Inverse size exclusion chromatography (ISEC)

In this work, an improved protocol for inverse size-exclusion chromatography (ISEC) was established to assess important pore structural data of porous silicas as stationary phases in packed chromatographic columns. After the validity of the values generated by ISEC was checked by comparison with data obtained from traditional methods like nitrogen sorption at 77 K (Study A), the method could be successfully employed as valuable tool at the development of bonded poly(methacrylate)-coated silicas, while traditional methods generate partially incorrect pore structural information (Study B). Study A: Different mesoporous silicas were converted by a pseudomorphical transition into ordered MCM-41-type silica while maintaining the particle-size and -shape. The essential parameters like specific surface area, average pore diameter and specific pore volume, the pore connectivity from ISEC remained nearly the same which was reflected by the same course of the theoretical plate height vs. linear velocity curves. Study B: In the development of bonded poly(methacrylate)-coated silicas for the reversed phase separation of biopolymers, ISEC was the only method to generate valid pore structural information of the polymer-coated materials. Synthesis procedures were developed to obtain reproducibly covalently bonded poly(methacrylate) coatings with good thermal stability on different base materials, employing as well particulate and monolithic materials.

Molekulare Mechanismen der Kontaktinhibition: Identifizierung neuer Tumorsuppressorgene

Die Zellen eines Organismus unterliegen ständig den Einflüssen wachstumsfördernder und –hemmender Signale. Die korrekte Verarbeitung dieser Signale ist essentiell für die Aufrechterhaltung der Gewebehomöostase. Wachstumsfördernde Signale sind z. B. Wachstumsfaktoren und –hormone. Diese Substanzen sowie ihre Rezeptoren und Signalwege sind relativ gut erforscht. Dagegen ist über die wachstumshemmenden Signalwege vergleichsweise wenig bekannt. Wichtige wachstumshemmende Signale werden einerseits über lösliche Faktoren, wie z. B. TGF-β, und andererseits über Zell-Zell-Kontakte vermittelt. Den Zell-Zell-Kontakt vermittelten Wachstumsstopp bezeichnet man auch als Kontaktinhibition. Die Kontaktinhibition ist ein wichtiges Merkmal nicht-transformierter Zellen. Im Gegensatz dazu zeichnen sich transformierte Zellen durch den Verlust der Kontaktinhibition aus, der einhergeht mit unkontrolliertem Wachstum der Zellen und Tumorbildung. Genauere Kenntnisse der molekularen Ursachen der Kontaktinhibition bzw. ihres Verlustes während der Tumorentstehung werden neue Ansatzpunkte für die Krebstherapie liefern. Diese können bei der Entwicklung neuer, nebenwirkungsärmerer Krebsmedikamente und einer verbesserten Diagnostik helfen. In der vorliegenden Arbeit sollten daher die molekularen Mechanismen der Kontaktinhibition in Fibroblasten aus der Maus näher untersucht werden. Dazu wurden differentielle Genexpressionsanalysen mittels genomweiter Microarrays durchgeführt. Weiterhin wurde der Einfluss der Kontaktinhibition auf die Regulation der Signalkaskaden der MAP-Kinasen ERK und p38 untersucht. Durch die Genexpressionsanalyse konnte gezeigt werden, dass viele Schlüsselgene des Zellzyklus und der DNA-Synthese in der Kontaktinhibition eine Rolle spielen, so zum Beispiel Skp2, Foxm1 und einige Komponenten des MCM-Komplexes. Weiterhin haben wir gezeigt, dass durch Kontaktinhibition selektiv die EGF-induzierte Signalkaskade über die MAP-Kinasen gehemmt wird.

Total OH reactivity measurements at the biosphere-atmosphere interface

The biosphere emits copiously volatile organic compounds (VOCs) into the atmosphere, which are removed again depending on the oxidative capacity of the atmosphere and physical processes such as mixing, transport and deposition. Biogenic VOCs react with the primary oxidant of the atmosphere, the hydroxyl radical (OH), and potentially lead to the formation tropospheric ozone and aerosol, which impact regional climate and air quality. The rate of OH decay in the atmosphere, the total OH reactivity is a function of the atmospheric, reactive compound's concentration and reaction velocity with OH. One way to measure the total OH reactivity, the total OH sink, is with the Comparative Reactivity Method - CRM. Basically, the reaction of OH with a reagent (here pyrrole) in clean air and in the presence of atmospheric, reactive molecules is compared. This thesis presents measurements of the total OH reactivity at the biosphere-atmosphere interface to analyze various influences and driving forces. For measurements in natural environment the instrument was automated and a direct, undisturbed sampling method developed. Additionally, an alternative detection system was tested and compared to the originally used detector (Proton Transfer Reaction-Mass Spectrometer, PTR-MS). The GC-PID (Gas Chromatographic Photo-Ionization Detector) was found as a smaller, less expensive, and robust alternative for total OH reactivity measurements. The HUMPPA-COPEC 2010 measurement campaign in the Finish forest was impacted by normal boreal forest emissions as well as prolonged heat and biomass burning emissions. The measurement of total OH reactivity was compared with a comprehensive set of monitored individual species ambient concentration levels. A significant discrepancy between those individually measured OH sinks and the total OH reactivity was observed, which was characterized in detail by the comparison of within and above the forest canopy detected OH reactivity. Direct impact of biogenic emissions on total OH reactivity was examined on Kleiner Feldberg, Germany, 2011. Trans-seasonal measurements of an enclosed Norway spruce branch were conducted via PTR-MS, for individual compound's emission rates, and CRM, for total OH reactivity emission fluxes. Especially during summertime, the individually monitored OH sink terms could not account for the measured total OH reactivity. A controlled oxidation experiment in a low NOx environment was conducted in the EUPHORE reaction chamber (CHEERS, Spain 2011). The concentration levels of the reactant isoprene and its major products were monitored and compared to total OH reactivity measurements as well as to the results of two models. The individually measured compounds could account for the total OH reactivity during this experiment as well as the traditional model-degradation scheme for isoprene (MCM 3.2). Due to previous observations of high OH levels in the isoprene-rich environment of the tropics, a novel isoprene mechanism was recently suggested. In this mechanism (MIME v4) additional OH is generated during isoprene oxidation, which could not be verified in the conditions of the CHEERS experiment.