Technique / Cell Biology / Cell culture / Cell culture medium

We have tested the hypothesis that cell adhesion and spreading on polymer films are influenced by the amount of time that the polymer films are pre-aged in cell culture medium. Cell adhesion and spreading were assessed after a 6-h culture on poly(D,L-lactic acid) (PDLLA) films that had been pre-aged in cell culture medium for 30 min, 1, 3 or 7 d. Cell adhesion and spread area were enhanced as the duration of pre-aging PDLLA films in cell culture medium was increased. Materials characterization showed that the hydrophobicity and surface morphology of the PDLLA films changed with increasing length of pre-aging time. These results suggest that cell adhesion and spreading are sensitive to the time-dependent changes in PDLLA hydrophobicity and surface morphology that occur during exposure of the polymer to cell medium for different lengths of time. These results demonstrate that cell response to a degradable, biomedical polymer can change as a function of the amount of time that the polymer is exposed to physiological medium.

In the present study we investigated the stability of anthocyanidins under cell culture conditions and addressed the question whether degradation products might contribute to the cellular effects assigned to the parent compounds. Substantial degradation was found already after 30 min, measured by HPLC/DAD. However, the decrease of detectable anthocyanidins exceeded by far the formation of the respective phenolic acids. From the formed phenolic acids only gallic acid (GA) exhibited growth inhibitory properties. However, also GA was found to be degraded rapidly. Furthermore, the incubation with delphinidin (DEL) or GA resulted in a substantial formation of hydrogen peroxide. The suppression of hydrogen peroxide accumulation by catalase modified significantly the growth inhibitory effects of DEL and GA, indicating that hydrogen peroxide formation might generate experimental artefacts. In summary, the results show that the phenolic acids formed by the degradation of cyanidin (CY), pelargonidin (PG), peonidin (PN) and malvidin (MV) do not contribute to the growth inhibitory effect of the parent compound. The degradation of DEL generates a phenolic acid with substantial growth inhibitory properties (GA). However, taken into account the small proportion of generated GA and its lacking stability, the contribution of GA to the growth inhibitory properties of DEL might be limited.

Fast and sensitive liquid chromatography-tandem mass spectrometric assays for the determination of salinomycin in mouse plasma, liver, brain and small intestinal contents and in OptiMEM cell culture medium, were developed and validated using simple sample pre-treatment procedures. Tissue samples were homogenized with phosphate buffered saline or, for high levels in liver, with human plasma. After addition of monensin as the internal standard to plasma, homogenate or culture medium and acetonitrile extraction for tissue and plasma, the diluted medium or the supernatant was directly injected into the isocratic chromatographic system using a polar embedded reversed-phase column and formic acid in water-acetonitrile as the eluent. The eluate was completely led into an electrospray interface with positive ionization and the analytes were quantified using triple quadrupole mass spectrometry. The assays were successfully validated in the ranges 10-2000 ng/ml for OptiMEM cell culture medium, 1-2000 ng/ml for plasma and 3-2000 ng/g in liver brain and small intestinal contents. At the lowest levels, the intra-day precisions were < or =9%, inter-day precisions were < or =14% and accuracies were between 91 and 112%. The analytes were chemically stable under all relevant conditions and the assays were applied in different in vitro transport studies and in pharmacokinetic and tissue distribution studies with salinomycin in mice.