| Περίληψη: | The purpose of this work is to make an attempt to quantify and model various types of cell death for a small cell lung cancer (SCLC) cell line (U1690) after exposure to a 137Cs source and as well as to compare cell survival models, the Linear-Quadratic (LQ) and Repairable Conditionally – Repairable model (RCR).
This study is based on four different experiments that were taken place at Cancer Centrum Karolinska (CCK). A human small cell lung cancer (SCLC) cell line after the exposure to a 137Cs source was used for the extraction of the clonogenic cell survival curve. Additionally for the determination and quantification of various modes of cell death the method of fluorescence staining was implemented, where we categorized the cell death based on morphological characteristics. As next with the flow cytometry analysis we measured the properties of individual particles and more specifically the percentage of cells in each phase of the cell cycle. The quantification of senescent cells was performed by staining the samples with senescence associated-β-gal solution and then scoring as senescent cells those that had incorporated the substance. These data were introduced into a maximum likelihood fitting to calculate the best estimates of the parameters used by the model in section 2.8. In this model we sorted the modes of cell death into three categories: apoptotic, senescent and other types of cell death (nec/apop, necrotic, micronuclei, giant).
In regards to the clonogenic cell survival assay the RCR model shows a ρ2 value that is equal to 6.10 whereas for the LQ model is 9.61. Moreover from the fluorescence microscopy and senescence assay we observed an initial increase of the probability of three different categories of cell death on day 2 and at higher doses there was saturation. On day 7 a significant induction of apoptosis in a dose and time dependent manner was evident whereas senescence was slightly increased in response to dose but not to time. As for the „other types of cell death‟ category on day 7 showed a higher probability that the one on day 2 and as well as a prominent dose dependence. A dose dependent accumulation of cells in the G2/M phase of the cell cycle was induced by photons on day 2. The accumulation in the G2/M phase on day 2 is released on day 7 and simultaneously an increase of the probability of apoptosis with time was observed.
The RCR model is fitted better to the experimental data rather than the LQ model.
On day 2 there is a slight increase of the apoptotic and senescent probability with dose. On the other hand on day 7 the shape of the curve of apoptosis differs and we observe a sigmoidal increase with dose. At both time points the mathematical model fit the data reasonable well. Due to the fact that the clonogenic survival doesn‟t coincide with the one extracted from the fluorescence microscopy, a more accurate way of quantification of cell death need to be used (e.g. CVTL).
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