Role of outgrowth endothelial cells for applications in tissue engineering

Co-culture systems, consisting of outgrowth endothelial cells (OEC) and primary osteoblasts (pOB), represent a prom¬ising instrument to mimick the natural conditions in bone repair processes and provide a new concept to develop constructs for bone replacement. Furthermore, co-culture of OEC and pOB could provide new insights into the molecular and cellular mechanisms that control essential processes during bone repair. The present study described several advantages of the co-culture of pOB and OEC for bone tissue engineering applications, including beneficial effects on the angiogenic activation of OEC, as well as on the assembly of basement membrane matrix molecules and factors involved in vessel maturation and stabilization. The ongoing angiogenic process in the co-culture system proceeded during the course of co-cultivation and correlated with the upregulation of essential angiogenic factors, such as VEGF, angiopoietins, basement membrane molecules and mural cell-specific markers. Furthermore the co-culture system appeared to maintain osteogenic differentiation capacity.rnrnAdditional treatment of co-cultures with growth factors or morphogens might accelerate and improve bone formation and furthermore could be useful for potential clinical applications. In this context, the present study highlights the central role of the morphogen, sonic hedgehog, which has been shown to affect angiogenic activation as well as osteogenic differentiation in the co-culture model of OEC and pOB. Treatment of co-cultures with sonic hedgehog resulted in an increased formation of microvessel-like structures as early as after 24 hours. This proangiogenic effect was induced by the upregulation of the proangiogenic factors, VEGF, angiopoietin1 and angiopoietin 2. In contrast to treatment with a commonly used proangiogenic agent, VEGF, Shh stimulation induced an increased expression of factors associated with vessel maturation and stabilization, mediated through the upregulation of growth factors that are strongly involved in pericyte differentiation and recruitment, including PDGF-BB and TGFbeta. In addition, Shh treatment of co-cultures also resulted in an upregulation of osteogenic differentiation markers like alkaline phosphatase, osteocalcin, osteonectin and osteopontin, as well as an increased matrix calcification. This was a result of upregulation of the osteogenic differentiation regulating factors, BMP2 and RUNX2 which could be assessed in response to Shh treatment. rn

Stable isotope composition of atmospheric carbon monoxide : a modelling study

Stable isotope composition of atmospheric carbon monoxide: A modelling study.rnrnThis study aims at an improved understanding of the stable carbon and oxygen isotope composition of the carbon monoxide (CO) in the global atmosphere by means of numerical simulations. At first, a new kinetic chemistry tagging technique for the most complete parameterisation of isotope effects has been introduced into the Modular Earth Submodel System (MESSy) framework. Incorporated into the ECHAM/MESSy Atmospheric Chemistry (EMAC) general circulation model, an explicit treatment of the isotope effects on the global scale is now possible. The expanded model system has been applied to simulate the chemical system containing up to five isotopologues of all carbon- and oxygen-bearing species, which ultimately determine the δ13C, δ18O and Δ17O isotopic signatures of atmospheric CO. As model input, a new stable isotope-inclusive emission inventory for the relevant trace gases has been compiled. The uncertainties of the emission estimates and of the resulting simulated mixing and isotope ratios have been analysed. The simulated CO mixing and stable isotope ratios have been compared to in-situ measurements from ground-based observatories and from the civil-aircraft-mounted CARIBIC−1 measurement platform.rnrnThe systematically underestimated 13CO/12CO ratios of earlier, simplified modelling studies can now be partly explained. The EMAC simulations do not support the inferences of those studies, which suggest for CO a reduced input of the highly depleted in 13C methane oxidation source. In particular, a high average yield of 0.94 CO per reacted methane (CH4) molecule is simulated in the troposphere, to a large extent due to the competition between the deposition and convective transport processes affecting the CH4 to CO reaction chain intermediates. None of the other factors, assumed or disregarded in previous studies, however hypothesised to have the potential in enriching tropospheric CO in 13C, were found significant when explicitly simulated. The inaccurate surface emissions, likely underestimated over East Asia, are responsible for roughly half of the discrepancies between the simulated and observed 13CO in the northern hemisphere (NH), whereas the remote southern hemisphere (SH) compositions suggest an underestimated fractionation during the oxidation of CO by the hydroxyl radical (OH). A reanalysis of the kinetic isotope effect (KIE) in this reaction contrasts the conventional assumption of a mere pressure dependence, and instead suggests an additional temperature dependence of the 13C KIE, which is driven by changes in the partitioning of the reaction exit channels. This result is yet to be confirmed in the laboratory.rnrnApart from 13CO, for the first time the atmospheric distribution of the oxygen mass-independent fractionation (MIF) in CO, Δ17O, has been consistently simulated on the global scale with EMAC. The applicability of Δ17O(CO) observations to unravelling changes in the tropospheric CH4-CO-OH system has been scrutinised, as well as the implications of the ozone (O3) input to the CO isotope oxygen budget. The Δ17O(CO) is confirmed to be the principal signal for the CO photochemical age, thus providing a measure for the OH chiefly involved in the sink of CO. The highly mass-independently fractionated O3 oxygen is estimated to comprise around 2% of the overall tropospheric CO source, which has implications for the δ18O, but less likely for the Δ17O CO budgets. Finally, additional sensitivity simulations with EMAC corroborate the nearly equal net effects of the present-day CH4 and CO burdens in removing tropospheric OH, as well as the large turnover and stability of the abundance of the latter. The simulated CO isotopologues nonetheless hint at a likely insufficient OH regeneration in the NH high latitudes and the upper troposphere / lower stratosphere (UTLS).rn

