Theses and Dissertations from UMD

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New submissions to the thesis/dissertation collections are added automatically as they are received from the Graduate School. Currently, the Graduate School deposits all theses and dissertations from a given semester after the official graduation date. This means that there may be up to a 4 month delay in the appearance of a give thesis/dissertation in DRUM

More information is available at Theses and Dissertations at University of Maryland Libraries.

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    REMOVAL OF STORMWATER DISSOLVED ORGANIC NITROGEN MODEL COMPOUNDS THROUGH ADSORPTION AND BIOTRANSFORMATION
    (2019) Mohtadi, Mehrdad; Davis, Allen P.; Civil Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Bioretention systems are stormwater control measures designed to reduce nitrogen and phosphorus transferred by stormwater to water resources. They are, however, not effectively designed to remove dissolved organic nitrogen (DON). This study concentrated on improvement of bioretention design to remove stormwater DON. Batch adsorption of eight organic nitrogenous compounds onto several adsorbents showed that coal activated carbon (AC) could be a reliable adsorbent for removal of organic nitrogenous compounds such as pyrrole and N-acetyl-D-glucosamine (NAG). The adsorption capacity of pyrrole and NAG on coal AC were 0.4 mg N/g (at equilibrium concentration, Ce = 0.02 mg N/L) and 0.71 mg N/g (at Ce = 1 mg N/L), respectively. These eight nitrogenous compounds were also tested for continuous column adsorption on a media mixture of coal AC + quartz sand, and only pyrrole showed an appreciable adsorption performance; the breakthrough and exhaustion depths for pyrrole were 88 and 499 m, respectively, at the fixed superficial velocity of 61 cm/h and influent DON concentration of 1 mg N/L. Pyrrole adsorption was also minimally affected by superficial velocity (DON removal efficiency stayed > 91% for all tested superficial velocities, 7 to 489 cm/h). Because the adsorption process was successful for removal of only one (pyrrole) out of eight examined compounds, biological treatment was also investigated for removal of organic nitrogenous compounds. Biotransformation alongside adsorption demonstrated benefits such as ammonification of bio-recalcitrant organic nitrogen compounds, e.g., pyrrole, and bioregeneration of the adsorbent (coal AC). According to the results, ammonifiction might be considered as a possible reliable mechanism for stormwater DON removal at low temperatures > 4°C. Under intermittent wetting/draining conditions, the effluent DON was less than 0.1 mg N/L after the applied depth of 48 m, indicating that DON was successfully removed through simultaneous adsorption/ammonification, although generated ammonium in the effluent must be properly addressed. Overall, based on the results from the current study, some DON types were strongly adsorbed by adsorbents, e.g., adsorption of pyrrole on coal AC, some were more bioavailable, e.g., ammonification of leucine, and some were barely adsorbable and bioavailable, e.g., Aldrich humic acid on coal AC. Accordingly, both adsorption and biotransformation should be considered to enhance stormwater DON removal as much as possible.
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    Hepatic Phase I and II Biotransformation Kinetics in Fishes: A Comparative Study
    (2006-12-04) Gonzalez, Jaime Fernando; Kane, Andrew S; Marine-Estuarine-Environmental Sciences; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Eight finfish species were selected to test the similarities and dissimilarities on their phase I and II biotransformation capabilities using microsomal and cytosolic fractions of the liver. This research had three main objectives: 1) a comparison among the kinetics of the 8 species using model substrates, 2) farm-raised and laboratory-acclimated specimens of channel catfish, rainbow trout and tilapia were compared to determine similarities and differences in the biotransformation reactions, and 3) the same latter three species were tested to compare in vitro hepatic metabolism of albendazole, a drug that undergoes metabolic biotransformation mainly through hepatic phase I reactions. The comparison among the 8 finfish species showed that some of them had higher biotransformation capabilities than others. For most of the seven phase I- II reactions that were tested; rainbow trout, tilapia, channel catfish and Atlantic salmon had higher enzymatic efficiencies than those showed by of striped bass, hybrid striped bass and bluegill. Largemouth bass shared some enzymatic capabilities with one group or the other. The comparison between lab-acclimated and farm-raised specimens of tilapia, channel catfish and rainbow trout did not show biologically significant differences among the two groups of fish for the 3 species. All the values found for the kinetics of the reactions were within the ranges of the constitutive expression that has been reported for them and far below those found in other works when inducers (e.g. pollutants) of enzymatic reactions have been used. The phase I-mediated hepatic sulfoxidation of albendazole in tilapia, channel catfish and rainbow trout showed significant differences in Vmax and Km values among the three species. However, the catalytic efficacies of the reaction (Vmax/Km) in the 3 species transforming the parent compound were similar. In addition, albendazole induced EROD activity (2.6 fold) in in vivo dosed channel catfish. The results found in the present study showed that the catalytic efficiency of hepatic phase I-II enzymatic reactions varied among finfish species. Some of them may be categorized as "more efficient metabolizers" than others. This may have important implications in drug metabolism and residue depletion patterns.