cell types. There is an inherent variability in cellular responses among cell types and within individual cells of a given population with regard to their ability to endure the freezing and thawing process. The aim of this study was to evaluate the fate of cryopreserved cells within an optical cryo apparatus, the individual-cell-based cryo-chip (i3C), by monitoring several basic cellular functional activities at the resolution of individual cells. Results In the present study, U937 cells underwent the freezing and thawing cycle in the i3C device. Then a panel of vital tests was performed, including the number of dead cells (PI staining), apoptotic rate (Annexin V staining), mitochondrial membrane potential (TMRM staining), cytoplasm membrane integrity and intracellular metabolism (FDA staining), as well as post-thawing cell proliferation assays. Cells that underwent the freezing - thawing cycle in i3C devices exhibited the same functional activity as control cells. Moreover, the combination of the multi-parametric analysis at a single cell resolution and the optical and biological features of the device enable an accurate determination of the functional status of individual cells and subsequent retrieval and utilization of the most valuable cells. Conclusions The means and methodologies described here enable the freezing and thawing of spatially identifiable cells, as well as the efficient detection of viable, specific, highly biologically active cells for future applications.