Etablierung eines Triple-Kultur-Modells der oberen Atemwege unter Einbeziehung immunkompetenter Zellen

Organophosphate können chronische Lungenerkrankungen und Vergiftungen hervorrufen. Bei der Vergiftung erfolgt eine Immunreaktion, welche noch nicht erforscht ist. In dieser Arbeit wurden Toxizitätsstudien an dendritischen Zellen und einem bronchialen Triple-Kultur-Modell durchgeführt. Dendritische Zellen spielen bei der ersten Immunabwehr in der Lunge eine große Rolle. Aus der Zell-Linie THP-1 und primären Monozyten wurden reife dendritische Zellen differenziert und mittels Durchflusszytometrie und Immunfluoreszenz auf spezifische Zellmarker, wie zum Beispiel CD11c, CD83 oder auch CD209, charakterisiert und etabliert. Durch die Vergiftung der Zellen mit Dimethoat und Chlorpyrifos konnte eine Erhöhung des Zelltodes, die Sekretion von proinflammatorischen Mediatoren, Veränderungen in der Morphologie der Zellen und ein Effekt auf den Proteinkinase-Signalweg festgestellt werden. Spezifische dendritische Zellmarker (CD83, CD209) wurden inhibiert und die Dendriten der Dendritischen Zellen kürzer und beschädigt. Die Schädigung von Chlorpyrifos war erheblich größer, als die bei Dimethoat.rnDie weiteren Toxizitätsstudien wurden an einem bronchialen Triple-Kultur-Modell durchgeführt. Hierzu wurden auf Transwell-Filtermembranen bronchiale Epithelzellen, Fibroblastenzellen und Dendritische Zellen verwendet. Die bronchialen Epithelzellen und Fibroblastenzellen waren hier physiologisch voneinander getrennt, konnten aber durch Poren in der Membran miteinander interagieren. Die Etablierung des Triple-Kultur-Modells erfolgte durch die Untersuchung von Entzündungsprozessen, durch Stimulation mit LPS, TNF-alpha und Interferon-gamma. In der Ko-Kultur konnten Zell-Zell-Kontakt Schädigungen und Erhöhung von proinflammatorischen Markern, wie zum Beispiel IL-1ß, IL-6 oder auch IL-8 gemessen werden. Versuche in der Triple-Kultur zeigten den positiven Effekt von Dendritischen Zellen. Bei höheren Konzentrationsbereichen von Dimethoat und Chlorpyrifos konnte ein Wandern der Zellen zu den geschädigten Zell-Zell-Kontakten nachgewiesen werden. Die Ausschüttung der proinflammatorischen Mediatoren wurde inhibiert, vor allem bei IL-10 war eine deutliche Reduktion, um mehr als 70% messbar. Ebenso konnten Veränderungen in dem Apoptose-Signalblick festgestellt werden. Vor allem anti-apoptotische Proteine wurden nach einer Vergiftung der Triple-Kultur induziert. Interventionsstudien mit Vitamin C zeigten allerdings keinen positiven Effekt.