The cytotoxic effects of malondialdehyde on human lung fibroblast cells

Yates, Sally A.

January 2015

Malondialdehyde (MDA) is a mutagenic and carcinogenic product of lipid peroxidation which has also been found at elevated levels in smokers. MDA reacts with nucleic acid bases to form pyrimidopurinone DNA adducts, of which 3-(2-deoxy-β-D-erythro-pentofuranosyl)pyrimidol[1,2-α]purin-10(3H)-one (M1dG) is the most abundant and has been linked to smoking. Mutations in the TP53 tumour suppressor gene are associated with half of all cancers. This research applied a multidisciplinary approach to investigate the toxic effects of MDA on the human lung fibroblasts MRC5, which have an intact p53 response, and their SV40 transformed counterpart, MRC5 SV2, which have a sequestered p53 response. Both cell lines were treated with MDA (0-1000 µM) for 24 and 48 h and subjected to a variety of analyses to examine cell proliferation, cell viability, cellular and nuclear morphology, apoptosis, p53 protein expression, DNA topography and M1dG adduct detection. For the first time, mutation sequencing of the 5’ untranslated region (UTR) of the TP53 gene in response to MDA treatment was carried out. The main findings were that both cell lines showed reduced proliferation and viability with increasing concentrations of MDA, the cell surface and nuclear morphology were altered, and levels of apoptosis and p53 protein expression appeared to increase. A LC MS-MS method for detection of M1dG adducts was developed and adducts were detected in CT-DNA treated with MDA in a dose-dependent manner. DNA appeared to become more fragmented with increasing MDA concentration, and the number of mutations in the 5’ UTR region of the TP53 gene also increased. The majority of mutations observed were insertions, compared to lung cancer mutation data where the majority were G to T transversions. This was unexpected, suggesting that tobacco smoke compounds have a different role in mutagenesis than endogenous lipid peroxidation. Thus, MDA has been found to have a clear effect on human lung fibroblasts at both the cellular and DNA level.

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Characterization of mass transport in the upper human airways

Bauer, Katrin

06 December 2011

Mechanical ventilation can be a life saving treatment. However, due to the inhomogeneous and anisotropic behavior of the lung tissue, ventilation can also lead to overdistensions of lung regions whereas other areas remain even collapsed. A first step is a more comprehensive understanding of the flow mechanics under normal breathing conditions in a healthy lung as well as for a diseased, collapsed lung. This is the aim of this work. Therefore, a realistic model of the upper human airways has been generated at which experimental and numerical investigations could be carried out. Experimentally, the flow was analyzed by means of Particle Image Velocimetry (PIV) measurements which revealed new details about the flow patterns occurring during different ventilation frequencies. Numerical results were in good agreement with the experimental results and could provide new details about the three-dimensional flow structure and emerging secondary flow within the upper airways. The study of reopening of collapsed airways has shown that larger frequencies lead to airway reopening without overdistension of already open parts. Higher frequencies also lead to homogenization of mass flow distribution within the human lung. / Künstliche Beatmung ist meist eine lebensrettende Maßnahme. Aufgrund der räumlich anisotropen und inhomogenen Eigenschaften der Lunge kann die Beatmung jedoch auch zu einer Schädigung der Lunge führen. Daraus ergibt sich die Forderung einer „Protektiven Beatmung“. Ein erster Schritt dahingehend ist ein verbessertes Verständnis der Atmung und Beatmung am Beispiel der gesunden sowie kranken, teilweise kollabierten Lunge. Dies ist das Ziel der Arbeit. Hierfür wurde ein realistisches Modell der oberen Atemwege (Tracheobronchialbaum) angefertigt. An diesem Modell können sowohl experimentelle als auch numerische Untersuchungen durchgeführt werden. Experimentell wurde die Strömung mittels Particle Image Velocimetry (PIV) untersucht, wobei neue Details bezüglich der auftretenden Strömungsmuster für unterschiedliche Frequenzen gefunden wurden. Numerische Strömungsberechnungen stimmen gut mit den experimentellen Ergebnissen überein. Dreidimensionale Strömungsstrukturen sowie die Entwicklung von Sekundärwirbeln in der Lunge konnten erklärt werden. Eine Studie am kranken, teilweise kollabierten Lungenmodell zeigte, dass mit steigender Frequenz kollabierte Bereiche wiedereröffnet werden können. Höhere Frequenzen führen weiterhin zu einer Homogenisierung der Massenstromverteilung in der Lunge.

info:eu-repo/classification/ddc/610

ddc:610