These factors introduce limitations to using forward scattered light as a trigger to discriminate cells from background and debris under some conditions. The non-specific binding of antibodies in immunofluorescence studies to dead and damaged cells was problematic when trying to distinguish intact cells of interest, especially in samples containing different cell types; using a forward scatter threshold to distinguish cells was the simplest means
of reducing artifacts from this non-specific binding. The application of this threshold to HUVEC room temperature controls shows how easily intact cells are identified from debris (Fig. 1B). In cryobiological studies learn more that require numeration of both damaged and healthy cells during assessments, traditional use of a light scatter threshold would lead to this website the exclusion of damaged cells of interest. These investigations often use the ratio of healthy to total cells (healthy and damaged) to determine the effectiveness of cryopreservation protocols. Plunging HUVEC directly into liquid nitrogen shows the extent of damage that can occur to cells in a cryopreservation procedure and the ineffectiveness of the forward scatter threshold to discriminate between debris, damaged cells and healthy cells (Fig. 1D). For cryobiological studies that need to include damaged cells in the final assessment,
an alternative strategy of gating and discriminating cells is required. The plasma membrane which has been shown to be a contributing factor to light scatter characteristics of cells is also an important determinant of cell viability. Under cryobiological conditions the membrane acts as a barrier to ice propagation during freezing, Unoprostone and is believed to be one of the primary sites of cryoinjury during exposure to freeze–thaw stress [33] and [44]. The plasma membrane is an ideal candidate to test the effectiveness of light scatter and fluorescence gating strategies to discriminate healthy and damaged cells from debris. A fluorescent membrane integrity assay (SytoEB) was used to assess the state of the cell
membrane in HUVEC room temperature controls and HUVEC plunged into liquid nitrogen (Fig. 2). The nucleic acid staining dyes of the membrane integrity assay (SytoEB) demonstrate the versatility of fluorescence measurements as membrane intact cells have high forward scatter and high green fluorescence, whereas damaged cells have low forward scatter and high red fluorescence. Due to the similarities in forward light scatter of damaged cells and debris it is difficult to accurately distinguish damaged cells from debris using forward light scatter alone. In cryobiological studies where the proportion of damaged to total (intact and damaged) cells is to be used; discarding damaged cells from assessment would introduce bias in the final result (Fig. 3).